A genome-wide scan for candidate lethal variants in Thoroughbred horses

Todd, Evelyn T.; Thomson, Peter; Hamilton, Natasha A.; Ang, Rachel A.; Lindgren, Gabriella; Viklund, Åsa; Eriksson, Staffan; Mikko, Sofia; Strand, Eric; Velie, Brandon D.

doi:10.1101/2020.05.04.077008

Cited by 1 publication

(3 citation statements)

References 79 publications

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“…In cattle, several potentially deleterious haplotypes have been discovered based on the principle of missing homozygosity [31][32][33][34]. On the contrary, in horses, this approach to detect lethal variants has only been used to a limited extent [37][38][39]. A major shortcoming of such analyses is that, especially for variants with a low frequency, a large sample size is necessary to statistically prove missing homozygosity.…”

Section: Identification Of Putative Lethal Variantsmentioning

confidence: 99%

“…They detected a couple of variants that potentially influenced stallion fertility, including a splice-site disruption variant in the NOTCH1 gene [37]. Furthermore, a haplotype in the LY49B gene was detected from genotype data on Thoroughbreds that showed a deficiency of homozygotes, and it represents a strong candidate for containing a recessive lethal mutation [38].…”

Section: Introductionmentioning

confidence: 99%

“…The detection of lethal variants can also aid in diminishing the prevalence of genetic disorders and in the optimisation of fertility rates in horses [38,39]. Therefore, we applied an approach based on missing homozygosity to identify putative lethal mutations.…”

Section: Introductionmentioning

confidence: 99%

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Development and validation of a horse reference panel for genotype imputation

et al. 2022

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Background Genotype imputation is a cost-effective method to generate sequence-level genotypes for a large number of animals. Its application can improve the power of genomic studies, provided that the accuracy of imputation is sufficiently high. The purpose of this study was to develop an optimal strategy for genotype imputation from genotyping array data to sequence level in German warmblood horses, and to investigate the effect of different factors on the accuracy of imputation. Publicly available whole-genome sequence data from 317 horses of 46 breeds was used to conduct the analyses. Results Depending on the size and composition of the reference panel, the accuracy of imputation from medium marker density (60K) to sequence level using the software Beagle 5.1 ranged from 0.64 to 0.70 for horse chromosome 3. Generally, imputation accuracy increased as the size of the reference panel increased, but if genetically distant individuals were included in the panel, the accuracy dropped. Imputation was most precise when using a reference panel of multiple but related breeds and the software Beagle 5.1, which outperformed the other two tested computer programs, Impute 5 and Minimac 4. Genome-wide imputation for this scenario resulted in a mean accuracy of 0.66. Stepwise imputation from 60K to 670K markers and subsequently to sequence level did not improve the accuracy of imputation. However, imputation from higher density (670K) was considerably more accurate (about 0.90) than from medium density. Likewise, imputation in genomic regions with a low marker coverage resulted in a reduced accuracy of imputation. Conclusions The accuracy of imputation in horses was influenced by the size and composition of the reference panel, the marker density of the genotyping array, and the imputation software. Genotype imputation can be used to extend the limited amount of available sequence-level data from horses in order to boost the power of downstream analyses, such as genome-wide association studies, or the detection of embryonic lethal variants.

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