Kevin L. McFarland

Defining MC1R Regulation in Human Melanocytes by Its Agonist α-Melanocortin and Antagonists Agouti Signaling Protein and β-Defensin 3

The melanocortin 1 receptor (MC1R), a Gs protein-coupled receptor, plays an important role in human pigmentation. We investigated the regulation of expression and activity of the MC1R in primary human melanocyte cultures. Human beta defensin 3 (HBD3) acted as an antagonist for MC1R, inhibiting the α-melanocortin (α-MSH)-induced increase in the activities of adenylate cyclase, and tyrosinase, the rate-limiting enzyme for melanogenesis. α-Melanocortin and forskolin, which activate adenylate cyclase, and 12-o-tetradecanoyl phorbol 13-acetate, which activates PKC, increased, while exposure to ultraviolet radiation (UV) reduced, MC1R gene and membrane protein expression. Brief treatment with α-MSH resulted in MC1R desensitization, while continuous treatment up to 3 hours caused a steady rise in cAMP, suggesting receptor recycling. Pretreatment with agouti signaling protein or HBD3 prohibited responsiveness to α-MSH, but not forskolin, suggesting receptor desensitization by these antagonists. Melanocytes from different donors expressed different levels of the G-protein-coupled receptor kinases (GRK) 2, 3, 5, and 6, and β-arrestin 1. Therefore, in addition to MC1R genotype, regulation of MC1R expression and activity is expected to affect human pigmentation and the responses to UV.

Engineered human skin substitutes undergo large-scale genomic reprogramming and normal skin-like maturation after transplantation to athymic mice.

Bioengineered skin substitutes can facilitate wound closure in severely burned patients, but deficiencies limit their outcomes compared with 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 after in vivo grafting with both in vitro maturation and normal human skin. Cultured skin substitutes were grafted on full-thickness wounds in athymic mice, and biopsy samples 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, 11 different expression profile clusters were partitioned on the basis of 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 the 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, immunological, trichogenic, and endothelial gene programs were largely lacking. These analyses suggest important areas for guiding further improvement of engineered skin for both increased homology with native skin and enhanced wound healing.

Keloid-derived keratinocytes exhibit an abnormal gene expression profile consistent with a distinct causal role in keloid pathology

Keloids are disfiguring scars that extend beyond the original wound borders and resist treatment. Keloids exhibit excessive extracellular matrix deposition, although the underlying mechanisms remain unclear. To better understand the molecular basis of keloid scarring, here we define the genomic profiles of keloid fibroblasts and keratinocytes. In both cell types, keloid‐derived cells exhibit differential expression of genes encompassing a diverse set of functional categories. Strikingly, keloid keratinocytes exhibited decreased expression of a set of transcription factor, cell adhesion, and intermediate filament genes essential for normal epidermal morphology. Conversely, they exhibit elevated expression of genes associated with wound healing, cellular motility, and vascular development. A substantial number of genes involved in epithelial–mesenchymal transition were also up‐regulated in keloid keratinocytes, implicating this process in keloid pathology. Furthermore, keloid keratinocytes displayed significantly higher migration rates than normal keratinocytes in vitro and reduced expression of desmosomal proteins in vivo. Previous studies suggested that keratinocytes contribute to keloid scarring by regulating extracellular matrix production in fibroblasts. Our current results show fundamental abnormalities in keloid keratinocytes, suggesting they have a profoundly more direct role in keloid scarring than previously appreciated. Therefore, development of novel therapies should target both fibroblast and keratinocyte populations for increased efficacy.

Characterization of Hair Follicle Development in Engineered Skin Substitutes

Generation of skin appendages in engineered skin substitutes has been limited by lack of trichogenic potency in cultured postnatal cells. To investigate the feasibility and the limitation of hair regeneration, engineered skin substitutes were prepared with chimeric populations of cultured human keratinocytes from neonatal foreskins and cultured murine dermal papilla cells from adult GFP transgenic mice and grafted orthotopically to full-thickness wounds on athymic mice. Non-cultured dissociated neonatal murine-only skin cells, or cultured human-only skin keratinocytes and fibroblasts without dermal papilla cells served as positive and negative controls respectively. In this study, neonatal murine-only skin substitutes formed external hairs and sebaceous glands, chimeric skin substitutes formed pigmented hairs without sebaceous glands, and human-only skin substitutes formed no follicles or glands. Although chimeric hair cannot erupt readily, removal of upper skin layer exposed keratinized hair shafts at the skin surface. Development of incomplete pilosebaceous units in chimeric hair corresponded with upregulation of hair-related genes, LEF1 and WNT10B, and downregulation of a marker of sebaceous glands, Steroyl-CoA desaturase. Transepidermal water loss was normal in all conditions. This study demonstrated that while sebaceous glands may be involved in hair eruption, they are not required for hair development in engineered skin substitutes.

Expression of genes encoding antimicrobial proteins and members of the toll-like receptor/nuclear factor-κB pathways in engineered human skin

Skin functions as a first line of defense against microbial invasion. Tissue‐engineered cultured skin substitutes (CSS) are used to aid wound closure in massively burned patients, and have been used to facilitate safe and effective wound closure in adult patients with chronic wounds. Although they contain only two cell types at grafting, they can potentially contribute to innate defense against pathogens and stimulation of adaptive immunity. Gene microarrays were used to identify expression in cultured skin of genes involved in innate and adaptive immune responses, and to evaluate the effects of cytokine stimulation on expression levels. Cultured skin expressed multiple antimicrobial protein genes, including human β defensins 1 and 2 and S100A12. In addition, the antiviral gene APOBEC3G, which was not previously identified in skin, was expressed in CSS and up‐regulated by interleukin‐1α and tumor necrosis factor α. Cathelicidin was not expressed in unstimulated CSS, but was induced by cytokine treatment. Further, genes encoding several proinflammatory cytokines and members of the toll‐like receptor and nuclear factor κ B pathways were expressed in CSS, suggesting that cells in CSS can mediate activation of inflammatory responses. The observed expression patterns indicate that engineered human skin utilizes innate defense mechanisms similar to those reported for native skin. Therefore, regulation of these pathways by cytokine stimulation may offer a mechanism for increasing innate immunity in CSS to combat wound infection after grafting onto patients.

Inhibition of hyaluronan synthase 2 reduces the abnormal migration rate of keloid keratinocytes.

Keloids are fibroproliferative scars that spread beyond the original wound boundary and are very resistant to treatment. Development of highly effective therapies requires a comprehensive understanding of the mechanisms regulating keloid formation. Previous studies indicated that keloid keratinocytes have abnormal expression of genes involved in differentiation and adhesion, and increased migration rates. The objective of the current study was to better understand the role of hyaluronan synthase 2 (HAS2) in keloid keratinocyte migration and gene expression. Keratinocytes were isolated from keloid scars and normal skin. Migration rates of keloid keratinocytes were quantified using an in vitro scratch assay. Expression levels of HAS2, related HAS1, and HAS3 genes, and genes aberrantly expressed in keloid keratinocytes, were quantified using real-time polymerase chain reaction. Treatment with 4-methylumbelliferone (4MU) was used to inhibit hyaluronic acid synthesis. The expression of HAS2 was significantly increased in keloid vs normal keratinocytes. Treatment with 4MU caused a dose-dependent reduction in keloid keratinocyte migration and HAS2 expression; HAS3 expression was moderately inhibited by 4MU and HAS1 was not expressed. Keloid keratinocytes displayed a motile phenotype in vitro, including loose colonies and widely separated refractile cells; this phenotype was normalized by 4MU. Further, 4MU altered gene expression in keloid keratinocytes. The results suggest that HAS2 overexpression contributes to increased migration and altered gene expression in keloid keratinocytes. Abnormal keratinocyte migration may contribute to the overhealing of keloid scars beyond the original wound boundaries. Therefore, inhibition of HAS2 expression using 4MU may represent a novel strategy for treatment of keloid scarring.

Culture medium and cell density impact gene expression in normal skin and abnormal scar-derived fibroblasts.

Fibroblasts, the main cell type of the dermis, are responsible for production and remodeling of extracellular matrix during wound healing. Disruption of either production or degradation of extracellular matrix can lead to abnormal scarring, resulting in hypertrophic scar or keloid scar. Aberrations in proliferation and gene expression have been observed in fibroblasts isolated from abnormal scars, but differences observed may be related to biologic responses to growth conditions and media formulations. This study examined gene expression in primary human fibroblasts from normal skin or abnormal scar in two culture media formulations and three relative cell densities. In general, higher expression of collagen type 1 alpha-1 (COL1A1) and alpha-2 (COL1A2) and matrix metalloproteinase 3 (MMP3) and lower levels of MMP1 were observed in all cell strains cultured in standard medium containing 10% fetal bovine serum compared with cells cultured in medium optimized for proliferation. Normal and scar-derived fibroblasts exhibited differences in gene expression in specific response to media formulations and cell density. COL1A1 and COL1A2 were increased, and MMP1 and MMP3 were decreased, in keloid cells compared with normal fibroblasts under most conditions analyzed. However, expression of plasminogen activator inhibitor 1 in keloid fibroblasts, which was significantly different than in normal fibroblasts, was either increased or decreased in response to the medium formulation and relative cell density. A related gene, plasminogen activator inhibitor 2, was shown for the first time to be significantly increased in keloid fibroblasts compared with normal fibroblasts, in both media formulations and at all three cell densities. The results emphasize the critical role of culture conditions in interpretation of cell behavior and expression data and for comparison of cells representing normal and fibrotic phenotypes.

Partial epithelial-mesenchymal transition in keloid scars: regulation of keloid keratinocyte gene expression by transforming growth factor-β1.

BackgroundKeloids are an extreme form of abnormal scarring that result from a pathological fibroproliferative wound healing process. The molecular mechanisms driving keloid pathology remain incompletely understood, hindering development of targeted, effective therapies. Recent studies in our laboratory demonstrated that keloid keratinocytes exhibit adhesion abnormalities and display a transcriptional signature reminiscent of cells undergoing epithelial-mesenchymal transition (EMT), suggesting a role for EMT in keloid pathology. In the current study, we further define the EMT-like phenotype of keloid scars and investigate regulation of EMT-related genes in keloid.MethodsPrimary keratinocytes from keloid scar and normal skin were cultured in the presence or absence of transforming growth factor beta 1 (TGF-β1) +/− inhibitors of TGF-β1 and downstream signaling pathways. Gene expression was measured using quantitative polymerase chain reaction. Migration was analyzed using an in vitro wound healing assay. Proteins in keloid scar and normal skin sections were localized by immunohistochemistry. Statistical analyses utilized SigmaPlot (SyStat Software, San Jose, CA) or SAS® (SAS Institute, Cary, NC).ResultsIn keloid and normal keratinocytes, TGF-β1 regulated expression of EMT-related genes, including hyaluronan synthase 2, vimentin, cadherin-11, wingless-type MMTV integration site family, member 5A, frizzled 7, ADAM metallopeptidase domain 19, and interleukin-6. Inhibition of canonical TGF-β1 signaling in keloid keratinocytes significantly inhibited expression of these genes, and TGF-β1 stimulation of normal keratinocytes increased their expression. The inhibition of the extracellular signal-regulated kinase 1/2 (ERK1/2) signaling pathway or the p38 mitogen-activated protein kinase pathway attenuated TGF-β1-induced expression of subsets of these genes. Migration of keloid keratinocytes, previously shown to be increased compared with normal keratinocytes, was significantly reduced by inhibition of TGF-β1 or ERK1/2 signaling. Biomarkers of EMT, including reduced E-cadherin and increased active β-catenin, were observed in keloid epidermis in vivo. However, evidence of basement membrane breakdown in keloid scar was not observed.ConclusionsThe results suggest that keloid keratinocytes exist in an EMT-like metastable state, similar to activated keratinocytes in healing wounds. The EMT-like gene expression pattern of keloid keratinocytes is regulated by canonical and non-canonical TGF-β1 signaling pathways. Therefore, interventions targeting TGF-β1-regulated EMT-like gene expression in keloid keratinocytes may serve to suppress keloid scarring.

Inflammatory responses, matrix remodeling, and re‐epithelialization after fractional CO2 laser treatment of scars

Fractional CO2 laser therapy has been used to improve scar pliability and appearance; however, a variety of treatment protocols have been utilized with varied outcomes. Understanding the relationship between laser power and extent of initial tissue ablation and time frame for remodeling could help determine an optimum power and frequency for laser treatment. The characteristics of initial injury caused by fractional CO2 laser treatment, the rates of dermal remodeling and re‐epithelialization, and the extent of inflammation as a function of laser stacking were assessed in this study in a porcine scar model.

Effects of early combinatorial treatment of autologous split‐thickness skin grafts in red duroc pig model using pulsed dye laser and fractional CO2 laser

The use of pulsed dye laser (PDL) and fractional CO2 (FX CO2) laser therapy to treat and/or prevent scarring following burn injury is becoming more widespread with a number of studies reporting reduction in scar erythema and pruritus following treatment with lasers. While the majority of studies report positive outcomes following PDL or FX CO2 therapy, a number of studies have reported no benefit or worsening of the scar following treatment. The objective of this study was to directly compare the efficacy of PDL, FX CO2, and PDL + FX CO2 laser therapy in reducing scarring post burn injury and autografting in a standardized animal model.