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RESEARCH ARTICLE (Open Access)

Development of Angus SteerSELECT: a genomic-based tool to identify performance differences of Australian Angus steers during feedlot finishing: Phase 1 validation

Brad C. Hine https://orcid.org/0000-0001-5037-4703 A D , Christian J. Duff https://orcid.org/0000-0002-3072-1736 B , Andrew Byrne B , Peter Parnell B , Laercio Porto-Neto C , Yutao Li C , Aaron B. Ingham C and Antonio Reverter https://orcid.org/0000-0002-4681-9404 C
+ Author Affiliations
- Author Affiliations

A CSIRO Agriculture & Food, F.D. McMaster Laboratory, Chiswick, New England Highway, Armidale, NSW 2350, Australia.

B Angus Australia, 86 Glen Innes Road, Armidale, NSW 2350, Australia.

C CSIRO Agriculture & Food, Queensland Bioscience Precinct, 306 Carmody Road, St Lucia, Brisbane, Qld 4067, Australia.

D Corresponding author. Email: brad.hine@csiro.au

Animal Production Science - https://doi.org/10.1071/AN21051
Submitted: 4 February 2021  Accepted: 2 June 2021   Published online: 19 August 2021

Journal Compilation © CSIRO 2021 Open Access CC BY

Abstract

Context: Genomic-based technologies are allowing commercial beef producers to predict the genetic merit of individual animals of unknown pedigree with increased ease and accuracy. Genomic selection tools that can accurately predict the feedlot and carcass performance of steers have the potential to improve profitability for the beef supply chain.

Aims: To validate the ability of the Angus SteerSELECT genomic product to predict differences in performance of Australian Angus steers, in terms of carcass weight, marbling score, ossification score and carcass value, using a short-fed (100 days) or long-fed (270 days) finishing protocol at a commercial feedlot.

Methods: A reference population of 2763 Australian Angus steers was used to generate genomic prediction equations for three carcass traits, namely, carcass weight, marbling score and ossification. The accuracy and bias of genomic predictions of breeding values were then evaluated using a validation population of 522 Angus steers, either short- or long-fed at a commercial feedlot, by comparing breeding values to measured phenotypes. The potential economic benefits for feedlot operators when using Angus SteerSELECT were estimated on the basis of the ability of the tool to predict the carcass value of steers in the validation population.

Key results: The accuracy of genomic predictions of breeding values for carcass weight, marbling score and ossification score were 0.752, 0.723 and 0.734 respectively. When steers were ranked in quartiles for predicted carcass value, calculated using genomic predictions of breeding values for carcass weight and marbling score, the least-square mean carcass value for steers in each quartile, from bottom 25% predicted performers to top 25% predicted performers, were estimated at A$1794, A$1977, A$2021 and A$2148 for short-fed steers and A$3546, A$3780, A$3864 and A$4258 for long-fed steers. Differences in the carcass value least-squares mean between the bottom and top quartile were highly significant (P < 0.001) for both short-fed and long-fed steers.

Conclusions: Genomic prediction equations used in Angus SteerSELECT can predict differences in carcass weight, marbling score, ossification score and carcass value in both short-fed and long-fed Australian Angus steers.

Implications: Genomic selection tools that can predict differences in performance, in terms of growth and carcass characteristics, of commercial feedlot cattle have the potential to significantly increase profitability for the beef supply chain by improving the quality and consistency of the beef products they produce.

Keywords: beef cattle, feedlot performance, carcass, genomic predictions, accuracy.


References

Angus Australia (2019) Australian beef breeding insights. Available at https://www.angusaustralia.com.au/australian-beef-breeding-insights/. [Verified 2 February 2021]

Boddhireddy P, Kelly MJ, Northcutt S, Prayaga KC, Rumph J, DeNise S (2014) Genomic predictions in Angus cattle: comparisons of sample size, response variables, and clustering methods for cross-validation. Journal of Animal Science 92, 485–497.
Genomic predictions in Angus cattle: comparisons of sample size, response variables, and clustering methods for cross-validation.Crossref | GoogleScholarGoogle Scholar | 24431338PubMed |

Bolormaa S, Pryce JE, Kemper K, Savin K, Hayes BJ, Barendse W, Zhang Y, Reich CM, Mason BA, Bunch RJ, Harrison BE, Reverter A, Herd RM, Tier B, Graser HU, Goddard ME (2013) Accuracy of prediction of genomic breeding values for residual feed intake, carcass and meat quality traits in Bos taurus, Bos indicus and composite beef cattle. Journal of Animal Science 91, 3088–3104.
Accuracy of prediction of genomic breeding values for residual feed intake, carcass and meat quality traits in Bos taurus, Bos indicus and composite beef cattle.Crossref | GoogleScholarGoogle Scholar | 23658330PubMed |

Chen L, Vinsky M, Li C (2015) Accuracy of predicting genomic breeding values for carcass merit traits in Angus and Charolais beef cattle. Animal Genetics 46, 55–59.
Accuracy of predicting genomic breeding values for carcass merit traits in Angus and Charolais beef cattle.Crossref | GoogleScholarGoogle Scholar | 25393962PubMed |

Clark SA, Hickey JM, Daetwyler HD, van der Werf JHJ (2012) The importance of information on relatives for the prediction of genomic breeding values and the implications for the makeup of reference data sets in livestock breeding schemes. Genetics, Selection, Evolution 44, 4
The importance of information on relatives for the prediction of genomic breeding values and the implications for the makeup of reference data sets in livestock breeding schemes.Crossref | GoogleScholarGoogle Scholar | 22321529PubMed |

Garrick DJ, Taylor JF, Fernando RL (2009) Deregressing estimated breeding values and weighting information for genomic regression analyses. Genetics, Selection, Evolution 41, 55
Deregressing estimated breeding values and weighting information for genomic regression analyses.Crossref | GoogleScholarGoogle Scholar | 20043827PubMed |

Goddard M, Hayes B (2009) Mapping genes for complex traits in domestic animals and their use in breeding programs. Nature Reviews Genetics 10, 381–391.
Mapping genes for complex traits in domestic animals and their use in breeding programs.Crossref | GoogleScholarGoogle Scholar | 19448663PubMed |

Hine BC, Bell AM, Niemeyer DOD, Duff CJ, Butcher NM, Dominik S, Ingham AB, Colditz IG (2019) Immune competence traits assessed during the stress of weaning are heritable and favourably genetically correlated with temperament traits in Angus cattle. Journal of Animal Science 97, 4053–4065.
Immune competence traits assessed during the stress of weaning are heritable and favourably genetically correlated with temperament traits in Angus cattle.Crossref | GoogleScholarGoogle Scholar | 31581299PubMed |

Jeyaruban MG, Johnston DJ, Walmsley BJ (2017) Genetic and phenotypic characterization of MSA index and its association with carcase and meat quality traits in Angus and Brahman cattle. In ‘Proceedings of the Association for the Advancement of Animal Breeding and Genetics’. (Ed. L Porton-Neto) pp. 313–316. (Townsville, Qld, Australia).

Lane J, Jubb T, Shephard R, Webb-Ware J, Fordyce G (2015) Priority list of endemic diseases for the red meat industries (MLA Project B.AHE.0010). Meat & Livestock Australia. Available at https://www.mla.com.au/research-and-development/search-rd-reports/final-report-details/Animal-Health-and-Biosecurity/Priority-list-of-endemic-diseases-for-the-red-meat-industries/2895 [Verified 1 February 2021]

Legarra A, Reverter A (2018) Semi-parametric estimates of population accuracy and bias of predictions of breeding values and future phenotypes using the LR method. Genetics, Selection, Evolution 50, 53
Semi-parametric estimates of population accuracy and bias of predictions of breeding values and future phenotypes using the LR method.Crossref | GoogleScholarGoogle Scholar | 30400768PubMed |

Macedo FLL, Reverter A, Legarra A (2020) Behavior of the Linear Regression method to estimate bias and accuracies with correct and incorrect genetic evaluation models. Journal of Dairy Science 103, 529–544.
Behavior of the Linear Regression method to estimate bias and accuracies with correct and incorrect genetic evaluation models.Crossref | GoogleScholarGoogle Scholar |

Magalhães AFB, Schenkel FS, Garcia DA, Gordo DGM, Tonussi RL, Espigolan R, de Oliveira Silva RM, Braz CU, Fernandes Júnior GA, Baldi F, Carvalheiro R, Boligon AA, de Oliveira HN, Chardulo LAL, de Albuquerque LG (2019) Genomic selection for meat quality traits in Nelore cattle. Meat Science 148, 32–37.
Genomic selection for meat quality traits in Nelore cattle.Crossref | GoogleScholarGoogle Scholar | 30296711PubMed |

Mehrban H, Lee DH, Moradi MH, IlCho C, Naserkheil M, Ibáñez-Escriche N (2017) Predictive performance of genomic selection methods for carcass traits in Hanwoo beef cattle: impacts of the genetic architecture. Genetics, Selection, Evolution 49, 1
Predictive performance of genomic selection methods for carcass traits in Hanwoo beef cattle: impacts of the genetic architecture.Crossref | GoogleScholarGoogle Scholar | 28093066PubMed |

Meuwissen TH, Hayes BJ, Goddard ME (2001) Prediction of total genetic value using genome-wide dense marker maps. Genetics 157, 1819–1829.
Prediction of total genetic value using genome-wide dense marker maps.Crossref | GoogleScholarGoogle Scholar | 11290733PubMed |

Meuwissen T, Hayes B, Goddard M (2013) Accelerating improvement of livestock with genomic selection. Annual Review of Animal Biosciences 1, 221–237.
Accelerating improvement of livestock with genomic selection.Crossref | GoogleScholarGoogle Scholar | 25387018PubMed |

Meuwissen T, Hayes B, Goddard M (2016) Genomic selection: a paradigm shift in animal breeding. Animal Frontiers 6, 6–14.
Genomic selection: a paradigm shift in animal breeding.Crossref | GoogleScholarGoogle Scholar |

Miller S (2010) Genetic improvement of beef cattle through opportunities in genomics. Brazilian Journal of Animal Science 39, 247–255.
Genetic improvement of beef cattle through opportunities in genomics.Crossref | GoogleScholarGoogle Scholar |

Pérez-Enciso M, Misztal I (2011) Qxpak.5: old mixed model solutions for new genomics problems. BMC Bioinformatics 12, 202
Qxpak.5: old mixed model solutions for new genomics problems.Crossref | GoogleScholarGoogle Scholar | 21612630PubMed |

R Core Team (2013) ‘R: a language and environment for statistical computing.’ (R Foundation for Statistical Computing: Vienna, Austria)

Raszek MM, Guan LL, Plastow GS (2016) Use of Genomic Tools to Improve Cattle Health in the Context of Infectious Diseases. Frontiers in Genetics 7, 30
Use of Genomic Tools to Improve Cattle Health in the Context of Infectious Diseases.Crossref | GoogleScholarGoogle Scholar | 27014337PubMed |

Reverter A, Hine BC, Porto-Neto L, Li Y, Duff CJ, Dominik S, Ingham AB (2021) ImmuneDEX: a strategy for the genetic improvement of immune competence in Australian Angus cattle. Journal of Animal Science 99, skaa384
ImmuneDEX: a strategy for the genetic improvement of immune competence in Australian Angus cattle.Crossref | GoogleScholarGoogle Scholar | 33677583PubMed |

VanRaden PM (2008) Efficient methods to compute genomic predictions. Journal of Dairy Science 91, 4414–4423.
Efficient methods to compute genomic predictions.Crossref | GoogleScholarGoogle Scholar | 18946147PubMed |

Weber KL, Thallman RM, Keele JW, Snelling WM, Bennett GL, Smith TPL, McDaneld TG, Allan MF, Van Eenennaam AL, Kuehn LA (2012) Accuracy of genomic breeding values in multibreed beef cattle populations derived from deregressed breeding values and phenotypes. Journal of Animal Science 90, 4177–4190.
Accuracy of genomic breeding values in multibreed beef cattle populations derived from deregressed breeding values and phenotypes.Crossref | GoogleScholarGoogle Scholar | 22767091PubMed |