Limb connective tissue is organized in a continuum of promiscuous fibroblast identities during development

Abstract

AbstractTight developmental coordination of muscle attachments with skeletal muscle is fundamental for building functional limbs and allowing locomotion. Muscle attachments include connective tissue fibroblasts of tendon and muscle connective tissue. Although muscle attachments play critical roles in development, our understanding of connective tissue fibroblast developmental programs lags behind that of other components of the musculoskeletal system, mainly because fibroblasts are highly heterogeneous and poorly characterized. Combining single-cell RNA-sequencing-based strategies including trajectory inference andin situhybridization analyses, we address the diversity of connective tissue fibroblasts and their developmental trajectories during chicken limb fetal development. We show that fibroblasts switch from a program providing positional information to a program of lineage diversification at the onset of fetal period. Muscle connective tissue and tendon contain several fibroblast populations that emerge asynchronously. Once the final muscle pattern is set,in silicofibroblast populations that are close in transcriptional identity are found in neighbouring locations in limbs, prefiguring the adult fibroblast layers associated to muscle. We propose that the limb connective tissue is organised in a continuum of promiscuous fibroblast identities, allowing for the robust and efficient connection of the muscular system to bone and skin.HighlightsDissection of connective tissue heterogeneity using single-cell RNA-sequencing andin situRNA stainingIn silicofibroblast populations map to distinct fibroblast layers in limbsMolecular signatures of fetal fibroblast populations at the origin of limb adult connective tissueEpimysium and endomysium fibroblasts are transcriptionally distinct at fetal stageLimb fibroblasts display promiscuous identities reflecting their interconnected 3D-networkFibroblasts switch from providing positional information to differentiation during development