Project description:In the present study, we demonstrate that hMSCs migrate toward human keratinocytes as well as toward conditioned medium from cultured human keratinocytes (KCM) indicating that the hMSCs can respond to signals from keratinocytes. Incubation of hMSCs with KCM induced dermal myofibroblast like differentiation characterized by expression of cytoskeletal markers vinculin and F-actin filaments with increased expression of alpha smooth muscle actin. We then examined the therapeutic efficacy of hMSCs in wound healing in two animal models representing normal and chronic wound healing. Accelerated wound healing, as determined by quantitative measurements of wound area, was observed when hMSCs and KCM exposed hMSCs (KCMSCs) were injected near the site of incisional/excisional wounds in nondiabetic athymic and NOD/SCID mice as compared with normal human fetal lung fibroblast WI38 cells or saline control induced wound healing. Experiment Overall Design: Keratinocyte conditioned media exposed MSCs(KCMSCs) were used in the experiment in triplicates as follows; Experiment Overall Design: KCM_1 Experiment Overall Design: KCM_2 Experiment Overall Design: KCM_3 Experiment Overall Design: Where as MSCs were exposed to Keratinocyte growth media for 30 days were used as a controls as follow; Experiment Overall Design: KGM_1 Experiment Overall Design: KGM_2 Experiment Overall Design: KGM_3 Experiment Overall Design: All the samples were analyzed.

Project description:The aim of this study was to provide proof of principle as to whether probiotic bacteria or their extracts, could stimulate cutaneous wound healing. To this end, we have used a keratinocyte monolayer scratch assay which assesses one important aspect of wound healing, re-epithelialization. Primary human keratinocyte monolayers were scratched and then exposed to lysates of Lactobacillus rhamnosus GG

Project description:Skin wound healing is one of the major prevalent medical problems in the worldwide. Wound healing involves multi-process synergy and re-epithelialization is an essential part of wound healing. Histone H3K36 tri-methylase Setd2 has been extensively studied in different biological processes and diseases. However, the function of Setd2 in the wound healing remains unclear. To elucidate the biological role of Setd2 in the skin wound healing, conditional gene targeting was employed to establish epidermis-specific Setd2-deficient mice. We found that Setd2 deficiency resulted in accelerated re-epithelialization during cutaneous wound healing by promoting keratinocytes proliferation and migration. Furthermore, we demonstrated that loss of Setd2 activated the AKT/mTOR pathway, and pharmacological inhibitions of AKT and mTOR with MK2206 and rapamycin delayed wound closure, respectively. In conclusion, our results reveal the essential role of Setd2 in skin wound healing that is Setd2 loss promotes cutaneous wound healing via activation of AKT/mTOR signaling.

Project description:Skin wound healing is one of the major prevalent medical problems in the worldwide. Wound healing involves multi-process synergy and re-epithelialization is an essential part of wound healing. Histone H3K36 tri-methylase Setd2 has been extensively studied in different biological processes and diseases. However, the function of Setd2 in the wound healing remains unclear. To elucidate the biological role of Setd2 in the skin wound healing, conditional gene targeting was employed to establish epidermis-specific Setd2-deficient mice. We found that Setd2 deficiency resulted in accelerated re-epithelialization during cutaneous wound healing by promoting keratinocytes proliferation and migration. Furthermore, we demonstrated that loss of Setd2 activated the AKT/mTOR pathway, and pharmacological inhibitions of AKT and mTOR with MK2206 and rapamycin delayed wound closure, respectively. In conclusion, our results reveal the essential role of Setd2 in skin wound healing that is Setd2 loss promotes cutaneous wound healing via activation of AKT/mTOR signaling.

Project description:Non-healing wounds are a major area of unmet clinical need that remain problematic to treat; therefore, improved understanding of pro-healing mechanisms is invaluable. The enzyme arginase1 is involved in pro-healing responses with its role in macrophages best-characterised. Arginase1 is also expressed by keratinocytes; however, the function of arginase1 in these critical wound repair cells is not understood. We characterised arginase1 expression in keratinocytes during normal cutaneous repair and reveal de novo temporal and spatial expression at the epidermal wound edge. Interestingly, epidermal arginase1 expression was decreased in both human and murine delayed healing wounds. We, therefore, generated a keratinocyte specific arginase1-null mouse model (K14-cre;Arg1fl/fl) to explore arginase function. Wound repair, linked to changes in keratinocyte proliferation, migration and differentiation, was significantly delayed in K14-cre;Arg1fl/flmice. Gene expression was studied by microarray.

Project description:We perfomed RNA-seq and wound healing analysis to identify the mechanism how SOX2 promote wound healing. We showed that induction of SOX2 in skin keratinocytes accelerates cutaneous wound healing by promoting keratinocyte migration and proliferation, and enhancement of angiogenesis via the upregulation of EGFR ligands.

Project description:Impaired re-epithelialization is a hallmark of non-healing, chronic skin wounds. These represent major causes of patient morbidity, particularly amongst ever-increasing ageing and diabetic populations, posing significant challenges to healthcare providers worldwide. Despite many treatment options being available, these often offer limited benefits to healing outcomes. We address the need for more efficacious treatments through evaluation of novel epoxy-tigliane compounds as chronic wound pharmaceuticals, based on their effectiveness in promoting keratinocyte healing responses and re-epithelialization in vivo. Here, we identify that prototype epoxy-tigliane (EBC-46) and analogue (EBC-211), accelerate G1/S and S/G2 cell cycle transitions and proliferation in a normal human keratinocyte cell line of skin origin (HaCaTs). EBC-46 and EBC-211 further induce HaCaT migration/wound repopulation, even with mitomycin C treatment, suggesting epoxy-tiglianes can promote migration/repopulation independently of proliferation. Epoxy-tiglianes modulate keratin, DNA synthesis/replication, cell cycle/proliferation, motility/migration, differentiation, proteinase; and cytokine/chemokine gene expression, to facilitate enhanced responses. Although epoxy-tiglianes down-regulate cytokine/chemokine agonists of keratinocyte proliferation/migration, we demonstrate that enhanced HaCaT responses are mediated through protein kinase C (PKC) phosphorylation and abrogated by inhibition of PKC activation with bisindolylmaleimide-1 (BIM-1). By identifying how epoxy-tiglianes stimulate keratinocyte healing responses, we highlight their potential as novel therapeutics for impaired re-epithelialization associated with non-healing, chronic wounds.

Project description:Stem cells support the lifelong maintenance of adult organs but their specific roles during injury are poorly understood. Here, we demonstrate that Lgr6 marks a regionally restricted population of epidermal stem cells that interact with nerves and specialize in wound re-epithelialization. Diphtheria toxin-mediated ablation of Lgr6 stem cells delays wound healing, and skin denervation phenocopies this effect. Using intravital imaging to capture stem cell dynamics after injury, we show that wound re-epithelialization by Lgr6 stem cells is diminished following the loss of nerves. This induces the recruitment of other stem cell populations, including hair follicle stem cells, which partially compensate to mediate the wound closure. Single-cell lineage tracing and gene expression analysis reveal that the fate of Lgr6 stem cells is shifted towards differentiation following the loss of their niche. We conclude that Lgr6 epidermal stem cells are primed for injury response and interact with nerves to regulate their fate

Project description:Olfactomedin-4 (OLFM4) is an olfactomedin-domain-containing glycoprotein which regulates cell adhesion, proliferation, gastrointestinal inflammation, innate immunity and cancer metastasis. In the present study investigated its role in skin regeneration and wound healing. We found that OLFM4 expression is transiently upregulated in the proliferative phase of cutaneous wound healing in humans as well as in mice. Moreover, a significant increase in OLFM4 expression was detected in the skin of lesional psoriasis, a chronic inflammatory disease characterized by keratinocyte hyperproliferation. In vitro experiments demonstrated that OLFM4 can selectively stimulate keratinocyte proliferation and increase both keratinocyte and fibroblast migration ability. Using proteotransciptomic pathway analysis we revealed that transcription factors POU5F1/OCT4 and ESR1 acted as hubs for OLFM4-dependent signalling in keratinocytes. In vivo experiments utilizing mouse splinted full-thickness cutaneous wound healing model showed that application of recombinant OLFM4 protein can significantly improve wound healing time. Taken together, our results suggest that OLFM4 is a transiently upregulated inflammatory signal that promotes wound healing by supporting the functions of both dermal and epidermal cell compartments.

Project description:Bone morphogenetic protein (BMP) signalling plays a key role in the control of skin development and postnatal remodelling by regulating keratinocyte proliferation, differentiation and apoptosis. To study the role of BMPs in wound-induced epidermal repair, we used transgenic mice overexpressing the BMP downstream component Smad1 under the control of a K14 promoter as an in vivo model, as well as ex vivo and in vitro assays. K14-caSmad1 mice exhibited retarded wound healing associated with significant inhibition of proliferation and increased apoptosis in healing wound epithelium. Furthermore, microarray and qRT-PCR analyses revealed decreased expression of a number of cytoskeletal/cell motility-associated genes including wound-associated keratins (Krt16, Krt17) and Myo5a, in the epidermis of K14- caSmad1 mice versus wild-type controls during wound healing. BMP treatment significantly inhibited keratinocyte migration ex vivo, and primary keratinocytes of K14-caSmad1 mice showed retarded migration compared to wild-type controls. Finally, siRNA-mediated silencing of Bmpr-1B in primary mouse keratinocytes accelerated cell migration and was associated with increased expression of Krt16, Krt17 and Myo5a compared to controls. Thus, this study demonstrates that BMPs inhibit keratinocyte proliferation, cytoskeletal organization and migration in regenerating skin epithelium during wound healing, and raises a possibility for using BMP antagonists for the management of chronic wounds. Two-condition experiment, Wild type vs. Smad1 overexpressing mice. Biological replicates: 2 replicates.