Genetics of swayback in American Saddlebred horses.

Extreme lordosis, also called swayback, lowback or softback, can occur as a congenital trait or as a degenerative trait associated with ageing. In this study, the hereditary aspect of congenital swayback was investigated using whole genome association studies of 20 affected and 20 unaffected American Saddlebred (ASB) Horses for 48,165 single-nucleotide polymorphisms (SNPs). A statistically significant association was identified on ECA20 (corrected P=0.017) for SNP BIEC2-532523. Of the 20 affected horses, 17 were homozygous for this SNP when compared to seven homozygotes among the unaffected horses, suggesting a major gene with a recessive mode of inheritance. The result was confirmed by testing an additional 13 affected horses and 166 unaffected horses using 35 SNPs in this region of ECA20 (corrected P=0.036). Combined results for 33 affected horses and 287 non-affected horses allowed identification of a region of homozygosity defined by four SNPs in the region. Based on the haplotype defined by these SNPs, 80% of the 33 affected horses were homozygous, 21% heterozygous and 9% did not possess the haplotype. Among the non-affected horses, 15% were homozygous, 47% heterozygous and 38% did not possess the haplotype. The differences between the two groups were highly significant (P<0.00001). The region defined by this haplotype includes 53 known and predicted genes. Exons from three candidate genes, TRERF1, RUNX2 and CNPY3 were sequenced without finding distinguishing SNPs. The mutation responsible for swayback may lie in other genes or in regulatory regions outside exons. This information can be used by breeders to reduce the occurrence of swayback among their livestock. This condition may serve as a model for investigation of congenital skeletal deformities in other species.

Two SINE families associated with equine microsatellite loci.

BLAST searches of 61 equine microsatellite sequences revealed two related families of retroposons. The first family included seven markers, all of which showed significant homology to the Equine Repetitive Element-1 (ERE-1) Short Interspersed Nucleotide Element (SINE) sequence. Length of homology ranged from 76 to 171 bases with identities to the ERE-1 consensus sequence ranging from 71% to 83%. The second family referred to as Equine Repetitive Element-2 (ERE-2) has a consensus sequence that showed homology to ERE-1 over approximately 60 bases. These 60 bases comprised subunit I. Sequence comparisons for the two retroposons led to the identification of a subunit II, subunit III, as well as the tRNAser subunit. The subunit structure of ERE-1 was tRNAser-I-II. By contrast, the subunit structure of ERE-2 was I-III-III. The nine markers related to ERE-2 showed homology lengths ranging from 84 to 163 bases with identities ranging from 75% to 99%. In addition to being present in microsatellites, ERE-2 appeared in three separate equine genes. It occurred in an intron of DNA-PK, in an untranslated region as well as in the promoter of PGHS, and in the coding region of PAM. The amino acids corresponding to the ERE-2 sequence in PAM were not present in the human or mouse PAM homologs. These amino acids associated with the ERE-2 sequence were present on the cytosolic side of the transmembrane domain of the PAM enzyme. Microsatellite markers in the ERE-1 and ERE-2 families were found throughout the genus equus and also for rhinoceros, indicating that the appearance of both retroposons predates the divergence of equids from the other perissodactyls. The markers did not amplify in human or bovine DNA. This indicated that ERE-1 and ERE-2 are, at least, perissodactyl specific.