Abstract

Abstract Background: The phase 2 TRITON2 (NCT02952534) study is evaluating the poly(ADP-ribose) polymerase inhibitor rucaparib in mCRPC patients with a deleterious germline or somatic mutation in BRCA1, BRCA2, ATM, or 1 of 12 other DNA damage repair (DDR) genes who have progressed on prior androgen receptor-directed therapy and 1 taxane-based therapy. Here we present results from central genomic screening of plasma and tissue samples for TRITON2. Methods: Plasma samples were profiled for genomic alterations (GAs) in 70 genes and tumor tissue FFPE samples for GAs in 395 genes by Foundation Medicine, Inc., using next-generation sequencing (NGS) assays. Deleterious alterations included frameshift, nonsense, and deleterious missense mutations, protein-truncating rearrangements, and (for tissue samples) homozygous loss. Tissue samples included both archival and more recent specimens, whereas plasma samples were collected at the time of disease progression on prior therapy. Results: As of July 2, 2018, 359 plasma samples from patients with mCRPC were screened for deleterious GAs in a DDR gene. Of the plasma samples, 96% (343/359) were successfully sequenced for a comprehensive genomic profile. The most commonly altered genes were AR (49%) and TP53 (48%). Deleterious GAs were detected in BRCA1 (2%), BRCA2 (10%), ATM (15%), CDK12 (6%), or other DDR genes (6%). GAs in the MAPK pathway were observed in 5% of plasma samples. Additionally, 738 tissue samples from primary prostate cancer tumors (78%) or metastases (22%) were profiled. Only 66% of tissue samples (487/738) were sequenced successfully, highlighting the challenges associated with NGS of predominantly archival prostate tissues (median sample age, 2.5 years [range, 4 days to 21 years]). The most commonly altered genes were TP53 (38%), PTEN (33%), ERG-TEMPRSS2 fusions (28%), AR (15%), and MYC (9%). Deleterious GAs were observed in BRCA1(2%), BRCA2 (9%), ATM (7%), CDK12 (7%), or other DDR genes (5%), as well as in the PI3K/AKT (41%), Wnt (11%), MAPK (5%), and mismatch repair (3%) pathways. Further, GAs in the DDR, PI3K/AKT, and Wnt pathways were observed at a higher rate in metastatic (42%, 40%, and 15%, respectively) than in primary prostate tissues (32%, 34%, and 12%, respectively). Updated and expanded genomic analyses and plasma-tissue concordance analyses will be presented. Conclusions: Genomic NGS profiling of plasma and FFPE tumor tissue samples successfully identified patients with GAs in a DDR gene for the evaluation of rucaparib in mCRPC. The plasma assay is convenient for patients and has a low NGS failure rate, whereas the tumor tissue assay has a higher failure rate but can detect more alteration types. Taken together, these data highlight the strengths and limitations of tissue and plasma testing to identify GAs for targeted therapies in mCRPC. Citation Format: Foad Green, Jeremy D. Shapiro, Ray McDermott, Josep Maria Piulats, Alison Reid, Peter Ostler, Jingsong Zhang, David Campbell, Dominique Spaeth, Ivor Percent, Arif Hussain, Andrew D. Simmons, Tony Golsorkhi, Simon P. Watkins, Andrea Loehr, Simon Chowdhury, Wassim Abida. Comprehensive genomic profiling of >1000 plasma and tumor tissue samples from metastatic castration-resistant prostate cancer (mCRPC) patients gives insight into targeted treatment strategies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 727.

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