Abstract
Skeletal dysplasias, characterized by bone, cartilage, and connective tissue abnormalities, often arise due to disruptions in extracellular matrix (ECM) dynamics and growth factor-dependent signaling pathways. RSPRY1, a secreted protein with RING and SPRY domains, has been implicated in bone development, yet its exact role remains to be determined. RSPRY1 gene mutations are associated with spondyloepimetaphyseal dysplasia (SEMD), a rare skeletal disorder characterized by severe epiphyseal and metaphyseal deformities. This study aimed to determine the molecular and cellular mechanisms by which RSPRY1 deficiency affects skeletal homeostasis. Transcriptome analysis of fibroblasts from patients with homozygous RSPRY1 mutations showed there was significant enrichment of transforming growth factor beta (TGF-β) signaling and ECM-related pathways. Functional wound healing assays showed that RSPRY1 knockout fibroblasts exhibited enhanced motility, a phenotype that was abrogated in RSPRY1 + SMAD3 double knockout fibroblasts, highlighting the SMAD3-dependence of RSPRY1's effects. The observed limited response to exogenous TGF-β in RSPRY1-deficient cells indicated that there was constitutive pathway activation. These findings show that RSPRY1 is a critical regulator of TGF-β signaling in ECM dynamics and cell motility, contributing to the pathophysiology of SEMD. An improvement in our understanding of the molecular roles of RSPRY1 might yield novel therapeutic strategies that target TGF-β signaling in patients with SEMD and other skeletal dysplasias.