Changes in Vascular Function with Aging in Fibrillin‐Mutant Mice

In Marfan syndrome, mutations in the fibrillin gene are known to result in aortic dilatation and aneurysm formation, which is associated with impaired endothelial function and increased vascular stiffness. Previous studies suggested these phenotypes may be partly attributable to overactivation of TGF β signaling, which leads to increased reactive oxygen species production, extracellular matrix production, and increased matrix metalloproteinase activity in aortic wall. To our knowledge, however, there are no studies comprehensively evaluating the relationships between conduit vessel vasomotor function, vascular stiffness, and aortic dilatation in young and aged models of Marfan syndrome. Thus, the aim of this study was to test the hypothesis that carotid arterial vasomotor dysfunction and increased vascular stiffness precede aortic dilatation in fibrillin mutant mice. We used wild‐type (+/+) or fibrillin mutant (+/C1037G) mice fed a normal chow diet for 3 months (young) or 14 months (old), measured changes in vasomotor function and vascular stiffness in carotid arterial segments using pressurized arteriography, aortic dimensions using high resolution echocardiography, gene expression using qRT‐PCR, and protein levels using immunohistochemistry. Consistent with our hypothesis, young +/C1037G mice had impaired endothelium‐dependent relaxation to acetylcholine (ACH) compared to +/+ littermates, but did not exhibit changes in vascular stiffness. In contrast, old +/C1037G mice did not have significant changes in vasomotor responses to ACH compared to +/+ mice, but displayed markedly increased vascular stiffness compared to their wild‐type littermates. Aortic dimensions were significantly increased in young +/C1037G mice compared to their +/+ littermates, and these changes were exaggerated further with aging. Consistent with previous reports, we found increased TGF beta‐1 expression and canonical TGF beta signaling (p‐Smad2/3 levels) in +/C1037G mice. Interestingly, we also observed increased expression of Runx2 with aging in +/+ mice with aging, and expression of Runx2 was substantially increased in +/C1037G mice compared to their +/+ littermates at both time points. Collectively, our data show that vasomotor function and vascular stiffness in carotid arterial segments change independent of changes in aortic root diameter, suggesting significant heterogeneity in the mechanical and molecular responses to fibrillin deficiency throughout the vascular system. Support or Funding Information NHLBI (R01‐111121)