Register      Login
Animal Production Science Animal Production Science Society
Food, fibre and pharmaceuticals from animals
Shopping Cart: ( empty )
You are here: Home > Journals > AN > AN19123
RESEARCH ARTICLE
Contents Vol 60(14)

Effect of controlling future rate of inbreeding on expected genetic gain and genetic variability in small livestock populations

S. I. Mwangi A , T. K. Muasya A C , E. D. Ilatsia B and A. K. Kahi A
+ Author Affiliations
- Author Affiliations

A Animal Breeding and Genomics Group, Department of Animal Sciences, Egerton University, PO Box 536, 20115 Egerton, Kenya.

B Kenya Agricultural Livestock and Research Organisation, Dairy Research Institute, PO Box 25, 20117, Naivasha, Kenya.

C Corresponding author. Email: muasyakt@yahoo.com

Animal Production Science 60(14) 1681-1686 https://doi.org/10.1071/AN19123
Submitted: 5 March 2019  Accepted: 13 March 2020   Published: 19 May 2020

Abstract

Context: In the present study we assessed the use of average relationship as a means to control future rates of inbreeding in small cattle closed nucleus and its effect on genetic gain for milk yield as a means of managing genetic variability in livestock improvement programs.

Aim: The aim was to strike an ideal balance between genetic gain and loss of genetic variability for Sahiwal population.

Methods: A total of 8452 milk yield records of Sahiwal cows from National Sahiwal Stud, Kenya, were used to estimate breeding values and 19 315 records used to estimate average relatedness of all individuals. The estimated breeding values and genetic relationships were then used to optimise individual genetic contributions between the best two males and the top 210 females in 2000–2008-year group, as well as between the best four, six and eight males and top, 420, 630 and 840 females based on estimated breeding values for lactation milk yield. Weights on genetic merit and average relationship considered in this study were (1, 0), (1, −300), (1, −500), (1, −1000) and (0, −1).

Key results: When the best sires were selected and used for mating disregarding average relationship with their mates i.e. (0, –1), genetic gain of up to 213 kg was realised accompanied by a rate of inbreeding per generation of 4%. Restricting average relationship alone i.e. (0, –1), resulted in a future rate of inbreeding of 1.6% and average merit of 154 when top two sires were used for breeding. At the same restriction level but using eight top sires, the rate of inbreeding per generation was 0.9% accompanied by an average merit of 128.2 kg. Controlling average relationship between mates resulted in increased genetic variability i.e. lower rate of inbreeding though average merit declined.

Conclusion: A rate of inbreeding per generation of <1% is required for a population to maintain its long-term viability. For this level to be attained, the size of the breeding population should be increased from the current two sires vs 210 dams to eight sires vs 840 dams.

Implications: Practical implications for closed nucleus programs such as the Sahiwal program in Kenya should include expanding the nucleus to comprise other institutional and privately-owned herds.

Additional keywords: average genetic merit, Kenyan Sahiwal, optimum contribution, relationship.


References

Berg P, Sørensen MK, Nielsen J (2007) ‘EVA interface user manual.’ Available at http://www.fao.org/tempref/AG/Reserved/DAD-Net/CIHEAM_Jan2010_lectures/TORO,%20MIGUEL%20ANGEL/EVA%20Software.pdf [Verified May 2020].

Colleau JJ (2002) An indirect approach to the extensive calculation of relationship coefficients. Genetics, Selection, Evolution 34, 409–421.
An indirect approach to the extensive calculation of relationship coefficients.Crossref | GoogleScholarGoogle Scholar | 12270102PubMed |

FAO (1998) ‘Secondary guidelines for development of national farm animal genetic resources management plans: management of small populations at risk.’ (FAO: Rome, Italy). Available at http://www.fao.org/docrep [Verified October 2016]

Falconer DS, Mackay TFC, Frankham R (1996) Introduction to quantitative genetics. (4th edn) Trends in Genetics 12, 280–288.
Introduction to quantitative genetics. (4th edn)Crossref | GoogleScholarGoogle Scholar |

Fernández J, Toro MA, Mäki-Tanila A (2011) Management of genetic diversity in small farm animal populations. Animal 5, 1684–1698.
Management of genetic diversity in small farm animal populations.Crossref | GoogleScholarGoogle Scholar | 22440408PubMed |

Franklin IR, Frankham R (1998) How large must populations be to retain evolutionary potential? Animal Conservation 1, 69–70.
How large must populations be to retain evolutionary potential?Crossref | GoogleScholarGoogle Scholar |

Gandini G, Stella A, Del Corvo M, Jansen GB (2014) Selection with inbreeding control in simulated young bull schemes for local dairy cattle breeds. Journal of Dairy Science 97, 1790–1798.
Selection with inbreeding control in simulated young bull schemes for local dairy cattle breeds.Crossref | GoogleScholarGoogle Scholar | 24440254PubMed |

Gicheha MG, Kosgey IS, Bebe BO, Kahi A (2006) Evaluation of the efficiency of alternative two‐tier nucleus breeding systems designed to improve meat sheep in Kenya. Journal of Animal Breeding and Genetics 123, 247–257.
Evaluation of the efficiency of alternative two‐tier nucleus breeding systems designed to improve meat sheep in Kenya.Crossref | GoogleScholarGoogle Scholar | 16882091PubMed |

Grundy B, Villanueva B, Woolliams JA (2000) Dynamic selection for maximizing response with constrained inbreeding in schemes with overlapping generations. Animal Science 70, 373–382.
Dynamic selection for maximizing response with constrained inbreeding in schemes with overlapping generations.Crossref | GoogleScholarGoogle Scholar |

Gutiérrez JP, Altarriba J, Díaz C, Quintanilla R, Cañón J, Piedrafita J (2003) Pedigree analysis of eight Spanish beef cattle breeds. Genetics, Selection, Evolution. 35, 43–63.
Pedigree analysis of eight Spanish beef cattle breeds.Crossref | GoogleScholarGoogle Scholar | 12605850PubMed |

Henrique C, Malhado M, Claudia A, Malhado M, Luiz P, Carneiro S (2013) Inbreeding depression on production and reproduction traits of buffaloes from Brazil. Animal Science Journal 84, 289–295.
Inbreeding depression on production and reproduction traits of buffaloes from Brazil.Crossref | GoogleScholarGoogle Scholar |

Henryon M, Ostersen T, Ask B, Sørensen AC, Berg P (2015) Most of the long-term genetic gain from optimum-contribution selection can be realised with restrictions imposed during optimisation. Genetics, Selection, Evolution. 47, 21
Most of the long-term genetic gain from optimum-contribution selection can be realised with restrictions imposed during optimisation.Crossref | GoogleScholarGoogle Scholar | 25887703PubMed |

Hinrichs D, Wetten M (2006) An algorithm to compute optimal genetic contributions in selection programs with large numbers of candidates. Journal of Animal Science 84, 3212–3218.
An algorithm to compute optimal genetic contributions in selection programs with large numbers of candidates.Crossref | GoogleScholarGoogle Scholar | 17093213PubMed |

Ilatsia ED, Roessler R, Kahi AK, Piepho HP, Zárate AV (2011) Evaluation of basic and alternative breeding programs for Sahiwal cattle genetic resources in Kenya. Animal Production Science 51, 682–694.
Evaluation of basic and alternative breeding programs for Sahiwal cattle genetic resources in Kenya.Crossref | GoogleScholarGoogle Scholar |

Kahi AK, Nitter G, Gall CF (2004) Developing breeding schemes for pasture based dairy production systems in Kenya: II. Evaluation of alternative objectives and schemes using a two-tier open nucleus and young bull system. Livestock Production Science 88, 179–192.
Developing breeding schemes for pasture based dairy production systems in Kenya: II. Evaluation of alternative objectives and schemes using a two-tier open nucleus and young bull system.Crossref | GoogleScholarGoogle Scholar |

Kamiti DN (2014) Evaluation of genetic diversity of Sahiwal cattle in Kenya. Master of Science, Department of Animal Sciences thesis, Egerton University, Kenya.

Kearney JF, Wall E, Villanueva B, Coffey MP (2004) Inbreeding trends and application of optimized selection in the UK Holstein population. Journal of Dairy Science 87, 3503–3509.
Inbreeding trends and application of optimized selection in the UK Holstein population.Crossref | GoogleScholarGoogle Scholar | 15377628PubMed |

Koenig S, Simianer H (2006) Approaches to the management of inbreeding and relationship in the German Holstein dairy cattle population. Livestock Science 103, 40–53.
Approaches to the management of inbreeding and relationship in the German Holstein dairy cattle population.Crossref | GoogleScholarGoogle Scholar |

König S, Tsehay F, Sitzenstock F, Von Borstel UU, Schmutz M, Preisinger R, Simianer H (2010) Evaluation of inbreeding in laying hens by applying optimum genetic contribution and gene flow theory. Poultry Science 89, 658–667.
Evaluation of inbreeding in laying hens by applying optimum genetic contribution and gene flow theory.Crossref | GoogleScholarGoogle Scholar | 20308397PubMed |

Malhado CHM, Malhado ACM, Carneiro PLS, Ramos AA, Carrillo JA, Pala A (2013) Inbreeding depression on production and reproduction traits of buffaloes from Brazil. Animal Science Journal 84, 289–295.
Inbreeding depression on production and reproduction traits of buffaloes from Brazil.Crossref | GoogleScholarGoogle Scholar |

Melka MG, Schenkel F (2010) Analysis of genetic diversity in four Canadian Swine breeds using pedigree data. Canadian Journal of Animal Science 90, 331–340.
Analysis of genetic diversity in four Canadian Swine breeds using pedigree data.Crossref | GoogleScholarGoogle Scholar |

Meuwissen THE, Sonesson AK (1998) Maximizing the response of selection with a predefined rate of inbreeding: overlapping generations. Journal of Animal Science 76, 2575–2583.
Maximizing the response of selection with a predefined rate of inbreeding: overlapping generations.Crossref | GoogleScholarGoogle Scholar |

Meyn K, Wilkins JV (1974) Breeding for milk in Kenya, with particular reference to the Sahiwal stud. World Animal Review 11, 24–30.

Misztal I, Tsuruta S, Lourenco D, Aguilar I, Legarra A, Vitezica Z (2014) ‘Manual for BLUPF90 family of programs.’ (Athens University Georgia: Athens, GA, USA)

Mrode RA (2014) ‘Linear models for the prediction of animal breeding values’, 4th edn. (CABI: Wallingford, UK)

Muasya TK, Magothe TM, Ilatsia ED, Kariuki JN (2009) Pedigree analysis of the Kenyan Sahiwal cattle based on founder contributions. In ‘Proceedings of 33rd Tanzania Society of Animal Production Conference, Mwanza Tanzania’. pp. 143–141.

Muasya TK, Kariuki JN, Muia JMK (2011) Population structure of the Sahiwal breed in Kenya. Livestock Research for Rural Development 23, 1–5.

Mwangi S, Muasya TK, Ilatsia ED, Kahi AK (2016) Assessment of the genetic variability using pedigree analysis of the Sahiwal breed in Kenya. Animal Genetic Resources 59, 7–14.
Assessment of the genetic variability using pedigree analysis of the Sahiwal breed in Kenya.Crossref | GoogleScholarGoogle Scholar |

Piccoli ML, Braccini Neto J, Brito FV, Campos LT, Bértoli CD, Campos GS, Cobuci JA, McManus CM, Barcellos JOJ, Gama LT (2014) Origins and genetic diversity of British cattle breeds in Brazil assessed by pedigree analyses. Journal of Animal Science 92, 1920–1930.
Origins and genetic diversity of British cattle breeds in Brazil assessed by pedigree analyses.Crossref | GoogleScholarGoogle Scholar | 24671583PubMed |

Rewe TO, Herold P, Kahi AK, Zárate AV (2011) Trait improvement and monetary returns in alternative closed and open nucleus breeding programmes for Boran cattle reared in semi-arid tropics. Livestock Science 136, 122–135.
Trait improvement and monetary returns in alternative closed and open nucleus breeding programmes for Boran cattle reared in semi-arid tropics.Crossref | GoogleScholarGoogle Scholar |

Santana ML, Oliveira PS, Eler JP, Gutiérrez JP, Ferraz JBS (2012) Pedigree analysis and inbreeding depression on growth traits in Brazilian Marchigiana and Bonsmara breeds. Journal of Animal Science 90, 99–108.
Pedigree analysis and inbreeding depression on growth traits in Brazilian Marchigiana and Bonsmara breeds.Crossref | GoogleScholarGoogle Scholar | 21841079PubMed |

Seré C, van der Zijpp A, Persley G, Rege E (2008) Dynamics of livestock production systems, drivers of change and prospects for animal genetic resources. Animal Genetic Resources 42, 3–24.
Dynamics of livestock production systems, drivers of change and prospects for animal genetic resources.Crossref | GoogleScholarGoogle Scholar |

Sonesson AK, Meuwissen THE (2002) Non-random mating for selection with restricted rates of inbreeding and overlapping generations. Genetics, Selection, Evolution. 34, 23–29.
Non-random mating for selection with restricted rates of inbreeding and overlapping generations.Crossref | GoogleScholarGoogle Scholar | 11929623PubMed |

Sørensen MK, Sørensen AC, Baumung R, Borchersen S, Berg P (2008) Optimal genetic contribution selection in Danish Holstein depends on pedigree quality. Livestock Science 118, 212–222.
Optimal genetic contribution selection in Danish Holstein depends on pedigree quality.Crossref | GoogleScholarGoogle Scholar |

Tang GQ, Xue J, Lian MJ, Yang RF, Liu TF, Zeng ZY (2013) Inbreeding and genetic diversity in three imported swine breeds in China using pedigree data. Asian-Australasian Journal of Animal Sciences 26, 755–765.
Inbreeding and genetic diversity in three imported swine breeds in China using pedigree data.Crossref | GoogleScholarGoogle Scholar | 25049847PubMed |

VanRaden PM (1992) Accounting for inbreeding and crossbreeding in genetic evaluation of large populations. Journal of Dairy Science 75, 3136–3144.
Accounting for inbreeding and crossbreeding in genetic evaluation of large populations.Crossref | GoogleScholarGoogle Scholar |

Weigeland KA, Lin SW (2002) Controlling inbreeding by constraining the average relationship between parents of young bulls entering AI progeny test programs. Journal of Dairy Science 85, 2376–2383.
Controlling inbreeding by constraining the average relationship between parents of young bulls entering AI progeny test programs.Crossref | GoogleScholarGoogle Scholar |

Woolliams JA, Berg P, Dagnachew BS, Meuwissen THE (2015) Genetic contributions and their optimization. Journal of Animal Breeding and Genetics 132, 89–99.
Genetic contributions and their optimization.Crossref | GoogleScholarGoogle Scholar | 25823835PubMed |