PSVIII-27 A weighted genomic relationship matrix based on FST prioritized SNPs for genomic selection

Abstract Using low to moderate density SNP marker panels, a substantial increase in accuracy was achieved. The dramatic increase in the number of identified variants due to advances in next generation sequencing was expected to significantly increase the accuracy of genomic selection (GS). Unfortunately, little to no improvement was observed. For mixed model-based approaches, using all SNPs in the panel to compute the observed relationship matrix (G) will not increase accuracy as the additive relationships between individuals can be accurately estimated using a much smaller number of markers. Due to these limitations, variant prioritization has become a necessity to improve accuracy. Further, it has been shown that weighting SNPs when calculating G could be effective in improving the accuracy of GS. FST as a measure population differential has been successfully used to identify genome segments under selection pressure. Consequently, FST could be used to both prioritize SNPs and to derive their relative weight in the calculation of the genomic relationship matrix. A population of 15,000 animals genotyped for 400K SNP markers uniformly-distributed along 10 chromosomes was simulated. A trait with heritability 0.3 genetically controlled by two hundred QTL was generated. The top 20K SNPs based on their FST scores were used either alone or with the remaining 380K SNPs to compute G with or without weighting. When only the top 20K SNPs were used to compute G, two scenarios were considered: 1) equal weights for all SNPs or 2) weights proportional to the SNP FST scores. When all 400K SNP markers were used, different weighting scenarios were evaluated. The results clearly showed that prioritizing SNP markers based on their FST score and using the latter to compute relative weights has increased the genetic similarity between training and validations animals and resulted in more than 5% improvement in the accuracy of GS.