miR424-5p functions as an anti-oncogene in cervical cancer cell growth by targeting KDM5B via the Notch signaling pathway

Aims: Aberrant expression of miRNAs exert the critical roles in carcinogenesis, including cervical cancer. Recent study corroborated the down-regulation of miR424-5p in uterine cervix adenocarcinoma. This research aimed to investigate the function and underlying mechanisms of miR424-5p in cervical cancer cell growth. Main methods: Tissues samples were collected from patients with cervical cancer and healthy control. The expression levels of miR424-5p were determined by qRT-PCR. After transfection with miR424-5p mimics or inhibitor, cervical cancer cell proliferation and apoptosis were evaluated by WST-1 and flow cytometry assay, respectively. The underlying mechanism involved in aforementioned processes was also explored. Key findings: Expression of miR424-5p was notably decreased in cervical cancer tissues and cells. Overexpression of miR424-5p restrained cell proliferation and promoted cell apoptosis, but with little function in miR424-5p inhibitor -treated groups. Furthermore, KDM5B was identified as a direct target of miR424-5p as the evidence that miR-424-5p inhibited KDM5B expression and luciferase activity of KDM5B 3'-UTR. Here, KDM5B elevation majorly reversed miR424-5p-triggered inhibition in cell proliferation and increase in cell apoptosis. Moreover, silencing KDM5B expression also restrained cell growth. Additionally, miR424-5p overexpression inhibited the expression of Notchl and Notch2, which was obviously rescued after KDM5B up-regulation. Simultaneously, blocking KDM5B also attenuated the activation of Notch pathway. Importantly, treatment with Notch agonist Jaggedl antagonized miR424-5p-mediated suppression on cell growth. Significance: This research suggests that miR424-5p may act as a novel anti-oncogene in cervical cancer by blocking cell growth through targeting KDM5B-Notch pathway. Accordingly, our study will support a promising therapeutic strategy against cervical carcinoma. (C) 2017 Elsevier Inc. All rights reserved.