Genomic attributes of homology-directed DNA repair deficiency in metastatic prostate cancer
Navonil De Sarkar, … , Robert B. Montgomery, Peter S. Nelson
Navonil De Sarkar, … , Robert B. Montgomery, Peter S. Nelson
Published December 8, 2021
Citation Information: JCI Insight. 2021;6(23):e152789. https://doi.org/10.1172/jci.insight.152789.
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Research Article Oncology

Genomic attributes of homology-directed DNA repair deficiency in metastatic prostate cancer

Abstract

Cancers with homology-directed DNA repair (HRR) deficiency exhibit high response rates to poly(ADP-ribose) polymerase inhibitors (PARPi) and platinum chemotherapy. Though mutations disrupting BRCA1 and BRCA2 associate with HRR deficiency (HRRd), patterns of genomic aberrations and mutation signatures may be more sensitive and specific indicators of compromised repair. Here, we evaluated whole-exome sequences from 418 metastatic prostate cancers (mPCs) and determined that one-fifth exhibited genomic characteristics of HRRd that included Catalogue Of Somatic Mutations In Cancer mutation signature 3. Notably, a substantial fraction of tumors with genomic features of HRRd lacked biallelic loss of a core HRR-associated gene, such as BRCA2. In this subset, HRRd associated with loss of chromodomain helicase DNA binding protein 1 but not with mutations in serine-protein kinase ATM, cyclin dependent kinase 12, or checkpoint kinase 2. HRRd genomic status was strongly correlated with responses to PARPi and platinum chemotherapy, a finding that supports evaluating biomarkers reflecting functional HRRd for treatment allocation.

Authors

Navonil De Sarkar, Sayan Dasgupta, Payel Chatterjee, Ilsa Coleman, Gavin Ha, Lisa S. Ang, Emily A. Kohlbrenner, Sander B. Frank, Talina A. Nunez, Stephen J. Salipante, Eva Corey, Colm Morrissey, Eliezer Van Allen, Michael T. Schweizer, Michael C. Haffner, Radhika Patel, Brian Hanratty, Jared M. Lucas, Ruth F. Dumpit, Colin C. Pritchard, Robert B. Montgomery, Peter S. Nelson

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Figure 3

Genomic alterations and gene expression associate with HRR deficiency mutational signatures.

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Genomic alterations and gene expression associate with HRR deficiency mu...
(A) Assessment of co-occurrence of monoallelic aberrations in HRGs and tumors classified as CSig3(+). Fisher’s exact tests of MML co-occurrence (or BAL for same gene pairs on the diagonal) versus CSig3 status for 418 tumors. Odds ratios were positive for all significant associations; Benjamini-Hochberg–corrected P value significance level color-coded as red (P < 0.01), pink (P < 0.05), or white (P > 0.05). Gray boxes indicate gene pairs with no co-occurrence of MML or no BAL for same gene pairs. (B and C) Association of genomic loss of (B) BRCA2 or (C) CHD1 with CSig3 status. Comparison of heterozygous (+/–) or homozygous (–/–) loss to WT (+/+) by Fisher’s exact test in 418 tumors with Benjamini-Hochberg multiple-testing correction shown on plot (FDR * ≤ 0.05; ** < 0.01; *** < 0.001; **** < 0.0001). (D and E) CSig3 score is elevated in tumors with low transcript levels of specific genes involved in HRR. CSig3 frequencies of samples with gene expression less than 2-fold below median to the HRG-Intact group in 379 tumors by 1-sided Wilcoxon rank test with Benjamini-Hochberg multiple-testing correction shown on plot (FDR * ≤ 0.05; ** < 0.01; *** < 0.001; **** < 0.0001; NS > 0.05). (FK) Association between genomic status of BRCA2, PALB2, RAD51B, and RAD51C and transcript expression levels. Comparison of heterozygous (+/–) or homozygous (–/–) loss to WT (+/+) in 259 tumors by Wilcoxon rank test with Benjamini-Hochberg multiple-testing correction shown on plot (FDR * ≤ 0.05; ** < 0.01; *** < 0.001; **** < 0.0001). FPKM, fragments per kilobase million.