Polyamine Metabolism as a Metabolic Vulnerability in Prostate Cancer Treated with Supraphysiological Androgens.

Prostate cancer progression is predominantly driven by androgen receptor (AR) signaling, and despite initial benefits of androgen deprivation therapy (ADT), most patients eventually develop lethal castration-resistant disease. Cyclic administration of supraphysiologic androgen (SPA) with ADT paradoxically suppresses tumor growth; however, responses are heterogeneous, and the mechanisms underlying the antitumor effects of SPA remain incompletely understood. In this issue of Cancer Research, Kumar and colleagues demonstrate that SPA induces a distinct metabolic response, characterized by AR-dependent induction of polyamine biosynthesis via ODC1 and AMD1. This metabolic rewiring elevates polyamine synthesis while concurrently depleting the methyl donor S-adenosylmethionine (SAM). Although increased polyamine metabolism by SPA may promote adaptive resistance, genetic or pharmacologic inhibition of ODC1 using difluoromethylornithine (DFMO) enhances SPA-induced growth suppression by disrupting protective polyamine pools and further exacerbating SAM depletion, revealing a metabolic vulnerability in SPA-treated prostate cancer cells. Supporting these findings, a clinical trial combining DFMO with bipolar androgen therapy (BAT) demonstrated reduced circulating polyamines in patients, confirming polyamine pathway suppression in patients with different genomic features. Together, this study uncovers a mechanistic link among androgen signaling, polyamine metabolism, and therapeutic response, providing a rationale for targeting metabolic dependencies to improve SPA efficacy. See related article by Kumar et al., p. 1148.