Lineage-tracing ofActa2+ cells in aged mice during lung fibrosis formation and resolution supports the lipofibroblast to myofibroblast reversible switch

Abstract

AbstractIdiopathic pulmonary fibrosis (IPF) develops mostly in old man and is characterized by the irreversible accumulation of excessive extracellular matrix components by activated myofibroblasts (aMYFs) leading to lung failure. Following bleomycin administration in young mice, fibrosis formation associated with efficient resolution takes place, the later limiting the clinical relevance of this model for IPF. In young mice, we previously reported that aMYFs captured during fibrosis formation differentiate towards a lipofibroblast (LIF)-like phenotype during resolution.In this study, we used aged mice in combination with bleomycin administration to trigger enhanced fibrosis formation and delayed resolution, as a more relevant model for IPF and examined the heterogeneity and fate of aMYFs at different time points. Alveolosphere assay were carried out to compare the alveolar resident mesenchymal niche activity for AT2 stem cells in young versus old mice. Lineage tracing of the Acta2+ aMYFs in old mice exposed to bleomycin followed by scRNAseq of the lineage-traced cells isolated during fibrosis formation and resolution was performed to delineate the heterogeneity of aMYFs during fibrosis formation and their fate during resolution. Data mining of human mesenchymal cells from IPF and control datasets were also performed to decipher the heterogeneity of aMYFs and investigate differentiation trajectories during fibrosis formation.Our results show that alveolar resident mesenchymal cells from old mice display decreased supporting activity for AT2 stem cells. We report that aMYFs consist of four subclusters displaying unique pro-alveologenic versus pro-fibrotic profiles. Alveolar fibroblasts displaying a high LIF-like signature largely constitute both the origin and fate of aMYFs during fibrosis formation and resolution, respectively. The heterogeneity of aMYFs is conserved in humans and a significant proportion of human aMYFs displays a high LIF signature.In conclusion, our data indicate that the cellular and molecular bases of aMYFs formation and differentiation towards the LIF phenotype are conserved between young and old mice. Importantly, our work identifies a subcluster of aMYFs that is potentially relevant for future management of IPF.