Maize (Zea mays L.)production in northern U.S. Corn Belt area requires hybrids that can
efficiently utilize the short growing season. Chase (1964) concluded that higher yield in maize
is expected in early hybrids that flower later in the season and then lose moisture rapidly after
physiological maturity of the grain. This implied that a fast dry down rate after physiological
maturity should be an important feature for maize hybrids grown especially in the northern
U.S. Corn Belt where early frost is common. Fast field dry down can reduce grower’s
production cost related to artificial grain drying and economical losses due to delayed
harvesting (e.g., yield losses caused by lodging, bird and insect damage, and ear rot disease).
With a faster dry down rate, hybrids reach an optimum level of grain test weight and quality at
harvest. Test weight of maize accounts for the packing densities of grain, which are caused by
weather, production practice, and/or genetic difference among hybrids. It can be improved by
avoiding late planting and by selecting early maturing hybrids with excellent genetic potential
in test weight and dry down.
Genetic factors contribute to maize hybrid differences in field dry down rate (Cross and
Kabir, 1969; Purdy and Crane, 1967; Zhang et al, 1996). Although the importance of dry down
rate has been recognized by maize breeders, it is still difficult to apply a simple and reliable
method to measure and screen inbred lines and hybrids for dry down rate. Field dry down is a
dynamic process influenced by various environmental factors. Therefore, a method that can
reflect dynamic change of grain moisture and minimize environmental influence is needed. In
addition to conventional oven-dried and laboratory moisture tester methods, the application of
electronic moisture meters were reported by Kang et al. (1978) and Freppon et al. (1992).
These methods are non-destructive when estimating ear moisture several times on the same
ear. In this research, an index, area under the dry down progress curve (AUDDC), was created
and used to represent field dry down rate. We propose this index as a new method for
screening genetic differences among maize genotypes for dry down.
The quantitative nature of dry down and test weight with large environmental influence
increases the difficulty for utilizing traditional and modern breeding methods to develop hybrids
with good performance on both traits. Increasing our understanding of their genetic nature
could aid breeders in selecting the right germplasm and breeding methodology for a
successful genetic improvement. Although previous studies have suggested additive gene
action is important for field dry down, more genetic information is desirable for breeding
purposes. In addition, this study proposes the exploitation of a linkage between traditional and
modern techniques for the best possible generation of knowledge and it is application.
Methods Results
Breeding and Genetics of Field Dry Down and Test Weight in Short-Season Elite Maize Hybrids†Junyun Yang1, Marcelo Carena1, and Jim Uphaus2
1Department of Plant Sciences, North Dakota State University; 2 AgReliant Genetics, LLCASA-CSSA-SSSA Meeting
November 1-5, 2009
Table 1. Three groups of North Carolina (NC II) mating designs between NDSU experimental lines and industry lines representing a wide range of test weight.
Bibliography
Moisture meter BLD5604 is reliable to estimate corn kernel moisture content after physiologic maturity.
Field dry down rate can be estimated by the AUDDC method, based on several field readings at a constant interval.
AUDDC has relatively high heritability compared with yield and test weight, and similar to quality traits such as starch, oil, and protein content.
Earlier maturing genotypes tend to have faster dry down rate in this set of genotypes.
Selection for fast dry down in inbreds and hybrids is recommended based on AUDDC.
Based on GCA and SCA data, several hybrids have been identified to generate additional
genetic information in cooperation with Ag-Reliant Genetics. F2 mapping populations have
been produced from these hybrids and new lines are being developed through doubled-haploid technology. The only limitation is the number of segregating populations that can be studied compared to the 138 hybrids studied with classical mating designs.
• Moisture meter calibrationTable 4. GCA and SCA values for inbred lines in NC II group 1†
Introduction Results
ObjectivesThis research was conducted to:
1) develop a simple and reliable procedure to select for fast dry down in early maturing maize inbreds and hybrids,
2) better understand the genetic base controlling the expression of test weight and dry down rate through the integration of classical and modern quantitative genetic approaches,
3) identify new and elite high-yielding inbred lines and hybrids with high test weight and fast rate of dry down.
Group 1 Group 2 Group 3Male Female Male Female Male Female
ND05-117 1† AGR1 3 ND04-21 1 AGR7 2 ND-290 3 AGR11 1
ND06-240 1 AGR2 3 ND05-65 2 AGR8 2 ND06-219 3 AGR12 NA‡
ND06-50 1 AGR3 3 ND05-73 3 AGR4 3 ND06-244 3 AGR13 2
ND06-211 1 AGR4 3 ND05-126 2 AGR9 NA ND06-85 3 AGR14 2
ND06-181 1 AGR5 3 ND05-96 1 AGR10 2 ND06-189 3 AGR6 2
AGR6 2 ND05-50 1 AGR6 2 AGR4 3
ND04-25 3†: test weight grade: 3 = high (>55.5 lb/bu), 2 = medium (54.0-55.4 lb/bu), 1 = low (<53.9 lb/bu).‡: test weight grade is not available.
• Field evaluation
– 138 crosses (NDSU × Industry elite lines) + 6 commercial checks
– Four environments: 2007 Fargo and Oakes, ND; 2008 Fargo and Casselton, ND
– 12x12 partially balanced lattice design, two reps for each environment
– Traits collected:
• Field dry down: AUDDC calculated based on meter reading on four dates (7-day interval) , started 45 days after pollination
• Test weight, yield, harvest moisture, stand, stalk logging, root logging• Quality: High extractable starch (HES), starch, oil, protein
• Estimation of dry down– Area under the disease progress curve (AUDPC)
• AUDPC is used to summarize the progress of disease severity. • We propose: Area under the dry down curve (AUDDC)
Date1 Date2 Date3 Date4 Date5
Hybrid1Hybrid2Hybrid3
15202530354045505560
Mois
ture
conte
nt
(%)
Larger AUDDC area, representing slower dry down progress
Smaller AUDDC area, representing faster dry down progress
• Moisture meter calibration– Electronic moisture meter BLD5604:(range: 7~99%; General Electric Co.)
Plug probes through the husk into the ear/kernels Each ear was probed at its middle part
– Regression model for meter reading and actual kernel moisture content• A total of 107 hybrid + inbred ears from Fargo field in 2007 and 2008• randomly sampled, 30 days after pollination until harvest (7-day intervals)• using electronic meter and oven-dried methods
– Converted field meter reading to kernel moisture based on regression model
Regression of oven-measured moisture on meter reading
10
20
30
40
50
60
10 20 30 40 50 60 70 80 90 100
Meter reading
Ove
n-m
easu
red
Moi
stur
e(%
)
2007 Hybrid
2007 Inbred
2008 Inbred
Y = 29.09+ 0.24x - 0.005(x-61.57)2 + 0.00008(x-61.57)3
r2 = 0.86
• Field evaluation Table 2. Mean square value for multiple traits across four environments
SOURCE D1† MOIST‡ AUDDC YIELD TWT§
Env. (E) 12924.0*** 2165.1*** 7616354*** 578.9*** 1884.8*** Hybrids (G) 36.6*** 35.0*** 21790*** 13.1*** 23.5*** E x G 10.4*** 5.9*** 3812*** 4.6*** 6.3*** Error 2.9 1.0 1313 3.0 3.6CV (%) 4.1 4.7 4.9 20.7 3.5
H¶ 0.71 0.83 0.83 0.65 0.73 †: physiologic moisture; ‡: harvest moisture; §: test weight, ¶ : Broad sense heritability *** Significant at 0.001 level
))(2
( 1
11
ii
n
i
ii ttyy
AUDDC
• Correlation among traits
MOIST AUDDC DS† TWT
AUDDC 0.83***
DS 0.68*** 0.80***
TWT -0.29*** -0.49*** -0.56***
Yield 0.40*** 0.49*** 0.41*** -0.11
AUDDC STARDH OIL PROTEIN
Starch 0.29***
Oil 0.07 -0.50***
Protein 0.03 -0.63*** 0.03
TWT -0.49*** -0.08 -0.05 0.03† Pollination day (days from planting to pollination)*** Significant at 0.001 level
• NC II groupsTable 3. Mean square values of different traits for NC II group I
SOURCE D1 MOIST AUDDC YIELD TWT DS
Env. 893.2*** 431.0*** 584389*** 35.1*** 198.4*** 782.8***
Male 54.9*** 21.6*** 20265*** 12.6*** 40.7*** 29.7***
Female 40.8*** 43.6*** 22220*** 6.7*** 29.7*** 19.7***
Male*female 3.1 3.9 2231 3.5* 4.3* 5.3
• For each NC II group, GCA effects (male and female expectation) were significant for most traits, except for stand, root logging, and stalk logging.
• SCA (male x female) effect was not significant for most traits, except for GRAIN yield, test weight, and oil grain content in some NC II groups.
*: significant at 0.5 level; ***: Significant at 0.001 level.
Conclusions
1. Chase, S.S. 1964. Relation of yield and number of days from planting to flowering in early maturity maize hybrids of equivalent grain moisture at harvest. Crop Sci. 4:111-112.
2. Cross, H.Z., and K.M. Kabir. 1989. Evaluation of field dry-down rates in early maize. Crop Sci. 29:54-58.3. Freppon, J.T., S.K. St Martin, R.C. Pratt, and P.R. Henderlong. 1992. Selection for low ear moisture in corn
using a hand-held meter. Crop Sci. 32:1062-1064.4. Kang, M.S., M.S. Zuber, and R.D. Horrocks. 1978. An electronic probe for estimating ear moisture content of
maize. Crop Sci, 18:1083-1084.5. Purdy, J.L., and P.L. Crane. 1967. Inheritance of drying rate in "Mature" corn (Zea mays L.). Crop Sci. 7:294-
297.6. Zhang, Y., M.-S. Kang, and R. Magari. 1996. A diallel analysis of ear moisture loss rate in maize. Crop Sci.
36:1140-1144.
Female AGR1 AGR2 AGR3 AGR4 AGR5 AGR6Male GCAm‡
AUDDCND05-117 15.98 -5.86 -20.80 -29.27 -1.31 41.26 -29.48ND06-181 -32.47 11.25 42.21 19.91 -25.86 -15.04 7.24ND06-211 -15.88 -21.12 -15.02 14.39 24.13 13.48 -27.42ND06-240 16.12 22.89 -2.42 -0.82 -9.60 -26.18 7.48ND06-50 16.24 -7.16 -3.98 -4.21 12.64 -13.52 42.18
GCAf§ 9.92 52.52 -31.93 -43.89 5.95 7.43Yield
ND05-117 0.02 1.50 -1.19 -0.27 0.03 -0.09 0.07ND06-181 0.53 0.56 0.61 -0.44 -0.39 -0.87 0.75ND06-211 -1.06 0.71 0.27 -0.03 -0.15 0.27 0.03ND06-240 0.97 -0.93 0.56 -0.76 0.42 -0.24 -1.18ND06-50 -0.45 -1.84 -0.24 1.51 0.09 0.93 0.33
GCAf 0.25 0.38 0.02 -1.24 0.37 0.23Test weight
ND05-117 -0.99 0.16 0.92 1.29 0.26 -1.64 2.14ND06-181 1.20 0.94 -1.95 -1.54 0.45 0.90 0.34ND06-211 -0.68 -0.03 0.82 -0.55 -0.12 0.55 -0.17ND06-240 0.58 -1.43 0.10 -0.12 0.50 0.36 -0.92ND06-50 -0.12 0.36 0.11 0.92 -1.09 -0.18 -1.39
GCAf -0.69 -1.03 -0.02 1.95 -1.27 1.06 †: to demonstrate selection of inbreds and crosses for yield, test weight, and fast dry down‡: GCAm – general combining ability of males; §: GCAf – general combining ability of females.