Estimates of autozygosity derived from runs of homozygosity: empirical evidence from selected cattle populations.

Using genome-wide SNP data, we calculated genomic inbreeding coefficients ( F_ROH > _{1 Mb}, F_{ROH > 2 Mb}, F_{ROH > 8 Mb} and F_{ROH > 16 Mb}) derived from runs of homozygosity ( ROH) of different lengths (>1, >2, >8 and > 16 Mb) as well as from levels of homozygosity ( F_HOM). We compared these values of inbreeding coefficients with those calculated from pedigrees ( F_PED) of 1422 bulls comprising Brown Swiss (304), Fleckvieh (502), Norwegian Red (499) and Tyrol Grey (117) cattle breeds. For all four breeds, population inbreeding levels estimated by the genomic inbreeding coefficients F_{ROH > 8 Mb} and F_{ROH > 16 Mb} were similar to the levels estimated from pedigrees. The lowest values were obtained for Fleckvieh ( F_PED = 0.014, F_{ROH > 8 Mb} = 0.019 and F_{ROH > 16 Mb} = 0.008); the highest, for Brown Swiss ( F_PED = 0.048, F_{ROH > 8 Mb} = 0.074 and F_{ROH > 16 Mb} = 0.037). In contrast, inbreeding estimates based on the genomic coefficients F_{ROH > 1 Mb} and F_{ROH > 2 Mb} were considerably higher than pedigree-derived estimates. Standard deviations of genomic inbreeding coefficients were, on average, 1.3-1.7-fold higher than those obtained from pedigrees. Pearson correlations between genomic and pedigree inbreeding coefficients ranged from 0.50 to 0.62 in Norwegian Red (lowest correlations) and from 0.64 to 0.72 in Tyrol Grey (highest correlations). We conclude that the proportion of the genome present in ROH provides a good indication of inbreeding levels and that analysis based on ROH length can indicate the relative amounts of autozygosity due to recent and remote ancestors. [ABSTRACT FROM AUTHOR]