Abstract 249: Potential Tissue-specific Interactions Between Inflammation and Canonical Tgfβ Signaling in Marfan Syndrome

Abstract

Marfan syndrome is a connective tissue disorder frequently driven by mutations in the fibrillin-1 gene (Fbn1). This results in multiple aberrant cardiovascular phenotypes, including aortic aneurysm and mitral valve prolapse. While the molecular changes underlying aortic aneurysm formation have been extensively studied, the molecular underpinnings of mitral valve prolapse in this syndrome remain poorly understood. Therefore, we hypothesized that smad2/3 phosphorylation would be significantly increased in both aorta and mitral valve from Fbn1 +/1037G mice with Marfan syndrome and associated with impaired anti-inflammatory signaling in both tissues. We used young (3 months) mice that were wild-type (Fbn1 +/+ ) or fibrillin-1 mutant (Fbn1 +/1037G ) and fed a normal chow diet. qRT-PCR was used to measure mRNA levels in aortic arch and mitral valve tissue, and fluorescent immunohistochemistry to evaluate changes in canonical TGFβ signaling. Consistent with previous reports, TGF-β1 mRNA levels were increased in Fbn1 +/1037G compared to wild-type mice in both aorta and mitral valve. Interestingly, while p-SMAD2/3 protein levels were increased in aorta from Fbn1 +/1037G mice, we were surprised to find that p-SMAD2/3 protein levels were decreased in mitral valve from Fbn1 +/1037G mice compared their wild-type littermates. Given the emerging role of inflammatory signaling in accelerated development of Marfan phenotypes, we sought to determine whether there were compensatory or maladaptive changes in IL10 (a known inhibitor of p-SMAD2/3). In aorta, IL10 mRNA levels were decreased in Fbn1 +/1037G compared to Fbn1 +/+ mice, suggesting a maladaptive response. In contrast, IL10 levels in mitral valve tissue were significantly increased in Fbn1 +/1037G mice compared to their wild-type littermates, suggesting a compensatory/protective response. Collectively, these data suggest that tissue-specific changes in IL10 levels may modulate p-SMAD2/3 signaling in aorta and mitral valve, which may be a key permissive step in the onset of Marfan-related phenotypes. Future work to experimentally determine the role of IL10 in the regulation of canonical and non-canonical TGFβ signaling and the penetrance of Marfan-associated phenotypes is warranted.