Abstract Background Thoracic aortic aneurysms and dissections (TAAD) are life‐threatening vascular disorders affecting the medial layer of the aortic wall, associated with high mortality when a rupture or dissection occurs. Though numerous genes are associated with familial TAAD (FTAAD), pathogenic variants in MYH11 , encoding smooth muscle cell specific myosin heavy chain (SM‐MHC), represent a rare but interesting subgroup as many gaps remain in the knowledge of disease mechanisms, phenotype presentation and gene–environmental interactions. No reliable therapy exists in halting aneurysm growth in affected individuals. Scope of Review This review aims to summarize current evidence on disease pathophysiological mechanisms. Furthermore, phenotypic variability, extrathoracic vascular involvement and the possibility of future curative gene therapy options are evaluated. Findings Most reported pathogenic MYH11 variants are missense or splice‐site variants that disrupt the C‐terminal coiled‐coil dimerization and therefore thick filament assembly. Evidence from mouse models, patient‐derived cells and limited human ex vivo tissue studies shows that these variants are associated with impaired thick filament organization, reduced force generation and disruption of the elastin‐contractile unit, with subsequent alterations in ECM remodelling. However, the precise causal sequence in human disease has not yet been established. Clinically, MYH11‐ associated disease is associated with FTAAD and patent ductus arteriosus (PDA). Reduced penetrance, variable expression of disease and unknown potential gene–environment interactions complicate risk prediction and clinical counselling of affected individuals. Emerging RNA‐therapy strategies aimed at allele‐specific correction of genetic disease offer interesting future therapeutic targets, although vascular delivery and long‐term safety remain challenges. Conclusion MYH11 should be viewed as a clinically meaningful gene that is associated with TAAD and PDA. Current limited evidence shows that the phenotype is characterized by contractile dysfunction, increased aortic stiffness and potential susceptibility to hemodynamic stress. Future work should investigate translatable mechanistic studies, larger registries for genotype–phenotype correlations and evaluation of targeted gene therapy approaches.
Atash et al. (Fri,) studied this question.