Homologous Recombination Genes Research Articles

Abstract B147: The relationship between germline variants and clinicopathological characteristics in triple negative breast cancer patients from Colombia

Abstract Introduction: Triple-negative breast cancer (TNBC) is the molecular subtype with the worst prognosis among breast tumors. It has been shown that the presence of germline variants can influence disease onset, progression, tumor biology, and other outcomes, however, to this date, the differences in clinical-pathological features according to germline variants in an admixed population like Colombian women, have not been yet explored. Therefore, the aim of this study was to explore the relationship between clinical-pathological characteristics and germline mutations in TNBC patients from Colombia. Methodology: This is a descriptive analysis that included 47 Colombian women with confirmed diagnosis of hereditary TNBC treated at the National Cancer Institute of Colombia, from 2008 to 2022. Germline mutations in 105 genes were assessed using the TruSigth multi-gene panel, and patients were divided according to the identified mutation into the following groups: BRCA1 carriers (n=18), BRCA2 carriers (n=13), homologous recombination (HR) gene carriers (n=13), and carriers of mutations in other genes (n=3). Fisher’s and Pearson’s chi-squared tests were used for categorical variables, and differences were considered statistically significant if p<0.05. Results: Among our cohort, the identified mutation with the highest prevalence was the c.5123C>A p. (Ala1708Glu) in the BRCA1 gene (36,9%). Regarding clinical-pathological features, we observed statistically significant differences in the distribution of germline mutations by age at diagnosis (p=0.042), body mass index (BMI) (p=0.04), and tumor differentiation (p=0.01). Women younger than 50 years at diagnosis had the highest frequency of BRCA1 (23,9%) mutations. Overweight (BMI: 25-30) and obese (BMI>30) patients presented a higher proportion of mutations in the BRCA1 (15,2%) and BRCA2 (13,0%) genes, compared to patients with mutations in HR repair pathways (8,6%) and mutations in other genes (2,2%). This is interesting as previous reports have shown an association between BRCA1/2 mutations with BMI and chronic inflammation, which could influence the development and progression of breast cancer. Poorly differentiated tumors (Bloom-Richardson: III) were more frequently observed in patients with BRCA1 mutations (32,6%), followed by patients with mutations in the HR genes (17,4%). It is possible that this is related to the genetic changes that germline mutations induce within the tumor, which ultimately lead to a less differentiated disease. Conclusion: Our study confirms the greater proportion of mutations in BRCA1/2 genes in TNBCs among the Colombian population. The characterization of clinical-pathological characteristics of germline mutation-related tumors may help improve diagnosis, prognosis assessment, and targeted therapeutic approaches. Further studies with larger patient cohorts are needed to confirm our findings. Additionally, large-scale studies are also warranted to elucidate the landscape of germline mutations relevant to the Colombian population, along with its clinical implications. Citation Format: Yina Tatiana Zambrano Ordonez, Laura Rey Vargas, Paula Daniela Morales, Silvia Juliana Serrano. The relationship between germline variants and clinicopathological characteristics in triple negative breast cancer patients from Colombia [abstract]. In: Proceedings of the 16th AACR Conference on the Science of Cancer Health Disparities in Racial/Ethnic Minorities and the Medically Underserved; 2023 Sep 29-Oct 2;Orlando, FL. Philadelphia (PA): AACR; Cancer Epidemiol Biomarkers Prev 2023;32(12 Suppl):Abstract nr B147.

Genomic Stability, DNA Repair and the SKP1-CUL1-F-Box Complex in HIV Associated Diffuse Large B-Cell Lymphoma

Introduction: Previously we demonstrated that HIV associated diffuse large B-cell lymphomas (DLBCL) of Germinal Center B-cell subtype (GCB) are more proliferative, with enhanced genomic stability and increased expression of DNA repair genes, particularly Fanconi anemia (FA) and homologous recombination (HR) genes compared to their HIV negative counterparts (Maguire et al, 2019). It is unknown if this signature is unique to the GCB subtype or if it is also observed in Activated B-cell (ABC) and Unclassified (UNC) DLBCL. Herein we validate our HIV associated GCB DLBCL findings in a larger independent cohort and report for the first time the aberrational profile of molecularly profiled HIV associated ABC DLBCL compared to their HIV negative counterparts respectively. Methods: An independent cohort of 353 DLBCL FFPE cases was assembled, including 125 HIV-DLBCL samples. All samples underwent hematopathological review to confirm diagnosis and determine tumor content. Samples with <60% tumor content were macro-dissected before they were RNA/DNA extracted. Cell of origin (COO) profiles were assessed using the Lymph3Cx molecular assay which can distinguish primary mediastinal B-cell lymphoma (PMBL) like from GCB, ABC and UNC DLBCL (Mottok et al 2018). Copy number (CN) analyses were performed on samples with sufficient DNA (41 HIV neg, 32 HIV pos) using the OncoScan FFPE assay kit and the resulting data analyzed using Chromosome Analysis Suite (ChAS) v4.1 and the multisample viewer module of Reproductive Health Research Analysis Software (RHAS) v1.1. Additional digital gene expression profiling was performed using the Pan-Cancer panel (NanoString, Seattle, WA) customized to include 9 BCL2 family genes for a total of 739 genes and analyzed using the NanoString nSolver Advanced Analysis module. Results: GCB, ABC, UNC and PMBL-like proportions were 50%, 30%, 14% and 6% in HIV unassociated (HIV neg) and 50%, 23%, 25% and 2% in HIV pos tumors respectively, confirming both cohorts were GCB-enriched by molecular profiling. PMBL-like cases were excluded from further analyses. OncoScan CN analyses showed that HIV pos DLBCL were significantly less aberrant than HIV neg DLBCL (median CN per sample 0.56 vs 1.01, p<0.001). HIV pos GCB tumors were significantly less aberrant than both HIV neg GCB tumors (median CN per sample 0.50 vs 1.11, p<0.001), and HIV pos ABC tumors (median CN per sample 0.50 vs 0.81, p=0.009). HIV pos ABC tumors were also less aberrant than HIV neg ABC tumors, however, the difference was not significant overall (median CN per sample 0.81 vs 1.03, p=0.162) or for gain/amplifications (median CN per sample 0.38 vs 0.42, p=0.814), but was borderline significant for loss/deletions (median CN per sample 0.31 vs 0.47, p=0.06). GEP analyses identified Cell Cycle and DNA repair as the top two upregulated pathways in HIV pos GCB tumors compared to HIV neg GCB tumors. In contrast, Cell Cycle and DNA repair were downregulated in HIV pos ABC tumors compared to HIV neg ABC tumors. However, one gene ( RBX1) was identified as significantly upregulated in both pathways in HIV pos GCB (adjusted p-value 0.0215) and HIV pos ABC (adjusted p-value 0.0046) tumors compared to their HIV neg counterparts. A second gene ( SKP1) was also significantly upregulated in HIV pos GCB (adjusted p-value 3.94E-5) and HIV pos ABC (adjusted p-value 0.0031) tumors. Together RBX1 and SKP1 encode the two principal functional subunits of the SKP1, CUL1, F-box protein (SCF) complex which is part of the ubiquitin proteasome system (UPS) and has been reported as essential for maintaining genome and chromosome stability (Thompson et al 2021). Conclusions: These results demonstrate that HIV pos DLBCL tumors are less aberrant than their HIV neg counterparts irrespective of COO subtype. However, the degree of genomic stability differs by COO, with HIV pos GCB tumors being more genomically stable than HIV pos ABC tumors. Although both have enhanced expression of UPS related SCF genes ( RBX1, SKP1), only HIV pos GCB tumors have enhanced expression of key DNA repair genes as well including Fanconi Anemia ( BRCA2/FANCD1, FANCL) and mismatch repair ( MSH2, MSH6) genes (adjusted p-values of ≤ 0.0263). Given the reported role of SCF in genomic stability maintenance, the HIV pos COO CN differences could be due to the contributions of both DNA repair and SCF mechanisms in HIV pos GCB and mainly SCF mechanisms in HIV pos ABC tumors.

Enhanced Genomic Stability in Monomorphic Post-Transplant Lymphoproliferative Disorders Is Driven By Distinct Mechanisms Stratified By EBV Status

Introduction: We previously showed that HIV associated EBV negative (-) diffuse large B-cell lymphomas (DLBCL) of germinal center origins (GCB) have enhanced genomic stability and increased expression of DNA repair genes compared to their HIV negative counterparts (Maguire et al 2019). Given that immune deficiency can be induced virally or therapeutically, including the administration of immunosuppressive drugs post solid organ or hematopoietic stem cell transplant, we questioned whether these observations are specific to HIV or if they represent a more global immune impaired signature. Here we assessed the genomic stability of monomorphic DLBCL post-transplant lymphoproliferative disorders (PTLD) and the potential role of DNA repair. Methods: A total of 49 monomorphic DLBCL PTLDs (26 EBV(-), 23 EBV positive (+)) and 170 immune competent (IC) DLBCL (EBV status unknown) were studied. All were pathologically reviewed and samples with <60% tumor content were macro-dissected before RNA/DNA extraction. Cell of origin (COO) profiles were assessed using the DLBCL90 molecular assay which can distinguish primary mediastinal B-cell lymphoma (PMBL) from GCB, Activated B-cell (ABC) and unclassified (UNC) DLBCL (Ennishi et al 2019). NanoString gene expression profiling (GEP) was performed using the PanCancer Pathways panel and analyzed using NanoString nSolver Advanced Analysis. Copy number (CN) analysis was performed on a subset of samples (45 PTLD, 41 DLBCL) using the OncoScan CN assay and analyzed using Chromosome Analysis Suite (ChAS) v4.1. All p-values listed were Benjamini-Hochberg adjusted and Mann-Whitney tested for the GEP and CN data respectively. Results: In contrast to IC-DLBCL which are GCB enriched (50%), COO profiling revealed PTLD to be ABC enriched (43%). CN analyses revealed that the median CN/sample for PTLD (0.57, p<0.001), EBV(+)PTLD (0.25, p<0.001) and EBV(-)PTLD (0.80, p = 0.050) tumors were significantly less aberrant than IC-DLBCL (1.01). The data also showed that EBV(+)PTLD are less aberrant than EBV(-)PTLD tumors (0.25 vs 0.80, p<0.001). GEP pathway analysis identified DNA repair as downregulated in PTLD and EBV(+)PTLD but upregulated in EBV(-)PTLD compared IC-DLBCL. Nine DNA repair genes ( RAD51, CCNA2a, CHEK1b, POLR2Da, PCNAa, WHSC1a, GTF2H3a, ATM c, EP300 c) were differentially expressed (DE) in EBV(-)PTLD compared to IC-DLBCL (7 increased, 2 decreased, p ≤ 0.0425): where the most overexpressed gene RAD51, a critical mediator of Homologous Recombination (HR) and the Fanconi Anemia (FA) DNA repair pathways, was not DE in PTLD or EBV(+)PTLD compared to IC-DLBCL. Five a genes were increased in PTLD (p ≤ 0.0204) but not EBV(+)PTLD, 1 b was decreased in EBV(+)PTLD (p = 0.01) but not PTLD and 2 c were reduced in PTLD regardless of EBV status compared to IC-DLBCL (p ≤ 0.0024). Twenty-8 genes were DE in EBV(+)PTLD compared to IC-DLBCL. Of these, 23 were downregulated (p ≤ 0.0418) and included HR, FA and mismatch repair genes ( CHEK1, CHEK2, BRAC1/FANCS, FANCA, FANCB, FANCE, MSH2, MSH6). All but 2/23 were similarly expressed in PTLD compared to IC-DLBCL of which 11 were significant (p ≤ 0.0356). The five upregulated genes ( ZBTB32, DDB2, NBN, POLB, RBX1, p ≤ 0.0092) were also upregulated in PTLD (p ≤ 0.0042) but not EBV(-)PTLD compared to IC-DLBCL. Two additional genes ( SKP1, FBXW7) were also identified as increased in EBV(+)PTLD and PTLD (p ≤ 0.0204) compared to IC-DLBCL. In contrast, SKP1 was increased (p = 2.7E-4) and FBXW7 was decreased (p = 0.3610) in EBV(-)PTLD compared to IC-DLBCL. Together the protein products of RBX1, SKP1 and FBXW7 comprise the functional cores of a complete UPS complex, the SCF FBXW7 E3 ubiquitin ligase which have been reported to regulate the DNA damage response and promote genomic stability. Conclusions: Like HIV associated DLBCL, these results show that PTLD is more genomically stable than IC-DLBCL, and that genomic stability is further enhanced in EBV(+)PTLD which have increased expression of UPS related genes. In contrast, EBV(-)PTLD have increased expression of DNA damage repair genes, including RAD51. In summary, monomorphic DLBCL PTLD tumors have enhanced genomic stability that appears to be mediated by two distinct mechanisms stratified by EBV status. Further work is required to assess if this stratification of mechanisms is unique to PTLD or reflects a more global immune impaired EBV related signature.

Genetic separation of Brca1 functions reveal mutation-dependent Polθ vulnerabilities

Homologous recombination (HR)-deficiency induces a dependency on DNA polymerase theta (Polθ/Polq)-mediated end joining, and Polθ inhibitors (Polθi) are in development for cancer therapy. BRCA1 and BRCA2 deficient cells are thought to be synthetic lethal with Polθ, but whether distinct HR gene mutations give rise to equivalent Polθ-dependence, and the events that drive lethality, are unclear. In this study, we utilized mouse models with separate Brca1 functional defects to mechanistically define Brca1-Polθ synthetic lethality. Surprisingly, homozygous Brca1 mutant, Polq−/− cells were viable, but grew slowly and had chromosomal instability. Brca1 mutant cells proficient in DNA end resection were significantly more dependent on Polθ for viability; here, treatment with Polθi elevated RPA foci, which persisted through mitosis. In an isogenic system, BRCA1 null cells were defective, but PALB2 and BRCA2 mutant cells exhibited active resection, and consequently stronger sensitivity to Polθi. Thus, DNA end resection is a critical determinant of Polθi sensitivity in HR-deficient cells, and should be considered when selecting patients for clinical studies.

Obtaining or Generating Gene Mutations in Mice.

The starting point in a mutational analysis of gene function is obtaining or producing a mutant. Here different methods of obtaining mouse mutants are discussed, including screening for spontaneous mutants, screening for mutants following chemical or X-ray mutagenesis, and producing mutations through targeted manipulation of the genome. Manipulation of the genome can be random, as in different types of insertional mutagenesis. Alternatively, targeted manipulation such as gene targeting using homologous recombination in embryonic stem (ES) cells or gene editing by CRISPR-Cas can be used to produce custom mutations in a specific gene. The basic methods are outlined, and the advantages and disadvantages of homologous recombination and CRISPR-Cas gene editing are discussed. Resources for obtaining mutations that already exist are provided. If, for your planned study, no suitable mutations are available, there is advice about what you should know about your gene of interest before embarking on a gene targeting experiment.

Embryonic Stem Cell Gene Targeting and Chimera Production in Mice.

Producing a custom gene mutation in embryonic stem (ES) cells, whether through homologous recombination or CRISPR-Cas gene editing, is the first step along the way to getting the mutation into live mice. However, there are a number of additional steps along the way, each presenting technical challenges. Here, we provide a guide for troubleshooting when the results are not as expected and to distinguish technical problems from possible biological effects of the mutation. From the isolation of clonal lines of targeted ES cells through the production of ES cell chimeras with the targeted ES cell clone, we discuss common technical problems and their most likely causes and solutions. We also provide guidance for situations where the mutation has a phenotype in the form of a dominant effect on ES cells or in chimeras.

ASSESSMENT OF THE PROGNOSTIC POTENTIAL OF EXPRESSION AND ABERRATIONS IN THE NUMBER OF DNA COPIES OF THE HOMOLOGICAL RECOMBINATION SYSTEM GENES IN PATIENTS WITH NON-SMALL CELL LUNG CANCER

Numerous studies have shown that the presence of homologous recombination deficiency (HRD) in breast tumors may be a good marker of the effectiveness of chemotherapy with DNA-damaging agents such as platinum-based and anthracycline-containing medication regimens. However, the formation of HRD due to disruptions in the BRCA1/2 genes is typical not only for breast cancer and ovarian cancer, but also for other cancer localizations, in particular for non-small cell lung cancer (NSCLC). Since the use of platinum-based drugs in patients with NSCLC is a standard treatment protocol, studying the expression profile of homologous recombination genes and the presence of chromosomal aberrations therein will allow us to fully study HRD in these patients and identify new prognostic markers.

Efficacy of olaparib in advanced cancers with germline or somatic mutations in BRCA1, BRCA2, CHEK2 and ATM, a Belgian Precision tumor-agnostic phase II study

The Belgian Precision initiative aims to maximize the implementation of tumor-agnostic next-generation sequencing in patients with advanced cancer and enhance access to molecularly guided treatment options. Academic tumor-agnostic basket phase II studies are part of this initiative. The current investigator-driven trial aimed to investigate the efficacy of olaparib in advanced cancers with a (likely) pathogenic mutation (germline or somatic) in a gene that plays a role in homologous recombination (HR). This open-label, multi-cohort, phase II study examines the efficacy of olaparib in patients with an HR gene mutation in their tumor and disease progression on standard of care. Patients with a somatic or germline mutation in the same gene define a cohort. For each cohort, a Simon minimax two-stage design was used. If a response was observed in the first 13 patients, 14 additional patients were included. Here, we report the results on four completed cohorts: patients with a BRCA1, BRCA2, CHEK2 or ATM mutation. The overall objective response rate across different tumor types was 11% in the BRCA1-mutated (n= 27) and 21% in the BRCA2-mutated (n= 27) cohorts. Partial responses were seen in pancreatic cancer, gallbladder cancer, endocrine carcinoma of the pancreas and parathyroid cancer. One patient with a BRCA2 germline-mutated colon cancer has an ongoing complete response with 19+ months on treatment. Median progression-free survival in responding patients was 14+ months (5-34+ months). The clinical benefit rate was 63% in the BRCA1-mutated and 46% in the BRCA2-mutated cohorts. No clinical activity was observed in the ATM (n= 13) and CHEK2 (n= 14) cohorts. Olaparib showed efficacy in different cancer types harboring somatic or germline mutations in the BRCA1/2 genes but not in ATM and CHEK2. Patients with any cancer type harboring BRCA1/2 mutations should have access to olaparib.

Histone and DNA Methylation as Epigenetic Regulators of DNA Damage Repair in Gastric Cancer and Emerging Therapeutic Opportunities.

Gastric cancer (GC), one of the most common malignancies worldwide, is a heterogeneous disease developing from the accumulation of genetic and epigenetic changes. One of the most critical epigenetic alterations in GC is DNA and histone methylation, which affects multiple processes in the cell nucleus, including gene expression and DNA damage repair (DDR). Indeed, the aberrant expression of histone methyltransferases and demethylases influences chromatin accessibility to the DNA repair machinery; moreover, overexpression of DNA methyltransferases results in promoter hypermethylation, which can suppress the transcription of genes involved in DNA repair. Several DDR mechanisms have been recognized so far, with homologous recombination (HR) being the main pathway involved in the repair of double-strand breaks. An increasing number of defective HR genes are emerging in GC, resulting in the identification of important determinants of therapeutic response to DDR inhibitors. This review describes how both histone and DNA methylation affect DDR in the context of GC and discusses how alterations in DDR can help identify new molecular targets to devise more effective therapeutic strategies for GC, with a particular focus on HR-deficient tumors.

Transcriptional Profiling of Homologous Recombination Pathway Genes in Mycobacterium bovis BCG Moreau.

Mycobacterium bovis BCG Moreau is the main Brazilian strain for vaccination against tuberculosis. It is considered an early strain, more like the original BCG, whereas BCG Pasteur, largely used as a reference, belongs to the late strain clade. BCG Moreau, contrary to Pasteur, is naturally deficient in homologous recombination (HR). In this work, using a UV exposure test, we aimed to detect differences in the survival of various BCG strains after DNA damage. Transcription of core and regulatory HR genes was further analyzed using RT-qPCR, aiming to identify the molecular agent responsible for this phenotype. We show that early strains share the Moreau low survival rate after UV exposure, whereas late strains mimic the Pasteur phenotype, indicating that this increase in HR efficiency is linked to the evolutionary clade history. Additionally, RT-qPCR shows that BCG Moreau has an overall lower level of these transcripts than Pasteur, indicating a correlation between this gene expression profile and HR efficiency. Further assays should be performed to fully identify the molecular mechanism that may explain this differential phenotype between early and late BCG strains.

A deregulated m6A writer complex axis driven by BRD4 confers an epitranscriptomic vulnerability in combined DNA repair–targeted therapy

Aberrant transcripts expression of the m6A methyltransferase complex (MTC) is widely found across human cancers, suggesting a dysregulated signaling cascade which integrates m6A epitranscriptome to drive tumorigenesis. However, the responsible transcriptional machinery directing the expression of distinct MTC subunits remains unclear. Here, we identified an unappreciated interplay between the histone acetyl-lysine reader BRD4 and the m6A writer complex across human cancers. BRD4 directly stimulates transcripts expression of seven MTC subunits, allowing the maintenance of the nuclear writer complex integrity. Upon BET inhibition, this BRD4-MTC signaling cascade accounts for global m6A reduction and the subsequent dynamic alteration of BRD4-dependent transcriptome, resulting in impaired DNA damage response that involves activation of homologous recombination (HR) repair and repression of apoptosis. We further demonstrated that the combined synergy upon BET/PARP inhibition largely relies on disrupted m6A modification of HR and apoptotic genes, counteracting PARP inhibitor (PARPi) resistance in patient-derived xenograft models. Our study revealed a widespread active cross-talk between BRD4-dependent epigenetic and MTC-mediated epitranscriptomic networks, which provides a unique therapeutic vulnerability that can be leveraged in combined DNA repair-targeted therapy.

RAD51D Secondary Mutation-Mediated Resistance to PARP-Inhibitor-Based Therapy in HGSOC.

Ovarian cancer is the leading cause of gynecologic cancer-related death, and PARP inhibitors (PARPis) are becoming a promising treatment option, as demonstrated by recent clinical trials. After PARPi exposure, somatic reversion mutations in the homologous recombination genes may be a mechanism of PARPi resistance in ovarian carcinoma. We present an ovarian cancer case of a 61-year-old woman, who underwent routine tumor reduction surgery followed by platinum and PARPis. She demonstrated a good response to PARPis for 15 months before recurrence and secondary tumor reduction surgery. However, post-surgery platinum and PARPi treatment only kept the disease stable for 5 months. A potential molecular mechanism for PARPi resistance was investigated using next-generation sequencing, immunohistochemical (IHC) staining, and other functional assays. A germline RAD51D loss-of-function mutation was found in the reported case (LRG_516t1:c.270_271dup p1:p.(Lys91fs*13)). Subsequently, a secondary mutation (LRG_516t1:c.271_282 del) was identified in the same locus of the germline duplication in the post-progression biopsies and ctDNA. The IHC staining supported low expression of RAD51D in the initial tumor tissue, but the expression was restored after the correction of the open reading frame by the secondary mutation. The in vitro results supported that the loss-of-function mutation of RAD51D was the basis for the initial response to the platinum and PARPi therapy, while the newly acquired reversion mutation could be attributed to the observed PARPi resistance. An acquired mutation can reverse a loss-of-function change in RAD51D and can result in PARPi resistance in a hereditary ovarian cancer patient. Liquid biopsy could be considered for longitudinal monitoring in ovarian patients under PARPi-based therapy, which can identify acquired resistant mutations earlier and facilitate precision management.

Recombination in Bacterial Genomes: Evolutionary Trends.

Bacterial organisms have undergone homologous recombination (HR) and horizontal gene transfer (HGT) multiple times during their history. These processes could increase fitness to new environments, cause specialization, the emergence of new species, and changes in virulence. Therefore, comprehensive knowledge of the impact and intensity of genetic exchanges and the location of recombination hotspots on the genome is necessary for understanding the dynamics of adaptation to various conditions. To this end, we aimed to characterize the functional impact and genomic context of computationally detected recombination events by analyzing genomic studies of any bacterial species, for which events have been detected in the last 30 years. Genomic loci where the transfer of DNA was detected pertained to mobile genetic elements (MGEs) housing genes that code for proteins engaged in distinct cellular processes, such as secretion systems, toxins, infection effectors, biosynthesis enzymes, etc. We found that all inferences fall into three main lifestyle categories, namely, ecological diversification, pathogenesis, and symbiosis. The latter primarily exhibits ancestral events, thus, possibly indicating that adaptation appears to be governed by similar recombination-dependent mechanisms.

Mutational spectrum of DNA damage and mismatch repair genes in prostate cancer.

Over the past few years, a number of studies have revealed that a significant number of men with prostate cancer had genetic defects in the DNA damage repair gene response and mismatch repair genes. Certain of these modifications, notably gene alterations known as homologous recombination (HRR) genes; PALB2, CHEK2 BRCA1, BRCA2, ATM, and genes for DNA mismatch repair (MMR); MLH1, MSH2, MSH6, and PMS2 are connected to a higher risk of prostate cancer and more severe types of the disease. The DNA damage repair (DDR) is essential for constructing and diversifying the antigen receptor genes required for T and B cell development. But this DDR imbalance results in stress on DNA replication and transcription, accumulation of mutations, and even cell death, which compromises tissue homeostasis. Due to these impacts of DDR anomalies, tumor immunity may be impacted, which may encourage the growth of tumors, the release of inflammatory cytokines, and aberrant immune reactions. In a similar vein, people who have altered MMR gene may benefit greatly from immunotherapy. Therefore, for these treatments, mutational genetic testing is indicated. Mismatch repair gene (MMR) defects are also more prevalent than previously thought, especially in patients with metastatic disease, high Gleason scores, and diverse histologies. This review summarizes the current information on the mutation spectrum and clinical significance of DDR mechanisms, such as HRR and MMR abnormalities in prostate cancer, and explains how patient management is evolving as a result of this understanding.

In vivo reduction of RAD51-mediated homologous recombination triggers aging but impairs oncogenesis.

Homologous recombination (HR) is a prominent DNA repair pathway maintaining genome integrity. Mutations in many HR genes lead to cancer predisposition. Paradoxically, the implication of the pivotal HR factor RAD51 on cancer development remains puzzling. Particularly, no RAD51 mouse models are available to address the role of RAD51 in aging and carcinogenesis in vivo. We engineered a mouse model with an inducible dominant-negative form of RAD51 (SMRad51) that suppresses RAD51-mediated HR without stimulating alternative mutagenic repair pathways. We found that in vivo expression of SMRad51 led to replicative stress, systemic inflammation, progenitor exhaustion, premature aging and reduced lifespan, but did not trigger tumorigenesis. Expressing SMRAD51 in a breast cancer predisposition mouse model (PyMT) decreased the number and the size of tumors, revealing an anti-tumor activity of SMRAD51. We propose that these in vivo phenotypes result from chronic endogenous replication stress caused by HR decrease, which preferentially targets progenitors and tumor cells. Our work underlines the importance of RAD51 activity for progenitor cell homeostasis, preventing aging and more generally for the balance between cancer and aging.

Genomic Profiling Reveals Germline Predisposition and Homologous Recombination Deficiency in Pancreatic Acinar Cell Carcinoma.

To determine the genetic predisposition underlying pancreatic acinar cell carcinoma (PACC) and characterize its genomic features. Both somatic and germline analyses were performed using an Food and Drug Administration-authorized matched tumor/normal sequencing assay on a clinical cohort of 28,780 patients with cancer, 49 of whom were diagnosed with PACC. For a subset of PACCs, whole-genome sequencing (WGS; n = 12) and RNA sequencing (n = 6) were performed. Eighteen of 49 (36.7%) PACCs harbored germline pathogenic variants in homologous recombination (HR) and DNA damage response (DDR) genes, including BRCA1 (n = 1), BRCA2 (n = 12), PALB2 (n = 2), ATM (n = 2), and CHEK2 (n = 1). Thirty-one PACCs displayed pure, and 18 PACCs harbored mixed acinar cell histology. Fifteen of 31 (48%) pure PACCs harbored a germline pathogenic variant affecting HR-/DDR-related genes. BRCA2 germline pathogenic variants (11 of 31, 35%) were significantly more frequent in pure PACCs than in pancreatic adenocarcinoma (86 of 2,739, 3.1%; P < .001), high-grade serous ovarian carcinoma (67 of 1,318, 5.1%; P < .001), prostate cancer (116 of 3,401, 3.4%; P < .001), and breast cancer (79 of 3,196, 2.5%; P < .001). Genomic features of HR deficiency (HRD) were detected in 7 of 12 PACCs undergoing WGS, including 100% (n = 6) of PACCs with germline HR-related pathogenic mutations and 1 of 6 PACCs lacking known pathogenic alterations in HR-related genes. Exploratory analyses revealed that in PACCs, the repertoire of somatic driver genetic alterations and the load of neoantigens with high binding affinity varied according to the presence of germline pathogenic alterations affecting HR-/DDR-related genes and/or HRD. In a large pan-cancer cohort, PACC was identified as the cancer type with the highest prevalence of both BRCA2 germline pathogenic variants and genomic features of HRD, suggesting that PACC should be considered as part of the spectrum of BRCA-related malignancies.

Finding significance: New perspectives in variant classification of the RAD51 regulators, BRCA2 and beyond

For many individuals harboring a variant of uncertain functional significance (VUS) in a homologous recombination (HR) gene, their risk of developing breast and ovarian cancer is unknown. Integral to the process of HR are BRCA1 and regulators of the central HR protein, RAD51, including BRCA2, PALB2, RAD51C and RAD51D. Due to advancements in sequencing technology and the continued expansion of cancer screening panels, the number of VUS identified in these genes has risen significantly. Standard practices for variant classification utilize different types of predictive, population, phenotypic, allelic and functional evidence. While variant analysis is improving, there remains a struggle to keep up with demand. Understanding the effects of an HR variant can aid in preventative care and is critical for developing an effective cancer treatment plan. In this review, we discuss current perspectives in the classification of variants in the breast and ovarian cancer genes BRCA1, BRCA2, PALB2, RAD51C and RAD51D.

A synthetic lethal approach to drug targeting of G-quadruplexes based on CX-5461

DNA G-quadruplex (G4) structures are enriched at human genome loci critical for cancer development, such as in oncogene promoters, telomeres, and rDNA. Medicinal chemistry approaches to developing drugs that target G4 structures date back to over 20 years ago. Small-molecule drugs were designed to target and stabilize G4 structures, thereby blocking replication and transcription, resulting in cancer cell death. CX-3543 (Quarfloxin) was the first G4-targeting drug to enter clinical trials in 2005; however, because of the lack of efficacy, it was withdrawn from Phase 2 clinical trials. Efficacy problems also occurred in the clinical trial of patients with advanced hematologic malignancies using CX-5461 (Pidnarulex), another G4-stabilizing drug. Only after the discovery of synthetic lethal (SL) interactions between Pidnarulex and the BRCA1/2-mediated homologous recombination (HR) pathway in 2017, promising clinical efficacy was achieved. In this case, Pidnarulex was used in a clinical trial to treat solid tumors deficient in BRCA2 and PALB2. The history of the development of Pidnarulex highlights the importance of SL in identifying cancer patients responsive to G4-targeting drugs. In order to identify additional cancer patients responsive to Pidnarulex, several genetic interaction screens have been performed with Pidnarulex and other G4-targeting drugs using human cancer cell lines or C. elegans. Screening results confirmed the synthetic lethal interaction between G4 stabilizers and HR genes and also uncovered other novel genetic interactions, including genes in other DNA damage repair pathways and genes in transcription, epigenetic, and RNA processing deficiencies. In addition to patient identification, synthetic lethality is also important for the design of drug combination therapy for G4-targeting drugs in order to achieve better clinical outcomes.

Alkylation of nucleobases by 2-chloro-N,N-diethylethanamine hydrochloride (CDEAH) sensitizes PARP1-deficient tumors.

Targeting BRCA1- and BRCA2-deficient tumors through synthetic lethality using poly(ADP-ribose) polymerase inhibitors (PARPi) has emerged as a successful strategy for cancer therapy. PARPi monotherapy has shown excellent efficacy and safety profiles in clinical practice but is limited by the need for tumor genome mutations in BRCA or other homologous recombination genes as well as the rapid emergence of resistance. In this study, we identified 2-chloro-N,N-diethylethanamine hydrochloride (CDEAH) as a small molecule that selectively kills PARP1- and xeroderma pigmentosum A-deficient cells. CDEAH is amonofunctional alkylating agent that preferentially alkylates guanine nucleobases, forming DNA adducts that can be removed from DNA by either a PARP1-dependent base excision repair or nucleotide excision repair. Treatment of PARP1-deficient cells leads to the formation of strand breaks, an accumulation of cells in S phase and activation of the DNA damage response. Furthermore, CDEAH selectively inhibits PARP1-deficient xenograft tumor growth compared to isogenic PARP1-proficient tumors. Collectively, we report the discovery of an alkylating agent inducing DNA damage that requires PARP1 activity for repair and acts synergistically with PARPi.

Abstract B074: Targeting CBP/p300 and its downstream transcriptional machinery in advanced PCa

Abstract Prostate cancer (PCa) is the second leading cause of cancer-related deaths in men in the US. There is a largely unmet clinical need to identify and develop novel strategies, that work either alone or in concert with AR-directed therapeutics, to combat CRPC. The highly conserved histone acetyltransferases CBP/p300 are potent co-activators for AR, and high p300 expression is associated with locally advanced disease and castration-resistant AR function. This study shows that CBP and p300 are highly expressed and correlate closely with AR gene expression and AR activity score in primary PCa and CRPC. By employing clinically relevant PCa models, the clinical significance of CBP/p300 expression in PCa patients as well as mechanistic evaluation of CBP/p300 transcriptional reprogramming and DNA damage response pathways have been undertaken. The molecular response to CBP/p300 inhibition will be assessed to discern novel metrics for precision medicine for PCa patients to improve therapeutic efficacy. Previous studies have relied on non-specific compounds and genetic silencing to target CBP/p300. CCS1477 (inobrodib) is a first-in-class bromodomain inhibitor developed by Cell Centric and targeted to inhibit CBP/p300 mediated bromodomain activity, and thus regulate cell survival. Inhibition of the CBP/p300 bromodomain resulted in significant downregulation of AR-FL, AR-V7, and its targets’ mRNA expression, as well as inhibition of associated factors such c-MYC and its downstream targets, in multiple PCa models. Transcriptomic analysis indicated that both CBP and p300 expression correlate with expression of genes involved in double strand break (DSB) DNA repair process including homologous recombination (HR) and non-homologous end joining (NHEJ) in both primary PCa and CRPC models. CCS1477 directly impacted DNA damage response and repair dynamics, as shown via delay in time to resolution of DNA damage foci formation, including RAD51 and γH2AX foci. Inhibition of CBP/p300 activity decreased tumor cell proliferation, blocked CRPC xenograft growth in vivo, and decreased proliferation ex vivo in patient-derived prostate tumor explants. Importantly, CBP/p300 expression correlated with HR genes in human prostate tissue samples in different cohorts. Lastly, inhibition of CBP/p300 activity also decreased HR gene expression in patients further supporting the essential role CBP/p300 plays in DNA repair. In sum, CBP/p300 inhibition mediates HR repair and impacts patient outcome. In conclusion, these studies identify CBP/p300 as a driver of PCa tumorigenesis through coordinated control of critical transcriptional events and lay the groundwork to optimize therapeutic strategies for advanced PCa via CBP/p300 inhibition, potentially in combination with AR-directed therapies. Combined, these studies have the capacity for significant near-term impact in the prevention and/or management of metastatic disease. Citation Format: Sumaira Sardar, Lakshmi Ravindranath, Christopher McNair, Saswati Chand, Wei Yuan, Denisa Bogdan, Jon Welti, Adam Sharp, Matthew Schiewer, Lisa Butler, Johann DeBono, Kris Frese, Nigel Brooks, Neil Pegg, Karen Knudsen, Ayesha A. Shafi. Targeting CBP/p300 and its downstream transcriptional machinery in advanced PCa [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 B074.