DNA Interstrand Cross-links Research Articles

A Photoinducible DNA Cross-Linking Agent with Potent Cytotoxicity and Selectivity Toward Triple-Negative Breast Cancer Cell Line.

DNA interstrand cross-links (ICLs) are the sources of the cytotoxicity of many anticancer agents. Selenium compounds showed great potential as anticancer drugs. In this work, we synthesized a binaphthalene analog 1 containing phenyl selenide (-SePh) as the leaving group and investigated its photochemical reactivity toward DNA as well as its cytotoxicity and selectivity. DNA ICLs were not observed with binaphthalene phenyl selenide 1 without UV irradiation, while ∼15% DNA ICL products were detected with UV irradiation, indicating a photoresponsive property of 1. The trapping reactions with TEMPO and MeONH2, respectively, suggested that free radicals and carbocations are involved in the DNA cross-linking process induced by the photoirradiation of 1. The photochemical reactivity of 1 toward DNA was sequence-dependent. DNA interstrand cross-linking occurred mainly at dG/dC base pairs, while monoalkylations occurred at dGs and dAs. Additionally, we have demonstrated that 1 alone without UV irradiation did not inhibit cancer cell growth even with a concentration of 100 μM, while the cytotoxicity of 1 toward cancer cells was significantly enhanced upon 350 nm irradiation with an IC50 of 1.7 μM. No cytotoxicity was observed toward normal epithelial MCF 10A cells, regardless of UV exposure, in the presence or absence of 1. The alkaline comet assay suggested that the photoinduced cytotoxicity of 1 is correlated to cellular DNA damage. Normal cells showed higher levels of GSH than cancer cells and exhibited efficient DNA repair mechanisms, which can both prevent and repair potential DNA damage induced by 1, contributing to the selective cytotoxicity of the prodrug toward triple-negative breast cancer cells.

The novel DNA cross-linking agent KL-50 is active against patient-derived models of new and recurrent post-temozolomide mismatch repair-deficient glioblastoma.

Acquired resistance to temozolomide (TMZ) chemotherapy due to DNA mismatch repair (MMR) enzyme deficiency is a barrier to improving outcomes for IDH wild-type glioblastoma (GBM) patients. KL-50 is a new imidazotetrazine-based therapeutic designed to induce DNA interstrand cross links, and subsequent double-stranded breaks, in an MMR-independent manner in cells with O-6-Methylguanine-DNA Methyltransferase (MGMT) deficiency. Previous research showed its efficacy against LN229 glioma cells with MMR and MGMT knockdown. Its activity against patient-derived GBM that model post-TMZ recurrent tumors is unclear. We created MMR-deficient GBM patient-derived xenografts through exposure to TMZ, followed by treatment with additional TMZ or KL-50. We also generated isogenic, MSH6 knockout patient-derived GBM and tested them for sensitivity to TMZ and KL-50. KL-50 extended the median survival of mice intracranially engrafted with either patient-derived TMZ-naïve GBM6 or TMZ-naïve GBM12 by 1.75-fold and 2.15-fold, respectively (p<0.0001). A low dose (4 Gy) of fractionated RT further extended the survival of KL-50 treated GBM12 mice (median survival=80 days for RT+ KL-50 vs. 71 days KL-50 alone, P=0.018). KL-50 also extended the median survival of mice engrafted with post-TMZ, MMR-deficient GBM6R-m185 (140 days for KL-50 vs. 37 days for vehicle, p<0.0001). MSH6-KO increased TMZ IC50 for GBM6 and GBM12 cultures by >5-fold and >12-fold for cell death and live cell count outputs, respectively. In contrast, MSH6-KO actually decreased KL-50 IC50 by 10-80%. KL-50-based compounds are a promising new strategy for the treatment of MGMT-deficient, MMR-deficient GBM that recurs after frontline TMZ.

CTNI-72. VAL-083 IN PATIENTS WITH RECURRENT GLIOBLASTOMA TREATED UNDER EXPANDED ACCESS PROGRAM

Abstract BACKGROUND Current standard-of-care for glioblastoma (GBM) includes surgery followed by chemoradiation with temozolomide (TMZ) followed by adjuvant TMZ. Almost all GBM patients experience disease progression despite upfront standard-of-care treatment, with a median overall survival of 3-9 months after first recurrence. There are limited treatment options at the time of disease progression, apart from participation in clinical trials. VAL-083 is a bi-functional DNA damaging agent that induces inter-strand DNA cross-links at N7-guanine in a manner independent of O6-methylguanine-DNA-methyltransferase (MGMT). METHODS Under an Expanded Access program (NCT03138629), we used VAL-083 to treat 30 patients with recurrent GBM who were not eligible to participate in clinical trials. Here we report safety and efficacy results. RESULTS Four patients (13.3%) with leptomeningeal disease were excluded from efficacy evaluation. All patients received chemoradiation with TMZ. Twelve (12/26; 46.2%) patients had ≥2 recurrences and 9/26 (34.6%) had prior lomustine. All tumors had ≥1 mutation, with 14/26 (53.8%) having ≥5 mutations; one patient had a hypermutator phenotype. The most common mutations were TERT (57.7%), PTEN (38.5%), TP53 (26.9%), and NF1 (26.9%). All patients started treatment with VAL-083 at 30 mg/m2/day administered on 3 consecutive days every 21 days. Eight (8/26; 30.8%) patients received bevacizumab concurrently with VAL-083. Eight (8/26; 30.8%) patients had a VAL-083 dose reduction. Patients received a median of 3.0 (5-95pth 1-10) VAL-083 treatment cycles. Median progression free survival (mPFS) and median overall survival (mOS) from last disease progression was 5.1 (95%CI: 2.7-7.2) and 9.8 (95%CI: 5.3-16.4) months, respectively. VAL-083 was well-tolerated and the most frequent adverse events were consistent with prior experience, i.e., thrombocytopenia and neutropenia. CONCLUSIONS Use of VAL-083 continues to show benefit in the treatment of GBM patients who have had multiple recurrences and have limited therapeutic options.

CTNI-71. RELA FUSION-POSITIVE EPENDYMOMA, DIFFUSE MIDLINE GLIOMA AND GRADE 4 IDH MUTANT ASTROCYTOMA TREATED WITH VAL-083 UNDER EXPANDED ACCESS: CASE REPORTS

Abstract RELA fusion-positive ependymoma is associated with supratentorial location, higher WHO grade and poor prognosis. Diffuse Midline Glioma (DMG) is a relatively rare CNS tumor, originating in the midline location of the brain. Surgical intervention is restricted to biopsy and radiation. Grade-4 astrocytoma, is highly aggressive with rapid progression. Standard treatment includes surgery and radiation therapy, with limited systemic options other than clinical trials for recurrent disease. VAL-083 is a DNA-targeting agent which rapidly induces inter-strand DNA cross-links at O6- and N7-guanine inducing double-strand breaks causing cell death and acts independent of MGMT DNA repair in high-grade gliomas. We report on 4 patients who had recent disease progression and unmethylated MGMT promoter status treated with VAL-083 under an expanded access program: Case #1: a 47-yo male diagnosed with IDHwt, RELA fusion-positive ependymoma. Case #2: an 18-yo male diagnosed with IDHwt, MAP2K1 and RELA fusion-positive ependymoma. Case #3: a 25-yo male diagnosed with IDHmut Grade 4 astrocytoma, with ATRX, INPP4A, RET and TP53 mutations. Case #4: a 21 yo male diagnosed with IDHwt DMG of the brain stem. All patients had multiple recurrences, received radiation and multiple systemic treatment regimens. They received VAL-083 (30 mg/m2 for 3 days every 21 days) under an expanded access program. Patients with ependymoma received 6 and 5 cycles of VAL-083, (case 1 and 2, respectively), while the patients with IDHmut Gr 4. astrocytoma and DMG received 5 and 18 cycles of VAL-083, respectively. No adverse events were reported and no dose reductions were required. These cases highlight that VAL-83 may be a treatment option for recurrent RELA fusion-positive ependymoma, Gr4. IDHmut astrocytoma, and DMG refractory to other treatment regimens. Additional outcomes related to these cases will be presented at the meeting. Clinicaltrials.gov Identifier: NCT03138629. The treatment plans for the EA patients were approved by MD Anderson Cancer Center IRB

CTNI-73. ASSESSMENT OF MOLECULAR ALTERATIONS IN NEWLY DIAGNOSED GBM MGMT-UNMETHYLATED PATIENTS TREATED WITH VAL-083

Abstract Glioblastoma (GBM) commonly features molecular alterations in the TERT, EGFR, PTEN, and TP53 genes, which contributes to uncontrolled cell growth, evasion of apoptosis, and enhanced tumor cell survival. VAL-083 is a bi-functional DNA-targeting agent which rapidly induces inter-strand DNA cross-links at N7 and O6-guanine inducing double-strand breaks causing cell death independently of MGMT DNA repair and DNA mismatch repair deficiency. VAL-083 was evaluated in an open-label, biomarker-driven, phase 2 trial in MGMT-unmethylated, bevacizumab-naïve GBM patients. The molecular profile of tumors from a newly diagnosed GBM patient subgroup who received VAL-083 alone after chemo-radiation with concurrent TMZ, was determined in order to correlate with clinical outcomes. Thirty-four (34/36, 94.4%) patients who received 30 mg/m2 VAL-083 (days 1-3 of 21-day cycle) had available next-generation sequencing data on their primary tissue. Patient median age was 54.8 years (5-95pth: 29.8-66.0), median KPS was 90 (5-95pth: 80-100) and 58.8% were males. The median number of cycles of VAL-083 was 7.5 (5-95pth: 1-12). There were 5 dose reductions due to toxicity. The median time to progression (PFS) and overall survival (OS) were 9.2 mo (95%CI: 7.6-10.2) and 16.5 mo (95%CI: 13.3-19.0), respectively. The mean number of molecular alterations was 3.9 (5-95pth 1-8). Six (17.6%) patients had gene fusions. The most common molecular alterations were TERT promoter (91.2%), EGFR amplification (amp) (52.9%), PTEN (50.0%), EGFR (20.6%), and TP53 (20.6%). Additional alterations (in ≥2 patients; 6%) included EGFR-EGFR (EGFRvIII), BRCA2, CDKN2A/B, CDK4/6 amp, MDM2/4 amp, NF1, NOTCH1, PIK3R1 and RB1. While TP53 mutations showed a trend as predictors for time to progression (P 0.027), this was not observed with OS. None of the molecular alterations were predictors of number of treatment cycles or dose reductions. No specific molecular alterations were identified that predicted either improved or poorer patient outcome, during treatment with VAL-083. Clinicaltrials.gov identifier: NCT02717962.

EXTH-23. NEW DNA-CROSSLINKING CHEMOTHERAPY IS EFFECTIVE AGAINST POST-TEMOZOLOMIDE MISMATCH REPAIR-DEFICIENT PATIENT-DERIVED HYPERMUTANT GLIOMAS

Abstract The DNA mismatch repair (MMR) pathway triggers glioblastoma (GBM) apoptosis when base mismatches induced by the alkylating agent temozolomide (TMZ) cannot be repaired. GBMs often develop hypermutation and resistance to TMZ through acquired inactivation of DNA MMR enzymes (MSH2, MSH6, MLH1, PMS2). A newly developed therapeutic, KL-50, fluoro-ethylates DNA bases, leading to DNA inter-strand cross-links. This form of DNA damage triggers MMR-independent apoptosis. Thus, KL-50 can target MMR-deficient tumor cells. Previous work showed that KL-50 is effective against GBM cell lines that were rendered TMZ-resistant through shRNA knockdown of MMR genes (PMID 35901163). In those studies, KL-50 was most effective when used in combination with an MGMT enzyme inhibitor, or in MGMT-deficient cells. Here, we extend those findings with a preclinical trial of KL-50 in GBM patient-derived xenografts (PDX), including PDX models of post-TMZ GBM that acquired MMR mutations and hypermutation through serial TMZ exposure (PMID 31852831). Among TMZ-naïve PDX, KL-50 extended survival of engrafted mice by 24 days for GBM6 (partially MGMT-deficient), and by 38 days for GBM12 PDX (fully MGMT-deficient) compared to vehicle (p&amp;lt;0.0001, Log-Rank). Combining KL-50 with 4.0 Gy radiation further extended survival of GBM12 mice (9 days, p=0.02), but not GBM6 mice. With engraftments of GBM6R-m185, a post-TMZ, MMR-deficient derivative of GBM6, 14/14 (100%) of KL-50 treated mice are still alive 60 days post-engraftment compared to 0/13 (0%) of vehicle control mice (median survival 37 days, p&amp;lt;0.0001, experiment ongoing). Complementary in vitro studies showed that GBM6R-m185 cells are more sensitive to KL-50 than TMZ at matched concentrations of 50µM (p=0.001, one-way ANOVA) and 100µM (p=0.047). These data demonstrate the potential of KL-50 in treating post-TMZ MMR-deficient recurrent gliomas.

Germline Variants in DNA Interstrand-Cross Link Repair Genes May Contribute to Increased Susceptibility for Serrated Polyposis Syndrome.

Serrated polyposis syndrome (SPS) is characterized by the development of multiple colorectal serrated polyps and increased predisposition to colorectal cancer (CRC). However, the molecular basis of SPS, especially in cases presenting family history of SPS and/or polyps and/or CRC in first-degree relatives (SPS-FHP/CRC), is still poorly understood. In a previous study, we proposed the existence of two molecular entities amongst SPS-FHP/CRC families, proximal/whole-colon and distal SPS-FHP/CRC, according to the preferential location of lesions and somatic events involved in tumor initiation. In the present study, we aimed to investigate these distinct subgroups of SPS patients in a larger cohort at the germline level and to identify the genetic defects underlying an inherited susceptibility for these two entities. Next-generation sequencing was performed using multigene analysis with a custom-designed panel in a Miseq platform in 60 SPS patients (with and without/unknown FHP/CRC). We found germline pathogenic variants in 6/60 patients (ATM, FANCM, MITF, RAD50, RAD51C, and RNF43). We also found variants of unknown significance (VUS), with prediction of probable damaging effect in 23/60 patients (ATM, BLM, BRCA1, FAN1, ERCC2, ERCC3, FANCA, FANCD2, FANCL, MSH2, MSH6, NTHL1, PALB2, PDGFRA, PMS2, PTCH1, RAD51C, RAD51D, RECQL4, TSC2, WRN, and XRCC5 genes). Most variants were detected in gene coding for proteins of the Fanconi Anemia (FA) pathway involved in the DNA Interstrand-Cross Link repair (ICLR). Notably, variants in ICLR genes were significantly more frequent in the proximal/whole-colon than in the distal subgroup [15/44 (34%) vs 1/16 (6%), p = 0.025], as opposed to the non-ICLR genes that were slightly more frequent in the distal group [8/44 (18%) vs. 5/16 (31%), p > 0.05]. Germline defects in the DNA-ICLR genes may contribute to increased serrated colorectal polyps/carcinoma risk in SPS patients, particularly in proximal/whole-colon SPS. The inclusion of DNA-ICLR genes in the genetic diagnosis of SPS patients, mainly in those with proximal/whole-colon lesions, should be considered and validated by other studies. In addition, patients with germline defects in the DNA-ICLR genes may be more sensitive to treatment with platinum-based therapeutics, which can have implications in the clinical management of these patients.

Stepwise phosphorylation and SUMOylation of PIDD1 drive PIDDosome assembly in response to DNA repair failure

SUMOylation regulates numerous cellular stress responses, yet targets in the apoptotic machinery remain elusive. We show that a single, DNA damage-induced monoSUMOylation event controls PIDDosome (PIDD1/RAIDD/caspase-2) formation and apoptotic death in response to unresolved DNA interstrand crosslinks (ICLs). SUMO-1 conjugation occurs on conserved K879 in the PIDD1 death domain (DD); is catalyzed by PIAS1 and countered by SENP3; and is triggered by ATR phosphorylation of neighboring T788 in the PIDD1 DD, which enables PIAS1 docking. Phospho/SUMO-PIDD1 proteins are captured by nucleolar RAIDD monomers via a SUMO-interacting motif (SIM) in the RAIDD DD, thus compartmentalizing nascent PIDDosomes for caspase-2 recruitment. Denying SUMOylation or the SUMO-SIM interaction spares the onset of PIDDosome assembly but blocks its completion, thus eliminating the apoptotic response to ICL repair failure. Conversely, removal of SENP3 forces apoptosis, even in cells with tolerable ICL levels. SUMO-mediated PIDDosome control is also seen in response to DNA breaks but not supernumerary centrosomes. These results illuminate PIDDosome formation in space and time and identify a direct role for SUMOylation in the assembly of a major pro-apoptotic device.

UVSSA facilitates transcription-coupled repair of DNA interstrand crosslinks

DNA interstrand crosslinks (ICLs) are covalent bonds between bases on opposing strands of the DNA helix which prevent DNA melting and subsequent DNA replication or RNA transcription. Here, we show that Ultraviolet Stimulated Scaffold Protein A (UVSSA) is critical for ICL repair in human cells, at least in part via the transcription coupled ICL repair (TC-ICR) pathway. Inactivation of UVSSA sensitizes human cells to ICL-inducing drugs, and delays ICL repair. UVSSA is required for replication-independent repair of a single ICL in a fluorescence-based reporter assay. UVSSA localizes to chromatin following ICL damage, and interacts with transcribing Pol II, CSA, CSB, and TFIIH. Specifically, UVSSA interaction with TFIIH is required for ICL repair and transcription inhibition blocks localization of transcription coupled repair factors to ICL damaged chromatin. Finally, UVSSA expression positively correlates with ICL-based chemotherapy resistance in human cancer cell lines. Our data strongly suggest that UVSSA is a novel ICL repair factor functioning in TC-ICR. These results provide further evidence that TC-ICR is a bona fide ICL repair mechanism that contributes to crosslinker drug resistance independently of replication-coupled ICL repair.

B-351 Genotoxic Producing Escherichia coli Protects and Promotes Breast Adenocarcinoma

Abstract Background Recent studies have linked certain colibactin producing subphylas of E. coli to colorectal cancer. The bacterium synthesizes colibactin via the pks genomic island containing a series of clbA to clbS genes. The genotoxin causes inter-strand DNA cross-links, which lead to double strand breaks and promotion of colorectal adenocarcinoma. The published studies have prioritized the colorectal regions of the body where E. coli is commonly found, but none have identified the same genotoxic relationship with other types of adenocarcinoma. In this study, we evaluate DNA damage and cellular changes of mammary breast tissue based on high and low levels of colibactin producing E. coli exposure. The goal is to evaluate if colibactin can affect cells in the mammary breast tissue promoting breast adenocarcinoma growth. Methods Two cell lines were acquired from ATCC: primary mammary epithelial cells (PCS-600-010) and MCF-7 breast adenocarcinoma cells (HTB-22). Both cell lines were split into six culture flasks and maintained until ∼80% confluence was reached using the ATCC cell culture protocols. Once all the flasks had reached the target confluence, they were divided into exposure groups of high and low concentrations of colibactin producing E. coli, a group of non-colibactin producing E. coli, a group exposed only to phosphate buffered saline, and a control group with no exposure. Cellular morphology was observed using light microscopy before, after exposure, and every 5 minutes up to 15 minutes. E. coli and colibactin DNA concentrations were quantified using quantitative polymerase chain reaction. Genomic DNA was extracted from each group of cells. The DNA from each group was whole genome sequenced and analyzed for genomic variation. Results The normal cells exposed to E. coli showed immediate lysing and continued to lyse after a 5 minute incubation; however, the adenocarcinoma positive cells showed no lysing up to 30 minutes incubation. Sequencing results show genomic variation between the groups and specific break points associated with the E. coli exposed groups. Conclusions Our results show that the presence of E. coli with mammary breast tissue can destroy normal tissue, promote lysis resistance, and allow adenocarcinoma cells to continue to grow. The colibactin producing E. coli does cause double stranded breaks and can lead to cell death. This new information points out a critical need to monitor the microbiome and infection levels of people at risk or in early stages of cancer to prevent adenocarcinoma growth and destruction of normal tissue. This study indicates that colibactin producing E. coli may play a larger role in tissue damage and promotion of other types of cancer. More research is needed to elucidate the molecular pathway and mechanisms of colibactin, which will lead to new diagnostics or therapeutics that monitor E. coli levels or inhibit colibactin’s toxic effects.

A non-tethering role for the Drosophila linker domain in promoting damage resolution.

DNA polymerase theta ( ) is an error-prone translesion polymerase that becomes crucial for DNA double-strand break repair when cells are deficient in homologous recombination or non-homologous end joining. In some organisms, also promotes tolerance of DNA interstrand crosslinks. Due to its importance in DNA damage tolerance, is an emerging target for treatment of cancer and disease. Prior work has characterized the functions of the helicase-like and polymerase domains, but the roles of the linker domain are largely unknown. Here, we show that the Drosophila melanogaster linker domain promotes egg development and is required for tolerance of DNA double-strand breaks and interstrand crosslinks. While a linker domain with scrambled amino acid residues is sufficient for DNA repair, replacement of the linker with part of the Homo sapiens linker or a disordered region from the FUS RNA-binding protein does not restore function. These results demonstrate that the linker domain is not simply a random tether between the helicase-like and polymerase domains. Furthermore, they suggest that intrinsic amino acid residue properties, rather than protein interaction motifs, are more critical for linker functions in DNA repair.

Lonidamine Increases the Cytotoxic Effect of 1-[(4-Amino-2-methyl-5-pyrimidinyl)methyl]-3-(2-chloroethyl)-3-nitrosourea via Energy Inhibition, Disrupting Redox Homeostasis, and Downregulating MGMT Expression in Human Lung Cancer Cell Line.

Lung cancer ranks as the second most diagnosed cancer and the leading cause of cancer-related deaths worldwide. Novel chemotherapeutic strategies are crucial to efficiently target tumor cells while minimizing toxicity to normal cells. In this study, we proposed a combination strategy using energy blocker lonidamine (LND) and cytotoxic drug nimustine (ACNU, 1-[(4-amino-2-methyl-5-pyrimidinyl)methyl]-3-(2-chloroethyl)-3-nitrosourea) to enhance the killing of a human lung cancer cell line and investigated the potential chemo-sensitizing mechanism of LND. LND was found to remarkably increase the cytotoxicity of ACNU to A549 and H1299 cells without significantly affecting normal lung BEAS2B cells. The combination of LND and ACNU also produced significant effects on cell apoptosis, colony formation, cell migration, and invasion assays compared to single drug treatment. Mechanistically, LND decreased intracellular ATP levels by inhibiting glycolysis and inducing mitochondrial dysfunction. Furthermore, the combination of LND and ACNU could intensify cellular oxidative stress, decrease cellular GSH contents, and increase reactive oxygen species (ROS) production. Notably, LND alone dramatically downregulated the expression of DNA repair protein MGMT (O6-methylguanine-DNA methyltransferase), enhancing DNA interstrand cross-link formation induced by ACNU. Overall, LND represents a potential chemo-sensitizer to enhance ACNU therapy through energy inhibition, disrupting redox homeostasis and downregulating MGMT expression in human lung cancer cell line under preclinical and clinical background.

Deciphering the role of post-translational modifications in fanconi anemia proteins and their influence on tumorigenesis.

Fanconi anemia (FA) is an autosomal or X-linked human disease, characterized by bone marrow failure, cancer susceptibility and various developmental abnormalities. So far, at least 22 FA genes (FANCA-W) have been identified. Germline inactivation of any one of these FA genes causes FA symptoms. Proteins encoded by FA genes are involved in the Fanconi anemia pathway, which is known for its roles in DNA inter-strand crosslinks (ICLs) repair. Besides, its roles in genome maintenance upon replication stress has also been reported. Post-translational modifications (PTMs) of FA proteins, particularly phosphorylation and ubiquitination, emerge as critical determinants in the activation of the FA pathway during ICL repair or replication stress response. Consequent inactivation of the FA pathway engenders heightened chromosomal instability, thereby constituting a genetic susceptibility conducive to cancer predisposition and the exacerbation of tumorigenesis. In this review, we have combined recent structural analysis of FA proteins and summarized knowledge on the functions of different PTMs in regulating FA pathways, and discuss potential contributions stemming from mutations at PTMs to the genesis and progression of tumorigenesis.

The role of SLFN11 in DNA replication stress response and its implications for the Fanconi anemia pathway

Fanconi anemia (FA) is a hereditary disorder characterized by a deficiency in the repair of DNA interstrand crosslinks and the response to replication stress. Endogenous DNA damage, most likely caused by aldehydes, severely affects hematopoietic stem cells in FA, resulting in progressive bone marrow failure and the development of leukemia. Recent studies revealed that expression levels of SLFN11 affect the replication stress response and are a strong determinant in cell killing by DNA-damaging cancer chemotherapy. Because SLFN11 is highly expressed in the hematopoietic system, we speculated that SLFN11 may have a significant role in FA pathophysiology. Indeed, we found that DNA damage sensitivity in FA cells is significantly mitigated by the loss of SLFN11 expression. Mechanistically, we demonstrated that SLFN11 destabilizes the nascent DNA strands upon replication fork stalling. In this review, we summarize our work regarding an interplay between SLFN11 and the FA pathway, and the role of SLFN11 in the response to replication stress.

Structure and in vivo psoralen DNA crosslink repair activity of mycobacterial Nei2.

Mycobacterium smegmatis Nei2 is a monomeric enzyme with AP β-lyase activity on single-stranded DNA. Expression of Nei2, and its operonic neighbor Lhr (a tetrameric 3'-to-5' helicase), is induced in mycobacteria exposed to DNA damaging agents. Here, we find that nei2 deletion sensitizes M. smegmatis to killing by DNA inter-strand crosslinker trimethylpsoralen but not to crosslinkers mitomycin C and cisplatin. By contrast, deletion of lhr sensitizes to killing by all three crosslinking agents. We report a 1.45 Å crystal structure of recombinant Nei2, which is composed of N and C terminal lobes flanking a central groove suitable for DNA binding. The C lobe includes a tetracysteine zinc complex. Mutational analysis identifies the N-terminal proline residue (Pro2 of the ORF) and Lys51, but not Glu3, as essential for AP lyase activity. We find that Nei2 has 5-hydroxyuracil glycosylase activity on single-stranded DNA that is effaced by alanine mutations of Glu3 and Lys51 but not Pro2. Testing complementation of psoralen sensitivity by expression of wild-type and mutant nei2 alleles in ∆nei2 cells established that AP lyase activity is neither sufficient nor essential for crosslink repair. By contrast, complementation of psoralen sensitivity of ∆lhr cells by mutant lhr alleles depended on Lhr's ATPase/helicase activities and its tetrameric quaternary structure. The lhr-nei2 operon comprises a unique bacterial system to rectify inter-strand crosslinks.IMPORTANCEThe DNA inter-strand crosslinking agents mitomycin C, cisplatin, and psoralen-UVA are used clinically for the treatment of cancers and skin diseases; they have been invaluable in elucidating the pathways of inter-strand crosslink repair in eukaryal systems. Whereas DNA crosslinkers are known to trigger a DNA damage response in bacteria, the roster of bacterial crosslink repair factors is incomplete and likely to vary among taxa. This study implicates the DNA damage-inducible mycobacterial lhr-nei2 gene operon in protecting Mycobacterium smegmatis from killing by inter-strand crosslinkers. Whereas interdicting the activity of the Lhr helicase sensitizes mycobacteria to mitomycin C, cisplatin, and psoralen-UVA, the Nei2 glycosylase functions uniquely in evasion of damage caused by psoralen-UVA.

The critical role of the iron-sulfur cluster and CTC components in DOG-1/BRIP1 function in Caenorhabditis elegans.

FANCJ/BRIP1, initially identified as DOG-1(Deletions Of G-rich DNA) in Caenorhabditiselegans, plays a critical role in genome integrity by facilitating DNA interstrand cross-link repair and resolving G-quadruplex structures. Its function is tightly linked to a conserved [4Fe-4S] cluster-binding motif, mutations of which contribute to Fanconi anemia and various cancers. This study investigates the critical role of the iron-sulfur (Fe-S) cluster in DOG-1 and its relationship with the cytosolic iron-sulfur protein assembly targeting complex (CTC). We found that a DOG-1 mutant, expected to be defective in Fe-S cluster binding, is primarily localized in the cytoplasm, leading to heightened DNA damage sensitivity and G-rich DNA deletions. We further discovered that the deletion of mms-19, a nonessential CTC component, also resulted in DOG-1 sequestered in cytoplasm and increased DNA damage sensitivity. Additionally, we identified that CIAO-1 and CIAO-2B are vital for DOG-1's stability and repair functions but unlike MMS-19 have essential roles in C. elegans. These findings confirm the CTC and Fe-S cluster as key elements in regulating DOG-1, crucial for genome integrity. Additionally, this study advances our understanding of the CTC's role in Fe-S protein regulation and development in C. elegans, offering a model to study its impact on multicellular organism development.

A Nutrigenomic View on the Premature-Aging Disease Fanconi Anemia.

Fanconi anemia, a rare disorder with an incidence of 1 in 300,000, is caused by mutations in FANC genes, which affect the repair of DNA interstrand crosslinks. The disease is characterized by congenital malformations, bone marrow failure within the first decade of life, and recurrent squamous cell carcinomas of the oral cavity, esophagus, and anogenital regions starting around age 20. In this review, we propose that Fanconi anemia should be considered a premature-aging syndrome. Interestingly, the onset and severity of the life-limiting clinical features of Fanconi anemia can be influenced by lifestyle choices, such as a healthy diet and physical activity. These factors shape the epigenetic status of at-risk cell types and enhance the competence of the immune system through nutritional signaling. Fanconi anemia may serve as a model for understanding the aging process in the general population, addressing research gaps in its clinical presentation and suggesting prevention strategies. Additionally, we will discuss how the balance of genetic and environmental risk factors-affecting both cancer onset and the speed of aging-is interlinked with signal transduction by dietary molecules. The underlying nutrigenomic principles will offer guidance for healthy aging in individuals with Fanconi anemia as well as for the general population.

Gemcitabine as chemotherapy of head and neck cancer in Fanconi anemia patients

Fanconi anemia (FA) is a rare hereditary disease resulting from an inactivating mutation in the FA/BRCA pathway, critical for the effective repair of DNA interstrand crosslinks (ICLs). The disease is characterized by congenital abnormalities, progressing bone marrow failure, and an increased risk of developing malignancies early in life, in particular head and neck squamous cell carcinoma (HNSCC). While ICL-inducing cisplatin combined with radiotherapy is a mainstay of HNSCC treatment, cisplatin is contra-indicated for FA-HNSCC patients. This dilemma necessitates the identification of novel treatment modalities tolerated by FA-HNSCC patients. To identify druggable targets, an siRNA-based genetic screen was previously performed in HNSCC-derived cell lines from FA and non-FA tumor origin. Here, we report that the Ribonucleotide Reductase (RNR) complex, consisting of the RRM1 and RRM2 subunits, was identified as a therapeutic target for both, FA and non-FA HNSCC. While non-FA HNSCC cells responded differentially to RNR depletion, FA-HNSCC cells were consistently found hypersensitive. This insight was confirmed pharmacologically using 2′, 2′-difluoro 2′deoxycytidine (dFdC), also known as gemcitabine, a clinically used nucleotide analog that is a potent inhibitor of the RNR complex. Importantly, while cisplatin exposure displayed severe, long-lasting toxicity on the hematopoietic stem and progenitor compartments in Fancg−/− mice, gemcitabine was well tolerated and had only a mild, transient impact. Taken together, our data implicate that gemcitabine-based chemoradiotherapy could serve as an alternative HNSCC treatment in Fanconi patients, and deserves clinical testing.

The splicing factor CCAR1 regulates the Fanconi anemia/BRCA pathway

The twenty-three Fanconi anemia (FA) proteins cooperate in the FA/BRCA pathway to repair DNA interstrand cross-links (ICLs). The cell division cycle and apoptosis regulator 1 (CCAR1) protein is also a regulator of ICL repair, though its possible function in the FA/BRCA pathway remains unknown. Here, we demonstrate that CCAR1 plays a unique upstream role in the FA/BRCA pathway and is required for FANCA protein expression in human cells. Interestingly, CCAR1 co-immunoprecipitates with FANCA pre-mRNA and is required for FANCA mRNA processing. Loss of CCAR1 results in retention of a poison exon in the FANCA transcript, thereby leading to reduced FANCA protein expression. A unique domain of CCAR1, the EF hand domain, is required for interaction with the U2AF heterodimer of the spliceosome and for excision of the poison exon. Taken together, CCAR1 is a splicing modulator required for normal splicing of the FANCA mRNA and other mRNAs involved in various cellular pathways.

An interstrand DNA crosslink glycosylase aids Acinetobacter baumannii pathogenesis

Maintenance of DNA integrity is essential to all forms of life. DNA damage generated by reaction with genotoxic chemicals results in deleterious mutations, genome instability, and cell death. Pathogenic bacteria encounter several genotoxic agents during infection. In keeping with this, the loss of DNA repair networks results in virulence attenuation in several bacterial species. Interstrand DNA crosslinks (ICLs) are a type of DNA lesion formed by covalent linkage of opposing DNA strands and are particularly toxic as they interfere with replication and transcription. Bacteria have evolved specialized DNA glycosylases that unhook ICLs, thereby initiating their repair. In this study, we describe AlkX, a DNA glycosylase encoded by the multidrug resistant pathogen Acinetobacter baumannii. AlkX exhibits ICL unhooking activity similar to that of its Escherichia coli homolog YcaQ. Interrogation of the in vivo role of AlkX revealed that its loss sensitizes cells to DNA crosslinking and impairs A. baumannii colonization of the lungs and dissemination to distal tissues during pneumonia. These results suggest that AlkX participates in A. baumannii pathogenesis and protects the bacterium from stress conditions encountered in vivo. Consistent with this, we found that acidic pH, an environment encountered during host colonization, results in A. baumannii DNA damage and that alkX is induced by, and contributes to, defense against acidic conditions. Collectively, these studies reveal functions for a recently described class of proteins encoded in a broad range of pathogenic bacterial species.