Abstract 1403: Modeling of Abi1 loss using spheroid cultures to investigate mechanisms of prostate tumorigenesis

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Abstract American Cancer Society predicts over 160,000 new prostate cancer cases in 2017, which amounts to about 20 percent of all cancer diagnoses in men. Despite several treatment options being available, poor prognosis of high-risk and metastasis remains a major concern for prostate cancer (PCa) patients. Therefore, it is important to understand molecular mechanisms of PCa progression to aggressive disease. Our previous research identified Abelson interactor 1 (Abi1), a member of WAVE complex, as a tumor suppressor in human prostate. Not only did we find mutations and deletions in the gene in prostate tumor patient samples, but WAVE complex levels were also found to be inversely correlated to disease recurrence and castration resistance. Moreover, Abi1 is downregulated in majority of prostate cancer cell lines, and patient organoid cultures derived from metastatic bone and lymph node biopsies. These data point to the clinical significance of defining Abi1-dependent tumor suppression mechanisms. To understand these mechanisms we generated CRISPR-mediated Abi1 KO in the RWPE-1 non-tumor human prostate cell line. When plated in 3D cultures in matrigel, we observed striking phenotypic differences in the appearance and behavior of the Abi1 KO spheroids compared to the parental cells. While the parental RWPE-1 grew into spherical organoids with tight cell-cell boundaries, the Abi1 KO cells grew as loose irregular-shaped spheres, with many cells migrating out of the organoids. Hence, the loss of Abi1 in these non-tumor cells lead to gain of an invasive phenotype. Western Blots of Abi1-KO cells demonstrated concurrent disruption of WAVE complex and deregulation of WAVE complex protein levels. Moreover, cell-cell adhesion proteins such as E-cadherin and β-catenin showed modest decrease and/or a substantial loss of membrane localization. Rescue experiments of Abi1 re-expression in the KO cells reversed the phenotype indicating that the observed phenotype is Abi1-dependent. Analyses of RNA sequencing of cells obtained from 3D cultures demonstrated differences in expression signatures characteristic of altered cell-cell and cell-matrix adhesion pathways and indicated upregulation of pathways associated with the invasive phenotype of cancer cells. We propose that Abi1 loss and WAVE complex deregulation represents key mediators of invasive phenotype in PCa. [Supported by NCI R01 CA161018 and NYS Department of Health Prostate Cancer Hypothesis Development RFA #1410200115] Citation Format: Disharee Das, Ming Chen, Claudia Mondragon, Dawn Post, Alexander Nappi, Heidi Hehnly, Anita Hryniewicz-Jankowska, Pier Paolo Pandolfi, Gennady Bratslavsky, Leszek Kotula. Modeling of Abi1 loss using spheroid cultures to investigate mechanisms of prostate tumorigenesis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1403.