Manganese-Mediated Decrease in Levels of c-RET and Tyrosine Hydroxylase Expression In Vitro.

Previous studies showed that overexposure to manganese causes parkinsonism, a disorder of dopaminergic neurons. Previous studies also showed that activity of c-RET kinase controls dopamine production through regulation of tyrosine hydroxylase (TH) expression, suggesting the involvement of c-RET in the development of parkinsonism. To our knowledge, however, there is no report showing a correlation between manganese-mediated parkinsonism and c-RET. In this study, we examined the effect of manganese on the expression and/or activation levels of c-RET and TH in human TH-expressing cells (TGW cells). We first found that treatment with 30 and 100 µM manganese resulted in reduction of c-RET transcript level and degradation of c-RET protein through promotion of ubiquitination. We then examined the biological significance of manganese-mediated decrease of c-RET protein expression. Decreased TH expression with decreased c-RET kinase activity was observed in c-RET protein-depleted TGW cells by treatment with manganese (30 µM) as well as by c-RET siRNA transfection. Since TH protein has been shown to be involved in the dopamine-producing pathway in previous studies, our results indicate the possibility that manganese-mediated reduction of TH expression and phosphorylation via decreased expression of c-RET protein in neural cells is involved in parkinsonism induced by manganese.

Arsenic-mediated hyperpigmentation in skin via NF-kappa B/endothelin-1 signaling in an originally developed hairless mouse model.

Chronic exposure to arsenic is associated with various diseases in humans. Skin hyperpigmentation is the most sensitive objective symptom for patients with arsenicosis. However, there is very limited information about the mechanism of arsenic-mediated skin hyperpigmentation in vivo. In this study, hairless homozygous mice (Hr/Hr-mice) that drank water containing 3 and 30 µM arsenic for 2 months developed skin hyperpigmentation with increased levels of arsenic and number of melanocytes in the skin. Since it is possible for humans to be exposed to 3 µM of arsenic in well drinking water, our results suggest that the Hr/Hr-mice could be a novel model sensitively reflecting arsenic-mediated skin hyperpigmentation. We then analyzed the mechanism of arsenic-mediated skin hyperpigmentation. The epidermis of Hr/Hr-mice and human HaCaT skin keratinocytes exposed to arsenic for 2 and 4 months, respectively, showed 5.4-21.5-fold increased levels of endothelin-1 (ET-1) expression via NF-kappa B activation. Coexposure of primary normal human epithelial melanocytes to arsenic and ET-1 activated their proliferation and melanin synthesis with increased levels of MITF-M and ET-1 receptor expression. Our results suggest that interaction between keratinocytes and melanocytes in the skin through ET-1 and its receptor contributes to arsenic-mediated skin pigmentation, a hallmark of arsenicosis.