Project description:Human and murine skin wounding commonly result in fibrotic scarring but the murine wounding model Wound Induced Hair Neogenesis (WIHN) can frequently result in a regenerative repair response. Here we show in single cell RNA-seq comparisons of semi-regenerative and fibrotic WIHN wounds, increased expression of phagocytic/lysosomal genes in macrophages associated with predominance of fibrotic myofibroblasts in fibrotic wounds. Investigation revealed that macrophages in the late wound drive fibrosis by phagocytizing dermal Wnt inhibitor SFRP4 to establish persistent Wnt activity. In accordance, phagocytosis abrogation resulted in transient Wnt activity and a more regenerative healing. Phagocytosis of SFRP4 was integrin-mediated and dependent on the interaction of SFRP4 with the EDA splice variant of fibronectin. In the human skin condition Hidradenitis suppurativa, phagocytosis of SFRP4 by macrophages correlated with fibrotic wound repair. These results reveal that macrophages can modulate a key signaling pathway via phagocytosis to alter the skin wound healing fate.

Project description:While considerable progress has been made towards understanding the complex processes and pathways that regulate human wound healing, regenerative medicine has been unable to develop therapies that coax the natural wound environment to heal scar-free. The inability to induce perfect skin regeneration stems partly from our limited understanding of how scar-free healing occurs in a natural setting. Here we have investigated the wound repair process in adult axolotls and demonstrate that they are capable of perfectly repairing full thickness excisional wounds made on the flank. In the context of mammalian wound repair, our findings reveal a substantial reduction in hemostasis, reduced neutrophil infiltration and a relatively long delay in production of new extracellular matrix (ECM) during scar-free healing. Additionally, we test the hypothesis that metamorphosis leads to scarring and instead show that terrestrial axolotls also heal scar-free, albeit at a slower rate. Analysis of newly forming dermal ECM suggests that low levels of fibronectin and high levels of tenascin-C promote regeneration in lieu of scarring. Lastly, a genetic analysis during wound healing comparing epidermis between aquatic and terrestrial axolotls suggests that matrix metalloproteinases may regulate the fibrotic response. Our findings outline a blueprint to understand the cellular and molecular mechanisms coordinating scar-free healing that will be useful towards elucidating new regenerative therapies targeting fibrosis and wound repair. We used microarray analysis to determine the gene expression changes that take place during scar free wound healing in aquatic and terrestrial axolotl salamanders. Epidermal tissue was harvested using a 4mm biopsy punch. Two wounds were made along the flank and posterior to the forelimbs. Harvested epidermis was pooled for each animal. Four biological replicates were collected from uninjured epidermis (D0) and at 1, 3, and 7 days post injury.

Project description:Injury in mammals induces a connective tissue response to either regenerate as before, or to scar. The fibroblastic actions and mechanisms that underlie these connective tissue responses remain obscure, as direct observation in animals is too difficult and current assays do not faithfully reproduce physiology. Here, we developed a skin explant technique termed scar-in-a-dish (SCAD) that faithfully recapitulates uniform scars with contraction and reveals how scarring occurs in unprecedented detail. By growing mouse SCADs, with a traceable scar-progenitor fibroblast lineage, we observed previously unseen intercellular connections form between scar-progenitors that then collectively swarm into the nascent wound in highly regular periodic movements that progressively contract the skin and form scars. Swarming is exclusive to scar progenitors and absent from oral cavity fibroblasts that regenerate scarless. By testing a panel of adhesion molecules that might instigate intercellular connections, we found swarming was induced by the upregulation of N-cadherin in scar progenitors. Impeding N-cadherin binding inhibited swarming and contraction, and led to reduced scarring in SCAD and in mice. Blocking N-cadherin and scar-progenitor swarming thus provides a novel therapeutic space to curtail pathological fibrotic responses across a range of medical settings.

Project description:Mammalian skin wounds heal by forming fibrotic scars. We report that reindeer antler velvet exhibits regenerative wound healing, whereas identical injury to back skin forms scar. This regenerative capacity was retained following ectopic transplantation of velvet to scar-forming sites. Single-cell mRNA/ATAC-Sequencing revealed that while uninjured velvet fibroblasts resembled human fetal fibroblasts, back skin fibroblasts were enriched in pro-inflammatory features resembling adult human fibroblasts. Injury elicited site-specific immune polarization; back skin fibroblasts amplified the immune response, whereas velvet fibroblasts adopted an immunosuppressive state leading to restrained myeloid maturation and hastened immune resolution ultimately enabling myofibroblast reversion to a regeneration-competent state. Finally, regeneration was blunted following application of back skin associated immunostimulatory signals or inhibition of pro-regenerative factors secreted exclusive to velvet fibroblasts. This study highlights a unique model to interrogate mechanisms underlying divergent healing outcomes and nominates both decoupling of stromal-immune crosstalk and reinforcement of pro-regenerative fibroblast programs to mitigate scar.

Project description:While considerable progress has been made towards understanding the complex processes and pathways that regulate human wound healing, regenerative medicine has been unable to develop therapies that coax the natural wound environment to heal scar-free. The inability to induce perfect skin regeneration stems partly from our limited understanding of how scar-free healing occurs in a natural setting. Here we have investigated the wound repair process in adult axolotls and demonstrate that they are capable of perfectly repairing full thickness excisional wounds made on the flank. In the context of mammalian wound repair, our findings reveal a substantial reduction in hemostasis, reduced neutrophil infiltration and a relatively long delay in production of new extracellular matrix (ECM) during scar-free healing. Additionally, we test the hypothesis that metamorphosis leads to scarring and instead show that terrestrial axolotls also heal scar-free, albeit at a slower rate. Analysis of newly forming dermal ECM suggests that low levels of fibronectin and high levels of tenascin-C promote regeneration in lieu of scarring. Lastly, a genetic analysis during wound healing comparing epidermis between aquatic and terrestrial axolotls suggests that matrix metalloproteinases may regulate the fibrotic response. Our findings outline a blueprint to understand the cellular and molecular mechanisms coordinating scar-free healing that will be useful towards elucidating new regenerative therapies targeting fibrosis and wound repair.

Project description:Although most mammals heal injured tissues and organs with scarring, spiny mice (Acomys) naturally regenerate skin and complex musculoskeletal tissues. Currently, the core signaling pathways driving mammalian tissue regeneration are poorly characterized. Here, we show that, while immediate ERK activation is a shared feature of scarring (Mus) and regenerating (Acomys) injuries, ERK activity is only sustained during complex tissue regeneration. Following ERK inhibition, regeneration in Acomys shifted towards a fibrotic repair. Using scRNA-seq, we uncovered that MAPK/ERK signaling acts in a cell type specific manner to direct regenerative healing. Loss- and gain-of-function experiments prompted us to identify FGF and ErbB signaling as upstream ERK regulators of regeneration. By ectopically activating ERK in Mus injuries, a pro- regenerative response was induced, including cell proliferation, extracellular matrix remodeling and hair follicle neogenesis. Our data provide new insights into why some mammals regenerate better than others and open avenues to redirect fibrotic repair towards regenerative healing.

Project description:Scarring is a normal outcome of the wound healing program, but excessive secretion of ECM proteins such as collagen can lead to fibrosis and compromise tissue function. Despite the widespread occurrence of fibrosis, effective therapies are lacking. A promising approach would be to limit the amount of collagen released from hyperactive fibroblasts. We designed membrane permeant-peptide inhibitors that specifically target and disrupt the primary interface between TANGO1 and cTAGE5, an interaction that is required for collagen export from endoplasmic reticulum exit sites (ERES). Dissociation of the TANGO1 and cTAGE5 complex leads to their partial degradation and a consequent inhibition in the secretion of several ECM components, including collagens. Peptide inhibitor treatment in zebrafish resulted in altered tissue architecture and reduced granulation tissue formation during cutaneous wound healing. The inhibitors reduced secretion of several ECM proteins, including collagens, fibrillin and fibronectin in human dermal fibroblasts and in cells obtained from patients with a generalized fibrotic disease (scleroderma). Taken together, this targeted interference in the TANGO1-cTAGE5 binding interface enables therapeutic modulation of ERES function in ECM hypersecretion, during wound healing and fibrotic processes.

Project description:Although most mammals heal injured tissues and organs with scarring, spiny mice (Acomys) naturally regenerate skin and complex musculoskeletal tissues. Currently, the core signaling pathways driving mammalian tissue regeneration are poorly characterized. Here, we show that, while immediate ERK activation is a shared feature of scarring (Mus) and regenerating (Acomys) injuries, ERK activity is only sustained at high levels during complex tissue regeneration. Following ERK inhibition, ear punch regeneration in Acomys shifted towards fibrotic repair. Using scRNA-seq, we identified ERK-responsive cell types. Loss- and gain-of-function experiments prompted us to uncover FGF and ErbB signaling as upstream ERK regulators of regeneration. Strikingly, the ectopic activation of ERK in scar-prone injuries induced a pro-regenerative response, including cell proliferation, extracellular matrix remodeling and hair follicle neogenesis. Our data detail an important distinction in ERK activity between regenerating and poorly regenerating adult mammals and open avenues to redirect fibrotic repair towards regenerative healing.

Project description:Hypertrophic skin scarring following dermal injury causes extreme pain and psychological trauma for patients. Unfortuately, we do not have effective treatments to prevent or reverse skin scarring. Using RNA and ATAC sequencing of mouse and human fibroblasts, we show that JUN expressing fibroblasts are responsible for skin scarring by regulating CD36 expression. In summary, we show that CD36 antagonism by represent a therapeutic target to overcome JUN hypertrophic skin scarring.

Project description:Full thickness and deep partial thickness burn injuries heal by scarring. There are several mechanisms thought to be essential for the development of burn scars, but a challenge to studying the skin response to burn injury is that there are few animal models of burn scarring that are either clinically similar to human burn scars or are practical for most investigators to use. The purpose of this study was to examine the changes in RNA expression in human skin to burn injury. This was done by comparing pre-injury tissue from otherwise healthy adults undergoing aesthetic scarification created by branding with a hot metal object to serial samples of untreated wounds in the same subjects.