PROJECT SUMMARY Composite tissue regeneration is very limited in mammals; however, humans and mice can fully regenerate the distal tips of the digits following amputation. This process involves the formation of a blastema, a cellular structure that is the source of the regenerated tissue and is integral to successful regeneration. Proximal amputations beyond the nail do not form a blastema and result in fibrotic wound-healing. This differential behavior makes the mouse digit tip an ideal model system to investigate the cellular and molecular factors driving each wound-healing response and why complex regeneration is so limited in mammals. Specifically, this project will focus on fibroblast subtypes and their role in fibrosis versus regeneration. Fibroblasts are a major contributor to the blastema and play an integral part in fibrosis; thus, they may be a cell population that drives the decision between fibrosis and regeneration. Our single cell transcriptomic (scRNA-seq) analysis of the regenerating blastema revealed an extremely heterogenous fibroblast population and that the subpopulations had distinct population dynamics and lineage trajectories during blastema formation and maturation. I hypothesize that there are specific fibroblast subtypes that promote regeneration, inhibit fibrosis, or both. However, no studies have performed direct lineage contributions by tracing fibroblast subpopulations in regeneration and fibrosis. Additionally, the in vivo functional roles and importance of our computationally defined candidate pro-regenerative genes have not been established. This project will utilize single-cell CRISPR based DNA barcoding for lineage tracing fibroblasts at the subtype resolution (Aim 1) and plasmid electroporation for gene delivery to functionally assess candidate pro-regenerative genes (Aim 2). Together, my two aims will provide important insight into how the fibrotic and regenerative processes are determined in the mouse digit tip and will open additional avenues for more effective clinical treatments for large wounds or amputations in humans.