Affiliation:
1. Developmental Genetics Laboratory, Regional Centre for Biotechnology (RCB) NCR Biotech Science Cluster Faridabad India
Abstract
AbstractMutations in MYH3, the gene encoding the developmental myosin heavy chain‐embryonic (MyHC‐embryonic) skeletal muscle‐specific contractile protein, cause several congenital contracture syndromes. Among these, recessive loss‐of‐function MYH3 mutations lead to spondylocarpotarsal synostosis (SCTS), characterized by vertebral fusions and scoliosis. We find that Myh3 germline knockout adult mice display SCTS phenotypes such as scoliosis and vertebral fusion, in addition to reduced body weight, muscle weight, myofiber size, and grip strength. Myh3 knockout mice also exhibit changes in muscle fiber type, altered satellite cell numbers and increased muscle fibrosis. A mass spectrometric analysis of embryonic skeletal muscle from Myh3 knockouts identified integrin signaling and cytoskeletal regulation as the most affected pathways. These pathways are closely connected to the mechanosensing Yes‐associated protein (YAP) transcriptional regulator, which we found to be significantly activated in the skeletal muscle of Myh3 knockout mice. To test whether increased YAP signaling might underlie the musculoskeletal defects in Myh3 knockout mice, we treated these mice with CA3, a small molecule inhibitor of YAP signaling. This led to increased muscle fiber size, rescue of most muscle fiber type alterations, normalization of the satellite cell marker Pax7 levels, increased grip strength, reduced fibrosis, and decline in scoliosis in Myh3 knockout mice. Thus, increased YAP activation underlies the musculoskeletal defects seen in Myh3 knockout mice, indicating its significance as a key pathway to target in SCTS and other MYH3‐related congenital syndromes.
Funder
Department of Biotechnology, Government of West Bengal
Science and Engineering Research Board
Indian Council of Medical Research
David F. Rankin College of Business, Southern Arkansas University
The Wellcome Trust DBT India Alliance
Publisher
Springer Science and Business Media LLC
Cited by
1 articles.
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