Genomic Prediction in Tetraploid Ryegrass

Xiangyu Guo; Fabio Cericola; Dario Fè; Morten Greve-Pedersen; Ingo Lenk; Christian Sig Jensen; Just Jensen; Luc Janss

Genomic Prediction in Tetraploid Ryegrass

Xiangyu Guo, Fabio Cericola, Dario Fè, Morten Greve-Pedersen, Ingo Lenk, Christian Sig Jensen, Just Jensen, Luc Janss

Publikation: Konferencebidrag › Konferenceabstrakt til konference › Forskning › peer review

Abstract

Perennial ryegrass is an outbreeding forage species, which is one of the most widely used forage grasses in temperate regions. Compared with diploid ryegrass, tetraploid ryegrass has better palatability, digestibility, and also hold a higher yield potential. Genomic selection has successfully been implemented in diploid ryegrass breeding during the past six years. The genomic selection is based on genotyping-by-sequencing (GBS), which is particularly well suited for genotyping plants that are bred in families. Similarly, statistical prediction models have been developed, which rely on allele frequencies that can easily be derived from GBS data. The aim of this study is to investigate the possibility of implementing genomic prediction in tetraploid perennial ryegrass and study the effects of different coverage depth.
A total of 1,148 F2 tetraploid ryegrass families from the breeding program at DLF Seeds A/S were included in the study. The traits considered were forage dry matter yield (DM), crown rust resistance (RUST) and heading date (HD) recorded between 2004 and 2014. Different SNP sets were created with minimum depth ranging from 1 to 50. The genomic prediction accuracy was estimated by using a “leave one single F2 family out” cross validation scheme, and the predictive ability was assessed with regards to accuracy and bias by comparing the corrected phenotypes and genomic breeding values.

The results indicate that genomic prediction can help to optimize the breeding of tetraploid ryegrass while bias needs to be further investigated by exploring possible missing of factors in the model or alternative scaling of the genomic relationship matrix.

Originalsprog	Engelsk
Publikationsdato	2019
Status	Udgivet - 2019
Begivenhed	PAG 2017 - San Diego, San Diego, USA Varighed: 13 jan. 2017 → 18 jan. 2017 https://pag.confex.com/pag/xxv/webprogram/start.html

Konference

Konference	PAG 2017
Lokation	San Diego
Land/Område	USA
By	San Diego
Periode	13/01/2017 → 18/01/2017
Internetadresse	https://pag.confex.com/pag/xxv/webprogram/start.html

Andre filer og links

https://pag.confex.com/pag/xxv/webprogram/Paper23375.html

Citationsformater

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title = "Genomic Prediction in Tetraploid Ryegrass",

abstract = "Perennial ryegrass is an outbreeding forage species, which is one of the most widely used forage grasses in temperate regions. Compared with diploid ryegrass, tetraploid ryegrass has better palatability, digestibility, and also hold a higher yield potential. Genomic selection has successfully been implemented in diploid ryegrass breeding during the past six years. The genomic selection is based on genotyping-by-sequencing (GBS), which is particularly well suited for genotyping plants that are bred in families. Similarly, statistical prediction models have been developed, which rely on allele frequencies that can easily be derived from GBS data. The aim of this study is to investigate the possibility of implementing genomic prediction in tetraploid perennial ryegrass and study the effects of different coverage depth.A total of 1,148 F2 tetraploid ryegrass families from the breeding program at DLF Seeds A/S were included in the study. The traits considered were forage dry matter yield (DM), crown rust resistance (RUST) and heading date (HD) recorded between 2004 and 2014. Different SNP sets were created with minimum depth ranging from 1 to 50. The genomic prediction accuracy was estimated by using a “leave one single F2 family out” cross validation scheme, and the predictive ability was assessed with regards to accuracy and bias by comparing the corrected phenotypes and genomic breeding values.The results indicate that genomic prediction can help to optimize the breeding of tetraploid ryegrass while bias needs to be further investigated by exploring possible missing of factors in the model or alternative scaling of the genomic relationship matrix.",

author = "Xiangyu Guo and Fabio Cericola and Dario F{\`e} and Morten Greve-Pedersen and Ingo Lenk and Jensen, {Christian Sig} and Just Jensen and Luc Janss",

year = "2019",

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TY - ABST

T1 - Genomic Prediction in Tetraploid Ryegrass

AU - Guo, Xiangyu

AU - Cericola, Fabio

AU - Fè, Dario

AU - Greve-Pedersen, Morten

AU - Lenk, Ingo

AU - Jensen, Christian Sig

AU - Jensen, Just

AU - Janss, Luc

PY - 2019

Y1 - 2019

N2 - Perennial ryegrass is an outbreeding forage species, which is one of the most widely used forage grasses in temperate regions. Compared with diploid ryegrass, tetraploid ryegrass has better palatability, digestibility, and also hold a higher yield potential. Genomic selection has successfully been implemented in diploid ryegrass breeding during the past six years. The genomic selection is based on genotyping-by-sequencing (GBS), which is particularly well suited for genotyping plants that are bred in families. Similarly, statistical prediction models have been developed, which rely on allele frequencies that can easily be derived from GBS data. The aim of this study is to investigate the possibility of implementing genomic prediction in tetraploid perennial ryegrass and study the effects of different coverage depth.A total of 1,148 F2 tetraploid ryegrass families from the breeding program at DLF Seeds A/S were included in the study. The traits considered were forage dry matter yield (DM), crown rust resistance (RUST) and heading date (HD) recorded between 2004 and 2014. Different SNP sets were created with minimum depth ranging from 1 to 50. The genomic prediction accuracy was estimated by using a “leave one single F2 family out” cross validation scheme, and the predictive ability was assessed with regards to accuracy and bias by comparing the corrected phenotypes and genomic breeding values.The results indicate that genomic prediction can help to optimize the breeding of tetraploid ryegrass while bias needs to be further investigated by exploring possible missing of factors in the model or alternative scaling of the genomic relationship matrix.

AB - Perennial ryegrass is an outbreeding forage species, which is one of the most widely used forage grasses in temperate regions. Compared with diploid ryegrass, tetraploid ryegrass has better palatability, digestibility, and also hold a higher yield potential. Genomic selection has successfully been implemented in diploid ryegrass breeding during the past six years. The genomic selection is based on genotyping-by-sequencing (GBS), which is particularly well suited for genotyping plants that are bred in families. Similarly, statistical prediction models have been developed, which rely on allele frequencies that can easily be derived from GBS data. The aim of this study is to investigate the possibility of implementing genomic prediction in tetraploid perennial ryegrass and study the effects of different coverage depth.A total of 1,148 F2 tetraploid ryegrass families from the breeding program at DLF Seeds A/S were included in the study. The traits considered were forage dry matter yield (DM), crown rust resistance (RUST) and heading date (HD) recorded between 2004 and 2014. Different SNP sets were created with minimum depth ranging from 1 to 50. The genomic prediction accuracy was estimated by using a “leave one single F2 family out” cross validation scheme, and the predictive ability was assessed with regards to accuracy and bias by comparing the corrected phenotypes and genomic breeding values.The results indicate that genomic prediction can help to optimize the breeding of tetraploid ryegrass while bias needs to be further investigated by exploring possible missing of factors in the model or alternative scaling of the genomic relationship matrix.

UR - https://pag.confex.com/pag/xxv/webprogram/Paper23375.html

M3 - Conference abstract for conference

T2 - PAG 2017

Y2 - 13 January 2017 through 18 January 2017

ER -