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University of Groningen

Physiology in a life history perspectiveVersteegh, Maaike Annechien

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Physiology in a life history perspective

Stonechats’ adaptations to different environments

The research presented in this thesis was carried out at the Animal Ecology research group of the Centre for Ecological and Evolutioary Studies (CEES), University of Groningen, the Nether lands, and at the Max Planck Institute for Ornithology, Andechs, Germany.

�� nwo-veni - 863.04.023) awarded to Prof. B.I.Tieleman and the university of Groningen.

�� Groningen and the Faculty of Mathematics and Natural Sciences.

Lay-out and Cover Design: Johanneke Oosten�� !�"��##�� $�%��"��&�'��

ISBN: 978-90-367-5349-4ISBN: 978-90-367-5350-0 (electronic version)

�� GRONINGEN

Physiology in a life history perspective

Stonechats’ adaptations to different environments

PROEFSCHRIFT

ter verkrijging van het doctoraat in de Wiskunde en Natuurwetenschappenaan de Rijksuniversiteit Groningen

op gezag van de �� in het openbaar te verdedigen op

vrijdag 24 februari 2012om 14�30 uur

door

Maaike Annechien Versteegh

geboren op 7 januari 1976te Groningen

Promotor: Prof. dr. B. I. Tieleman

Beoordelingscommissie: Prof. dr. K. C. Klasing � � �� Prof. dr. F. J. Weissing

CONTENTS

I.

General introduction

II.

�� Pace-of-Life axis? Covariation and constraints

among physiological systems

III.!��"�� #� ��

�� $��"$��%�&� ��"

��'�� #� ��$��"$��%�&� ��"��(� ��in constitutive immunity: a common garden study with stonechats

from different environments

��'�� "��

mitochondrial function

10

22

44

66

90

��$�� "��(��

��(�$� ��(��)�� *��"�� European stonechats

��+��$ � ��"��*��$��$$ ��$�

unravel the complexity of the immune system in an ecological context

�� $��"� ��)��

avian life history: a synthesis

REFERENCES

��,!��!-��!��'

DANKWOORD

LIST OF AUTHORS

LIST OF PUBLICATIONS

110

124

166

180

202

212

218

220

10

CHAPTER I

General introduction

-��#��!��

Including physiology in life history thinking!�� .��/��$�� $ ��(�� $�� "� �� $ ��)��(�� $ ��again. There are many strategies that organisms can follow to opti-��0�� /�� &$ �� (� ��"�� found on this planet. Ricklefs and Wikelski (20021�� -�� "�� 2��(��(�� (�� $�"��$�� %�� (�(�� $ ��(�� "3��)��/��-�� 4�� "�)��"��/�-��$�� (� ��-�� "�� "�$�"��"�� (�� or demography (Ricklefs and Wikelski 2002). Moreau (1944) and Lack (19471� )� �� / �� $� �� "� � �� *� ��0��"�� $�� "��)� ��$� �� $� �� $�� (��-�� "� �� (� ��5��6��"�1966, Ricklefs 1980, 2000, Promislow and Harvey 1990, Hayes et al. 1992, Stearns 1992, Charnov 1993, Ricklefs and Wikelski 2002). It is ��)�)�� 0��"�� )�� )�� "�� #��(��$��-gevity (Cody 1966, Williams 19661��!�� (� �� "�� (Charnov 1993, Ricklefs 2000).

11

��"�� $� �� )��life history traits (Pearl 1928, Drent and Daan 1980, Wikelski et al. 2003, Tieleman et al. 2004, 2006, Speakman 2005, Wiersma et al. 2007). This results in a single dominant axis of covarying life his-tory traits and physiology, commonly referred to as Pace-of-Life axis 5�� 1996, Ricklefs and Wikelski 2002). Bird spe-cies with a slow Pace-of-Life generally produce small clutches, have ��(��$��$��)�� (��low latitudes. Species with a fast Pace-of-Life generally produce large clutches, have short development times, short life spans and live at high latitudes (Promislow and Harvey 1990, Ricklefs and Wikelski 2002, Tieleman et al. 2006, Wiersma et al. 2007). Biologists have put forward many explanations for the latitudinal trends in associated physiological and life history traits, including variation in food avail-� ��"��$ �� #�� "�� $ ��-tion, pathogen pressure and disease risk and seasonality of resources (Lack 1947, Ashmole 1963, Ricklefs 1980, 2000�� -hulst 1996, Cichon 1997, Speakman 2005). These explanations are ��(�� "��(�� )��$ ��)�"��/��$��0��56��"�1966, Gadgil and Bossert 1970, Ricklefs 2000).

Pace-of-Life and physiological constraints��"$��&$��7��7,��&�� /�� "�� physiological mechanisms are often proposed to play a part in the evolution of correlated physiological and life history traits (Ketterson et al. 1996, Ricklefs and Wikelski 2002�� 2010). The �� &�� "��&$�� "�in relation to reproduction (e. g. Drent and Daan 1980, Harvey et al. 1991, Johnson et al. 2001, Speakman 2005, Tieleman et al. 2006). �� "� �� "��&$�� $ �� -�� &�� "$ �� )�� %�� $��58�� 20071��4�� "��&$�� for example when it has to raise a lot of young or to migrate over ��)��$ ��"�� )��%�-ence life expectancy (see for a review Dowling and Simmons 2009).

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�� )��%��(�� $ ��maintenance (Cichon 1997). Over the last few years not only energy �&$�� "�� "�7�� "��"��7��(�� $ �$��7��7,��&��5�� 1996, Ricklefs and Wikelski 2002, Martin et al. 2004, 2007, Tiele-man et al. 2005, Hau et al. 20101��,��#�� and immune system exist. For example, the hormone corticoster-�� 0�� "��%�� "�� (��limited the variation in these systems that natural selection can act upon, one might expect that they have played a role in the evolution �� 4�� #�� immune systems have resulted in the evolution of a single Pace-of-Life axis is unclear. -�� (�� "�� 0�� 59-�1� 5�� 1990, Hayes et al. 1992, Wikel-ski et al. 2003, Speakman 20051��9-��/�� "� �&$�� $�� $��(�� the rest phase and at thermoneutral temperatures (King 1974). It is �� (� ��"�� "��&$�� /�� 5��"�1987, Daan et al. 19901��(��"�5�� 1998, Nudds and Bry-ant 20011��(�� "��5-�� 1988, Mueller and Dia-mond 20011��$� ��"��&$�� "�� 0�� "�composition (Daan et al. 1990, Piersma et al. 1996, Tieleman et al. 2003�1�� )��7��7,��&��54�#��#��al. 2003, Tieleman et al. 2004, Wiersma et al. 2007). These proper-ties make it a good measure for researchers interested in constraints among life history and physiology. Corticosterone is an important hormone related to self-maintenance. �� $�"�� "�� 0��)�"��$ �� (��5��$��#"��2000, Landys et al. 2006). Corticosterone increases rapidly when environmental fac-�� :� ��$ �� 54��/��1998). One of the properties of such a stress-induced corticosterone response is that individuals redirect their activities from those typical of the nor-�� "��5�� $ ��1�� (�� $�"��"��"$�� (�(��54��/��1998, Landys et al. 2006). Baseline �� )�� (��

13

workloads, like during migration or feeding of young (Landys et al. 2002, Bókony et al. 2009, Hau et al. 2010). Stress induced corticoster-��"$��0�� )��(�� $ ��)�and the value of self-maintenance is high (Bókony et al. 2009, Hau et al. 20101�� $ �� (� ��58��2010).�� "�� $ �$�� 7��7,��&��)��5�� 1996, Ricklefs and Wikelski 2002). The immune system is a complex system, with many different com-$��)�� "��$��5��78��$�� 2003, Lee 20061��"�� (��;�� "�� (�� (�� "� 5��78��$�� 2003, Janeway et al. 2004). Constitutive innate immune defenses provide the non-�$��/��/ �� is an important part of immunity (Janeway et al. 2004, Buehler et al. 2008�1�� )�� $ ��7��and trade-offs with other life history traits are thought to have $��"�� $��"�5�� 1996�� ,�� 2000, Tella et al. 2002, Martin 2005). However, pathogen pressure may differ among environments (Guernier et al. 2004), and the value of immunity may not only de-$�� 7��)�� "�� 5�&-pected) pathogen pressures (Horrocks et al. 2011). Geographical and seasonal variation in trade-offs with resource demanding life history traits together with variation in environmental factors, such as patho-gen pressure, may have led to variation among species and seasons in constitutive innate immunity.

�� Birds living at low latitudes generally have a slow Pace-of-Life, and � �� (�� 7��7,��+�� #��"� �� %�� "� � � $�"�� +�� (� �� )�� 5��$� �� "1� � �� altering clutch size, migration distance, longevity and physiology. One distinct characteristic of environments is that they express pro-��$� ��%�� $�� (�� "7��%��-

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tuations (Nelson et al. 20021�� %��(� ��$��*��$��%��"7�� ;�� "7��%��-�� )�� (� ��-ment. Depending on the location on earth, environments express a � �� (�� "�� -fall, temperature, pathogen pressure, photoperiod and many more factors (Nelson et al. 2002). Birds living in these environments may have evolved in such a way ��"�� (�� $�"��"�/��$��"��"��(� ��"�� 5-��7��#��and Hahn 2007, Helm 2009). Seasonality as a characteristic of the ��(� ��"��%�� "�� )��5��#��1980, �� "� �� 1991). Seasonality in physiology is well studied in rela-tion to reproduction and migration (Landys et al. 2002, MacDougall-Shackleton and Hahn 2007, Bauchinger et al. 2008). Animals that ��(��$�� (�� $�"��"��$ �-�� "��(��(��(� ��&$ �� processes randomly (MacDougall-Shackleton and Hahn 2007). Environmental factors affect life history and physiology at different evolutionary timescales, and as a result variation in life history and $�"��"� �%�� &�� (�� "�$��These phenomena include phenotypic plasticity, genetic differences ��$�� -��(�� "�$��)�"�� "��disentangled when raising organisms from different environments in a common environment (Turesson 1922, Gwinner et al. 1995a, Falconer and Mackay 1996). Such a common-garden experiment minimizes environmental components of variation, and highlights the genetic component of the adaptive response to different environ-��5�� &�1.1). When the experiment is restricted to closely-re-�� &�� $�� $��-ways are minimized.

Stonechats: a model species for answering evolutionary questions

�� $�� )�� (� ��-ments and showing distinct life history variation (Urquhart 2002;

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�� &�1.21�� $�� -ing from four locations (Kazakhstan, Austria, Ireland and Kenya), #�$�� -�&��#� �� + ��"�� !�-dechs, Germany (Gwinner et al. 1987). Their environments of origin �� "��$��5��$ �� "��$� �� -ity) and the stonechats have associated life history characteristics (see �&�1.2). When held in captivity stonechats display life history traits �"$�� 7��(�� $��<� ��&��$�� $��maintain variation in clutch size, development time and timing of $��=�(��)�� $��(��"�5� ��1922, König and Gwinner 1995, Starck et al. 1995, Helm and Gwinner 1999). The fact that variation is maintained in captivity indicates �� "�� (�� #� ��$��(��"��#��)�� #��them ideal study species for researchers interested in the evolution of physiology and life history.

Variation among physiology and life history traits in stonechats

In chapter 2 of this thesis we take measurements of three physiologi-��"��7�� 7��(�� $��-�� #��)�� with life history traits such as clutch size and migration distance in stonechats (Klaassen 1995, Wikelski et al. 2003), and we use it as �� 7��7,��4�� 7��corticosterone response and six measures of constitutive innate im-munity commonly used in ecological immunological studies: Micro- �� "� ��Escherichia coli, Staphylococcus aureus and Candida albicans �� )�� 5�� 2005, Millet et al. 20071�� "�� "� �� $��(Matson et al. 20051��$�� $��(Delers et al. 1983). We investigate how immune measures and cor-�� )�� )�� among or within systems at the individual level could have led to (� �� $��(��There are many studies investigating seasonality in energy expendi-ture (for a review see McKechnie 20081�� )�� "�� (�� #� �� (��-

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tion, is largely unknown. This is essential knowledge when trying to link seasonality in energy expenditure to life history traits. Most �� (�� (�� performed in temperate regions and only compare two seasons (e.g. migrating-non migrating or winter-summer; Cooper and Swanson 1994, Cooper 2000, Kvist and Lindström 2001). There are a few studies that investigate variation in energy expenditure over more than two seasons (Piersma et al. 1995, Klaassen 1995, Zheng et al. 2008��>0��20111�� #�� -parison of annual cycles in energy expenditure among temperate and � �$�� $�� 3�)��(�� $��"$��%�&� ��"��$�� 9-��4��$� �� -cannual cycles of BMR among Kazakh, European and Kenyan stone-chats housed under the same conditions. Additionally we measured �� "��9-��" �� )�� $��5�� &�1.21��(��$��"$��%�&� ��"��9-��)��-ured stonechats under different thermal regimes.��"� �� (�� (�� "� �� -��"��"��$� �� some ‘quiescent’ period (see Martin et al. 2008). Exceptions are Bue-hler et al. (2008c), who studied immunity during a whole annual cy-cle in captive red knots, and Pap et al. (2010�� 1�)�� (-�� "�� $ �� resource demands of many life cycle stages (e.g. migration (Owen and Moore 20061�� 5�� 1998), moult (Martin 2005)). However, additionally environmental factors such as pathogen pres-�� (�� "� �� %�� "� 5' ��et al. 2011, Horrocks et al. 20111��-� ��(� �� $�� (� ��)��"�� pathogen communities (Møller and Erritzøe 1998). In chapter 4 we investigate variation in circannual patterns of indices of constitu-��(��"�� $��" ��)��chapter 3. Because of the different expression of life cycle stages and the differences in seasonality of the environments we would expect ��/�� "�� 7��(�� Because we measured captive stonechats under standard conditions, �� (� �� $� �� )�� " �� $ �� )�� #� ��of circannual cycles in immunity.

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The size of an organism influences BMR within individuals over �� (�� $�� -explained variation remains within and among individuals or spe-cies when size is accounted for. Chapter 5� �&$�� $�� (� �� "�� )��7�� some organs use more energy than others, and therefore organ size �� $ �$��&$��(� ��9-�� (Daan et al. 1990, Konarzewski and Diamond 1995). Yet, there are �� (��)�� $� ��)��variation in BMR and organ size (Tieleman et al. 2003a, Russell and Chappell 2007). This leaves us with questions regarding the �� )�� $ ��)�� "��&$�� 4�� "�� #�� $�� -tochondria (Rolfe and Brown 1997, Nichols and Ferguson 2002). 9-�� "��&"��$�� -gy that is gained through the oxidative chain reaction in the mito-�� "�� $ �(��#� ��)��the cellular processes and whole animal BMR. Mitochondria are maternally inherited, and we could study the nature of heredity �� 9-�� )�� " �� $� �� $�� 56��$-ter 51��9��" ��)� �� $��(��"�� $�� known. Therefore we know to which population the mothers (and �� 1� ��

Evaluating sources of variation !�� (��(� �� $�� "��of BMR and indices of constitutive immunity we will now look in more detail at variation among species and individuals. In the follow-ing chapters we will look at sources of variation in BMR among and within individuals. We will also investigate how complex and simple �� "0��(��that are used to measure immunity. �� "��&$�� (�� 5��-sen 1995, Tieleman et al. 2003a, Wikelski et al. 20031�� related to life history traits such as clutch size, which are known to �� 5'� ��1988, Godfray et al. 1991). However, the direct �(�� "��&$�� )�� 5�?�-ning et al. 2007). In chapter 6 we investigate whether BMR and total

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evaporative water loss are individual characteristics, a prerequisite for �� "��4��(��)��)��(��(� �� &$�� "��&�� "��In chapter 2 and 4 we measured multiple indices of immunity. This stems from the fact that one immune index does not capture immu-nity as a whole. The immune system is a complex system, and can ��(�� (�� :� �� ;�� 5��78��$�� 2003, Lee 2006). To capture the complexity ecological immunologists have started to measure multiple aspects of immunity (Martin et al. 2007, Buehler et al. 2008c, Pap et al. 2010�� 1��$$ �� &-��$ �� $ �(��$$ �$ ��"0��the multiple indices is challenging. In chapter 7 we investigate how to use multivariate and simple statistics to meaningfully summarize multiple indices of immunity in an ecological context.Finally, in chapter 8�� 0��/��)��have gained from this thesis. I indicate what we have learned and what unexplored areas there still are for future work.

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Box 1.1Common garden setup

The Max Planck Institute for Ornithology had a successful history of keep-�� $�� (� ��a common garden set-up. Common garden experiments have their origin ��(�� "�$�� "�5� ��1922, Clausen et al. 19401�� )�� ;��"�� "�� 5��')�� 1995a, Klaas-sen 1995, Martin et al. 2004�� )�=#��2006). In common �� &$� �� 5�� 1�$�� environment. This is a useful set-up for investigating what proportion of ��$��"$��(� �� )��5�� 1�$�� (��/�� #� ��5<�� -��#�"�1996, Merilä and Sheldon 20011��8�)�(� �� (�� (�� -�-ternal effects (e.g. investment in the egg) and the environment of the nest may also play a role in the development of the chick (Falconer and Mackay 1996, Merilä and Sheldon 2001). By hand-raising chicks from different nests and species together, Gwinner and colleagues minimized the en-vironmental effects during development (Gwinner et al. 1987). Another point of caution is the fact that having a relatively small captive population �� "� �� "� ��(�� $�� )��$�$��A common garden experiment has the requirement that the environ-�� $��)�� #�$�� -�� thesis were kept at 20°6� "�� "� %�� -ropean day-length. A common garden set-up also gives researchers the �$$� ��"� ��$�� exposed to. I used this opportunity to look for the effects of temperature on physiology. I kept European stonechats under the standard condi-tions (20°C and European day-length) and under European day-length ��"�(� �� $� �� $� �� )�� average temperature that free-living European stonechats are exposed to as derived from locations of ringing recoveries (Helm et al. 2006). We ��=��$� �� )��)��#�"��

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Box 1.2Study species

Stonechats (Saxicola torquata �$$�1�� $�� (��(�� $�� $�� many environments over a wide range of latitudes in Eurasia and Af-rica (35oS-71oN; Urquhart 2002). All through their range their typi-�� $�� $�� -�� (��"�� $�� )�� $�� (� �� "�� )�� $�� $�� 54��2008). However, I will refer to the stonechats from different locations �� $�� Until recently, the Max Planck Institute for Ornithology in Andechs, '� ��"��$��(�� $ �� "� � �� ')�� "�1980s. The stonechats ��"� �� $��*��0�#�� stonechats (S. t. maura), European or Austrian stonechats (S. t. rubi-cola), Irish Stonechats (S. t. hibernans) and Kenyan or African stone-chats (S. t. axillaris1��-��"� ��(��)� �� $��(��"� �� )� ��#�� /��)��"�� hatching (Gwinner et al. 1987). ��(� �� $�� "�� (� ��$� �� "��)�� %�� "�� 5')��-ner et al. 1995a, König and Gwinner 1995, Helm et al. 2009, Helm 20091��0�#�� $ �� short time, from early May to end of August, during which they lay a ��)��(� ��/(�7��&�� ;��"�� moult (Helm 2002). Thereafter they migrate over long distances to Iraq, Iran, Afghanistan, Pakistan, northern India, the Middle East, ��! � �� 7��!� ��5� ;�� 2002, Raess 20081�� $��$�� -� �� $�� )�� "� ��"� �)�� )��(� ��/(��58��2002). After moult they mi-grate short distance to southern Europe and Northern Africa(Helm

21

2002, Urquhart 2002). Irish Stonechats are partly present on the �� "�� 7 ��$� ��"�� $� ��$�$��$ �� -� ��$�� winter in Spain and northern Africa (Helm 2002, Urquhart 2002). � �� "� ��"� �� )��/(��"�� "� �� rainy season, with the precise timing depending on the rains. They lay one clutch with three eggs per year (Helm 2002, Urquhart 2002). 4�� $�� #�$�� 5�� &�1.11��"��$��"�� 0�� (�� 5')�� 1995a, König and Gwin-ner 1995, Klaassen 1995, Wikelski et al. 2003, Tieleman 2007, Helm et al. 2009, Tieleman et al. 2009a, Helm 2009).

Hybrids!� ��(��#��$�� $��$-��(��"��" �� -zakh and European stonechats and European and Kenyan stonechats ��"� �� $��(��"��$ �� " �� "��(�� %��$��$�$��< ��"��" �� )��$� �� $�� %�� $� �� "��"- ��(�� "��#�� )��5�� #��1995), moult (Helm and Gwinner 1999), clutch size (Gwinner et al. 1995a) and circannual rhythms (Helm et al. 2009).��" ��(�� #� ��of physiological traits. I will refer to the two different lines as Kazakh &�� $�� $��&��"��" �� -script. Only in chapter 5�� " ��!��&�� $�� $��&�!� �� $� ��$�� %��sex of the parents in this chapter (e.g. Asian x European have Asian mothers, European x Asian have European mother).

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CHAPTER II

D��traits fall on a single Pace-of-Life axis?

Covariation and constraints among physiological systems

-��#��!�� )� ��$��;�� B. Irene Tieleman

Abstract�� $�� $�"�� -tory is thought to fall on one single axis, a phenomenon termed the ��7��7,��!��)��7��7,�� 0�� "��)�� $ �-��7�$��)�� 7��7,�� "��$$�� &��&�� $�"�� thought to restrict evolutionary potential. In that case, physiological traits should covary in the same fashion at the levels of individual organisms and species. We examined covariation at the levels of indi-(�� $�� $�"��"��5�� -�� 1�� $��)�� "�� 7�$��4�� -�� 7��7,�� -� �� &�� (��"��-�� rate covaried with two indices of immunity at the individual level, and with corticosterone concentrations and one index of immunity at �� $��(�� )�� $��-�� (� ��(�� $��-onstrate that links among physiological traits are loose and suggest that these traits can evolve independent of each other.

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Introduction�� $��$�"�� "�strategies is thought to fall on one dominant slow-fast axis, with low �$ ��(�� $�� )�� end, and the opposite traits at the other end (Promislow and Har-vey 1990, Ricklefs and Wikelski 2002). This single dominant axis �� $� �� (�� 0�� studies that include a wide array of different species (Promislow and Harvey 1990, Ricklefs 2000) to those that investigate among-individual variation within a single species (Johnson 2000, Ricklefs 2000, Tieleman et al. 2005). Traditionally, most studies connecting �� "��$�"��"�� 0��(�� -ic rate (e.g. Pearl 1928, Drent and Daan 1980, Ricklefs and Wikelski 2002, Wikelski et al. 2003, Speakman 2005, Tieleman et al. 2006), �� "� �� "�� "��(�� 7��@��7��7,��$� �$��(�.��)��5�� 1996, Ricklefs and Wikelski 2002, Tieleman et al. 2005, Lee 20061�� (��)�� -��$�"�� "�� 5�� 1�� "��#��5�� -�)��1997, Lochmiller �� 2000, Speakman 2005, Landys et al. 2006), in ad-��$��"��)�� )�� $ ��-tive effort and adult self-maintenance that characterizes the Pace-��7,��&��9��$�"��"�� $� ��)��organism and environment, Ricklefs and Wikelski (2002) suggest that the organization of physiological mechanisms may constrain ��(�� $��(� �� "��-ry variation. Constraints at the individual level would result in lim-ited evolutionary potential (Lande 1979, Schluter 1996, Duckworth 20101��A��&�� (��This requires measurements of all three physiological systems in comparative contexts.When evaluating whether and how physiological constraints play a role in shaping life history variation, patterns of covariation of traits at different levels of organization can provide complementary in-sights. If the connections among physiological mechanisms have restricted the independent evolutionary potential of physiological traits, one might expect that these traits covary in the same way within and among species. Moreover, if physiological mechanisms

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d life h

istory covary?

restrict the evolutionary potential of life history traits, one would �&$�� (� �� (� "�)��7��7,��&�� -�� $�� 8�)�(� ��$�� (� ��among traits differ within and among species, then links among physiological mechanisms are unlikely to act as constraints on life �� "� (� �� $�� $� �� -relations among traits at the individual level would strongly indicate that traits are not forced to covary through mechanistic connections. The presence, on the other hand, of a strong correlation among traits at the individual level does not necessarily confirm the existence of $�"�� (�� -f lect individual condition or quality. Finally, patterns of covariation among individuals can also stem from environmental conditions ��(��"��(� �� $��"� ��-ing in different patterns of covariation within and among species (Lande 1986, Duckworth 2010). Therefore, in studies of the physiol-��":�� "��&�� (� �� &$��"�considered as well.Environmental conditions affect life history and physiology at dif-ferent evolutionary timescales, and as a result variation in life his-tory and physiology reflects a mixture of different evolutionary phe-nomena. These phenomena include phenotypic plasticity, genetic �� $�� (�� "�$��)�"�� at least largely, disentangled when raising organisms from differ-ent environments in a common environment (Falconer and Mackay 1996). Such a common-garden experiment minimizes environmen-tal components of variation, and highlights the genetic component of the adaptive response to different environments. When the ex-periment is restricted to closely-related taxa, effects of historical pathways are minimized.Stonechats (Saxicola torquata) are an ideal study system to address evolutionary questions related to variation in life history, physiol-��"� �� (� �� )��$ �� $�� (� ��(� ��"�� )��7��(� �� "��$�"�� 5� ��2.1), and their ease of handling and acclimation to captivity (Gwinner et al. 1995a, Raess 20051��4�� #�$�� -

25

�$�� 0�� (�� 5')�� 1995a, König and Gwinner 1995, Klaassen 1995, Wikelski et al. 2003, Tieleman 2007, Helm et al. 2009, Tieleman et al. 2009a, Helm 20091��!�� )�� $��.�� (� �� "�� "��(� �� %��dominant Pace-of-Life axis. However, the stonechat immune system �� $��(�� $� �$��-��(�� "�� &�� #��)�� )�� common-garden set up allowed for a powerful integrative study of physiology and life history.In this study, we evaluate the hypothesis that variation in immune, �� "�� 7��7,�� &�� )�� $�� kept in a common garden. We then explore if physiological con-�� (��(�� &$��(� ��$�"�-��"� �� 7�� (�� $�� $��"��)��)�� $��)�� $��

sedentary partially short-distance

short-distance long-distance

()

0 0; 1200 1700 2600

year-round year-round; migrants February-September

March- mid October

early May- early September

1-2 3-4 2-3 1

3 5 5 6

related to rainy season

early April-August mid April-August late May/June

Table 2.1 – Life history traits of the studied stonechat subspecies. Kenyan stonechats have a slow Pace-

of-Life, Kazakh stonechats have a fast Pace-of-Life and Irish and European stonechats have intermediate

Pace-of-Life characteristics (after Helm 2003, Baldwin et al. 2010).

slow fast

26

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)�� $�� - �� 7��7,��54�#��#��2003, Tieleman et al. 2009a).

MethodsBirds and measurement period

�� $�� )�� $�� -ing from 71°N to 35°S (Urquhart 2002). We studied four geographi-��"�� $��*��"��S. torquata axillaris, the Irish S. torquata hibernans, the European S. torquata torquata, and the Kazakh S. torquata maura. Kenyan stonechats have a slow Pace-of-Life, Irish and European stonechats have an intermediate Pace-of-Life, and Kazakh stonechats have a fast Pace-of-Life (see Ta- ��; Klaassen 1995, Wikelski et al. 2003). We took measurements from a total of 123��7 �� 5-�&��#�� + -��"��!��'� ��"1��6�$��(�� )� ��5�B31), �)��5�B361�� 5�B23) generations removed from the wild. Wild � ��5�B331�)� ��#�� /��(��-stitute and hand-raised (Gwinner et al. 1987). All individuals were fully grown and ranged in age from 0-12 years; most individuals were 0-4�"�� 5�B109). Birds were housed individually in cages. Eight to fourteen cages were placed in rooms that were maintained at constant temperature (20-22C61�� /��*�� #��"-cle, which matched natural day length of the European population in winter at 40°N. We measured multiple innate constitutive immune �� 7�� "�� 59-�1�� )�� )��(�� <� �� "��4�� ;�� $� �� $��$��(��"*�� )� ��-� �� 4�� $� ��-�� "�� 14 Kenyan, 16 Irish, 19 European and 15 ��0�#�� <� ��$� �� "��5�� )1�)�� 26 European and 2 Kazakh �� 5�� 2008, Tieleman et al. 2009a) to the data set. We measured corticosterone concentrations in �� (��512 Kenyan, 7 European and 12 Kazakh stone-��D�� 1� �� "��0�� "� ��#��$� ��(��

27

Baseline and stress-induced corticosterone levels�� 7�� (�� )�� )��)�� $��$� � � ��/ ��$��)��)��within 3�� )�� )� ��)�� )� ��$�� 30 minutes, after which �� $��)��#�� 7�� 54��/��1992). To minimize ef-�� %�� )� ��$�� )��13.00 and 14.30 hr (Joseph and Meier 1973). Blood was kept on ice and cen-trifuged within 90�� $��<� �� $��)�� )��)�� -�)�� $��/ �� )�Samples were analyzed using radioimmunoassay protocol of Goy-mann et al. (20061�� &� �� /��)� ��90% ± 4% for �� $�� 91% ± 5% for stress-induced samples. Each sample was measured in duplicate. Intra- and inter-assay variations were 3.1% and 18.8%, respectively; the detection limit was 0.06 ng/�� 7��

Indices of constitutive immunityMicrobicidal capacity�E�4�� "�� against three microorganisms: Escherichia coli, Candida albicans and Staphylococcus aureus�� $�� )� �� )�� )�� !��"��)� ��$� �� %�)��)�� $��)-ing Tieleman et al. (2005) and Millet et al. (20071�� #�� "� $ �� "� ��E. coli and C. albicans�� )�� 5��2010). Micro- �� "��S. aureus�� $� �� #��"�� )��4��reconstituted lyophilized pellets of S. aureus (Epower Microorganisms, ATCC #6538 MicroBioLogics #0485E7, MicroBioLogics, St. Cloud, -��!D1� ��)�� .�� 4�� #� �� -$��"�� #��)� #�� Tieleman et al. (2010). We added 30�F��)� #��75 F�� &��)��225�F��4�� 15 minutes (E. coli) and 240 minutes (C. albicans and S. aureus1�� "��5��$� ��1�

28

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Complement and natural antibodies� E� 4�� -ples within one hour after collection to separate plasma and cellular fractions; we stored the plasma at -80°C until further analysis. We ;��/�� "��$��(��"� ��)��7��"��"�� "�-��52005) )�� /�� "� -��#� �� 52005). We scored hemagglutination and hemolysis titers as the last well at which the � �� )� �� "��4��)��partial agglutination or lysis were assigned half scores. All scoring )�� "��$� ��5-!�1�

Haptoglobin�E�4�� $�� $��with a commercial kit following the manufacturer’s instructions (Tridelta Development Ltd., Maynooth, Ireland). The kit colori-�� "�;�� $�� 4��&��plasma and reagents in 967)��$�� at 630 nm after 5 minutes using a Molecular Devices Spectra Max 340 plate reader.

Body mass and metabolic measurements

Respirometry equipment and setup, measurement protocol and data ��"�� )�� 5�� 2007�� 20081��4�� "�� 59-�1��(��5�B581��)��5�B281�� 5�B21�� 5�B1) times. 4��7�$��/��9-�� "��(��9-�� "� ��"��

Statistical analysesWe used the program R 2.8.0 for all statistical analyses (R develop-ment core team 20081��4�� &�� $�� (� �� "��$� �� -�� "��E. coli was left-skewed and transformed to the power of seven. After trans-�� (� �� )� �� "� �� 4�� "0��transformed and untransformed data and found that transforma-tion of the data did not affect the significance of fixed effects. First )�� $�� corticosterone concentrations and indices of constitutive immu-��"�� $� ��"�� ;��"�� )�� (�� )�� (� �� $��(��multivariate statistics.

29

Comparing each physiological trait separately among subspecies – For ��$� ��$�"�� $��)�� )�� $�� /&�� <� � �� -�� "�)�� (��per individual and we used linear models (lm in R). For the other �� )��$�� (��$� ��(��)��used mixed effect models with individual as random effect (lme in R; package lme41��4��/&��&�� $��G ��&� �� "�� 4�� /-�� G �� $�� "�� 5<�H�1.36��I�0.271��&��$�� "��E. coli 5<�B�3.50��B�0.02). Including or excluding this interaction for �� $��(� �� /�� /&��4�� $� �� G �� $�� -��$��/��)�� #)� ��-tion with P < 0.05 as selection criterion (Crawley 2007).Because immunological indices (Matson et al. 2006 ��9�� 2008�1�� 54��/��1992) can ��;��#�"�� $�� )�� $�� )�� (� ��"�� $��(� �� <� �� - ��"��)�� 5��"�1�� #�solution as a covariate. To determine if there was an effect of stress on corticosterone concentration, we used an additional mixed effects ��(�� $��$�� 50 or 30��1��/&��4��$� �� &��9-�� "7��7��-$��9-��4��(��9-��$�� "�� "��7�$��/��9-�� $��(� �� "�� "��(� ��)��9-�� $��(� �-� ��!��"��)��$� �� &�� -�� 9-��)�� "��(� ��from transformed and untransformed data did not differ and we only report results from untransformed data.

Covariation of physiological traits among subspecies – By correlating �� )��7�$��/��9-�� )�� &$�� 7�� $�� $�� (� �� -tween physiological traits and the Pace-of-Life. To reduce the num-

30

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� �� (� �� (��(� ��)��-stitutive immunity, we performed a discriminant analysis on the six immune measures (lda in R; package MASS). Discriminant analysis �&$�� $�� "�$��$�"��-�� /&�� 5�� $��1��#��(� ��(��/�� $��8��-ings on the same discriminant function indicate covariation (Craw-ley 2007). We correlated the resulting discriminant functions with ��7�$��/��9-�� "��#��(� �-�� (�� (�� "��$� ��&��$� ��"��)��$� �� $�� each trait separately, not taking into account how the values covary among individuals. This may lead to differences in the results of the two methods.

Covariation of physiological traits among individuals – To investigate ��(� �� (��-��)��"� ��(��(� �� $�� "� �� )�� $��/&�� -��(� �� (��(� ��-ces, we performed a varimax rotated principal component analysis (PCA) on the residuals of the immune indices (principal in R; pack-age psych). High loadings on the same principal component indicate ��(� �� ;��"��)�� 7�$��/��9-��with the principal components with an eigenvalue larger than one. Corticosterone concentrations were measured in a different set of ��(�� (��(��)��7�$��/��9-��

ResultsWhen we compared each physiological trait separately among the �� $��)�� $�� (� �� *�one that did not correspond with the stonechats’ Pace-of-Life varia-�� / �� $�� )��not correspond to Pace-of-Life, included all immune indices except

% E

.col

ice

lls k

illed

−16

−8

0

8

16 14 16 17 13

ab b b a

A

% C

.alb

ican

sce

lls k

illed

−24

−12

0

12

24 14 16 16 11B

% S

.aur

eus

cells

kill

ed

−40

−20

0

20

40 14 16 16 12C

hem

aggl

utin

atio

ntit

er

−0.2

−0.1

0.0

0.1

0.2 12 13 19 14D

hem

olys

istit

er

−0.6

−0.3

0.0

0.3

0.6 13 16 17 13

a b b ab

E

hapt

oglo

bin

(mg/

ml)

KenyanIris

h

European

Kazakh

−0.04−0.02

0.000.020.04 14 16 17 12F

31

Figure 2.1 – Residuals of immune indices of four subspecies of stonechats. Microbicidal

capacity of blood against (A) E. coli, (B) C. albicans and (C) S. aureus (D) hemagglutination,

(E) hemolysis and (F) haptoglobin concentration in plasma. The residuals are calculated

from linear models with covariates and all significant fixed effects except subspecies. Bars

and whiskers refer to mean values ± standard error. Letters refer to significant differences

among subspecies. Numbers refer to sample sizes.

32

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��$�� "�� 0�#�� )�� and Irish or European showed the highest or lowest values compared )�� $��$�� $��7��)�Pace-of-Life continuum (Figure ��A-��E). Although the pattern )��;��(��"�$ ��&��$��$�� )�� $��)� ��"��"�� $��"� ��E. coli� 5� ��, Figure ��A and ��E). The second pattern, which did corre-spond to Pace-of-Life, consisted of a gradual change from Kenyan to � �� $��0�#��$�� 5�� Figure ��F), stress-induced corticosterone levels (increase, Figure ��91�� "�� 5�� <�� C) and mass-specific BMR (increase, Figure ��E). In other words, for these indices the Ken-"��0�#�� $�� $�� $��)� �� !��$�� )��;��(��"�$ �� )�� $�-��)� ��"��"�� "��7�$�-��9-��5� ��).To explore patterns of covariation of physiological traits at the level �� $��)�� )��7�$��/��9-�� 7��7,��5<�� ). We �� $��.� �� 7�$��/�� 9-�� )�� (�� 7�� -��7�$��/�� 9-�� )�� /��"� �� )�� (�� 5��B�1.12��B�1��B�0.47), nor, de-spite the positive trend, with residual stress-induced levels of corti-�� 5��B�5.50��B�1��B�0.11) (Figure ��A). When we used �)� (�� )��/��$��(��5��B�25.85��B�1��B�0.02). Discrimi-�� "�� /�� )�� 7��/�� -��5� ��1��/��/ �� )�� "�� 0�#�� $�� )� �� Irish and European stonechats had intermediate values, a result con-sistent with the Pace-of-Life hypothesis (Figure ��B). The correla-��/�� )�� / �� 7�$��/��9-��)�� "� ��/�� 5�� B�3.50�� B�2�� B�0.07). Because ��)��(� �� "�� / �� )�� /��)��

33

SS

A

S

PF

d.f.P

Fd.f.

PF

d.f.P

Fd.f.

M

<0.00127.13

3, 84<0.001

14.091, 84

0.301.09

1, 340.06

2.503, 81

B

0.321.18

3,840.02

5.501, 84

0.580.31

1, 340.37

3.163, 81

B

0.0492.73

3, 850.31

1.041, 84

0.710.14

1, 330.13

1.923, 81

M-

<0.001

7.083, 84

0.171.92

1, 840.77

0.091, 34

0.013.87

3, 81

B a

0.580.56

2,220.08

3.431,20

0.790.07

1,190.40

0.962,17

S- a

0.132.21

2,260.60

0.291,25

0.035.42

1,260.63

0.482,23

H

a

0.072.51

3, 350.86

0.031, 55

0.122.53

1, 560.28

1.353, 32

H

a

0.033.21

3, 420.13

2.311, 56

<0.00114.61

1, 570.47

0.843, 39

H

a0.28

1.313, 55

0.770.09

1, 530.33

0.981, 54

0.740.42

3, 50M

:E.coli b

0.0016.24

3,500.74

0.111,50

0.680.17

1,490.01

4.153,50

C.albicans b

0.680.51

3,500.03

5.161,50

0.870.03

1, 490.99

0.043,46

S.aureus b0.51

0.783,51

0.034.73

1,510.72

0.131,50

0.710.47

3,47

a: Included as covariate in the model is the tim

e between entering the room

and completion of sam

pling.

b: Included as covariates in the model are tim



pling, and age of the microbicidal stock solution.

Table 2.2 – Results of the linear m

odels for the fixed effects subspecies, sex and age, and the interaction subspecies x sex on measures of

body mass, m

etabolic rate, imm

une function and corticosterone concentration of four subspecies of stonechats from different environ-

ments. Results are from

mixed effects or linear regression m

odels after backward elim

ination of non significant terms (P > 0.05).

base

line

cort

icos

tero

ne (n

g/m

l)

−0.6

−0.3

0.0

0.3

0.6 10 7 8A

stre

ss−i

nduc

edco

rtic

oste

rone

(ng/

ml)

−8

−4

0

4

8 12 6 12B

body

mas

s (g)

−1.0

−0.5

0.0

0.5

1.0

1.5

a b b c

BMR

(kJ/d

ay)

−1.2

−0.6

0.0

0.6

1.2 14 15 45 15D

mas

s−sp

ecifi

cBM

R (k

J/day

/g)

Kenyan Irish

European

Kazakh−0.16

−0.08

0.00

0.08

0.16 14 15 45 15

a b b c

E

34

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Figure 2.2 – Residuals of (A) baseline and (B) stress-induced corticosterone,

(C) body mass, (D) BMR and (E) mass-specific BMR of four subspecies of stone-

chats. Residuals are calculated from linear models with covariates and all signifi-

cant fixed effects except subspecies. Bars and whiskers refer to mean values ±

standard error. Letters refer to significant differences among subspecies. Num-

bers refer to sample sizes.

disc

imin

ant f

unct

ion

1he

mag

glut

inat

ion Kazakh

European

Irish

Kenyan P=0.07

B

disc

imin

ant f

unct

ion

2ha

ptog

lobi

n &

E.c

oli

−2

−1

0

1

2

3

Kazakh

European

Irish

Kenyan

P=0.66

C

mass-specific BMR (kJ/day/g)

disc

imin

ant f

unct

ion

3he

mol

ysis,

S. a

ureu

s & C

.alb

ican

s

−2

−1

0

1

2

3

1.2

Kazakh

European

IrishKenyan

P=0.83

D

resid

ual

cort

icos

tero

ne co

ncen

trat

ion

−0.4

−0.2

0.0

0.2

0.4

Kazakh

European

Kenyan

A

P=0.47P=0.11

−2

−1

0

1

2

3

1.4 1.6 1.8

35

Figure 2.3 – Subspecies level correlations between (A) residual baseline (black

circles) and stress-induced (grey circles) corticosterone and (B-D) the three discri-

minant functions of constitutive immunity and the indicator for Pace-of-Life, mass-

specific BMR. Residual corticosterone is calculated from linear models with covari-

ates and all significant fixed effects except subspecies. Dots and whiskers refer to

mean values ± standard error. P-values of the correlation are shown in the graphs. If

the correlation showed a trend (P < 0.1) a regression line was drawn.

36

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�� $ �� /�� $��/�� (� �� -��"��$�� $��"��E. coli, C. albicans and S. aureus� 5� ��; Figure ��C and ��D). The �� /��"�� )��7�$��/��9-�� $ �� 7��7,�� "��0�#�� $��)� �� the second and third functions. The principal component analysis at the level of individual revealed grouping of physiological traits that was different from the result at ��(�� $��5� �� versus�� ). The first prin-ciple component was highly correlated with hemagglutination and hemolysis. This principal component showed a significant negative �� )��7�$��9-��5��B�72.45��B�44��B�0.02) (Figure ��A). The second principle component explained most of ��(� �� $��"��E. coli and C. albi-cans. The third principal component explained most of the vari-�� $��"� ��S. aureus� ��$�� 5� ��). These two principal components did not significantly correlate with mass-specific BMR (t > -1.50�� B� 44, P > 0.14) (Figure ��B-��C).

Discussion�� $�� did not fall on a single dominant Pace-of-Life axis in stonechats, nei-�� $�� (�� 5<�� , Figure ��). Our finding that patterns of covariation of immune, endocrine �� )�� (�� $��(�� $$� ��"$�� -�� )�� $�"�� "�� (��-�� $�"�� "� �� 7��7,��(Ricklefs and Wikelski 2002). In our study, covariation among some physiological traits at the level of individual is present and points to potential� �� 5�� )1��however, find that these same traits can also vary independently of each other. Synthesizing results among studies, we therefore con-clude that the phenomenon of a single Pace-of-Life axis does not

37

F 1 F 2 F 3

H 0.757 -0.067 0.223H -0.097 -0.374 0.388H 0.101 0.290 0.131M

E. coli 0.125 -0.714 0.474C. albicans -0.071 0.249 0.905S. aureus -0.180 0.106 0.188

E 0.50 0.32 0.06P. (%) 56.94 35.93 7.14C . (%)

56.94 92.86 100.00

�2 29.72 13.45 2.44.. 18 10 4P- 0.04 0.20 0.66

Table 2.3 – Results of the discriminant analysis of six measures of constitutive immune function among

four subspecies of stonechats from different environments.

– The highest loading for each physiological trait shows to which function that trait contributes

the largest explanatory value (compare values within rows, highest value is bold). Significance of each

discriminant function indicates whether that function can be significantly discriminated among subspe-

cies. High loadings on the same discriminant function indicate correlation between physiological traits.

�� (� ��$�"�� !�$�� -tive hypothesis is that environmental factors select sets of covarying physiological traits and life history characteristics, potentially lead-ing to constrained evolution. Other environmental factors might se-lect traits (e.g. immune and endocrine) which do not covary with life history characteristics.

Physiological variation among subspeciesWe found that only some physiological traits covaried with Pace-��7,�� (�� $��$ �(�� #� ��)�� "� �� 5� ��), we used mass-specific BMR as an index for Pace-of-Life (Klaassen 1995, Wikelski et al. 2003, Tieleman et al. 2009�1��6� �� (�� "$��0��

38

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�� )�� )� ��7��7,�� -mone’s role in favoring self-maintenance over current reproduction (Wingfield et al. 1995, Wikelski and Ricklefs 2001). Our results do not support this prediction: concentrations of corticosterone were higher in fast-living Kazakh stonechats than in relatively slower-��(�� $��5�� 7��1��"��5 �� 7��1�� (� �� (�� 5-� ��2005, Bókony et al. 2009, Hau et al. 2010) or stress-induced corticosterone concentra-tions (Martin et al. 20051��7��(��$�� $�� $�$�-lations. However, other studies, including one on free-living stone-�� 54��1995, Silverin et al. 1997, Breuner et al. 2003, Goymann et al. 2006, Bókony et al. 20091�� $$� �� "$��0�� #� ��)�� corticosterone concentrations with a slower Pace-of-Life. A third set �� $� ��)�� -tions and Pace-of-Life characteristics (Breuner et al. 2003, Lind-ström et al. 2005, Hau et al. 2010). Therefore, we conclude that the corticosterone response does not overlay the single axis of variation fitting with the Pace-of-Life syndrome. 9� ��)�� $��)� ��7��7,�� /�� 59��9�)� ��2004, Lee et al. 2008, Horrocks et al. 20111�� $��)�(� ��)�no clear covariation among constitutive immunity and their Pace-of-,��4��&�)��"0��$� ��"��$�� )��only index that covaried with Pace-of-Life. When immune indices were collapsed in a discriminant analysis, only hemagglutination co-varied with Pace-of-Life. Earlier studies that measured constitutive ��"�� 7��7,�� )�� $�� !�� $�� $��)��)��7��7,�� "� ��E. coli than species with a fast Pace-of-Life (Tieleman et al. 2005). In contrast, a population of Garter Snakes (Thamnophis elegans) with a slow Pace-of-Life had ��)� �� "� ��E. coli than a fast-living popula-tion (Sparkman and Palacios 2009). The slow-living population also had comparatively lower hemagglutination and hemolysis titers. In �� $��/��"��(��Peromyscus mice species life history �� "�)��)�� "�� E. coli or with other immune measures (Martin et al. 2007). Investigations of

39

P1 P2 P3

H 0.836 -0.092 0.042H 0.849 0.168 0.093H 0.183 0.444 -0.625M

E. coli 0.268 0.720 -0.135C. albicans -0.213 0.822 0.130S. aureus 0.297 0.200 0.789

E 1.66 1.47 1.06P. (%) 28 24 18C . (%)

28 52 70

Table 2.4 – Results of principal component analysis after varimax rotation for constitutive immune

indices of individual stonechats pooled across the four subspecies.

– Loadings on the first three principal components (’s) had an eigenvalue larger than 1. Loadings

larger than 0.50 are bold. Variables are correlated if they have a high loading on the same .

induced immune responses in a Pace-of-Life context also show mixed results (Tella et al. 2002, Ardia 2005, Palacios and Martin 2006, Martin et al. 20071��+(� �� $�� our study and previous studies suggest that variation in immune �� &�� "� �� &�� "�align with a single Pace-of-Life axis.

Physiological variation among individuals!�� 7��(�� 5��)�� $��1� ��(�� "��-glutination and hemolysis were associated with Pace-of-Life. That ��"��/ �� $ ��$��$��(� �� )��7�$��/�� 9-�� 5<�� ). Studies ��(�� )��(�� -nity and Pace-of-Life characteristics at the individual level are still �� &�� )�� /��Tieleman et al. (20051� �$� �� "�� E. coli correlates with mass-corrected BMR in tropical house wrens (Troglo-dytes aedon1�� 520081��)�(� ��/�� $� ��)��(�� $ �&"�� 7��7,��

P=0.02

imm

une

PC 1

hem

olys

is &

hem

aggl

utin

atio

n

A

−3

−2

−1

0

1

2

3

P=0.25

imm

une

PC 2

E.

coli

& C

.alb

ican

s B

−3

−2

−1

0

1

2

3

P=0.14

resid. mass-specific BMR (kJ/day/g)

imm

une

PC 3

hapt

oglo

bin

& S

.aur

eus

C

−3

−2

−1

0

1

2

3

−0.4 0.0 0.2 0.4

KazakhEuropeanIrishKenyan

−0.4

−0.2

40

Ch

apter ii | D

o ph

ysiology an

d life h

istory covary?

Figure 2.4 – Individual level correlations between the indicator for Pace-of-Life,

mass-specific BMR and (A) PC1, (B) PC2 and (C) PC3 resulting from the principal

component analysis on indices of immunity. The y-axes are labeled with the indi-

ces that had the highest loadings on the PCs. Mass-specific BMR was statistically

corrected for subspecies. Correlation coefficients are calculated with pooled sub-

species, but subspecies are represented by different symbols. Significance of the

correlation is shown in the graphs and if the correlation was significant (P < 0.05) a

regression line was drawn.

41

�� "��E. coli��$� �� 5Lamprotornis superbus). Ots and Horak (1996) found that great tits (Parus major) )�� (��(�� $��:�"�$��"�� $� �� )��)� ��(��-gesting a decrease in health status. Investigations of induced immu-nity and Pace-of-Life characteristics at the individual level also lead to equivocal results (Nordling et al. 1998, Ilmonen et al. 2003, Apanius �� 20061�� $��(�� $��-�� $�� "��(� ��"�� )��and Pace-of-Life characteristics implies that at the individual level �� $� ��D��"��$�"��(� ��"�the Pace-of-Life axis. !�� "�� $� �-tween immunity and Pace-of-Life, the correlations among immune indices, which we identified at the individual level, may still rep-resent constraints within the immune system. Constraints could �&$�� )��"�� )�� "� ��E. coli and C. albicans, and ��)�� "��S. aureus ��$�� these correlations represent universal physiological constraints (i.e. �� )��1��)��)��expect to find the same correlations in other species. Red knots (Calidris canutus) and several species of waterfowl show the same �� )��"�� 5-��al. 2006a, Buehler et al. 2008 ��2008c, 2011). Furthermore, these �� )��&$�� "��$�"��*� �� $��"� � ��hemagglutination, interact functionally with lytic enzymes, like ��$�� "�� (�� 5+�� J��#-ernagel 2000, Janeway et al. 2004). However, there are also two �� $� �� )��-nation and hemolysis (Mendes et al. 2006�� =��(��2009), �� $��$� -ate, at least partly, independently from each other. Of three studies �� #�� "��E.coli and C.albicans are correlated in only one (Buehler et al. 2008 ��2008c, 2009). In previ-�� )��$�� "��S. aureus was consistently insignificant (Matson et al. 2006a, Buehler et al. 2009, 20111��$��$�"��

42

Ch

apter ii | D

o ph

ysiology an

d life h

istory covary?

�� (��"�� correlations that we identified among immune indices at the level ��(�� (� �� #��"�� -sult from physiological constraints.

Evolutionary consequences!�� &$�� (� �� =� � $�"�� "�� determine the potential presence and role of physiological con-straints in explaining the Pace-of-Life phenomenon, we validate �� (� �� )�� $�� "� � �� "�-tems do not. Therefore, if physiological constraints limit the evo-lutionary potential for variation in life history traits (Sheldon and �� 1996, Ricklefs and Wikelski 2002, Lee 2006, Hau et al. 20101�� (�� $� ��"� �� "��!�� -lar mechanisms of aging (Speakman 2005, Dowling and Simmons 20091�� !�� (�� "7 �� "$�� explain the covariation among traits that characterize the Pace-of-,�� "�� 6�� (� �� 5�� (�� "��$ �� #��$��$ �� 1�$��"� ��(�� "� �� $� �� (Lande 1986, Duckworth 20101�� (� ��"�� (� ��(�� $��&$��)�"�� "�� "�-tems, covaries with a more general life history (slow-fast) axis. On �� (� �� $�� "�� -��5��$� �� (�� "�5��2003 ��2004)) might covary with factors that impact demographic � ��5��(�� "��$ �� "�on clutch size or mortality (Ashmole 1963, Chalfoun and Martin 2007��' �� 2010, Biancucci and Martin 2010)). In this �� $�� (� "�)�� presence of constraints. On the other hand, environmental factors that impact immune system (e.g. pathogen pressure (Guernier et al. 2004, Buehler et al. 2008 ��8� ��#��2011)) or endocrine �� 5�� (� �� $ �� "1�� (� "� �� )�"�� "� �� -

43

mographic life history traits. We therefore advocate including envi- �� (��#�� )�� "�and the immune and endocrine systems.

AcknowledgementsWe thank B. Helm, L. Trost, S. Kuhn, M. Trappschuh, W. Jensen, E. Koch and W. Goymann, in addition to the late E. Gwinner for support. E. Croese, S. Engel, A. Lohrentz, C. Muck, J. Partecke, M. ��6��74�� ,�� !��4��0�� A�-��$��,�� !��<�� -�� $��"0�� $��4�� #�-�� $��9�� 4��'�"��-��-��-��#�$ �(��(�� $��)� #�)�� $$� �� "� �� + ��0�� -��/�� 5��863.04.023��9�1��7 � �� 5-!�1��

44

CHAPTER III

Annual cycles of metabolic rate result from genetic background rather than

�� !��

-��#��!�� 9� � ��8�� ')�� 9��

Abstract9� ��(��=�� "��$�"�� characteristics of their seasonally changing environments. Annual cycles in physiology can result from phenotypic plasticity or from (� �� !� #�"� $�"�� )��(� �� 59-�1��4��$��"$�� (� �� "�� "��9-��7�$��/��9-�� $�� -�� (� �� "��)��" ��lines. Birds were kept in a common garden set-up, under annually (� �� "� �� $� �� 4�� whether stonechats use the proximate environmental factor tempera-�� "�#��$�� )�� $� �� 4��"�� "��9-��7�$��/��9-�� $��#�$��(� ��$�� "��!�� (� �� " ��)��-�� $� ��$��/ ��"��(�� Temperature treatment did not affect the shape of the annual cycles �� )�� #�$�� (� �� $� �� 4��"��

45

��"�� -��(� �� #�$��(� ��$��-�� #� �� $��"$��"�%�&� ��response to proximate environmental cues.

Introduction�� (� �� %�� 5-��2008, Swanson 2010) and have repercussions for �� (�� $�"��"��"��(� �� - �� )��"��5�� (��)��-��2008), �� )��)��5��!� ��9 ��)�1988, Coop-er and Swanson 1994, Kvist and Lindström 2001, Wikelski et al. 20031�� "�� 7 ��5�� 1995, Klaassen 1995, Zheng et al. 2008��>0��2011). The variety of patterns emerging from these studies indicates that annual cycles in �� (� �� :� �)�� "�� <� ��&��$�� $� ��0�� "��(�� )�� 56��$� ��Swanson 1994, Cooper 2000, Dawson 2003). Temperate or arctic �� "��(��)� ��- �� )�� 5�� 1998, Kvist and Lindström 2001, Wikelski et al. 20031�� $�-�� $�� )�� variation (Bush et al. 2008, Maldonado et al. 2008, Doucette and Geiser 2008), an increase (Chamane and Downs 2009), or a decrease �� )�� $� ��)�� 5-��#��Geiser 2000, Smit and McKechnie 2010). Whether variation in an-��"�� -�� $��"$��%�&� ��"�� "��#��)�� $� �� "� �� "�� -�� 59-�1�� /�� 9-�� 0�� /�� "��&$�� $��7� �� $��(�� $�� 5��19741�� $��(��"�5�� 1998, Nudds and Bryant 20011�� (�� "��5-�� 1988, Mueller and Diamond 20011�� 0�� "��$��5��1990, Piersma et al. 1996, Tieleman et al. 2003a), and daily energy expend-

46

Ch

apter iii | G

en

etic backgrou

nd of an

nual cycles in

m

etabolic rate

iture (Daan et al. 1990, Nilsson 2002, Tieleman et al. 2008) make it an interesting trait for researchers studying seasonal variation.9-��%�� "��"�(� �� (� �� $� �� (�� "� 5�)��+��1999, Tieleman et al. 2003a, Broggi et al. 2007, Swanson 20101�� "��"�(� �� "�� $�"��"�5��1995, Ricklefs and Wikelski 2002, Wikelski et al. 2003��>0��2007). �� (� ��"$�� "�� =��9-��"�� -��!��"��9-��(�� "�� (��(��(�� $�� environments and not to others (Piersma and Drent 2003, Hahn and MacDougall-Shackleton 2008). Alternatively, or superimposed on a genetically orchestrated pattern, annual cycles in BMR could result � ��$��"$��"�%�&� ��=�� 5�� 2003, Hahn and MacDougall-Shackleton 20081�� )�� )� � ��=�� "��9-�� "��-vironmental conditions that they encounter. Whether annual cycles �� (�� $��"$��%�&-� ��"�� (�� "�$��$�� "�� environments in a common environment (Turesson 1922, Gwinner et al. 1995�1��"��(�� $��)�� 8�)�(� ��"�� $��"$��%�&� ��"�� )��=�� (� �� )�� the species. Additional means to investigate genetic and phenotypi-��"�%�&� �� $�� "�� "��" �� )�� "�� (� ��-��)�� #�$��Stonechats provide an ideal study system to address evolutionary ;�� "�� )�� on extensive knowledge from previous studies of their physiology and life history. Stonechats, widespread small passerines (Urquhart 20021�� (� ��(� "�� "��"��(� ��)�� %��"-cles and life history traits (Gwinner et al. 1995a, König and Gwinner 1995, Helm et al. 2009, Helm 20091��"�� "�#�$�� $��(��"��" �� )�� $�� -�� "�� $�� $ �-

amplitude A

shape B

shape + amplitude C

S MB A W S MB A W

47

Figure 3.1 – A schematic graph of how annual variation of a certain measure can

show differences in variability or shape or both. In panel (A) the gray subspecies

shows annual variation that has larger variability than the white subspecies, but that

has a similar shape; in panel (B) the grey and white subspecies show annual varia-

tion that has a similar variability, but they differ in shape; in panel (C) the subspecies

show annual variation that differs in both variability and shape. Letters refer to life

cycle stages. S=spring migration, B=breeding season, M=moult, A=autumn migra-

tion and W=winter.

48

Ch

apter iii | G

en

etic backgrou

nd of an

nual cycles in

m

etabolic rate

��)�� $��(��"�5')�� 1995a, König and Gwinner 1995, Helm et al. 2009, Helm 2009). Studies of �� $��(��)�� -�$��)�� )� ��#�$�� $��$� ��5��1995), or under common housing conditions (Wikelski et al. 2003, Tieleman 2007). In addition, repeated measures, inclusion of pedi-� �� " ��0�� $��(�� (��9-�� $�� $��5�� -steegh et al. 2008, Tieleman et al. 2009a, 2009 1��!��&��(��"�� -�� (� �� -��"��(�� $��"$��responses to annual environmental and life cycle variation. 4��$��"$�� #� ��"�� "��9-��7�$��/��9-��0�#�� $��"�� " �� -��(� ��4��$� �� $��(� �� "��-al cycles (Gwinner et al. 1995 1� �� $��$-regulate or downregulate BMR in different life cycle stages, resulting �� $�� $��"�� $�� (� �� "�5�� )��"��)��)��value; Figure ��1��"�� "�� (�� #� ��)��&$�� $��:� �(� �� "�� $��" ��)�(�� -�� $� �� $��(��)�� $��"$��%�&-� ��"��5��1��"��)��#�$�� $��stonechats under different temperature regimes, either at year-round ��$� �� "�%��$� ��

MethodsBirds

Stonechats (Saxicola torquata) originated from three different loca-��*��0�#��5�B17) (S. t. maura1�� $��5�B61) (S. t. rubicola), ��"�� 5�B22) (S. t. axillaris). Kazakh stonechats migrate over ��(�� )��"��"� �� )�� (� �� /(�7��&� �� $�� -chats are short-distance migrants that lay two to three clutches with �� (� ��/(�� "�� "�

49

generally one clutch with three eggs (Helm 2003). Birds were from / ��5�B301��5�B481�� 5�B281�� 7raised at the Max Planck Institute for Ornithology, Andechs, Ger-��"�� #�� /��(�� 7 ��5�B32) (Gwinner et al. 1987). In addition to �� $��)�� " �� )��0�#�� $�� $��5�B171�� )�� $��"�� $��5�B21). All individuals were fully grown, ranging in age from 0 to 12�"�� (��)� ��0 to 4�"�� 5�B128).

Treatments Birds were housed with 8-12 individuals per room and individuals were kept in separate cages. They were housed randomly assigned to ��)�� $�� $�� consisted of year-round constant temperatures of 20-22°C and day length following natural day length of the European population. In �� )��#�$�� -$�� 5�B14) under a weekly changing temperature regime, that mimicked the average natural temperature cycles of free-living Euro-pean stonechats (Figure ��).

Measurements 4��$� �� /(�� "�� )��<� �� "�2005 and March 2006: Spring migration (27�<� �� "��24�-� ��1�� 510 May to 2 June), moult (21 July to 19 August), autumn migration (30��$�� 7��(�� 1��)�� 524 No-(�� 14�<� �� "1�� $� �� (��during the night (Helm et al. 20051��)��)�� "��-�� 7 ��4��/��)�� ;��$� �� $ �� )� ��$�� "��$�"��-��"�$ �$� �� (��"��$ ��-� ��$�� 5')�� 1995 ��8��al. 2005). Birds were checked twice a week for moult.4�� "��9-��0�#�� $��"��)��" ��$� �� "��$�� -��$ ��"�� )�� 5��2007�� 2008, Tieleman et al. 2009a). Before and after �� )�� "��)��-

50

Ch

apter iii | G

en

etic backgrou

nd of an

nual cycles in

m

etabolic rate

��7�$��/��9-�� "��(��9-�� "��(� ��)�� "��4�� "�� 6 to 17 individuals per life cycle ��$� �� $�#�$�� 9�� -��)�� 5�� 2008, Tieleman et al. 2009a) ��$��0�� )�� 5� �$��B�45, European &��"��" ��B�21). We measured 7 to 13 individuals per life �"�� $��#�$��(� �� $� ��

Statistical analysisWe used R version 2.8.0 for statistical analyses (R development core team 20081�� )� �� "� �� 5�� (7Smirnov D < 0.09, P > 0.10), and we used mixed effects models for ��"�� 9-�� 7�$��/�� 9-��4�� "0�� 9-��)�� "��(� �� )�� $� �� "�� "��7�$��/��9-��4��(��-��)�� "�� "��9-��7�$�-��/��9-�� $��5��" ��1�� $�� $��:� � (� �� "��4��/ �� "0��(� ��-��"�� $�� #�$�� )�� $��"��&�� "��G�� $��"��G��&�� $��G��&��4��"0�� $��$� �� $�-an stonechats with models including treatment, life cycle stage, sex, �� "��G� ��"��G��&�� $��G��&��9��)�� (�� -ing multiple life cycle stages, we included individual as random effect �� "��G�� $�� "��G� ��)��/��)��/��"�� $�� $� ��$� ��"�� "��)��/��$� ��"��)�� ;��"��$��7�� $� �� $��(� �� "�� "�� "��9-��7�$��/��9-��!��"��(�� (� �� "�� )��(� �� (� ��$� � �� "�� $�� group separately (Figure ��). We compared the variances in a pair-)�� $��)��7��<7��4��/ ��-$� ��"��0�#�� $��"�� $��(��)�� "� � �� $��"$�� -ences. To further investigate genetic components of annual cycles,

−2

−1

0

1

2

3

resid

ual b

ody m

ass (

g)

Kazakh Eur x Kaz European Eur x Ken Kenyan A

−4

−2

0

2

4

resid

ual B

MR

(kJ/d

ay)

B

B

−0.6

−0.3

0.0

0.3

0.6

resid

ual m

ass−

spec

ific B

MR

(kJ/d

ay/g

)

C

S M A W BS M A W BS M A W BS M A WBS M A W

51

Figure 3.2 – Annual variation of (A) body mass and (B) BMR and (C) mass-spe-

cific BMR of Kazakh, European and Kenyan stonechats, and Kazakh x European

and European x Kenyan hybrid lines. Stonechats were kept at constant tempera-

ture and annually fluctuating day length. Bars represent means ± standard errors

of residuals of a linear model with subspecies as fixed effect. Letters represent life

cycle stages; S=spring migration, B=breeding season, M=moult, A=autumn migra-

tion and W=winter.

52

Ch

apter iii | G

en

etic backgrou

nd of an

nual cycles in

m

etabolic rate

)�� $� ��" �� 5��0�#��x European or Euro-pean x��"��1�)�� $� �� $��4�� $� ��(� �� "��9-��7�$��/��9-��$� �� $�� $� ��)�� "��x� �� $�� "��x treatment. We visualized results of ��"�� "�$�� -�$�� /&��

ResultsGenetic differences in annual cycles of mass and metabolism

!��"�� "��9-��7�$��/��9-�� $��)��(� �� "�� $��" ��of stonechats kept in a common environment (�2 >38.59��B�16, P < 0.001D�� A; Figure ��).

Comparing subspecies in a common environment6��$� �� $��$��"�� "��)�� 0�#��"�� $��(��$��"�� 5<�� A, Appendix ��). Rela-��(�� $��.��(� ��0�#��"�� )� ��$�-��"��("��)�� $� �� -ing, moult and winter. European stonechats were also heavier in the �� $� �� these life cycle stages were less pronounced and not significant (Ap-pendix ��1��8�)�(� �� $� �� $��)� �� -tively heavy, unlike Kazakh and Kenyan stonechats. Despite the im-$ �� (� �� $�� (� �� "��"�� $��5� ��). !�� "�� 9-�� $�� $�� 5<��-ure ��B, Appendix ��). Kazakh stonechats had a relatively high 9-�� )�9-�� In contrast, in European stonechats BMR was not elevated dur-�� (��"� ��)� �� 6�� "�� 0�#�� $�� 9-��Kenyan stonechats was especially elevated during moult. Although ��0�#�� $$�� (�� (� ��"��(� �� "��"�� -�$��5� ��)

53

Table 3.1 – Statistics for body m

ass, BMR and m

ass-specific BMR of (A

) Kazakh, K

azakh x European, European, European x Kenyan and Kenyan stonechats and (B)

European stonechats kept at constant and variable temperature. Results are from

linear mixed m

odels with individual as random

effect, after backwards elim

ination

of non-significant (P>0.05) terms. W

henever an interaction was significant, statistics of m

ain effects cannot be meaningfully interpreted, and they are not show

n.

B

BMR

- BM

R

..�

2P

�2

P�

2P

AL 16

38.590.001**

48.71<0.001**

48.89<0.001**

S 4

1.660.80

4.040.40

4.110.39

L 4

3.240.52

1.720.79

1.690.79

S4

--

--

--

L 4

--

--

--

S1

16.13<0.001**

1.730.19

5.580.02*

A

10.12

0.730.14

0.710.93

0.33

BL

47.01

0.1410.26

0.04*2.66

0.62

T

10.76

0.380.35

0.550.05

0.82

L 4

5.710.22

12.610.01*

4.280.37

T

10.95

0.33-

-6.31

0.01*

L 4

32.21<0.001**

--

10.010.04*

S1

15.21<0.001**

--

6.730.01

A

11.12

0.290.08

0.781.06

0.30

54

Ch

apter iii | G

en

etic backgrou

nd of an

nual cycles in

m

etabolic rate

�� $�� "�� 7�$��/�� 9-�� $��5<�� C, Appendix ��) with for Kazakh stonechats low values during spring and especially autumn migration, and high (�� $� �� $��)��(� -��7�$��/��9-�� "�� "��-�� 7�$��/�� 9-�� )�� (�� during autumn migration. The other life cycle stages did not differ � �� (� �� "� )�� /��"� �� $��*��0�#�� (� �� $��(F

4,4�B�12.37��B�0.02D�� ).

Comparing hybrids with parent lines4�� $� �� "�� " �� )�� $��-��(��$� ��)�� "��9-��7�$��9-��" ��)�� (��$�- �� $�� $� ��lines (Figure ��D�� D�� ). Body mass of Kazakh x Eu-ropean stonechats showed a annual cycle similar in shape to that of ��0�#�� #��(��$ �� $� ��)�� $�� $�� 5<�� !1�� )�� (� �� -��"��0�#��&�� $��" �� $� �� $��5� ��1��9��"�� $�� &��"��" ��)� �� -�� $� �� $�� )�� $�� &� ��"�� " �� )�� "�� $�� $� ��)��"��(Figure ��!1�� (� �� "� )�� $$�� (�� )� �� $��&��"��" �� $� �� $��5� ��). ��$��"��9-��0�#��&�� $��" ��was similar to that of European stonechats, lacking the pronounced ��)�(�� $��-��(��"�� 0�#�� 5!$$��&��A; Figure ��B). The vari-� ��"��"��9-��)��/��"��)� ��0�#��&�� $��" ��0�#��5<

4,4�B�7.27,

��B�0.04D�� 1�� $��&��"��" ��9-�� European stonechats during spring migration, Kenyan stonechats �� )�� -

55

B

()

BMR (/)

- BMR (//)

V

S

± ..

V

S

± ..

V

S

± ..

K

1.636a

13.8 ± 0.56a

4.120

a22.4 ± 0.73

a0.042

a1.63 ± 0.06

a

K E

1.104ab

14.4 ± 0.40ab

0.567 b

23.1 ± 0.51a

0.019 ab

1.63 ± 0.04a

E0.474

ab14.3 ± 0.47

a1.311

ab22.0 ± 0.60

a0.003

b1.54 ± 0.05

ab

E K

0.184 b

15.6 ± 0.52b

0.568 b

22.1 ± 0.67a

0.006 ab

1.43 ± 0.06b

K

0.967 ab

17.7 ± 0.58

c

1.249 ab

22.3 ± 0.74

a

0.013 ab

1.26 ± 0.06

c

B

()

BMR (/)

- BMR (//)

V

T

± ..

V

T \

± ..

V

T

± ..

C

0.474

a14.36 ± 0.43

1.311 a

22.0 ± 0.560.003

a1.54 ± 0.05

V

1.092a

14.74 ± 0.371.775

a23.37 ± 0.48

0.002a

1.60 ± 0.04

Table 3.2 – Variance of estim

ates over the five life cycle stages and overall subspecies means ± standard errors for body m

ass, BMR and m

ass-specific BMR of

Kazakh, European and Kenyan stonechat and tw

o hybrid lines. Different letters indicate significant differences (P < 0.05).

Table 3.3 – Variance of estim

ates over the five life cycle stages and overall treatment group m

eans ± standard errors for body mass, BM

R and mass-specific BM

R

of European stonechats kept at variable and constant temperature. D

ifferent letters indicate significant differences (P < 0.05).

56

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tween parent lines during moult (Figure ��91��(� �� "�)�� /��"� �� )�� $�� &� ��"�� $� �� $��5� ��). -��7�$��/��9-��0�#��&�� $��" ��)�� 0�#�� close to values of European stonechats during spring migration and winter (Figure ��61��-��7�$��/��9-��0�#��&�� $��"- �� /��"� �� (� �� "� � �� 0�#�� $�� )�� $� �� $��did differ from each other implies that annual variation of this hy- �� $� �� $��5� ��). �� $��&��"��" ��7�$��/��9-��)�� moult and low during autumn migration, a similar shape as Kenyan stonechats (Figure ��61�� $ �� )�� 7�$��/��9-��(� �� $��&��"��" �� $� �� $��(� �� "��9-��- �$��&��"��" �� $��"��5� ��).

�� response to temperature

When comparing European stonechats kept at constant temperature )��#�$��(� �� $� �� )��$��(� �� "�� "�� "��7�$��/��9-�� )�� 7�$��/��9-��)�� "�� 7 �� (� �� $� �� $� 5<�� B and �� 1��!�� (��/�� -�� G�� "�� 5� �� B), we found that mass-�$��/��9-��)�� "��)��/��"�� -�)�� $��5� ��B). The effect of life cycle stage was ��/�� "��7�$��/��9-��5� ��B). !(� �� (� � �� /(�� "�� #�$�� (� �� temperature had a 8K�� 7�$��/��9-�� #�$��$� �� (� �� "��"�� "��7�$��/��9-��/��"�� )��)�� $��5� ��)<� �9-��"�� )�� $��-�� "��/�� G��"��5� ��B; Figure ��61��4��/ ��$� ��$��"��

tem

pera

ture

(ºC

) A10

20

Apr Jul Oct Jan Mar Jun Sep Dec Mar

−1.6

−0.8

0.0

0.8

1.6

resid

ual b

ody m

ass (

g) B

−2.4

−1.2

0.0

1.2

2.4

resid

ual B

MR

(kJ/d

ay) C

−0.2

−0.1

0.0

0.1

resid

ual m

ass−

spec

ific

BMR

(kJ/d

ay/g

)

D

S B M A W S B M A W

57

Figure 3.3 – (A) Annual variation in temperature in standard and variable tempera-

ture treatment groups. The dotted line represents the temperature birds were ex-

posed to, the solid lines the measurement periods. (B) Body mass (C) BMR and (D)

mass-specific BMR of European stonechats kept at standard and variable tempera-

ture treatments and measured during five life cycle stages. Bars represent means ±

standard error of the residuals of a linear model with treatment as fixed effect. Let-

ters represent life cycle stages; S=spring migration, B=breeding season, M=moult,

A=autumn migration and W=winter.

58

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using post-hoc tests comparing life cycle stages with each other per treatment, and found that the difference occurred in the autumn mi-� ��$� �� #�$��(� �� temperature had a BMR close to the treatment group’s average, while stonechats kept at constant temperature showed a relatively low value (Appendix ��1��4��#��(� �� "��9-�� (� �� $��5� ��). Because different temperature regimes can also result in overall dif-�� 9-�� )�� $�� "�� )��also explored for each life cycle stage if treatment groups differed from each other. During spring migration (�2�B�3.87��B�1��B�0.049) and autumn migration (�2�B�12.49��B�1, P < 0.001) stonechats kept at ��$� �� /��"��)� �9-��#�$��(� �� $� �� "�� groups did not differ from each other (�2�B�2.21��B�1��B�0.14).

Discussion� �� $�� (� �� "� �� "�� "��9-��7�$��/��9-��)�� #�$��-��(� ��$��(��"��)��" �� -�)�� $��$��"�� "��)��(��intermediate to the parent lines. Keeping stonechats at two tempera-�� (� �� "�� $�� (� �� "��"�� "��7�$��/��9-��8�)�(� ��7�$��/��9-��)��8% higher �� "�� #�$��(� �� $� �� 9-��)�� #�$��(� �� $� �� )��"-��/��)��(� ��$��(� �-� ��"��"�� "�� $��"$��%�&� ��"�� modest variation superimposed on the genetic program.�� #� �� "�� Kazakh, European and Kenyan stonechats indicates that these cycles � �� (��(�� "�� "�� $�� (� ��-�� $�� "�� )��(� �� "�

59

characteristics (Daan et al. 1990, Ricklefs and Wikelski 2002). One ��&$�� (� ��"�� -ter larger environmental differences during the year or that vary their work levels more during the year. Because it is challenging to provide �� .��$� �$��(��(� �� $��"� "�� )��/ ��&$�� "�� could explain the annual cycle differences among stonechats. Because ��0�#�� (� ��"�� -est clutch and migrate the longest distance (Raess 2008), we expected that they would experience the largest differences in energy expendi-�� "��4��&$�� $�� "� ��$� ��(�� -��0�� distance (Helm 2003). Free-living Kenyan stonechats may experience ��(� ��"�� "�� and only produce one small clutch per year (Dittami and Gwinner 19851�� (�� "�� -� ��"��%�� "�� "�� )��)��&$��Kenyans would have evolved the least, Europeans intermediate and ��0�#�� (� �� "�� $��(�� "�� $ ��(�� 8�)�(� ��)��/�� $��"��)��(� �� "��7�$��/��9-�� (� �� "� �� $�� 0�� $�� "��$��/��"��stages, such as migration and moult. This may indicate that environ-�� $� �� (�� "��$��/��life cycle stage demands play important roles in the evolution of the ��"�� $�� "� �� 9-�� 7�$��/�� 9-�� $ �� "�� 9-�� 0�#�� $��7�$��/��9-�� -0�#�� "��=�� -gration periods are commonly found in many captive and free-living � �� $�� $�� 5��')�� 1996, �� 2000�� >0�� 2007). The result of a lower BMR during autumn than during spring migration is also found in � ��7��(�� "��)7 ��$�� )� �� 5�)�� 1999). In several waders BMR was lower during autumn migration

60

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�� )�� $�� in the arctic (Lindström 1997, Kvist and Lindström 2001). BMR de-$�� &�� "� ��:� � � �� $�� 58��9�� 1996, Piersma et al. 1999, Dietz et al. 1999, Tieleman et al. 2003�1�� 7��(�� $ �� 5��more urgent) than autumn migration (Pearson and Lack 1992), and �� $ �� "� �� $� �� 5��reproductive organs, see Bauchinger et al. 2005), leading to a differ-ence in BMR in the two migration periods.9-��7�$��/��9-��"��)�� #� �"�� /�� )�� #�� $�-cies. Klaassen (1995) showed that Kenyan stonechats had a higher total plumage mass, and a shorter duration of moult, than European stonechats. Related, Tieleman (2007) found that the insulation of ��"��)�� $��0�#��9�� )�� )��of feathers produced per day (Dietz et al. 1992, Lindström et al. 1993). Therefore, our results support Klaassen’s (1995) hypothesis of a higher �� 9-�� )��$ ��)��cycle stages in Kenyan than in European stonechats. 9��"� �� 9-�� 7�$��/�� 9-�� )�� " �� )� �� $� �� $��"�� $� �� $�� (�� $�� "�� )�� "�� $��-�� "� ��"��$��$�-��"��0�� "��(�� density and mitochondrial function (Daan et al. 1990, Tieleman et al. 2003a, 2009��>0��4��2005, Zheng et al. 2008), that ��"��(�� 6�� 0�� "�� "�� 5�� 1999, Dietz et al. 1999, Tieleman et al. 2003a, Zheng et al. 20081�� (��)� #��" �� )�� $ �� "� �� -�� "� ��&�� 5�� "� � �� 1� �� 5�� $� -��1�� )��$� ��5��et al. 2009�1��,�#�)�� "�� "��$�� "�� $� ��" ��

61

��"� ��$��&��$�� #� ��"��(�� $��(� �� -�� "��)��" ��$��(� �� "��"�� $��)� �� "��$� �� "��7�$��/�� 9-�� "� �� $� �-�� 9-��A�� #�$�� (� �� $� �� 7�$��/��9-��"�� #�$��$� �� $��=�� (� �� "��/&�� $� �� #��#�$��(� �� $� �� 9-�� )� �7��$��/�� 7��$��/��)�� 5�>0��20111��!�� 7��(��$� �� =�� 9-��:� ��7�$��/��9-�� )�� $� �-tures (Swanson and Olmstead 1999, Broggi et al. 20071��>0��(20111�$ �$��=��"�� -�� #�� "�(� �� (e.g. high and low temperatures) that knots face during the annual cycle, a fact that may also apply to temperate resident species (Swan-son and Olmstead 1999, Broggi et al. 2007). Free-living European stonechats may keep their thermal environment relatively constant �� "�� "� �� $��)��-ter in southern Europe and northern Africa, where winters are mild (Helm 20031��"��%�&� ��"��"��9-�� "��"� �� $� �-�� "��"� ��

AcknowledgementsWe thank the animal care takers and technical staff of the Max Planck Institute for Ornithology, especially Lisa Trost, Willi Jensen �� 4��)��#��#�-� �� (��-��-�� $��9��)��/��"��$$� �� "�� + �� -��/�� 5�4+�� 863.04.023)

62

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Appendix 3.1A K K E

||- P ||- P

B – 4.335 <0.001** 1.418 0.61 – 0.062 1.00 1.265 0.71 - 3.748 0.002** 7.042 <0.001** – 5.012 <0.001** 5.571 <0.001** - 5.988 <0.001** 0.959 0.87 – 4.558 <0.001** 2.837 0.04* - 3.304 0.008** 5.11 <0.001** – 0.888 0.90 2.169 0.19 - 1.529 0.54 3.876 0.001** – 0.698 0.96 0.619 0.97

BMR - 1.300 0.69 0.421 0.99 - 2.348 0.13 1.472 0.58 - 1.869 0.33 0.302 1.00 - 2.014 0.25 0.589 0.98 - 1.109 0.80 0.991 0.86 - 0.880 0.90 1.119 0.80 - 4.016 <0.001** 1.828 0.36 - 0.107 1.00 0.224 1.00 - 2.486 0.09 1.481 0.57 - 2.733 0.047* 1.370 0.65

- BMR - 3.209 0.01* 1.305 0.69 - 2.298 0.14 0.591 0.98 - 3.837 0.001** 3.795 0.001** - 4.996 <0.001** 3.045 0.02* - 1.975 0.27 0.285 1.00 - 1.210 0.74 0.746 0.94 - 5.702 <0.001** 4.093 < 0.001** - 0.667 0.96 1.118 0.80 - 2.048 0.24 2.910 0.03* - 1.985 0.27 1.650 0.46

63

E E K K

||- P ||- P ||- P

0.676 0.96 0.354 1.00 1.807 0.372.799 0.04* 1.086 0.81 0.645 0.971.809 0.36 2.658 0.06 4.444 <0.001**1.244 0.72 1.978 0.27 2.854 0.03

2.348 0.13 0.516 0.99 0.631 0.972.572 0.07 1.308 0.68 2.452 0.100.942 0.88 1.572 0.51 3.8 0.001*0.988 0.86 1.128 0.79 2.105 0.220.435 0.99 1.027 0.84 1.993 0.272.524 0.08 0.14 1.00 1.385 0.64

0.642 0.97 2.373 0.12 1.045 0.832.903 0.03* 1.657 0.45 4.446 <0.001**0.195 1.00 2.187 0.18 4.397 <0.001**2.867 0.03* 2.176 0.18 1.578 0.511.288 0.69 1.387 0.63 0.452 0.99

3.998 <0.001** 0.915 0.89 3.401 0.006**2.633 0.06 0.530 0.98 0.048 1.003.219 0.01* 0.415 0.99 3.391 0.006**3.654 0.002** 2.840 0.04* 0.996 0.860.326 1.00 1.548 0.53 1.633 0.47

0.653 0.96 1.4920 0.56 0.625 0.970.078 1.00 2.2420 0.16 3.608 0.003**1.255 0.71 3.8760 < 0.001** 6.368 <0.001**

3.007 0.02* 3.5380 0.003** 3.252 0.01*1.264 0.71 0.3230 1.00 0.832 0.920.560 0.98 0.4780 0.99 4.232 <0.001**1.158 0.77 1.6350 0.47 2.760 0.045*1.564 0.51 1.0230 0.84 3.964 <0.001**1.967 0.28 2.9300 0.03* 2.136 0.201.674 0.44 1.6150 0.48 0.124 1.00

64

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Appendix 3.1 (continued)

B T

C V

||- P ||- P

- 0.642 0.97 0.492 0.99 - 2.903 0.03* 2.55 0.08 - 0.195 1.00 1.872 0.33 - 2.867 0.03* 0.758 0.94 - 1.288 0.69 2.375 0.12 - 3.998 <0.001** 3.644 0.002** - 2.633 0.06 0.745 0.94 - 3.219 0.01* 1.142 0.78 - 3.654 0.002** 1.431 0.60 - 0.326 1.00 1.473 0.58

Appendix 3.1 – Statistics of pair-wise post hoc tests between life cycle stages (A)

per subspecies and hybrid line and (B) per treatment group. The effect of the in-

teraction life cycle stage*treatment was not significant for body mass and mass-

specific BMR in European stonechats kept at different temperature treatments.

Therefore we did not perform post-hoc tests on these measures for birds kept at

fluctuating temperature.

66

CHAPTER IV

G�� !��of annual variation in constitutive immunity:

a common garden study with stonechats from different environments

-��#��!�� 9� � ��8��,�0��"�� ')�� 9��

Abstract9� ��$��)��(� ��7�$��/��(� �� (�� "��$��$ �� $� �-�� =�� $�"��"� �� "�� function, a physiological trait important in life history evolution, is ��(��(�� 7�� )�� "� �� "�� demands and environmental factors. We tested the hypothesis that constitutive immunity is adapted to environmental seasonality, re-sulting in different genetically encoded annual cycles in different en-vironments. We studied these annual cycles in continental long-dis-tance migrant Kazakh, temperate short-distance migrant European �� $�� "�� $��)��" ��lines, using a common garden set-up. Additionally, we investigated $��"$��%�&� ��"� �� "�� $� �� regimes. We measured annual cycles of hemagglutination, hemoly-��$�� "��Escherichia coli and Staphylococcus aureus�� $�� &��$��$�� 8" �� )� ��)�"�� $� �� $��$� �� "��%��"��"�� -

67

ity against E. coli. We conclude that annual cycles in constitutive im-��"��(�� #� �� "��)��-ple mendelian rules, and that some immune measures are relatively ��)�� %�&� ��

IntroductionIn seasonal environments ecological factors such as temperature, ��(�� "��$��$ �� "�(� �� 5��-lay 1988, Lovegrove 2003, Altizer et al. 2006). The physiology (Klaas-sen 1995, Romero 20021�� (�� 58�� 2009) and life history � ��5�� ,�(��2007��' �� 20101�� =�� (� �� "�� (� �� "� ��(�� !�-�� .� $�"��"� �� (�� $��"$��"�%�&� �� =�� (� �� can result from a genetic organisation (Piersma and Drent 2003, MacDougall-Shackleton and Hahn 2007). An important physiologi-cal system that relates to self-maintenance and survival, and that connects these life history traits with environmental factors is the ��"��5�� 1996, Ricklefs and Wikelski 20021��"��"� ��"�� "�� -es (Schmid-Hempel 2003, Klasing 2004), and having a high immune �� (� � �� "��"�� $�� -�� "��"�� )��(� "��5��-?�� al. 2003, Martin et al. 2004, Owen and Moore 2006, Buehler et al. 2008c, Pap et al. 2010�� -��7<��2010). This variation ��"$��0�� 7��)��"�� "��5�� 1996, Nordling et al. 1998��,�� 2000, Moreno-Rueda 2010), ��"� �� %�� "� ��"� �� (� �� $��$ �� (�� "��$� �� 5,�� 2000��,=��2002, Martin 2005, Altizer et al. 2006, Marais et al. 20111��,��#��)�� &-tent to which annual variation in immunity stems from phenotypic plasticity or is genetically engrained. Yet, if annual variation in im-munity plays a role in the evolution of life history traits in different environments, one might expect that it has a genetic component.If immunity is traded-off against other resource demanding life cy-��(��5�� 1996, Nordling et al. 1998,

68

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ual cycles of im

mu

nity in

su

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ech

ats

,�� 2000, Moreno-Rueda 2010), seasonal (� �� "� �� &$�� (�� "� ��"� (� �� (� �� -��"� �� (� �� (� �� 9� �� (�� distance and large annual reproductive output, characteristics �"$��"��)��$� �� "��(��)� #�� $� �� :� ��(��a small annual reproductive output, characteristics typically asso-�� )�� $�� !�� 7�� demanding seasons such as migration or reproduction, immune ��"� �� $ �� 5�� 1997, Nord-ling et al. 1998, Nelson et al. 2002, Martin et al. 2004, Owen and Moore 2008, Machado-Filho et al. 2010). If immunity is primarily �� "��(� �� (�� "��-$� �� $��$ �� 5,=�� 2002, Maizels and A�0�� #��2003, Marais et al. 2011), predictions for seasonal $�� "� �� +�� &$�� &��$�� "�� $� �� "� � �� $�� $��(� �� -ent pathogen communities, compared with residents that stay in the same environment year-round (Møller and Erritzøe 1998). Thus far, most studies linking environment, life history and immunity ��(��(�� "��(� ��-ment (e.g. Bonneaud et al. 2003, Ilmonen et al. 2003, Tieleman et al. 2005, Martin et al. 20071��)�� investigating variation in immunity in two or three seasons is in-creasing (e.g. Hasselquist et al. 1999, Møller et al. 2003, Martin et al. 2004, Owen and Moore 2006, Machado-Filho et al. 2010) few studies have included the perspective of the complete annual cycle (Buehler et al. 2008c, Pap et al. 2010�� 1��4��$� ��(� �-�� large variation exists among annual cycles of immunity.��(� ��"�� )��-ies, can result from the fact that different indices of immunity have ��5!��2004, Lee 2006). The immune system consists of a complex collection of interrelated and overlapping pathways that $ �� "�� (��;�� -��"�� (��(��$�-��5��78��$�� 2003, Janeway et al. 2004, Lee and

69

Klasing 2004). In our study of seasonal patterns, we decided to focus ��(�� $� ��-��"��$ �(��7�$��/��7�� "� ��/ ��of defense against general challenges (Janeway et al. 2004, Buehler et al. 2008c). We included different aspects of constitutive innate im-��"*�� "��)�� )�� $��-� �� 7�� $��of constitutive innate immunity (Tieleman et al. 2005, 2010, Mil-let et al. 20071D�� "��$��"�� cells (Matson et al. 20051��(��(�� $�� "�� 5+�� J��#� ��2000); and con-�� $�� $��$ �� $��%�� 5�� "�0"�#��1997��6 ��#� ��2010).Distinguishing phenotypic from genetic variation of a trait is typi-��"�� )��(� �� &��$�� "�#��$�� $��(��"��4�� (� �� )�� "�� and kept in a common environment, differences that one finds are ��#��"� �� (�� #� �� 5� �� 1922, Gwinner et al. 1995a). Stonechats are an ideal study species for such studies: They are widespread (Urquhart 2002), occur in environments that (� "�� "��$�� (� ��(Gwinner et al. 1995a, König and Gwinner 1995, Helm et al. 2009, Helm 20091�� "�#�$�� $��(��"��" �� )�� $�� "�� $�"��"�� $�� )��7�� $ ��)�� $��(��"� 5')��-ner et al. 1995a, König and Gwinner 1995, Klaassen 1995, Wikel-ski et al. 2003, Tieleman 2007, Helm et al. 2009, Tieleman et al. 2009a, Helm 2009). A study of immune indices of stonechats in a �� )�� $�� $ �-sent when they are kept in a common environment, suggesting a �� 56��$�� 1�We studied annual cycles in hemagglutination, hemolysis, hapto-�� "��Escherichia coli and Staphylo-coccus aureus of continental long-distance migrant Kazakh, temper-ate short-distance migrant European and tropical resident Kenyan �� " �� (� ��-

70

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ual cycles of im

mu

nity in

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ech

ats

ment. Because of the differences in seasonality of the environments of origin and associated life history traits, we expected that seasonal (� �� )�� 0�#�� -�� "�� $��"��(�� "��(�� #� ��)��&$��$��:� �(� �� "��"�� $��" ��)�(�� $� �� $��(��)�� $��"$��%�&-� ��"� �� 5��1� �� "�� "��)��#�$�� $��5� �$��1�� )�� -ent temperature regimes, one group at year-round constant tempera-�� "�(� �� $� ��

MethodsBirds and treatments

Stonechats (Saxicola torquata) originated from three different loca-��*��0�#��5�B24) (S. t. maura1�� $��5�B57) (S. t. rubicola), ��"�� 5�B15) (S. t. axillaris). Kazakh stonechats migrate over ��(�� )��"��"��)��(� ��/(�7��&�� $��are short-distance migrants that lay two to three clutches with on av-� ��/(��"�� "�� -ally one clutch with three eggs (Helm 2002). In addition to these �� $��)�� " �� )��0�#�� -$�� $��5�B201�� )�� $��"�� $�-��5�B211��9� ��)� �� / ��5�B331��5�B421�� 5�B22) � �� 5�B51�� 7 ��-�&��#�� + ��"�� !�� '� ��"�� #�� /��(�� 7 ��5�B35) (Gwinner et al. 1987). All individuals were fully grown, rang-ing in age from 0 to 12�"�� 5��B�1371�� (��)� ��0 to 4�"�� 5��B�124). Birds were housed with 8-12 individuals per room and individuals were kept in separate cages. They were housed randomly assigned to ��)�� $�� $�� consisted of year-round constant temperatures of 20-22°C and day length following natural day length of the European population. In �� )��#�$�� $�-

71

�� 5�B141�� (� �� $� �� -perature each week to mimic the average natural temperature cycle of free-living European stonechats (Figure ��A).

Measurements of immune indices4��;��/��/(�� (�� "�� /(��"�� )��<� �� "�2005 and March 2006: spring migration (24� <� �� "�E�30�-� ��1�� 510 May – 2 June), moult (1 August – 17 August), autumn migration (11�+�� 78 No-(�� 1��)�� 524��(�� E�18�<� �� "1�� -� ��$� �� (�� 58��2005), )��)�� "�� 7 ��4��/��)�� ;��$� �� $ �� )� �� $�� "��$�"��"�$ �$� �� -��(��"��$ �� $�� (Gwinner et al. 1995 ��8��2005). Birds were checked twice a week for moult.

Complement and natural antibodies�E�4�� )��-�� $��$� ��$�� and stored the plasma at -80C6�� "��4��;��/�� "��$��(��"��)��-��7��"��"�� "�-��52005) with modi-/�� "�-��#� �� 52005). We scored hemaggluti-��"�� )�� )� �� "��4��)��$� ��agglutination or lysis were given half scores. Scoring of all scans was �� "��$� ��5-!�1�

Haptoglobin�E�4�� $�� $��with a commercial kit following the manufacturer’s instructions (Tridelta Development Ltd., Maynooth, Ireland). The kit uses a col-� �� ;��"�� $�� 4��mixed plasma and reagents in a 96�%�� )��$�� 630 nm using a Molecular Devices Spectra Max 340 plate reader.

Bactericidal ability�E�4�� "�� )��"$�� $ �� 7��(��

72

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�� 5Escherichia coli1�� 7$��(�� 5Staphylococ-cus aureus) (Millet et al. 20071�� (�� "�� ;�� "��0��$��"�confounding effect of different antigen-exposure histories (Millet et al. 2007). In addition, they represent different response path-ways of the immune system: E. coli� �� #�� $�-��"� "�$��$�� $��cascade, whereas S. aureus��#�� "� "�$��"��5-��et al. 20071�� $��)� �� #��)�� -�� )�� !��"�� )� �� $� �� )��)�� $�� )-ing Tieleman et al. (2005, 2010) and Millet et al. (20071�� we reconstituted lyophilized pellets of E. coli (Epower Microorgan-isms, ATCC #8739, MicroBioLogics, St. Cloud, MN, USA) and S. aureus (Epower Microorganisms, ATCC #6538 MicroBioLogics, St. Cloud, MN, USA) following manufacturer’s instructions. Every ��"�)��#�� $�� #��)�� )� #�� "�� 200 microorgan-isms per 70�F��7 ��7�� &�� $�� 5�� )1�� #� ��)� #�� )� �� #�$�� at all times. For the E. coli assay, we diluted 30� F�� )�� in 270�F��6+

27��$��5'� ��7��(�� 6� ��

CA, USA) with 4mM L-glutamate. The assay was started when 30 F��E. coli�)� #��)�� 7�� &�� )�� 7.5 minutes. For S. aureus we mixed 75� F�� )��225F�� 30F�� S. aureus�)� #�� "�� 7S. aureus��&�� )�� 3 hours. We chose the incu- �� "��5�� $� �� 1�� !�� &�� )� �� 41°C and ��#��"� �� $��70�F�� "$��"�� $��(Fluka, St Louis, MO, USA), in duplicate. To determine the num- � �� 0� �� )��)�� )��(�� !�� $��)� �� 5E. coli) or two (S. aureus1��"�� "�� )� ��"�� 59�+�� $��1��(� "��)��)��#��)�� #��

73

Statistical analysisWe used R version 2.12.1 for statistical analyses (R development core team 20101�� )� �� "�� 5�� (7Smirnov D < 0.07, P > 0.08), and we used mixed effects models for �� "�� $�� "�against E. coli and S. aureus. We investigated whether the annual cy-�� $��5��" ��1�� $�� $��:� �(� �� "��4��/ ��-�"0��(� ��"�� $�� #�$�� )�� $�� "�� &�� "�� G�� $�� "��G��&�� $��G��&��4��(� ��-$��5��1��#��5�� "1��4��"0�� $��$� �� $��-chats with models including treatment, life cycle stage, sex, age and �� "�� G� �� "�� G��&� �� G��&�� 9�� )�� (�� multiple life cycle stages, we included individual as random effect in �� "��G�� $�� "��G� ��)��/��)��/��"-�� $�� $��$� ��"��"-��)��/��$� ��"��)�� ;��"��$��7��$� ��$��(� �� "��"�� $�� $��4��/ ��$� ��"��0�#�� $��"�� $�-cies. To further investigate genetic components of annual cycles, we ��$� ��" ��5��0�#��&�� $�� $��&��"��1�)�� $� �� $��<��"��)��$� ��"�� $��#�$��(� �� $� �-ture treatment.

ResultsGenetic differences in annual cycles of subspecies and hybrid lines

!��"��"�� -ity against E. coli and S. aureus �� /��"��$��)��(� �� "�� $��" ��#�$�� (� �� 5�� $��G�� "�� *� �2 > 26.83,

74

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H- a Ha

.. �2 P �2 P

AL * 16 30.48 0.02* 36.89 0.002**

S* 4 2.78 0.60 6.37 0.17

L * 4 5.21 0.27 8.47 0.08

S 4 - - - -

L 4 - - - -

S 1 0.27 0.60 0.02 0.90

A 1 10.35 0.001** 18.43 <0.001**

B

L * 4 3.80 0.43 12.20 0.02*

T* 1 0.11 0.74 0.34 0.56

L * 4 5.21 0.27 5.51 0.24

T 1 0.21 0.65 - -

L 4 7.12 0.13 - -

S 1 2.87 0.09 0.13 0.72

A 1 0.85 0.36 13.71 <0.001**

a Included as covariate in the model is the time between entering the room

and completion of sampling.b Included as covariates in the model is age of the microbicidal stock solution.

75

HaB

E. colia,b

B

S. aureusa,b

�2 P �2 P �2 P

14.29 0.58 59.96 <0.001** 26.83 0.04*6.94 0.14 5.08 0.28 7.87 0.101.51 0.82 3.35 0.50 6.69 0.15

3.91 0.42 - - - -8.70 0.07 - - - -2.79 0.10 2.03 0.15 0.38 0.541.50 0.22 9.60 0.002** 1.78 0.18

4.51 0.34 9.60 0.048* 4.42 0.350.13 0.72 0.28 0.60 1.56 0.214.92 0.30 3.58 0.47 5.86 0.210.72 0.40 - - 0.08 0.779.86 0.04* - - 34.89 <0.001**0.72 0.40 0.56 0.46 1.39 0.240.10 0.75 7.94 0.005** 2.50 0.11

Table 4.1 – Statistics and P-values of life cycle stage, sex, age, the interaction life cycle stage*sex

and (A) the interaction subspecies*life cycle stage, subspecies*sex and main effect subspecies,

and (B) the interaction treatment*life cycle stage, treatment*sex and main effect treatment in

analyses on hemagglutination titers, hemolysis titers, haptoglobin (mg/ml) and bactericidal ability

(% cells killed) against E. coli and S. aureus. When the interaction terms subspecies*life cycle or

treatment*life cycle stage are significant, significance of the main effects subspecies or treatment

group and life cycle stage is not meaningful and is not shown. Results are from mixed effects mod-

els after backward elimination of non significant terms (P>0.05).

76

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��B�16, P < 0.043D�� ; Figure ��). Annual cycles in hapto-�� /��"�� $��" ��5�� $��G��"��*��2�B�14.29��B�16��B�0.58D�� ; Figure ��61��!��(��/��"��-�� "��E. coli�5� ��A). Older � �� "�� "��E. coli.

Comparing subspeciesHemagglutination –� 6��$� �� $�� "��of hemagglutination differed among Kazakh, European and Ken-"�� 5� ��A, Figure ��A, Appendix ��A). Kazakh ��)�� -ing autumn migration, European and Kenyan stonechats showed no ��/�� "�� $�� "�� the other seasons (Appendix ��A). Also, during spring migration, Europeans seem to have a lower hemagglutination than the other two �� $��

Hemolysis –�!�� "�� "��)� �� $� � �� $��0�#�� $�� "�� 5� ��A, Figure ��B, Appendix ��A). Kazakh and European stonechats had a low lysis during spring and autumn mi-gration. The decrease is more pronounced in Kazakh than European stonechats. Kenyan stonechats showed less annual variation, with ��$�� "�� /��"�� 5!$$��&��A).

Haptoglobin� E� !�� "�� $�� /-��"� �� $�� "� �� /�� -�� $��G��"��5� ��A, Figure ��C). The large �� $��"�� &��$��"�� "��(��)� ��

Bactericidal ability against E. coli�E�!��"�� "�against E. coli�� /��"��0�#�� $��"�� 5� ��A, Figure ��D; Appendix ��A). Ka-0�#�� )�� )� ��

3

4

5

6

7

hem

aggl

utin

atio

ntit

er

A

1

2

3

4

5

hem

olys

istit

er

B

0.0

0.2

0.3

0.4

0.5

hapt

oglo

bin

conc

entr

atio

n (m

g/m

l)

C

0

25

50

75

100

E.co

lice

lls k

illed

(%) D

−100

−50

0

50

100

W

S.au

reus

cells

kill

ed (%

) E

life cycle stage

KazakhEuropeanKenyan

0.1

AMBS

77

Figure 4.1 – Annual variation of (A) hemagglutination, (B) hemolysis, (C) hapto-

globin concentration, (D) bactericidal ability against E. coli and (E) S. aureus of Ka-

zakh (black circles), European (grey diamonds) and Kenyan (white triangles) stone-

chats. Stonechats were kept at constant temperature and annually variable day

length. Dots represent means ± standard error. Letters represent life cycle stages;

S = spring migration, B = breeding season, M = moult, A = autumn migration and

W = winter.

78

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high during the rest of the year (Appendix ��A). European stone-��)�� "��E. coli during spring mi-� �� "�� )� �� Kazakh stonechats the rest of the year (Appendix ��A). The resident ��"�� )�� "��"�� 7 �� (�� )�� $�� )�� (Appendix ��!1��"��)��$ �� )�(�� $� �� )�� $��

Bactericidal ability against S. aureus – !��"�� -ity against S. aureus showed large variation among life cycle stages in �� $��$�� 0�#�� $��"��5� ��, Figure ��E; Appendix ��A). Kazakh �� "� ��#��S. aureus �� period and a low score during autumn migration (Appendix ��A). The annual patterns of European and Kenyan stonechats had simi-lar shapes, with peaks during moult and lowest values during spring and autumn migration (Appendix ��!1��"�� Europeans have a slightly higher value than Kenyan stonechats.

Comparing hybrids with parent lines4��$� �� "��" �� )�� $��-tive parent lines, we found that hemagglutination, hemolysis and �� "��E. coli and S. aureus��" �� $� �� $��5� ��; Figure ��; Appendix ��A). ��" ��)�� -��(��$� �� $�� $� �� )� �� $� ��5<�� ; Appendix ��A).

�� Housing European stonechat under different temperature regimes affected two of the immune indices. The annual cycles of hemaggluti-��$�� "��S. aureus did not �� $�� )��#�$�� (� �� $� �� "� �� /�� G��"��5� ��B; Figure ��B, D and F). How-�(� ��"��"�� "��E. coli�)� ��/��"�� )�� $��5� ��

3

4

5

6

7

hem

aggl

utin

atio

ntit

er

A

1

2

3

4

5

hem

olys

istit

er

B

0.0

0.1

0.2

0.3

0.4

0.5

hapt

oglo

bin

conc

entr

atio

n (m

g/m

l)

C

0

25

50

75

100

E.co

lice

lls k

illed

(%) D

−100

−50

0

50

100

W

S.au

reus

cells

kill

ed (%

) E

life cycle stage

KazakhKaz x EurEuropean

F

G

H

I

J EuropeanEur x KenKenyan

AMBS WAMBS

life cycle stage

79

Figure 4.2 – Annual variation of hemagglutination, hemolysis, haptoglobin con-

centration, bactericidal ability against E. coli and S. aureus of Kazakh (white circles),

European (white diamonds) and Kazakh x European (black triangles) stonechats

(A-E), and of European (white diamonds), Kenyan (white triangles) and European

x Kenyan (black circles) stonechats (F-J). Stonechats were kept at constant tem-

perature and annually variable day length. Dots represent means ± standard error.

Letters represent life cycle stages; S = spring migration, B = breeding season, M =

moult, A = autumn migration and W = winter.

80

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��B, Figure ��C and E; Appendix ��B). Hemolysis of stonechats #�$��(� �� $� �� )�� "�� "�� #�$��$� �� )��decrease during spring and autumn migration (Figure ��C, Appen-dix ��91��9�� "��E. coli showed an increase from �$ �� #�$��(� �� $� �� #�$��(� �� $� �� maintained this high level during the other life cycle stages, while ��#�$��$� �� -ity against E. coli during autumn migration. As a result, spring mi-� ��/��"�� -chats kept at constant temperature (Figure ��E, Appendix ��B)

Discussion4��)� �� $�� )�� "-cle stage demands and originating from environments that differ in seasonality maintained different annual cycles in hemagglutination, ��"�� "��E. coli and S. aureus, when �� #�$��(� ��)��" �� )�� $��$��"��"��"�that differed from parental stonechats. Some of these annual cycles ��" ��)� �� $� ��5��"��0�#��&�� $��1�� $� �� 5�� "��E. coli in Kazakh x European and European stonechats) and sometimes they were dissimilar to ei-�� $� �� $��5�� $��&�Kenyan stonechats). Keeping stonechats at two temperature regimes, ��(� �� "�� %�� $�� (� �� "� �� "�� $�� "��S. aureus. However, he-molysis showed less variation throughout the year in stonechats kept ��(� �� $� �� #�$��$� �� 9�� "��E. coli was lower during autumn migra-��#�$��$� �� (� �� $� -�� /��)��(� ��"�� $��"$��%�&� ��-��"�� (� ��$� ��$��$ �� some immune indices.

10

20

Mar May Jul Sep Nov Jantem

pera

ture

(ºC

) A

3

4

5

6

7

hem

aggl

utin

atio

ntit

er

B

1

2

3

4

5

hem

olys

istit

er

C

0.00.1

0.20.30.40.5

hapt

oglo

bin

conc

entr

atio

n (m

g/m

l)

D

0

25

50

75

100

E.co

lice

lls k

illed

(%) E

−100

−50

0

50

100

W

S.au

reus

cells

kill

ed (%

) F

life cycle stage

VariableConstant

AMBS

81

Figure 4.3 – (A) Annual variation in temperature in standard and variable tem-

perature treatment groups. The dotted line represents the temperature birds were

exposed to, the solid lines the measurement periods. (B) Hemagglutination, (C)

hemolysis, (D) haptoglobin and bactericidal ability against (E) E. coli and (F) S. au-

reus of European stonechats kept at standard (white diamonds) and variable (black

circles) temperature treatments and measured during five life cycle stages. Dots

represent means ± standard error. Letters represent life cycle stages; S=spring mi-

gration, B=breeding season, M=moult, A=autumn migration and W=winter.

82

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Continental long-distance migrant Kazakh stonechats show larger (� �� "� �� "�� "�� S. aureus� �� $�� "�� "� ��environment, life history traits and physiology may underlie the �� "��$� �� 0�� "� �� -ing seasons and Kazakh stonechats generally produce large clutches �� "�� )� ��59��4��#� �2001, Helm et al. 20091�� (�� $ �$�� 7�� "� 5�L � �� 1998, Bonneaud et al. 2003, Martin 2005, Moreno-Rueda 2010, Pap et al. 20111��-� ��(� �� 0�#�� )�� &$�� $��(� �� (� ��$��$�-sitions (Møller and Erritzøe 1998), and this may lead to changes in ��"��'��"� ��=��-dices of Kazakh stonechats may take place in anticipation of variation ��"��$��$ �� (�� "�� $�� (�� not migrate (Dittami and Gwinner 1985, Helm 2009). The pathogen $ �� &$��$��"��(� �� (� �� "� �&$�-rience only one environment. However, tropical environments have �� "$��0�� $�� 5-?�� 1998, Guernier et al. 2004, Martin 2005). If pathogen pressure experi-�� "��"�� "�� 7 ��"��(�� (� �� "�� !�� (��"$�� $��(� �� $ �� 5�� -stein et al. 2008, Helm 20091�� %�&-� ��"�� "��(��(��(��%�&� ��"��=�� $�"��"��$��-ing on current environmental conditions. As a result, in a relatively �� $��(��(� ��)��(�� $��(��"��"� �� (��"�� $��$ �� #��)�� )��$�$��test these scenarios in the future.8��"�� "��E. coli )� �� )�� $� ��)��migration in long-distance migrant Kazakh and short-distance mi-grant European stonechats. Spring migration shows similar dips in � �$�� 0�#��"�� +�� (��

83

reported changes in immunity during migration periods. Changes in organ sizes occur due to migration, also in organs related to immunity (Møller and Erritzøe 1998, Bauchinger et al. 2005, Bauchinger and 9�� 20061�� %"�� 5Elaenia chiriquensis) het-� �$�� )��"�$��"�� $� �� 5-��7<�� 2010). In two species of migratory thrushes (Catharus ustulatus and C. fusces-cens1�� )�� -�� (�� $� ��$� �� 5+)��-�� 2006). These changes during migration in different indices in our study and the literature suggest shifts in immunity during these periods are a general phenomenon. However, when we consider all life cycle stages and restrict comparisons with other studies to the constitutive innate immune indices that we used, we encounter different patterns of annual variation in some species. A long distance migratory wader, the red knot (Calidris canutus), held in captivity, showed no variation in hemagglutination; hemolysis was ��)� �� "� �� )�� D� �� "��E. coli was high during migra-�� )�� 59�� 2008c). In free-living temperate house sparrows (Passer domesticus), �� )�� (� �� -��)�� )�� )�� D�� &��"�� "�)� �� $� ��)�� )�� 5��$��2010a). We found that �� "��S. aureus increased in European and es-pecially Kenyan stonechats during moult. Few studies investigated ��(��"�� -ity against S. aureus�� *��$� �)�� $��-tern was found (Pap et al. 2010�1�� $��(�� #�� "�)��)�� 59�� 2008c). Therefore, we �� (� ��$��&�� "�� $� � �� (�� "�� $��7�$��/��&��$��/�� /��-munity versus other life cycle stage demands, and from the character-istics of the environments that different species occupy. !��"��(��" �� $� �� $�� )� �� )�"�� $�� "�� (�� #� ��

84

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heredity of the indices does not follow simple mendelian rules. The immune system consists of many components, each having their own �� /��5��)�"��2004). The immune indices that we �� 0�� "�� "�� :� �� $�� $��7�$��/��)��#��them particularly useful for comparative ecological studies (Tiele-man et al. 2005, Millet et al. 2007, Lee et al. 20081��-�� -says are functional measures that integrate many components, which $ �(��&��)�)�� #�� 5��et al. 2005, Millet et al. 2007). The hemagglutination-hemolysis as-��"�� "��$��(��"��)��(��(��"�$ ��5+�� J��#� ��2000, Janeway et al. 2004, Matson et al. 2005). The integrated nature of these im-mune measures may also cause complexity of inheritance and may �&$��(� ��$�� )��" ��$� ��-�� $��Temperature treatment did have an effect on the annual cycles of ��"�� "��E. coli, and not on those �� $�� "� ��S. aureus�� )�� "�� "�� "��E. coli in two temperature treatments is ��)�� (��#�$��(� �� $� �� showed less variation in these indices than stonechats kept at con-stant temperature. Moreover, hemolysis was most dissimilar during �� )�� $� �� )��(� "�� -tween the two treatment groups. Our results suggest that in stone-�� (�� "� ��%�� "�� $� �� #�$��(�� "�� $��(� �� "�� -(� ��%�&� ��"��"��"�� $��to temperature was not found in the only previous study that looked at this: Buehler et al. (2008�1� �$� ��"�� "� ��E. coli �� )�� #�� #�$�� (� �� $� �� )�that annual cycles of some immune indices (i.e. hemagglutination �� "� ��S. aureus) are rigid in stonechats, )�� 5�� "�� "� ��E. coli) � �� %�&� ��

85

AcknowledgementsWe thank the animal care takers and technical staff of the Max Planck Institute for Ornithology, especially Lisa Trost, Willi Jensen and Er-ich Koch. Sophie Jaquier, Elsemiek Croese and Johan Leenders were a great help with collecting and analyzing samples. We would like to ��#�-� �� $�� 9�� )�� /��"� ��$$� �� "� �� +�� /�� 5�4+7��863.04.023).

86

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ech

ats

B E. coli

S-B

0.820.92

4.71

<0.001**

5.02

<0.001**

4.28

<0.001**

2.120.20

B-M

0.231.0

00.22

1.00

0.111.0

01.49

0.561.71

0.42M

-A

4.48

<0.001**

1.340.66

1.800.37

1.850.34

0.800.93

A

-W

5.09<0.001**

1.450.59

1.620.48

2.490.09

3.860.001**

W-S

1.990.27

4.84<0.001**

5.21<0.001**

5.95<0.001**

4.01<0.001**

S-M

1.170.76

4.97<0.001**

4.73<0.001**

2.710.05

0.490.99

B-A

3.32

0.008**0.96

0.871.73

0.410.58

0.980.95

0.87M

-W

0.490.99

0.091.0

00.46

0.994.20

<0.001**

4.31<0.0

01**S-A

3.120.02*

3.380.0

06**

2.360.12

4.15<0.0

01**1.17

0.77B -W

0.69

0.96

0.151.0

0

0.361.0

0

3.070.0177 *

2.84

0.03*

B S. aureusS-B

2.820.04*

1.24

0.73

2.220.17

0.28

1.00

0.16

1.00B-M

2.88

0.03*1.43

0.600.78

0.943.27

0.009**

2.530.08

M-A

3.470.0

05**

2.560.08

2.450.10

2.460.10

3.230.01 *

A

-W

2.500.09

0.540.98

0.470.99

1.810.36

0.321.0

0W

-S2.24

0.161.75

0.400.51

0.990.67

0.960.66

0.96S-M

0.60

0.970.29

1.00

2.960.03*

2.810.04*

1.910.31

B-A

5.73

<0.001**

0.830.92

1.750.40

0.430.99

0.900.90

M-W

1.18

0.762.18

0.182.30

0.144.52

<0.001**

3.270.0

09**S-A

4.36<0.0

01**2.04

0.240.09

1.000.55

0.980.85

0.91B -W

4.31

<0.001**

0.45

0.99

1.530.53

1.34

0.65

0.670.96

87

AK

K E

E

E K

K

||-P

||-P

||-P

||-P

||-P

H

S-B0.40

0.99

1.090.81

2.25

0.15

1.410.61

0.31

1.00

B-M

0.650.97

0.790.93

1.480.57

1.260.71

1.010.85

M-A

2.780.04*

3.97<0.0

01**0.91

0.892.03

0.250.98

0.86A

-W

3.62

0.003**3.68

0.002**

0.670.96

2.800.04*

0.251.0

0W

-S0.32

1.00

1.480.57

0.241.0

03.19

0.01*0.14

1.00S-M

0.39

0.992.18

0.180.59

0.982.54

0.081.33

0.67B-A

3.190.01*

2.780.04*

2.230.16

0.810.92

0.021.0

0M

-W

0.171.0

01.15

0.770.43

0.990.29

1.00

1.410.62

S-A

3.65

0.002**2.11

0.210.49

0.990.64

0.970.33

1.00

B -W

0.620.97

0.081.0

02.15

0.191.81

0.360.23

1.00

H

S-B

1.380.63

0.410.99

2.400.11

0.710.95

0.191.0

0B-M

0.30

1.00

0.101.0

00.52

0.990.35

1.00

0.171.0

0M

-A

5.95

<0.001**

3.120.02*

3.360.0

07**0.96

0.871.63

0.47A

-W

7.56

<0.001**3.90

<0.001**3.80

0.001**

2.380.12

1.820.36

W-S

2.150.19

0.840.91

3.95< 0.001**

2.240.16

0.131.0

0S-M

1.27

0.700.59

0.983.0

00.02*

1.010.85

0.021.00

B-A

5.51

<0.001**

2.710.051

2.820.04*

0.640.97

1.820.36

M-W

0.40

1.00

0.071.0

00.15

1.00

1.180.76

0.141.0

0S-A

5.51<0.0

01**2.81

0.04*0.99

0.850.12

1.00

1.670.45

B -W

0.021.0

0

0.181.0

0

0.450.99

1.63

0.47

0.331.0

0

Appendix 4.1

88

Ch

apter iv

| A

nn

ual cycles of im

mu

nity in

su

bspecies of ston

ech

ats

89

Appendix 4.1 – Statistics of pair-w

ise post hoc tests be-

tween life cycle stages (A

) per subspecies and hybrid line

and (B) per treatment group. In the com

parison among

subspecies the interaction term subspecies*life cycle stage

was not significant in haptoglobin and results are not

shown. In the com

parison between treatm

ent groups the

interaction life cycle stage*treatment w

as significant in he-

molysis and bactericidal ability against E. coli, and w

e only

performed a post-hoc test on these indices.

BT

C

V

||-P

||-P

H

S-B2.40

0.11

0.640.97

B-M

0.520.99

0.470.99

M-A

3.360.007**

2.130.20

A

-W

3.800.001**

0.400.99

W-S

3.95< 0.001**

0.710.95

S-M

3.000.02*

1.130.79

B-A

2.82

0.04*1.54

0.53M

-W

0.151.00

2.420.11

S-A

0.99

0.850.93

0.88B -W

0.45

0.99

1.580.50

B E. coli

S-B5.02

<0.001**

2.890.03*

B-M

0.111.00

1.910.31

M-A

1.790.37

0.400.99

A

-W

1.620.48

0.530.98

W-S

5.21<0.001**

5.05<0.001**

S-M

4.73<0.001**

4.79<0.001**

B-A

1.73

0.411.43

0.61M

-W

0.460.99

0.131.00

S-A

2.36

0.124.52

<0.001**B -W

0.36

1.00

1.950.29

Appendix 4.1 (continued)

90

CHAPTER V

Genetic modulation of energy metabolism in birds through mitochondrial function

9�� -��#��!�� !��"�< ��9� � ��8��

8��,��'� ��$��9��4��

Proceedings of the Royal Society B. 276: 1685-1693 (2009)

AbstractDespite their central importance for the evolution of physiological variation, the genetic mechanisms that determine energy expendi-ture in animals have largely remained unstudied. We used quan-��(�� / �� 7�$��/�� )��7� -�� 59-�1�)� �� $��(�7 ��population of Stonechats (Saxicola torquata �$$�1�� from three wild populations (Europe, Africa, Asia) that differed in BMR. This argues that BMR is at least partially under genetic con-� �� "��$��#��)�� )�� $��"$��4�� 9-�� 7�� $�� " �� )�� -cestral populations with high and low BMR (Europe-Africa, Asia-� �$�1��)�� $� ��/�� 5��

high – male

low

or femalelow

– malehigh

1�)�� $�$��8"- ��)�� $� ��/�� (��(� ��&�� !�� !� �� "��-��7�$��/��9-�� -�)��" ��)�� $� ��/�� $�"��

91

�� !��- �� /��$�� $� �� "�� )�� "�genetic differences in the mitochondrial genome, these results set the stage for further investigations of a genetic control mechanism ��(��(�� - �� )��7� ��(��

IntroductionThe genetic mechanisms that determine energy expenditure in ani-mals are largely unknown, despite the central importance of meta- �� (�� "�� "�� $� �� $��5,��"��,"��1979, Sadows-ka et al. 2005, Rønning et al. 20071�� 59-�1�� $��and in the thermal neutral zone (King 1974), whereas others do not (Dohm et al. 2001, Nespolo et al. 2003, Nespolo et al. 2005), and only few demonstrate a direct response to selection on BMR (Ksiazek et al. 2004). These results imply that at least some within-species vari-��9-�� "�� -�� "��)��7� ��9-��7�$��/��BMR in three populations of Stonechats (Saxicola torquata spp.) showed that these traits can evolve independently (Tieleman et al. 2009 1�� $�� "�� %�-�� "��$�� 9-�� "� �&"�� $�� $ �� summed mitochondrial oxygen consumption, mitochondrial func-�� $ �(�� $� �� #� ��)�� $ �� )��7� �� $��-ed set of candidate genes to impart genetic control. After accounting �� "��0��(� ��9-�� 0�� "��"��(�� 5��1990, Konarze-wski and Diamond 19951�� "�5��8�� 19851�� :� �� $�� $ ��$� �� "�58�� 20051��8�)�(� ��/ ��

92

Ch

apter v

| M

odu

lation

of en

ergy m

etabolism

in

birds

organ size accounted for variation in BMR (Tieleman et al. 2003a, Russell and Chappell 20071�� (� ��$�� was associated with BMR (Brookes et al. 1997, Brzek et al. 2007), ��(��)��$�� )��-lular processes and whole-organism energy expenditure. -�� 90% of respired oxygen during the production of ATP, the molecule that powers such processes as pro-tein synthesis, ion gradients, and actinomyosin ATPase (Rolfe and Brown 1997, Nichols and Ferguson 2002). The myriad of chemical reactions that supply electrons to the electron transport system in �� $ �� "$ �� -moregulation in endotherms (Rolfe and Brown 1997, Nichols and Ferguson 2002). Within mitochondria, the electron transport system �� $ �� $��&�� 5��$��&� �� 1� �� -quentially transport electrons and create a proton-motive force which drives ATP synthesis. The electron transport system contains 13�� -�� "�� 70 nuclear encoded peptides that are imported into the mitochondria �� )�� "�� to produce functional complexes (Blier et al. 2001, Ballard and Rand 2005, Das 2006). Proteins containing mitochondrial DNA-encoded polypeptides play crucial roles in the regulation of mitochondrial res-$� ��$��&��$ ��!��$��&��5��(�"��6�� #�1996, Bai et al. 2000). -�� "� �� !� �� "� ��used as neutral marker in phylogeographic studies (Zink and Bar-rowclough 20081�� $$� �� idea that climatic conditions can provide a selective ecological gra-dient that alter mitochondria haplotype, potentially changing mito-chondria function and heat production (Matsuura et al. 1993, Mish-mar et al. 2003, Ruiz-pesini et al. 2004, Ballard and Whitlock 2004, Ballard and Rand 2005, Zink 20051�� 5�� 2004). Further, Fontanillas et al. (20051��)�� $� ��)��-tochondrial haplotype and maximal nonshivering thermogenesis in white-toothed shrews from a lowland and an upland population, sug-gesting selection on mitochondria in these two populations.We exploited differences in inheritance of mitochondrial and nuclear �� %�� $��(�7 �� $�$��

93

(Saxicola torquata� �$$�1� �� )��$�$��)�� 5�� *�Asia, Europe, Africa (Klaassen 1995, Wikelski et al. 2003, Tieleman 200711��)��/ ��$$��;��(��"��(�� 9-�� 7� �� -� �$�$�� (� �� are compared with previous analyses for each of the three ancestral populations separately (Tieleman et al. 2009 1��4�� "$�� %�� 9-��)�� "$��" �� $��7!� ��!��7� �$�� -��)�� $ ��$� �� /�� $�

female – Africa

male

versus Africa

female – Europe

male and Asia

female – Europe

male versus

Eu-

ropefemale

– Asiamale

��!�$ �� )��(�� $�� *�(11�� )��" ��)�� -�� $� �� /�� " �� -�� )�� (��)�� $ ��"� � �� !7�� $ �� 52��-clear control”-hypothesis). (21�-�� )��" ��)�� $� ��/�� .�� $�� !7encoded components of the electron transport system in determin-�� 52-�� 37�"$��1��531�-�� )�� " �� )�� $� �� /�� -�� .�� $ �(��(�� $� �� )�� 52-�� 7�� coadaptation”-hypothesis, (Rand et al. 2004)). Next, we added quan-titative genetics analyses to explore maternal and paternal effects on �� <��"��)��$� ��;�� $ �� )�� $��!� ��$�$��/ ��$ ��7�� in the mitochondrial genome.

MethodsBirds and housing

�� $�� )��)�� $�� in Europe, Africa and Asia, ranging from 71°N to 35°S (Urquhart 20021��4�� $�$�� -

94

Ch

apter v

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lation

of en

ergy m

etabolism

in

birds

�� $�� $�� 5!�� S. t. rubicola), Africa (Kenya, S. t. axillaris) and Asia (Kazakhstan, S. t. maura1�� $��7!� �� " �� $��7!��" ��$�"�� $��$�$��-�� $��(�� 5�20081��!�� $��"��$� ��-�� "�$ �� " ��)�� $��(��"��Our study design provided us with two independent tests of the ef-��$� ��/�� )��7�$��/��9-��" ��<� � �� $��7!� �� )��-ured 80 individuals of four different genotypic pairings including 45 pure Europeans, 14 pure Africans, 11��" ��)�� $��-ers, and 10��" ��)��!� �� <� ��"�� $��and Asians, we measured 29 individuals in addition to the 45 pure Europeans: 15 pure Asians, 5��" ��)�� $�� 9 �" ��)��!�� 9�� )�� (� ��in age from 8 months to 8 years, we incorporated age as a factor in the analyses. Individuals were kept in separate cages, in rooms with controlled temperature (20-22°61��"��&$� �� "��- �$�� )�� ;�� 540°N). We measured each indi-vidual one to three times during winter (total 131 measurements), in the periods 9-13�<� �� "�2005 or 24��(�� 2005 - 13�<� �� "�2006�� $� �� )� �� )�� "� �� (� �/�� "� �� nighttime activity (Helm et al. 2005).

Metabolic ratesLaboratory setup and metabolic measurements� E� +�� the start of experiments we removed water and food from cages, to �� )� ��$�� $��(�� 5��$� �� 1��4��$�� 13.57,�� )�� &�� 7�� $� ��)� ��$�� $��(� ��"� ��$� ��/��4�� )��$� �� 35°C ± 0.5°C, a temperature within the thermoneutral zone of Euro-pean stonechats (Tieleman 2007). 4�� %�)7�� $� �� "� �� +

2-con-

sumption of stonechats (Gessaman 1987). Compressed air was pumped through columns of silica gel-soda lime-silica gel to remove

95

water and CO2�� 5,�("�19641��7%�)��

(model 5850��9 ��#��8��/��!��!1� �� 500 ml/min, and �� !� � �� &�� $�� 7�� 7�� &"��"0� �5+&0�� "��,��!1� �� -tion of oxygen of the air stream. A stream of dry CO

2-free air was

used as reference air. We recorded atmospheric pressure, air temper-�� +

2 with a data logger

(model CR23M��6��$ ��/��,��!1��!�� )� ��$�� - � �� )�� +

27��

minutes, we calculated the lowest running average over ten minutes of data for BMR (Tieleman 2007). To calculate BMR from O

2-con-

sumption we used equation (2) from Hill (1972) using a conversion factor of 20.1 J/ml O

2 (Schmidt-Nielsen 1997). Birds were weighed

��"� �� (� ��weights are used in analyses.

Statistical analysis of metabolic rates – We analyzed data for BMR � �� $��7!� ��" �� $��7!��" ��$� ��"��<� ��)��(�� $��5$� �� $��" ��)�� $�� " ��)��!� ��5� �Asian) mothers, and pure Africans (or Asians)) and tested differences in BMR among groups. We used a mixed model with individual en-tered as random effect to incorporate multiple measurements on one third of the individuals (using MLwiN 2.021��!��&�� "��)� �� /&�� )�� #)� �� 7��/��/&��5��N�0.05) as our selection procedure (Crawley 19931��4��)�7)�"�� $� ��7��/�� !�� /�� "� �� models (all P > 0.29); we therefore omitted age from the models.

Calculation and interpretation of mass-specific BMR – We calculated ��7�$��/��9-��)��7� ��9-��(�� "� ��"��4�� $ ��(��$ �� $ �� (� �� (� �� 7�$��/�� rate (Speakman 2005, Tieleman et al. 20061��4�� "�composition and mitochondrial density are the same in the different � ��$��" �� $ �� 7�$�-

96

Ch

apter v

| M

odu

lation

of en

ergy m

etabolism

in

birds

��/��9-�� 4��/��#��"��$� ��/�� " ��)�� "� ��$�� "�� $��0��)��(�� "��$�� "��8��$��

Quantitative genetics analysis with animal modelsPedigrees�E�4��7��(�� $��(��population over a 15-year period. For our quantitative genetics analy-ses, we assumed that wild-caught nestlings collected from different nests were not related to each other, and that nestlings collected from the same nest had the same genetic father and mother. In captivity, �� (�� $�� offspring the genetic father and mother were known. After hatch-��#��)� �� "�� 5 days and thereaf-ter hand-raised. We had a panmictic population of stonechats with #��)�� $�� -erations and among populations. The resulting pedigree included 50 African, 127 European and 53 Asian individuals, in addition to 21�� $��7!� ��" �� 14� � �$��7!��" �� )�� 0 (wild-caught) to 4, )�� 1 and 2. To indicate the �� (� ��)��$��(��$�$��)��-�� (�� )��$ ��/ ��generation of captive individuals: 20 African, 43 European and 18 Asian stonechats (Lynch and Walsh 1998).

Estimation of genetic parameters and statistical analysis – We estimat-��(� ��$�� )��restricted maximum likelihood ‘animal models’ (Falconer and Mac-kay 1996, Kruuk 2004) using the program ASReml 2.0 (Gilmour et al. 2006). We used these ‘animal models’ to partition the total $��"$��(� ��5�

P1�� (��(� ��5�

A)

�� (� ��5�R). The model included sex as fixed effect,

�� )��&��$��"$��animal as random effect, taking into account repeated measures. 8� �� "� 5h21� )��

A:�

P (Falconer and Mackay

19961��4�� (� ��(�� -sidual covariances, and correlations (r1��

A was significantly

97

larger than zero we compared the -2G��#��

A with one that did not. To test if estimates of r

A were

significantly different from zero (or from 1 or –1), we compared the -2G��#��)��

A fixed, and r

A either fixed at

zero (or 1 or -1) or unconstrained. The corresponding significance levels were taken from a �27�� )� ��$� �� additive genetic and residual variances across traits we calculated ��(��(� ��56�

A) and residual variance

56�R) following Houle (1992).

The maternal inheritance of mitochondria might lead to a maternal ��$ �� 52�� 3��"-pothesis). To estimate the maternal genetic effect, we constructed an animal model that included mother as additional random effect with �� (� ��7��(� �� &� �� "� �� -tive genetic relatedness matrix (Kruuk 2004). Likewise, we tested �� (� �� 5 "�/�� "� �� -dom effect), paternal genetic and environmental effects, and perma-nent environment effects (following Kruuk 2004). We calculated the �27�� )�� 72G��#�� )��)�� /��

Mitochondrial DNA sequencesGeneration of mtDNA sequences – DNA was isolated from muscle tis-sue from two African and two European individuals using a stand-� ��$��7�� $ �� 5�� #��1989). Sequences �� )� �� "� ��$��"�� roughly 500� $��$ �� "�-�� ;��!�� 5�� $*::$��$�� :�� -

en/primers.html1��$$��)��$ �� "�O. Haddrath and A.J. Baker. Both strands of each amplicon were se-quenced using a Big Dye (version 3.0) Cycle Sequencing Kit (Applied Biosystems). Cycle-sequenced products were cleaned using Sephadex columns and nucleotide sequences determined using an ABI 3100 Genetic Analyser.

Analyses of mitochondrial DNA – Because we were interested in dif-ferences among populations in mitochondrial proteins as functional components in the electron transport system, we focused on a com- �� "�� $ �� /(��

98

Ch

apter v

| M

odu

lation

of en

ergy m

etabolism

in

birds

�� $��&�� $� �� "�� 5��(�"� ��Clark 1996, Korzeniewski and Mazat 1996, Bai et al. 2000): Complex I (NADH 1-61��6��$��&��56"�� 1��6��$��&��56+�7��1��6��$��&�� 5!�6 and 8). We explored if the sequence differ-�� )�� $�� !� �� $�$�� $�� "� �� $�� 7��synonymous, variation. We present results for individual mitochon-drial genes in Appendix "��.

Finally we looked for evidence of selection leading to divergence in mi-tochondrial DNA among stonechat populations using McDonald-Kre-itman (MK) tests (McDonald and Kreitman 1991) to compare the ratio of amino acid replacement variation to synonymous variation within �$��)�� $�� "��"�� (� �� -�)��&�� "��)�� ;��)�� under different types of selection this ratio should differ from one. The direction and degree of departures from this neutral prediction were ;��/��)�� "� ��&��5��1996). As-suming that synonymous sites are evolving neutrally, NI < 1.0 indicates an excess of amino acid divergence, which is inferred to result from positive selection, whereas NI > 1.0 indicates an excess of amino acid polymorphism resulting from purifying selection.

ResultsHeritabilities and genetic correlations of body mass and metabolic rate

Estimates of h2� �� 7�$��/��9-��)��7� ��9-�� "��(� �� )��0.36 and 0.70, and all additive genetic var-��)� ��/��"� �� 0� ��5� ��"��). Furthermore, �� )� ��/��"�� 1 (or -1 for mass versus� ��7�$��/�� 9-�1�� (� �� (��(��$� ��"��$��"�� 5� ��"��).

�� in metabolic rate

-��7�$��/��9-��" ��)�� $� ��-/�� $��7!� �� !��7� �$�� $�� 5� �� "��; Figure "��). Further, �� / �� 7�$��/��9-��)��7� -

99

ATP

()V

A ()V

R ()h

2 ()

A

R

B ()

14.9 (2.29)3.277 (0.679) <0

.00

01

1.389 (0.253)0.702 (0.0

67)12.1

7.9

BMR (J

-1)22.2 (2.23)

1.857 (0.818) 0.0

033.345 (0.599)

0.357 (0.130)6.1

8.2

M- BM

R (-1

-1)1.51 (0.215)

0.035 (0.0077) <0

.00

01

0.015 (0.0029)

0.694 (0.073)12.4

8.2

Table 5.1– Q

uantitative genetics parameters for body m

ass, whole-organism

basal metabolic rate (BM

R) and

mass-specific BM

R in stonechats (combined from

Europe, Africa, and A

sia, including hybrids). A. Estim

ates of ad-

ditive genetic variance (VA ), residual variance (V

R ), heritability (h2), coefficient of additive genetic variation (C

VA ),

and coefficient of residual variation (CV

R ). P-values (written as exponents) indicate one-tailed significance of dif-

ference from zero for estim

ates of VA . Sex w

as included as fixed factor for all traits (see Methods). B. Phenotypic

correlations (in italics) and additive genetic correlations (rA ). Above the diagonal, P-values denote tw

o-tailed signifi-

cance of differences from zero (P

0 ) for estimates of rA , and one-tailed significance from

1 (P1 ) or -1 (P

-1 ).

B

B ()

BMR (

-1)M

- BMR

(-1

-1)

B ()

–

0 = 0.20

1 < 0.00

01

0 < 0.00

01

-1 = 0.001

(J

-1)0.294 (0.084)

0.264 (0.195)–

0 = 0.12

1 < 0.0

001

M-

(J -1

-1)-0.703 (0.048)-0.826 (0.073)

0.443 (0.076)0.291 (0.205)

–

100

Ch

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| M

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lation

of en

ergy m

etabolism

in

birds

��9-�� "�� 5� �� "��; Figure "��). Analysis of the European-African data set (Figure "��!1� ��)�� 7�$��/��9-��)�� /��"� ��-�� "�� $�5�2�B�35.88��B�3, P < 0.00011�� "��&�5�2�B�8.76, �� B�1��B�0.003). Post-hoc analysis supported the mitochondria-nuclear coadaptation hypothesis and failed to support the mitochon-� �� "$��*��)��" �� $�� /��"�� $� ��lines (African × European vs African × African, �2�B�19.18��B�1, P < 0.0001; European × European vs European × African, �2�B�12.27, ��B�1��B�0.0005; European × African vs African × European, �2�B�5.96��B�1��B�0.015). The analysis of European and Asian stonechats duplicated the group-�� $��!� �� *�' ��$��-��/��"��7�$��/��9-�5�2�B�9.56��B�3��B�0.023), ��&��5�2�B�2.80��B�1��B�0.09; after deleting the interac-tion group × sex, �2�B�7.35��B�3��B�0.062). Post-hoc analysis re-(��/�� )�� " ��"$��5� �$��× Asian vs Asian × European, �2�B�4.15��B�1��B�0.04), and did not support a maternal effect that would indicate mitochondrial control (European × European vs European × Asian, �2�B�4.71��B�1��B�0.03; Asian × European vs Asian × Asian, �2�B�3.53��B�1��B�0.06).

No maternal and paternal effects on metabolic rate Maternal (or paternal) effects occur when the phenotype of the moth-er (father) affects the offspring phenotype in ways additional to the ��(�� "�� (� ��-tally determined, the latter for example through maternal invest-ments in eggs. We tested for a maternal genetic effect in analyses of the mitochondrial control hypothesis. Because visual inspection of results (Figure "��1��$�� $�� )��also to test the paternal genetic and environmental effect, maternal environmental effect, and permanent environment effect. None of ��)� ��/��5� ��"��).

Mitochondrial DNA sequences differ between European and African populations

Comparing the mitochondrial DNA of European and African stone-��)�� -

101

A

P ( ) B 1 (g) W-

2 ( d-1)M- ( d-1 g-1) n, N

A A 18.0 ± 2.44a 22.3 ± 1.83 1.26 ± 0.144 19, 14

A E 15.0 ± 1.39b 22.3 ± 1.33 1.50 ± 0.191 18, 10

E A 16.1 ± 2.89c 21.9 ± 2.24 1.38 ± 0.166 22, 11

E E 14.3 ± 1.73b 22.0 ± 2.34 1.55 ± 0.184 72, 45

1 Body mass was significantly affected by group (�2 = 38.95, d.f. = 3, P < 0.0001) and sex (�2 =

16.52, d.f. = 1, P < 0.0001). Identical letters written as exponents indicate non-significant differ-

ences between groups, with a post-hoc test.2 Whole-organism BMR: Without including body mass as covariate, whole-organism BMR was not

significantly affected by group (�2 = 0.34, d.f. = 3, P = 0.95) or sex (�2 = 2.59, d.f. = 1, P = 0.11).

When including body mass as covariate, the model included the interaction sex x body mass (�2

= 5.90, d.f. = 1, P = 0.015), body mass (�2 = 11.22, d.f. = 1, P = 0.0008), sex (�2 = 5.56, d.f. = 1, P =

0.018), and group (�2 = 9.37, d.f. = 3, P = 0.025).

B

P ( ) B 1 (g) W-

BMR2 (d-1)M- BMR ( d-1 g-1) n, N

E E 14.3 ± 1.73a 22.0 ± 2.34 1.55 ± 0.184 72, 45

E A 14.0 ± 1.30ab 24.6 ± 2.77 1.76 ± 0.093 5, 5

A E 14.2 ± 1.30ab 21.7 ± 1.54 1.55 ± 0.201 10, 9

A A 13.1 ± 1.39b 21.8 ± 2.98 1.67 ± 0.223 18, 15

1 Body mass was significantly affected by group (�2 = 13.71, d.f. = 3, P = 0.003) and sex (�2 = 19.45,

d.f. = 1, P < 0.0001). 2 Whole-organism BMR: Without including body mass as covariate, whole-organism BMR was not

significantly affected by group (�2 = 6.92, d.f. = 3, P = 0.07), but significantly differed between

sexes (�2 = 5.73, d.f. = 1, P = 0.0017). When including body mass, the model that remains after

eliminating nonsignificant effects of sex (�2 = 0.72, d.f. = 1, P = 0.40) and group (�2 = 7.30, d.f. =

3, P = 0.063), contains only mass (�2 = 14.46, d.f. = 1, P = 0.0001).

Table 5.2 – Body mass, whole-organism and mass-specific basal metabolic rate (BMR) for

four groups of stonechats with different parental configurations, originating from (A) the

African and European populations and (B) the European and Asian populations. Values are

average ± 1 SD for all measurements per group. Number of measurements = n, number of

individuals = N.

102

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�� $��&�)��(�� 4 �� 6��$��&��to 35�� 6��$��&��5� ��"��). Results from the M-K tests and values for the NI index indicate that overall purifying selection acts on amino acid-altering mutations in stonechat mitochondrial DNA although our small samle size limits the power of our analysis $� �� "�� -7��(��5� ��"�� and Appen-dix "��1��/�� )�� 5�1��:� �� 5�1�� 7 "7��(c.f. Appendix "��1��#�� )��7 ��- �� !��

Discussion8" �� $� ��/�� 5��-male

high – male

low versus female

low – male

high1��

��(� �/��)��$� ��)�� )�� $�$�� /�� $ �(�� (�� )�� !� �� !� ��;�� 8" ��)�� $� ��/�� (��(� ��&�� DNA, and differ only in the mitochondrial DNA that they inherited � �� /�� $�� $� �� "�� )�� 2�� 7�� $��3� �"-$��2�� 3��"$��)��a priori $ �� 2�� 3��"$��$ �� )��" ��)�� $ ��$� ��/�� (�� $$� �� )�� -�� "�� -ences in mitochondrial DNA sequences, these results set the stage for further investigations of the genetic control mechanism determining �� $�� )�� !�� $ �(��"� �� )�� )��7� ��(�� Studies on copepods (Tigriopus californicus), however, have shown �� $�$��" ��)�� nuclear genomes, have reduced mitochondrial function resulting

Eu x EuEu x Af

Af x EuAf x Af

mas

s-sp

ecifi

c BM

R (k

J/day

/g)

0.0

1.0

1.5

2.0* **

** * *

Eu x EuEu x As

As x EuAs x As

mas

s-sp

ecifi

c BM

R (k

J/day

/g)

0.0

1.0

1.0

2.0* * 0.06

a ab c

a ab b

103

Figure 5.1 – Mass-specific basal metabolic rate (BMR, kJ d-1 g-1) of stonechats with

different parental configurations, specified as mother x father. Origin is abbreviated

as Eu – Europe, Af – Africa, As – Asia. Bars are SE, for sample sizes see Table 5.2.

Identical letters indicate non-significant differences between groups, with a post-

hoc test. P-values for pairwise comparisons: *** = < 0.0001, * = < 0.05.

104

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ergy m

etabolism

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birds

from loss of activity of those complexes in the electron transport ��(��(�� 5��and Burton 2006). In these copepods, impaired mitochondrial func-��(��"��/�� "�� -(�(�� $��/��;�� (��" ��)�� /��)�� 5!(��1989, Hel- ��1994��20071�� $�� &$�� )��-chondrial and nuclear DNA varies and affects the functional or evo-�� "��/�� )�"��+� ��"�)��$� �� "��$�� "�� $��"�� " ��.�� rate to that of their father (Figure "��1�� &$�� "�alternative mechanisms. Whereas the animal model analyses do not support paternal and maternal genetic or environmental effects the sample size is modest and as a result the power of these tests limited. Alternative explanations fall into three main categories: control by sex-chromosomes, genomic imprinting, and non-genetic maternal or paternal effects. Control by sex-chromosomes�� &7�$��/�� )�� $�� )�� J7�� $�� 4J� �� 4��/�� #��"��&$�� &��/�� "�� $�� does not differ among sexes. In our stonechats the direction of the sex effect differs among populations, with females having a higher ��7�$��/��9-�� $��!� ��$�$��lower value in the Asian population, when compared with their male counterparts. Genomic imprinting (Wilkins and Haig 2003, Keverne 20071��$ ��)�� "�� $� ��-nates over its counterpart from the other parent, can occur on sets of �� $ �� set of Z-chromosomes in male offspring. Applying these mechanisms to the results in this paper, the paternally inherited genes involved �� (� � �� "� �� $� ��$�� (�� $ �� )��

105

M

LV

A (SE)V

E (SE)V

R (SE)�

2P

N

185.1990.0348 (0.0

077)-

0.0154 (0.0029)

--

M

185.1990.0348 (0.0

077)0.0

00

0 (0.00

00)

0.0154 (0.0029)

01

M

185.199

0.0348 (0.0077)

0.00

00 (0.0

00

0)0.0154 (0.0

029)0

1P

185.3730.0322 (0.0

089)0.0031 (0.0

061)

0.0154 (0.0029)

0.3480.56

P

185.2250.0340 (0.0

087)0.0

00

9 (0.0048)

0.0153 (0.0029)

0.0520.82

P

185.367

0.0296 (0.0117)0.0

044 (0.0081)

0.0149 (0.0029)

0.3360.56

Table 5.3 – Results of anim

al model analyses to test for m

aternal, paternal and

permanent environm

ent effects on mass-specific BM

R of a panmictic population

of stonechats, with individuals from

populations in Europe, Africa and A

sia and

crosses among these populations. Estim

ates of additive genetic variance (VA ),

variance of effect (VE ), residual variance (V

R ) are reported ± SE. Effects were test-

ed using the �2-distributed difference betw

een the -2*loglikelihood of a model

containing the effect with that of the sim

ple model w

ith no effects included.

106

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�(�� $�� $ �� rate. Finally, non-genetic maternal or paternal effects � �� $�� (� ��"��&$�� $��)�"�� &�� (�� #��)��at present. �� $� �� )�� !�� !�� " ��$$�� (�� !� �� =�� -lection (e.g. Zink 2005, Ballard and Rand 2005). Our results imply that a co-evolutionary response of mitochondrial and nuclear DNA is ��(��(��7�$��/�� 5��9�� al. 20011��)��$$� ��2�� $-��3��"$�� (�� -�� $��"$�� "�� 5��!�7production) and heat production (Matsuura et al. 1993, Mishmar et al. 2003, Ruiz-pesini et al. 2004, Ballard and Rand 2005, Zink 2005, Fontanillas et al. 20051�� 2�� $��3��"$�� (�� (� ��"� �� $�� -tutions in mitochondrial DNA have on heat production. Estimates of h2� �� )��7� �� 9-�� 7�$��/��BMR, and of r

A� ��)�� )��

�� 5� ��"��1�� 7��-�� $�$��(� �� "��" ��$�$�-lation separately (Tieleman et al. 2009 1�� $��"� ��)��$�$��(� �� "�� "�� 4�� 0�� /�� )��#�� )��)��7� ��9-��7�$��/��9-�� (��5� ��"��), especially in light of the �� "��/��9-��$��"$��(��However counter-intuitive these results might seem, the data indicate �� &�� %�� In conclusion, we have shown that whole-organism and mass-specif-�� !��$�� "��;��(��"�� #��"�� $�� " �� -ciprocal parental configurations demonstrate that mitochondrial-�� 7��$�� $� ��"� ��$�� mass-specific BMR.

107

AcknowledgmentsWe thank W. Jensen, E. Koch, L. Trost, the animal care takers, and other staff of the Max Planck Institute for Ornithology for technical support and animal care. We gratefully acknowledge D. Garant, A. '�� >�� (�� "-��0��+��8�� $�)�� )� #��9�� and T. Piersma for comments on a previous draft. This study was /��"��$$� �� "�� + �� /�� 9�� 5�4+�� 863.04.023) and funds � ��+��(� ��"��94�)��$$� �� "��<�� 9��0212587��)�� $$� �� "� �� + �� /�� 5�4+�� 863.05.002).

N. C

F S

P S

F NS

P NS NI P (MK)

C I 2121 266 18 35 6 2.53 0.099C III 380 35 38 4 11 2.53 0.161C IV 1001 103 6 4 1 4.29 0.275C V 282 41 5 5 0 0.00 1.000C 3784 445 67 48 18 2.49 0.005

Table 5.4 – Numbers of codons, synonymous (S) and nonsynonymous (NS) substitutions, Neutrality

Index (NI) values and P values for MK tests for genes which make up metabolic complexes of mitochon-

drial subunits. “Combined” refers to a data set consisting of all genes combined across all Complexes.

See Appendix 1 for results per individual gene. Poly = polymorphic substitutions within populations;

Fixed = fixed substitutions between populations.

108

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Appendix 5.1

N. S

F S

P S

F NS

P NS NI P

ATP6 681 35 4 4 0 0.00 1.000ATP8 165 6 1 1 0 0.00 1.000COI 1539 52 1 0 0 NA NACOII 681 26 0 2 1 0.00 0.103COIII 783 25 5 2 0 0.00 1.000CB 1140 35 38 4 11 2.53 0.161ND1 975 33 3 2 1 5.50 0.283ND2 1038 33 1 6 1 5.50 0.315ND3 348 21 0 2 2 21.00 0.020*ND4-1 1377 60 7 7 1 1.22 1.000ND4L 294 11 2 2 0 0.00 1.000ND5 1815 85 5 13 0 0.00 1.000ND6 516 23 0 3 1 0.00 0.148

Appendix 5.1 – Numbers of sites analyzed, synonymous (S) and nonsynonymous (NS)

substitutions, Neutrality Index (NI) values and P values for MK tests for individual mito-

chondrial genes. Poly = polymorphic substitutions within populations; Fixed = fixed substi-

tutions between populations.

110

CHAPTER VI

Repeatability and individual correlates of basal metabolic rate and total evaporative water loss in birds: a case study in European stonechats

-��#��!�� 9� � ��8�� Niels J. Dingemanse, B. Irene Tieleman

Comparative Biochemistry and Physiology A 150: 452-457 (2008)

Abstract 9�� 59-�1��(�$� ��(��)�� 54,1�� (��(��(��=��)�� "�� "��-ological traits can show large intraindividual variation at short and long timescales, yet natural selection can only act on a trait if it is a �� (�� $�� "� �� $� �� (� �� "� �� among individuals, indicates if it is a characteristic feature of an in-��(��4�� $�� "��9-��4,��18 cap-tive European stonechats (Saxicola torquata rubicola) within the )�� $�� "�)��0.56 for BMR and 0.60 for mass-�$��/��9-��!�� "��/��(� ��-tion in BMR. Also after accounting for this variation, BMR remained �$�� 4,��7�$��/��4,��)��/�� $�� 0.11 and 0.12, respectively. We conclude that BMR is a characteristic feature of an individual in our population of Euro-pean stonechats, whereas TEWL is not. We discuss our results in the ��&�� (��)�� "��(�� $�� "��9-��4,��

111

Introduction,�(�� "� �&$�� )�� (� "�)�� -vironment (Klaassen 1995, Tieleman et al. 2003 ��4�#��#�� 2003), season (Weathers and Sullivan 1993��4� �� 4�� 2000) and workload (Wiersma et al. 2005). These physiological traits � ��(��(��(��=��)�� "�� /�� 0�� (�(�� #��)�� 5'� ��1988, Godfray et al. 1991). Several studies suggest that the variation in energy expenditure and water loss among species ��$�$�� )��5��1995, Tieleman et al. 2003 ��4�#��#��20031��8�)�(� ��#��)�� for physiological variation among individuals within populations of )�� $�� (��-��$�"�� $� �� /��59� ��et al. 2001�� 2006). Physiological traits can show large $��"$��%�&� ��"�)��(�� 5��"�� )��#�1��long (months or years) timescales (Piersma et al. 1996, McKechnie et al. 2007). Yet, selection of traits can only have evolutionary conse-quences if the traits are characteristic features of an individual that, in addition, display interindividual variation within the population.A common measure for the extent to which a trait is a characteristic �� (�� $�� "��&$ ��)��$ �$� ��of the overall phenotypic variation, the sum of inter- and intraindi-(��(� �� "�� (��(� ��5,��Boag 19871�� (��$��"$��(� �� $� ��into environmental variation, arising from external circumstances that affect the animal permanently, and genetic variation (Falconer and Mackay 19961�� $�� "� �� "� �� $$� �� "�59��#��1989, Falconer and Mackay 1996, Dohm 20021�� 7�� (��(� ��"�(� "� ��)��$�$��-�� (� �� :� � �� 8�� $�� "�� "�� $�$�� 9�� 59-�1��(�$� ��(��)�� 54,1�are widely used as measures of energy expenditure and water loss �� 7�� $�� (� ��or at different times of the year. BMR is defined as the minimum �� "� �&$�� $�� $��(�� the rest phase and at thermoneutral temperatures (King 1974). It is related to overall daily energy expenditure in the field (Nagy 1987,

112

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epeatability of bm

r an

d tew

lDaan et al. 19901��(��"�5�� 1998, Nudds and Bry-ant 20011��(�� "��5-�� 2001, -�� 20031�� $� ��"��&$�� "�� 0�� "��$��5��1990, Piersma et al. 1996, Tieleman et al. 2003�1��6��$� ��(��)�� (�$�-rative water loss (TEWL), the sum of cutaneous and respiratory wa-ter loss, as yardstick (Dawson 1982, Williams 1996, Tieleman et al. 2003�1��)�� "� �� =�� (��$ ��-�� "��&$�� $��"�� &$� �� $� �� "�� #��)�� or during migration�� $�� "��9-��59��1999, Hõrak et al. 2002, Tieleman et al. 2003 ��>0��4��2005a, Rønning et al. 2005) and especially TEWL (Tieleman et al. 2003�1� �� !� ��7��"�� $�� "�� -ed 6 estimates for avian BMR (Nespolo and Franco 2007). The study �� $�� "� �� 0�� &�� )� �� -� ��%�� $��< ��52007) ��)��$�� $� �� "��52003a), that ��)�� $�� "��9-�� "� "��>0��4��(20051��<� �� $�� "��$�$�� $ ��-ence and magnitude can differ among populations. Compiling all �(�� $�� "�� 9-�� )��values ranged from 0.00 to 0.87 and 22K�� $�� )� ��7��/��6��$��(�� $�� "�� 4,�� )��(�� 0.00 to 0.73 and 60K�� $�� )� ��7��/��5� ��#��). This vari-�� $�� "��$��$�$�� &�� )��9-��TEWL are characteristic features of an individual, and hence for the $�� "�� 4�� $�� "��(��(� ��9-��4,�in captive European stonechats (Saxicola torquata rubicola) during the )�� 9�� $�� "��$�� (��(� ��-tion as well as intraindividual variation, we explored factors that poten-��"��%��$��*��&�� "�� 4��(� ��9-��4,�)��single season to determine whether these traits are characteristic fea-

113

P

C

V

BMR

S18

0.560.0

02BM

R7.7

This studyS

180.60

<0.001

msBM

R8.4

This studyZ

18-200.41-0.52

<0.001

mcBM

R4.5-6.3

Rønning et al., 2005

Z 19-37

0.29-0.63<0.0

01m

cBMR

6.6-13.5Vézina and W

illiams, 20

05K

8-190.35-0.52

0.01-0.03m

cBMR

11.4-14.4Bech et al., 1999

G

280.65-0.87

<0.01m

sBMR

Horak et al., 20

02S

14-0.17

0.79BM

R18.2*

Tieleman et al., 20

03aW

14

0.170.29

BMR

23.0*Tielem

an et al., 2003a

S- 20

0.660.0

01BM

R16.7*

Tieleman et al., 20

03aD

’ 16

0.480.03

BMR

9.0*Tielem

an et al., 2003a

H

140.57

0.02BM

R8.0*

Tieleman et al., 20

03a

TEWL

S18

0.110.53

TEWL

9.6This study

S18

0.120.51

msTEW

L10.8

This studyS

140.73

<0.001

TEWL

26.8*Tielem

an et al., 2003a

W

140.22

0.09TEW

L28.0*

Tieleman et al., 20

03aS-

10-0.04

0.56TEW

L19.1*

Tieleman et al., 20

03aD

’ 16

0.500.03

TEWL

33.9*Tielem

an et al., 2003a

H

14-0.10

0.64TEW

L19.7*

Tieleman et al., 20

03a

* Coefficients of variation are based on m

ass-adjusted values of BMR and TEW

L. Mass-adjusted values w

ere calculated as the residual of the regression

of BMR on body m

ass. Two values for repeatability represent m

ultiple measurem

ents for repeatability. Some studies distinguish betw

een sex, others

report repeatability measurem

ents on short and long time scales. A

ll measurem

ents were done on non-breeding individuals except Bech et al. (1999).

Table 6.1 – Literature overview

of repeatability (r) and interindividual coefficients of variation (CV

) of whole-organism

, mass-adjusted (m

cBMR)

and mass-specific (m

sBMR) values of BM

R and whole organism

and mass -specific TEW

L (msTEW

L) of birds.

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epeatability of bm

r an

d tew

ltures of a given individual at a given time of the year. This knowledge �� )�� $ ��$�� (�� "��-derlying physiological differences among environments and seasons.

MethodsBirds

�� $�� )�� )�� $�� (latitudinal range 71°N to 35°S) (Urquhart 2002), are ideal organ-isms to study evolutionary questions related to seasonality and en-vironment (Gwinner and Scheuerlein 1999, Helm et al. 2005). We measured BMR and TEWL of 18 stonechats from a central Euro-$��$�$��)��(�� (��)� ��/ �� 5��B�61�� 5��B�21�� 5��B�41�� -�&��#��for Ornithology, Andechs, Germany, and six were taken as nestlings � ��/��(��7 ��5')�� 1987). Their ages were 1�5��B�7), 2�5��B�6), 3�5��B�1), 4�5��B�3), and 5 (n B�1) years. Individuals were kept in separate cages, in rooms with con-trolled temperature (20-22°C) and under wintering day length (48°N 11C1�� Free living European stonechats normally migrate in March and Oc-�� $��)�� -�� 4�� $��(��(��)��5�B141�� 5�B4) times during the winter $� �� )��7�� 2005 and 13�<� �� "�2006. Average �� )�� ;��24.7 days (range 12-41 days). Winter is a quiescent period for stonechats (Helm and Gwinner 19991*�� )� �� -chats are nocturnal migrants, and show nighttime activity during the migratory periods even when kept in captivity. To verify that we ��"�� ;��$� ��)�� activity with a passive infrared sensor.

Laboratory setup and measurements!�� )�� &$� ��)�� (��)�-�� $�"�� (�� 4��(�� into 13.5� �� )��&�� 7�� )��temperature of 35°C ± 0.5°C, within the thermoneutral zone of Euro-pean stonechats (Tieleman 20071��

115

)� ��$�� )��$��(� ��"� ��$� ��/��&��water evaporating from feces from the measurements. 4�� %�)7�� $� �� "�� +2-consumption and H2O-production of stonechats (Gessaman 1987). Compressed air from a tank was pumped through the system, caus-��$��(��$ �� !� �$�� 7�� 7�� /�� (�� )�� 6+2 and �� ;��"�� 7%�)�� 5��5850E, 9 ��#�� 8��/�� !�� !1� �� 500 ml/min. Before experiments �� )�� "7$�� through a dewpoint hygrometer (model M4-DP, General Eastern, Fair-/��6��!1�� )$�� "�� -;��"�� )�� The outgoing air passed through the dewpoint hygrometer to measure ��)�� ;��"�6+2 and H2O were removed using sil-��7�� 7��/�� +2-content of the air was meas-� ��)��&"��"0� �5+&0�� "��,��USA). A reference stream of dry air without CO2��)�� "7$�� )��"��&"��"0� ��4�� $�� $ �� $� �� $� �� "� �� )$�� O27�� )��$�� )��-ger (model CR23M��6��$ ��/��,��!1��All BMR and TEWL measurements were done during night. We only �� )� ��$�� "� )�� +2-consumption and ��)$�� 9-��from O2-consumption we used equation (2) from Hill (1972) using a conversion factor of 20.1 kJ/ml O2 (Schmidt-Nielsen 1997). TEWL was calculated following Tieleman et al. (20021��4��)�� "� �� the average of these two measurements for further analysis.

Statistical analysis and repeatability calculationWe performed multilevel random effects analyses in MLwiN 2.02, with 2 levels: level 2 was individual and level 1 was measurement. 4��/&�� &��5)�� $��(�1�� "��9��)��$ �� &$��/�� )��9-�� 4,��

116

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epeatability of bm

r an

d tew

l)�� "�� (� �� 4��/ �� $�� "� ��)��/&��4��-�� $�� "� �� /&��-��9��#)� ��7��/��/&��5��N�0.05) was used as model selection criterion. We used the likelihood-ratio test and �27��(��/��(� �� "�� )��(�� )��measurements on the same individual. Understanding the effects of ��"��(� ��9-��4,��)��-(�� ;�� $� ��(� �� "�� 7� �� (�� $��8��)��/ �� &$�� 7� �� (�� (� �� "�� $�� "�� "��$� ��4��(��)�� 7�� (��(� �� "��9-��4,��-�� "� "�$� �� "��(� �� "��(��5-O�(P1��(�� (� �� "��(��"�� 5-O��(P1�5�� 2006). Because nat-� ��"��7�$��/��9-��4,�5�$��#-man 2005, Tieleman et al. 20061��)��7�$��/��(��-�� "��(��9-��4,� "� ��"��$�� "� )�� )�� ;�� $�� "� B� 5��-terindividual variance)/(intraindividual variance + interindividual variance) (Lessells and Boag 19871��4�� 7� �� -traindividual variances from the multilevel models. Standard errors were calculated following Becker (19841�� $� ��(� �-ation in BMR with variation in TEWL, and with variation reported in the literature we calculated interindividual and intraindividual ��/�� (� �� 56�1� �� 6�� B� 5�� (��1:�� (��6��)�� "�/ ��(� ��(��per individual and then calculating standard deviation and mean of ��(��(� �� (��6��)�� "��-��(� ��(��6�.��)��)� �� "��#��standard deviations and means per individual. We compared the in-�� (��6�.��9-��4,��)��J� �51996) and the �� (��6�.��)��4��&��5��14). We repeated all statistical calculations using log-transformed values for BMR, TEWL �� "��9��$ �(��/�� 9-�� "�� 5 2B0.16 vs. r2B0.18) and TEWL �� "��5 2B0.07 vs. r2B0.05), we do not report the results.

117

ResultsBody mass

��$�� "� �� "�� )��0.23 ± 0.21, and not ��/�� 5�2

1B1.136�� B0.291�� 6�.�� 7� �� -

dividual level equaled 7.9 and 6.4, respectively. This indicates that �� 7� �� (�� (� �� "�� considered when evaluating variation in BMR and TEWL.

Basal metabolic rate4��7� ��9-�� /�� $�� "��0.56, indi-cating that intraindividual variation was relatively small compared )�� (��(� ��5� ��#��; Figure #��A). Inter- and in-� ��(��6�.��)� ��7.7 and 4.8, respectively.4��&$�� $��"��%��(� ��9-��the interindividual (age, sex, hatching location, M[av]) and intraindi-(��5-O��(P1��(��#��/�� $�� "��)��7� ��9-��+�� $��"�� (��(� ��)��7� ��-��9-��-O�(P��/��5<�� #��) while ��&��(��/��5<��#��; � ��#��!1��!�� (��(��-O��(P��/��-fect on variation in BMR (Figure #��D�� #��!1��/��)�� -O�(P� ��-O��(P�� $�� "� ��9-��)��0.47 ± 0.17 (�2

1B6.057��B0.013).

-��7�$��/��9-��5��9-��(�� "� ��"��1�� /-�� $�� "� ��0.60� 5� ��#��). Interindividual variation was ��/��"� �� "� �� 5�2

4B12.696�� B0.0131� �� "� ��&�

(�21B0.304��B0.58) and hatching location (�2

1B0.784��B0.38). When

�� )��7�$��/��9-�� $�� "��0.33 ± 0.19 (�2

1B2.676��B0.11).

Total evaporative water loss��$�� "��)��7� ��4,�)��0.11 ± 0.21, indicating that intraindividual variation is relatively large compared with inter-��(��(� ��5� ��#��; Figure #��B). Inter- and intraindivid-��6�.��)� ��9.6 and 11.3 respectively.�� &��(� �� "��(M[av]), which could affect interindividual variation in TEWL, and �� $�� "��/��5� ��#��B;

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epeatability of bm

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lFig 31��-O��(P��)��%�� (��(� �� $�� "�� /�� 5� ��#��B; Figure #��). 4��(��4,� "� ��"��7�$��/��4,��!�� &� �� /�� (age: �2

4B5.510�� B0.24, sex: �2

1B0.460�� B0.50, hatching location:

�21B2.310��B0.131�� $�� "��7�$��/��4,�)��0.12

± 0. 21�5� ��#��).

Difference in repeatability between BMR and TEWL��&$�� )�"� �$�� "�� 9-�� for TEWL, we compared the interindividual and intraindividual vari-��$�� )��9-��4,�� (��6��9-�� /��"� � �� (��6��4,�56��9-�B7.7��6��4,B9.6��JB0.662��B0.53). How-�(� �� (��6��9-��)��/��"��)� �� (��6��4,�56��9-�B4.8��6��4,B11.3, JB�73.027��B0.0021��8��)� �$�� "�� 4,�)��-� � �� (��"�� (��(� ��relatively low interindividual variation, compared with BMR.

Discussion��9-��)�� $�� (�� )�� "�� with hatching location and sex. In contrast, TEWL was poorly re-$�� (� "�)�� "�� &��9��"��)��$�� "� �$�� $�$�-lation as well, indicating that it varied more within than among in-dividuals. In the following section, we will compare our results with /�� %�� $�� "��-nisms, and discuss repercussions for the evolutionary potential of these physiological traits. +� �� $�� "�� 9-��)�� $ �(��"� �$� �� 8 out of 10 $�$��)��9-�� $�� 5� ��#��). The interindivid-��/��(� ��56�1��9-��)�� "�)��$� ��)�� $�$�� $ ��"�� )��$�$�� )�� $�� "��9-��)��7��/��

16 20 24 28

BMR(kJ/day)

A

0.8 1.2 1.6

2.0

TEWL(ml/day)

B

individual

119

V�

2..

P

AA

4.557

10.03

D

14.1051

<0.001H

0.803

10.37

A

12.7644

0.01S

0.300

10.58

BA

0.512

10.47

D

0.0731

0.79H

0.878

10.35

A

4.0944

0.39S

2.3421

0.17

�2-Values are based on a m

odel including all significant factors.

Table 6.2 – Values of �

2, degrees of freedom (d.f.) and P-values for factors

which possibly explained variation in (A

) BMR and (B) TEW

L.

Figure 6.1 – Variation in m

easurements of (A

.) whole-organism

BMR

and (B) whole-organism

TEWL per individual. Sym

bols with error

bars represent means ± S.E. G

rey symbols depict separate m

easure-

ments on the sam

e individual. Individuals are listed in random order.

120

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l�� (��6��)��$�$�� "� �� (� �� (�� (� ��)�� (��)�� $�� "��4,�)��also within the range of reported values, resulting in 2 out of 6 avian $�$��)��4,�� $�� -(��6��4,��&�� 9-��8�� (��(� ��4,�)�� $�� )�� $�� "��$�� "�� 7��(��(� ��5�� (�1��8�� (��(� �� "�high, the power for detecting individual consistency is low, unless in-terindividual variation is very high as in some species of larks shown �� #�� (��6��4,�)��lowest reported so far, and the study has consequently low power for concluding that TEWL is inconsistent within individuals. Body mass ��)�� )� ��7��/�� $�� "�� $��(�� $��)�� "��"��"-�� 5$� �� (��1�� (�� "��)�� &$� �� (�� (� �� 9-�� )�� $� ��&$�� "��)�� 4,�)�� /��"� �� "�this factor (Figure #��). Older stonechats had a higher BMR. This result is in contrast with the only three other studies that investigated �� )��9-�� )��)�� )��9-�� 59��#�� 2005, Moe et al. 2007) and one found a decrease with age (Broggi et al. 2007). �� )��-�� (� ��58� $� �1998, Even et al. 2001, Speakman et al. 2002, 20041��!�� )�� -�� 7 �� "��$��(��"�� (�� "�� (��)�� -$��"�� $�� $�$��7 ��(�� )��)�� Body mass did not correlate with TEWL at the inter- or intraindivid-ual level in our stonechat population; yet, it did correlate with BMR. ��(� �� "��9-��)��(��"� ��-� � �� "��$��$��"��0�� )�� (��"�� (�� #��"�and liver (Kersten and Piersma 1987, Daan et al. 1990, Piersma et

16

20

24

28 A

1.0

1.2

1.4

1.6 B

age

0 1 2 3 4

TEW

L (m

l/day

)BM

R (k

J/day

)%

varia

nce

1.0

BMR TEWL

Explained by age and

body mass

Explained by body mass

0.8

0.6

0.4

0.2

0.0

121

Figure 6.2 – (A) BMR and (B) TEWL in relation to age. Triangles represent average BMR and

average TEWL of individuals.

Figure 6.3 – Partitioned variances of BMR and TEWL and the factors that significantly ex-

plained part of the variances. White is the variance among individuals, grey is the variance

within individuals. 39% of the within-individual variance and 14% of the among-individual

variance was explained by body mass, and 50% of the among individual variance of BMR was

explained by age.

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lal. 19961��8�)�(� ��)�� )��&��(additional) changes at the tissue level, such as mitochondrial density and function, to explain variation in BMR.<� �� (� �� -��(�� (��(��-�� #� ��5<�� -��#�"�19961��!��/ ��)��of these criteria are met for BMR in most avian populations studied, including the stonechats of this study, and for TEWL in a third of ��(��$�$��&��5� ��#��). The next step in understanding the potential for selection in these $�"�� "�� "��)�� 58�"��1998, Johnson 2000, Nespolo et al. 2003, Ksiazek et al. 20041��"�� $��5�?��et al. 20071��!�� 9-�� &� �$�� 5��?��al. 2005), we can conclude that an evolutionary interpretation of the mechanisms underlying variation in BMR, for example among sea-sons and populations, is appropriate. TEWL is as yet a less studied � �� $�� "�� $�$��(� �� $��)�� (��-ary understanding of this trait.

AcknowledgementsWe thank the technical staff, especially W. Jensen and E. Koch, and the animal care takers of the Max Planck institute of Ornithology. E. Croese was a great help with the planning of all the measurements. 4��#��$�� $$�"�� 7��"��"�)��$$� �� "��7� �� + �� /��-search to B.I.T.

124

CHAPTER VII

O��$��approaches help unravel the complexity of the

immune system in an ecological context

�� -��9�� -��#��!�� , Kevin D. Matson, B. Irene Tieleman

� �� ;��"��)� #��

PLoS ONE 6: e18592 (2011)

AbstractThe immune system is a complex collection of interrelated and over-��$$��$ � ��)��-plexity, researchers have devised multiple ways to measure immune ��"0�� )�"� �� -�� $��"��"�� (��$��&�$ � -lem. One challenge facing ecological immunologists is the question ��)��"�� "��-sized to facilitate meaningful interpretations and conclusions. We ��#�� "� ��$��"�� $� �� (� �� -��)��)��$�� )��$��aspects of immune function are related at different organizational levels. We analyzed three distinct datasets that characterized 1) spe-cies, 21� �� $�� 3) among- and within-individual level dif-ferences in the relationships among multiple immune indices. Spe-��/��"�� )�� $ ��$�� $�� "�� 56�6!1�and two simpler approaches, pair-wise correlations and correlation circles. We also provide a simple example of how these techniques

125

�� "0�� $�� +� �/��lead to several general conclusions. First, relationships among indi-�� "� �� 0�-�� $��5��(� ��"��1� �� 5��$��1D�� "��$��"� �;�� -fore further analyses. Second, simple statistical techniques used in ��=��)�� $��&��(� ��(�� $�� $��&�statistics alone. Moreover, these simpler approaches have potential �� "0�� $� � �� $�� $��"� ��/��"��(��)� �� -logical standardization.

IntroductionBackground: One problem, many solutions

The immune system is a complex collection of interrelated and �(� ��$$�� $ � �� (� �� immune system these solutions include relatively general and con-��"�� 5�� (� �� 1� �� #��"�� $ ��5��(��-�"1�� $��(� ��#�� (-iours (induced innate immunity), and more specific and induced ��$��$ �� "�97��5��acquired immunity; (Murphy et al. 2008)). Organisms employ these multiple mechanisms to prevent and limit the effects of disease. Im-��$��&��"��)�(� ��$ ��$ � �� -ers interested in studying immune function in an ecological con-��&�� (� �� "�captured using a single measure (Adamo 2004, Martin et al. 2006, Matson et al. 2006a, Lee 2006). Furthermore, incongruence is of-�� )�� (��)��study. For example, in house sparrows (Passer domesticus) phyto-��5�8!1��)��)� ��)��$��(��"�� - ��)�� (�(��)��$�� $� �� cell challenge (SRBC) are negatively correlated with survival (Gon-zalez et al. 1999, and see Buehler et al. 2010 for a review of other �&��$��1�� $�� 7�� )��the immune system (see examples in (Lee 2006)). Over the past few

126

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"�� (�� $�� -��$��&��"� "��(��$��$��methods to measure immune function and to analyze the resulting �� "��$$�"��$��$��&�$ � ��$$ �� &��$ �� 0��"�� function and providing appropriate statistical tools to analyse these data have proven difficult. To understand how ecological immunology achieved its current sta-tus, it is useful to review why ecologists study immunology and what led them to devise multiple ways to measure immune function. First, ecologists are interested in understanding natural variation in im-��(��(� �� 7 ��/��$� -spective within an ecological and evolutionary context (Sheldon and �� 19961�� "�� -sional, ecologists often want or need to quantify multiple aspects of immune function to fully answer a research question. Furthermore, for practical and philosophical reasons, ecologists are interested in )��5��"1�� &�� (� �� )��(� "��$��"�� -ured separately (Matson et al. 2006a). Third, ecologists are interest-ed in whether relationships among aspects of immune function are ��)�� 0� �� 0��levels (e.g. from one individual, species, time point or environment to another). Some researchers suggest that selection or constraint may result in consistently correlated axes of immune defence (sensu Piersma 1997, Ricklefs and Wikelski 2002), while others suggest that %�&� ��"��"� ��$� ��$��/��"$��$�� $�� in different circumstances (Lee 2006, Buehler et al. 2010). In this paper, we explore the usefulness of several statistical approaches for �� $�� (��$$ ��$�� )��$��$�� -lated among different organizational levels.The field of ecological immunology needs analytical tools that can simultaneously summarize variation in multiple measures of im-mune function. Few studies have empirically examined relation-��$�� "��"�� 7�� -

127

logical knowledge from humans, domesticated animals and other model systems (reviewed in Lee 2006, Clark 2008, Murphy et al. 2008, Buehler et al. 2010) or rooted in life history hypotheses (e.g. Ricklefs and Wikelski 2002). When undertaken, multivariate stud-ies in ecological immunology often apply different statistical ap-proaches and include different immune indices. For example, sim-$�� (�� &�� $�� aspects of immune function (Mendes et al. 2006, Sparkman and Palacios 2009) and among measures of immune function and an-tioxidants (Hõrak et al. 2006, 2007). Principle component analysis 5�6!�� %�� "�� (��1�� to examine relationships among immune indices within an axis of immune function (e.g. constitutive immunity Matson et al. 2006a, Buehler et al. 2008 �� 2008c, 2009) and among multiple axes of immune function (Martin et al. 2007). Thus, the field of ecologi-cal immunology lacks a statistical protocol for analysing and sum-marizing variation in multiple measures of immune function. This ��"�� $� �� "� �� ;�� $��(�� (��"� �� &��$��)�� $��morphological traits (e.g. Ackermann and Cheverud 2000, McCoy et al. 2006) and when relating multiple genotypic and phenotypic (� �� 5��8��2009).��$�)� ��;��$�� "0��$�� $$��-tion of multivariate tools. For example, PCA and structural equation modelling (SEM, Tomarken and Waller 20051�� &��-ine how immune indices are correlated within a single group, and common principal components analysis (CPCA, Flury 1988, Phillips and Arnold 19991�� &��)�� in the same way among multiple groups. However, in order to employ these methods across multiple studies, the same aspects of immune �� <� �� 6!�� -�� )�� 5�� 1��$�� $��5��$��1�� $��among immune indices are the same in the different groups. To our #��)��-�� "�� &�� immunology, and although ecological immunologists have used PCA; the next step – using CPCA to test whether immune indices �� )�"�� $��E��"�� #��4��

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explore the usefulness of CPCA in this paper, and we illustrate the value of statistically simpler methods, such as pair-wise correlations, as complements to complex multivariate techniques. Although we do ��-��)��$�$� �)�� $�� (��/�� )� ��

Principal component analysis (PCA) and its assumptions� ��$��$��"�� (�� -�� (� �� 0��(� ��(Quinn and Keough 2002��! �� 4��20101��6!�� "�(� �� )� �� (��(� �� 5$ ��$��$�� 6�1�� )�� "��6!�� "��(� �� )��(� �� (�� 6!� �� 0��data taken from multiple measures of immune function and to ex-amine how the PCs vary over the annual cycle (Buehler et al. 2008c), ��)��(�� 5-��2006a, Buehler et al. 2008c, 2009), and among species (Matson et al. 2006a, Martin et al. 2007). However, determining relationships among indices at these different organizational levels often requires pooling data from different groups (e.g. individuals in different months). PCA provides a multivariate description of data structure within a single group, not among multiple groups (McCoy et al. 2006). Previ-��"�� )�� "�$� ��(� ��-tion into different levels (i.e. among species and among individuals (Matson et al. 2006a), or among individuals and over time (Buehler et al. 2008c). For example, variation in indices of immune function �� 5��(�� 1� ��-ing to multiple groups (i.e. species (Matson et al. 2006a) or individu-als (Buehler et al. 2008�11� "�$�� $�� -�� $��/��8�)�(� �� $$ �� (� "�� "�� $��#��$�� our knowledge this assumption remains untested in the context of ecological immunology. Testing this assumption will provide new in-sight into immunological covariation. Consistent relationships may �� $�"�� )�� $�� have different interpretations depending on the organizational level 5��$��7�$��/��$ �� (��7�$��/�� 7�$��/�� $��1��

129

Testing this assumption��(� �� (�� $�� <� ��6�6!� �� $ �� )�� (� �� (� "� �� -lar way in different groups. CPCA determines whether the variance-covariance matrices among groups are structurally similar, and the method differentiates among degrees of matrix similarity. Immune indices could covary in a similar way among groups (i.e. the matrices � ��;��1��(� "�� )�"�� )��the strength of covariation differing among groups (i.e. the matrices are proportional). Some immune indices could covary in a similar way while others covary differently among groups (i.e. the matrices �� 6�1��<��"�� $��"�unrelated (Flury 1988, Phillips and Arnold 1999). CPCA can serve �� $�)� �� (� �� (�� #�� )��#�� $ �� CPCA (Houle et al. 2002). CPCA, like PCA, assumes that relation-ships among the PCs are orthogonal. However, in ecology it is often unrealistic to assume that the underlying causes of the data struc-ture are completely independent. For example, covariation in indices �� "� �� "� �� )�� "� �� )�� <� �� when CPCA determines that PCs are not common among groups, the analysis does not identify which or how particular relationships � �(� �� 58��2002). In light of the limitations of CPCA, it is also useful to employ simple pair-wise correlations. To summarize correlations, we plot correlation ��/�� &$�� /��individually allows for visual evaluation of whether particular groups � �� )��7�� &$�� )�� a simple visual examination of how pairs of indices are related in general (the mean correlation) and whether correlations are consist-�� $�� (� ��5��)�� &��)��#� �1�!� /�� $$ �� "� �� $� �� 6!�� $�� $� �� $�� &��$�� $�� $��individual or time points. In a correlation circle, all of the original (� �� 6!� � �� $�� )�� $ ��-pal components, which are represented as the x- and y-axes. Using a simple, hypothetical dataset with only two immune indices and two groups, Figure %�� )� �� -

130

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$ ��5�1� �� $�� )��(� �� )�� $��5 1��"�� )��5�1��"�� $-posite. The fourth panel of Figure %�� highlights how important pat-�� "� ��5 1�� 5�1�)�� $�� $��6� -relation circles allow for graphical examination of the relationships among indices, and the consistency of these relationships among groups and over time. This approach can supplement the pair-wise correlation approach. While that approach allows simultaneous eval-�� (� �� $��$� ��6!�� circles allow for simultaneous examination of covariation among multiple immune indices. We used these three methods to test the assumption of consistent ��$��$�� $�� -��(��$� ��(��4��"��$� ��)��$ �(��"�$� ��(� �� *� 51) multiple species of waterfowl at a single time point (Matson et al. 2006a), (21��$�� $��$�� 5�� $-ter 2) during a single season and (3) multiple individuals of a single �� $��(� ��"��59�� 2008c).

MethodsDatasets

Matson et al. (2006a) measured 13 indices of immune function in 10��$��)�� )��/(�� $ ��*�� -tivity, leukocyte concentrations, hemolysis-hemagglutination titers, ��$�� 7��#�� &��$��"��-��et al. (2006�1��)� ��$��$��7 �� -�� $��0��)��$��)�� 6!��(� �� "��"�)�� "�� /(�� (�� $��$��*� �� $��"� �� $�� Escherichia coli and Staphylococcus aureus (anti-E.coli and anti-S. aureus capaci-��1D��"�� D��$�� 7��#�� 5�� %�� (��-tions). We omitted hemolysis and hemagglutination titers against � �� "� � �� (��(� "�� 5-��2006a). We omitted antioxidant capacity in order to limit the examined indi-

131

S T

PCA Principal components analysisCPCA Common principal components analysisSEM Structural equation modeling

W

ALCG Aleutian Canada gooseNABD North American black duckCHPT Chilean pintailSGPT South Georgia pintailLATE Laysan tealMUSC Muscovy duckNENE Nene or Hawaiian gooseWWWD White-winged wood duck

S

KXE Cross between Kazakh and European stonechatsEXK Cross between European and Kenyan stonechats

I

H Heterophil concentrationE Eosinophil concentrationL Lymphocyte concentrationM Monocyte concentrationMCS Microbicidal capacity against S. aureusMCC Microbicidal capacity against C. albicansMCE Microbicidal capacity against E.coliL Complement mediated lysisA Natural antibody mediated agglutinationH Haptoglobin-like activity

Table 7.1 – Abbreviations used in the text, tables and figures.

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ces to those with a primarily immunological function. We excluded �)��$�� $��0��5�B2��B1) were not �� )��7�$��6!�� /��-set included eight species: Aleutian Canada goose, Branta canaden-sis leucopareica� 5!,6'�� B71D� �� !�� #� ��#�� Anas rubripes� 5�!9�� B6); Chilean pintail, Anas georgica spinicauda 568��B8); South Georgia pintail, Anas georgica georgica (SGPT, �B8); Laysan teal, Anas laysanensis� 5,!�� B8); Muscovy duck, Cairina moschata� 5-��6�� B5); nene or Hawaiian goose, Branta sandvicensis�5��B8); white-winged wood duck, Cairina scutu-lata� 5444��B8�� %��). Although we also analysed the cel-lular indices of immune function, these results are presented in the supplementary material only.�� 5��$�� 2) measured six indices of immune function �� $��)��" ��$�$��$��(�� $ ��*�� $��"��E. coli, S. aureus and Candida albicans, hemolysis-hemagglutination titers ��$�� 7��#��(��"��!��(��)� �� a single quiescent period in the annual cycle (winter). The geograph-��"7�� $�� 0�#�� 5Saxicola torquata maura��B10), Europe (S. t. rubicola��B15), Kenya (S. t. ax-illaris��B13) and Ireland (S. t. hibernans��B161��" ��)� �� )��0�#�� $��5��0M� ��B12) �� $��"�� 5� M��B20�� %��). 8" �� $�� $�� $��"��Buehler et al. (2008c) measured 14 indices of immune function in red knots (Calidris canutus1�� $ ��*�� capacity, leukocyte concentrations and hemolysis-hemagglutination titers. We restricted our analyses to the 27� � �� (� ��entire study period of 11 consecutive months. We also restricted our analyses to eight indices of immune function: a single time point in �� $��5E. coli after 10 min, C. al-bicans after 60 min and S. aureus after 120 min); concentrations of heterophils, lymphocytes and monocytes; and hemolysis and he-�� #��"��concentrations were excluded since they are the sum of the differen-tial concentrations; eosinophil concentrations were excluded due to a �� 0�(��D�� "�� )� ��&�� "�;��/�� "��4��

Group 1Group 2

AIn

dex

2Group 1

PC2

Group 2 Combined

B

Inde

x 2

PC2

C

Index 1

Inde

x 2

PC1

PC2

PC1 PC1

133

Figure 7.1 – Simplified scenarios illustrating how correlation circles can be inter-

preted when relationships between variables among groups are similar (a), dissimi-

lar (b), or opposite (c).

The first vertical panel consists of a scatterplot showing the correlation between

two indices in two groups (e.g. species, individuals or months). The next two panels

show the resulting correlation circles for the two groups separately. The fourth pan-

el shows the relationship given when the two groups are combined, and highlights

how important patterns may be diluted (B), or missed (C). In the correlation circles,

vectors are loadings for the two indices of immune function. The angle between

two vectors gives the degree of correlation (adjacent = highly correlated, orthogo-

nal (90°) = uncorrelated, and opposite (180°) = negatively correlated).

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used the transformed leukocyte concentration data to ensure nor-mality and to maintain consistency with Buehler et al. (2008c).Anti-E. coli and anti-S. aureus capacities were measured in all three �� "� ��$� � ��-�� (2006�1� �� $��)�� $��"� �� $��9�� 52008�1�� et al. (chapter 21��)�� )��$��"� �%�� "� �� 5��$��"��1�� $��

Statistical methodsCommon principal component analysis (CPCA): A statistical test of matrix similarity. Common principal component analysis is an ex-tension of PCA that compares the structure of two or more covari-�� "� �� the recognition that any two matrices can relate to one another in a complex fashion and that the two are not simply equal or unequal. CPCA determines whether matrices are equal, proportional, share �� $ ��$�� $�� of principal components shared can range from one to p-2, where p �� (� �� 6�6!� �� )��$$ ��Q��7 �� $$ �� $7�$� �$$ ��Q� �� "��#��"� ��$�� $$ �� )��)��!#��#�� -mation criterion (AIC). In the step-up approach, a null-hypothesis is iteratively compared to an alternative hypothesis. The compared �� "��)�� )�� )�� -lated matrices, and progresses through matrices that share one PC, that share more than one (up to p-2) PC, that are proportional, and, /��"�� ;�� )�"�� (��$�� "��!��/��7(�� 5��$��and Arnold 1999).We used the program CPC (Phillips 2000), which performs the anal-"�� "�<�� "� 5<�� "�1988), to carry out CPCA. We used �� (� �� )��)� �� $� ��)�� $�� (��4�� $�� $��(��<� ��$� ��-(��)� �� -

135

�� )� �� $� � � �� $� �� $��(��"�� 6�6!� �� $�� )�� )�� $�� )�� (�� )��&�� (��$� �� &�5��-��6��$��)��&�� )��(��(� �� "� �� &1D��6�6!�� $��)�� &�matrices with 12 to 20� � �� (�� D� ��6�6!�� (�� #��)�� 27 matrices with 11�� (��D��the CPCA of ��#��(� ��)�� 11 matrices with 27 � �� (��

Pair-wise correlations and boxplots – We calculated Pearson correla-��/�� $�� -/�� $ �� &$�� $�� $� ��-�� (��"��5��$�� $��(��1��<� ��&��$��$��(�� &�)��)��#� �� $ �� $��7�$��/�� - �� 5 to 8 individuals. Furthermore, we calculated 95K��/�� (��$� �� 7��&��)�� /�� $�� 7)��$� ��-�� /��"�� 0� ��5�� $��$� �-sons using a sequential Bonferroni correction (Rice 1989)). Because �� /�� "�� )�� the correlations into z-scores (Sokal and Rohlf 1995, page 5781� �-fore carrying out the t-tests. For waterfowl and stonechats, sample ��0�� $�� $�� )�� -��)�� $�� 0�� )�"� �� $� 5� �groups) with the largest sample size were given a weight of 1 (adapt-ed from Sokal and Rohlf 1995, page 42). We multiplied the z-trans-�� /��)��)�� )��correlations. Using these weighted correlations, we calculated means �� (� �� $� �� 7�� 5�� B� �� $�� the analysis). T-tests performed on weighted and unweighted correla-�� &$�� )��7��)�� "�� -��5)�� &:)��#� �1��)�� /��"�� 0� ��<��"�� /��)� ��$��(��"��$�� "��$�� $�� 2�� $�$��3�5�� $�� #��(Buehler et al. 2008c)). These dotplots were examined for clustering

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��$��)�� )�� &$�� $�� "� �� <� ��&��$�� /�� 0� ��)�� &��)��#� �� -�� )�� $��(��"� �� $�� negatively correlated (or consistently uncorrelated) in other groups. Pearson correlations, plots and t-tests were performed using R (R de-velopment core team 2010).

Within-group principal component analysis (PCA) and correlation circles – We carried out separate PCAs and plotted a separate cor-relation circle for each group at each organizational level (species, �� $�� (�� $��1�� "� �&�� relationships among indices and among groups. This analysis allows the examination of multiple dimensions at once (i.e. immune indi-��1�� $�� in all groups. PCAs were performed and correlation circles were generated using the ade4 package in R (Dray and Dufour 2007). In every correlation �� (� �� )��(�� )�� $�� )�� (� �� )��6�� 5(�� 1� ��)�� -��$�� $��(�� (��5(�� 1�� )��)��(�� )��)�� (� �� !� ��)��(� �� $��"�uncorrelated; zero or 180�� )��)��(� �� complete positive or negative correlation. Consistent relationships among groups at a particular level (i.e. species, individual, month) � �� "�� (�� -relation circles. While we only show correlation circles with PC1 and PC2��)��&�� PCs 1 to 4 (not shown). Unless otherwise stated, all correlation cir-cles resulted in the same conclusions as those showing PC1 and PC2 alone. 4�� 6!�� CPCA. Unlike Matson et al. (2006a) and Buehler et al. (2008c), we �� (� ��&� �� )��)�� $� �� )�� 6!�� 6�6!�� 5)�� $� �� (��1��(� ��)��&�� $7�$��/�� %��6��

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H

H L �2 .. P AIC

E P 0.570 6 0.9969 126.0P CPC 62.021 24 <0.0001 137.4CPC CPC(3) 4.524 6 0.6062 123.4CPC(3) CPC(2) 19.496 12 0.0772 130.9CPC(2) CPC(1) 15.393 18 0.6348 135.4CPC(1) U 23.977 24 0.4629 156.0U --- 180.0

Table 7.2 – Common principal components analysis (CPCA) of covariance matrices among

waterfowl species for plasma-based indices of immune function.

The Table shows Flury’s Decomposition of Chi Square using step-up and model building

approaches (Flury 1988, Phillips and Arnold 1999). In the step-up approach at each step

in the hierarchy the hypothesis labeled “higher” is tested against the hypothesis on the

step below, “lower”. The hierarchy is built in a step-wise fashion starting with no relation

between the matrices (Unrelated) and rising to CPC(1), then CPC(2), etc, through CPC,

Proportionality, and Equality. The likelihood that a particular model is valid is given by the

P-value, thus low P-values indicate a low probability that the higher model is better than

the lower model (Phillips and Arnold 1999). The best solution can also be evaluated using

the model building approach where the best model is indicated as the “higher” model in

the row with the lowest Akaike information criterion (AIC). Both methods indicate that the

matrices share all PCs in common but have different eignevalues (CPC)

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the previous varimax-rotated PCA performed with all species, indi-(�� !�� $�� $ ��$��"��$� � �� 6��$�-�� )��(�� $� ��)��(� �� 6!�� $ �(�-ous analysis and the current analysis are in agreement, then indices ��(�� 5��$��(��"�correlated) or in opposition (if negatively correlated), at least in the ��=� ��"��

ResultsCommon principal component analysis (CPCA)

!�� )�� )�� $�� 6�6!� �$$ �� -$�� )�� (�� $��56�6D�� %��1�� $��56�6D�� !%��). Among �� $��)��$$ ��"�� structures for plasma components. The step-up approach suggested complete shared structure with differing eigenvalues (CPC), and the �� $$ �� ;��"� �� 5�- ��%��). Among red knot individuals, the two approaches to CPCA �� &� �� $�� $7�$�approach suggested that the matrices were unrelated, whereas the �� $$ �� )� ��;��5�- ��%��). Finally, among months in individual red knots, the step-up �$$ �� 6�� (��56�61��7 ��$$ �� )� ��;��5� ��%�").

Pair-wise correlations and boxplots9�&� �� )��#� � $�� )�� )�� $��7�$��/�� /�� )� �� )�� 5�� R�� B� 0.471�� &� )�� (� ��(0.14<IQR<0.711�� )�� &� �&�� 5<��-ure %��D� �� %�� &� � �(��1�� <� �� -more, 95K��/�� (��7�� /�� /��"�� 0� ��5� ��A%��1��6�� $�� immune indices are weakly and inconsistently correlated among )�� )�� $�� 7)�� $�-

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H

H L �2 .. P AIC

E P 1.015 5 0.9614 103.7P CPC 47.044 25 0.0048 112.7CPC CPC(4) 8.443 5 0.1335 115.6CPC(4) CPC(3) 4.514 10 0.9212 117.2CPC(3) CPC(2) 10.241 15 0.8043 132.7CPC(2) CPC(1) 13.959 20 0.8326 152.4CPC(1) U 18.464 25 0.8221 178.5U --- 210.0

Table 7.3 – Common principal components analysis (CPCA) of covariance matrices

among stonechat subspecies.

The step-up approach (where a low p-value indicates a low probability that the higher

model is better than the lower model) suggests that covariance matrices among sub-

species share all PCs, but have differing eigenvalues (CPC), and the model building

approach (where the lowest AIC value indicates the best model) suggests that the

matrices are equal (see Table 1 for a complete description of the step-up and model

building approaches).

Table 7.4 – Common principal components analysis (CPCA) of covariance matrices con-

taining indices of immune function among individual red knots.

H

H L �2 .. P AIC

E P 6.978 26 0.9999 1464.2P CPC 281.317 182 <0.0001 1509.3CPC CPC(6) 33.538 26 0.1471 1591.9CPC(6) CPC(5) 64.881 52 0.1083 1610.4CPC(5) CPC(4) 88.281 78 0.1998 1649.5CPC(4) CPC(3) 152.434 104 0.0014 1717.2CPC(3) CPC(2) 214.075 130 <0.0001 1772.8CPC(2) CPC(1) 304.889 156 <0.0001 1818.7CPC(1) U 317.835 182 <0.0001 1825.8U --- 1872.0

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�� )�� "� �� (� �� "� �� )�� )�� $��(0.12<IQR<0.49�� R�� B� 0.32; Figure %��1�� &��had outliers. Furthermore, only one of the 15 mean correlation coef-/�� /��"�� 0� ��5!��7,"�D�� !�%��). Pair-wise correlations among knot individuals showed a similar �� (� �� "� �� )�� $�� $��(0.20<IQR<0.61��R��B�0.41; Figure %��a). The most posi-tively (lymphocytes-monocytes) and negatively (hemolysis-anti-E.coli capacity) correlated pairs had whiskers that did not include zero, ��(��$�� 0� ��8�)�(� ��the 28 relationships had mean correlation coefficients that differed significantly from zero (Figure %�� !%��a). Within indi-vidual knots over 11�� &��)��#� �$��)� �� )� �than at any other level (0.09<IQR<0.55��R��B�0.25; Figure %�� 1��<� �� 6 of the 28 relationships were significantly dif-�� 0� �� 5� ��!%�� 1�� 6 significant pairs, only one had whiskers that included zero and none had outliers. Thus, some indices were consistently correlated, either positively or nega-tively, over the year.Dotplots of individual correlation coefficients (not shown) indicat-�� )�� )�� $�� $��<� �� #��)�� "�� 5��)� �� (� �� 1�� "� �� 5�� moult, wintering).

Within-group principal component analysis (PCA) and correlation circles

�� )��(�� $��7�$��/�� differed widely indicating that relationships among plasma (Fig-ure %�") and cellular (Figure A%��) indices were generally inconsist-ent among waterfowl species. For example, anti-E.coli capacity and hemagglutination were uncorrelated (perpendicular) in ALCG and highly correlated (parallel) in CHPT. An exception is the uncorre-�� $�5$� $�� 1� ��)��$�� "-��)��)��$��5�� %�� "�� )� �&��<�� %��1��(� �� <�� %�" indicated that immune indices that were related in the previous analysis (Matson et al. 2006a) were not related when the PCA was performed on each species separately.

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Table 7.5 – Common principal components analysis (CPCA) of covariance matrices con-

taining indices of immune function among 11 month within individual red knots.

H

H L �2 .. P AIC

E P 2.189 10 0.9947 362.8P CPC 122.267 70 0.0001 380.6CPC CPC(6) 17.194 10 0.0702 398.3CPC(6) CPC(5) 22.560 20 0.3109 401.1CPC(5) CPC(4) 18.012 30 0.9583 418.5CPC(4) CPC(3) 29.036 40 0.9004 460.5CPC(3) CPC(2) 50.667 50 0.4471 511.5CPC(2) CPC(1) 47.340 60 0.8823 560.8CPC(1) U 53.495 70 0.9286 633.5U --- 720.0

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Figure 7.2 – Boxplots showing correlation coefficients for pair-wise Pearson cor-

relations between plasma-based indices of immune function among waterfowl

species (n = 8, see Table 7.1 for abbreviations).

Solid lines indicate the median, boxes the inter-quartile range, whiskers the

range and open circles outliers. Lower variation (smaller boxes, whiskers and few

outliers) indicates more consistent correlations among species.

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Figure 7.3 – Boxplots showing correlation coefficients for pair-wise Pearson

correlations between indices of immune function among stonechat (Saxicola

torquata) subspecies (n = 12 to 20, see methods for sample size details and Table

7.1 for abbreviations).

Solid lines indicate the median, boxes the inter-quartile range, whiskers the range

and open circles outliers. Lower variation (smaller boxes, whiskers and few outli-

ers) indicates more consistent correlations among subspecies. Asterisks indicate

weighted mean correlation coefficients (Sokal and Rohlf 1995) that differed sig-

nificantly from zero after sequential Bonferroni correction (Rice 1989, see Table

A7.3 for statistics).

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Figure 7.4 – Boxplots showing correlation coefficients for pair-wise Pearson correla-

tions between indices of immune function (see Table 7.1 for abbreviations) in red knots

(Calidris canutus) among individuals (A, n = 27 birds), and over time (B, n = 11 monthly

measurements).

Solid lines indicate the median, boxes the interquartile range, whiskers the range and

open circles outliers. Lower variation (smaller boxes, whiskers and few outliers) indi-

cates more consistent correlations. Asterisks indicate mean correlation coefficients

that differed significantly from zero after sequential Bonferroni correction (Rice 1989,

see Table A7.4 for statistics).

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Figure 7.5 – Correlation circles for unrotated principal component analyses (PCA) on

plasma-based immune indices among waterfowl species (see Table 7.1 for abbreviations).

Vectors are the loadings on PC1 (x-axis) and PC2 (y-axis). Vector length indicates the

strength of the relationship and the angle between two vectors gives the degree of cor-

relation (adjacent = highly correlated, orthogonal (90°) = uncorrelated, and opposite

(180°) = negatively correlated). Shading indicates how the indices of immune function

were grouped in a previous varimax rotated PCA performed with all species combined

(Matson et al. 2006a). Indices having the same shading were associated with the same

PC in the previous analysis.

147

Figure 7.6 – Correlation circles for unrotated principal component analyses (PCA)

on immune indices among stonechat subspecies (see Table 7.1 for abbreviations).

Vectors are the loadings on PC1 (x-axis) and PC2 (y-axis). Vector length indicates

the strength of the relationship and the angle between two vectors gives the de-

gree of correlation (adjacent = highly correlated, orthogonal (90°) = uncorrelated,

and opposite (180°) = negatively correlated). Shading indicates how the indices of

immune function were grouped in a varimax rotated PCA performed with all sub-

species combined (see Table A7.5). Indices having the same shading were associ-

ated with the same PC in the combined PCA. Anti-C. albicans capacity correlated

equally across two PCs in the pooled analysis (Table A7.5), therefore it has darker

grey shading with white lettering.

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�� $��7�$�� )� ��"� �� $��D�� )� ��"� �� $��D��"�� )� �� "� �� $��(Figure %�#). For example, hemolysis and hemagglutination were $��(��"�� $�� )��(��-�� )� ��(��&�� $��5<�� %�#1D� �� 0�#�� )�� $� $�� the vectors were short, indicating that they were not strongly cor-related with PC1 or PC2. Examination of the first four PCs showed that they were positively correlated with a high loading on the third PC (not shown). Anti-E. coli and anti-S. aureus were positively cor- �� $�� )��(��-�� )� ��(��&�� $��5<�� %�#1�� M��0� �� $�� )��$� $�� vectors were short. Examination of the first four principal com-ponents showed that these two indices were negatively correlated �� 6� 5�� )�1�� <��"�� $�� -tination showed completely different relationships in the different �� $��"�)� ��$��(��"� �� M��" �� (��"� �� 0�#�� (� �� 5<�� %�#) indicated that immune indices that were �� (� ��&� ��6!�� $�� 5� ��A %�", see Matson et al. 2006a for method) clustered in some (e.g. � �$��1� ��5��0M� 1�� $��)��6!�)��$� �� $��$� ��"��(��7�$��/�� $��among some indices were consistent among most red knot individu-als (Figure A %��a). However, not all indices were consistently related �� (��<� ��&��$�� )��"��"�$��"�� 5�� 19 and 24, Figure A %��a). In this way, the correlation circle results supported �&$�� &�$�� )�� )� �&��5<�� %��) are the same indices that group together in most correlation circles 5�� "�$��"��"��1��(� �� <�� A %��a indicated that immune indices that grouped together previ-��"�)�� )� �� "��59�� al. 2008�1�� 5�� "�$��"�� "��1�� &��$�� 5�� 19 and 24).

149

<��"��7�$��/�� $��among indices were relatively consistent through the year (Figure A%�� 1��<� ��&��$�� )��"�$��"��"��(� �� )��indices that grouped together previously (Buehler et al. 2008c) again clustered fairly consistently when all months were analyzed separate-ly (i.e. lymphocytes, monocytes; heterophils and anti-C. albicans and anti-S. aureus capacities, Figure A%�� 1��

DiscussionTo deal with the complexity of the immune system, ecological im-munologists have devised multiple techniques to measure differ-ent aspects of immune function in wild animals. In this paper we address the question of how multivariate immunological datasets �� "� ��"0�� $ �� groups at a particular organizational level (e.g. species or popula-tions). Previously, researchers have applied multivariate methods to data that are pooled after statistically neutralizing any group-ef-fect. However, the implicit assumption is that relationships among the assayed immune indices are similar in all groups. We tested this assumption using CPCA, and then employed pair-wise corre-lations and correlation circles to delve deeper into the consistency and inconsistency of these relationships among groups. These statistical analyses range in complexity and in novelty, at least in terms of their use with multivariate datasets concerning immune function. Nonetheless, when packaged together and treated as a statistical protocol, these methods can serve as an important new ��)�� $$�� (� ��"�� 0�-tional levels.

Fresh insights provided by this novel statistical approach�� $ �� (�� )�� when using previous analytical approaches. As a result, the presented protocol facilitates more-detailed conclusions than were previously $�� 5��-��2006a, Martin et al. 2007, Buehler et al. 2008c) and, thus, acts as a foundation for new hypotheses. We high-��)�� "��$� �� prior results at different organization levels.

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Overall, the extent to which multivariate patterns are consistent among groups at different organizational levels varies. For example, relationships among immune indices differed from species to spe-�� $�� )� �� "� �� (� �� "��$��;�� 0��(�� +�� $��"��$ ��$�� )�� )�� "�� $��/�� 0�� (�� made. For instance, patterns among immune defenses might typi-��"� �� $�$�� $��fact, our results suggest that relationships among immune indices ��$��&��"�� 0��(�� 5�� (�� $��$��1��$��-tern holds as additional datasets and analyses come to light, then it �� (�� )��"$��<� ��&��$��(� �� timescales physiological mechanisms might limit plasticity and vari-� ��"��)�� (� �� time scales selection pressures might gradually reshape physiology and lead to decoupled and reorganized immunological relationships (Duckworth 2010).�� $ ��)�� 7�&�� /��of previous multivariate analyses of immune function. Matson et al. (2006a) pooled individuals across species and reported a general among-individual pattern, which parallels assay category. The cur-rent approach, however, revealed that this use of pooling individu-��"��%�� "��7��(��$�� "��$��9�� 52008c) pooled their data in two ways: 1) data points from a given individual were $�� "��"�� &��7��-vidual patterns 2) data points from a given month were statistically corrected for individual to examine among-month patterns. Our �� $$ �� "� �� $�� )�� )�� +�� "� �� (��(��$�� $$�� )��7supported since we demonstrate that relationships among immune indices were consistent from one month to the next. On the other hand, statistically correcting for individual to examine annual pat-�� $$ �$ ��"� ��$�� $�� immune indices since we demonstrate that these relationships varied

151

from individual to individual. To summarize, if correlations are con-�� $�� 0��(�� (��approach and the approach of pooling data across groups give simi-lar results. However, if correlations are inconsistent across among � ��$�� 0�� (�� "�� $�� )��)��$$ �� -ference space and sample size. The general patterns derived from ��"��$��"�� =��$��"�� -ference (e.g. the order Anseriformes as opposed to the species Anas platyrhynchos). One caveat is that in pooled analyses disparities in sample sizes among groups can affect patterns: a well-represented � ��$�)�� )��&� �� %�� $�� $�� "� �$ �� $�)�� )�� -ments. While the groups we compared were generally similar in sam-ple size, checking the consistency of correlations among groups is particularly important when sample sizes vary in such a way that one or a few groups dominate over many others. In the latter case, any �(�� $�� $ �� "�� $7 "7� ��$�evaluations. Another caveat is that the value of a general pattern ��$��"�� "��(� ��"�� $ �-��(�� $��"��$��0�� $��$$�� measurements per group.

Immunological consistency and inconsistency among groups The statistical protocol outlined in this paper provided insights into consistencies and inconsistencies in the way that immunological in-dices interrelate among groups. The usefulness of the protocol, how-�(� �� &�� "�� $� �� "7��-�"0�� 0��(�� &��$��"��$$�� "��$ �� 0��(��$�� "��(�� multivariate datasets unrelated to immune function. Nevertheless, ��$ �(�� $ ��)�� %"�� "0��(��Among waterfowl species, the CPCA indicated complete common principal component structure. This result suggests that covari-ance matrices are not statistically different among species. That is, immune indices interrelate similarly among species, and therefore

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pooling individuals into a single PCA is valid (Matson et al. 2006a). +�� "��$�� 7)�� &$��$��7�$��/��correlation circles provided no evidence for consistent immunologi-�� $��$��%�� )��7�$��$��0��5��B�6-8 individuals), which can increase the likelihood of recovering shared covariance structure with CPCA even when little similarity actually exists (Steppan 1997). Consequently, we cannot unequivocally conclude that immunologi-cal relationships are consistent within the tested species, and, the results seemingly invalidate the approach of pooling individuals of different species into a single PCA.!�� $��6�6!�� ;��"�� complete common PC structure. That is, immunological relation-��$�� $��8�)�(� ��$�� 7)�� -�� &$�� $��7�$��/�� 4��)� ��"� �� $�� )� �� 6�� $�� (�� )�� !�� 6�6!� ��-cated shared PCs, the other methods cautioned against pooling all ��(�� $��6!��"��Among individual red knots, the two CPCA approaches gave highly divergent results. The step-up approach indicated that relationships among immune indices differed among individuals; the model- ��;��"��$�� 7)�� &-plots and the correlation circles showed that some immune indices � ��$��(��"�� (��"�� (�� $�� "� �� (� ��5��)�� &��)��#� �1�� &$�� "��-�� )��(�� $�� "�� These inconsistent relationships, apparent upon graphical examina-��%��$7�$��$$ ��"��"��&$��why this approach resolved that the matrices were different. Overall, �� )�� $�� $$ �� 6�6!�step-up approach suggested that immunological relationships were inconsistent at the individual level.Among months, the two CPCA approaches and the two graphical ap-proaches suggested that immunological relationships were consist-ent. Furthermore, immunological relationships that were previously ��/�� (�� 6!� �� $�� 59��

153

2008�1�)� �� "��/��(�� (�� %�&� ��over the annual cycle (Buehler et al. 2008c), relationships among �� (��"��<� ��&��$�� &�!�� (� �� )�� (� �� within each month, indices A and B always correlate without regard �� (��

Future analyses: opportunities and challengesThe datasets we analyzed focused on indices of constitutive levels of innate immunity. Conducting similar analyses on datasets that in-�� )�� (�� <� � �&��$��Martin et al. (2007) present a dataset that includes indices of consti-tutive innate immunity, acquired immunity, and induced responses. ��"�� "�� &��)��-er relationships among types of immune defences, which represent $��(��2� ��3��"�� $��However, application of the protocol presented here requires separate �$��7�$��/��6!�� the same individuals within each species. Unfortunately in Martin’s dataset different individuals were used (Martin et al. 2007).Our analyses demonstrated the value of graphical examination of pair-wise correlations. In addition to serving the overall statistical protocol, the graphical examination of pair-wise correlations may also serve as a starting point for meta-analysis and the synthesis of sev-� ��$� ��+�� )��$ ��$�� $�� 7)�� 7��"�� ;��56�6!�� $7�$��/�� 1� �;�� (�� $��particular challenge in ecological immunology. Oftentimes, the num- � �� #�� (�� "��(�� "�� =�� "��0��-� ��(� ��"��$��"�� "��or at least different protocols to measure immune function. We illustrate the potential value and pitfalls of graphical examina-�� $�� 7)�� 7��"�� "� �� three datasets presented in this paper (Figure %�%). In this case, we $�� /��(��"� �� 0��(� ��(� ��)�� &$��#��

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Figure 7.7 – Dotplot showing correlation coefficients for pair-wise Pearson correlations be-

tween indices of immune function (see Table 7.1 for abbreviations) in an analysis combining

waterfowl, stonechat and knot datasets.

Each correlation coefficient for each species or subspecies is shown as a dot with its dataset

of origin indicated in the shading. Waterfowl correlations are based on 5 to 8 individuals,

stonechat correlations are based on 10 to 20 individuals, and knot correlations are based

on 27 individuals. Asterisks indicate where weighted mean correlation coefficients (Sokal

and Rohlf 1995) differed significantly from zero after sequential Bonferroni correction (Rice

1989).

155

��)� �� "�� "�� / �� was very little consistency in relationships among immune indices ��$��5��1��5��1��7�� /��)�� $�� 0�� 5��#�� Rohlf 1995), demonstrated that only two relationships (hemaggluti-nation and hemolysis, anti-E. coli and S. aureus capacities) differed ��/��"� � ��0� �D� ��(�� $��)� �� -sistently positive (e.g. in the hemagglutination and hemolysis pair, ��)�� )��$�� /��0� ��5�'�1��another of -0.6 (ALCG)). �� $�� )��-/�� "� �� &� �� $��0�� $��&��"��8�)�(� �� $ �� "�� (�� $��)��)� �� "�� (� ��$$ �&��"��/(�7"�� $� ��#��$��-�� "��<� �� $��"�)�� differently in waterfowl (plasma only) versus stonechats and knots 5)�� 1��6��$�� "�)��-��)�� &��"Q�� $��)� �� "��$��)�(� �� %�� "�� -ical immunology community, in which research groups often focus on particular study species and customize immunological assays in one way or another. Second, recall that for the knot dataset we have multiple samples from each individual over an annual cycle. Because Buehler et al. (2008�1��/��(� ��)��selected only measurements that were recorded during a quiescent )�� $� �� )�� )�� $� � �� Intra-annual patterns demonstrate the importance of explicitly stat-ing when in the annual cycle samples were collected, if independent �� 7��"��Overall, the need for and utility of multivariate statistical methods �� 6� ��"�� #�� $ ��)�� useful and informative when applied within individual studies. Ana-lytical integration among datasets remains a challenge; meeting this �� )�� ;�� =�� 0�� related to the collecting, processing and assaying of samples.When considering the future of ecological immunology analyses, the potential importance of methods that can unite several multivariate datasets also comes to light. Additional datasets might, for example,

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��$�� (� �� (� �� -(� ��5 �� 1�(� �� ;��modelling (SEM) is a potentially powerful analytical method for �� "�� &�� -��$�� )�� (� �� )�� $ ��$��-� ��(� �� !� ��(� �� "� �� 5� ��(��7�� D�5�� #��4�� 2005)). For example, multiple �� 5�� (� �� 1� �� -�� 5�� (� �� 1� � � ��(� �� 2� ��3��5�� (� �� -;�� 1��-�� $�� "��$��$ �� -��&��)�� (� �� (� �� 5��-� ��1� ��)� �� (� �� 5�� 1��8�)�(� ��/��"�)��$ � � �"��(��(��$�� $��-�� $��/��a priori�� -rent limitations on our knowledge mean specifying a model for even ��(� �� )��$�� $$��-�� (�� =�� "�� "�

Acknowledgements4��#�!�8��6�8� ��#�� C Both for helpful discussions and comments on earlier drafts of the manuscript. We also thank editor Frederick Adler and anonymous reviewers for improvements on earlier drafts.

157

H

H L �2 .. P AIC

E P 0.43 6 0.9986 102.5P CPC 64.23 18 <0.0001 114.0CPC CPC(2) 8.33 6 0.2152 85.8CPC(2) CPC(1) 16.27 12 0.1792 89.5CPC(1) U 13.21 18 0.7789 97.2U --- 120.0

Table A7.1 – Common principal components analysis (CPCA) of covariance matrices

among waterfowl species for cellular indices of immune function. The Table shows

Flury’s Decomposition of �2 using step-up and model building approaches (see Table

7.2 for details). Both methods indicate that covariance matrices among species share

all PCs, but have differing eigenvalues (CPC). This CPCA is based on five matrices

with six to eight observations per matrix because two species (NABD and MUSC)

were excluded due to low levels of variability in one or more immune index.

Appendix 7.1

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V M T .. P 95% C

AL-MCE -0.227 -1.697 7 0.1336 -0.503 to 0.091L-MCS -0.037 -0.187 7 0.8568 -0.469 to 0.409A-MCE -0.015 -0.131 7 0.8992 -0.279 to 0.251L-H 0.038 0.809 7 0.4454 -0.073 to 0.149H-MCE 0.040 0.261 7 0.8017 -0.314 to 0.385MCS-A 0.041 0.193 7 0.8528 -0.430 to 0.494A-H 0.045 0.374 7 0.7196 -0.237 to 0.321H-MCS 0.113 0.599 7 0.5682 -0.324 to 0.511MCE-MCS 0.280 1.729 7 0.1274 -0.105 to 0.592A-L 0.510 2.122 7 0.0715 -0.064 to 0.831

BEos-Mon -0.273 -1.491 6 0.1866 -0.629 to 0.178Eos-Lym -0.043 -0.392 6 0.7084 -0.303 to 0.223Lym-Mon 0.012 0.053 6 0.9593 -0.480 to 0.497Het-Lym 0.064 0.344 6 0.7426 -0.373 to 0.478Het-Mon 0.219 0.869 6 0.4184 -0.383 to 0.690Eos-Het 0.416 1.158 6 0.2907 -0.456 to 0.881

Table A7.2 – Mean correlation coefficients for pairwise Pearson correlations be-

tween plasma-based (A), and cellular (B), indices of immune function (see Table

7.1 for abbreviations) among species of waterfowl (n = 8 for plasma-based and n =

7 for cellular immune function). No mean correlation coefficients were significantly

different from zero after sequential Bonferroni correction (Rice 1989, see text for

statistical details).

159

V M T .. P 95% C

H-MCC -0.115 -0.837 5 0.4407 -0.439 to 0.235L-MCC -0.058 -0.601 5 0.5742 -0.296 to 0.187A-H -0.040 -0.536 5 0.6150 -0.230 to 0.152A-MCC 0.038 0.448 5 0.6726 -0.176 to 0.248H-L 0.085 0.711 5 0.5092 -0.219 to 0.374H-MCE 0.096 1.288 5 0.2543 -0.096 to 0.282MCC-MCE 0.101 0.893 5 0.4128 -0.187 to 0.373H-MCS 0.114 1.345 5 0.2365 -0.104 to 0.322A-MCE 0.118 0.886 5 0.4162 -0.222 to 0.433MCC-MCS 0.119 1.353 5 0.2341 -0.107 to 0.333L-MCE 0.160 1.582 5 0.1744 -0.101 to 0.400A-MCS 0.196 1.810 5 0.1301 -0.083 to 0.446L-MCS 0.243 2.077 5 0.0924 -0.059 to 0.503MCE-MCS 0.396 3.395 5 0.0194 0.101 to 0.627A-L 0.627 5.272 5 0.0033 0.360 to 0.798

Table A7.3 – Mean correlation coefficients for pairwise Pearson correlations of

indices of immune function (see Table 7.1 for abbreviations) among six stonechat

subspecies. P-values indicating significant difference from zero after sequential

Bonferroni correction (Rice 1989) are bold (see text for statistical details).

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V M T .. P 95% C

ALys-MCEc -0.466 -7.477 26 <0.0001 -0.568 to -0.351Lym-MCCa -0.177 -2.950 26 0.0066 -0.294 to -0.054Lym-MCSa -0.179 -2.130 26 0.0428 -0.342 to -0.006Lym-Lys -0.143 -2.868 26 0.0081 -0.242 to -0.041Het-Lys -0.082 -1.286 26 0.2096 -0.211 to 0.049Lys-Mon -0.080 -1.409 26 0.1708 -0.195 to 0.037Agg-Lym -0.070 -1.071 26 0.2939 -0.202 to 0.065MCCa-Mon -0.066 -0.835 26 0.4112 -0.225 to 0.096Lys-MCSa -0.023 -0.369 26 0.7152 -0.152 to 0.106Agg-Mon -0.003 -0.052 26 0.9590 -0.124 to 0.118MCSa-Mon 0.007 0.105 26 0.9168 -0.133 to 0.147Agg-MCSa 0.046 0.556 26 0.5827 -0.124 to 0.214Agg-Het 0.046 0.735 26 0.4691 -0.082 to 0.172MCCa-MCEc 0.079 0.923 26 0.3646 -0.096 to 0.249Agg-MCEc 0.064 1.091 26 0.2852 -0.056 to 0.182Lys-MCCa 0.072 0.880 26 0.3869 -0.095 to 0.234Agg-MCCa 0.106 1.627 26 0.1157 -0.028 to 0.236MCEc-MCSa 0.129 1.666 26 0.1078 -0.03 to 0.281Lym-MCEc 0.129 2.301 26 0.0297 0.014 to 0.242Het-Lym 0.192 2.904 26 0.0074 0.057 to 0.321MCEc-Mon 0.226 3.104 26 0.0046 0.077 to 0.364Het-MCEc 0.266 3.424 26 0.0021 0.109 to 0.411Het-Mon 0.257 4.083 26 0.0004 0.130 to 0.376Agg-Lys 0.273 3.912 26 0.0006 0.132 to 0.403Het-MCCa 0.291 4.041 26 0.0004 0.146 to 0.424MCCa-MCSa 0.320 4.035 26 0.0004 0.161 to 0.462Het-MCSa 0.424 8.711 26 <0.0001 0.333 to 0.507Lym-Mon 0.679 9.849 26 <0.0001 0.574 to 0.761

161

V M T .. P 95% C

BLym-MCSa -0.0709 -1.023 10 0.3302 -0.222 to 0.083Lym-MCEc -0.0481 -1.090 10 0.3013 -0.146 to 0.050Lym-Lys -0.0342 -0.677 10 0.5136 -0.146 to 0.078Lym-MCCa -0.0154 -0.198 10 0.8471 -0.186 to 0.156Agg-Lym -0.0076 -0.169 10 0.8690 -0.107 to 0.092Agg-Mon 0.0188 0.264 10 0.7975 -0.140 to 0.176MCCa-Mon 0.0529 0.702 10 0.4984 -0.115 to 0.217MCSa-Mon 0.0808 1.061 10 0.3137 -0.089 to 0.246Lys-Mon 0.0987 1.898 10 0.0870 -0.017 to 0.212Agg-MCSa 0.1205 2.858 10 0.0170 0.027 to 0.212Agg-Het 0.1331 1.777 10 0.1059 -0.034 to 0.293MCEc-MCSa 0.1359 1.740 10 0.1125 -0.038 to 0.302MCCa-MCEc 0.1405 2.156 10 0.0565 -0.005 to 0.280Agg-MCEc 0.1525 2.337 10 0.0415 0.007 to 0.292Lys-MCCa 0.1712 2.859 10 0.0170 0.038 to 0.298Agg-MCCa 0.1768 3.571 10 0.0051 0.067 to 0.282Lys-MCSa 0.1834 3.197 10 0.0095 0.056 to 0.305Lys-MCEc 0.1875 3.974 10 0.0026 0.083 to 0.288MCEc-Mon 0.2076 3.815 10 0.0034 0.087 to 0.322Het-MCEc 0.2143 3.908 10 0.0029 0.093 to 0.329Het-Lys 0.2545 3.563 10 0.0052 0.097 to 0.399Het-Lym 0.2614 3.180 10 0.0098 0.080 to 0.426Het-MCCa 0.3198 6.520 10 0.0001 0.215 to 0.417MCCa-MCSa 0.3199 4.453 10 0.0012 0.164 to 0.460Het-Mon 0.3591 5.940 10 0.0001 0.231 to 0.475Agg-Lys 0.3677 4.101 10 0.0021 0.174 to 0.534Het-MCSa 0.4366 9.823 10 <0.0001 0.347 to 0.518Lym-Mon 0.5419 6.989 10 <0.0001 0.391 to 0.664

Table A7.4 – Mean correlation coefficients for pairwise Pearson correlations of

indices of immune function (see Table 7.1 for abbreviations) among 27 individuals

(A), and over 11 monthly measurements (B) in red knots (Calidris canutus). P-values

indicating significant difference from zero after sequential Bonferroni correction

(Rice 1989) are bold (see text for statistical details).

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PC1 PC2 PC3

H (2) 0.83 0.15 -0.16H (2) 0.86 0.10 0.10H (/) -0.13 0.20 0.86E. coli (. ) 0.12 0.78 0.00S. aureus (. ) 0.27 0.74 0.19C. albicans(. ) -0.24 0.55 -0.55E 1.59 1.53 1.10

Table A7.5 – Loadings and eigenvalues for a varimax rotated

principal component analysis (PCA) on indices of immune func-

tion measured in stonechat subspecies. The analysis was per-

formed on data combined from six subspecies combined after

statistically accounting for subspecies effects (see Matson et al.

2006a for method).

163

Figure A7.1 – Correlation circles for unrotated principal component analyses (PCA) on cellular

indices of immune function among species of waterfowl (see Table 7.1 for abbreviations). Vec-

tors are the loadings on PC1 (x-axis) and PC2 (y-axis). Vector length indicates the strength of

the relationship and the angle between two vectors gives the degree of correlation (adjacent

= highly correlated, orthogonal (90°) = uncorrelated, and opposite (180°) = negatively corre-

lated). Shading indicates how indices of immune function were grouped in a previous varimax

rotated PCA performed with all species combined (Matson et al. 2006a). Indices having the

same shading were associated with the same PC in the previous analysis.

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A

165

Figure A7.2 – Correlation circles for unrotated principal component analyses

(PCA) on indices of immune function (see Table 7.1 for abbreviations) measured

in 27 individuals (A) and over 11 months (B) in red knots (Calidris canutus). Vec-

tors are the loadings on PC1 (x-axis) and PC2 (y-axis). Vector length indicates the

strength of the relationship and the angle between two vectors gives the degree

of correlation (adjacent = highly correlated, orthogonal (90°) = uncorrelated,

and opposite (180°) = negatively correlated). Shading indicates how the indices

of immune function were grouped in a previous varimax rotated PCA performed

with all individuals (A) or all months (B) combined (Buehler et al. 2008c). Indi-

ces having the same shading were associated with the same PC in the previous

analysis. Among individuals (A), monocytes correlated nearly equally across two

PCs in the previous analysis (Buehler et al. 2008c), therefore it has darker grey

shading with white lettering.

B

166

CHAPTER VIII

The interplay between energetics and immune function in avian life histories: a synthesis

-��#��!��

Overall conclusions and outline of this chapter�� )�� "�� corticosterone and immunity, do not correlate in the same way �� (�� $�� these physiological traits have not limited the evolution of life his-�� "� � �� <� �� (� �� $�� "��"�� "�are partly correlated. This may indicate that life history evolution �� "�$�"�� $�� "�� "� �� "�� physiological function that a population or species requires during ��"�� -� ��(� �� $�)��-sonal demands of different life cycle stages leaves room for alternate �&$�� function. For example, environmental factors, such as food avail-� ��"� ��$��$ �� )�� (� "�)�� "�� "�� $�� $�"��In contrast with a factor like day length, this type of environmental (� ��"� ��$�� "�� may interact synergistically or antagonistically with the demands of a life cycle stage. Life history traits and annual cycles of physiology ��"� �� "�� "�� environmental factors.

167

�� "�� $ �� $�� 7 "7��$�� "�� then integrate the findings of chapters 2, 3 and 4 using methods presented in chapters 6 and 7. Next, I investigate whether immune �� &�� "�� 7 �� "� )�� (�� "� ��-�� $�� "� �� (�� )� �� in multiple life cycle stages. I also investigate whether the among-��(�� )�� are consistent over the annual cycle using data form chapters 3 and 4. Finally, I offer several potential avenues for further research that address some of the most exciting and promising questions that re-main unanswered.

Adaptations of physiology to different environments: a summary��"�� "� � �� (�� $ �$��to have led to the Pace-of-Life axis (Ricklefs and Wikelski 2002). In chapter 2 we investigated whether constraints among physiological �"�� "�(� ��"�� $�-cies of stonechats. If constraints among physiological traits and life �� "��(�� )��)��&$��/�� (�� $�� -�� rate correlates with life history traits in stonechats (Klaassen 1995, Wikelski et al. 2003) and we use it as an indicator of Pace-of-Life. We �� )�� stress-induced corticosterone, and constitutive immune function. ��=� ��"�� )� �� )��(��-��(�� $�� "��-straints among physiological systems are not a driver of Pace-of-Life ��(� ��/��-� ��(� �� "��-fy a need to take environmental factors into account when mounting similar studies in the future.In chapter 3�)��(��%��(� �� "�� 59-�1��9� �� )� ��-�� 5�� 1995, Kersten et al. 1998, Wikelski et al. 2003, Bush et al. 2008��>0��2011). 4�� (�� #� �� "�� 9-�� "� ��"�� $�� )��" �� -��/(��"��$��(��"�� $��$��"�� life history traits and originate from environments with associated �� "��4�� $��" ��

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in a common garden setup under a constant temperature regime, and we measured an additional set of European stonechats under an ��"�(� �� $� �� $��)�� "��" �� )�"��&-�� (�� )� �� $� �� $��$� �� (� ��9-��(�� pattern. The results of this chapter show that annual cycles in BMR ��(��(��(�� "�� $��"�� %�� "��$� �� In chapter 4�)��(��"��/(��-��(�� "� �� $�� 7�$� �� $-ter 3�� 7��(�� (� �� immunity exists (Hasselquist et al. 1999, Møller et al. 2003, Owen and Moore 2006, Machado-Filho et al. 2010). Immune function �� "� ��"�� migration and reproduction (Møller et al. 2003, Machado-Filho et al. 20101��(� �� "�� &$�� 7offs with other life cycle demands and/or variation in the pathogen pressure in the environment (Møller et al. 2003, Martin 2005). But )�� (� �� #� �� (��(�� $��"$��%�&� ��"�� "�unknown. Because of the variation in life cycle stage demands and �� (� �� $��)��&-pected variation in annual cycles in immunity. Keeping stonechats in a common garden setup allowed us to investigate whether annual cy-��"��(�� #� ��(��(�� $�� )��(�� $��"$��%�&� ��"��"�� "��4�� $��"�� /(�� "��4�� " ��$� �� $�� " ��)� ��)�"�� -��#�$��(� �� $� �� )��(� ��)��/(��#�$��constant temperature. These results indicate that annual cycles of in-��"��(�� "��$��&��!��"��"��$� ��"� �� "��demands. Differences in environmental factors (e.g. annual variation in pathogen pressure) among locations of origin are likely candidates to have caused additional selection pressures.

169

In chapter 5 we investigated the mechanism that determines energy �&$�� 4�� "��(��%�� 7�$��/��9-�� 7�$��/��9-�� 0�� "� ��"� ��(�� 5�� 1990, Konarzewski and Diamond 19951�� "�5��8�� 1985), �� :� � �� -�� $�� $ �� $� �� "�58�� 2005). Mitochondria are important organelles for storing energy and thermoregulation (Rolfe and Brown 1997, Nich-ols and Ferguson 2002). In the process of storage of energy peptides � �� )�� "�� -dition to nuclear-encoded peptides (Rolfe and Brown 1997, Nichols and Ferguson 2002). A characteristic of the mitochondrial genome is that it is only inherited from the mother. To investigate the role �� 7�$��/��9-��)��/ �� "� ��7�$��/��9-��)�� $�� 5��0�#�� $��"��1� "��;��-tative genetic methods (Falconer and Mackay 1996, Kruuk 2004). 4�� "��0.69�� 7�$��/��9-��$� ��"�� 4��(��7�$��/��9-�� $� �� $��" ��)�� $� ��/�� 5�� 0�#�� &� � �$��)�� 0�#�� -ropean mothers, and European x Kenyan with either European or Kenyan mothers). If mitochondrial genes play an important role in ��7�$��/��9-��)��)��&$��" �� .�� $��"�� $��"�� 7�$��/��9-��)��)��&$��" ��)�� $� ��/�� )�� 7�$��/��9-��4��7�$��/��9-�� " ��)�� $� �� /�� -�� )� �� $� �� $�� $�� $��"�� 7�$��/��9-�� )��" �� .�� $�� "�� )��nuclear and mitochondrial genes. In chapter 6�)��(��)�� (��(� �-ation of mass, BMR and total evaporative water loss (TEWL). We took repeated measurements of BMR and TEWL of European stone-��)�� 4��(��)��$� ��(� ��

170

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esis

�&$�� "� �� (�� "� �� $�� "� �� )��measures (Lessells and Boag 1987). We also investigated sources of (� ��)��(�� "�� &��(� ��)��(�� "�(� �-�� "��4��9-�� $�� an individual characteristic in stonechats. Sex did not and age did have an effect on variation in BMR among individuals. Body mass ��(� ��9-�� )��(��-��4,�)�� $�� "� �� "��)�(� ��(�� 4,��)��(��)��%�� "�� &�� "��In chapter 7 we investigated the usefulness of simple and multivari-ate statistics to study relationships among immune indices, using �)�� $ �(��"� $� �� immune system is a multidimensional system and ecological immu-��(�� $$ �� "� ��#��$�� of immunity (e.g. Matson et al. 2006a, Martin et al. 2007, Buehler et al. 2008c, Pap et al. 2011). The interpretation of these multiple ��$��-��(� ��(�� summarize the outcome of these studies. We found that in the ana-lysed datasets immune indices are relatively consistently correlated )��(�� "�� (��of organization (e.g. species). Furthermore, we argue that often sim-ple correlations are helpful in addition to more complex multivariate techniques for understanding what causes the variation in the often relatively small datasets at hand.

Life history and physiological traits in seasonal environmentsI will now use the methods of chapter 6 and 7��"�� -tion of the data from chapters 3 and 4. First, I will calculate repeat-� �� "��)��$ �(�� "�of immune indices within individuals over a whole annual cycle. Sec-��)��(��"�� )��$�"��-ological traits. In chapter 2 we had found correlations among certain $�"�� (�� )� �� to the winter season. In chapter 7 we showed that in red knots (Calid-ris canutus1�� )��)� ��-

171

�� 9"�� $�� 3 and 4 (annual cycles of BMR and immunity), I can investigate the correla-�� )��9-��5�� "�� 1��indices in different life cycle stages in stonechats as well. We have repeatedly measured the same individuals over the annual cycle. This gives me the opportunity to investigate the consistency ��(� ��)��(��/ �� $�� "��/(��(��0�#�� $��"�� $��"�� -tain within and among individual variance from a model including ��"�� $�� "�� "�� $�-��(� ��/&��(�� -��5� ��&��; See chapter 6�� &$�� $�� "��1�� ;��"�� $�� "��indices in Kazakh, European and Kenyan stonechats separately 5� ��&��1�� )��(��(� �� "�� (� �� /&�� (�� 0�#�� $�� -��"�� (��"��)��7��/��This means that in Kazakh stonechats the indices are not consistent within individuals. In European and Kenyan stonechats the repeat-� ��"��"��)�� "��"��)�� -��(��"��/�� $�� $�� (�� $�� measures over long time-spans (i.e. a year). Furthermore, the fact that )�� /��/�� $�� -mune assays over short (i.e. weeks) and long (i.e. a year) time spans shows that they are individual characteristics (Buehler et al. 2008c, Tieleman et al. 2010D�� &��).��)�)�� (��)�� $�� 3 and im-mune data from chapter 4��)�� )��7�$��/�� 9-�� "�� $��)��$ �(�� (��)�� not life histories and indices of immunity are constrained. If con-�� &��&$��/�� /(��"�� $-ter 2��$� �� &$��/��7�$��/��9-�� negatively with hemagglutination and hemolysis, the strongest cor-relations in chapter 2. Furthermore, I can compare the correlations

172

Ch

apter v

iii | Syn

th

esis

�� $��"��(��(��(��differently in response to selection pressures of different (pathogen-ic) environments (Horrocks et al. 2011). This potentially could have �� "�� $�� (� �� $��"� �� -�� %��(� ��(��the immune system. I investigate how hemagglutination, hemolysis, ��$�� "��E. coli and S. aureus are �� )��7�$��/��9-��(��(��/(��"��$� ��"�5<�� &��). I also investigate the �� "� �� $�� $�� -�� (�� $�� $� ��"� 5<�� &��). The results of this analysis show that correlations of the immune in-��(� "� ��)��"�� $��)�� $��"��<� ��&��$�� $ ��-� �� (�� )�� 7�$��/�� 9-�� (� �� )�� 70.33 (European x Kenyan stonechats) and 0.53 (Kazakh stonechats). Also within other life cycle stages, and within other immune indices, correlations are not con-�� $�� $$� �� /��$�� 2��(�� "�� "�� !��"��)�� $�� are also not consistent. Within Kazakh stonechats, the correlation ��)��7�$��/��9-�� (� �� )��-0.41�5 ��1��0.53 (spring migration). Similar variations can �� "�� 5<�� &��). ��/ ��/��$�� 2 that immune measures and ��7�$��/��9-�� #��"�� )�� $��and that environmental factors can select physiological traits, to a certain degree independent of each other.

Future directions: uncovering connections between physiology, ��

Life history traits (e.g. clutch size and mortality) are limited to a sin-��&��$�"�� 5�� 1��)��axis (Tieleman et al. 2004, Williams et al. 2010). The role of other physiological systems (e.g. the immune system) in the evolution of life history traits is still unclear. Physiology mediates the internal organi-0�� 5�� (�� "�� 1��(� ��-

173

R,

PR, K

P

R, EP

R, K

P

H

0.090.30

0.100.47

0.240.14

0.00

1.00

H

0.440.0

00.20

0.120.46

0.040.55

0.00

H

0.0

01.0

00.0

01.0

00.0

01.0

00.13

0.56B E.coli ,

0.580.0

00.24

0.150.68

0.00

0.430.01

S.aureus ,0.36

0.00

0.330.0

60.51

0.00

0.330.04

Included as covariate in the model is the tim



pling Included as covariate in the m

odel is age of the microbicidal stock solution

Table 8.1 – Repeatability of im

mune indices calculated for K

azakh, European and Kenyan stonechats

taken together and separately for each subspecies. Repeatability was calculated over the five life cycle

stages with variance com

ponents of a mixed m

odel including subspecies and/or life cycle stage and

covariates as fixed effects and individual as random effect.

174

Ch

apter v

iii | Syn

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esis

ment (Ricklefs and Wikelski 2002). Therefore, selective forces caused "� ��(� �� $�"��"�� "� � ��are likely to also affect the other (Figure &��). However, the evolution of life history traits may depend on a multitude of environmental factors and constraints among different physiological systems. I will give an example of how environmental factors and physiological sys-��%��(�� "�� "��For simplicity, I will assume that pathogen pressure and immunity ��"� �� )��$��/��)� �� (�� (� ��)��$��$ �� $ � � �"��a high investment in immunity to reduce the chances of sickness �� "�� "��"��"�� )�� (�� "�� $ �-��!� � �� (� ��)�� "��$��pressure that would invest little in immunity would have a reduced life expectancy (see also Figure &�� in Horrocks et al. 20111� ��;��)��(�� (�� $ �� )��(��"�� than diseases (e.g. as a consequence of cold temperatures in winter 5��(� ��1�� $ �� 7 ��5$�"��-��"D�� )11�� "��"� �� /��(��-munity depends on pathogen pressure in the environment (Horrocks et al. 20111�� (�� $ �� 56��S�1997). In this example immunity and life history are constrained, ��#�� )�� %�� "��(� �� other physiological systems. ��)��$$ ��)�� $�"��"��(�� "�� / ��approach is to include measurement of environmental factors -such ��(�� "��$ �� "��$ �� #��$��$ ��-sure- in evolutionary studies on physiology and life history traits. -�� (�� "� 5��"�1988, Doxon et al. 20111�� $ �� "� 5�� J�� -�� 1985�� and Lovette 2007), and predation risk (e.g. Page and Whitacre 1975, Martin et al. 20111��(�� "�� -�� /��4�� #��"� �� $ �-�� /��$�� -��"�� (��

02468

10he

mm

aggl

utin

atio

ntit

er

sping migration breeding moult autumn migration winter

0

2

4

6

8

hem

olys

istit

er

0.0

0.5

1.0

1.5

2.0

hapt

oglo

bin

(mg/

ml)

−40

0

40

80

120

E.co

li k

illed

(%)

0.5 1.5 2.5−200

−100

0

100

S.au

reus

kille

d (%

)

mass−specific BMR0.5 1.5 2.5 0.5 1.5 2.5 0.5 1.5 2.5 0.5 1.5 2.5

175

Figure 8.1 – Correlations between mass-specific BMR and the hemagglutination, hemoly-

sis, haptoglobin, and bactericidal ability against E. coli and S. aureus in subsequent life cy-

cle stages for three subspecies of stonechats and two hybrid lines. Kazakh stonechats are

represented by solid circles, Kazakh x European by grey squares, European stonechats by

white diamonds, Kenyan x European stonechats by grey triangles and Kenyan stonechats

by black triangles.

176

Ch

apter v

iii | Syn

th

esis

has the potential to evolve in response to its immune defence (Hor-rocks et al. 20111�� 7 �$ ��$ � -� �"� �� "� 7�� /��/�� "��#��)��7�� (��"�"��/��8�)�(� ��&��$ �� (� � �� )�"�� ;�� "�� "� �� $�� "�� -gists (e.g. cultivation, PCR, DGGE; West et al. 2008��Boersma 2011, Horrocks 2012D� ' �0� �� $� �� 1��+��)�"�� $�� (� �� )�� "�� $�� (West et al. 20081��$�� (�� 5��1��8�)�(� ��/�� -�)��$�� $-�� $� �� is pathogenic in different environments. This is a crude assumption �� !��)��"��$�� $�� (�� $��/�� $ �� $��&�� 7$�� #�(Troisfontaines and Cornelis 2005). These complexes, called type �� "�� =��)��&��(for a review of its function see Troisfontaines and Cornelis 2005, 9��#�� $�"�2010). Type III secretion systems occurs ��"�$�� "��"� ��(Troisfontaines and Cornelis 20051��-�� )��"$��secretion systems can help us compare pathogen pressures among �� (� ��+�� -��"� �� -��7�� $� �� 5��#��1��(� �� -� �� 58� ��#��2011). Once we have measured environmental factors, such as pathogen pressure, we can link them to physiological measures and life history traits. Also we ��&$� ��)� #�� "�� (� �� e.g. changing the pathogen pressure (Graham et al. 2011), and meas-ure the physiological and life history response of individuals. !��$$ �� )��$�"�� "�� )�� -� ��$�"��"�� )��/�� $� ��)�� (�� "�

Biotic factors -Food availability-Competition-Pathogen pressure-Predation risk-Etc.

Envi

ronm

ent

Org

anism

Constraints

Abiotic factors-Predictability-Temperature-Precipitation-Etc.

Life history traits -Clutch size-Longevity-Migration-Development time-Etc.

Physiology-Immune system -Metabolic rate-Endocrine system-Antioxidants-Etc.

177

Figure 8.2 – schematic representation of how environmental factors can shape

physiology and life history traits over evolutionary time scales. Environmental fac-

tors can select for physiological traits, which in turn constrain life history traits. For

example, in environments where food availability is generally low (e.g. deserts),

birds that have evolved a low metabolic rate, thus requiring little food, will survi-

ve better. However, having a low metabolic rate may constrain birds from having

a large clutch. Environmental factors can also select life history traits directly. For

example, in environments with high food availability, birds that have evolved a large

clutch size may have a higher fitness. However, spending a lot of resources on off-

spring may limit the resources that can be spent on self-maintenance, e.g. immunity.

Physiological systems also can constrain each other. For example, hormones can

influence immunity. Also, biotic environmental factors can evolve under selection

pressures from abiotic and biotic factors (including the organism itself).

178

Ch

apter v

iii | Syn

th

esis

� �� $��8�)�(� ��)��/�� "�� $��(��$��$�� -ity that immunity and life history traits are somehow constrained. �� &�� $�"�� "� ��-(��(��<� �� "�� "��$��understand the trade-offs and constraints within the immune system (Lee 2006), and the complexity of the immune system (Norris and Ev-ans 20001��!��/��"�� "��;��(�� $�� /�� "� ��$��(Demas et al. 2011). As a consequence, many methods are not easy to �$$�"��7��$�� &��$�� $��$��/�� 5��,��!D��2008). The methods we used in this thesis to measure constitutive innate immunity are $� �� "�� "�� )��$��-�� /�� $�� $��7�$��/�� -stances. However, the constitutive innate immune system consists of many more cells, proteins and peptides (Janeway et al. 2004), many of which are still unexplored in non-model species. Recently, new ��(�� (��$�� $ ��peptides. For example, Horrocks et al. (20111��(�� "�� $ ��(�� +(�� 5�#�� 2010). Besides clear-��$� �� $ �$� -�� 5� ��19981��+(�� "�� "� � �� $��(�� (�� (� ��5��1983, 1985, Giansanti et al. 2007). The method ��"�$� �� )�� $��$�� 7�$��/��$�� #��$� �� "�� (��to (comparative) ecological studies. 9�� "�� -ing measurements of the acquired immune system can give us new insights in the constraints within the immune system, and among physiological systems and life history traits. A recent study compares certain signaling proteins of the acquired immune system, the cy-tokine interleukin-6 (IL-61�� )��)�� $�$�� 5!��et al. 20101��6"��#�� "��cells, and are involved in fever and sickness response (Janeway et al. 2004). Adelman et al. (20101��$��"�� ,76

179

��$�� )��5��+� ��1988). IL-6 is released in the plasma upon infection, and concentrations of the molecule can ��(�� in vitro with this assay, using only a small plasma sample. IL-6� �� (��(�� $�� $�� -� �� $ ��(�� %�� -�� "� 5��(�� 1990). These properties of IL-6 make it likely ��"�$��"�� )�� $ ��-��"�� ;�� immunity will give us insights in how different arms of immunity are organized. This can help us understand how immunity and other physiological systems are constrained. Measurement of other physiological systems, especially those that $��"� ��#�� "�� $��&��"��"��$��"��#�� -��"�� "�� !��&��$ �� "�� 7 �� (��(��in aging and mortality, an important life history trait (Harman 1956, Beckman and Ames 1998). Free-radicals are produced during me-�� (�� "$��0�� $� ��#� �-�)�� "� � �� 5�$��#��2005). Also �� %�� $� �� &��(��(�� 59��#��!��1998). Some antioxidants (e.g. carotenoids, vitamin E; Puthpongsiriporn et al. 2001, Hughes 2001, McGraw and Ardia 2003) and free-radicals (e.g. nitric oxide; Sild and Hõrak 2009) are involved in the immune system as well. At the same time, some indices considered as part of �� "��(�� &�� $ �$� �� 5�� $�� D�Gutteridge 1987). These properties of the antioxidant system make �� #��"�� $ �(�� #�� )�� rate, immunity and life history. Measuring a wider range of immune indices and/or a multitude of physiological systems in closely related �$��)�� "�� "�� )��measurement of environmental factors, will increase our understand-ing of how physiology and life history traits are connected.

180

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202

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Fysiologie en levensloop eigenschappen��(�� #��(��)�� )� �� $�� =��)��$ ��-�� 0�=��(�� #��)��=�� $ �� 0�=��(�� \��)�� $�� #��$�� 0�� \��worden gekenmerkt door variatie in zogenaamde levensloop ei-��$$��,�(��$��$$��0�=��\(�� eigenschappen, waaronder fysiologische, anatomische en gedrag-seigenschappen, die in meer of mindere mate een directe invloed �� $� �(� ��(�� $ �� (�� (��$��$$�� 0�=�� (��(� )�� =��)�� =�� -��=#�� $ �� )� �� )�� #��)� ��$� �=�� 0�=��(�� \��(� ��4��#�� -tegie de hoogste fitness oplevert, en dus een evolutionair voordeel �� (�� \��)� ��(�� $�� (�� 9�(��#��fysiologie, gedrag en demografie de variatie in levensloop eigen-��$$�� $� #��-� ��,��#�)� ��=� ��]^�(��(� ��)��(�� (�� =#��(��$��$� �=�(�� =�� _�� (�� 0��#�� 8��)� ��=#�� maar ook andere levensloop eigenschappen - zoals levensverwachting 7��"��$$��7�0�� 7�� )�� $� (�� 9�(��)� ��-��=#�� (��(��$��$$��

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Roodborsttapuiten�� $��5Saxicola torquata1�0�=��#��0��(��=�� (� )�� (� �� (�� 0�\��!� �#�� #�� $ �� #��#��(�� (�� (� �� $�$��*� �� 0��-�� $�� 5S.t.maura1�� $�� $��(S.t.rubicola1�� 9 �� $��5S.t.hibernans) en de �� $�� 5S.t.axillaris). De verschillende popula-ties worden soms gezien als verschillende soorten, en verschillen van elkaar in morfologie, gedrag, fysiologie en levensloop eigenschappen 5� ��`��<�� 1��=#��(��(��$0��$��#�� $ �� (� ��$�$��( �� #��wanneer ze worden gekruist. Daarom worden ze ook wel gezien als �� $ �� (� )�=��#��#��$�� 0�� $�� #�� #��(� � �� (�� 0�=�� 0�#�� (� )��-�� #�� !��#��

K I E K

T niet trekkend gedeeltelijk, over korte afstand

korte afstand lange afstand

T () 0 0; 1200 1700 2600

A

het hele jaar deels hele jaar; deels februari-september

maart-midden oktober

begin mei - begin septem-

berA

1-2 3-4 2-3 1

A

3 5 5 6

U

afhankelijk vanhet regenseizoen

begin april tot augustus

midden april tot augustus

eind mei/juni

Tabel 1 – life history eigenschappen van roodborsttapuiten uit verschillende gebieden.

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g��-��+��! � �� !� �#��J�=�� 0�� #� ��)�� =�>>��(��a�� $�� $�� (�� $�� #�� 0�� $�� !� �#��)�� 8�=��b��c��(��#��d�� -$�� (��$�$�� #��)�� !� �#��(��$�$��(� )�� 9 �� - � ��$��c��]��(��#��d�� -�� $��0�=�� =�� J��$ �� `��$� �=�� b�als het eerste legsel mislukt, en leggen gemiddeld 3 eieren per legsel. +�#�� (� �� 0�� $�� $� �� -�� $�� +$� ��-�&� ��#� ��voor Ornithologie in Andechs, Duitsland, hielden ze deze vogels onder zogenaamde common-garden omstandigheden. Dit houdt in ��(�� 0��0�=��$�� )� ��8�� #�� =�� (� ��=�� (�� - �� (�� (� �� (��$� �� "�� -��$$��#�� #��0�=��(�� ( �=7��(�� $��populaties, komen ook tot expressie onder common garden omstan-�� $��$ �� #��0�=��0�� =�� $� �� (��b^�6�� =��(� �\ ��0��( �=��(�� $�� $��die ondervinden.

Fysiologie en levensloop eigenschappen: de aanpassingen van roodborsttapuiten aan verschillende omstandigheden.

��"��$$�� #�� (��$��$$�� -�� "��(��$��$$��(�� 0��+ ��#� �� (��(� )�� - ��(��=��$� �=�� $ �� (� �� 5@��(��.�� 1��+ ��(��(� )�� )�� =�� $� � =�� $ �� (� �� 5@��0��(��.�� 1��9�=��$ ��(�� #�� =$ ��( �=�� -

205

��( �=��=#�0�=��(�� (��(�� =�� (� ��#�� "��5�� corticosteron) en het immuun systeem met levensloop eigenschap-pen is minder goed onderzocht. Koppelingen tussen deze twee sys-�� 0�� =#��(� ��(��#�� 0��#�$$��0��0�� (��systemen en van levensloop eigenschappen die in de natuur voorko-�� #�� $� #�� 8�� =(�� )� ��)�� - �=#� �=�#��0��(��(�� (�� (� ��(��6� �� $�� =#�� =�� (�� _�(�� =#� ��=�� "��4�� koppelingen tussen fysiologische systemen de evolutionaire potentie �$� #��0�� =��(� )�� 0��"��(�� 5�� (�� $��1� ��0�� $�� =��als de relatie in (onder) soorten (het evolutionaire product).

Figuur 1: Gebieden waar roodborsttapuiten voorkomen, weergegeven in grijs. De pijlen geven de

trekafstanden weer van de ondersoorten die in dit proefschrift onderzocht zijn.

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g��#�b�� )�=�0��(�� -�"�� (�� $�� *��$�-��(�� $�� 7� ��Esche-richia coli, Staphylococcus aureus en Candida albicans te doden, hemagglutinatie en hemolyse van plasma en de concentratie hap-�� $�� )�� 59-�1��8�� /��-�� (� ��#�(�� =�� (�� $��.�7��)� ��gedaan in de thermoneutrale zone wanneer de vogel niet verteerd. �� (�� (� ��#��0��&$� ��0�=�� )�� $� ��(�� $�� #�b�staan in contrast met wat we zouden verwachten vanuit de theorie dat �$� #��"��$$��(�� (�� $� #�� $� #�� (�� -vensloop eigenschappen die we terugvinden in de natuur: correlaties �� (�� "�� -lische eigenschappen op het niveau van individuen verschillen van de correlaties op het niveau van ondersoorten. Dit doet ons vermoeden ��(�� )�� =#�� (��(��7�� 7�� "��$��(� (�� 0��#� �� )�� #�#�� (�� (��omgevingsfactoren op fysiologie en levensloop eigenschappen.��#�c��]�� 0��)�=�)��(��(��0��-(� �� =#��(�� $�� "��8�� (� ��#�(��(��(� �� (� ��0��(��=�� "��5 �(��)�� 0�-�� 1��#�c�� )�� (��0��seizoensvariatie onderzocht, door BMR van Kazachstaanse, Europe-�� $�� )��" �� (��-��$�� (�=��(��=�� =#��"��*�)�� (�� =�� #�� =�� #��9��(�� -$�� =� �� 0�� 5b^�6�� (� �\ ��1�� )��#� �� $�� $��-�� =�0�)��(� �\ ��$� �� (� �\ ��0��$� �� (��0�� $��)��=#��$� �� ( �=� ��(�� $�� $�� (��-��9-��(�� (� ��0��$�� 8" �-

207

�� =��)�� )�� van de twee ondersoorten waar ze van afstamden inlagen. Tempera-�� _�(��)��(��9-�� $�� seizoensvariatie. De resultaten van dit hoofdstuk duiden erop dat er een genetische achtergrond is in seizoensvariatie, maar dat deze niet �� (� � ��9�(��=#��0��(� �� -��(��)� �� _�(�� $� �� #�]�� )�� 0��(� �� (�� "�� 0�� 0�� $�� #�c�� "��( �=��(��(��0�� 0��(� �� #�)� ��(��"��(� 0)�#�� =�� =�� "��)�� (�� \�� $ ��)� �� -steed aan veeleisende levensloop eigenschappen zoals reproductie of trek. De verklaring van dit fenomeen wordt wel gezocht in trade-offs �� (��=�� "��7��$$�� #��#��-0��)� ��(� ��$�� #��+��=�� =#��(� �-atie in het immuunsysteem ook een genetische achtergrond heeft, en dus in een evolutionair perspectief gezien kan worden, is niet �#�� (�� $�� #�� 0�� (� �� (�� (� �� (��$� ��-genschappen. Als het immuunsysteem een genetische achtergrond 0�� (� )��)�� (� �� -0��$�� )�� 0��$�� 0�=�� 4�� (�=��5��(��E.coli en S.aureus, hemagglu-��"��$�� 1�(�� "�� )��" �� =��(� ��$� �� #��(� ��0��(� ��(�� (��(�=��4�� #�(� ��(�� " �� (��#� ��)�� (��" �� )�� (�� )�� =� �� -��$�� =� �� (� �\ �� $� �� 0�� )��(��(�=�� (� �� $�� =��$� �� 0��0�� 0��(� ��(�� heeft, maar dat de overerving complex is. De complexe overerving ��0��(� ��=�� #��)�=�� #�� $��&��(�� $ ��

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g4�� =��=#�0�=�� =��0�� #-#�� $�� (� � �� trekken de grootste verandering in immuun maten zien, en de rood- � ��$�� =�� $��0��$��#� ��=(��(� �\ �� 0�� #��)�� =��=#��=�� "�� (�� "�� _�(��)� �� "��-�� (��$��$$��*�9�(�� =#��=�� "��$��0�=��$�(� )��(� ��(��-toren, zoals pathogenen druk. ��#�d�� )��(�� (� - ��#� �=� �� $�� 0��4�� indirect de invloed van nucleaire en mitochondriale genen op BMR te �� 0��#�� 9-��)� ��)�� (��(� �� (�� (�� (��-�� \�� (� ��)� #��(��-� �\��-�� \��0�=�� =#�� (�� $��genereren van energie. In het proces van opslag van energie worden $�$�� #��)�� (�� 0�)�� als in het nucleair DNA liggen. Het nucleair DNA wordt doorgegeven �� (�� )�=�� !��0�=��(�� $�#��(� � ��+�� $��9-�� - �� (�� )�� _�(��)� �� -�� !�� )�� "�(��9-�� $�� $�(��#)��(�� "�(��-��$��(��"$��$�)�� $��)� �� (� � (��(� �� $��)� �� (��+�� #�� =�� -��(� �� (��(��=��-�� $�(�� (�� $�� )�� "�(��9-�� #��0��)��ae�K�� (�� )�� )��7�� 9-�� (�� "- �� $�� $��0�� $�� $��(��0�� -�� " ��)� �� (� ��(�� (� �� $��)�� (��/�� (�� (� ��5 �(��" ��0�� $�� )� ��-derverdeeld in een groep met Kazachstaanse moeders en een groep �� $�� 1�� !�� \�� =#�� $�� $��(��9-��0��)��(� )��-

209

chaamsgewichts-gecorrigeerde BMR van de nakomelingen het meest ��=#��$�� (�� !�� invloed heeft op het lichaamsgewichts-gecorrigeerde DNA, zouden we verwachten dat het BMR van nakomelingen tussen dat van de ou-ders in zou liggen. Onze resultaten lieten zien dat lichaamsgewichts-gecorrigeerd BMR niet tussen dat van de oudersoorten lag en ook niet op dat van de moeders leek, maar in plaatst daarvan het dichtst �=��)�� (��(�� $�� !�� !��(� ��)�� =#��(�� 9-��4�� =��=#�� !�� =��9-�� " ��twee soorten DNA. ��#�a�� =(��)��)��(��(��(�-duele eigenschappen op variatie in BMR en verdamping (Total Eva-$� ��(��4�� ,��4,1��4�� )�� (�� #� �� 9-�� 4,� ��4�� 0��)�� (�� (�� =�� #�� )�� $�9-��4,�)��+�#�� )�� 0��)��#��(��(� ��verklaard kon worden door het individu, met andere woorden, welk �� 0��#��)� �� (�� $�� 9-��(��)� �� _�(�� =�� #�� (��0�)��(��)� �� _�(�� )��ccK��a^K�(��(� ��9-��)� ��(� #�� (� �� (��,��=�� #��-)�� (��$�(� ��4,��-(��$�� $�� #� f� �� )�� 0�� # �� $�� $��&� ��#�0�=��(�� 0��#��(�� immuun maten. Het immuunsysteem is een multidimensionaal sys-��_�� 0�=��0�=�� 0�� -�� # �=�� (�� "�� (� �� -��#�� $ �� =#��+��0�� (��)� �� (��#�� #��#�� (��(� �-ate statistische technieken, die relaties tussen meer dan twee maten �� (� ��#�� 0�� #��)� �� (�� #��$��)��$$��(�#�� )�� ##��=#�� #$ ��(��(� # �=��(��0�� #��(��#�� #�(��(��#�� -

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gsets, en dit zorgt ervoor dat voorzichtig omgegaan moet worden met de interpretatie van de resultaten van deze multivariate technieken. 4�� )�� $� �� (��-��-��5b^^a1��9�� 5b^^g1�� $��(��#�b��$��)��"�� -�� (� ��=#�� (�� (� �� =�� =#��(� �� (��4��#�� #�(��-tivariate technieken en met simpele statische technieken zoals cor- �� )�� (�� #�� (� ��#��4��(��$��#�� =� �� $�van hoe de immuun maten op verschillende niveaus met elkaar ver- ��0�=�� )��(�� =#�consistent correleren met elkaar op individueel niveau, maar dat deze �� 0�=��$�� (��(�� #�=#��5 �(��(�� 1��

Onderzoek naar fysiologie en omgevingen��$ �� )��(� �� "�� 0��)�� 0�=�� =�� "��"��$$�� Gedetailleerd onderzoek naar hoe fysiologische eigenschappen zich (� ��#�� 0��#�� =� �� $��(� ��0�� (�� (�� (��$� ��$$�� _�(�� $ �� #� �� (�� "��gemeten, maar het immuunsysteem is veel groter. Zowel het aange- � �� (� )� (�� "��#�� (�� worden in mensen en inmiddels in sommige dieren. De technieken �� (�� #��)� ��0�=�� (��#�� 7�$��/�#��)��(� -��=#�� 0��#�0��#�� =#��+�#�0��)�� "��"�� #�� ##�� -0��#��9�=(�� &�� 0�� #�#�� (� �� (� ��#��"�� "�� -tingen van antioxidanten zouden we verder kunnen komen in het �� =$��(��0��$$��0��#�� (� ��0��\(�� 0�=��)��0��)�� (��(�� 0�� -��# �� (��(��$ �� #��$�� #��met de evolutie van fysiologie en levensloop eigenschappen kunnen

211

�� 0��#��9��# �� (��(��$ �� #�0�=��(� �� =��(��#��=#��-��#�� #�� (��#��$ � �� #� ��)� �� #�� #�� de immuun-ecologie, waarmee de verscheidenheid aan micro-or-ganismen in omgevingen gemeten kan worden. Dit wordt gedaan �� (� �� (�� 5�� $�van technieken zoals PCR en DGGE) de hoeveelheden verschillende �� !�� #�� (� ��=#��8��(��#��=#��$�� (��-��=#�� 7� �� $��#�� #��)� �� $��)��5�"$�� "��1��Metingen aan meerdere aspecten van het immuun systeem en/of een verscheidenheid aan fysiologische systemen in gerelateerde soorten of ondersoorten met verschillende levensloop eigenschappen, ideaal ��0�� (�� 0�� $�(�� (��"��$��(��(��(��$��-schappen vergroten.

212

DANKWOORD

8��)��#��(��(�� 0��#� ��)��(� ��=#��(��0�� =#��$ �-��7�� 0��#�� 0�� $�(��.�� -ders, vrienden en familie.�� )��#�� #��*��#� ��#� ��$ �=��=��)��$�� 0�� =�=��=�� 0��#� ��=(��$��##�� (�� 0��#� ��#�#��#�)�� =�=��$ ��7�� 0��#��)��#��)�=��#��$��)��(�� )��$$��=#��)� �� =�� 0�=��=#��)��(�� =��(�� =�� $�� (�� =�(�� -�� #�� (�� )� #�� #� �=�=��#� ��# �� (�� =�� #��(� �� #��#�=#�� #��5��1��=��#)��+�#�)��#�=�� #��(�� =��0��-�� )�=��=��=#��0��#�)�� (�� =��#��0��5��=�� # �� 1�� #� �� =��#��=�=��=��)� #�� )�� )��)�� 0��#�� =�� )�� 0�=�� )�� (� (��=�=�� -��$��2(� (�� 3��#�� (�� #� �� ##��=#� �� )�� -0��#��$�� =�� 0��#��#� �� =��=��#��)�� =��=��$ ��#��0�=��#�(�� 0� ��)��=��_�� )��#��)��=��/��\�� =�� #)��=�� =��#�� (� ��=�� 0��#��)��(��vragen hoe het ging.

213

-� �� #�� =��#��#�� )�#��$��++�#)�� $� �� #�� 0��=��=�� -�� ( ��(� ��=�� $� �� (� 0��( ��=�� =(� �=��#��-)�� 0��)�� (�� 0�� =�=� �� #�� )��#=��)�� ++��#��0��=�=��)��(��$�� =��#��(�� =��( ��=#��$�� =��#��4� #��$��++��=�=�� $��0�� =��$ ��7�� 0��#�)�� (��#�=��)��h

4�� =�� 7� ��$�52�� #�� $3�� 2�� $3�� )�� 2��-man”). Although Irene is the engine of team Tieleman, it consists of �� $��$��(�� "��)�"�� )��&$� ��7�� $��;��)��"�� "�� !�+.��6��<��"�� )��"��thanks for writing an article together, that is now a chapter in this ��5�� $�$��1��=�"��7��conversations on skype and your visits to Groningen. You are always )��"��"��5��"�� $��" �$1��,��"��)� ��2�� 3��#�� /��in Groningen and on Schier, and for the Portuguese marmelada (my favourite). Nick, Arne and Liz, you started as PhD-students at more or less the same time as me. It is good to have people around you that � �� "��(��=�"��)� #�� /��5��)��/��1��"�� 7�� #�$ �=��)��! �� (� ��=�"��(�� 52� ��#��31�� ,�0�� $��"��=�"� "�� 7$ �=�� 6��#�� #�� $� ��It was nice to know that I was not the only one working crazy hours, and struggling with the last hurdles. I am really proud that we can defend on the same day, and am looking forward to the defence (and �� $� �"� �� )� �1��8�� "� �� $�� )�� 2��)� ��3�� $�� "��)��8�� "��=�"��"�� (��(��you as a part-time roommate. Stephanie, I am looking forward to �� "�� J� ��<��$ �=��(�� )�� "��)� ��"� �� $� ��"��7$ �=��

214

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��"��)� ��9�� "�� )�� /��"��)� ��@ ��.��#�� 0�� $��or further away (Hilvesum, Paris, Bermuda, Riga, Berlin), good food 5�� /�� $��)��)�� >��)��(� "��#�1�� 5�� -diso, End of the Road). !�� "� 5�� 9�+1� �� $�� 9� � �� 6�� 6� �� -� ��=�� "�� 8�� 5�� 7� 1�� /��-� ��#��5��#�� $�)��(� �� 7�� 1��6� ��!��#��6�� #��5 �� 1�A(��Almut, Götz, Jildou, Sander, Jan K., Jan vd B., Christiaan, Maurine, Jeroen, Joyce, Richard and Marion (if you need a house- and garden-�� "��#��)�)�� /��1��-� ��,��-��#��5��$��$�� 1*��#�� /��$�� #��

'�� $��=� �� #�� #� ��$ ��van de cursus ecologische interacties gegeven. Hoewel het strikt ge-0�� =��=��$ ��7�� 0��#�� =#��)��(�� =��)�##��#�� (�� -��- �� =�� $�� #�� 0�#� �� #��)�� #� ��0�� =�� =#��/�� =#��)��$��(��)�� # �� (�� =�=� �� #�� (�� $ ��0�=��(��(�� )��#� ��#�� =�� )��-��=� �� =�� $�(��=� ��)��-� ��=��8��-$��=�� #��$��#�=��)��9�=��$ �� #�(�� #�(�� $� �� )��-�� #� �� =#��'� ��8� �� '� � ��+(� #��$��#� ��#�=��(�� #� �� $� �-meter stuk was, en ik snel een oplossing nodig had. Gerard, dank ook (�� =��&$� �� #�(��$$� �� (��

�� )� #��$ �=��'� ��"��)��#��$��$�� !��*�9� � ��4��-��!�� >��8�� 4�� #� "�� 9� � �� "��

215

)� �� $$� �� $ ��)� #�� -�� ) ��$��)�"��=�"��"��at conferences, and getting your (always positive) emails. I wish you ��(� "��'��)�� 4��#��Z �� Z�0��5�� 1��Living in the guesthouse was a lot of fun. Thank you Elli for all the midnight conversations, Irish coffee in Herrsching and drinks in �� $��)��"��h��#��!�� >��-� ��-��Sophie, Maude, Dieter (your Reh und Hase were always spiced with �� 1��"�(��8��#��$��$��)� ��=��$��-�� #��$��)��=�"� �� $� ��#��$� �� $ �=��)��(��&��)��*� ��')�� !��(� ��him I think I would have liked him.

� ��7�� 0��#� �� =�� ##��=#� �� #� �� (��gehad aan de mensen die me lieten zien dat er ook andere dingen )� ��)��$��#��=�=�� #��=�=��!��0��##� �$�$�� =�� #�� =��-��8��=��=�� =�� #��$ ��(� �)� #��(��#��=��#��=��muziek of op reis gaan. Ik hoop dat we nog veel dingen doen samen. -�0��#��#�� %��#�#�� #��0�#� ��=��#�=��)��< >�� < ��#=��5�� -��1��#��-� =��6� "�� #��(�� -��0��#��$��0�� #��-��(��=��5��(��-=��1��#��(��-� =��)� ��#��=��(��)�� #��#� =��)��#�(�� #��)��(�#��6� "��!�#��<� �� /=��)�-��#��=�� =�=��#��#��$$�� <��&��=��)� ��5��0�=�1��=��(� ��(�#�� #��$��#��(��#��#��#� �� =��=��)�� =�)��>��#�(�� #� ��#��!�� =�=�� =(��slapen als ik vroeg in de ochtend een vliegtuig moest halen. Bert en ,��#�(�� #��#��4��0�=��-��)��/=��#��=��(�� =�=��#��$�)��(��)� #�� #��#�=��)��(�� )� $��(��=�� #=�� ##��=��#�(�� )�=�� #��#�� =�� #� �� =��#�� "�

216

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�� )��)��#�� #�� #��( �� #��#�� )��)��#��#��$��)��#�� (��#� ��=(��zien, ondanks dat we iets verder van elkaar wonen.-�=�� =�� (�� (�� )�� #� ��#��)��#�=��)��#�(�� =��(� � ��)�� )�� #�� "�� #�)�� =��#� )�� $� �0��#� #)�� )� #� ��=�� $ � �� )��#�� 8�� 0� �� =�� (�� #� ��$�� 0�#� � ��(�� =�� -� ��=�� =#�9 ��=��/=��=��0�� =�)��-� ��=��#�(�� $��=��$�� =� �� $ �� .�� (��$��$��$��#��0��)�##��7�� $��$�� =$��#�=��)��h��)��$��#�� =�� #�=��)��(�� )��0�=��8��$��=�� )� ��#� ��#��$�9 ��=��$��)� ��(�� !��0�=�� )��#��#��)��)� #��)��$ ��#�=��)��=��0�.��( ��=#��=�� 9 ��=��

<��"��)��#�� (�� "�$� ��"�$��You two are the people I want to have around me when I am very �� (��)��

218

LIST OF AUTHORS

�� -��9�� *��(� ��"�� "��+�� -�-seum, 100 Queen’s Park Circle, Toronto, M5S 2C6, Canada.

�� *�-�&� ��#� �� + ��"�� -hard-Gwinner-Straße, Haus Nr. 7, 82319 Seewiesen, Germany

Anthony Fries: Ohio State University, Department of Evolution, Ecol-ogy, and Organismal Biology, 318 W 12th Avenue, 43210, Colum- ��!�

8��,��'� �*�+��(� ��"��$� ��(��-ogy, and Organismal Biology, 318 W 12th Avenue, 43210, Colum- ��!�

� �� ')�� †*�-�&��#�� + ��"��7�� 7Tann-Strasse 7, 82346 Andechs, Germany.

9� � ��8��*��(� ��[��0��<�� 9��778457 Konstanz, Germany. University of Glasgow, Institute of Biodiversity, Animal Health and Comparative Medicine, Graham Kerr Building, G12 8QQ, Glasgow, UK

��$��;�� *�-�&��#�� + ��"��7�� 7��7Strasse 7, 82346 Andechs, Germany.

,�0��"��*��(� ��"��9 ��6�� 4200-6270 Univer-��"�9�(��(� ��6T 1Z4, Canada.

Kevin D. Matson: University of Groningen, Centre for Ecological and Evolutionary Studies, Centre for Life Sciences, PO Box 11103, 9700 CC, Groningen, The Netherlands.

�� )� �*� -�&� ��#� �� + ��"�� 7Gwinner-Straße, Haus Nr. 6, 82319 Seewiesen, Germany.

219

B. Irene Tieleman: University of Groningen, Centre for Ecological and Evolutionary Studies, Centre for Life Sciences, PO Box 11103, 9700 CC, Groningen, The Netherlands.

-��#��!�� *��(� ��"��' ��6�� and Evolutionary Studies, Centre for Life Sciences, PO Box 11103, 9700 CC, Groningen, The Netherlands.

Joseph B. Williams: Ohio State University, Department of Evolution, Ecology and Organismal Biology, 318 W 12��!(��6�� 43210, USA.

220

LIST OF PUBLICATIONS

Buehler, D. M., M. A. Versteegh, Matson and B. I. Tieleman. 2011. +��$ � ��"��*��$��$$ ��$��-ravel the complexity of the immune system in an ecological context. Plos One 6: e18592

Tieleman, B. I., E. Croese, B. Helm and M. A. Versteegh. 2010. Re-$�� "� �� (�� "� �� Comparative Biochemistry and Physiology – Part A 156: 537-540.

�� 6 ��#� �� 6�� 8� ��#��M. A. Versteegh, J. Komdeur, B. I. Tieleman, K. D. Matson. 2010. Effects of immune enhancement and immune challenge on oxidative status and physiol-ogy of Homing Pigeons (Columba livia): implications for ecologists. Journal of Experimental Biology 213: 3527-3535.

Tieleman, B. I., M. A. Versteegh, A. Fries, B. Helm, N. J. Dingeman-��8��,��'� ��9��4��2009. Genetic modulation of energy �� Proceedings of

the Royal Society B: Biological Sciences 276: 1685-1693.

Tieleman, B. I., M. A. Versteegh, B. Helm, N. J. Dingemanse. 2009. Quantitative genetics parameters show partial independent evolu-�� "�$�� "�� different populations. Journal of Zoology 279: 129-136.

Versteegh, M. A., B. Helm, N. J. Dingemanse, B.I. Tieleman. 2008. ��$�� "� �� (�� (�$� ��(��)�� *��"�� $��-chats. Comparative and Biochemical Physiology – Part A 150: 452-457.

Reneerkens, J., M. A Versteegh, A. M. Schneider, T. Piersma, E. H. Burtt Jr. 2008. Seasonal changing preen-wax composition: Red Knots’ (Calidris canutus1�%�&� �� 7�� V�The Auk 125: 285–290.

Versteegh, M.A., T. Piersma, H. Olff. 2004. Biodiversity in the Dutch 4��*�� ;�� (��-�� /�� De Levende Natuur 105: 6-9 (in Dutch with English Summary)

university of groningen physiology in a life history ... · geog raph ical and seasonal variation...

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