DNA Damage Repair Activity Research Articles

Electrochemical response mechanism of DNA damaged cells: DNA damage repair and purine metabolism activation

In modern society, due to the sharp increase in pollutants that cause DNA damage, there is a growing demand for innovative detection techniques and biomarkers. In this paper, the electrochemical behavior of HepG2 cells exposed to CdCl2 was investigated, and the electrochemical response mechanism of DNA damage was identified by exploring the correlation between the DNA damage response and purine metabolism. Western blot analysis revealed that the expression levels of ATM and Ku70 increased at 0.3 μM CdCl2, indicating a DNA damage response and activation of DNA repair processes. Simultaneously, elevated expression levels of PRPP aminotransferase, HPRT, and XOD were observed, leading to an increase in intracellular purine levels and electrochemical signals. The expression of Ku70 peaked at 0.5 μM CdCl2, indicating the highest DNA repair activity. The expression profiles of these purine metabolism proteins mirrored those of Ku70, suggesting a strong correlation between the activation of purine metabolism and DNA damage repair. Consistently, intracellular purine levels exhibited a similar trend, leading to corresponding changes in electrochemical signals. In summary, electrochemical using intracellular purines as biomarkers has the potential to emerge as a novel method for detecting early DNA damage.

Syntheses and Applications of Coumarin-Derived Fluorescent Probes for Real-Time Monitoring of NAD(P)H Dynamics in Living Cells across Diverse Chemical Environments.

Fluorescent probes play a crucial role in elucidating cellular processes, with NAD(P)H sensing being pivotal in understanding cellular metabolism and redox biology. Here, the development and characterization of three fluorescent probes, A, B, and C, based on the coumarin platform for monitoring of NAD(P)H levels in living cells are described. Probes A and B incorporate a coumarin-cyanine hybrid structure with vinyl and thiophene connection bridges to 3-quinolinium acceptors, respectively, while probe C introduces a dicyano moiety for replacement of the lactone carbonyl group of probe A which increases the reaction rate of the probe with NAD(P)H. Initially, all probes exhibit subdued fluorescence due to intramolecular charge transfer (ICT) quenching. However, upon hydride transfer by NAD(P)H, fluorescence activation is triggered through enhanced ICT. Theoretical calculations confirm that the electronic absorption changes upon the addition of hydride to originate from the quinoline moiety instead of the coumarin section and end up in the middle section, illustrating how the addition of hydride affects the nature of this absorption. Control and dose-response experiments provide conclusive evidence of probe C's specificity and reliability in identifying intracellular NAD(P)H levels within HeLa cells. Furthermore, colocalization studies indicate probe C's selective targeting of mitochondria. Investigation into metabolic substrates reveals the influence of glucose, maltose, pyruvate, lactate, acesulfame potassium, and aspartame on NAD(P)H levels, shedding light on cellular responses to nutrient availability and artificial sweeteners. Additionally, we explore the consequence of oxaliplatin on cellular NAD(P)H levels, revealing complex interplays between DNA damage repair, metabolic reprogramming, and enzyme activities. In vivo studies utilizing starved fruit fly larvae underscore probe C's efficacy in monitoring NAD(P)H dynamics in response to external compounds. These findings highlight probe C's utility as a versatile tool for investigating NAD(P)H signaling pathways in biomedical research contexts, offering insights into cellular metabolism, stress responses, and disease mechanisms.

Ku70 Binding to YAP Alters PARP1 Ubiquitination to Regulate Genome Stability and Tumorigenesis.

Yes-associated protein (YAP) is a central player in cancer development, with functions extending beyond its recognized role in cell growth regulation. Recent work has identified a link between YAP/transcriptional coactivator with PDZ-binding motif (TAZ) and the DNA damage response. Here, we investigated the mechanistic underpinnings of the cross-talk between DNA damage repair and YAP activity. Ku70, a key component of the nonhomologous end joining pathway to repair DNA damage, engaged in a dynamic competition with TEAD4 for binding to YAP, limiting the transcriptional activity of YAP. Depletion of Ku70 enhanced interaction between YAP and TEAD4 and boosted YAP transcriptional capacity. Consequently, Ku70 loss enhanced tumorigenesis in colon cancer and hepatocellular carcinoma (HCC) in vivo. YAP impeded DNA damage repair and elevated genome instability by inducing PARP1 degradation through the SMURF2-mediated ubiquitin-proteasome pathway. Analysis of samples from patients with HCC substantiated the link between Ku70 expression, YAP activity, PARP1 levels, and genome instability. In conclusion, this research provides insight into the mechanistic interactions between YAP and key regulators of DNA damage repair, highlighting the role of a Ku70-YAP-PARP1 axis in preserving genome stability. Significance: Increased yes-associated protein transcriptional activity stimulated by loss of Ku70 induces PARP1 degradation by upregulating SMURF2 to inhibit DNA damage, driving genome instability and tumorigenesis.

Abstract B003: Identification of novel genes that regulate aneuploidy tolerance by attenuating aneuploidy-induced stresses

Abstract Aneuploidy, an imbalanced number of chromosomes or chromosome arms, is the most common genetic aberration in cancer and is associated with a worse prognosis and advanced disease. However, in non-transformed cells, aneuploidy has a substantial fitness cost, leading to cell cycle arrest and cell death. This fitness cost is the result of several cellular stresses associated with aneuploidy, including proteotoxic, metabolic, mitotic and replication stress. Therefore, for aneuploidy to become beneficial, tolerance mechanisms that enable cancer cells to cope with aneuploidy-induced cellular stresses must come into play. Such mechanisms may uncover novel synthetic lethalities of aneuploid cancer cells. To this end, we systematically dissected the cellular mechanisms that facilitate aneuploidy tolerance. We combined large-scale analyses of gene expression, as well as genetic and pharmacological dependency datasets from human tumors, cancer cell lines and non-transformed cells, to identify genes and pathways associated with aneuploidy tolerance. We identified 55 genes associated (with high confidence) with aneuploidy tolerance. Gene set enrichment analysis (GSEA) revealed an enrichment for ribosome biogenesis and translation, DNA repair, replication stress and the p53 pathway. Interestingly, these pathways were all previously implicated with the aforementioned aneuploidy-induced cellular stresses. We plan to conduct a dependency mini-screen to validate the top ‘hits’ from our comprehensive bioinformatic analysis, and to explore the role of validated candidates in conferring aneuploidy tolerance. One of the top ‘hits’ of our exploratory analysis was a novel gene with an unclear cellular function. We experimentally confirmed that this gene was over-expressed in aneuploid cells, across several isogenic systems of matched diploid-aneuploid cell lines. Aneuploidy induction using MPS1 inhibitors led to its significant upregulation, demonstrating that its increased expression is a general feature of aneuploid cells. Mechanistically, we found that the novel gene had a role in regulating chromosome segregation, as its knockdown increased the rate of mitotic aberrations – as well as the sensitivity to mitotic checkpoint inhibition – resulting in increased chromosomal instability. We now study the molecular basis for the effect of this novel gene on aneuploidy tolerance. Specifically, we knocked it down in aneuploid cells, and over-expressed it in diploid cells, and we currently explore how these manipulations affect the above-mentioned aneuploidy tolerance pathways, namely replication stress, ribosome biogenesis, DNA damage repair and tp53 activation. In summary, we revealed a novel gene that is a key regulator of aneuploidy tolerance in cancer cells, likely due to its direct involvement in pathways required for the cellular coping with aneuploidy-induced stresses. Citation Format: Yonatan Eliezer, Adi V Tarrab, Tal Ben-Yishay, Hajime Okada, Tom Winkler, Uri Ben-David. Identification of novel genes that regulate aneuploidy tolerance by attenuating aneuploidy-induced stresses [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Expanding and Translating Cancer Synthetic Vulnerabilities; 2024 Jun 10-13; Montreal, Quebec, Canada. Philadelphia (PA): AACR; Mol Cancer Ther 2024;23(6 Suppl):Abstract nr B003.

Th2 Cells Are Associated with Tumor Recurrence Following Radiation.

The curative treatment of multiple solid tumors, including head and neck squamous cell carcinoma (HNSCC), utilizes radiation. The outcomes for HPV/p16-negative HNSCC are significantly worse than HPV/p16-positive tumors, with increased radiation resistance leading to worse locoregional recurrence (LRR) and ultimately death. This study analyzed the relationship between immune function and outcomes following radiation in HPV/p16-negative tumors to identify mechanisms of radiation resistance and prognostic immune biomarkers. A discovery cohort of 94 patients with HNSCC treated uniformly with surgery and adjuvant radiation and a validation cohort of 97 similarly treated patients were utilized. Tumor immune infiltrates were derived from RNAseq gene expression. The immune cell types significantly associated with outcomes in the discovery cohort were examined in the independent validation cohort. A positive association between high Th2 infiltration and LRR was identified in the discovery cohort and validated in the validation cohort. Tumor mutations in CREBBP/EP300 and CASP8 were significantly associated with Th2 infiltration. A pathway analysis of genes correlated with Th2 cells revealed the potential repression of the antitumor immune response and the activation of BRCA1-associated DNA damage repair in multiple cohorts. The Th2 infiltrates were enriched in the HPV/p16-negative HNSCC tumors and associated with LRR and mutations in CASP8, CREBBP/EP300, and pathways previously shown to impact the response to radiation.

DNA Repair in Nucleosomes: Insights from Histone Modifications and Mutants.

DNA repair pathways play a critical role in genome stability, but in eukaryotic cells, they must operate to repair DNA lesions in the compact and tangled environment of chromatin. Previous studies have shown that the packaging of DNA into nucleosomes, which form the basic building block of chromatin, has a profound impact on DNA repair. In this review, we discuss the principles and mechanisms governing DNA repair in chromatin. We focus on the role of histone post-translational modifications (PTMs) in repair, as well as the molecular mechanisms by which histone mutants affect cellular sensitivity to DNA damage agents and repair activity in chromatin. Importantly, these mechanisms are thought to significantly impact somatic mutation rates in human cancers and potentially contribute to carcinogenesis and other human diseases. For example, a number of the histone mutants studied primarily in yeast have been identified as candidate oncohistone mutations in different cancers. This review highlights these connections and discusses the potential importance of DNA repair in chromatin to human health.

Abstract 1987: PARP inhibitor (PARPi) rechallenge shows differential sensitivity in PARPi olaparib-resistant BRCA1-mutated (BRCA1m) high-grade serous ovarian cancer (HGSC)

Abstract Background: PARPis have changed the treatment paradigm in HGSC, particularly for women with BRCA mutations. PARPi, olaparib (O), is a standard of care maintenance therapy following platinum-based chemotherapy in newly diagnosed BRCA-mutated (BRCAm) HGSC. But patients ultimately develop resistance to O. We investigated whether rechallenge with different PARPi monotherapy could cause cytotoxicity in BRCAm HGSC after becoming O-resistant. We also aimed to identify possible mechanisms of actions of PARPi’s differential sensitivity. Methods: We developed a PARPi-resistant line (UWB-OlaJR) from BRCA1m PARPi-sensitive cells (UWB1.289) by gradient exposure of O with initial lower doses to a final concentration of 20 μM over 10 months. Four PARPis including O, niraparib (N), talazoparib (T), and veliparib (V) were tested. Cell growth was assessed using 5-day XTT and 10-day clonogenic assays. DNA damage and homologous recombination (HR) repair activity were evaluated using immunofluorescence (IF) staining of γH2AX and RAD51 foci, respectively. Replication fork (RF) dynamics was measured by DNA fiber assay. All data were repeated in triplicate and analyzed using t-test or one-way ANOVA. Data were shown as mean ± SD and P < 0.05 was considered statistically significant. Results: 5-day XTT assay shows a 53.7-fold increase in resistance to O in UWB-OlaJR relative to UWB1.289 (IC50 2.2 μM vs. 118.1 μM). Cross-resistance was observed with other 3 PARPis, showing increased IC50 values compared to its parental line (V: 23.4-fold, N: 160.5-fold, T: 229.6-fold). However, 10-day clonogenic assay showed no resistance against N (1.09-fold) and T (0.51-fold) in UWB-OlaJR, indicating differential sensitivity to different PARPis by a long-term cytotoxicity measure. Surprisingly, γH2AX foci did not increase in response to PARPis in UWB-OlaJR compared to UWB1.289 (O: 2.58-fold, V: 2.33-fold; N: 2.89-fold, T: 2.58-fold; all P < 0.05), suggesting possible restored DNA repair function. All four PARPis induced replication stress in both O-sensitive and -resistant cell lines as evidenced by decreased RF speed compared to untreated group (O: 0.57- and 0.7-fold, V: 0.68- and 0.74-fold, N: 0.47- and 0.47-fold, T: 0.47- and 0.52-fold; all P < 0.001). Notably, N and T treatments reduced fork speed to a greater extent than O and V in UWB-OlaJR. However, RF protection was not affected when UWB-OlaJR treated with different PARPis compared to UWB1.289 (O: 0.89-fold, V: 0.87-fold, N: 0.71-fold, T: 0.83-fold; all P < 0.05), suggesting that differential sensitivity to different PARPis was unlikely due to modulation of RF stabilization. Conclusions: Our findings demonstrate different PARPis may induce varied levels of cytotoxicity and replication stress in O-resistant BRCA1m HGSC, possibly via modulating alternative RF dynamics besides RF protection. Citation Format: Chi-Ting Shih, Tzu-Ting Huang, Jayakumar R. Nair, Jung-Min Lee. PARP inhibitor (PARPi) rechallenge shows differential sensitivity in PARPi olaparib-resistant BRCA1-mutated (BRCA1m) high-grade serous ovarian cancer (HGSC) [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 1987.

Stratification of glioma based on stemness scores in bulk and single-cell transcriptomes

BackgroundBrain tumours are known to have a high mortality and morbidity rate due to their localised and frequent invasive growth. The concept that glioma resistance could originate from the dissimilarity in the vulnerability of clonogenic glial stem cells to chemotherapeutic drugs and radiation has driven the scientific community to reexamine the comprehension of glioma growth and strategies that target these cells or modify their stemness. MethodsBased on the enrichment scores of 12 stemness signatures, we identified glioma subtypes in both tumour bulks and single cells by clustering analysis. Furthermore, we comprehensively compared molecular and clinical features among the glioma subtypes. ResultsConsistently, in seven different datasets, hierarchical clustering uncovered three subtypes of glioma, termed Stem-H, Stem-M, and Stem-L, with high, medium, and low stemness signatures, respectively. Stem-H and Stem-L exhibited the most unfavorable and favourable overall and disease-free survival, respectively. Stem-H showed the highest enrichment scores of the EMT, invasion, proliferation, differentiation, and metastasis processes signatures, while Stem-L displayed the lowest. Stem-H harboured a greater proportion of late-stage tumours compared to Stem-L. Moreover, Stem-H manifested higher tumour mutation burden, DNA damage repair and cell cycle activity, intratumour heterogeneity, and a more frequent incidence of TP53 and EGFR mutations than Stem-L. In contrast, Stem-L had higher O6-Methylguanine-DNA Methyltransferase (MGMT) methylation levels. ConclusionThe classification of glioma based on stemness may offer new insights into the biology of the tumour, as well as more accurate clinical management of the disease.

ITGB1 and DDR activation as novel mediators in acquired resistance to osimertinib and MEK inhibitors in EGFR-mutant NSCLC

Osimertinib is a third-generation tyrosine kinase inhibitor clinically approved for first-line treatment of EGFR-mutant non-small cell lung cancer (NSCLC) patients. Although an impressive drug response is initially observed, in most of tumors, resistance occurs after different time and an alternative therapeutic strategy to induce regression disease is currently lacking. The hyperactivation of MEK/MAPKs, is one the most common event identified in osimertinib-resistant (OR) NSCLC cells. However, in response to selective drug pressure, the occurrence of multiple mechanisms of resistance may contribute to treatment failure. In particular, the epithelial-to-mesenchymal transition (EMT) and the impaired DNA damage repair (DDR) pathways are recognized as additional cause of resistance in NSCLC thus promoting tumor progression. Here we showed that concurrent upregulation of ITGB1 and DDR family proteins may be associated with an increase of EMT pathways and linked to both osimertinib and MEK inhibitor resistance to cell death. Furthermore, this study demonstrated the existence of an interplay between ITGB1 and DDR and highlighted, for the first time, that combined treatment of MEK inhibitor with DDRi may be relevant to downregulate ITGB1 levels and increase cell death in OR NSCLC cells.

TMIC-76. GLIOBLASTOMA VESSEL CO-OPTION OCCURS AS A RESISTANCE MECHANISM TO CHEMORADIATION VIA INDUCTION OF A NOVEL CELL STATE

Abstract Glioblastoma (GB) is one of the deadliest types of human cancer. Despite a very aggressive treatment regime-including resection, chemo-radiation, its recurrence rate is more than 90%. Recurrence is mostly caused by highly resistant and invasive cells that spread from tumor bulk and are not removed by resection. To develop an effective therapeutic approach, we need to better understand underlying molecular and cellular mechanism driving therapy resistance and invasion in GB. To dynamically track the changes post-therapy and chemoradiation-resistant cells, we employed multiple bulk and single cell transcriptomics, phosphoproteome, in vitro and in vivo real time imaging, organotypic cultures, functional analysis, digital pathology and spatial transcriptomics on patient material and preclinical models of GB. We demonstrated that the chemoradiation and brain vasculature induce a transition to invasive functional cell state, which we rename as VC-Resist. Better cell survival, G2M arrest, senescence/stemness pathway induction, makes this GB state much more resistant. Notably, these GB cells are highly vessel co-opting allowing homing to perivascular niche, which in turn increases their transition to this cell state. Molecularly, the transition to VC-Resist cell state takes place through FGF-FGFR1 signaling that leads to activation of DNA damage repair, YAP and Rho pathways. These findings demonstrate that the perivascular niche and GB cell plasticity jointly generates a vicious loop that leads to resistance and brain infiltration during GB recurrence.

Loss of Function of SETD2 Tumor Suppressor in Chronic Myeloid Leukemia (CML) Progenitors Fosters Genomic Instability and Enhances Clonogenic Potential

BACKGROUND AND AIMS - Genomic instability is a hallmark of chronic myeloid leukemia (CML) cells since the chronic phase (CP) of the disease, and results in BCR::ABL1 mutations and/or additional genetic and genomic aberrations that may drive resistance to tyrosine kinase inhibitors (TKIs) and progression to blast crisis (BC). Genomic instability is also a feature of CML stem and progenitor cells and may contribute to their persistence. The SETD2 tumor suppressor codes for a protein that trimethylates histone H3 at lysine 36 (H3K36me3). In solid tumors, SETD2 loss of function has been shown to impair H3K36me3-mediated recruitment of DNA damage response components. We have recently reported that non genomic loss of function of SETD2 is a feature of BC CML and results from premature proteasome-mediated degradation of the SETD2 protein triggered by Aurora kinase A phosphorylation and MDM2 ubiquitination. In the present study, we aimed to assess SETD2/H3K36me3 status in CD34+ progenitors of CP CML patients (pts) and whether SETD2/H3K36me3 deficiency may play a role in genomic instability in CML models. METHODS - Western blotting (WB) was used to assess SETD2 protein expression and H3K36me3 as a surrogate marker of SETD2 function in the CD34+ cell fraction isolated from the bone marrow of 20 newly diagnosed CP CML pts and from a pool of healthy donors (HD). SETD2 forced expression in CD34+ progenitors from newly diagnosed CP CML pts and in the SETD2-deficient KCL22 cell line was performed by nucleofection. SETD2 knock-down in the SETD2-proficient LAMA84 cell line was performed by RNAi. Clonogenic capacity was evaluated by clonogenic assays. Chromatin immunoprecipitation sequencing (ChIP-seq) for H3K36me3 was performed on an Illumina HiSeq2000 with a min 50 million 150-bp single-end reads per replicate. High resolution karyotyping wias perfomed with Cytoscan HD arrays. DNA damage and DNA repair activation were assessed in primary samples and cell lines by WB and immunofluorescence (IF) using antibodies specific for phospho-H2AX, mismatch repair (MMR) and homologous recombination repair (HR) proteins. RESULTS - WB demonstrated a marked down-modulation of SETD2 expression, paralleled by H3K36me3 deficiency, in the CD34+ cells of all newly diagnosed CP CML pts as compared to the total mononuclear fraction and to CD34+ cells from HDs. To investigate whether SETD2 loss affects the activation and proficiency of HR and MMR, we used chronic exposure to UV rays or a single exposure to hydrogen peroxide (1mM for 30 and 60 min). Both induced DNA damage in SETD2 siRNA-depleted LAMA84 cells. Compared to parental cells, cells silenced for SETD2 failed to activate the ATM-dependent repair pathway. Moreover, we found that ATM inactivation prevents H2AX foci formation, associated with a loss of RAD51 and RAD54 (HR) and MSH6 (MMR) repair foci. To confirm the hypothesis that SETD2 is a tumor suppressor implicated in maintaining genomic stability in CML, we transfected SETD2-deficient KCL22 cells with an ectopic SETD2 plasmid. SETD2 forced expression was able to restore DNA damage response, as demonstrated by WB and IF detection of ATM, p95 and H2AX phosphorylation, BRCA1, BRCA2 and CtIP expression and finally RAD51 and RAD54 localization on HR repair foci observed after UV or hydrogen peroxide exposure. High-resolution karyotyping after DNA damage showed increased rate of DNA breakpoints in SETD2-deficient cells, preferentially occuring at loci where H3K36me3 marks were lost as assessed by ChiP-seq. In line with the effects observed in cell line models, forced expression of SETD2 in CD34+ cells from 5 CP CML pts was found to restore proliferation control, since a >50% reduction in clonogenic potential was observed after nucleofection. CONCLUSIONS - Our findings demonstrate that SETD2 is a bona fide tumor suppressor in CML progenitors and establish a functional link between SETD2 loss of function and genomic instability. SETD2 inactivation may thus play a pivotal role in the harmful cascade of events that may foster drug resistance and ultimately lead to disease progression. Since SETD2 loss of function in CML is mediated by post-translation mechanisms, hence is reversible, therapeutic strategies aimed at interfering with these mechanisms may restore proliferation control and interrupt this cascade. Supported by AIRC IG 2019 (23001) and by Italian Ministry of Health, “Bando Ricerca Finalizzata 2016”, project GR-2016-02364880.

OS07.5.A GLIOBLASTOMA VESSEL CO-OPTION AND TRANSITION TO A RESISTANT CELL STATE ARE INDUCED BY CHEMORADIATION

Abstract BACKGROUND Glioblastoma (GB) is one of the deadliest types of human cancer. Despite a very aggressive treatment regime, including resection of the tumor, radiation, and chemotherapy, the recurrence rate is more than 90%. Recurrence is mostly caused by the regrowth of highly invasive and resistant cells that have spread from the tumor bulk and are not removed by resection. To develop an effective therapeutic approach, we need to better understand the underlying molecular and cellular mechanisms of GB chemoradiation resistance and tumor spreading. MATERIAL AND METHODS To dynamically follow the changes occurring in GB post-therapy and investigate its relationship with vascular microenvironment, we employed multiple bulk and single-cell RNA-Seq analyses, phosphoproteome, in vitro and in vivo real-time imaging, organotypic cultures and functional assays, digital pathology, and spatial transcriptomics on patient material or preclinical models of GB. RESULTS We demonstrated that chemoradiation and the brain vasculature induce a transition to a functional cell state, which we named VC-Resist. This cell state is midway through the transcriptomic axis between proneural and mesenchymal GB cells and is closer to the AC/MES-like state. Better cell survival, G2M-arrest, activation of senescence/stemness pathways make this GB cell state more resistant to therapy. Notably, these persister GB cells are highly vessel co-opting, allowing homing to the perivascular niche, which, in turn, increases their transition to this cell state and resistance to therapy. Molecularly, the transition to the VC-Resist cell state is driven by FGF-FGFR1 signaling, which leads to the activation of DNA damage repair and YAP1 pathways. CONCLUSION These findings demonstrate that the perivascular niche and GB cell plasticity jointly generate a vicious loop that leads to resistance to therapy and brain infiltration during GB recurrence. SUPPORT This work was supported by the European Research Council (ERC) under the European Union’s Horizon 2020 (Grant Agreement No. 805225), the INSERM-CNRS ATIP-Avenir grant, the NanoTheRad grant from Paris-Saclay University, Fondation ARC pour la recherche sur le cancer, Campus France and Canceropole Ile-de-France (2022-1-EMERG-06-ICR-1).

Nitric Oxide Prevents Glioblastoma Stem Cells' Expansion and Induces Temozolomide Sensitization.

Glioblastoma multiforme (GBM) has high mortality and recurrence rates. Malignancy resilience is ascribed to Glioblastoma Stem Cells (GSCs), which are resistant to Temozolomide (TMZ), the gold standard for GBM post-surgical treatment. However, Nitric Oxide (NO) has demonstrated anti-cancer efficacy in GBM cells, but its potential impact on GSCs remains unexplored. Accordingly, we investigated the effects of NO, both alone and in combination with TMZ, on patient-derived GSCs. Experimentally selected concentrations of diethylenetriamine/NO adduct and TMZ were used through a time course up to 21 days of treatment, to evaluate GSC proliferation and death, functional recovery, and apoptosis. Immunofluorescence and Western blot analyses revealed treatment-induced effects in cell cycle and DNA damage occurrence and repair. Our results showed that NO impairs self-renewal, disrupts cell-cycle progression, and expands the quiescent cells' population. Consistently, NO triggered a significant but tolerated level of DNA damage, but not apoptosis. Interestingly, NO/TMZ cotreatment further inhibited cell cycle progression, augmented G0 cells, induced cell death, but also enhanced DNA damage repair activity. These findings suggest that, although NO administration does not eliminate GSCs, it stunts their proliferation, and makes cells susceptible to TMZ. The resulting cytostatic effect may potentially allow long-term control over the GSCs' subpopulation.

Genomic Profiling of Lower-Grade Gliomas Subtype with Distinct Molecular and Clinicopathologic Characteristics via Altered DNA-Damage Repair Features.

Lower WHO grade II and III gliomas (LGGs) exhibit significant genetic and transcriptional heterogeneity, and the heterogeneity of DNA damage repair (DDR) and its relationship to tumor biology, transcriptome, and tumor microenvironment (TME) remains poorly understood. In this study, we conducted multi-omics data integration to investigate DDR alterations in LGG. Based on clinical parameters and molecular characteristics, LGG patients were categorized into distinct DDR subtypes, namely, DDR-activated and DDR-suppressed subtypes. We compared gene mutation, immune spectrum, and immune cell infiltration between the two subtypes. DDR scores were generated to classify LGG patients based on DDR subtype features, and the results were validated using a multi-layer data cohort. We found that DDR activation was associated with poorer overall survival and that clinicopathological features of advanced age and higher grade were more common in the DDR-activated subtype. DDR-suppressed subtypes exhibited more frequent mutations in IDH1. In addition, we observed significant upregulation of activated immune cells in the DDR-activated subgroup, which suggests that immune cell infiltration significantly influences tumor progression and immunotherapeutic responses. Furthermore, we constructed a DDR signature for LGG using six DDR genes, which allowed for the division of patients into low- and high-risk groups. Quantitative real-time PCR results showed that CDK1, CDK2, TYMS, SMC4, and WEE1 were significantly upregulated in LGG samples compared to normal brain tissue samples. Overall, our study sheds light on DDR heterogeneity in LGG and provides insight into the molecular pathways of DDR involved in LGG development.

Role of ionizing radiation activated NRF2 in lung cancer radioresistance

Radiotherapies are commonly used to target remaining tumor niches after surgery of solid tumors but are restricted due to therapeutic resistance. Several pathways of radioresistance have been reported in various cancers. This study investigates the pivotal role of Nuclear factor-erythroid 2–related factor 2 (NRF2) in the activation of DNA damage repair in lung cancer cells after x-rays exposure. To explore the NRF2 activation after ionizing irradiations, this study uses a knockdown of NRF2, which shows potential DNA damage after x-rays irradiation in lung cancers. This work further shows that NRF2 knockdown disrupts damaged DNA repair by inhibiting DNA-dependent protein kinase catalytic subunit. At the same time, NRF2 knockdown by shRNA considerably disparate homologous recombination by interfering with Rad51 expression. Further investigation of the associated pathway reveals that NRF2 activation mediates DNA damage response via the mitogen-activated protein kinase (MAPK) pathway as the knockout of NRF2 directly enhances intracellular MAPK phosphorylation. Similarly, both N-acetylcysteineand constitutive knockout of NRF2 disrupt DNA-dependent protein kinase catalytic subunit, while NRF2 knockout failed to upregulate Rad51 expression after irradiation in-vivo. Taken together, these findings advocate NRF2 plays a critical role in the development of radioresistance by upregulating DNA damage response via the MAPK pathway, which can be of great significance.

Abstract LB228: Replication stress activates the DNA damage response and contributes to lapatinib resistance in HER2-positive SK-BR-3 cells

Abstract Background: Lapatinib is a small molecular inhibitor of HER2 and EGFR tyrosine kinases, which is approved for HER2-positive metastatic breast cancer as second line treatment. Significant proportion of patients experience disease progression due to acquired resistance. Activation of DNA damage repair (DDR) is one of the drug-resistance mechanism, however, the impact of DDR on sensitivity to lapatinib is unclear. Thus, lapatinib resistance mechanism was explored from the standpoint of DDR activation. Methods: Acquired lapatinib-resistant (LR) SK-BR-3 cell lines were generated by continuously exposing to lapatinib, starting with 30 nmol/L and incrementally increasing to 10 μmol/L over 7 months. MTT assay was used to confirm lapatinib sensitivity. Cell cycle progression was analyzed using BrdU assay. Replication fork speed and stalled fork were analyzed by DNA fiber assay. Expression of the molecules was examined using Western blotting, immunofluorescence assay and transcriptome data analysis. DNA strand breaks and repair efficacy were evaluated through alkaline comet assay. Results: G1/S phase transition was increased and early/late S phase population was increased in SK-BR-3 LR cells. Replication fork speed was accelerated and replication stress are elevated in SK-BR-3 LR cells. p-Chk1, Rad51, Rad51B, Rad51C and XRCC3 were upregulated in SK-BR-3 LR cells. After irradiation or treatment with ATR inhibitor, γ-H2AX was continuously increased in parental cells. In contrast, γ-H2AX did not change significantly in SK-BR-3 LR cells, and Chk1 was activated after irradiation or treatment with ATR inhibitor. Tail of comet disappeared at early time point in in SK-BR-3 LR cells after induction of DNA damage compared with parental cells. These results demonstrated that DDR was activated and DNA damage repair capacity was enhanced in LR cells. Conclusion: Replication stress is elevated in SK-BR-3 LR cells. Up-regulation of molecules involved in the homologous recombination repair pathway was observed in SK-BR-3 LR cells. Moreover, DNA repair capacity was increased in SK-BR-3 LR cells. These data suggested that activation of DNA damage repair pathway caused by replication stress contributes to lapatinib resistance. Citation Format: So Hyeon Kim, Ahrum Min, Seongyeong Kim, Yu Jin Kim, Sujin Ham, Hae Min Hwang, Minyoung Lee, Changyun Lee, Jinyong Kim, Dae-Won Lee, Kyung-Hun Lee, Seock-Ah Im. Replication stress activates the DNA damage response and contributes to lapatinib resistance in HER2-positive SK-BR-3 cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 2 (Clinical Trials and Late-Breaking Research); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(8_Suppl):Abstract nr LB228.

Abstract 6106: Epigenetic-miRNA regulatory circuit confers ovarian cancer chemoresistance through RAD18-mediated DNA damage tolerance and repair signaling

Abstract Epithelial ovarian cancer (EOC) is the deadliest gynecological malignancy. This cancer typically is not detected, 70-80% of patients, until an advanced stage (stage III-IV). The standard of care OC entails complete surgical resection of all visible abdominal-pelvic tumors, followed by platinum-based chemotherapy combined with a taxane. New recommendations for patients responding to adjuvant therapy is to include a PARP inhibitor with or without bevacizumab for maintenance therapy. Despite initial responses, the majority of stage 3 & 4 more than 70% of OC patients experience recurrent disease. Frequently, individuals become resistant to these treatments. This dreadful circumstance highlights the pressing need to identify the molecular mechanisms underlying the disease's aggressive nature upon recurrence and the development of treatment resistance. Several genetic and epigenetic factors have been linked to the reprogramming of tumor cells by controlling the pattern of transcriptional and post-transcriptional gene expression. Particularly, the miRNA-mediated regulatory circuit plays a significant role in tumor progression and therapeutic responses. Our analysis of miRNA expression signature in human ovarian cancer cell line panel showed little to no expression of miR221_5p and a corresponding increase in DNA damage response and repair gene RAD18 expression. RAD18 plays a critical role in cellular DNA damage tolerance and repair activity against chemotherapeutics, including platinum drugs. Similarly, loss of miRNA221_5p is associated with aggressive tumor cell growth, stemness, chemoresistance to platinum drugs, and poor prognosis in several cancers. Based on this information, we have hypothesized that miR221_5p regulates RAD18-mediated DNA damage tolerance and repair and may offer novel therapeutic intervention to overcome EOC chemoresistance. Our experimental data confers that miR221_5p post-transcriptionally regulates RAD18 by binding to its 3’-UTR region and restores OC cell sensitivity to platinum drugs. Mechanistically, our results demonstrate that miRNA221_5p epigenetically regulates RAD18-mediated DNA damage tolerance and homologous recombination repair and could be a novel therapeutic to overcome OC chemoresistance. Collectively, our studies identify a novel chemotherapy-induced epigenetic modulator in OC therapeutic resistance and offer novel miRNA 221-5p-mediated therapeutic intervention for the treatment of chemoresistant OC and to prevent disease recurrence. Citation Format: Tasmin Rahman Omy, Chinnadurai Mani, Komaraiah Palle, Mark Reedy. Epigenetic-miRNA regulatory circuit confers ovarian cancer chemoresistance through RAD18-mediated DNA damage tolerance and repair signaling. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 6106.

Degradation of Ubiquitin-Editing Enzyme A20 following Autophagy Activation Promotes RNF168 Nuclear Translocation and NF-κB Activation in Lupus Nephritis

The correlation between ubiquitin-editing enzyme A20 and E3 ubiquitin ligase ring finger protein (RNF) 168 has been reported to be critical for repair of DNA damage. This study aimed to evaluate the potential role of this regulatory interaction in the pathogenesis of lupus nephritis (LN). The expression of RNF168 and A20 was measured in the podocytes derived from MRL/lpr murine lupus as well as patients with LN. Cell-based studies using renal podocytes bearing silenced RNF168, over-expressed A20, autophagy-related gene (Atg) 5 (a ubiquitin-like modifier), or silenced Atg5 were used to assess the effect of RNF168, A20, and Atg5 on DNA damage repair and nuclear factor kappa-B (NF-κB) activation in LN. It was found that podocyte autophagy was over-activated in LN and the abnormal podocyte autophagy led to down-regulation of A20, up-regulation of RNF168, and activation of the NF-κB. RNF168 silencing or A20 restoration inhibited activation of NF-κB pathway and promoted repair of DNA damage, where the level of autophagy was not changed. Activated A20 in podocytes weakened the promoting action of cell autophagy on RNF168. The current results suggest that RNF168 dysfunction may be involved in the pathogenesis of LN via down-regulation of A20 expression. Autophagy and RNF168 may be therapeutic targets for the prevention and treatment of LN.

CXCR4 inhibitor, AMD3100, down-regulates PARP1 expression and Synergizes with olaparib causing severe DNA damage in BRCA-proficient triple-negative breast cancer

Poly ADP-ribose polymerase inhibitor (PARPi) treatment is effective in triple-negative breast cancer (TNBC) with BRCA mutation. However, its efficacy in BRCA-proficient TNBC remains unexplored. It is, therefore, an exciting proposition to broaden the indication of PARPi for BRCA-proficient TNBC patients. Chemokine receptor (CXCR4) is a transmembrane G protein-coupled receptor, which is involved in cell migration, proliferation, apoptosis, and damage repair, and it initiates many signalling pathways. Although administration of CXCR4 inhibitor alone is not ideal as a target drug, it can play a strong synergistic role in combination with other drugs. We explored the effect of CXCR4 and PARP1 on tumour cell proliferation, migration, metastasis, and apoptosis in vitro and in vivo and found that a CXCR4 inhibitor, AMD3100, enhanced the anti-tumour effect of PARP1 inhibitor, olaparib, on BRCA-proficient TNBC. When CXCR4 was inhibited and silenced, DNA damage repair and DNA replication fork activity were suppressed by up-regulating caspase-3-mediated increase in PARP1 cleavage; in combination with the inhibition of PARP1, AMD3100 resulted in the accumulation of fatal DNA damage and induction of apoptosis. This combination regimen can be effective against BRCA-proficient TNBC.

DNA methylation regulator-mediated modification pattern defines tumor microenvironment immune infiltration landscape in colon cancer.

Emerging evidence implies a non-negligible role of DNA methylation in tumor immunity, however, its comprehensive impact on tumor microenvironment (TME) formation and immune activation remains unclear. In this study, we integrated 24 DNA methylation regulators among 754 colon cancer patients to distinguish different modification patterns via an unsupervised clustering method, and explore their TME immune characteristics. Three DNA methylation modification patterns with distinct prognosis and biological behaviors were identified, consistent with three known phenotypes of immune-inflamed, immune-excluded, and immune-desert. We then determined a DNA methylation gene signature and constructed a DNA methylation score (DMS) to quantify modification patterns individually through principal component analysis algorithms. DMS-low group had characteristics of specific molecular subtypes, including microsatellite instability, CpG island methylator phenotype positive, and mutant BRAF, presented by increased mutation burden, activation of DNA damage repair and immune-related pathways, highly TME immune cells infiltration, and hence, a preferable prognosis. Further, low DMS was also demonstrated to be correlated to better response and prolonged survival of anti-PD-L1 antibody, indicating that DMS could be considered as an effective predictive tool for immunotherapy. In conclusion, our work presented a landscape of different DNA methylation modification patterns, and their vital role in the formation of TME diversity and complexity, which could help to enhance understanding of TME immune infiltration characteristics and more importantly, guide immunotherapy strategies more effectively and personalized.