High-Resolution Dissection of Chemical Reprogramming from Mouse Embryonic Fibroblasts into Fibrocartilaginous Cells

Summary: Articular cartilage injury and degeneration causing pain and loss of quality-of-life has become a serious problem for increasingly aged populations. Given the poor self-renewal of adult human chondrocytes, alternative functional cell sources are needed. Direct reprogramming by small molecules potentially offers an oncogene-free and cost-effective approach to generate chondrocytes, but has yet to be investigated. Here, we directly reprogrammed mouse embryonic fibroblasts into PRG4+ chondrocytes using a 3D system with a chemical cocktail, VCRTc (valproic acid, CHIR98014, Repsox, TTNPB, and celecoxib). Using single-cell transcriptomics, we revealed the inhibition of fibroblast features and activation of chondrogenesis pathways in early reprograming, and the intermediate cellular process resembling cartilage development. The in vivo implantation of chemical-induced chondrocytes at defective articular surfaces promoted defect healing and rescued 63.4% of mechanical function loss. Our approach directly converts fibroblasts into functional cartilaginous cells, and also provides insights into potential pharmacological strategies for future cartilage regeneration. : In this article, Ouyang and colleagues develop a chemical-driven direct reprogramming of mouse embryonic fibroblasts into PRG4+ chondrocytes, with a screen-defined cocktail VCRTc. Their induced chondrocytes promote in vivo cartilage functional regeneration. The dynamical cellular phenotypes were analyzed by single-cell RNA sequencing, illustrating the inhibition of fibroblast features and activation of chondrogenesis pathways in early reprogramming. Keywords: chemical reprogramming, single-cell analysis, cartilage regeneration, drug discovery