Role In DNA Damage Response Research Articles

Interaction of RECQL4 with poly(ADP-ribose) is critical for the DNA double-strand break response in human cells.

To overcome genotoxicity, cells have evolved powerful and effective mechanisms to detect and respond to DNA lesions. RecQ Like Helicase-4 (RECQL4) plays a vital role in DNA damage responses. RECQL4 is recruited to DNA double-strand break (DSB) sites in a poly(ADP-ribosyl)ation (PARylation)-dependent manner, but the mechanism and significance of this process remain unclear. Here, we showed that the domain of RECQL4 recruited to DSBs in a PARylation-dependent manner directly interacts with poly(ADP-ribose) (PAR) and contains a PAR-binding motif (PBM). By replacing this PBM with a PBM of hnRNPA2 or its mutated form, we demonstrated that the PBM in RECQL4 is required for PARylation-dependent recruitment and the roles of RECQL4 in the DSB response. These results suggest that the direct interaction of RECQL4 with PAR is critical for proper cellular response to DSBs and provide insights to understand PARylation-dependent control of the DSB response and cancer therapeutics using PARylation inhibitors.

Ribosomal S6 kinase (RSK) plays a critical role in DNA damage response via the phosphorylation of histone lysine demethylase KDM4B

BackgroundEpigenetic dysregulation affecting oncogenic transcription and DNA damage response is a hallmark of cancer. The histone demethylase KDM4B, a factor regulating these processes, plays important roles in estrogen receptor-mediated transcription and DNA repair in breast cancer. However, how oncogenic phospho-signal transduction affects epigenetic regulation is not fully understood. Here we found that KDM4B phosphorylation by ribosomal S6 kinase (RSK), a downstream effector of the Ras/MAPK pathway, is critical for the function of KDM4B in response to DNA damage.MethodsKDM4B-knockout breast cancer cell lines were generated via CRISPR/Cas9-mediated gene editing. Re-expression of wild-type or phospho-site mutated KDM4B in knockout cells was performed by lentivirus-mediated gene transfer. Gene knockdown was achieved by RNA interference. DNA double-strand breaks (DSBs) were induced by ionizing radiation or laser-microirradiation. Protein accumulation at DSB sites was analyzed by immunofluorescence. KDM4B phosphorylation by RSK was assessed by in vitro and in vivo kinase assays. Gene and protein expression levels were analyzed by RT‒PCR and western blotting. The sensitivity of cells to ionizing radiation was examined by a clonogenic survival assay.ResultsRSK phosphorylated KDM4B at Ser666, and inhibition of the phosphorylation by RSK depletion or RSK inhibitors abrogated KDM4B accumulation at the sites of DNA double-strand breaks (DSBs). DSB repair was significantly delayed in KDM4B-knockout cells or cells treated with RSK inhibitors. The replacement of endogenous KDM4B with the phosphomimetic mutant S666D restored KDM4B accumulation and DSB repair that had been inhibited by RSK inhibitors, suggesting a critical role for RSK at the specific serine residue of KDM4B in the effect of RSK inhibitors on DSB repair. As a consequence of these aberrant responses, inhibition of KDM4B phosphorylation increased the sensitivity of the cells to ionizing radiation.ConclusionsOverall, the present study uncovered a novel function of RSK on the DNA damage response, which provides an additional role of its inhibitor in cancer therapy.

Temporal regulation of acetylation status determines PARP1 role in DNA damage response and metabolic homeostasis.

Poly(ADP-ribose) polymerase 1 (PARP1) is an abundant nuclear protein involved in DNA repair, chromatin structure, and transcription. However, the regulation of its different functions remains poorly understood. Here, we report the role of PARP1 acetylation status in modulating its DNA repair and transactivation functions. We demonstrate that histone deacetylase 5 (HDAC5) determines PARP1 acetylation at Lys498 and Lys521 sites. HDAC5-mediated deacetylation at Lys498 site regulates PARP1 DNA damage response and facilitates efficient recruitment of DNA repair factors at damaged sites, thereby promoting cell survival. Additionally, HDAC5-mediated deacetylation at Lys521 site promotes PARP1 coactivator function, resulting in induction of proliferative and metabolic genes in an activating transcription factor 4-dependent manner. Thus, PARP1 induces metabolic adaptation to spur malignant phenotype. Our studies in mouse tumor models suggest that pharmacological inhibition of PARP1 enzymatic activity does not block tumor progression robustly as transactivation function remains unperturbed. These findings provide key mechanistic insights into PARP1 regulation and expand its role in tumor development.

VGLL3 modulates chemosensitivity through promoting DNA double-strand break repair.

Transcription cofactor vestigial-like 3 (VGLL3), as a master regulator of female-biased autoimmunity, also functions in tumor development, while the underlying mechanisms remain largely elusive. Here, we report that VGLL3 plays an important role in DNA damage response (DDR). VGLL3 can be recruited to damage sites in a PARylation-dependent manner. VGLL3 depletion impairs the accumulation of RNF8 and RAD51 at sites of DNA damage, leading to reduced homologous recombination efficiency and increased cellular sensitivity to chemotherapeutic drugs. Mechanistically, VGLL3 can prevent CtIP from KLHL15-mediated ubiquitination and degradation through competitive binding with KLHL15 and, meanwhile, stabilize MDC1 by limiting TRIP12-MDC1 but promoting USP7-MDC1 associations for optimal RNF8 signaling initiation. Consistently, VGLL3 depletion delays tumor development and sensitizes the xenografts to etoposide treatment. Overall, our results reveal an unexpected role of VGLL3 in DDR, which is distinct from its transcriptional cofactor function and not conserved among VGLL family members.

ADP-ribosylome analysis reveals homogeneous DNA-damage-induced serine ADP-ribosylation across wild-type and BRCA-mutant breast cancer cell lines

ADP-ribosylation (ADPr) signaling plays a crucial role in DNA damage response. Inhibitors against the main enzyme catalyzing ADPr after DNA damage, poly(ADP-ribose) polymerase 1 (PARP1), are used to treat patients with breast cancer harboring BRCA1/2 mutations. However, resistance to PARP inhibitors (PARPi) is a major obstacle in treating patients. To understand the role of ADPr in PARPi sensitivity, we use liquid chromatography-tandem mass spectrometry (LC-MS/MS) to analyze ADPr in six breast cancer cell lines exhibiting different PARPi sensitivities. We identify 1,632 sites on 777 proteins across all cell lines, primarily on serine residues, with site-specific overlap of targeted residues across DNA-damage-related proteins across all cell lines, demonstrating high conservation of serine ADPr-signaling networks upon DNA damage. Furthermore, we observe site-specific differences in ADPr intensities in PARPi-sensitive BRCA mutants and unique ADPr sites in PARPi-resistant BRCA-mutant HCC1937 cells, which have low poly(ADP-ribose) glycohydrolase (PARG) levels and longer ADPr chains on PARP1.

Role of DNA damage response in cyclophosphamide-induced premature ovarian failure in mice.

To investigate the DNA damage response (DDR) in a cyclophosphamide (CTX)-induced mouse model of premature ovarian failure (POF). The POF model was established by injecting mice with CTX. The body, ovarian weights, the estrus cycle, and pathological changes of the ovaries were recorded. The serum levels of 17 β-estradiol (E2) and follicle-stimulating hormone (FSH) were measured. The expression of Ki67, β-galactosidase (β-gal), p21, p53, γH2AX, and pATM in ovarian tissues was detected by immunohistochemistry. The expression of β-gal, γH2AX, and pATM was analyzed by immunofluorescence staining of primary cultured granulosa cells (GCs). The body and ovarian weights decreased, the estrus cycles were erratic, and the FSH level increased, whereas the E2 level decreased in POF mice compared to controls. The pathological consequences of POF revealed an increase in atretic follicles, corpus luteum, and primordial follicles and a decrease in the number of primary, secondary, and tertiary follicles. Ki67 expression was reduced, β-gal, p21, p53, γH2AX, and pATM expression were elevated in the ovaries of POF mice. The expression of β-gal, γH2AX, and pATM increased in GCs with the concentration in a time-dependent manner. In total, CTX induced POF in mice, which was mediated by the DDR pathway of ATM-P53-P21.

The role of DNA damage response in human embryonic stem cells exposed to atmospheric oxygen tension: Implications for embryo development and differentiation

Previous retrospective cohort studies have found that, compared with oxygen tension in the uterus and fallopian tubes (2 %-8 %), exposure of pre-implantation embryos to atmospheric oxygen tension (AtmO2, 20 %) during assisted reproductive technology(ART) can affect embryo quality, pregnancy outcomes and offspring health. However, current research on the effects and mechanisms of AtmO2 on the development of embryos and offspring is mainly limited to animal experiments. Human embryonic stem cells (hESCs) play a special and irreplaceable role in the study of early human embryonic development. In this study, we used hESCs as a model to elucidate the possible effects and mechanisms of AtmO2 exposure on human embryonic development. We found that exposure to AtmO2 can reduce cell viability, produce oxidative stress, increase DNA damage, initiate DNA repair, activate autophagy, and increase cell apoptosis. We also noticed that approximately 50 % of hESCs survived, adapted and proliferated through high expression of self-renewal and pluripotency regulatory factors, and affected embryoid body differentiation. These data indicate that hESCs experience oxidative stress, accumulation of DNA damage, and activate DNA damage response under the selective pressure of AtmO2.Some hESCs undergo cell death, whereas other hESCs adapt and proliferate through increased expression of self-renewal genes. The current findings provide in vitro evidence that exposure to AtmO2 during the early preimplantation stage negatively affects hESCs.

Long non-coding RNA LIP interacts with PARP-1 influencing the efficiency of base excision repair

In recent years, various long non-coding RNAs (lncRNAs) involved in DNA damage response (DDR) have been identified and studied to deepen our understanding. However, there are rare reports on the association between lncRNAs and base excision repair (BER). Our designed DNA microarray identified dozens of functionally unknown lncRNAs, and their transcription levels significantly increased upon exposure to DNA damage inducers. One of them, named LIP (Long noncoding RNA Interacts with PARP-1), exhibited a significant alteration in transcription in response to methyl methanesulfonate (MMS) and temozolomide (TMZ) treatments. LIP knockdown or knockout cell lines are sensitive to MMS and TMZ, indicating that LIP plays a crucial role in DDR. The loss or insufficiency of LIP significantly influences the efficiency of BER in human cells, and it suggests that LIP participates in the BER pathway. The interaction between LIP and a key factor in BER, poly (ADP-ribose) polymerase 1 (PARP-1), has been confirmed. We identified and characterized LIP, a lncRNA, which is involved in DDR, significantly influences BER efficiency, and interacts with the BER key factor PARP-1. This advances our understanding of the connection between lncRNAs and BER, presenting the potential for the discovery of new drug targets.

Abstract 7116: Targeting the CBP/p300 axis in lethal prostate cancer impacts DNA repair

Abstract Prostate cancer (PCa) is the 2nd leading cause of cancer related deaths in US men. PCa is an androgen dependent disease driven by the androgen receptor (AR). Currently, androgen-deprivation therapy (ADT) is the standard of care first-line therapy for metastatic PCa. Resistance to ADT uniformly leads to lethal disease, termed castration-resistant prostate cancer (CRPC). Thus, there is an unmet clinical need to identify and develop novel strategies to treat CRPC. CBP/p300 are potent co-activators for AR. High expression of CBP/p300 is associated with locally advanced disease and castration resistant function of AR, resulting in poor patient outcomes and further highlighting the need to discern the role of CBP/p300 to potentially develop therapeutic targets for precision medicine. Previous studies have relied on non-specific compounds and genetic silencing to target CBP/p300. In this study, CBP/p300 mediated bromodomain activity is targeted by CCS1477 (inobrodib), a first-in-class bromodomain inhibitor developed by Cell Centric. CCS1477 treatment demonstrated effective inhibition in growth and clonogenicity assays. Inhibition of the CBP/p300 bromodomain with CCS1477 resulted in significant downregulation of AR-FL, AR-V7, and its targets’ mRNA expression in addition to inhibition of associated factors such as c-MYC and its downstream targets in PCa cell lines as well as patient derived xenograft (PDX) models. 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 patient samples. The clinical significance of CBP/p300 expression in PCa has been investigated via elucidation of CBP/p300 transcriptional reprogramming and its role in DNA damage response (DDR) pathways. Specifically, findings revealed that CBP/p300 bromodomain suppression sensitizes to AR-dependent DNA-repair. Transcriptional mapping identified CBP/p300 as regulators of cell proliferation and DNA repair processes, which were functionally confirmed across several PCa model systems. To assess relevance, exogenous challenge with radiation revealed that CBP/p300 are required for AR-mediated DNA repair, and CBP/p300 expression is linked to DNA repair capacity in the clinical setting. Molecular analyses revealed that CBP/p300 facilitate double-strand break (DSB) repair efficiency via homologous recombination (HR) mediated DDR. Congruently, CBP/p300 strongly correlated with HR gene expression in PCa patient tissue. These collective findings reveal that CBP/p300 govern repair of DNA DSBs by regulating HR, thus modulating genome integrity and promoting CRPC growth. 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. Citation Format: Sumaira Sardar, Lakshmi Ravindranath, Christopher McNair, Saswati N. Chand, Wei Yuan, Denisa Bogdan, Jonathan Welti, Adam Sharp, Matthew Schiewer, Lisa Butler, Johann de Bono, Kris Frese, Nigel Brooks, Neil Pegg, Karen Knudsen, Ayesha A. Shafi. Targeting the CBP/p300 axis in lethal prostate cancer impacts DNA repair [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 7116.

Abstract 7127: An ATM inhibitor: ZN-B-2262 in combination with radiation/ADCs containing topoisomerase inhibitors for the treatment of solid tumors

Abstract Background: ZN-B-2262 is a best-in-class, IND-approved, small molecule serine/threonine kinase receptor inhibitor targeting Ataxia Telangiectasia Mutated (ATM), which plays a key role in DNA damage response (DDR) associated with double-strand breaks (DSB). Radiotherapy (RT) and topoisomerase inhibition can directly cause DSB. ZN-B-2262 is expected to enhance the therapeutic effect of RT, or antibody drug conjugates (ADCs) containing topoisomerase inhibitors by suppressing DSB DNA repair and blocking checkpoint controls. Methods: The inhibition of isolated recombinant ATM, ATR, mTOR, DNA-PK, PI3Kα, PI3Kβ, PI3Kδ and PI3Kγ enzymes was evaluated using In-Cell-Western assay to determine the effect of ZN-B-2262 on ATM enzyme activity by detecting phosp-KAP1 (Ser824) expression. The inhibition of phospho-ATM (Ser1981) was evaluated by ATM assay on HT29 cells using a High-Content Imaging System (HCS). Therapeutic efficacy, as measured by tumor growth inhibition (TGI), was evaluated using ZN-B-2262 in combination with DS-1062 (Trop2 ADC), irinotecan or RT in MDA-MB-468 triple negative breast cancer (TNBC), SW620 colorectal cancer, and Fadu head and neck squamous cell carcinoma (HNSCC) subcutaneous xenograft murine models, respectively. In addition, ZN-B-2262 was tested for Human Aldehyde Oxidase (AO) activity. Safety margins were determined based on the ratio of unbound AUC obtained from 28-day GLP animal toxicology studies and predicted human PK at efficacious dose. Results: ZN-B-2262 exhibited strong inhibition against ATM with the IC50 at 4.4 nM. No inhibition effect was observed on other IKK family enzymes with IC50 value >10 uM. ZN-B-2262 showed high inhibition activity on phosp-KAP1 with IC50 of 13.25 nM and on phospho-ATM with IC50 of 21.5 nM. In the MDA-MB-468 xenograft efficacy study, ZN-B-2262 combined with a clinically relevant dose of DS-1062 showed significantly superior tumor inhibition effects compared to DS-1062 alone. In the SW620 xenograft efficacy study, in combination with irinotecan, ZN-B-2262 showed synergistic tumor inhibition effects. In the Fadu xenograft efficacy study, ZN-B-2262 demonstrated synergistic anti-tumor activity when combined with RT. Sustained and enhanced anti-tumor efficacy was observed post withdrawal of ZN-B-2262 combined with RT, which was not observed after stopping treatment of RT alone. Based on 28-day GLP tox in rat and dog, the predicted human safety margin is 25- to 50-fold. Conclusion: ZN-B-2262, in combination with ADCs containing topoisomerase inhibitors, (e.g., Dato-Dxd), or RT, is expected to be a best-in-class (possibly first-in-class) compound, for the treatment of solid tumors. In particular, ZN-B-2262 should demonstrate improved PK and minimal inter-patient PK variability compared to current ATM clinical candidates since ZN-B-2262 is not an AO substrate. Citation Format: Ding Zhou, Zheng Wang, Yan (Pita) Liu, Tingting Fu, Ziqiang (Zack) Cheng. An ATM inhibitor: ZN-B-2262 in combination with radiation/ADCs containing topoisomerase inhibitors for the treatment of solid tumors [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 7127.

Computational Analysis of Non-synonymous SNPs in ATM Kinase: Structural Insights, Functional Implications, and Inhibitor Discovery.

Ataxia telangiectasia-mutated (ATM) protein kinase, a key player in cellular integrity regulation, is known for its role in DNA damage response. This study investigates the broader impact of ATM on cellular processes and potential clinical manifestations arising from mutations, aiming to expand our understanding of ATM's diverse functions beyond conventional roles. The research employs a comprehensive set of computational techniques for a thorough analysis of ATM mutations. The mutation data are curated from dbSNP and HuVarBase databases. A meticulous assessment is conducted, considering factors such as deleterious effects, protein stability, oncogenic potential, and biophysical characteristics of the identified mutations. Conservation analysis, utilizing diverse computational tools, provides insights into the evolutionary significance of these mutations. Molecular docking and dynamic simulation analyses are carried out for selected mutations, investigating their interactions with Y2080D, AZD0156, and quercetin inhibitors to gauge potential therapeutic implications. Among the 419 mutations scrutinized, five (V1913C, Y2080D, L2656P, C2770G, and C2930G) are identified as both disease causing and protein destabilizing. The study reveals the oncogenic potential of these mutations, supported by findings from the COSMIC database. Notably, Y2080D is associated with haematopoietic and lymphoid cancers, while C2770G shows a correlation with squamous cell carcinomas. Molecular docking and dynamic simulation analyses highlight strong binding affinities of quercetin for Y2080D and AZD0156 for C2770G, suggesting potential therapeutic options. In summary, this computational analysis provides a comprehensive understanding of ATM mutations, revealing their potential implications in cellular integrity and cancer development. The study underscores the significance of Y2080D and C2770G mutations, offering valuable insights for future precision medicine targeting-specific ATM. Despite informative computational analyses, a significant research gap exists, necessitating essential in vitro and in vivo studies to validate the predicted effects of ATM mutations on protein structure and function.

Abstract B009: Targeting the AR co-activator CBP/p300 axis in castration resistant prostate cancer Impacts DNA damage repair function

Abstract Prostate cancer (PCa) is the second leading cause of cancer related deaths in US men. PCa is an androgen dependent disease and the transcription factor, androgen receptor (AR), is crucial for the overall outcome. Currently, androgen-deprivation therapy (ADT) is the standard of care first-line therapy for metastatic PCa. Resistance to ADT almost uniformly leads to lethal disease, termed castration-resistant prostate cancer (CRPC). Thus, there is a significant unmet clinical need to identify and develop novel strategies to treat CRPC. CBP/p300 are potent co-activators for AR. High expression of CBP/p300 are associated with locally advanced disease and castration resistant function of AR; thus, resulting in poor patient outcome and further highlighting the need to discern the role of CBP/p300 to potentially develop novel therapeutic targets for precision medicine. Previous studies have relied on non-specific compounds and genetic silencing to target CBP/p300 and its associated transcriptional machinery. In this study, CBP/p300 mediated bromodomain activity is targeted by CCS1477 (Inobrodib), a first-in-class bromodomain inhibitor developed by Cell Centric. CCS1477 was shown to demonstrate effective inhibition in growth and clonogenicity assays. Inhibition of the CBP/p300 bromodomain with CCS1477 resulted in significant downregulation of AR-FL, AR-V7, and its targets’ mRNA expression in addition to inhibition of associated factors such as c-MYC and its downstream targets in PCa cell lines as well as patient derived xenograft (PDX) models. 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 patient samples. The clinical significance of CBP/p300 expression in PCa has been investigated via elucidation of CBP/p300 transcriptional reprogramming and role in DNA damage response (DDR) pathways. Specifically, findings revealed that CBP/p300 bromodomain suppression sensitizes to AR-dependent DNA-repair. Transcriptional mapping identified CBP/p300 as regulators of cell proliferation and DNA repair processes, which were functionally confirmed across several PCa model systems. To assess relevance, exogenous challenge with radiation revealed that CBP/p300 bromodomain is required for AR-mediated DNA repair, and CBP/p300 expression is linked to DNA repair capacity in the clinical setting. Molecular analyses revealed that CBP/p300 facilitate double-strand break (DSB) repair efficiency via homologous recombination (HR) mediated DDR. Congruently, CBP/p300 strongly correlated with HR gene expression in PCa patient tissue. These collective findings reveal that CBP/p300 govern repair of DNA DSBs by regulating HR, thus modulating genome integrity, and promoting CRPC growth. 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. Citation Format: Sumaira Sardar. Targeting the AR co-activator CBP/p300 axis in castration resistant prostate cancer Impacts DNA damage repair function [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: DNA Damage Repair: From Basic Science to Future Clinical Application; 2024 Jan 9-11; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2024;84(1 Suppl):Abstract nr B009.

In silico and structure-based evaluation of deleterious mutations identified in human Chk1, Chk2, and Wee1 protein kinase.

Checkpoint kinases Chk1, Chk2, Wee1 are playing a key role in DNA damage response and genomic integrity. Cancer-associated mutations identified in human Chk1, Chk2, and Wee1 were retrieved to understand the function associated with the mutation and also alterations in the folding pattern. Therefore, an attempt has been made to identify deleterious effect of variants using in silico and structure-based approach. Variants of uncertain significance for Chk1, Chk2, and Wee1 were retrieved from different databases and four prediction servers were employed to predict pathogenicity of mutations. Further, Interpro, I-Mutant 3.0, Consurf, TM-align, and have (y)our protein explained were used for comprehensive study of the deleterious effects of variants. The sequences of Chk1, Chk2, and Wee1 were analyzed using Clustal Omega, and the three-dimensional structures of the proteins were aligned using TM-align. The molecular dynamics simulations were performed to explore the differences in folding pattern between Chk1, Chk2, Wee1 wild-type, and mutant protein and also to evaluate the structural integrity. Thirty-six variants in Chk1, 250 Variants in Chk2, and 29 in Wee1 were categorized as pathogenic using in silico prediction tools. Furthermore, 25 mutations in Chk1, 189 in Chk2, and 14 in Wee1 were highly conserved, possessing deleterious effect and also influencing the protein structure and function. These identified mutations may provide underlying genetic intricacies to serve as potential targets for therapeutic inventions and clinical management.

Abstract B070: Antitumor effect of AZD5305, a selective PARP1 inhibitor, in breast and gastric cancer cells

Abstract Background: Poly (ADP-ribose) polymerase (PARP) 1 has multiple cellular functions including its crucial role in DNA damage response. PARP inhibitor (PARPi) blocks the synthesis of PAR polymers and traps PARP1 on the damage sites. Currently approved PARPis target both PARP1 and PARP2, but the inhibition of PARP2 can cause undesirable hematological toxicity. AZD5305 is a novel selective PARP1 inhibitor that can reduce the hematological toxicity by off-targeting of PARP2. We evaluated the anti-tumor effects and mechanism of action of AZD5305 in breast and gastric cancer cells in vitro. Methods: To investigate the anti-tumor effects of AZD5305, we used 2 cell lines of breast cancer cells (HCC1395 and MCF7) and 3 cell lines of human gastric cancer cells (SNU-601, SNU-668 and KATO Ⅲ). The cytotoxicity of AZD5305 was evaluated by colony formation assay (CFA) for 14 days with increasing concentration of AZD5305 (doses range: 0-5nM). Cell cycle was analyzed by flow cytometry and apoptotic cell death was assessed by annexin-Ⅴ/PI staining. DNA damage was detected by comet assay and cell immunofluorescence assay. Results: BRCA1/2 mutated HCC1395 and RAD51C deficient SNU-601 were sensitive to AZD5305 (IC50: 0.25 nM), and SNU-668 was moderately sensitive (IC50: 2.05nM), while MCF7 and KATO III were less-sensitive to AZD5305 (IC50 > 5 nM). AZD5305 induced the G2/M cell cycle arrest in a dose-dependent manner in HCC1395 and SNU-601, but not in MCF7 and KATO Ⅲ. Moreover, AZD5305 increased sub-G1 population in HCC1395 and SNU-601 cells indicating apoptotic cell death, which was also confirmed by annexin-V assay and the cleaved PARP and caspase-7. Phosphorylation of RPA, γH2AX, and the expression of molecules related to DNA damage response were increased in the sensitive cells. Moreover, comet tails which indicate fragmented DNA were observed in the sensitive cells, but not in insensitive cells. Conclusions: AZD5305, a novel PARP1 selective inhibitor, shows cytotoxic effect in HR defective breast and gastric cancer cells in vitro. AZD5305 accumulates DNA damage which leads to apoptotic cell death in sensitive cell lines, but not in less-sensitive cell lines. Citation Format: Sujin Ham, So Hyeon Kim, Hae Min Hwang, Minyoung Lee, Youlim Noh, Changyun Lee, Yu-Jin Kim, Jinyong Kim, Dae-Won Lee, Kyung-Hun Lee, Seock-Ah Im. Antitumor effect of AZD5305, a selective PARP1 inhibitor, in breast and gastric cancer cells [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2023 Oct 11-15; Boston, MA. Philadelphia (PA): AACR; Mol Cancer Ther 2023;22(12 Suppl):Abstract nr B070.

Genome-Wide Mapping of R-Loops in Single Cells Reveals Cell-Type Specific Roles for R-Loops in Hematopoietic Cell Identity

R-loops are three-stranded structures composed of an RNA-DNA hybrid and a single strand of DNA. R-loops play critical roles in gene regulation and pathologic roles in DNA damage response. Current methods to map R-loops require at least 500,000 cells. Consequently, R-loop characterization in primary cells is limited. Furthermore, there are no genomic tools to identify R-loops in single cells. We therefore developed here methods to map genome-wide R-loops at single cell resolution. R-loop mapping in primary stem and mature hematopoietic cell populations, and individual single cells revealed striking cell-type specific R-loops. Current methods to map R-loops utilize immunoprecipitation with a monoclonal antibody (clone “S9.6”) or catalytically inactive, but R-loop binding competent, RNAseH1. Motivated by success mapping chromatin modifications in single cells through fusion of Tn5 transposase to a nanobody as well as insertion of T7 promoters to amplify DNA at sites of transposition, we combined both techniques to identify R-loops in limited cell numbers, down to the single cell level. We used a nanobody-Tn5 fusion to identify S9.6 and developed an orthogonal recombinant fusion protein of enzymatic dead RNAseH1 fused to Tn5 (Figure A). We first applied our nanobody-Tn5 method to identify R-loops bound by S9.6 in mouse lineage-negative c-Kit + bone marrow cells in biological duplicates of increasingly reduced cell numbers (64,000, 32,000, 16,000, and 8,000 cells). This revealed remarkable reproducibility of R-loop detection and characteristics. R-loops identified were sensitive to RNAseH1 and enriched at sites with G/C skew and mitochondrial DNA (a site with abundant physiologic R-loops), suggesting authentic, bona fide R-loops mapped in as few 8,000 cells. We next evaluated R-loops across FACS-isolated hematopoietic stem and mature cells from mouse and human bone marrow. Mapping of R-loops in 10,000 cells in duplicate revealed reproducible R-loops which were characteristic of each cell population. Hierarchical clustering of R-loop profiles delineated mature from stem and progenitor cells and discovered increased abundance of genic R-loops in hematopoietic stem and progenitors relative to mature cells (Figure B). Application of our enzymatic dead RNaseH1/Tn5 fusion protein to CD34 + cells revealed a similar genome-wide distribution of R-loops as with the S9.6/nanobody-Tn5 method. There was high correlation of long- and short-term HSC-specific R-loops with sites characteristic of active transcription (based on H3K4me1/2/3 as well as H3K27Ac). Transcription factor motifs activated in unique hematopoietic cell types were enriched at R-loops within the same cell types. For example, GATA motif usage was enriched at R-loops in CMP, MEP, and erythroid precursors. We also detected massive increases in R-loop abundance at the immunoglobulin heavy chain locus in primary B-cells stimulated to undergo class switch recombination. This provides further proof of our low input method to identify R-loops, as physiologic R-loops are known to occur at this locus to promote class switch recombination. Despite recent advances in single cell genomics there are no single cell maps of R-loops. We therefore profiled R-loops using our nanobody-Tn5, low-input S9.6 CUT&Tag approach in individual human CD34 + and mouse c-Kit + cells. We obtained 1,579 single-cell profiles from human and 1,716 from mouse. Uniform manifold approximation and projection (UMAP) identified 12 clusters in human and 9 mouse hematopoietic clusters. Aggregated single-cell R-loop profiles closely resembled bulk profiles indicating that single-cell data captured features of multi-cell maps. Pseudotime analyses of R-loops inferred LT-HSCs as the shared root of hematopoiesis in both mouse and human and identified seven terminal states without prior knowledge of the number of branches in the hematopoietic development. These data provide the first maps of R-loops in primary normal hematopoietic cells and identify scheduled, physiologic cell-type specific R-loops which have not previously been uncovered. The atlas of R-loops across hematopoiesis generated here will motivate future studies to understand the roles of R-loops in hematopoietic differentiation. Moreover, the methods presented map R-loop abundance at nucleotide resolution in primary and limited cell types which can be used for wide-reaching applications.

Targeting the DNA Damage Response for Cancer Therapy.

Over the course of long-term evolution, cells have developed intricate defense mechanisms in response to DNA damage; these mechanisms play a pivotal role in maintaining genomic stability. Defects in the DNA damage response pathways can give rise to various diseases, including cancer. The DNA damage response (DDR) system is instrumental in safeguarding genomic stability. The accumulation of DNA damage and the weakening of DDR function both promote the initiation and progression of tumors. Simultaneously, they offer opportunities and targets for cancer therapeutics. This article primarily elucidates the DNA damage repair pathways and the progress made in targeting key proteins within these pathways for cancer treatment. Among them, poly (ADP-ribose) polymerase 1 (PARP1) plays a crucial role in DDR, and inhibitors targeting PARP1 have garnered extensive attention in anticancer research. By delving into the realms of DNA damage and repair, we aspire to explore more precise and effective strategies for cancer therapy and to seek novel avenues for intervention.

YTHDF2 promotes DNA damage repair by positively regulating the histone methyltransferase SETDB1 in spermatogonia†.

Genomic integrity is critical for sexual reproduction, ensuring correct transmission of parental genetic information to the descendant. To preserve genomic integrity, germ cells have evolved multiple DNA repair mechanisms, together termed as DNA damage response. The RNA N6-methyladenosine is the most abundant mRNA modification in eukaryotic cells, which plays important roles in DNA damage response, and YTH N6-methyladenosine RNA binding protein 2 (YTHDF2) is a well-acknowledged N6-methyladenosine reader protein regulating the mRNA decay and stress response. Despite this, the correlation between YTHDF2 and DNA damage response in germ cells, if any, remains enigmatic. Here, by employing a Ythdf2-conditional knockout mouse model as well as a Ythdf2-null GC-1 mouse spermatogonial cell line, we explored the role and the underlying mechanism for YTHDF2 in spermatogonial DNA damage response. We identified that, despite no evident testicular morphological abnormalities under the normal circumstance, conditional mutation of Ythdf2 in adult male mice sensitized germ cells, including spermatogonia, to etoposide-induced DNA damage. Consistently, Ythdf2-KO GC-1 cells displayed increased sensitivity and apoptosis in response to DNA damage, accompanied by the decreased SET domain bifurcated 1 (SETDB1, a histone methyltransferase) and H3K9me3 levels. The Setdb1 knockdown in GC-1 cells generated a similar phenotype, but its overexpression in Ythdf2-null GC-1 cells alleviated the sensitivity and apoptosis in response to DNA damage. Taken together, these results demonstrate that the N6-methyladenosine reader YTHDF2 promotes DNA damage repair by positively regulating the histone methyltransferase SETDB1 in spermatogonia, which provides novel insights into the mechanisms underlying spermatogonial genome integrity maintenance and therefore contributes to safe reproduction.

DNA-translocation-independent role of INO80 remodeler in DNA damage repairs

Chromatin remodelers utilize ATP hydrolysis to reposition histone octamers on DNA, facilitating transcription by promoting histone displacements. Although their actions on chromatin with damaged DNA are assumed to be similar, the precise mechanisms by which they modulate damaged nucleosomes and their specific roles in DNA damage response (DDR) remain unclear. INO80-C, a versatile chromatin remodeler, plays a crucial role in the efficient repair of various types of damage. In this study, we have demonstrated that both abasic sites and UV-irradiation damage abolish the DNA translocation activity of INO80-C. Additionally, we have identified compromised ATP hydrolysis within the Ino80 catalytic subunit as the primary cause of the inhibition of DNA translocation, while its binding to damaged nucleosomes remains unaffected. Moreover, we have uncovered a novel function of INO80-C that operates independently of its DNA translocation activity, namely, its facilitation of apurinic/apyrimidinic (AP) site cleavage by the AP-endonuclease 1 (APE1). Our findings provide valuable insights into the role of the INO80-C chromatin remodeler in DDR, thereby advancing our understanding of chromatin remodeling during DNA damage repairs.

Translational control of SOG1 expression in response to replication stress in Arabidopsis

DNA damage, which may arise from cellular activities or be induced by genotoxic stresses, can cause genome instability and significantly affect plant growth and productivity. In response to genotoxic stresses, plants activate the cellular DNA damage response (DDR) to sense the stresses and activate downstream processes. The transcription factor SUPPRESSOR OF GAMMA RESPONSE 1 (SOG1), a functional counterpart of mammalian p53, is a master regulator of the DDR in plants. It is activated by various types of DNA lesions and can activate the transcription of hundreds of genes to trigger downstream processes, including cell cycle arrest, DNA repair, endoreplication, and apoptosis. Since SOG1 plays a crucial role in DDR, the activity of SOG1 must be tightly regulated. A recent study published in Plant Cell (Chen et al., Plant Cell koad126, 2023) reports a novel mechanism by which the ATR-WEE1 kinase module promotes SOG1 translation to fine-tune replication stress response.

Discovery and Evaluation of 3-Quinoxalin Urea Derivatives as Potent, Selective, and Orally Available ATM Inhibitors Combined with Chemotherapy for the Treatment of Cancer via Goal-Oriented Molecule Generation and Virtual Screening.

ATM plays an important role in DNA damage response and is considered a potential target in cancer therapies. In this study, a goal-directed molecular generation approach based on ligand similarity and target specificity was applied to sample active molecules, and they were screened virtually to identify the theoretical lead compound 7a, which was later shown to inhibit ATM adequately. However, there is a main concern about its poor metabolic stability in vitro. Subsequent optimization was performed to improve the potency and selectivity toward ATM and attenuate the hepatic clearance in vitro, culminating in the identification of 10r with nanomolar ATM inhibition, excellent cellular sensitivity to radiation and chemotherapy drugs, and impressive pharmacokinetic profiles. Furthermore, 10r combined with irinotecan demonstrated a synergistic antitumor efficacy in SW620 xenograft models, suggesting that it could be a promising candidate drug combined with chemotherapy for the treatment of cancer.