Development of molecular signature and CMap analysis. A, A molecular signature was established through the integration of significant changes between MIBC and NMIBC derived from multiomics data (proteomics and transcriptomics), further enriched with literature-mined data. B, The signature was randomly divided into 10 sets of molecular features and used to query the CMap to predict drugs/compounds affecting the disease’s molecular signature. C, The significant negative enrichment scores for the drugs selected for subsequent in vitro investigations are depicted. GEO, Gene Expression Omnibus; MIBC, muscle-invasive bladder cancer; NMIBC, non muscle-invasive bladder cancer.
ARTICLE ABSTRACT
Cisplatin-based neoadjuvant chemotherapy followed by radical cystectomy is the main treatment for muscle-invasive bladder cancer (MIBC). However, low survival rates highlight the necessity for new therapeutic strategies. Drug repurposing has emerged as a promising approach in cancer treatment, with various studies proposing the use of existing drugs for the treatment of bladder cancer. In this context, we previously established an in silico repurposing strategy using patient omics signatures, identifying drugs and compounds with the potential to reverse nonmuscle-invasive bladder cancer (NMIBC) to less aggressive subtypes. In the present study, we expanded our in silico approach to verify a list of compounds with potential antitumor activity against MIBC. We investigated the efficacy of the predicted candidates in a group of different bladder cancer cell lines, including NMIBC and MIBC. The most potent compound for decreasing cell viability was amiodarone, an antiarrhythmic drug widely used in the field of cardiology. Amiodarone reduced cell proliferation and colony formation capacity, with a stronger effect on the most aggressive invasive models, validating our repurposing pipeline. The drug additionally induced cell death and inhibited the activity of mTOR and its target protein S6, suggesting that the anticancer effect of the drug is, in part, mediated by inhibition of the mTOR signaling pathway. Furthermore, the administration of amiodarone in a xenograft MIBC mouse model reduced tumor growth without inducing toxicity. Altogether, we demonstrated that amiodarone is a potential repurposed drug for bladder cancer, which might be especially effective in MIBC.
Treatment of advanced bladder cancer remains a therapeutic challenge in urological oncology. In order to make more drugs available to patients in the future, we identified amiodarone, a repurposed drug used in cardiology as a compound that inhibits bladder cancer in vitro and in vivo.
