AUP1 transcriptionally activated by KDM5B reprograms lipid metabolism to promote the malignant progression of cervical cancer

Cervical cancer is one of the reproductive malignancies threatening women's lives worldwide. In the present study, it was aimed to explore the role and mechanism of ancient ubiquitous protein 1 (AUP1) in cervical cancer. Through bioinformatics analysis, AUP1 expression in cervical cancer tissues and the correlation between AUP1 and the prognosis of patients were analyzed. AUP1 expression in several cervical cancer cell lines was detected. Following the co-transfection of short hairpin RNA specific to AUP1 with or without lysine demethylase 5B (KDM5B) overexpression plasmids in SiHa cells, the proliferation and apoptosis of SiHa cells were detected. Additionally, wound healing and Transwell assays were used to detect SiHa cell migration and invasion. Cellular lipid droplets level was detected using the Oil red O staining. Meantime, the levels of triglyceride, cholesterol, oxygen consumption rates and expression of lipid metabolism-related proteins were detected to assess the lipid metabolism in SiHa cells. Then, the luciferase reporter assay and ChIP assay were used to verify the binding between KDM5B and AUP1. Finally, the effects of AUP1 and KDM5B on the growth and lipid metabolism in SiHa tumor-bearing mice were measured. AUP1 was significantly upregulated in cervical cancer tissues and cells. AUP1 interference inhibited the malignant biological behaviors and lipid metabolism reprogramming of SiHa cells, which was blocked by KDM5B overexpression. Moreover, KDM5B could transcriptionally activate AUP1 and upregulate AUP1 expression. Furthermore, AUP1 knockdown transcriptionally regulated by KDM5B limited the tumor growth and suppressed the lipid metabolism reprogramming in vivo. Collectively, AUP1 could be transcriptionally activated by KDM5B to reprogram lipid metabolism, thereby promoting the progression of cervical cancer. These findings reveal possible therapeutic strategies in targeting metabolic pathways.