The impact of genetic architecture on genome-wide evaluation methods
The rapid increase in high-throughput single-nucleotide polymorphism data has led to a great interest in applying genome-wide evaluation methods to identify an individual's genetic merit. Genome-wide evaluation combines statistical methods with genomic data to predict genetic values for complex traits. Considerable uncertainty currently exists in determining which genome-wide evaluation method is the most appropriate. We hypothesize that genome-wide methods deal differently with the genetic architecture of quantitative traits and genomes. A genomic linear method (GBLUP), and a genomic nonlinear Bayesian variable selection method (BayesB) are compared using stochastic simulation across three effective population sizes and a wide range of numbers of quantitative trait loci (NQTL). GBLUP had a constant accuracy, for a given heritability and sample size, regardless of N QTL. BayesB had a higher accuracy than GBLUP when NQTL was low, but this advantage diminished as NQTL increased and when N QTL became large, GBLUP slightly outperformed BayesB. In addition, deterministic equations are extended to predict the accuracy of both methods and to estimate the number of independent chromosome segments (Me) and NQTL. The predictions of accuracy and estimates of Me and NQTL were generally in good agreement with results from simulated data. We conclude that the relative accuracy of GBLUP and BayesB for a given number of records and heritability are highly dependent on Me, which is a property of the target genome, as well as the architecture of the trait (N QTL). Copyright © 2010 by the Genetics Society of America.
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dig-inia-es-20.500.12792-60282020-12-15T09:55:07Z The impact of genetic architecture on genome-wide evaluation methods Daetwyler, H. D. Pong-Wong, R. Villanueva, B. Woolliams, J. A. The rapid increase in high-throughput single-nucleotide polymorphism data has led to a great interest in applying genome-wide evaluation methods to identify an individual's genetic merit. Genome-wide evaluation combines statistical methods with genomic data to predict genetic values for complex traits. Considerable uncertainty currently exists in determining which genome-wide evaluation method is the most appropriate. We hypothesize that genome-wide methods deal differently with the genetic architecture of quantitative traits and genomes. A genomic linear method (GBLUP), and a genomic nonlinear Bayesian variable selection method (BayesB) are compared using stochastic simulation across three effective population sizes and a wide range of numbers of quantitative trait loci (NQTL). GBLUP had a constant accuracy, for a given heritability and sample size, regardless of N QTL. BayesB had a higher accuracy than GBLUP when NQTL was low, but this advantage diminished as NQTL increased and when N QTL became large, GBLUP slightly outperformed BayesB. In addition, deterministic equations are extended to predict the accuracy of both methods and to estimate the number of independent chromosome segments (Me) and NQTL. The predictions of accuracy and estimates of Me and NQTL were generally in good agreement with results from simulated data. We conclude that the relative accuracy of GBLUP and BayesB for a given number of records and heritability are highly dependent on Me, which is a property of the target genome, as well as the architecture of the trait (N QTL). Copyright © 2010 by the Genetics Society of America. 2020-10-22T22:08:08Z 2020-10-22T22:08:08Z 2010 journal article http://hdl.handle.net/20.500.12792/6028 10.1534/genetics.110.116855 eng Attribution-NonCommercial-ShareAlike 4.0 International http://creativecommons.org/licenses/by-nc-sa/4.0/ open access |
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The rapid increase in high-throughput single-nucleotide polymorphism data has led to a great interest in applying genome-wide evaluation methods to identify an individual's genetic merit. Genome-wide evaluation combines statistical methods with genomic data to predict genetic values for complex traits. Considerable uncertainty currently exists in determining which genome-wide evaluation method is the most appropriate. We hypothesize that genome-wide methods deal differently with the genetic architecture of quantitative traits and genomes. A genomic linear method (GBLUP), and a genomic nonlinear Bayesian variable selection method (BayesB) are compared using stochastic simulation across three effective population sizes and a wide range of numbers of quantitative trait loci (NQTL). GBLUP had a constant accuracy, for a given heritability and sample size, regardless of N QTL. BayesB had a higher accuracy than GBLUP when NQTL was low, but this advantage diminished as NQTL increased and when N QTL became large, GBLUP slightly outperformed BayesB. In addition, deterministic equations are extended to predict the accuracy of both methods and to estimate the number of independent chromosome segments (Me) and NQTL. The predictions of accuracy and estimates of Me and NQTL were generally in good agreement with results from simulated data. We conclude that the relative accuracy of GBLUP and BayesB for a given number of records and heritability are highly dependent on Me, which is a property of the target genome, as well as the architecture of the trait (N QTL). Copyright © 2010 by the Genetics Society of America. |
| format |
journal article |
| author |
Daetwyler, H. D. Pong-Wong, R. Villanueva, B. Woolliams, J. A. |
| spellingShingle |
Daetwyler, H. D. Pong-Wong, R. Villanueva, B. Woolliams, J. A. The impact of genetic architecture on genome-wide evaluation methods |
| author_facet |
Daetwyler, H. D. Pong-Wong, R. Villanueva, B. Woolliams, J. A. |
| author_sort |
Daetwyler, H. D. |
| title |
The impact of genetic architecture on genome-wide evaluation methods |
| title_short |
The impact of genetic architecture on genome-wide evaluation methods |
| title_full |
The impact of genetic architecture on genome-wide evaluation methods |
| title_fullStr |
The impact of genetic architecture on genome-wide evaluation methods |
| title_full_unstemmed |
The impact of genetic architecture on genome-wide evaluation methods |
| title_sort |
impact of genetic architecture on genome-wide evaluation methods |
| publishDate |
2010 |
| url |
http://hdl.handle.net/20.500.12792/6028 |
| work_keys_str_mv |
AT daetwylerhd theimpactofgeneticarchitectureongenomewideevaluationmethods AT pongwongr theimpactofgeneticarchitectureongenomewideevaluationmethods AT villanuevab theimpactofgeneticarchitectureongenomewideevaluationmethods AT woolliamsja theimpactofgeneticarchitectureongenomewideevaluationmethods AT daetwylerhd impactofgeneticarchitectureongenomewideevaluationmethods AT pongwongr impactofgeneticarchitectureongenomewideevaluationmethods AT villanuevab impactofgeneticarchitectureongenomewideevaluationmethods AT woolliamsja impactofgeneticarchitectureongenomewideevaluationmethods |
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1758005151809929216 |