Increased genomic prediction accuracy in wheat breeding using a large Australian panel

Norman, Adam; Taylor, Julian; Tanaka, Emi; Telfer, Paul; Edwards, James; Martinant, Jean‐Pierre; Kuchel, Haydn

doi:10.1007/s00122-017-2975-4

Cited by 41 publications

(51 citation statements)

References 71 publications

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“…It is important for genomic prediction of a complex trait that it displays a reasonable 260 heritability. Our estimate of broad sense heritability for yield (0.65) is well within range of 261 similar studies in wheat (Poland et al, 2012;Combs and Bernardo, 2013;Michel et al, 2016;262 Schopp et al, 2017;Norman et al, 2017). We note that the heritability values within individual 263 families ( Figure ) cover the whole range of heritability for this trait reported in the literature.…”

Section: Cross-validation Prediction Accuracy 209supporting

confidence: 85%

The effects of training population design on genomic prediction accuracy in wheat

Edwards

Buntjer

Jackson

et al. 2018

Preprint

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17Genomic selection offers several routes for increasing genetic gain or efficiency of plant 18 breeding programs. In various species of livestock there is empirical evidence of increased 19 rates of genetic gain from the use of genomic selection to target different aspects of the 20 breeder's equation. Accurate predictions of genomic breeding value are central to this and the 21 design of training sets is in turn central to achieving sufficient levels of accuracy. In summary, 22 this study emphasize the importance of the training set design in relation to the genetic 35 material to which the resulting prediction model is to be applied. 36

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Section: Cross-validation Prediction Accuracy 209supporting

confidence: 85%

The effects of training population design on genomic prediction accuracy in wheat

Edwards

Buntjer

Jackson

et al. 2018

Preprint

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“…A training set model was fitted using an adaptation of the linear mixed model defined in (1) with non-genetic parameters fixed at their estimates from the full model. Marker effects were then predicted using the methods described in Norman et al (2017), namely

{\overset{true\sim}{boldq}}_{t} = {boldM}_{t}^{T} {boldK}_{t}^{- 1} {\overset{true\sim}{bolda}}_{t}

where

{boldM}_{t}

and

{boldK}_{t}

were the genetic marker data and additive relationship matrix respectively for the training set of lines and

{\overset{true\sim}{bolda}}_{t}

were GBLUPs for training lines calculated using (3). Genomic predictions for lines in the validation set were then determined using

{\overset{true\sim}{bolda}}_{v} = {boldM}_{v} {\overset{true\sim}{boldq}}_{t}

where

{boldM}_{v}

is the genetic marker data for the validation set and

{\overset{true\sim}{boldq}}_{t}

is defined in (4).…”

Section: Methodsmentioning

confidence: 99%

Optimising Genomic Selection in Wheat: Effect of Marker Density, Population Size and Population Structure on Prediction Accuracy

Norman

Taylor

Edwards

et al. 2018

G3 Genes|Genomes|Genetics

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144

181

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Genomic selection applied to plant breeding enables earlier estimates of a line’s performance and significant reductions in generation interval. Several factors affecting prediction accuracy should be well understood if breeders are to harness genomic selection to its full potential. We used a panel of 10,375 bread wheat (Triticum aestivum) lines genotyped with 18,101 SNP markers to investigate the effect and interaction of training set size, population structure and marker density on genomic prediction accuracy. Through assessing the effect of training set size we showed the rate at which prediction accuracy increases is slower beyond approximately 2,000 lines. The structure of the panel was assessed via principal component analysis and K-means clustering, and its effect on prediction accuracy was examined through a novel cross-validation analysis according to the K-means clusters and breeding cohorts. Here we showed that accuracy can be improved by increasing the diversity within the training set, particularly when relatedness between training and validation sets is low. The breeding cohort analysis revealed that traits with higher selection pressure (lower allelic diversity) can be more accurately predicted by including several previous cohorts in the training set. The effect of marker density and its interaction with population structure was assessed for marker subsets containing between 100 and 17,181 markers. This analysis showed that response to increased marker density is largest when using a diverse training set to predict between poorly related material. These findings represent a significant resource for plant breeders and contribute to the collective knowledge on the optimal structure of calibration panels for genomic prediction.

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“…Marker (genotypic) data are available for 2,845 (of the 2,869) varieties, genotyped according to a high confidence set of 16,124 single‐nucleotide polymorphisms (SNPs) (see Norman et al., , for further details). For each marker, individuals were coded as either ‐1 (homozygous minor allele), 0 (heterozygous) or 1 (homozygous major allele).…”

Section: Motivating Examplementioning

confidence: 99%

Genomic selection in multi‐environment plant breeding trials using a factor analytic linear mixed model

Tolhurst

Mathews

Smith

et al. 2019

J Animal Breeding Genetics

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Genomic selection (GS) is a statistical and breeding methodology designed to improve genetic gain. It has proven to be successful in animal breeding; however, key points of difference have not been fully considered in the transfer of GS from animal to plant breeding. In plant breeding, individuals (varieties) are typically evaluated across a number of locations in multiple years (environments) in formally designed comparative experiments, called multi‐environment trials (METs). The design structure of individual trials can be complex and needs to be modelled appropriately. Another key feature of MET data sets is the presence of variety by environment interaction (VEI), that is the differential response of varieties to a change in environment. In this paper, a single‐step factor analytic linear mixed model is developed for plant breeding MET data sets that incorporates molecular marker data, appropriately accommodates non‐genetic sources of variation within trials and models VEI. A recently developed set of selection tools, which are natural derivatives of factor analytic models, are used to facilitate GS for a motivating data set from an Australian plant breeding company. The power and versatility of these tools is demonstrated for the variety by environment and marker by environment effects.

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Increased genomic prediction accuracy in wheat breeding using a large Australian panel

Cited by 41 publications

References 71 publications

The effects of training population design on genomic prediction accuracy in wheat

The effects of training population design on genomic prediction accuracy in wheat

Optimising Genomic Selection in Wheat: Effect of Marker Density, Population Size and Population Structure on Prediction Accuracy

Genomic selection in multi‐environment plant breeding trials using a factor analytic linear mixed model

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