Age‐dependent Changes in Aortic Valve and Mitral Valve Function in Fibrillin‐mutant Mice

The structural protein, fibrillin, is important for maintaining the strength and reliability of connective tissue found in blood vessels and heart valves. Mutations in fibrillin‐1 result in Marfan syndrome and leads to left‐sided heart valve regurgitation, aortic root dilatation and aortic aneurysm. While previous studies have focused predominantly on young fibrillin‐mutant mice, hemodynamically significant disease generally does not emerge in patients with fibrillin mutations until later in life. Thus, this study aims to evaluate molecular and functional changes in heart valves from aged fibrillin mutant mice. Wild‐type (+/+) or fibrillin mutant (+/C1037G) mice were fed normal chow diet for 3 months (young) or 14 months (old). Heart valve function, aortic dimensions, and cardiac function were evaluated using high‐resolution echocardiography, and gene expression was measured using qRT‐PCR. Consistent with previous reports, we found no evidence of mitral regurgitation in young mice of either genotype. In old +/C1037G mice, however, we did find evidence of mitral regurgitation (~5%). In contrast, aortic valve regurgitation was evident in a relatively large proportion of +/C1037G mice at both ages (~20% at both time points), and was not detected in any +/+ animals. Interestingly, left ventricular dimensions were not associated with the presence of mitral regurgitation, but aortic root dilatation was present in all mice with aortic valve regurgitation. To gain insight into the molecular underpinnings of these phenotypic changes, we measured expression of IL‐10 (an anti‐inflammatory gene) and Runx2 (a pro‐proliferative gene that drives matrix remodeling), both of which are genes previously implicated in the pathogenesis of mitral and aortic valve disease. In young animals, expression of IL‐10 in mitral valves tended to be increased in +/C1037G mice compared to +/+ littermates. With aging, IL‐10 increased substantially in mitral valves from in +/+ mice, and increased further in +/C1037G littermates. Similar trends were observed in expression of Runx2 in mitral valves from both genotypes of mice. While IL‐10 followed a similar pattern in aortic valve tissue from young and old mice of both genotypes, Runx2 was not significantly increased across any of the groups. Collectively, while our data suggest that there are substantial, potentially adaptive molecular changes that occur during development of regurgitant valvular diseases, aortic dilatation may be a key early factor driving development of aortic regurgitation. Future experimental work aimed at determining the relative mechanical and molecular contributions to development of heart valve regurgitation will be critical to development of novel therapeutic strategies in patients with syndromes secondary to fibrillin mutations. Support or Funding Information NHLBI (R01‐HL111121)