Abstract Background: Mutations in DNA Damage Response (DDR) genes, including Ataxia, Telangiectasia, Mutated (ATM), are common in advanced castration-resistant prostate cancers (CRPCs). Poly (ADP-ribose) polymerase (PARP) inhibitors are approved in DDR mutant CRPCs, but demonstrate limited clinical efficacy in CRPCs with ATM mutations. In this project, we sought to specifically define the impact of ATM loss on DDR pathways in CRPC, with the goal of identifying alternate therapeutic vulnerabilities. Methods: ATM-KO CRPC cell lines were generated via CRISPR-Cas9 mediated knockout. ATM loss and abolishment of downstream ATM kinase activity was confirmed via western blot. We performed an unbiased phospho-proteomic evaluation of DDR pathways in parental and ATM-KO cells after ionizing radiation (IR). Clonogenic survival assays were performed with either an ATR inhibitor (VX970), the selective DNA-PKcs inhibitor (M3814), or combination therapy. Kinetics of DDR protein recruitment and resolution were interrogated with immunofluorescence (IF) staining for γH2ax, 53BP1, MDC1, and Rad51 foci. Results: ATM-KO cells were able to effectively repair DNA damage following IR, as measured by recruitment and resolution of γH2ax, 53BP1, MDC1, and Rad51 foci. Phospho-proteomic studies demonstrated that ATM-KO cells maintain canonical DDR pathways through ATR and DNA-PKcs kinase activation. Treatment of ATM-KO cells with either VX-970 or M3814 only incrementally affected DDR in ATM-KO cells compared to parental controls, as evidenced by clonogenic survival assays and maintenance of DDR foci. Importantly, combination treatment with VX-970 and M3814 prevented downstream DDR foci recruitment and radio-sensitized ATM-KO CRPC to a greater extent than parental controls. This suggested that activity of any of the trinity of kinases is sufficient to mediate DDR, and that blockade of both ATR and DNA-PKcs is required to effectively prevent DDR in ATM-KO CRPC. We then leveraged a RUVBL1 ATPase inhibitor Compound B, which significantly attenuates levels of these kinases in lung cancer cells. We confirmed that Compound B treatment attenuated ATR and DNA-PKcs protein expression and kinase activity in ATM-KO CRPC cells, and demonstrated sensitivity of ATM-KO cells to Compound B. Conclusions: Our data demonstrates that dual targeting of ATR and DNA-PKcs is necessary in ATM-KO CRPC, as either kinase is independently capable of mediating DDR following IR. Our initial studies indicate that the RUVBL1 ATPase inhibitor Compound B may effectively block DDR in ATM-mutant CRPC, and could be utilized as a novel therapeutic strategy in this molecular subtype. Citation Format: Mia Hofstad, Lan Yu, Andrea Woods, Zoi Sychev, Collin Gilbreath, Xiaofang Huo, Ralf Kittler, Justin M. Drake, Ganesh V. Raj. Delineating molecular vulnerabilities of ATM mutant prostate cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 2405.