Abstract A078: Identifying and targeting the genetic determinants of immune suppression and immunotherapy failure in prostate cancer

Abstract The advent of immunotherapies such as immune checkpoint blockade (ICB) has greatly expanded the therapeutic options available to patients with treatment-refractory solid tumors. However, patients with castration-resistant prostate cancer (CRPC) generally remain unresponsive to ICB therapy d...

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Published inCancer research (Chicago, Ill.) Vol. 83; no. 11_Supplement; p. A078
Main Authors Murphy, Katherine C., DeMarco, Kelly, Lopez-Diaz, Yvette, Zhou, Lin, Ruscetti, Marcus
Format Journal Article
LanguageEnglish
Published 02.06.2023
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Summary:Abstract The advent of immunotherapies such as immune checkpoint blockade (ICB) has greatly expanded the therapeutic options available to patients with treatment-refractory solid tumors. However, patients with castration-resistant prostate cancer (CRPC) generally remain unresponsive to ICB therapy due to an immunologically “cold” prostate tumor microenvironment (TME) with limited accessibility to cytotoxic lymphocytes such as Natural Killer (NK) and T cells that can mediate potent anti-tumor immunity. During the course of tumor evolution, CRPCs acquire many genomic alterations and copy number changes that can influence therapy outcomes. Yet the impact of such genetic alterations on the immune TME and response to ICB remains largely unknown, in part due to the lack of models to functionally study them in an immune competent setting. To this end, we previously developed a novel electroporation-based genetically engineered mouse model (EPO-GEMM) to rapidly generate genetically defined prostate tumors de novo within an intact prostate TME (Leibold*, Ruscetti* et al., Cancer Discovery 2020). Here, we applied the EPO-GEMM approach to characterize the immune landscapes of distinct genetic subtypes of CRPC and subsequently identify and target tumor intrinsic mediators of immune suppression for prostate cancer immunotherapy. Using transposon systems to overexpress the MYC oncogene and CRISPR/Cas9 vectors to inactivate tumor suppressor genes (TSGs) commonly altered in CRPC (Pten, P53, Rb1, Apc), we generated a suite of genetically distinct prostate cancer-bearing EPO-GEMMs. Histological analysis revealed genotype-specific immune infiltrates, with MYC-driven tumors generally lacking cytotoxic CD8+ T cells and harboring increased numbers of regulatory T cells (Tregs). A similar correlation was also observed between MYC levels and cytotoxic lymphocyte suppression in CRPC patient samples. In particular, tumors with compound MYC overexpression and p53 loss (MP) displayed drastic NK cell suppression. Cytokine and RNA-seq profiling of primary EPO-GEMM CRPCs, tumor-derived cell lines, and isogenic Myc-CaP cells engineered with TSG losses revealed that MP alterations led to not only inhibition of inflammatory cytokine and interferon signaling and antigen presentation/processing gene expression, but also induction of VEGF signaling and increased angiogenesis in the prostate TME. Treatment of MP tumors with a VEGFR2 antibody to block VEGF signaling significantly reduced tumor growth and increased NK and CD8+T cell infiltration and activation, indicating a phenotypic switch from a traditionally “cold” TME. Our results demonstrate that the genetic configuration of prostate cancer shapes its surrounding TME. Additionally, targeting VEGF signaling may be a mechanism to overcome ICB resistance in prostate cancer. More broadly, we believe that by understanding the tumor intrinsic mechanisms driving immune suppression, we can identify rational immunotherapy combinations for CRPC based on the genetic fingerprint of a patient’s tumor for precision medicine. Citation Format: Katherine C. Murphy, Kelly DeMarco, Yvette Lopez-Diaz, Lin Zhou, Marcus Ruscetti. Identifying and targeting the genetic determinants of immune suppression and immunotherapy failure in prostate cancer [abstract]. In: Proceedings of the AACR Special Conference: Advances in Prostate Cancer Research; 2023 Mar 15-18; Denver, Colorado. Philadelphia (PA): AACR; Cancer Res 2023;83(11 Suppl):Abstract nr A078.
ISSN:1538-7445
1538-7445
DOI:10.1158/1538-7445.PRCA2023-A078