origin of the taxa examples of protista topic 6 bot 3015 bill outlaw, instructor
TRANSCRIPT
Origin of the TaxaExamples of Protista
Topic 6 BOT 3015
Bill Outlaw, Instructor
Lecture Outline (a)
Chronology of life and life processes on EarthPossible origins of the proto-eukaryal cellEndosymbiosis and other methods for non-vertical gene transferMorphology and function of chloroplasts16(18)S rRNA sequence analysisGreen AlgaeRed AlgaeHeterokonts (Brown Algae and Oomycetes)
Lecture Outline (a)
Chronology of life and life processes on Earth
Possible origins of the proto-eukaryal cellEndosymbiosis and other methods for non-vertical gene transferMorphology and function of chloroplasts16(18)S rRNA sequence analysisGreen AlgaeRed AlgaeHeterokonts (Brown Algae and Oomycetes)
Chronology (a-1)
4.5 Earth Formed (Universe ~13 billion years old; Solar System ~ 10 billion years old.)
4.5-3.8 Earth Inhospitable (Asteroid impacts/heat would have destroyed any organisms.)
3.5-3.8 Appearance of the First Organisms (Non-photosynthetic prokaryotes; insignificant atmospheric O2.)
3.5 Appearance of Oxygenic Photoautrophs (debatable) (Oxygenic photosynthesis resulted in atmospheric O2 increase.)
2 Rise of O 2-rich Atmosphere; Evolution of O 2-respiring
Organisms (10-15% O2 only at this time; reached present levels by 0.8 BYBP)
BYBP EVENT
Chronology (a-2)
4.5 Earth Formed (Universe ~13 billion years old; Solar System ~ 10 billion years old.)
4.5-3.8 Earth Inhospitable (Asteroid impacts/heat would have destroyed any organisms.)
3.5-3.8 Appearance of the First Organisms (Non-photosynthetic prokaryotes; insignificant atmospheric O2.)
3.5 Appearance of Oxygenic Photoautrophs (debatable) (Oxygenic photosynthesis resulted in atmospheric O2 increase.)
2 Rise of O 2-rich Atmosphere; Evolution of O 2-respiring
Organisms (10-15% O2 only at this time; reached present levels by 0.8 BYBP)
BYBP EVENT
Chronology (a-3)
4.5 Earth Formed (Universe ~13 billion years old; Solar System ~ 10 billion years old.)
4.5-3.8 Earth Inhospitable (Asteroid impacts/heat would have destroyed any organisms.)
3.5-3.8 Appearance of the First Organisms (Non-photosynthetic prokaryotes; insignificant atmospheric O2.)
3.5 Appearance of Oxygenic Photoautrophs (debatable) (Oxygenic photosynthesis resulted in atmospheric O2 increase.)
2 Rise of O 2-rich Atmosphere; Evolution of O 2-respiring
Organisms (10-15% O2 only at this time; reached present levels by 0.8 BYBP)
BYBP EVENT
Chronology (a-4)
4.5 Earth Formed (Universe ~13 billion years old; Solar System ~ 10 billion years old.)
4.5-3.8 Earth Inhospitable (Asteroid impacts/heat would have destroyed any organisms.)
3.5-3.8 Appearance of the First Organisms (Non-photosynthetic prokaryotes; insignificant atmospheric O2.)
3.5 Appearance of Oxygenic Photoautrophs (debatable) (Oxygenic photosynthesis resulted in atmospheric O2 increase.)
2 Rise of O 2-rich Atmosphere; Evolution of O 2-respiring
Organisms (10-15% O2 only at this time; reached present levels by 0.8 BYBP)
BYBP EVENT
Chronology (a-5)
4.5 Earth Formed (Universe ~13 billion years old; Solar System ~ 10 billion years old.)
4.5-3.8 Earth Inhospitable (Asteroid impacts/heat would have destroyed any organisms.)
3.5-3.8 Appearance of the First Organisms (Non-photosynthetic prokaryotes; insignificant atmospheric O2.)
3.5 Appearance of Oxygenic Photoautrophs (debatable) (Oxygenic photosynthesis resulted in atmospheric O2 increase.)
2 Rise of O 2-rich Atmosphere; Evolution of O 2-respiring
Organisms (10-15% O2 only at this time; reached present levels by 0.8 BYBP)
BYBP EVENT
Chronology (b-1)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Chronology (b-2)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Chronology (b-3)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Chronology (b-4)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Chronology (b-5)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Chronology (b-6)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Chronology (b-7)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Chronology (b-8)
BYBP EVENT
2.2 Appearance of Eukaryotes
0.9-1.3 Appearance of Sex
0.7-1.5 Appearance of Multicellular Organisms
0.5-1 Appearance of Large Eukaryotes
0.5 Appearance of Plants ([CO2] ~ 15x present.)
0.3 Appearance of Seed Plants ([CO2] ~ present, result of photosynthesis.)
0.14 Appearance of Angiosperms
0.003 Appearance of Humans
Schopf and His Fossils
Microfossils (~3.5 BYBP, Australia)
Lecture Outline (b)
Chronology of life and life processes on Earth
Possible origins of the proto-eukaryal cell
Endosymbiosis and other methods for non-vertical gene transferMorphology and function of chloroplasts16(18)S rRNA sequence analysisGreen AlgaeRed AlgaeHeterokonts (Brown Algae and Oomycetes)
Origin of the Major Groups (a)Bacteria, Archaea, Eukarya
1. An unknown protobiont evolved two lineages—one leading to Bacteria and a second leading to the progenitor of Archaea and Eukarya. Or, . . .
Credit: Andrew White, Staffordshire University, UK
Origin of the Major Groups (b-1)Bacteria, Archaea, Eukarya
2. Bacteria and Archaea arose (either independently or from a single unknown ancestor). A single Bacterial cell fused with a single Archaeal cell, creating the proto-eukaryal cell.
Bacterium Archaeaon
?
Whole-cell Fusion
Proto-eukaryal cell
idea from Lynn Margulis
Origin of the Major Groups (b-2)Bacteria, Archaea, Eukarya
Bacterium
**Membrane lipids
**Many/most cytosolic metabolic pathways (e.g. glycolysis)
Archaeaon
**Transcription/DNA compaction
**Translation machinery
**ATPases (except organellar)
**Many enzymes
Whole-cell Fusion
Origin of the Major Groups (c)Bacteria, Archaea, Eukarya
Summary
Both explanations are essentially based on inferences from present-day organisms. Both explanations have strong advocates.
Interpretations must have reservations. (For example, whole-cell fusion, a common ancestor, or lateral gene transfer could account for a trait in Eukarya.)
Lecture Outline (c)
Chronology of life and life processes on EarthPossible origins of the proto-eukaryal cell
Endosymbiosis and other methods for non-vertical gene transfer
Morphology and function of chloroplasts16(18)S rRNA sequence analysisGreen AlgaeRed AlgaeHeterokonts (Brown Algae and Oomycetes)
Phagocytosis as a means of horizontal gene transfer.
PNAS 100: 7419
In part, as a lead-in to endosymbiosis . . . .
Basic Outline of (Primary)
Endosymbiosisusing the plastid as
an example
The bulk of evidence (more later) indicates that all chloroplasts resulted from a single primary endosymbiotic event (=monophyletic origin of plastids).
In virtually all ways:
chloroplasts = mitochondria = bacteria
Basis for the Endosymbiosis Mechanism (a)
**size
**ribosomes size & sensitivity antibiotics (implying homologous function)/translation
** . . . and other features such as bias towards certain lipids in membranes
**DNA packaging/transcription
**. . . and, as expected, all the above being in agreement with sequence data (more later)
In virtually all ways:
chloroplasts = mitochondria = bacteria
. . .but they are not identical:
Basis for the Endosymbiosis Mechanism (b)
**DNA-containing organelles are only semiautonomous For example, a chloroplast may contain ~100 ORF, but requires ~1000 polypeptides for function. (Some of the missing genes were transferred to the nucleus and some—being redundant with those of the host—were lost.)
** loss of function/features (e.g. cell wall) is the rule (again, a reason for loss of genes).
The details . . .
Endosymbiosis—The devil is in the details.
**all chloroplasts are not the same. (more later)
**all mitochondria are not the same. For example, the typical mammalian mitochondrial genome has only 0.017 MB, but those of some plant mitochondria have up to 2.5 MB.
Secondary Endosymbiosis
At least three separate secondary endosymbiotic events led to plastids in different groups of algae. Some odd algae even have two kinds of chloroplasts—either from tertiary endosymbiosis or serial acquisition of chloroplasts.
Endosymbiosis—Summary and BOT 3015 Focus
Primary
Secondary
Green Alga/Plant
Red Alga
Cryptomonad
Heterokont
Expert opinion, but not inclusive of all opinions.
The historical way to think of gene transfer is vertically:
1. Asexual (e.g., division of a single-celled organism to form twodaughter organisms by mitosis)2. Sexual (i.e., formation of gametes followed by syngamy)
Gene transfer . . . Summary (a)
In this historical way of thinking, gene transfer is linear. One can thus construct a tree in which there are unambiguous lines of descent.
---------------------------------------------------------------------------“Life” is not so simple because of horizontal (=lateral) gene transfer.
Mechanisms for horizontal gene transfer:
Gene transfer . . . Summary (b)
**conjugation, phagocytosis, & endosymbiosis (as shown earlier)
** bacterial transformation (=uptake of naked DNA). Natural (complex cell machinery required) and artificial (e.g., by treatment with membrane-permeabilizing agent); more later
** bacterial transduction (gene introduction by virus)
** “Transformation” is used broadly in most genetic engineering literature to mean a stable change in genetic potential. In plants, e.g., introduction of a novel gene is usually accomplished by (a) transfer of a gene via a recombinant plasmid from the crown gall bacterium, Agrobacterium; (b) biolistics (“gene gun”); electroporation or chemically induced membrane pores; (d) microfibers (stabbing cells with gene-coated fibers.)
How important is gene-by-gene horizontal gene transfer in evolution?
Gene transfer . . . Summary (c)
**central force of evolution of many different prokaryotes.
** occurs across domains
** role in eukaryotes less certain, but evidence is accumulating in some groups, particularly phagocytotic algae. (E.g., in one study, 21% of nuclear genes for plastid-targeted proteins were derived by horizontal gene transfer.)
Lecture Outline (d)
Chronology of life and life processes on EarthPossible origins of the proto-eukaryal cellEndosymbiosis and other methods for non-vertical gene transfer
Morphology and function of chloroplasts
16(18)S rRNA sequence analysisGreen AlgaeRed AlgaeHeterokonts (Brown Algae and Oomycetes)
Chloroplasts are one kind of plastid
Green Algal and Plant Chloroplast
PS II (LHCII with chl b—regions of membrane appression)
PSI & most ATPase
Calvin Cycle & Starch Storage
Two limiting membranes
Chloroplast Types (a)
Red Algae(most similar to Cyanobacteria)
Green Algae & Plant (share recent common ancestor)
Secondary Endosymbiosis(Both these particular examples result from engulfing a Red Alga)
Brown Algae (and others) (example of heterokont & meiotic gametogenesis)
Cryptomonad (convincing example of surviving nucleomorph)
Proximal Chl a-complexTwo types of chl a-binding proteins (also carotenes); role is to harvest light and
transfer energy.
Organization of PS II light-harvesting pigments
Three types of antenna complexes involved in light harvesting.
Reaction Center ComplexA few Chl a, other electron-transfer reagents, 5 proteins;
role is charge separation.
Core Complex =The above two complexes—sufficient for photosynthesis. Essentially the same in all
photosynthetic eukaryotes.
*** phycobilisomes,cyanobacteria and red algae*** LHCII (chl a/b binding), plants & green algae
*** fucoxanthin/chl a/c complex, brown algae
Organization of PS II light-harvesting pigments
Three types of antenna complexes involved in light harvesting.
*** phycobilisomes,cyanobacteria and red algae
Extrinsic (little proteinaceous knobs on membrane); no lateral heterogeneity in thylakoid membranes; associated with linear pigments (phycocyanin and phycobilins)
Integral complexes. No lateral heterogeneity in thylakoid membranes.
*** fucoxanthin/chl a/c complex, brown algae
*** LHCII (chl a/b binding), plants & green algae
Integral complexes that migrate between photosystems to balance light, thus stacking and unstacking thylakoids. (Recall, stacked and unstacked regions have different functions.)
Lecture Outline (e)
Chronology of life and life processes on EarthPossible origins of the proto-eukaryal cellEndosymbiosis and other methods for non-vertical gene transferMorphology and function of chloroplasts
16(18)S rRNA sequence analysis
Green AlgaeRed AlgaeHeterokonts (Brown Algae and Oomycetes)
Plastidic and other 16S rRNA phylogeny
18S rRNA phylogeny
Plants and Green Algae
Animals and Fungi
Phototrophic & Heterotrophic Heterokonts
Summary of Relationships
***Chloroplasts have a monophyletic origin (All plastidic16S rRNA sequences more similar to each other than to any extant cyanobacterium; gene clusters in chloroplasts similar to each other but different to cyanobacteria; similarity of protein import machinery)
***The eukaryotic portions of heterokonts share a common history, regardless of whether photosynthetic or not (morphology, 18S rRNA sequence, much more)
***Fungi and animals share a “recent” common ancestor not shared by other eukaryotes (18S rRNA and much more)
***Green Algae and plants share a recent common ancestor not shared by other groups (chloroplast structure, chemistry, 16S & 18S rRNA sequences)
Diversification of plastids
The large diversity of plastids, assumed to have been achieved since the seminal endosymbiotic event, obviously raises questions because no single extant cyanobacterium contains the range of light-absorbing pigments found in algae.
. . . but the biosynthetic pathways leading to pigments are similar, and, moreover, the engulfed cyanobacterium might have had the range of pigments, which have been subsequently lost.
Lecture Outline (f)
Chronology of life and life processes on EarthPossible origins of the proto-eukaryal cellEndosymbiosis and other methods for non-vertical gene transferMorphology and function of chloroplasts16(18)S rRNA sequence analysis
Green Algae
Red AlgaeHeterokonts (Brown Algae and Oomycetes)
Examples of Green Algae: Colonial Forms
These panels depict three species (Gonium, Pandorina, Eudorina) that comprise a colonial series made up of Chlamydomonas-type cells. The pinnacle in this dead-end evolutionary series is Volvox, which is made of thousands of cells.
Examples of Green Algae: Siphonous Form
Acetabularia
Examples of Green Algae: Parenchytamous Forms
Ulva
Chlamydomonas sp.
Chlamydomonas asexual life cycle
Chlamydomonas sexual life cycle
Lecture Outline (g)
Chronology of life and life processes on EarthPossible origins of the proto-eukaryal cellEndosymbiosis and other methods for non-vertical gene transferMorphology and function of chloroplasts16(18)S rRNA sequence analysisGreen Algae
Red Algae
Heterokonts (Brown Algae and Oomycetes)
Examples of Red Algae: Bonnemaisonia
Examples of Red Algae: coralline alga (calcified walls)
Examples of Red Algae: Batrachospermum
Lecture Outline (h)
Chronology of life and life processes on EarthPossible origins of the proto-eukaryal cellEndosymbiosis and other methods for non-vertical gene transferMorphology and function of chloroplasts16(18)S rRNA sequence analysisGreen AlgaeRed Algae
Heterokonts (Brown Algae and Oomycetes)
Heterokont (=different flagella)
Image from Graham & Wilcos
“Tinsel-type” flagellum with two rows of stiff glycoproteinaceous hairs.
Shorter, smooth flagellum, often with a basal swelling that is involved in light sensing.
Examples of Brown Algae: Durvillea, New Zealand
Examples of Brown Algae: Laminaria
Examples of Brown Algae:
Macrocystis
Examples of Brown Algae: Fucus (Rockweed)
Fucus sexual life cycle
Phytophthora infestans on potato
Phytophthora life cycle
End
End