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Early biochemical and morphological changes in the mouse skin from cutaneous application of petrochemical and petroleum derived materialsBird, Michael Gavin January 1985 (has links)
Topical application of phorbol ester tumour promoter evoked the stimulated generation of hydrogen peroxide in the mouse skin in vivo, probably resulting from its action on an associated non-target population of infiltrating inflammatory cells. This formation was demonstrated indirectly by hydrogen peroxide dependent 3-amino-1,2,4-triazole catalase complex formation and confirms the hypothesis and findings of Goldstein et al. (1983). In the assay model discussed, n-alkanes representing the range C6-C14 caused stimulated production of hydrogen peroxide but in mouse skin already containing inflammatory cells. It is proposed that the known tumour-promoting activity of dodecane and tetradecane is free radical mediated, and that this activity is expressed when these alkanes cause an inflammatory state such as occurs upon repeated dermal application. Free radical generation and possible tumour-promoting activity of lower alkanes is latent, due to lower irritancy and high volatilization, unless these alkanes are encountered in combination with an irritant. Skin explant studies demonstrated a priming potential of the phorbol ester tumour promoter to the induction of skin catalase by oxygen. This dose-dependent induction is also seen in untreated skin and may represent a possible compensatory response to oxygen toxicity. Such induction may confound the interpretation of other air-incubation studies in vitro. The generation of hydrogen peroxide was stimulated as a consequence of abrasion, a known tumour promoting agent, and this indicates that irritation, (and possibly the immune response) has a role in tumour promotion and in the variation in strain susceptibility to tumour promoters. Current techniques for the assay of enzymic activities specific for cytochrome P-450 and cytochrome P-448 failed to detect these in mouse skin. The presence of these activities in mouse hepatic tissue was demonstrated. Preliminary data is presented for a novel skin irritation screening test based on phorbol ester-stimulated oxygen consumption by inflammatory cells responding to the applied test material. The technique may offer a more precise and convenient measure of irritancy than that provided by the currently used Draize test.
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Natural Killer Cells in Inflammatory Lesions and Transplanted Tumors in Mouse SkinNAKANE, PAUL K., OHASHI, MASARU, HABU, SONOKO, KONDO, TAKAO, NAHAR, LUTFUN 03 1900 (has links)
No description available.
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The role of EP1 receptor for prostaglandin E₂ in mouse skin carcinogenesisSurh, In Ok 07 November 2011 (has links)
Prostaglandin E₂ (PGE₂), the most abundant prostaglandin in mouse skin, has been shown to promote skin tumor development. EP1 is one of four PGE₂ receptors. EP1 mRNA levels analyzed by a quantitative real-time polymerase chain reaction were increased after treatments of 12-O-tetradecanoylphorbol 13-acetate (TPA) or ultraviolet light on skin as well as in 7,12 dimethylbenz[a]anthracene (DMBA)/TPA or UV-induced skin tumors. To determine whether the EP1 receptor levels affect skin tumor development, we generated BK5.EP1 transgenic mice which overexpress EP1 in the basal layer of the epidermis. The skins of these mice are histologically indistinguishable from wild type mice. To determine the role of EP1 in skin tumor development, a DMBA/TPA skin carcinogenesis protocol was used. EP1 transgenic mice had a reduced tumor multiplicity and a reduced tumor incidence compared to wild type mice, but had a higher papilloma to carcinoma conversion rate. In a DMBA-only skin carcinogenesis protocol, EP1 transgenic mice developed more tumors than wild type mice. The effect of EP1 on cell proliferation was measured in vivo. After TPA treatment, cell proliferation was induced in both EP1 transgenic mice and wild type mice to a similar extent. However, 5 days after DMBA treatment, there were about 2-fold more proliferating cells in the basal layer of the epidermis of EP1 transgenic mouse skin than in wild type mice. To confirm that the enhanced tumor formation in transgenic mice is in fact PGE₂ dependent, EP1 transgenic mice were administered the selective cyclooxygenase-2 inhibitor Celecoxib or a control diet starting 1 week before DMBA treatment. Surprisingly, there was no lesion development on mice that were fed Celecoxib. Histological sections of skin from Celecoxib-fed mice showed a fairly normal skin histology 2 weeks after DMBA treatment compared to the pronounced pseudocarcinomatous hyperplasia observed in control diet mice. Therefore, it can be concluded that EP1 signaling increases PGE₂ production through COX-2 induction and promotes tumor development. / text
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Neurotrophin-3 regulates mast cell functions in neonatal mouse skinBotchkareva, Natalia V., Botchkarev, Vladimir A., Paus, R., Tobin, Desmond J. January 2006 (has links)
No / Nerve growth factor (NGF) has long been recognized as an important mast cell (MC) growth factor. To explore whether other neurotrophins (NTs) of the NGF family, which are widely expressed in mouse skin, affect the numbers and/or functions of MCs we examined the effects of NT-3 on neonatal skin MCs. We demonstrate that TrkC, the high affinity NT-3 receptor, is expressed by virtually all neonatal skin MCs in C57BL/6 mice, which indicates that MCs can respond to NT-3. Skin of neonatal and early postnatal NT-3-overexpressing mice (promoter: K14) displayed significantly and up to twofold increased numbers of MCs during the first 20 days after birth, as compared to wild-type mice. To check whether this increase in MC numbers in NT-3 transgenic mice reflects a higher rate of proliferation, we performed immunohistochemistry, which revealed that only 1-2% of all skin MCs both in NT-3-overexpressing and in wild-type controls showed Ki-67-positive nuclei, suggesting that the observed differences in the number of MCs do not reflect a higher rate of MC proliferation. Additionally, we show that the effect of NT-3 on the number of MCs is most likely to be stem cell factor (SCF)-independent, because NT-3 significantly downregulates secretion of SCF-protein in cultured dermal fibroblasts, as assessed by enzyme-linked immunosorbent assay. Numbers of skin MCs in neonatal TrkC-deficient mice were found to be modestly reduced, as compared to wild-type mice, indicating that NT-3 can modulate the number of MCs directly via TrkC, although TrkC does not seem to be essential for the number of basal MCs. To further analyze the effects of NT-3 on MCs, we stimulated skin organ culture of early postnatal C57BL/6 mouse skin with 5-50 ng/ml NT-3, which induced a significant increase in MC degranulation, as visualized by Giemsa staining. However, stimulation of isolated neonatal dermal skin MCs with NT-3 in vitro failed to result in MC activation, as measured by serotonin release. Our data suggest a role for NT-3 in the maturation of MCs, such as a TrkC-mediated stimulation of the differentiation of pre-existing, less mature MCs and/or by enhancing the migration of circulating MC precursors into the skin.
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