Genomic Breeding Programs Realize Larger Benefits by Cooperation in the Presence of Genotype × Environment Interaction Than Conventional Breeding Programs

Lu Cao; Huiming Liu; Han A Mulder; Mark Henryon; Jørn Rind Thomasen; Morten Kargo; Anders Christian Sørensen

doi:10.3389/fgene.2020.00251

Genomic Breeding Programs Realize Larger Benefits by Cooperation in the Presence of Genotype × Environment Interaction Than Conventional Breeding Programs

Front Genet. 2020 Apr 21:11:251. doi: 10.3389/fgene.2020.00251. eCollection 2020.

Authors

Lu Cao¹, Huiming Liu¹, Han A Mulder², Mark Henryon^{3

4}, Jørn Rind Thomasen⁵, Morten Kargo^{1

6}, Anders Christian Sørensen¹

Affiliations

¹ Center for Quantitative Genetics and Genomics, Aarhus University, Tjele, Denmark.
² Wageningen University & Research, Animal Breeding and Genomics, Wageningen, Netherlands.
³ Danish Pig Research Centre, SEGES, Copenhagen, Denmark.
⁴ School of Agriculture and Environment, The University of Western Australia, Crawley, WA, Australia.
⁵ VikingGenetics, Randers, Denmark.
⁶ SEGES, Aarhus, Denmark.

Abstract

Genotype × environment interaction (G × E) is of increasing importance for dairy cattle breeders due to international multiple-environment selection of animals as well as the differentiation of production environments within countries. This theoretical simulation study tested the hypothesis that genomic selection (GS) breeding programs realize larger genetic benefits by cooperation in the presence of G × E than conventional pedigree-based selection (PS) breeding programs. We simulated two breeding programs each with their own cattle population and environment. Two populations had either equal or unequal population sizes. Selection of sires was done either across environments (cooperative) or within their own environment (independent). Four scenarios, (GS/PS) × (cooperative/independent), were performed. The genetic correlation (r _g ) between the single breeding goal trait expressed in two environments was varied between 0.5 and 0.9. We compared scenarios for genetic gain, rate of inbreeding, proportion of selected external sires, and the split-point r _g that is the lowest value of r _g for long-term cooperation. Between two equal-sized populations, cooperative GS breeding programs achieved a maximum increase of 19.3% in genetic gain and a maximum reduction of 24.4% in rate of inbreeding compared to independent GS breeding programs. The increase in genetic gain and the reduction in rate of inbreeding realized by GS breeding programs with cooperation were respectively at maximum 9.7% and 24.7% higher than those realized by PS breeding programs with cooperation. Secondly, cooperative GS breeding programs allowed a slightly lower split-point r _g than cooperative PS breeding programs (0.85∼0.875 vs ≥ 0.9). Between two unequal-sized populations, cooperative GS breeding programs realized higher increase in genetic gain and showed greater probability for long-term cooperation than cooperative PS breeding programs. Secondly, cooperation using GS were more beneficial to the small population while also beneficial but much less to the large population. In summary, by cooperation in the presence of G × E, GS breeding programs realize larger improvements in terms of the genetic gain and rate of inbreeding, and have greater possibility of long-term cooperation than conventional PS breeding programs. Therefore, we recommend cooperative GS breeding programs in situations with mild to moderate G × E, depending on the sizes of two populations.

Keywords: across-environment selection of sires; genetic gain; joint genetic evaluation; long-term cooperation; rate of inbreeding; stochastic simulation.