Activation of the Hedgehog signaling pathway leads to fibrosis in aortic valves

• Published in: Cell & bioscience Vol. 13; no. 1; p. 43
• Main Authors: Gu, Dongsheng, Soepriatna, Arvin H, Zhang, Wenjun, Li, Jun, Zhao, Jenny, Zhang, Xiaoli, Shu, Xianhong, Wang, Yongshi, Landis, Benjamin J, Goergen, Craig J, Xie, Jingwu
• Format: Journal Article
• Language: English
• Published: England BioMed Central 02.03.2023; BMC
• Subjects: Animal models; Aortic stenosis; Aortic valve; Calcification; Cancer; Extracellular matrix; Fibrosis; Gene expression; Heart; Hedgehog; Hedgehog protein; Kidneys; Mutation; Signal transduction; Smoothened; Stenosis; Thymus gland; Transcription factors; Wound healing; Stenosis; Hedgehog; Smoothened; Aortic valve; Fibrosis
• ISSN: 2045-3701; 2045-3701
• DOI: 10.1186/s13578-023-00980-1

Fibrosis is a pathological wound healing process characterized by excessive extracellular matrix deposition, which interferes with normal organ function and contributes to ~ 45% of human mortality. Fibrosis develops in response to chronic injury in nearly all organs, but the a cascade of events leading to fibrosis remains unclear. While hedgehog (Hh) signaling activation has been associated with fibrosis in the lung, kidney, and skin, it is unknown whether hedgehog signaling activation is the cause or the consequence of fibrosis. We hypothesize that activation of hedgehog signaling is sufficient to drive fibrosis in mouse models. In this study, we provide direct evidence to show that activation of Hh signaling via expression of activated smoothened, SmoM2, is sufficient to induce fibrosis in the vasculature and aortic valves. We showed that activated SmoM2 -induced fibrosis is associated with abnormal function of aortic valves and heart. The relevance of this mouse model to human health is reflected in our findings that elevated GLI expression is detected in 6 out of 11 aortic valves from patients with fibrotic aortic valves. Our data show that activating hedgehog signaling is sufficient to drive fibrosis in mice, and this mouse model is relevant to human aortic valve stenosis.