Sunlight (UVB) triggers cutaneous lupus erythematosus (CLE) and systemic lupus through an unknown mechanism. We tested the hypothesis that UVB triggers CLE through a CSF-1-dependent, macrophage (Mø)-mediated mechanism in MRL-Faslpr mice. By constructing mutant MRL-Faslpr strains expressing varying levels of CSF-1 (high, intermediate, none), and use of an ex vivo gene transfer to deliver CSF-1 intradermally, we determined that CSF-1 induces CLE in lupus-susceptible MRL-Faslpr mice, but not in lupus-resistant BALB/c mice. UVB incites an increase in Møs, apoptosis in the skin, and CLE in MRL-Faslpr, but not in CSF-1-deficient MRL-Faslpr mice. Furthermore, UVB did not induce CLE in BALB/c mice. Probing further, UVB stimulates CSF-1 expression by keratinocytes leading to recruitment and activation of Møs that, in turn, release mediators, which induce apoptosis in keratinocytes. Thus, sunlight triggers a CSF-1-dependent, Mø-mediated destructive inflammation in the skin leading to CLE in lupus-susceptible MRL-Faslpr but not lupus-resistant BALB/c mice. Taken together, CSF-1 is envisioned as the match and lupus susceptibility as the tinder leading to CLE.
Reorganization of skin during wound healing, inflammatory disorders, or cancer growth is the result of expression changes of multiple genes associated with tissue morphogenesis. We wanted to identify proteins involved in skin remodeling and select those that may be targeted for agonistic or antagonist therapeutic approaches in various disease processes. Full-thickness human skin was grafted to severe combined immunodeficient mice and injected intradermally with 38 different adenoviral vectors inserted with 37 different genes coding for growth factors, cytokines, proteolytic enzymes and their inhibitors, adhesion receptors, oncogenes, and tumor suppressor genes. Responses were characterized for infiltration of inflammatory cells, vascular density, matrix formation, fibroblast-like cell proliferation, and epidermal hyperplasia. Of the 17 growth factor vectors, 16 induced histological changes in human skin. Members of the VEGF and angiopoietin families induced neovascularization. PDGFs and TGF-betas stimulated connective tissue formation, and the chemokines IL-8 and MCP-1 attracted inflammatory neutrophils and monocytes, respectively. The serine protease uPA induced a vascular response similar to that of VEGF. Vectors with adhesion receptors, oncogenes and tumor suppressor genes had, with few exceptions, little effects on skin architecture. The overall results suggest that adenoviral vectors can effectively remodel the architecture of human skin for studies in morphogenesis, inflammatory skin disorders, wound healing, and cancer development.
DFSP may demonstrate areas with features more characteristic of a benign neural lesion, such as a neurofibroma, which can lead to underdiagnosis and subsequent failure to treat. Clinicians and pathologists should recognize this potential diagnostic pitfall and understand that equivocal clinical information, combined with non-specific immunohistochemical staining patterns, can further complicate the dilemma. In these situations, where DFSP is the likely diagnosis but definitive evidence cannot be obtained, full excision of the lesion should be recommended to avoid mistreatment of a potentially malignant lesion.
Melanoma develops from a series of architectural and phenotypically distinct stages and becomes progressively aggressive. Considerable progress has been made in understanding the biological, pathological, and immunological aspects of human melanoma. Genetic and cytogenetic studies have revealed broad chromosomal abnormalities and wide mutational spectra. Precise biological and molecular determinants responsible for melanoma progression are not yet known. This is in part due to lack of experimental models that mimic human melanomas. Experimental models in melanoma should not only identify cause and origin of malignancy, but also should represent the ordered progression steps that culminate in metastasis to distant organs. Currently, there are several mouse and other vertebrate melanoma models under investigation; several of them promise to shed light on mechanisms of melanomagenesis. However, many of them suffer from lack of context to human skin architecture and hence, are of basic interest. The lack of appropriate models impeded the efforts to understand origin, etiology, progression and ultimately therapeutic benefits to humans. Development of human skin-mouse chimeric models has appeal because it mimics human diseases. In addition, human artificial skin constructs in vitro promises to be a versatile and efficient model to study not only origin and mechanisms of melanoma, but also progression. This review will focus on the recent progress in establishing tumor models in melanoma in general and their relevance to human melanoma as molecular determinants of tumor progression.
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