Homologous Recombination Pathway Research Articles

USP1 deubiquitinates PARP1 to regulate its trapping and PARylation activity.

PARP inhibitors (PARPi) represent a game-changing treatment for patients with ovarian cancer with tumors deficient for the homologous recombination (HR) pathway treated with platinum (Pt)-based therapy. PARPi exert their cytotoxic effect by both trapping PARP1 on the damaged DNA and by restraining its enzymatic activity (PARylation). How PARP1 is recruited and trapped at the DNA damage sites and how resistance to PARPi could be overcome are still matters of investigation. Here, we described PARP1 as a substrate of the deubiquitinase USP1. At molecular level, USP1 binds PARP1 to remove its K63-linked polyubiquitination and controls PARP1 chromatin trapping and PARylation activity, regulating sensitivity to PARPi. In both Pt/PARPi-sensitive and -resistant cells, USP1/PARP1 combined blockade enhances replicative stress, DNA damage, and cell death. Our work dissected the biological interaction between USP1 and PARP1 and recommended this axis as a promising and powerful therapeutic choice for not only sensitive but also chemoresistant patients with ovarian cancer irrespective of their HR status.

EPCO-32. PROSPECTIVE GERMLINE SEQUENCING OF PATIENTS WITH GLIOMAS, GLIONEURONAL OR NEURONAL TUMORS

Abstract BACKGROUND Several genetic syndromes have been linked to the development of central nervous system (CNS) tumors; however, the prevalence and clinical significance of germline pathogenic variants in this population remain unclear. METHODS 2,367 patients with a glioma, glioneuronal, or neuronal tumor (WHO grade 1-4) ages 0.2-93.8 years underwent tumor and matched normal sequencing with MSK-IMPACT. Germline variants and copy-number variants affecting 90 well-established cancer predisposing genes were analyzed; the presence of biallelic inactivation was determined using FACETS. RESULTS Eleven percent harbored germline pathogenic mutations in high-, moderate-, and low-penetrance genes. High- and moderate-penetrance genes included CHEK2 (n=32, 1.3%), BRCA2 (n=10; 0.4%), TP53 (n=9; 0.4%), NF1 (n=6; 0.2%), and mismatch repair (MMR) genes (n=20, 0.9%). Low-penetrance genes included monoallelic MUTYH (n=42; 1.8%) and the APC I1307K variant (n=28, 1.2%). Biallelic inactivation was found in all tumors from patients with germline TP53 and NF1 mutations, with lower rates in tumors from patients with a germline MMR alteration (53%). Biallelic inactivation was rare among patients with a germline mutation in homologous recombination pathway (HRD) genes (27%), and in the aforementioned low-penetrance APC (15.3%) and MUTYH (10.2%) variants. All patients with biallelic inactivation of an MMR gene were hypermutated. Biallelic inactivation of MMR genes and TP53 were observed in IDH-mutant astrocytoma and IDH-WT gliomas, while biallelic inactivation of NF1 and somatic IDH1/2 mutation were mutually exclusive. When examining the age at diagnosis among patients with germline alterations, tumors with biallelic inactivation were diagnosed at a younger age compared to tumors with monoallelic alterations (37.7 vs 51.6 years, p=0.002). CONCLUSION Clinical germline sequencing identifies a germline mutation in a high proportion of patients with CNS tumors. Biallelic inactivation was most commonly identified in tumors from patients with germline TP53 or NF1 mutations and were less common in patients with a germline MMR alteration.

DNAR-11. INHIBITION OF RAD52 ACTIVITY INDUCES DNA DAMAGE BY ACCUMULATING R-LOOPS IN DIFFUSE MIDLINE GLIOMA

Abstract Diffuse midline glioma (DMG) is one of the most devastating childhood cancers with a median survival of < 1year from diagnosis. There is a critical need for new therapeutics for improving treatment outcomes for DMG patients. We performed genome-wide CRISPR/Cas9 screening and identified RAD52 as a potential therapeutic target in DMG cells. RAD52 inhibition, using shRNA-mediated RAD52 depletion and treatment with RAD52 inhibitor, D-I03, suppressed DMG cell proliferation. Western blotting revealed that RAD52 inhibition increased DNA double-starand breaks (DSBs) marker γH2AX while it decreased repair markers BRCA1 and RAD51. Also, RAD52 inhibition causes a sustained level of phosphorylated RAD50 and γH2AX in irradiated DMG cells over 24 hours. Immunocytochemistry (ICC) of γH2AX and repair marker 53BP1 showed that RAD52 inhibition sustained DNA damage with high levels of γH2AX at 24 hours following radiation while the level of 53BPI was decreased, thereby inhibiting DNA DSB repair. DNA repair assay showed that RAD52 inhibition suppressed DNA DSB repair through a homologous recombination pathway. RNA sequencing showed that RAD52 inhibition downregulated genes associated with the DNA repair pathway. Importantly, RAD52 inhibition increased the radiosensitivity of DMG cells. To understand the mechanism of RAD52 inhibition on DNA damage, we performed dot plot assay and ICC of S9.6 which recognizes DNA-RNA hybrids (also known as R-loops) and found accumulation of R-loop formation in DMG cells treated with RAD52 inhibitor. In addition, RAD52 inhibition decreased the expression of RNA polymerase II. Finally, the combination therapy of RAD52 inhibitor and radiation inhibited tumor growth and increased survival of mice bearing DMG patient-derived xenografts, outperforming either monotherapy. Together, our results highlight that RAD52 inhibition induces DNA damage by accumulating R-loops, results in reducing DMG cell proliferation, while also increase DMG radiosensitivty, and providing a rationale for developing combination therapy with radiation for the treatment of DMG.

DDDR-30. ENHANCED CHEMO AND RADIO-SENSITIZATION OF GLIOMAS BY HSP90 INHIBITION WITH JIN-001, A NOVEL BLOOD-BRAIN BARRIER PENETRANT HSP90 INHIBITOR

Abstract BACKGROUND HSP90, an abundant molecular chaperone, plays a pivotal role as a key regulator in the growth and survival of malignant cells and has been a therapeutic target in various cancers. We have previously reported a strong role for HSP90 inhibitors to disable DNA damage repair mechanisms and induce cell death. Here, we determined the effects of JIN-001 mediated HSP90 inhibition on alkylator and radiation induced DNA damage. Method: Using a panel of patient-derived glioma stem cells (GSCs) we determined the synergy scores for cell viability of JIN-001 (0.1µM to 0.5µM) in combination with radiation (RT) and Temozolomide (TMZ). We also examined cell cycle dynamics and cell death of the combination using flow cytometry (PI and PI/Annexin method) and cell viability assays. Additionally, organotypic human glioma slice cultures treated with JIN-001 and chemoradiation were analyzed for changes in gene and protein expression as well as cell viability in situ. Ongoing in-vivo studies are being conducted to further elucidate drug combination efficacy in mouse models. RESULTS JIN-001 sensitized the cells to chemoradiation leading to cell cycle arrest and cell death which was higher in the combination compared to single agent. Significant changes in expression of downstream molecules of homologous recombination pathway was noted (ATM, pATM, CHK1, pCHK1, ATR, pATR) in the cell lines and confirmed in human glioma slice culture. Based on the synergy score from four cell lines, an effective dose for combination of JIN-001+RT+TMZ was identified; Results of ongoing ex-vivo human glioma gene expression changes and in-vivo mouse studies will be presented. CONCLUSION Through a comprehensive analysis, we demonstrated that HSP90 inhibitor JIN-001 sensitizes glioma cells to radio-chemotherapy including in human glioma tissue. Our study underscores the potential of combining JIN-001 with standard therapies in glioma treatment in future clinical trials for patients with glioblastoma.

The Influence of DNA Repair Genes and Prenatal Tobacco Exposure on Risk of Childhood Acute Lymphoblastic Leukemia-A Gene-Environment Interaction Study.

Acute lymphoblastic leukemia (ALL) is the most common type of cancer among children. Tobacco exposure during gestation has been investigated as a potential risk factor, but its role remains undefined. Given tobacco's toxicological profile as a DNA damaging agent, we examined the impact of DNA repair gene variability as a source of vulnerability to tobacco exposure risk for ALL. Leveraging demographic and genotype data from two large California-based ALL epidemiology studies, we used logistic regression, MinimumP (MinP) statistical method and permutation tests to examine interactions between DNA repair genes and prenatal tobacco exposure. We found statistically significant interactions between prenatal tobacco exposure and DNA repair genes RECQL (minP= 1.00x 10-4, FDR-P value = 1.86x 10-2) and TDG (minP= 1.00x 10-4, FDR-P value = 1.86 x 10-2) regarding childhood ALL risk. Notable interactions in the homologous recombination pathway were observed among Latino children, while non-Latino White children displayed significant interactions in the base excision repair and nucleotide excision repair pathways. Our study highlights the significance of DNA repair genes and pathways when evaluating environmental exposure to tobacco smoke, suggesting that genetic variability within these pathways could impact vulnerability in the development of childhood ALL. This study highlights the significant impact of genetic variation interacting with prenatal tobacco exposure on ALL risk. Further research is needed to understand these interactions and their implications for ALL etiology. Expanding studies to other gene-environment interactions will aid in developing targeted prevention, diagnosis, and treatment strategies for pediatric oncology.

Pan-cancer Analysis of Homologous Recombination Deficiency in Cell Lines.

Homologous Recombination Deficiency (HRD) drives genomic instability in multiple cancer types and renders tumors vulnerable to certain DNA damaging agents such as PARP inhibitors. Thus, HRD is emerging as an attractive biomarker in oncology. A variety of in silico methods are available for predicting HRD; however, few of these methods have been applied to cell lines in a comprehensive manner. Here we utilized two of these methods, "CHORD" and "HRDsum" scores, to predict HRD for 1,332 cancer cell lines and 84 non-cancerous cell lines. Cell lines with biallelic mutations in BRCA1 or BRCA2, which encode key components of the homologous recombination pathway, showed the strongest HRD predictions, validating the two methods in cell lines. A small subset of BRCA1/2-wildtype cell lines were also classified as HRD, several of which showed evidence of epigenetic BRCA1 silencing. Similar to HRD in patient samples, HRD in cell lines was associated with p53 loss, was mutually exclusive with microsatellite instability and occurred most frequently in breast and ovarian cancer types. In addition to validating previously identified associations with HRD, we leveraged cell line-specific datasets to gain new insights into HRD and its relation to various genetic dependency and drug sensitivity profiles. We found that in cell lines, HRD was associated with sensitivity to PARP inhibition in breast cancer, but not at a pan-cancer level. By generating large-scale, pan-cancer datasets on HRD predictions in cell lines, we aim to facilitate efforts to improve our understanding of HRD and its utility as a biomarker.

Enhancing cisplatin efficacy in hepatocellular carcinoma with selenocystine: The suppression of DNA repair and inhibition of proliferation in hepatoma cells

Cisplatin (cDDP) is a crucial chemotherapy drug for treating various cancers, including hepatocellular carcinoma (HCC). However, its effectiveness is often hindered by side effects and drug resistance. Selenocystine (SeC) demonstrates potential as an anticancer agent, particularly by inhibiting DNA repair mechanisms. This study explored the synergistic potential of SeC combined with cDDP for treating HCC. Our results show that SeC pretreatment followed by cDDP significantly suppresses HCC cell proliferation more effectively than either treatment alone, with minimal toxicity to normal liver cells. The combination induces significant DNA damage by inhibiting homologous recombination (HR) and non-homologous end joining (NHEJ) pathways. Xenograft experiments confirmed that the combined therapy strongly inhibits tumor growth. SeC boost the effectiveness of cDDP by amplifying DNA damage and inhibiting DNA repair, presenting a promising approach to enhancing liver cancer treatment.

Structural insights into the mechanism of DNA branch migration during homologous recombination in bacteria.

Some DNA helicases play central and specific roles in genome maintenance and plasticity through their branch migration activity in different pathways of homologous recombination. RadA is a highly conserved bacterial helicase involved in DNA repair throughout all bacterial species. In Gram-positive Firmicutes, it also has a role in natural transformation, while in Gram-negative bacteria, ComM is the canonical transformation-specific helicase. Both RadA and ComM helicases form hexameric rings and use ATP hydrolysis as an energy source to propel themselves along DNA. In this study, we present the cryoEM structures of RadA and ComM interacting with DNA and ATP analogs. These structures reveal important molecular interactions that couple ATP hydrolysis and DNA binding in RadA, as well as the role of the Lon protease-like domain, shared by RadA and ComM, in this process. Taken together, these results provide new molecular insights into the mechanisms of DNA branch migration in different pathways of homologous recombination.

RAD51 recombinase and its paralogs: Orchestrating homologous recombination and unforeseen functions in protozoan parasites

The DNA of protozoan parasites is highly susceptible to damage, either induced by environmental agents or spontaneously generated during cellular metabolism through reactive oxygen species (ROS). Certain phases of the cell cycle, such as meiotic recombination, and external factors like ionizing radiation (IR), ultraviolet light (UV), or chemical genotoxic agents further increase this susceptibility. Among the various types of DNA damage, double-stranded breaks (DSBs) are the most critical, as they are challenging to repair and can result in genetic instability or cell death. DSBs caused by environmental stressors are primarily repaired via one of two major pathways: non-homologous end joining (NHEJ) or homologous recombination (HR). In multicellular eukaryotes, NHEJ predominates, but in unicellular eukaryotes such as protozoan parasites, HR seems to be the principal mechanism for DSB repair. The HR pathway is orchestrated by proteins from the RAD52 epistasis group, including RAD51, RAD52, RAD54, RAD55, and the MRN complex. This review focuses on elucidating the diverse roles and significance of RAD51 recombinase and its paralogs in protozoan parasites, such as Acanthamoeba castellanii, Entamoeba histolytica (Amoebozoa), apicomplexan parasites (Chromalveolata), Naegleria fowleri, Giardia spp., Trichomonas vaginalis, and trypanosomatids (Excavata), where they primarily function in HR. Additionally, we analyze the diversity of proteins involved in HR, both upstream and downstream of RAD51, and discuss the implications of these processes in parasitic protozoa.

Prediction of homologous recombination deficiency identifies colorectal tumors sensitive to PARP inhibition

The synthetic lethal effect observed with the use of PARP inhibitors (PARPi) with tumors characterized by the loss of key players in the homologous recombination (HR) pathway, commonly referred to as “BRCAness”, is maintaining high interest in oncology. While BRCAness is a well-established feature in breast, ovarian, prostate, and pancreatic carcinomas, our recent findings indicate that up to 15% of colorectal cancers (CRC) also harbor defects in the HR pathway, presenting promising opportunities for innovative therapeutic strategies in CRC patients. We developed a new tool called HRDirect, which builds upon the HRDetect algorithm and is able to predict HR deficiency (HRD) from reference-free tumor samples. We validated HRDirect using matched breast cancer and CRC patient samples. Subsequently, we assessed its efficacy in predicting response to the PARP inhibitor olaparib by comparing it with two other commercial assays: AmoyDx HRD by Amoy Diagnostics and the TruSight Oncology 500 HRD (TSO500-HRD) panel by Illumina NGS technology. While all three approaches successfully identified the most PARPi-sensitive CRC models, HRDirect demonstrated superior precision in distinguishing resistant models compared to AmoyDX and TSO500-HRD, which exhibited overlapping scores between sensitive and resistant cells. Furthermore, we propose integrating HRDirect scoring with ATM and RAD51C immunohistochemical analysis as part of our “composite biomarker approach” to enhance the identification of HRD tumors, with an immediate translational and clinical impact for CRC personalized treatment.

TMPRSS2:ERG Gene Fusion Might Predict Resistance to PARP Inhibitors in Metastatic Castration-resistant Prostate Cancer.

The emergence of novel DNA damage repair (DDR) pathways in molecular-target therapy drugs (MTTD) has shown promising outcomes in treating patients with metastatic castration-resistant prostate cancer (mCRPC). About 25% of mCRPC patients have actionable deleterious aberrations in DDR genes, primarily in the homologous recombination (HR) pathway. However, the response rate in patients with BRCA1/2 or mutations in HRR-related genes is only 45%-55%, when exposed to poly ADP ribose polymerase (PARP) inhibitor-based therapy (PARPi). A frequent characteristic feature of prostate cancer (PC) is the occurrence of genomic rearrangement that affects the transmembrane protease serine 2 (TMPRSS2) and E26 transformation-specific (ETS)- transcription factor-related gene (ERG). In this study, a total of 114 patients with mCRPC had their RNA and DNA sequenced using next-generation sequencing. Based on their genetic profile of deleterious gene alterations of BRCA1/2 or ATM, six patients were selected for PARPi. Patients with TMPRSS2:ERG gene fusion and homozygous alteration in ATM or BRCA2 (n=2) or heterozygous alterations (BRCA1 or BRCA2) and lack of TMPRSS2:ERG gene fusion (n=2) did not show clinical benefit from PARPi (treatment duration <16 weeks). In contrast, patients (n=2) without TMPRSS2:ERG gene fusion and homozygous deleterious alterations in ATM or BRCA2 all had clinical benefit from PARPi (treatment duration ≥16 weeks). The TMPRSS2:ERG transcript product might be used as a PARPi resistance biomarker.

The role of RAD51 regulators and variants in primary ovarian insufficiency, endometriosis,and polycystic ovary syndrome.

The study of RAD51 regulators in female reproductive diseases has novel biomarker potential and implications for therapeutic advancement. Regulators of RAD51 play important roles in maintaining genome integrity and variations in these genes have been identified in female reproductive diseases including primary ovarian insufficiency (POI), endometriosis, and polycystic ovary syndrome (PCOS). RAD51 modulators change RAD51 activity in homologous recombination, replication stress, and template switching pathways. However, molecular implications of these proteins in primary ovarian insufficiency, endometriosis, and polycystic ovary syndrome have been understudied. For each reproductive disease, we provide its definition, current diagnostic and therapeutic treatment strategies, and associated genetic variations. Variants were discovered in RAD51, and regulators including DMC1, RAD51B, SWS1, SPIDR, XRCC2and BRCA2 linked with POI. Endometriosis is associated with variants in XRCC3, BRCA1and CSB genes. Variants in BRCA1 were associated with PCOS.Our analysis identifiednovel biomarkers for POI (DMC1 and RAD51B) and PCOS (BRCA1). Further biochemical and cellular analyses of RAD51 regulator functions in reproductive disorders will advance our understanding of the pathogenesis of these diseases.

Abstract C046: Targeting wild-type IDH1 sensitizes homologous recombination proficient pancreatic cancer to PARP inhibition

Abstract Introduction: Pancreatic ductal adenocarcinoma (PDAC) is a leading cause of cancer-related mortality in the United States. While Poly (ADP-ribose) polymerase (PARP) inhibitors show promise for PDAC with Homologous Recombination Deficiency (HRD), this mutation is present in less than 10% of cases. Our research focuses on exploiting a vulnerability in the remaining 90% of HR proficient (HRP) tumors. We identified that wild-type isocitrate dehydrogenase 1 (IDH1) plays a critical role in HR repair. By inhibiting IDH1, we discovered suppression of the homologous recombination (HR) pathway, leading to compromised genomic integrity. This renders cancer cells more susceptible to PARP inhibitor therapy, offering a novel therapeutic approach for HRP PDAC. Methods:We assessed the impact of IDH1 inhibition on HR pathway activity using Western blotting to measure HR repair protein levels and HR reporter assays. The effect of IDH1 inhibition (Ivosidenib) combined with PARP inhibition (Olaparib) on in vitro growth inhibition was assessed through drug combination assays. Additionally, we investigated the molecular mechanisms underlying the synergistic effects of the drug combination. To further evaluate the therapeutic potential of IDH1 inhibition in combination with PARP inhibitors, we examined tumor growth in xenograft models of PDAC in athymic nude mice and survival studies were performed in C57BL/6J mice transplanted with orthotopic murine pancreatic cancer. Results:Wild-type IDH1 blockade induces a BRCA-like phenotype by decreasing α-ketoglutarate (αKG) levels and causing histone hypermethylation. This leads to decreased HR repair efficiency in HRP pancreatic cancer cells (MiaPaCa-2 and Panc-1), resulting in a strong synergistic effect when combined with the DNA-damaging agent Olaparib. The combination treatment significantly reduced cell survival in both short and long-term assays. Furthermore, we discovered that these compounds complemented each other in the DNA damage response, leading to increased γ-H2AX (DNA damage marker) and apoptosis. In vivo studies using murine PDAC models demonstrated that the combination of ivosidenib and olaparib synergistically enhanced anti-tumor activity compared to either single agent alone. Conclusion:These data provide novel insight into the mechanisms underlying in the context of HRP cancer susceptibility to a dual treatment approach involving an IDH1 inhibitor and a PARP inhibitor. This approach holds promise for precision medicine in pancreatic cancer treatment, although further pre- clinical studies are needed for validation and refinement. Citation Format: Mehrdad Zarei, Omid Hajihassani, Hallie J. Graor, Soubhi Tahhan, Alexander W. Loftus, Faith Nakazzi, Semmer A. Ali, Parnian Naji, Luke D. Rothermel, Jonothan R. Brody, Jordan M. Winter. Targeting wild-type IDH1 sensitizes homologous recombination proficient pancreatic cancer to PARP inhibition [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr C046.

DNA repair-dependent immunogenic liabilities in colorectal cancer: opportunities from errors.

Colorectal cancer (CRC) remains one of the major causes of cancer death worldwide. Chemotherapy continues to serve as the primary treatment modality, while immunotherapy is largely ineffective for the majority of CRC patients. Seminal discoveries have emphasized that modifying DNA damage response (DDR) mechanisms confers both cell-autonomous and immune-related vulnerabilities across various cancers. In CRC, approximately 15% of tumours exhibit alterations in the mismatch repair (MMR) machinery, resulting in a high number of neoantigens and the activation of the type I interferon response. These factors, in conjunction with immune checkpoint blockades, collectively stimulate anticancer immunity. Furthermore, although less frequently, somatic alterations in the homologous recombination (HR) pathway are observed in CRC; these defects lead to genome instability and telomere alterations, supporting the use of poly (ADP-ribose) polymerase (PARP) inhibitors in HR-deficient CRC patients. Additionally, other DDR inhibitors, such as Ataxia Telangiectasia and Rad3-related protein (ATR) inhibitors, have shown some efficacy both in preclinical models and in the clinical setting, irrespective of MMR proficiency. The aim of this review is to elucidate how preexisting or induced vulnerabilities in DNA repair pathways represent an opportunity to increase tumour sensitivity to immune-based therapies in CRC.

Characterization of DNA damage repair pathway utilization in high-grade serous ovarian cancers yields rational therapeutic approaches

While poly (ADP-ribose) polymerase (PARP) inhibitors (PARPi) have improved the prognosis of ovarian high-grade serous carcinoma (HGSC) tumors that are homologous recombination (HR) deficient (HRD), new therapeutic strategies are needed for tumors that are HR proficient (HRP) because they demonstrate greater resistance to current treatments and thus have poorer clinical outcomes. Additionally, clinical precautionary statements regarding potential risks associated with PARPi, such as myelodysplastic syndrome, highlight the need for combinatorial approaches that can lessen the dose and duration of PARPi treatment to reduce toxicities. Here, we evaluated DNA double-strand damage repair pathways in HRD and HRP ovarian cancer cell lines and found that in HRD cell lines, PARPi therapy reduced non-homologous end joining (NHEJ)-mediated repair, specifically due to decreased theta-mediated end-joining. The combination of PARPi with ATM serine/threonine kinase inhibitor (ATMi) suppressed both NHEJ and HR pathways in HRD and HRP cell lines, with synergistic increases in apoptosis and decreases in cell viability and colony formation. Interestingly, PARPi plus ATMi also decreased NF-κB p65 phosphorylation, which was not observed when PARPi was combined with inhibition of the ATR kinase (ATRi). These findings indicate that PARPi plus ATMi is a promising strategy for HGSC independent of underlying tumor HR status.

Hyper-recombination in ribosomal DNA is driven by long-range resection-independent RAD51 accumulation

Ribosomal DNA (rDNA) encodes the ribosomal RNA genes and represents an intrinsically unstable genomic region. However, the underlying mechanisms and implications for genome integrity remain elusive. Here, we use Bloom syndrome (BS), a rare genetic disease characterized by DNA repair defects and hyper-unstable rDNA, as a model to investigate the mechanisms leading to rDNA instability. We find that in Bloom helicase (BLM) proficient cells, the homologous recombination (HR) pathway in rDNA resembles that in nuclear chromatin; it is initiated by resection, replication protein A (RPA) loading and BRCA2-dependent RAD51 filament formation. However, BLM deficiency compromises RPA-loading and BRCA1/2 recruitment to rDNA, but not RAD51 accumulation. RAD51 accumulates at rDNA despite depletion of long-range resection nucleases and rDNA damage results in micronuclei when BLM is absent. In summary, our findings indicate that rDNA is permissive to RAD51 accumulation in the absence of BLM, leading to micronucleation and potentially global genomic instability.

1780P Homologous recombination pathway in sarcomas: A novel opportunity of therapy?

1780P Homologous recombination pathway in sarcomas: A novel opportunity of therapy?

1087P Phase II study of niraparib in patients with advanced melanoma with homologous recombination pathway gene mutations

1087P Phase II study of niraparib in patients with advanced melanoma with homologous recombination pathway gene mutations

Molecular basis of CX-5461-induced DNA damage response in primary vascular smooth muscle cells

Our previous studies have shown that the novel selective RNA polymerase I inhibitor CX-5461 suppresses proliferation of vascular smooth muscle cells, mainly by inducing DNA damage response (DDR), including activations of ataxia telangiectasia mutated (ATM)/ATM and Rad3-related (ATR) and p53. Currently, there is no information about the molecular mechanism(s) underlying CX-5461-induced DDR in vascular cells, while the results obtained in cancer cells and immortalized cell lines are controversial. In this study, we examined the responses of various DDR pathways to CX-5461 treatment in primary aortic smooth muscle cells isolated from normal adult Sprague Dawley rats. We demonstrated that CX-5461-induced DDR was not associated with activations of the nucleotide excision repair, DNA mismatch repair, or the non-homologous end joining pathways, while the homologous recombination pathway was activated. However, the alkaline comet assay did not show massive DNA double strand breaks in CX-5461-treated cells. Instead, CX-5461-induced DDR appeared to be related to induction of DNA replication stress, which was not attributable to increased formation of G-quadruplex or R-loop structures, but might be explained by the increased replication-transcription conflict. CX-5461-induced DDR was not exclusively confined to rDNA within the nucleolar compartment; the extra-nucleolar DDR might represent a distinct secondary response related to the downregulated Rad51 expression in CX-5461-treated cells. In summary, we suggest that DNA replication stress may be the primary molecular event leading to downstream ATM/ATR and p53 activations in CX-5461-treated vascular smooth muscle cells. Our results provide further insights into the molecular basis of the beneficial effects of CX-5461 in proliferative vascular diseases.

Stressed? Break-induced replication comes to the rescue!

Break-induced replication (BIR) is a homologous recombination (HR) pathway that repairs one-ended DNA double-strand breaks (DSBs), which can result from replication fork collapse, telomere erosion, and other events. Eukaryotic BIR has been mainly investigated in yeast, where it is initiated by invasion of the broken DNA end into a homologous sequence, followed by extensive replication synthesis proceeding to the chromosome end. Multiple recent studies have described BIR in mammalian cells, the properties of which show many similarities to yeast BIR. While HR is considered as “error-free” mechanism, BIR is highly mutagenic and frequently leads to chromosomal rearrangements—genetic instabilities known to promote human disease. In addition, it is now recognized that BIR is highly stimulated by replication stress (RS), including RS constantly present in cancer cells, implicating BIR as a contributor to cancer genesis and progression. Here, we discuss the past and current findings related to the mechanism of BIR, the association of BIR with replication stress, and the destabilizing effects of BIR on the eukaryotic genome. Finally, we consider the potential for exploiting the BIR machinery to develop anti-cancer therapeutics.