PIN1 isomerase promotes the initiation and progression of bladder cancer through SREBP2-mediated cholesterol biosynthesis pathway

Bladder cancer, one of the most diagnosed cancers worldwide, is associated with high morbidity, mortality, and a poor prognosis. The PIN1 phospho-dependent prolyl isomerase is frequently overexpressed in many human cancer types and affects tumor initiation and progression through disrupting the balance of oncoprotein and tumor suppressor protein signaling. However, the functional pSer/Thr.Pro protein substrates of PIN1 and its effects on downstream signaling in bladder carcinogenesis remain largely unknown. Phenotypically, we discovered that ablation of Pin1 in human/mouse bladder cancer cells and organoids formed from mouse primary urothelial cells resulted in decreased cell proliferation, stemness maintenance, cell invasion, migration, urothelium clearance capacity, and reduced free/total cholesterol levels in vitro. Re-expressing Pin1 in Pin1 knockout cells reversed the defects caused by lack of Pin1. Moreover, in vivo subcutaneous xenograft and allograft transplantation mouse models combined with an orthotopic implantation model were utilized to confirm a positive role for Pin1 in controlling tumor growth and potential metastasis. Therapeutically, a combination of the sulfopin PIN1 inhibitor and the simvastatin HMGCR inhibitor was shown to suppress cell proliferation in vitro and tumor growth in vivo synergistically. Mechanistically, we observed a negative enrichment of SREBP2-driven cholesterol metabolism pathways in PIN1 knockout cells via RNA-sequencing and used a suite of diverse molecular and biochemical approaches to show that PIN1 interacts with JNK-dependent phosphorylated SREBP2 (Ser455) and vice versa. These results indicate that active cholesterol biosynthesis pathway in bladder cancer cells is regulated by PIN1-mediated isomerization and JNK-mediated phosphorylation of its key transcriptional factor SREBP2. These findings emphasize that PIN1 can act as a regulator and potential therapeutic target in bladder cancer. To elucidate the underlying molecular mechanisms by which PIN1 mediated cis-trans isomerization of phosphosites in target proteins induces functional alterations in downstream signaling We performed bulk RNA-sequencing using T24 and 5637 cells with different PIN1 expression levels. Comparative gene expression profiling analyses of RNA-seq data for T24 and 5637 cells with different PIN1 expression levels, control, PIN1 knockout and PIN1 re-expression