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Long non-coding RNA urothelial carcinoma-associated 1 (UCA1) functions as an oncogene in different human cancers, including melanoma. However, the molecular mechanism of UCA1 underlying melanoma progression still remains largely unknown. In the present study, reverse transcription quantitative polymerase chain reaction and western blot analyses were used to examine the mRNA and protein expression levels, respectively. Cell Counting Kit-8 and wound healing assays were conducted to study cell proliferation and migration, respectively. A luciferase reporter assay was used to confirm the targeting relationship. It was demonstrated that UCA1 expression was increased in melanoma tissues and cell lines. In addition, UCA1 expression was higher in melanoma tissues at stage III-IV than in tissues at stage I-II. Inhibition of UCA1 expression markedly reduced melanoma cell proliferation and migration. Further investigation revealed that UCA1 functioned in melanoma cells through directly binding with microRNA (miR)-28-5p. The expression of miR-28-5p was significantly reduced in melanoma tissues and had an inverse correlation with UCA1 expression. In addition, miR-28-5p expression was higher in melanoma tissues at advanced stages than in stage I-II tissues. Furthermore, homeobox (HOX)B3 was identified as a target gene of miR-28-5p in melanoma cells, and HOXB3 overexpression reversed the suppressive effects of UCA1 downregulation on melanoma cell proliferation and migration. Finally, HOXB3 was upregulated in melanoma tissues compared with its expression in adjacent tissues, and HOXB3 expression was increased in melanoma tissues at advanced stages. Taken together, the regulatory network of the UCA1/miR-28-5p/HOXB3 axis in melanoma was demonstrated for the first time in the present study, expanding the understanding of the molecular mechanism underlying melanoma progression. Future studies may further confirm the function of this signaling pathway in vivo.
The F1F0-ATP synthase, an enzyme complex, is mainly located on the mitochondrial inner membrane or sometimes cytomembrane to generate or hydrolyze ATP, play a role in cell proliferation. This study focused on the role of F1F0-ATP synthase in keratinocyte differentiation, and its relationship with intracellular and extracellular ATP (InATP and ExATP). The F1F0-ATP synthase β subunit (ATP5B) expression in various skin tissues and confluence-dependent HaCaT differentiation models was detected. ATP5B expression increased with keratinocyte and HaCaT cell differentiation in normal skin, some epidermis hyper-proliferative diseases, squamous cell carcinoma, and the HaCaT cell differentiation model. The impact of InATP and ExATP content on HaCaT differentiation was reflected by the expression of the differentiation marker involucrin. Inhibition of F1F0-ATP synthase blocked HaCaT cell differentiation, which was associated with a decrease of InATP content, but not with changes of ExATP. Our results revealed that F1F0-ATP synthase expression is associated with the process of keratinocyte differentiation which may possibly be related to InATP synthesis.
Background: BRAF gene mutation causes melanoma patients to develop drug resistance after 8-9 months BRAF inhibitors treatment. Therefore, overcoming BRAF inhibitor resistance has important implications for improving patient survival. Sorafenib directly inhibits tumor cell proliferation by blocking the RAF/MEK/ERKmediated cell signaling pathway. It remains unknown that whether the combination of sorafenib with vemurafenib could sensitize melanoma cells to vemurafenib, and the underlying mechanism needs to be clarified.Methods: Vemurafenib resistant melanoma cells A375/Vem and SK-Mel-28/Vem were established by exposing to a series of concentration of vemurafenib. Cell viability was measured when A375 and SK-Mel-28 cells treated with vemurafenib or combined with sorafenib. Meanwhile the levels of Iron, GSH, MDA and reactive oxygen species (ROS) were detected. Finally we examined that whether sorafenib sensitizes melanoma cells to vemurafenib through ferroptosis.Results: We found that sorafenib sensitized melanoma cells to vemurafenib. Sorafenib treatment did not significantly alter the production of ROS and the content of iron, GSH and MDA in vemurafenib resistant cells, but cotreatment of sorafenib and vemurafenib dramatically upregulated ROS production, MDA and iron, but decreased GSH concentration. Interestingly, sorafenib strongly promoted vemurafenibinduced cell death, which was blocked by lipid peroxidation inhibitors ferrostatin-1 but not ZVAD-FMK or necrosulfonamid.Conclusions: Sorafenib sensitized melanoma cells to vemurafenib by increasing ROS production through ferroptosis. Our study reveals that the combination of sorafenib may provide a novel strategy of vemurafenib resistant melanoma therapy.
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