Abstract
Endotrophin (ETP), a cleavage product of the C5 domain of collagen VI α3 (COL6A3), plays a crucial role in extracellular matrix remodeling. Previously established Col6a3-knockout mouse models primarily reflect the consequences of COL6A3 loss rather than the specific effects of ETP depletion, making it challenging to directly assess the functions of ETP. These models either disrupt COL6A3 along with ETP production or express functionally defective COL6A3 while maintaining ETP production. Here we developed and validated a novel ETP-knockout (ETP(KO)) mouse model that selectively ablates ETP while preserving Col6a3 expression to address these limitations. To generate the ETP(KO) model, we introduced lox2272 sites and a fluorescent mCherryCAAX reporter into the Col6a3 locus, ensuring that ETP expression is turned off and reporter expression is turned on upon Cre-mediated recombination. Crossing the Col6a3-Etp+mCherryCAAX mouse line with CMV-Cre mice yielded ETP(KO) mice, in which successful ETP deletion was confirmed by sequencing of genomic DNA and analysis of mCherryCAAX expression. Using this model, we investigated the role of ETP in kidney fibrosis. ETP(KO) mice subjected to unilateral or bilateral kidney ischemia-reperfusion injury exhibited complete Etp messenger RNA ablation with only a partial reduction in Col6a3 mRNA. Notably, ETP depletion significantly attenuated fibrosis progression, demonstrating a critical contribution of ETP to the pathogenesis of kidney fibrosis. The ETP(KO) mouse model provides a targeted and specific approach to study ETP function independently of COL6A3 expression. These findings establish ETP as a key driver of fibrosis and position ETP(KO) mice as a valuable tool for elucidating ETP-mediated mechanisms in preclinical disease models.