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MicroRNA-30d preserves pancreatic islet β-cell function through negative regulation of the JNK signaling pathway via SOCS3 in mice with streptozotocin-induced diabetes mellitus.

Shan WangXin WenXin-Rui HanYong-Jian WangMin ShenShao-Hua FanJuan ZhuangWei XuZi-Feng ZhangQun ShanMeng-Qiu LiBin HuChun-Hui SunDong-Mei WuJun LuYuan-Lin Zheng
Published in: Journal of cellular physiology (2018)
The loss of pancreatic islet β-cell function represents the classical feature in the pathogenesis of type 2 diabetes mellitus (T2DM). Previous evidence has highlighted the involvement of the activated JNK pathway in relation to islet β-cell apoptosis. Hence, during the present study a streptozotocin-induced DM mice model was established in a bid to ascertain as to whether microRNA-30d (miR-30d) plays a regulatory role in the JNK pathway in relation to islet β-cell dysfunction. The collection and identification of the islet β cells from streptozotocin-induced mice was performed. Islet β cells with elevated or suppressed levels of miR-30 as well as knocked down SOCS3 were established in order to verify the regulatory mechanisms by which miR-30d governs SOCS3 in vitro. We found miR-30d was overexpressed among tissue samples obtained form streptozotocin-induced mice and their islet β cells, as well as increasing miR-30d expression when the JNK pathway was activated were found to promote islet β cell growth and cell cycle entry, and inhibit apoptosis. SOCS3, confirmed to be a miR-30d target, was decreased in the islet β cells following the promotion of miR-30d, while the JNK pathway was inhibited following SOCS3 knocdown. Furthermore, the effect of miR-30d inhibition was lost in islet β cells when SOCS3 was knocked down. The data of the present study support the notion that miR-30d-mediated direct suppression of SOCS3 acts to protect pancreatic β-cell functions through the JNK signaling pathway, emphasizing the potential of miR-30d as a novel pharmacological target for treatment and intervention of DM.
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