Frostbite occurs when the skin is exposed to localized low temperatures. The main causes of frostbite are thought to be direct cell injury due to freezing of cells and tissue ischemia due to abnormal blood circulation. However, the molecular mechanism of frostbite has not been elucidated. This study aims to explain the molecular dynamics of frostbite using a mouse frostbite model and keratinocyte cell culture. Comprehensive gene expression analysis performed on mouse skin samples revealed that β-catenin signaling is activated by frostbite. Immunohistochemistry showed nuclear translocation of β-catenin in the skin of frostbite model mice that was not observed in mice subjected to a mechanical skin damage model induced by tape stripping. Tissue hypoxia, as detected by pimonidazole staining, coexisted with nuclear expression of β-catenin. In keratinocyte cell cultures, nuclear translocation of β-catenin was induced by hypoxia, but not by low temperature. Hypoxia induced epithelial-mesenchymal transition - an important biological event in the healing process of skin - and in vitro wound-healing activity, both of which were suppressed by β-catenin inhibition. Our results suggest that during frostbite, impaired blood flow causes hypoxia, which in turn activates β-catenin that promotes keratinocyte motility and tissue repair.
Keywords: Frostbite; Hypoxia; β catenin.
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