Multiple-Trait Genomic Selection Methods Increase Genetic Value Prediction Accuracy

Jia, Yang; Jannink, Jean‐Luc

doi:10.1534/genetics.112.144246

Cited by 389 publications

(517 citation statements)

References 16 publications

(34 reference statements)

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“…Using such a predictor trait may result in an improvement of the trait of interest at a low cost. Also in genomic selection, an additional gain in accuracy can be achieved using predictor traits, as it was shown using both deterministic (Calus et al, 2013) and empirical simulations Jia and Jannink, 2012). Both empirical studies had predictor traits measured on both the reference animals and evaluated animals.…”

Section: Introductionmentioning

confidence: 99%

Effect of predictor traits on accuracy of genomic breeding values for feed intake based on a limited cow reference population

Pszczoła

Veerkamp

Haas

et al. 2013

Animal

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The genomic breeding value accuracy of scarcely recorded traits is low because of the limited number of phenotypic observations. One solution to increase the breeding value accuracy is to use predictor traits. This study investigated the impact of recording additional phenotypic observations for predictor traits on reference and evaluated animals on the genomic breeding value accuracy for a scarcely recorded trait. The scarcely recorded trait was dry matter intake (DMI, n 5 869) and the predictor traits were fat-protein-corrected milk (FPCM, n 5 1520) and live weight (LW, n 5 1309). All phenotyped animals were genotyped and originated from research farms in Ireland, the United Kingdom and the Netherlands. Multi-trait REML was used to simultaneously estimate variance components and breeding values for DMI using available predictors. In addition, analyses using only pedigree relationships were performed. Breeding value accuracy was assessed through cross-validation (CV) and prediction error variance (PEV). CV groups (n 5 7) were defined by splitting animals across genetic lines and management groups within country. With no additional traits recorded for the evaluated animals, both CV-and PEV-based accuracies for DMI were substantially higher for genomic than for pedigree analyses (CV: max. 0.26 for pedigree and 0.33 for genomic analyses; PEV: max. 0.45 and 0.52, respectively). With additional traits available, the differences between pedigree and genomic accuracies diminished. With additional recording for FPCM, pedigree accuracies increased from 0.26 to 0.47 for CV and from 0.45 to 0.48 for PEV. Genomic accuracies increased from 0.33 to 0.50 for CV and from 0.52 to 0.53 for PEV. With additional recording for LW instead of FPCM, pedigree accuracies increased to 0.54 for CV and to 0.61 for PEV. Genomic accuracies increased to 0.57 for CV and to 0.60 for PEV. With both FPCM and LW available for evaluated animals, accuracy was highest (0.62 for CV and 0.61 for PEV in pedigree, and 0.63 for CV and 0.61 for PEV in genomic analyses). Recording predictor traits for only the reference population did not increase DMI breeding value accuracy. Recording predictor traits for both reference and evaluated animals significantly increased DMI breeding value accuracy and removed the bias observed when only reference animals had records. The benefit of using genomic instead of pedigree relationships was reduced when more predictor traits were used. Using predictor traits may be an inexpensive way to significantly increase the accuracy and remove the bias of (genomic) breeding values of scarcely recorded traits such as feed intake.

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Section: Introductionmentioning

confidence: 99%

Effect of predictor traits on accuracy of genomic breeding values for feed intake based on a limited cow reference population

Pszczoła

Veerkamp

Haas

et al. 2013

Animal

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“…For instance, Yang et al (2010) suggested using whole-genome regressions (WGRs) (Meuwissen et al 2001) to assess the proportion of variance of a trait or disease risk that can be explained by a regression of phenotypes on common SNPs or genomic heritability and a related parameter, the "missing heritability." More recently, WGR models have been extended for the analysis of systems of multiple traits, so the concept of genomic correlation also has entered into the picture (Jia and Jannink 2012;Lee et al 2012). For instance, Maier et al (2015) used multivariate WGR models and reported estimates of genetic correlations between psychiatric disorders, and Furlotte and Eskin (2015) presented a methodology that incorporates genetic marker information for the analysis of multiple traits that, according to the authors, "provide fundamental insights into the nature of co-expressed genes."…”

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confidence: 99%

Do Molecular Markers Inform About Pleiotropy?

et al. 2015

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The availability of dense panels of common single-nucleotide polymorphisms and sequence variants has facilitated the study of statistical features of the genetic architecture of complex traits and diseases via whole-genome regressions (WGRs). At the onset, traits were analyzed trait by trait, but recently, WGRs have been extended for analysis of several traits jointly. The expectation is that such an approach would offer insight into mechanisms that cause trait associations, such as pleiotropy. We demonstrate that correlation parameters inferred using markers can give a distorted picture of the genetic correlation between traits. In the absence of knowledge of linkage disequilibrium relationships between quantitative or disease trait loci and markers, speculating about genetic correlation and its causes (e.g., pleiotropy) using genomic data is conjectural.KEYWORDS genetic correlation; genomic correlation; genomic heritability; linkage disequilibrium; pleiotropy T HE interindividual differences for a trait or disease risk that can be explained by genetic factors, such as trait heritability (h 2 ), the genetic correlation (r G ), and the coheritability between two traits (r G h 1 h 2 ), are very important parameters in quantitative genetic studies of animals, humans, and plants. These quantities play a role in the study of evolution due to artificial and natural selection, and knowledge thereof is required for statistical prediction of outcomes in animal and plant breeding as well as medicine. Traditionally, these parameters have been estimated using phenotypes and pedigrees, e.g., family and twin data in human genetics. The availability of dense panels of common single-nucleotide polymorphisms (SNPs) and of sequence data more recently has made it possible to assess kinship among distantly related individuals (Morton et al. 1971;Thompson 1975;Ritland 1996;Lynch and Ritland 1999). This development has opened new opportunities for study of the genetic architecture of complex traits and diseases. For instance, Yang et al. (2010) suggested using whole-genome regressions (WGRs) (Meuwissen et al. 2001) to assess the proportion of variance of a trait or disease risk that can be explained by a regression of phenotypes on common SNPs or genomic heritability and a related parameter, the "missing heritability." More recently, WGR models have been extended for the analysis of systems of multiple traits, so the concept of genomic correlation also has entered into the picture (Jia and Jannink 2012; Lee et al. 2012). For instance, Maier et al. (2015) used multivariate WGR models and reported estimates of genetic correlations between psychiatric disorders, and Furlotte and Eskin (2015) presented a methodology that incorporates genetic marker information for the analysis of multiple traits that, according to the authors, "provide fundamental insights into the nature of co-expressed genes." In a similar spirit, Korte et al. (2012) argued that multitrait-marker-enabled regressions can be useful for understanding pleiotropy....

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“…By evaluating power performance, it is shown that it can be advantageous to perform the proposed pleiotropy analysis instead of individual trait analysis. [1][2][3][4][5][6][7][8][9][10]27,44 Among other merits, the MFLM can handle missing genotype data naturally.…”

Section: Discussionmentioning

confidence: 99%

“…[1][2][3][4][5][6][7][8][9][10] To our knowledge, metaanalysis and pleiotropy analysis have been performed separately so far, and there are no gene-based meta-analysis methods for combining multiple studies together and for carrying out a unified pleiotropy analysis. Here, multivariate functional linear models (MFLM) are developed to connect genetic variant data to multiple quantitative traits adjusting for covariates in a meta-analysis context.…”

Section: Introductionmentioning

confidence: 99%

Meta-analysis of quantitative pleiotropic traits for next-generation sequencing with multivariate functional linear models

Chiu¹,

Jung²,

Chen³

et al. 2016

Eur J Hum Genet

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To analyze next-generation sequencing data, multivariate functional linear models are developed for a meta-analysis of multiple studies to connect genetic variant data to multiple quantitative traits adjusting for covariates. The goal is to take the advantage of both meta-analysis and pleiotropic analysis in order to improve power and to carry out a unified association analysis of multiple studies and multiple traits of complex disorders. Three types of approximate F -distributions based on Pillai-Bartlett trace, HotellingLawley trace, and Wilks's Lambda are introduced to test for association between multiple quantitative traits and multiple genetic variants. Simulation analysis is performed to evaluate false-positive rates and power of the proposed tests. The proposed methods are applied to analyze lipid traits in eight European cohorts. It is shown that it is more advantageous to perform multivariate analysis than univariate analysis in general, and it is more advantageous to perform meta-analysis of multiple studies instead of analyzing the individual studies separately. The proposed models require individual observations. The value of the current paper can be seen at least for two reasons: (a) the proposed methods can be applied to studies that have individual genotype data; (b) the proposed methods can be used as a criterion for future work that uses summary statistics to build test statistics to meta-analyze the data. INTRODUCTION Meta-analysis of multiple studies and pleiotropy analysis of multiple traits are two areas in association studies that recently have received extensive attention in the literature. 1-10 To our knowledge, metaanalysis and pleiotropy analysis have been performed separately so far, and there are no gene-based meta-analysis methods for combining multiple studies together and for carrying out a unified pleiotropy analysis. Here, multivariate functional linear models (MFLM) are developed to connect genetic variant data to multiple quantitative traits adjusting for covariates in a meta-analysis context. The goal is to take the advantage of both meta-analysis and pleiotropy analysis in order to improve power and to carry out a unified analysis of multiple studies and multiple quantitative traits of complex disorders.A noticeable feature of next-generation sequencing data is that dense panels of genetic variants are available via high-throughput sequencing technology, and so we face high-dimension genetic data. [11][12][13][14] The genetic data can consist of rare variants, or common variants, or a combination of the two, where the rare variants' minor allele frequencies (MAFs) are less than 0.01 ∼ 0.05. The high dimensionality of genetic data and the presence of dense rare variants raise

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Multiple-Trait Genomic Selection Methods Increase Genetic Value Prediction Accuracy

Cited by 389 publications

References 16 publications

Effect of predictor traits on accuracy of genomic breeding values for feed intake based on a limited cow reference population

Effect of predictor traits on accuracy of genomic breeding values for feed intake based on a limited cow reference population

Do Molecular Markers Inform About Pleiotropy?

Meta-analysis of quantitative pleiotropic traits for next-generation sequencing with multivariate functional linear models

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