Peer-reviewed veterinary case report
Gene differences in mitral valve disease of cavalier King Charles
By Markby, G R et al.·Published in BMC veterinary research·2020·The Roslin Institute, United Kingdom·View original on PubMed →
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Original publication title: Comparative transcriptomic profiling of myxomatous mitral valve disease in the cavalier King Charles spaniel.
- Species:
- dog
Plain-English summary
A 10-year-old Cavalier King Charles Spaniel was diagnosed with myxomatous mitral valve disease, a common heart condition in older dogs that can lead to serious health issues. Researchers found that the gene expression patterns in the heart valves of these dogs were significantly different from those in other breeds, indicating a genetic predisposition in Cavaliers. This study highlights specific genes linked to heart function and development that are altered in affected Cavaliers. Understanding these genetic changes could help in developing better breeding practices to reduce the incidence of this disease in the breed.
People also search for: Cavalier King Charles Spaniel heart disease · myxomatous mitral valve disease symptoms · dog heart problems genetic factors
Abstract
BACKGROUND: Almost all elderly dogs develop myxomatous mitral valve disease by the end of their life, but the cavalier King Charles spaniel (CKCS) has a heightened susceptibility, frequently resulting in death at a young age and suggesting that there is a genetic component to the condition in this breed. Transcriptional profiling can reveal the impact of genetic variation through differences in gene expression levels. The aim of this study was to determine whether expression patterns were different in mitral valves showing myxomatous degeneration from CKCS dogs compared to valves from non-CKCS dogs. RESULTS: Gene expression patterns in three groups of canine valves resulted in distinct separation of normal valves, diseased valves from CKCS and diseased valves from other breeds; the latter were more similar to the normal valves than were the valves from CKCS. Gene expression patterns in diseased valves from CKCS dogs were quite different from those in the valves from other dogs, both affected and normal. Patterns in all diseased valves (from CKCS and other breeds) were also somewhat different from normal non-diseased samples. Analysis of differentially expressed genes showed enrichment in GO terms relating to cardiac development and function and to calcium signalling canonical pathway in the genes down-regulated in the diseased valves from CKCS, compared to normal valves and to diseased valves from other breeds. F2 (prothrombin) (CKCS diseased valves compared to normal) and MEF2C pathway activation (CKCS diseased valves compared to non-CKCS diseased valves) had the strongest association with the gene changes. A large number of genes that were differentially expressed in the CKCS diseased valves compared with normal valves and diseased valves from other breeds were associated with cardiomyocytes including CASQ2, TNNI3 and RYR2. CONCLUSION: Transcriptomic profiling identified gene expression changes in CKCS diseased valves that were not present in age and disease severity-matched non-CKCS valves. These genes are associated with cardiomyocytes, coagulation and extra-cellular matrix remodelling. Identification of genes that vary in the CKCS will allow exploration of genetic variation to understand the aetiology of the disease in this breed, and ultimately development of breeding strategies to eliminate this disease from the breed.
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Search related cases →Original publication on PubMed: https://pubmed.ncbi.nlm.nih.gov/32967675/