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REVIEW (Open Access)
Contents Vol 52(3)

Designing dairy cattle breeding schemes under genomic selection: a review of international research

J. E. Pryce A B and H. D. Daetwyler A
+ Author Affiliations
- Author Affiliations

A Biosciences Research Division, Department of Primary Industries, 1 Park Drive, Bundoora, Vic. 3083, Australia.

B Corresponding author. Email: jennie.pryce@dpi.vic.gov.au

Animal Production Science 52(3) 107-114 https://doi.org/10.1071/AN11098
Submitted: 3 June 2011  Accepted: 1 November 2011   Published: 9 December 2011

Journal Compilation © CSIRO Publishing 2012 Open Access CC BY-NC-ND

Abstract

High rates of genetic gain can be achieved through (1) accurate predictions of breeding values (2) high intensities of selection and (3) shorter generation intervals. Reliabilities of ~60% are currently achievable using genomic selection in dairy cattle. This breakthrough means that selection of animals can happen at a very early age (i.e. as soon as a DNA sample is available) and has opened opportunities to radically redesign breeding schemes. Most research over the past decade has focussed on the feasibility of genomic selection, especially how to increase the accuracy of genomic breeding values. More recently, how to apply genomic technology to breeding schemes has generated a lot of interest. Some of this research remains the intellectual property of breeding companies, but there are examples in the public domain. Here we review published research into breeding scheme design using genomic selection and evaluate which designs appear to be promising (in terms of rates of genetic gain) and those that may have unfavourable side-effects (i.e. increasing the rate of inbreeding). The schemes range from fairly conservative designs where bulls are screened genomically to reduce numbers entering progeny testing, to schemes where very large numbers of bull calves are screened and used as sires as soon as they reach sexual maturity. More radical schemes that incorporate the use of reproductive technologies (in juveniles) and genomic selection in nucleus herds are also described. The models used are either deterministic and more recently tend to be stochastic, simulating populations of cattle. A key driver of the rate of genetic gain is the generation interval, which could range from being similar to that in conventional testing (~5 years), down to as little as 1.5 years. Generally, the rate of genetic gain is between 12% and 100% more than in conventional progeny testing, while the rate of inbreeding tends to be lower per generation than in progeny testing because Mendelian sampling terms can be estimated more accurately. However, short generation intervals can lead to higher rates of inbreeding per year in genomic breeding programs.


References

Boichard D, Ducrocq V, Fritz S, Colleau JJ (2010) Where is dairy breeding going? A vision of the future. Interbull Bulletin 41, 63–68.

Browning BL, Browning SR (2009) A unified approach to genotype imputation and haplotype-phase inference for large data sets of trios and unrelated Individuals. American Journal of Human Genetics 84, 210–223.
A unified approach to genotype imputation and haplotype-phase inference for large data sets of trios and unrelated Individuals.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXisFCrtL8%3D&md5=f35b8508f230a0710e68d56d2f433597CAS |

Buch LH (2011) Genetic improvement of functional traits in dairy cattle breeding schemes with genomic selection. PhD Thesis, Aarhus University, Denmark.

Buch LH, Sørensen AC, Lassen J, Berg P, Eriksson JÅ, Jakobsen JH, Sørensen MK (2011) Hygiene-related and feed-related hoof diseases show different patterns of genetic correlations to clinical mastitis and female fertility. Journal of Dairy Science 94, 1540–1551.
Hygiene-related and feed-related hoof diseases show different patterns of genetic correlations to clinical mastitis and female fertility.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXmvFeit7s%3D&md5=68474d38077d8a9a227a41a6bfc6fe32CAS |

Daetwyler HD, Villanueva B, Bijma P, Woolliams JA (2007) Inbreeding in genome-wide selection. Journal of Animal Breeding and Genetics 124, 369–376.
Inbreeding in genome-wide selection.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD2sjjvFyhsQ%3D%3D&md5=5ba3cf2631fc8649c8ee5d81a416cc46CAS |

Daetwyler HD, Wiggans GR, Hayes BJ, Woolliams JA, Goddard ME (2011) Imputation of missing genotypes from sparse to high density using long-range phasing. Genetics 189, 317–327.
Imputation of missing genotypes from sparse to high density using long-range phasing.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXhtlehsbvK&md5=e4d13a8264ab562e9b67c528d2066210CAS |

de Roos APW, Hayes BJ, Spelman RJ, Goddard ME (2008) Linkage disequilibrium and persistence of phase in Holstein–Friesian, Jersey and Angus cattle. Genetics 179, 1503–1512.
Linkage disequilibrium and persistence of phase in Holstein–Friesian, Jersey and Angus cattle.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD1cvmsFeltw%3D%3D&md5=19f65e22eddf6efe5d7aa914e77a7a3cCAS |

de Roos APW, Schrooten C, Veerkamp RF, van Arendonk JAM (2011) Effects of genomic selection on genetic improvement, inbreeding, and merit of young versus proven bulls. Journal of Dairy Science 94, 1559–1567.
Effects of genomic selection on genetic improvement, inbreeding, and merit of young versus proven bulls.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXmvFeit7k%3D&md5=807608252a02edaad1fd5800bb7045d8CAS |

Dekkers JCM (2007) Prediction of response from marker-assisted and genomic selection using selection index theory. Journal of Animal Breeding and Genetics 124, 331–341.
Prediction of response from marker-assisted and genomic selection using selection index theory.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD2sjjvFyiuw%3D%3D&md5=02eb2d1285b7c61038e0cbab1d4fdb2eCAS |

Druet T, Georges M (2010) A hidden Markov model combining linkage and linkage disequilibrium information for haplotype reconstruction and quantitative trait locus fine mapping. Genetics 184, 789–798.
A hidden Markov model combining linkage and linkage disequilibrium information for haplotype reconstruction and quantitative trait locus fine mapping.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3cXhsFOnurvN&md5=115ebea4006f5cc985537ecc2316ad79CAS |

Grundy B, Villanueva B, Woolliams JA (1998) Dynamic selection procedures for constrained inbreeding and their consequences for pedigree development. Genetical Research 72, 159–168.
Dynamic selection procedures for constrained inbreeding and their consequences for pedigree development.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1MXmvVantQ%3D%3D&md5=622d19af4902941473e310a74db30513CAS |

Habier D, Fernando RL, Dekkers JCM (2007) The impact of genetic relationship information on genome assisted breeding values. Genetics 177, 2389–2397.

Harris BL, Johnson DL, Spelman RJ (2008) Genomic selection in New Zealand and the implications for national genetic evaluation. In ‘Proceedings of the 36th ICAR session’, Niagara Falls, NY. (Ed. JD Sattler) pp. 325–330. (ICAR, Via G. Tomassetti 3, 1/A, 00161 Rome)

Hickey J, Kinghorn B, Tier B, Wilson J, Dunstan N, van der Werf J (2011) A combined long-range phasing and long haplotype imputation method to impute phase for SNP genotypes. Genetics, Selection, Evolution. 43, 12
A combined long-range phasing and long haplotype imputation method to impute phase for SNP genotypes.Crossref | GoogleScholarGoogle Scholar |

König S, Swalve HH (2009) Application of selection index calculations to determine selection strategies in genomic breeding programs. Journal of Dairy Science 92, 5292–5303.
Application of selection index calculations to determine selection strategies in genomic breeding programs.Crossref | GoogleScholarGoogle Scholar |

König S, Simianer H, Willam A (2009) Economic evaluation of genomic breeding programs. Journal of Dairy Science 92, 382–391.

Lillehammer M, Meuwissen THE, Sonesson AK (2011) A comparison of dairy cattle breeding designs that use genomic selection. Journal of Dairy Science 94, 493–500.
A comparison of dairy cattle breeding designs that use genomic selection.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXjslCms7w%3D&md5=87a49f6139c38713814092c57c639167CAS |

Lund MS, de Roos APW, de Vries AG, Druet T, Ducrocq V, Fritz S, Guillame F, Guldbrandsten B, Liu Z, Reents R, Schrooten C, Seefried M, Su G (2010) Improving genomic prediction by Eurogenomics collaboration. In ‘10th world conference of genetics applied to livestock production’, Leipzig, Germany. (German Society for Animal Science) p. 880. CD-ROM Communication paper.

Mc Hugh N, Meuwissen THE, Cromie AR, Sonesson AK (2011) Use of female information in dairy cattle breeding programs. Journal of Dairy Science 94, 4109–4118.
Use of female information in dairy cattle breeding programs.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXpsVylurY%3D&md5=56199aac99229b6c68339bf5307725edCAS |

Meuwissen THE (1997) Maximizing the response of selection with a predefined rate of inbreeding. Journal of Animal Science 75, 934–940.

Meuwissen THE, Hayes BJ, Goddard ME (2001) Prediction of total genetic value using genome-wide dense marker maps. Genetics 157, 1819–1829.

Nicholas FW, Smith C (1983) Increased rates of genetic change in dairy-cattle by embryo transfer and splitting. Animal Production 36, 341–353.
Increased rates of genetic change in dairy-cattle by embryo transfer and splitting.Crossref | GoogleScholarGoogle Scholar |

Pedersen LD, Sørensen AC, Berg P (2009a) Marker-assisted selection can reduce true as well as pedigree-estimated inbreeding. Journal of Dairy Science 92, 2214–2223.
Marker-assisted selection can reduce true as well as pedigree-estimated inbreeding.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXlsFymsL8%3D&md5=e23d0b852d1658004096383d0fbc7f5dCAS |

Pedersen LD, Sørensen AC, Henryon M, Ansari-Mahyari S, Berg P (2009b) ADAM: a computer program to simulate selective breeding schemes for animals. Livestock Science 121, 343–344.
ADAM: a computer program to simulate selective breeding schemes for animals.Crossref | GoogleScholarGoogle Scholar |

Pedersen LD, Sørensen AC, Berg P (2010a) Marker-assisted selection reduces expected inbreeding but can result in large effects of hitchhiking. Journal of Animal Breeding and Genetics 127, 189–198.
Marker-assisted selection reduces expected inbreeding but can result in large effects of hitchhiking.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BC3cvpsVOitA%3D%3D&md5=bc65f9f90bc432595bd429a55b29ece7CAS |

Pedersen LD, Sorensen MK, Berg P, Andersen JV, Sorensen AC (2010b) Using sexed semen has limited effect on genetic gain in a dairy cattle breeding scheme using genomic selection. In ‘10th world conference of genetics applied to livestock production’, Leipzig, Germany. (German Society for Animal Science) p. 714. CD-ROM Communication.

Pryce JE, Goddard ME, Raadsma HW, Hayes BJ (2010) Deterministic models of breeding scheme designs that incorporate genomic selection. Journal of Dairy Science 93, 5455–5466.
Deterministic models of breeding scheme designs that incorporate genomic selection.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXnvVSjtQ%3D%3D&md5=f8d02320f524c9c2172ba33239724eb1CAS |

Pryce JE, Arias J, Bowman PJ, Macdonald KA, Waghorn GC, Wales WJ, Williams YL, Spelman RJ, Hayes BJ (2011a) Accuracy of genomic selection for residual feed intake and 250-day liveweight in dairy heifers using high-density (630k) SNP. Proceedings of the Association for Advancement of Animal Breeding and Genetics. 19, 367–370.

Pryce JE, Gredler B, Bolormaa S, Bowman PJ, Egger-Danner C, Fuerst C, Emmerling R, Sölkner J, Goddard ME, Hayes BJ (2011b) Genomic selection using a multi-breed, across-country reference population. Journal of Dairy Science 94, 2625–2630.
Genomic selection using a multi-breed, across-country reference population.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXnvFCgt74%3D&md5=f859626fc4067fb0fbf8ad4316404129CAS |

Robertson A, Rendel JM (1950) The use of progeny testing with artificial insemination in dairy cattle. Journal of Genetics 50, 21–31.
The use of progeny testing with artificial insemination in dairy cattle.Crossref | GoogleScholarGoogle Scholar |

Schaeffer LR (2006) Strategy for applying genome-wide selection in dairy cattle. Journal of Animal Breeding and Genetics 123, 218–223.
Strategy for applying genome-wide selection in dairy cattle.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD28vlvFCitA%3D%3D&md5=baf38b72655ef765385a0c797a65c8a6CAS |

Sonesson A, Meuwissen T (2009) Testing strategies for genomic selection in aquaculture breeding programs. Genetics, Selection, Evolution. 41, 37
Testing strategies for genomic selection in aquaculture breeding programs.Crossref | GoogleScholarGoogle Scholar |

Sonesson AK, Woolliams JA, Meuwissen THE (2010) Maximising genetic gain whilst controlling rates of genomic inbreeding using genomic optimum contribution selection. In ‘World congress of genetics applied to livestock production’, Leipzig, Germany. (German Society for Animal Science) p. 892. CD-ROM Communication.

Sorensen AC, Sorensen MK (2009) Inbreeding rates in breeding programs with different strategies for using genomic selection. Interbull Bulletin 40, 94–97.

Soyeurt H, Dehareng F, Gengler N, McParland S, Wall E, Berry DP, Coffey M, Dardenne P (2011) Mid-infrared prediction of bovine milk fatty acids across multiple breeds, production systems, and countries. Journal of Dairy Science 94, 1657–1667.
Mid-infrared prediction of bovine milk fatty acids across multiple breeds, production systems, and countries.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXnvFChtro%3D&md5=88f0183d5a851bd8a3297d96481389abCAS |

VanRaden P, Sullivan P (2010) International genomic evaluation methods for dairy cattle. Genetics, Selection, Evolution. 42, 7
International genomic evaluation methods for dairy cattle.Crossref | GoogleScholarGoogle Scholar |

VanRaden PM, O’Connell JR, Wiggans GR, Weigel KA (2011) Genomic evaluations with many more genotypes. Genetics, Selection, Evolution. 43, 10
Genomic evaluations with many more genotypes.Crossref | GoogleScholarGoogle Scholar |

Villanueva B, Bijma P, Woolliams JA (2000) Optimal mass selection policies for schemes with overlapping generations and restricted inbreeding. Genetics, Selection, Evolution. 32, 339–355.
Optimal mass selection policies for schemes with overlapping generations and restricted inbreeding.Crossref | GoogleScholarGoogle Scholar | 1:STN:280:DC%2BD2c%2Fms1Kquw%3D%3D&md5=2fd65359613cd6db3a61aa050ee54edcCAS |

Winkelman AM, Spelman RJ (2010) Response using genome-wide selection in dairy cattle breeding schemes. In ‘World congress for genetics applied to livestock production’, Leipzig, Germany. (German Society for Animal Science) p. 0290. CD-ROM Communication 714.

Woolliams JA, Pong-Wong R, Villanueva B (2002) Strategic optimisation of short- and long-term gain and inbreeding in MAS and non-MAS schemes. In ‘7th world congress of genetics applied to livestock production’, Montpellier, France. CD-ROM Communication no. 23–02.

Wray NR, Goddard ME (1994) Increasing long-term response to selection. Genetics, Selection, Evolution. 26, 431–451.
Increasing long-term response to selection.Crossref | GoogleScholarGoogle Scholar |