Inhibition of adenosine/A2A receptor signaling suppresses dermal fibrosis by enhancing fatty acid oxidation.

Abstract

Background: Skin fibrosis presents a major challenge for clinicians treating conditions like systemic sclerosis (SSc) due to its progressive course and limited treatment options. While the role of metabolism in fibrosis has gained increasing attention, the crucial alterations of metabolic pathway and the underlying signaling of metabolic interconnections in regulating SSc-related skin fibrosis remain largely elusive.

Methods: Metabolomic analysis was performed on plasma samples from 35 SSc patients to identify metabolic alterations. In bleomycin (BLM)- and hypochlorous acid (HOCL)-induced skin fibrosis mouse models, we assessed the impact of global A2a receptor knockout on skin fibrosis. Single-cell RNA sequencing of mouse skin was utilized to investigate the role of A2A in fibroblasts during fibrotic challenge. Human dermal fibroblasts were used in in vitro experiments, employing RNA sequencing and Seahorse assays, to assess the relationship between A2A signaling and fatty acid oxidation (FAO). Finally, fibroblast-specific conditional A2a knockout mice were used to test the effects of specifically targeting A2A in dermal fibroblasts.

Results: Adenosine-centered nucleotide metabolism was elevated in the plasma of SSc patients. Mechanistically, by stimulating dermal fibroblasts with key pathogenic cytokines associated with SSc, we observed significant changes in adenosine receptor A2A expression in response to IL-1β. Immunofluorescence revealed upregulation of A2A expression in dermal fibroblasts of SSc patients. Further, global A2a knockout significantly attenuated skin fibrosis in both BLM- and HOCL-induced skin fibrosis mouse models. Single-cell RNA sequencing of mouse skin revealed significant alterations in fatty acid metabolism in fibroblasts from A2a-deficient mice following fibrotic challenge. RNA sequencing, Seahorse assays and in vitro experiments showed that A2A inhibition promotes FAO by upregulating CPT1A expression via suppressing CREB phosphorylation, alleviating fibrosis in human primary dermal fibroblasts. Furthermore, targeted intervention of A2a specifically in fibroblasts improves outcomes and increases CPT1A expression in BLM-induced skin fibrosis mouse model.

Conclusion: Our study highlights the crucial interplay between adenosine metabolism-A2A receptor axis and FAO in SSc-associated skin fibrosis, suggesting that targeting the adenosine receptor A2A-FAO metabolic axis offers a promising therapeutic strategy for skin fibrosis.