VDAC1 selective molecules promote patients’-derived cancer organoids death through mitochondrial-dependent metabolic interference

Author:

Conti Nibali Stefano,De Siervi Silvia,Luchinat Enrico,Magrì Andrea,Brocca Lorenza,Mantovani Stefania,Oliviero Barbara,Mondelli Mario U.,De Pinto Vito,Turato Cristian,Arrigoni Cristina,Lolicato Marco

Abstract

AbstractIn the continuous pursuit of advanced cancer therapeutics, our research unveils the potential to selectively target Voltage-Dependent Anion-selective Channel isoform 1 (VDAC1), a pivotal component in cellular metabolism and apoptosis. VDAC1’s role in metabolic rewiring and its subsequent prominence in many cancer types offer a unique intervention point. The incorporation of a systematic,in silicotoin vitromethodology identified novel VA (VDAC-Antagonist) molecules with the capability to selectively bind to VDAC1, displaying a substantial specificity towards cancer cells while sparing healthy ones.This research first led to the revelation of a specialized VDAC1 pocket, which accommodates the binding of these VA molecules, thereby instigating a selective displacement of NADH. The coenzyme is a critical metabolic substrate, and its displacement ensues in notable mitochondrial distress and a reduction in cell proliferation, specifically in cancer cells. Furthermore, meticulous analysis using organoids derived from intrahepatic cholangiocarcinoma patients (iCCA) demonstrated a dose-dependent reduction in cell viability upon treatment with VA molecules, correlating with the findings from commercial cell lines.Interestingly, VA molecules significantly reduced cell viability and demonstrated a lower impact on healthy cells than conventional treatments like gemcitabine. This differential impact is possibly due to the elevated expression of VDAC1 in various cancer cell lines, rendering them more susceptible to metabolic disruptions induced by VA molecules.This endeavor uncovers a multifaceted approach to cancer treatment, involving meticulous targeting of metabolic gatekeepers like VDAC1 using novel entities, thereby paving the way for developing more selective and refined cancer therapeutics. The identified VA molecules, albeit in the nascent stages, represent promising candidates for further optimization and development, potentially revolutionizing treatment modalities in cancer therapy through precise metabolic interventions.

Publisher

Cold Spring Harbor Laboratory

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