Correlation between the VSMC mechanobiology with phenotypic reprogramming and exacerbated responses to stress in Marfan syndrome cardiovascular phenotype

Marfan Syndrome (MFS) is an autosomal dominant connective tissue disease affecting to variable extents the musculoskeletal, ocular and cardiovascular systems. Cardiovascular phenotype and in particular thoracic aorta aneurysm/dissection (TAAD), is responsible for the bulk of disease morbimortality. MFS is due to mutations in fibrillin-1, one of the main structural proteins of the extracellular matrix (ECM), which in addition regulates TGF-Beta activity by means of its physical retention in the ECM. However, mechanisms by which fibrillin-1 mutation determines TAAD with elevated phenotypic variability are yet poorly understood. Vascular smooth muscle cells (VSMC), the main component of aortic medial layer, are central targets of aneurysm pathophysiology in general. By exerting regulation of contractile tone, cytoskeletal structure and ECM interaction, VSMC control aortic structure and response to pathologic stimuli. Mutations that promote loss of VSMC contractile apparatus impair contractile function and mechanoadaptative responses and associate with distinct types of TAAD. However, the role of VSMC mechanobiology in MFS pathophysiology is poorly known. In this study, we investigated whether VSMC loss of force-generating capacity occurs in MFS and whether it associates with specific changes in cell phenotype. Biomechanical VSMC responses were assessed in cells cultured from aortas collected from mice with the mgDeltalpn MFS mutation at early (3-monthold mice, the main focus of our study) and advanced (6-month-old mice) stages of disease evolution. At 3 months of disease evolution, we detected important phenotypic alterations in MFS-VSMC, with enhanced expression of markers for cellular proliferation and lower expression of some differentiation markers (calponin-1), but, increase in others (SM alfaactin and SM22). In parallel, there were important morphologic changes, with increased VSMC area and loss of its fusiform shape. Such alterations are consistent with a transition towards a mesenchymal-like phenotype, which was confirmed through the expression of several markers. Endoplasmic reticulum (ER) stress markers increased in MFS-VSMC vs. WT (wild-type)-VSMC in basal condition, without augmentation after cyclic mechanical stretching. Replacement of defective fibrillin-1 ECM from MFS-VSMC with a normal fibroblast-derived ECM promoted reversion of some aspects of the phenotype but not of ER stress. MFS-VSMC exhibited a proteomic profile divergent from that of WT-VSMC, particularly with respect to the lower expression of cytoskeleton regulatory proteins. Importantly, MFS-VSMC displayed a lower traction force-generating capacity when seeded in ECM under physiological stiffness and generated an impaired contractile moment in this situation. In particular, MFS-VSMC depicted a strong attenuation of the traction force response to enhanced ECM stiffening. These defects did not occur as a result of lower adhesion structure and decreased adhesion capacity of MFS-VSMC. In parallel, MFS-VSMC exhibited lower density of actin stress fiber vs. WT-VSMC. With 6 months of disease evolution, several of these alterations were not detectable. Both WTVSMC and MFS-VSMC showed reduced capacity of force generation, without evidence of cell senescence. In summary, starting already in the early stages of disease evolution, MSF-VSMC display important phenotypic changes which go beyond a simple reversible phenotypic modulation, with some aspects suggesting a transition mesenchymal-like phenotype, accompanied by reduced force-generating capacity not linked to loss of cell adhesion properties but rather to impaired organization of action stress fibers. These mechanisms, described for the first time, contribute to elucidate MFS pathophysiology, depicting both some aspects in common with the pathophysiology of other types of aortic aneurysm and some aspects peculiar to MFS (AU)