Ratite oils promote keratinocyte cell growth and inhibit leukocyte activation.

Traditionally, native Australian aborigines have used emu oil for the treatment of inflammation and to accelerate wound healing. Studies on mice suggest that topically applied emu oil may have anti-inflammatory properties and may promote wound healing. We investigated the effects of ratite oils (6 emu, 3 ostrich, 1 rhea) on immortalized human keratinocytes (HaCaT cells) in vitro by culturing the cells in media with oil concentrations of 0%, 0.5%, and 1.0%. Peking duck, tea tree, and olive oils were used as comparative controls. The same oils at 0.5% concentration were evaluated for their influence on peripheral blood mononuclear cell (PBMC) survival over 48 hr and their ability to inhibit IFNγ production in PBMCs activated by phytohemagglutinin (PHA) in ELISpot assays. Compared to no oil control, significantly shorter population doubling time durations were observed for HaCaT cells cultured in emu oil (1.51×faster), ostrich oil (1.46×faster), and rhea oil (1.64×faster). Tea tree oil demonstrated significant antiproliferative activity and olive oil significantly prolonged (1.35×slower) cell population doubling time. In contrast, almost all oils, particularly tea tree oil, significantly reduced PBMC viability. Different oils had different levels of inhibitory effect on IFNγ production with individual emu, ostrich, rhea, and duck oil samples conferring full inhibition. This preliminary investigation suggests that emu oil might promote wound healing by accelerating the growth rate of keratinocytes. Combined with anti-inflammatory properties, ratite oil may serve as a useful component in bandages and ointments for the treatment of wounds and inflammatory skin conditions.

Differentiation of HaCaT cell and melanocyte from their malignant counterparts using micro-Raman spectroscopy guided by confocal imaging.

BACKGROUND: Skin cancer is the most common type of cancer in humans. Current techniques for identifying normal and neoplastic tissues are either destructive or not sensitive and specific enough. Raman spectroscopy and confocal imaging may obviate many limitations of existing methods by providing noninvasive, high-resolution, and real-time morphological and biochemical analysis of living tissues and cells. METHODS: We conducted micro-Raman spectroscopy studies on HaCaT cells, melanocytes (MC) and their malignant counterparts squamous cell carcinoma (SCC) and melanoma (MM) cells, respectively. Reflectance confocal imaging is used as guidance for the spectral measurements. RESULTS: Significant differences were found between the spectra of HaCaT cells and SCC cells, MC cells and MM cells, as well as all normal cells (HaCaT and MC) and all tumor cells (SCC and MM). Approximately 90% sensitivity and specificity was achieved for all the separations that we performed. CONCLUSION: Our results demonstrated the robust capability of confocal Raman spectroscopy in separating different cell lines. The acquired Raman spectra of major types of skin cells and their malignant counterparts will be useful for the interpretation of Raman spectra from in vivo skin. We believe it will eventually help diagnosis of skin cancer and other skin disease in clinical dermatology.

CXCR3/ligands are significantly involved in the tumorigenesis of basal cell carcinomas.

Basal cell carcinoma (BCC) is the most common skin malignancy encountered worldwide. We hypothesized that CXC chemokines, small cytokines involved in inducing directed leukocyte chemotaxis, could play a key role in the modulation of BCC growth. In this study, quantitative RT-PCR revealed that the chemokines CXCL9, 10, 11, and their receptor CXCR3 were significantly upregulated by an average 22.6-fold, 9.2-fold, 26.6-fold, and 4.9-fold, respectively in BCC tissue samples as compared with nonlesional skin epithelium. Immunohistochemistry analysis revealed that CXCR3, CXCL10, and CXCL11, but not CXCL9, colocalized with cytokeratin 17 (K17) in BCC keratinocytes. In addition, CXCR3 and its ligands were expressed in cells of the surrounding BCC stroma. The chemokines and K17 were also expressed in cultured human immortalized HaCaT keratinocytes. Exposure of HaCaT cells or primary BCC-derived cells to CXCL11 peptides in vitro significantly increased cell proliferation. In primary BCC-derived cell cultures, addition of CXCL11 progressively selected for K17+/CXCR3+ co-expressing cells over time. The expression of CXCR3 and its ligands in human BCC keratinocytes, the enhancement of keratinocyte cell proliferation by CXCL11, and the homogeneity of K17+ BCC cells in human BCC-isolated cell population supported by CXCR3/CXCL11 signaling all suggest that CXCR3 and its ligands may be important autocrine and/or paracrine signaling mediators in the tumorigenesis of BCC.

Alopecia areata: pathogenesis and potential for therapy.

Although the complete picture for alopecia areata (AA) pathogenesis has yet to be determined, recent research has made much progress in our understanding of the disease mechanism. Numerous circumstantial evidence supports the notion that AA is fundamentally a disease mediated by inflammatory cells and may be autoimmune in nature. Recent research has shown the hair-loss phenotype is precipitated predominantly by CD8+ lymphocytes, but the disease mechanism is driven by CD4+ lymphocytes. Although genetic susceptibility is a key contributor to disease development, disease onset and phenotypic presentation are probably modified by complex environmental interplay. On the basis of our current understanding of AA disease pathogenesis, several experimental and theoretical therapeutic approaches might be possible. However, the pathogenetic disease mechanism is particularly robust and the development of a cure for AA will be a significant challenge.

Somatostatin expression in human hair follicles and its potential role in immune privilege.

Immune privilege (IP) is believed to exist in the anagen hair follicle (HF). Studies have shown that downregulation of major histocompatibility complex Class I occurs and immunosuppressive factors are expressed in the HF bulb and bulge. However, demonstration and quantification of functional IP in HF cells are required. We examined the middle (sheath) and lower (bulb) portions of the human HF using quantitative real-time RT-PCR (qPCR), immunohistology, ELISA, in vitro coculture with peripheral blood mononuclear cells (PBMCs), and flow cytometry. We found that HF cells, relative to non-follicular epidermal cells, failed to promote allogeneic PBMC proliferation and CD4(+) and CD8(+) IFNγ production. By qPCR, we found significant downregulation of Class I and Class II HLA alleles in both the bulb and sheath, and upregulation of multiple immunoregulatory genes. It is noteworthy that somatostatin (SST) was significantly upregulated relative to epidermis. By immunohistochemistry, SST was most strongly expressed in the HF outer root sheath, and, by ELISA, cultured sheath cells secreted SST. PBMCs, cultured with stimulatory allogeneic epidermal cells and SST, secreted significantly less IFNγ than controls. Addition of SST antagonists to PBMCs cocultured with allogeneic HF cells increased IFNγ secretion. The data identify SST as a secretory factor potentially contributing to the HF IP repertoire.

Lichen planopilaris and pseudopelade of Brocq involve distinct disease associated gene expression patterns by microarray.

BACKGROUND: Lichen planopilaris (LPP) and pseudopelade of Brocq (PPB) are two scarring alopecia diagnoses that exhibit similar clinical features. Some suggest LPP and PPB are not distinct diseases, but rather different clinical presentations in a spectrum derived from the same underlying pathogenic mechanism. OBJECTIVE: We explored the degree of similarity between LPP and PPB gene expression patterns and the potential for common and unique gene pathway and gene activity in LPP and PPB using microarrays. METHODS: Microarray analysis, using a 21K cDNA set, was performed on pairs of biopsies obtained from affected and unaffected scalp of untreated patients. Diagnosis was confirmed by histopathology. Significantly differentially expressed genes were identified by analysis of microarray results in various datasets and screened for signaling pathway involvement. Selected genes were validated by quantitative PCR and immunohistology. RESULTS: The global gene expression profiles in LPP and PPB versus comparative intra-control scalp tissue were distinguishable by significance analysis of microarrays (SAM). There was limited commonality in the gene expression profiles between LPP and PPB. Specific genes, such as MMP11, TNFSF13B, and APOL2, were identified with significantly differential expression in association with LPP versus PPB. CONCLUSIONS: Our findings may have important implications for understanding the pathogenesis of LPP and PPB at the molecular level. Results suggest LPP and PPB involve different mechanisms of disease development and should be regarded as biologically distinct cicatricial alopecia diagnoses. Genes that we have identified may be useful as markers of the respective diagnoses and may be potential therapeutic targets.