The p42/p44 mitogen-activated protein kinase (MAPK) cascade includes Ras, Raf, Mek, and Erk MAPK. To determine the effect of a full knockout at a single level of this signaling pathway in mammals, and to investigate functional redundancy between Mek1 and Mek2, we disrupted these genes in murine and human epidermis. Loss of either protein alone produced no phenotype, whereas combined Mek1/2 deletion in development or adulthood abolished Erk1/2 phosphorylation and led to hypoproliferation, apoptosis, skin barrier defects, and death. Conversely, a single copy of either allele was sufficient for normal development. Combined Mek1/2 loss also abolished Raf-induced hyperproliferation. Human tissue deficient in either Mek isoform was normal, whereas loss of both proteins led to hypoplasia, which was rescued by active Erk2 expression. These data indicate that Mek1/2 are functionally redundant in the epidermis, where they act as a linear relay in the MAPK pathway to mediate development and homeostasis.
Little is known about the mechanisms involved in the dysfunction of melanocytes in vitiligo epidermis. It is hypothesized that some cytokine/receptor interactions may be affected, resulting in dysfunction and/or loss of melanocytes. This study has compared the expression of endothelin (ET)-1, the ET-1 receptor (ET(B)R), granulocyte macrophage colony stimulating factor (GM-CSF), stem cell factor (SCF), the SCF receptor (KIT protein), tyrosinase, and S100 alpha between lesional and non-lesional vitiligo epidermis. Analysis by reverse transcription-polymerase chain reaction (RT-PCR) and by western blotting for ET-1 and SCF unexpectedly demonstrated up-regulated expression of these cytokines in lesional vitiligo epidermis. Immunohistochemistry with antibodies to melanocyte markers revealed that at the edge of the lesional epidermis, melanocytes remain and express tyrosinase, S100 alpha and ET(B)R, but not KIT protein or melanocyte-specific microphthalmia-associated transcription factor (MITF-M). Quantitation of the staining revealed a slight or moderate decrease in the number of S100 alpha, tyrosinase, and ET(B)R-positive cells at the edge of the lesional epidermis. In contrast, the number of cells expressing KIT protein was markedly decreased at the edge of the lesional epidermis compared with the non-lesional epidermis. At the centre of the lesional epidermis, there was complete loss of melanocytes expressing KIT protein, S100 alpha, ET(B)R, and/or tyrosinase. Western blotting revealed down-regulated expression of c-kit and MITF-M proteins at the edge of the lesional epidermis in vitiligo. These findings suggest that reduction in the expression of KIT protein by melanocytes and its downstream effectors, including MITF-M, may be associated with the dysfunction and/or loss of melanocytes in vitiligo epidermis.
Recently T cell immunoreceptor with Ig and ITIM domains (TIGIT) was reported as a candidate for novel immune checkpoints. However, the impact of TIGIT on melanoma specific CTLs in the effector phase remains still unclear. In this study, we demonstrated that melanoma cells control anti-melanoma CTL responses via the TIGIT-CD155 interaction in the effector phase. TIGIT is an inhibitory receptor expressed on T cells, and CD155 is one of the cognate ligands expressed on the tumor cells or antigen-presenting cells. First, we confirmed that CD155 was constitutively expressed on melanoma cells. We then demonstrated that CD155 on melanoma cells suppressed cytokine release from melanoma-specific CTLs via interaction with TIGIT. Overexpression of CD155 enhanced, and its downregulation attenuated the suppressive effect. This suggested that anti-melanoma CTL responses are controlled not only by an imbalance in CD226 (an activating molecule binds to CD155) and TIGIT expression on T cells but also by the expression levels of CD155 on melanoma cells. In addition, co-blockade of TIGIT and PD-1 signals synergistically elicited a response of tumor-infiltrating lymphocytes (TILs) on autologous melanoma cells. These results suggest that the CD155-TIGIT interaction should be blocked for enhancement of anti-melanoma immune responses.Journal of Investigative Dermatology accepted article preview online, 12 October 2015. doi:10.1038/jid.2015.404.
Malassezia spp. are lipophilic fungi that occur on all skin surfaces of humans and animals as commensal and pathogenic organisms. In the 2000s, several new species were added to the Malassezia genus by Japanese researchers. The genus Malassezia now includes 14 species of basidiomycetous yeast. Culture-independent molecular analysis clearly demonstrated that the DNA of Malassezia spp. was predominantly detected in core body and arm sites, suggesting that they are the dominant fungal flora of the human body. Malassezia spp. have been implicated in skin diseases including pityriasis versicolor (PV), Malassezia folliculitis (MF), seborrheic dermatitis (SD) and atopic dermatitis (AD). While Malassezia spp. are directly responsible for the infectious diseases, PV and MF, they act as an exacerbating factor in AD and SD. The fatty acids generated by Malassezia lipase can induce inflammation of the skin, resulting in development of SD. Patch and serum immunoglobulin E tests revealed that AD patients were hypersensitive to Malassezia. However, these findings only partially elucidated the mechanism by which Malassezia spp. induce inflammation in the skin; understanding of the pathogenetic role of Malassezia spp. in SD or AD remains incomplete. In this article, the latest findings of Malassezia research are reviewed with special attention to skin diseases.
Background:The availability of molecular-targeted therapies for the treatment of melanoma has emphasised the need to identify mutations in target genes such as BRAF and KIT. Circulating tumour cells (CTC) are present in the peripheral blood of a significant proportion of cancer patients.Methods:High molecular weight melanoma-associated antigen (HMW-MAA) was used to isolate melanoma cells from peripheral blood as it is selectively expressed at high levels on melanomas. The HMW-MAA-positive cells were isolated using immunomagnetic beads. After removing CD45+ cells, CTC were identified by staining with MART-1- and gp100-specific antibodies (HMW-MAA+, CD45−, MART-1/gp100+). Single, isolated CTC were then subjected to BRAF and KIT mutational analysis.Results:CTC (HMW-MAA+, CD45−, MART-1/gp100+) were isolated from the blood of 11 patients and BRAF and KIT were sequenced in nine and four patients, respectively. The BRAF sequences identified in the CTC were inconsistent with those identified in autologous melanoma tumours in three patients and the KIT sequences were inconsistent in three patients. In addition, polyclonal BRAF mutations were identified in one patient and concomitant mutations in BRAF and KIT were identified in another patient.Conclusion:Melanoma cells show clonal heterogeneity. Therefore, CTC genotyping may be crucial for successful molecular-targeted therapy.
Phosphoinositide 3-kinases (PI3Ks) regulate an array of cellular processes and are comprised of three classes. Class I PI3Ks include the well-studied agonist-sensitive p110 isoforms; however, the functions of class II and III PI3Ks are less well characterized. Of the three class II PI3Ks, C2␣ and C2 are widely expressed in many tissues, including the epidermis, while C2␥ is confined to the liver. In contrast to the class I PI3K p110␣, which is expressed throughout the epidermis, C2 was found to be localized in suprabasal cells, suggesting a potential role for C2 in epidermal differentiation. Overexpressing C2 in epidermal cells in vitro induced differentiation markers. To study a role for C2 in tissue, we generated transgenic mice overexpressing C2 in both suprabasal and basal epidermal layers. These mice lacked epidermal abnormalities. Mice deficient in C2 were then generated by targeted gene deletion. C2 knockout mice were viable and fertile and displayed normal epidermal growth, differentiation, barrier function, and wound healing. To exclude compensation by C2␣, RNA interference was then used to knock down both C2␣ and C2 in epidermal cells simultaneously. Induction of differentiation markers was unaffected in the absence of C2␣ and C2. These findings indicate that class II PI3Ks are not essential for epidermal differentiation.
IFN-γ released from cytotoxic T lymphocytes (CTLs) during the effector phase is essential for rejecting bulky melanoma tumors. In contrast, IFN-γ is known to induce certain immunosuppressive factors in tumor cells such as programmed cell death 1 ligand 1 (PD-L1). In this study, we have identified candidates for IFN-γ-inducible CTL-suppressive factors in melanoma cells using complementary DNA microarray analysis, and CD271/p75/neurotrophin receptor (NTR) was one of the candidate genes. Recently, CD271 was identified as a marker of the cancer stem cell-like population in human melanoma tissues. In this study, we showed that overexpression of CD271 on melanoma cells suppressed the in vitro activation of melanoma-specific CTLs. This suppression was mediated by CD271 ligation with activated CTL-derived nerve growth factor and the subsequent downregulation of melanoma antigens. Moreover, we found that the expression levels of PD-L1 on melanoma cells correlated with those of CD271, and they additively suppressed the activation of melanoma-specific CTLs. To the best of our knowledge, the role of overexpression of CD271 in an anti-melanoma T-cell response has been unreported.
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