Project description:Characterization at the global transcriptome level of the gene networks ensuring the regulation of the immature status of cutaneous stem- and precursor-cells is a necessary step to further understand the concept of ‘stemness’ in this tissue. Moreover, considering possible clinical applications, the search for molecular targets to control stem cell characteristics and regenerative capacity is a necessary step to improve therapeutic approaches. Cutaneous cell therapy is concerned by this objective, as skin graft bioengineering requires a phase of ex vivo expansion of keratinocytes from donors, during which the preservation of a sufficient stem cell pool is critical for graft take and long-term skin regeneration. We have investigated the role of transcription factor MXD4/MAD4 in native keratinocyte precursors from adult human skin. A stable lentiviral-based shRNA-mediated MXD4 knock‑down (KD) approach was developed and used to study the properties of MXD4-deficient [MXD4KD] versus control [MXD4WT] native keratinocyte precursors. Using long-term cultures and clonal assays, we found that decreased MXD4 expression increased keratinocyte precursor immaturity and clonogenic potential, thus promoting self-renewal. Importantly, [MXD4KD] keratinocyte precursors exhibited an improved capacity for three-dimensional epidermis reconstruction, which was preserved at a late ex vivo expansion stage where this potential was lost in [MXD4WT] keratinocytes. To analyze the biological impact of MXD4 knock‑down at the molecular level, comparative transcriptome profiling of [MXD4WT] and [MXD4KD] cells was performed using next-generation RNA sequencing (RNA-seq). This set of data provides a material that permits the dissection of genetic networks modulated by MXD4 in human keratinocyte precursor cells, and controlling their immature status and epidermis regeneration capacity.

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:The repair of skin and soft tissue defects has been a long-standing topic of interest in plastic surgery. Skin grafts and flaps are the most commonly used methods for such repair, but both have some disadvantages. If a high-quality skin flap transplantation outcome could be obtained through simple skin grafting, it would surely benefit a majority of patients. Transplantation of adipose-derived stem cells (ADSCs) into skin and soft tissue wounds is a promising “therapeutic angiogenesis” strategy in this context. In the present study, we used TNF-α to mobilize ADSCs for the tissue regenerative process. Then, we injected the TNF-α-activated ADSCs intradermally into the donor skin of full-thickness skin grafts (FTSGs). TNF-α may activate ADSCs through the TNF-α/NF-κB pathway and enhance the ability of ADSCs to signal the paracrine secretion of the angiogenic factor IL-8, ultimately promoting the angiogenesis of donor skin. The use of vasculature-rich donor skin for grafting presented in our study could accelerate skin graft anastomosis; shorten the nutrient deprivation time of the epidermis, hair follicles, and dermis; and thereby improve the survival of FTSGs. Overall, the findings of the present study demonstrate a possible mechanism through which TNF-α acts on ADSCs to improve their angiogenic capacity and provide a novel approach for the repair of skin and soft tissue wounds.

Project description:The incidence of keratinocyte-derived skin cancer, cutaneous squamous cell carcinoma (cSCC) is increasing worldwide making it the second most common metastatic skin cancer. We used microarrays to characterize gene expression profile in normal human epidermal keratinocytes (NHEK) and cSCC cell lines.

Project description:The goal of the experiment: To characterize the dynamic gene expression profile of engineered human skin in vitro and after grafting, and compare with expression profile of uninjured human skin. Bioengineered skin substitutes can facilitate wound closure in massively burned patients, but deficiencies limit their outcomes compared to native skin autografts. To identify gene programs associated with their in vivo capabilities and limitations, we extended previous gene expression profile analyses to now compare engineered skin following in vivo grafting to both in vitro maturation and to normal human skin. Cultured skin substitutes were grafted to full-thickness wounds in athymic mice; biopsies for microarray analyses were collected at multiple in vitro and in vivo time points. Over 10,000 transcripts exhibited large-scale expression pattern differences during in vitro and in vivo maturation. Using hierarchical clustering, eleven different expression profile clusters were partitioned based on differential sample type and temporal stage-specific activation or repression. Analyses show that the wound environment exerts a massive influence on gene expression in skin substitutes. For example, in vivo healed skin substitutes gained expression of many native skin-expressed genes, including those associated with epidermal barrier and multiple categories of cell-cell and cell-basement membrane adhesion. In contrast, immunologic, trichogenic, and endothelial gene programs were largely lacking. These analyses suggest important areas to guide further improvement of engineered skin for both increased homology with native skin and enhanced wound healing.

Project description:The goal of the experiment: To characterize the dynamic gene expression profile of engineered human skin in vitro and after grafting, and compare with expression profile of uninjured human skin. Bioengineered skin substitutes can facilitate wound closure in massively burned patients, but deficiencies limit their outcomes compared to native skin autografts. To identify gene programs associated with their in vivo capabilities and limitations, we extended previous gene expression profile analyses to now compare engineered skin following in vivo grafting to both in vitro maturation and to normal human skin. Cultured skin substitutes were grafted to full-thickness wounds in athymic mice; biopsies for microarray analyses were collected at multiple in vitro and in vivo time points. Over 10,000 transcripts exhibited large-scale expression pattern differences during in vitro and in vivo maturation. Using hierarchical clustering, eleven different expression profile clusters were partitioned based on differential sample type and temporal stage-specific activation or repression. Analyses show that the wound environment exerts a massive influence on gene expression in skin substitutes. For example, in vivo healed skin substitutes gained expression of many native skin-expressed genes, including those associated with epidermal barrier and multiple categories of cell-cell and cell-basement membrane adhesion. In contrast, immunologic, trichogenic, and endothelial gene programs were largely lacking. These analyses suggest important areas to guide further improvement of engineered skin for both increased homology with native skin and enhanced wound healing. Experiment Overall Design: In the study, we hybridized RNA isolated from skin substitutes from days 3, 7, or 14 of in vitro incubation, and 3, 7, 14, 28, 42, or 56 days after transplantation to athymic mice, to Affymetrix Human U133 Plus 2.0 gene chips.

Project description:Our goal was to identify gene expression patterns that correlated with treatment of established autoimmune alopecia in C3H/HeJ mice following alopecic graft transplantation skin from 3 mice were taken at 6, 12 and, in some cases, 24 weeks of topical drug administration following grafting; mice were treated with ruxolitinib (jak1i), tofacitinib (jak3i), or control pbs

Project description:Our goal was to identify gene expression patterns that correlated with prevention of autoimmune alopecia in C3H/HeJ mice following alopecic graft transplantation skin from 3-5 mice were taken at 5/6 weeks and 12/13 weeks of drug administration following grafting; mice were treated with ruxolitinib (jak12i) by oral gavage, tofacitinib (jak3i) by osmotic pump, antiIL15R-beta antibody by i.p. injection, or control pbs by either ip injection, oral gavage, or osmotic pump. sham indicates mice that received no graft.

Project description:The incidence of keratinocyte-derived skin cancer, cutaneous squamous cell carcinoma (cSCC) is increasing worldwide making it the second most common metastatic skin cancer. In this project we used SOLiD next generation sequencing to characterize gene expression profiles in normal human epidermal keratinocytes (NHEKs) and cSCC cell lines.

Project description:We report transcripts from tomato:tomato and pepper:pepper self-grafts, and tomato:pepper and pepper:tomato hetergrafts over 4 time points: 24 hours after grafting, 3 days after grafting, 5 day after grafting, and 2 weeks after grafting Examination of 4 graft combinations over 4 time points