Inbreeding in a Population of Polish Holstein-Friesian Young Bulls Before and After Genomic Selection

Bjelland D., Weigel K., Vukasinovic N., Nkrumah J. (2013). Evaluation of inbreeding depression in Holstein cattle using whole-genome SNP markers and alternative measures of genomic inbreeding. J. Dairy Sci., 96: 4697–4706.Search in Google Scholar

Boichard D. (2007). PEDIG – a Fortran package for pedigree analysis suited for large populations. Proc. 7th World Congress on Genetics Applied to Livestock Production, Montpellier.Search in Google Scholar

Cassell B., Adamec V., Pearson R. (2003). Maternal and fetal inbreeding depression for 70-day nonreturn and calving rate in Holsteins and Jerseys. J. Dairy Sci., 86: 2977–2983.Search in Google Scholar

Croquet C., Mayers P., Gillson A., Vanderick S., Gengler N. (2006). Inbreeding depression for global and partial economic indexes, production, type and functional traits. J. Dairy Sci., 89: 2257–2267.Search in Google Scholar

Daetwyler H.D., Villanueva B., Bijma P., Woolliams J.A. (2007). Inbreeding in genome-wide selection. J. Anim. Breed. Genet., 124: 369–376.Search in Google Scholar

De Roos A., Schrooten C., Veerkamp R., Van Arendonk J. (2011). Effects of genomic selection on genetic improvement, inbreeding, and merit of young versus proven bulls. J. Dairy Sci., 94: 1559–1567.Search in Google Scholar

Doekes H.P., Veerkamp R.F., Bijma P., Hiemstra S.J., Windig J.J. (2018). Trends in genome-wide and region-specific genetic diversity in the Dutch-Flemish Holstein-Friesian breeding program from 1986 to 2015. Genet. Select. Evol., 50: 15.Search in Google Scholar

Filistowicz A. (1977). Genetic analysis of Red-and-White Lowland sires used in Lower Silesia. Implementation study (in Polish). AR Wrocław.Search in Google Scholar

Forutan M., Ansari Mahyari S., Baes C., Melzer N., Schenkel F.S., Sargolzaei M. (2018). Inbreeding and runs of homozygosity before and after genomic selection in North American Holstein cattle. BMC Genomics, 19: 98.Search in Google Scholar

Gurgul A., Szmatoła T., Topolski P., Jasielczuk I., Żukowski K., Bugno-Poniewierska M. (2016). The use of runs of homozygosity for estimation of recent inbreeding in Holstein cattle. J. Appl. Genet., 57: 527–530.Search in Google Scholar

Henderson C. (1975). Rapid method for computing the inverse of the relationship matrix. J. Dairy Sci., 58: 1727–1730.Search in Google Scholar

Henderson C. (1976). A simple method for computing the inverse of a numerator relationship matrix used in prediction of breeding values. Biometrics, 32: 69–83.Search in Google Scholar

Howard J., Pryce J., Baes C., Maltecca C. (2017). Invited review: Inbreeding in the genomics era: Inbreeding, inbreeding depression, and management of genomic variability. J. Dairy Sci., 100: 6009–6024.Search in Google Scholar

Howard D., Pong-Wong R., Knap P., Kremer V., Woolliam J. (2018). Selective advantage of implementing optimal contributions selection and timescales for the convergence of long-term genetic contributions. Genet. Select. Evol., 50: 24.Search in Google Scholar

Jagusiak W., Ż arnecki A. (1994). Relationship and inbreeding in the population of Black and White sires used in artificial insemination (in Polish). Pr. Mat. Zoot., 46: 75–81.Search in Google Scholar

Jagusiak W., Ż arnecki A. (2002). Estimation of inbreeding and relationship among young Polish Black-and-White bulls. Proc. 7th World Congress on Genetics Applied to Livestock Production, Montpellier, France, 19–23.08.2002.Search in Google Scholar

Jagusiak W., Ptak E. (2003). Inbreeding in the population of Polish Black and White cattle (in Polish). Rocz. Nauk. Zoot. Supl., 17: 377–380.Search in Google Scholar

James J., Mc Bride G. (1958). The spread of genes by natural and artificial selection in closed poultry flock. J. Genet., 56: 55–62.Search in Google Scholar

Kania-Gierdziewicz J. (2005). Inbreeding and relationship in Polish Black-and-White sires. J. Appl. Genet., 46: 187–193.Search in Google Scholar

König S., Tsehay F., Sitzenstock F., von Borstel U.U., Schmutz M., Preisinger R., Simianer H. (2010). Evaluation of inbreeding in laying hens by applying optimum genetic contribution and gene flow theory. Poultry Sci., 89: 658–667.Search in Google Scholar

Lutaaya E., Misztal I., Bertrand J., Maybry J. (1999). Inbreeding in populations with incomplete pedigrees. J. Anim. Breed. Genet., 116: 4475–4480.Search in Google Scholar

Meuwissen T., Luo Z. (1992). Computing inbreeding coefficients in large populations. Genet. Sel. Evol., 24: 305–313.Search in Google Scholar

Miglior F., Burnside E., Dekkers J. (1995). Production traits of Holstein cattle: Estimation of nonadditive genetic variance components and inbreeding depression. J. Dairy Sci., 78: 1174–1180.Search in Google Scholar

Oh S. (2012). Evaluation of optimum genetic contribution theory to control inbreeding while maximizing genetic response. Asian-Australas J. Anim. Sci., 25: 299–303.Search in Google Scholar

Panetto J., Gutierres J., Ferraz J., Cunha D., Golden B. (2010). Assessment of inbreeding depression in a Guzerat dairy herd: Effects of individual increase in inbreeding coefficients on production and reproduction. J. Dairy Sci., 93: 4902–4912.Search in Google Scholar

Parland S., Kearney J., Rath M., Berry D. (2007). Inbreeding effects on milk production, calving performance, fertility, and conformation in Irish Holstein-Friesians. J. Dairy Sci., 90: 4411–4419.Search in Google Scholar

Pavlik I., Kadlecik O., Huba J., Peskovicova D., Gondekova M. (2019). Genetic variability of Holstein cattle assessed by pedigree analysis. Slovak J. Anim. Sci., 52: 30–38.Search in Google Scholar

PFHBiPM (2018). Krajowy program hodowlany dla bydła rasy Polskiej Holsztyńsko-Fryzyjskiej w Polsce (in Polish). Available from www.pfhb.pl (accessed 18.11.2018).Search in Google Scholar

Polak G. (2019). Genetic variability of cold-blooded horses participating in genetic resources conservation programs, using pedigree analysis. Ann. Anim. Sci., 19: 49–60.Search in Google Scholar

Różańska-Zawieja J., Nienartowicz-Zdrojewska A., Mucha M., Sobek Z., Stanisławski D., Gierdziewicz M., Kania-Gierdziewicz J. (2013). Evaluation of inbreeding and relationship coefficients in Hovawart dogs and analysis of trends in coat colour changes. Ann. Anim. Sci., 13: 253–262.Search in Google Scholar

Sanchez-Molano E., Pong-Wong R., Banos G. (2016). Genomic-based optimum contribution in conservation and genetic improvement programs with antagonistic fitness and productivity traits. Front Genet., 7: 25.Search in Google Scholar

Sell-Kubiak E., Czarniecki Ł., Strabel T. (2018). Challenges in inbreeding estimation of large populations based on Polish Holstein-Friesian cattle pedigree. J. Appl. Genet., 59: 313–323.Search in Google Scholar

Sewalem A., Kistemaker G., Miglior F., Van Doormaal B. (2006). Analysis of inbreeding and its relationship with functional longevity in Canadian dairy cattle. J. Dairy Sci., 89: 3609–3614.Search in Google Scholar

Smith L., Cassell B., Pearson R. (1998). The effects of inbreeding on the lifetime performance of dairy cattle. J. Dairy Sci., 81: 2729–2737.Search in Google Scholar

Sorensen A., Madsen P., Sorensen M., Berg P. (2006). Udder health shows inbreeding depression in Danish Holsteins. J. Dairy Sci., 89: 4077–4082.Search in Google Scholar

Strabel T. (2001). Reducing inbreeding in modern dairy farming (in Polish). Pr. Mat. Zoot., 59: 25–36.Search in Google Scholar

Świderek W., Fiszdon K., Kacprzak N. (2015). Inbreeding in Pembroke Welsh Corgi population in Poland. Ann. Anim. Sci., 15: 861–866.Search in Google Scholar

Thompson J., Everet R., Hammerschmidt N. (2000). Effects of inbreeding on production and survival in Holsteins. J. Dairy Sci., 83: 1856–1864.Search in Google Scholar

Topolski P. (2008). Insemination of cattle in 2007 (in Polish). IZ PIB, Kraków, 6, 36.Search in Google Scholar

Topolski P. (2017). Inbreeding in dairy cattle (in Polish). Wiad. Zoot., LV: 31–38.Search in Google Scholar

Topolski P., Majewska A. (2006). Insemination of cattle in 2005 (in Polish). IZ PIB, Kraków, 4, 36.Search in Google Scholar

Topolski P., Jagusiak W. (2011). Relatedness analysis in a population of Polish Black-and-White Holstein-Friesian bulls (in Polish). Rocz. Nauk. Zoot., 38: 169–176.Search in Google Scholar

Topolski P., Jagusiak W. (2012). Genetic background of conformation defects in Polish Black-and-White Holstein-Friesian bulls – analysis of phenotypic distribution. Ann. Anim. Sci., 12: 471–482.Search in Google Scholar

Trela J., Wójcik P., Adamik P. (1995). Doskonalenie bydła czarno-białego przy użyciu buhajów odmiany niemieckiej (in Polish). Biul. Inf. IZ, 1: 17–28.Search in Google Scholar

Van Raden P. (1992). Accounting for inbreeding and crossbreeding in genetic evaluation for large populations. J. Dairy Sci., 75: 3136–3144.Search in Google Scholar

Wall E., Brotherstone J., Kearney J., Wooliams J., Coffey M. (2005). Impact of nonadditive genetic effects in the estimation of breeding values for fertility and correlated traits. J. Dairy Sci., 88: 376–385.Search in Google Scholar

Wang Y., Segelke D., Emmerling R., Bennewitz J., Wellmann R.. (2017). Long-term impact of opitmum contribution selection strategies on local livestock breeds with historical introgression using the example of German Angler cattle. G3 (Bethesda), 7: 4009–4018.Search in Google Scholar

Westell R., Quaas R., Van Vleck L. (1988). Genetic groups in an animal model. J. Dairy Sci., 71: 1310–1318.Search in Google Scholar

Wiggans G., Van Raden P., Zuurbier J. (1995). Calculation and use of inbreeding coefficients for genetic evaluation of United States dairy cattle. J. Dairy Sci., 78: 1584–1590.Search in Google Scholar

Woolliams J., Berg P., Dagnachew B., Meuwissen T. (2015). Genetic contributions and their optimization. J. Anim. Breed. Genet., 32: 89–99.Search in Google Scholar

Young C., Seykora A. (1996). Estimates of inbreeding and relationship among registered Holstein females in the United States. J. Dairy Sci., 79: 502–505.Search in Google Scholar