Stock, Joy2025-03-212025-03-212024https://hdl.handle.net/11299/270526University of Minnesota M.S. thesis. 2024. Major: Veterinary Medicine. Advisors: Sian Durward Akhurst, Molly McCue. 1 computer file (PDF); ix, 87 pages.Background: Exercise-associated sudden death (EASD) is a fatal collapse occurring during or within 2 hours of racing or training in an otherwise healthy individual. It represents a significant cause of mortality in racehorses, accounting for 25% of the approximately 500 annual racehorse fatalities in the United States. Beyond its negative impact on equine welfare, EASD poses risks to jockey safety and challenges the public perception of horse racing. Cardiac-related issues are the cause of approximately 50% of EASD cases. Cardiac arrhythmias are also thought to be an important contributor to the EASD cases without a diagnosis at necropsy. In human patients without a diagnosis at necropsy, ion channelopathies are found to be an important underlying cause. The genetics underlying EASD have been largely unexplored in horses.Hypothesis: Thoroughbred racehorses with variants in ion channels and other arrhythmogenic genes are predisposed to a higher risk of EASD. Specific Aim1: This study aimed to identify causative positional candidate regions for EASD in Thoroughbred racehorses. Methods: Whole-genome sequencing (target: 12X coverage) and a Genome-wide Efficient Mixed Model Association (GEMMA) univariate linear mixed model genome-wide association study (GWAS) were performed on 50 EASD cases and 48 controls. Results: We identified 8 significant regions linked to EASD. Although genes in these regions were not directly analogous to known human ion channelopathy genes, aquaporin 4 (AQP4) and potassium channel tetramerization domain containing 1 (KCTD1) on the region in chromosome 8, showed potential relevance to dysrhythmia development. Specific Aim 2: This study aimed to identify causative variants in arrhythmogenic candidate genes for EASD in Thoroughbred racehorses. Methods: Candidate genes were identified using a keyword-based query of four databases: Phenolyzer, ClinVar, Online Mendelian Inheritance of Man, and OpenTargets. From these, a narrow (genes identified in all four programs) and a broad (genes identified in two or three programs) candidate gene set were established. SnpSift CaseControl was used to identify significant differences between EASD cases and controls. Results: We identified a significant modifier variant in troponin T2-cardiac type (TNNT2) from the narrow gene set. The broad gene set analysis identified 39 significant variants across 21 genes, with notable findings in triadin (TRDN) and calcium voltage-gated channel subunit alpha1 D (CACNA1D), both of which are linked to cardiac arrhythmias in people and may contribute to equine EASD. Conclusions: We identified variants and genes that may be contributing to EASD in Thoroughbred racehorses. These variants and genes warrant further investigation for their roles in exercise-induced arrhythmias, sudden death, and EASD in Thoroughbred racehorses.enCandidate geneEquineExercise associated sudden deathGeneticsGenome wide association studyRacehorsesGenetic exploration of exercise associated sudden death in racehorsesThesis or Dissertation