Abstract
Submitted 2020-06-22 | Accepted 2020-07-20 | Available 2020-12-01 https://doi.org/10.15414/afz.2020.23.mi-fpap.347-352 In this study, 68 genotyped purebred cows and bulls of Charolais cattle were used to determine runs of homozygosity (ROH) for evaluation of selection effect on the genome structure. ROH analysis was performed for 41,153 SNPs, and homozygous segments considering a minimum of 15 consecutive SNPs. The aim was to identify if regions of the genome with a high frequency of SNPs in ROH include signatures of selection. The most significant outlier SNPs were found on BTA2, 5, 7 and 19 (11 regions), with a sum of ROH length of 15.85 Mb. These regions contained genes included in various biological processes associated with the functioning of the immune system, growth, reproduction and metabolism. Various quantitative traits loci (QTLs) which affected the characteristics of meat production and reproduction have been identified in these regions. 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Highlights
The Charolais cattle is the popular beef breed worldwide
Selection left footprints in the genome, which were characterised by high genetic differentiation between breeds or an evident decrease in genetic diversity in genomic regions associated with traits that undergone directional selection
This study provided information about potential candidate genes and QTL regions affected by directional selection in Charolais cattle
Summary
The Charolais cattle is the popular beef breed worldwide. Due to the number of animals, Charolais is one of the most numerous beef breeds in Slovakia. The Charolais cattle originated from France and is characterised by a robust and muscular body, excellent feed conversion rate and calving ease. The main breeding goal included the effort to create a population of modern animals with excellent meat production in combination with maintaining good adaptability to the natural environment, excellent maternal characteristics, good ability of grazing and hornless (Jahuey-Martínet et al, 2019; The Breeding Services of the Slovak Republic, s.e., 2019; Pomichal, 2009). Selection left footprints in the genome, which were characterised by high genetic differentiation between breeds or an evident decrease in genetic diversity in genomic regions associated with traits that undergone directional selection. The identification of selection signals involved in phenotypic variations was important for understanding the evolutionary processes and mechanisms that underlie properties that have been subjected to natural or artificial selection (Mastrangelo et al, 2020)
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