Reactive Oxygen Species-induced DNA Damage Research Articles

Efficient drug supply in stem cell cytosol via pore-forming saponin nanoparticles promotes in vivo osteogenesis and bone regeneration

Directional differentiation of stem cells is a key step in stem cell therapy. In this study, we developed saponin-based nanoparticles (Ad-SNPs) containing dexamethasone (Dex) and alpha-lipoic acid (ALA) to promote osteogenic differentiation of human mesenchymal stem cells (hMSCs) and bone regeneration. The Ad-SNPs can achieve rapid cellular uptake through a pore-forming effect without cytotoxic cationic charges. They also provide extended retention in cell cytosol due to their uptake route. These properties are advantageous in efficiently supplying drugs to the hMSCs. The combination of Dex and ALA facilitated mitochondrial fusion and prevented reactive oxygen species–induced DNA damage. It also helped to preserve mitochondrial dynamics, and the efficient supply of it provided by the Ad-SNPs induced differentiation of hMSCs into osteoblasts. The Ad-SNPs showed outstanding performance in osteoblast differentiation, maturation, and mineralization in 3D culture compared with NPs without saponin and with free drugs. When Ad-SNP-treated hMSCs were tested in a rat femoral bone defect model, they showed the fastest regeneration of bones and complete repair in the shortest period among all groups. To the best of our knowledge, this study is the first application of pore-forming saponin-based NPs with rapid cellular uptake and extended retention to stem cell therapy, and we demonstrated their promising potential in bone regeneration and efficient delivery of Dex and ALA.

Antiproliferative Mechanisms of a Polyphenolic Combination of Kaempferol and Fisetin in Triple-Negative Breast Cancer Cells

Herein, we investigate the combinatorial therapeutic effects of naturally occurring flavonoids kaempferol (K) and fisetin (F) on triple-negative breast cancer (TNBC: MDA-MB-231 cell line). Dose-dependent MTT assay results show that K and F exhibited cytotoxicity in MDA-MB-231 cells at 62 and 75 μM (IC50), respectively, after 24 h. However, combined K + F led to 40% and more than 50% TNBC cell death observed at 10 and 20 μM, respectively, which revealed the synergistic association of both. The combination of K and F was determined to be more effective in inhibiting cell viability than either of the agents alone. The morphological changes associated with significant apoptotic cell death were observed under a fluorescent microscope, strongly supporting the synergistic association between K and F. We also proposed that combining the effects of both polyphenols, as opposed to their individual effects, would increase their in vitro efficacy. Furthermore, we assessed the cell death pathway by the combinational treatment via reactive oxygen species-induced DNA damage and the mitochondrially mediated apoptotic pathway. This study reveals the prominent synergistic role of phytochemicals, which helps in elevating the therapeutic efficacy of dietary nutrients and that anticancer effects may be a result of nutrients that act in concert.

Inhibition of GABAA receptors in intestinal stem cells prevents chemoradiotherapy-induced intestinal toxicity.

Lethal intestinal tissue toxicity is a common side effect and a dose-limiting factor in chemoradiotherapy. Chemoradiotherapy can trigger DNA damage and induce P53-dependent apoptosis in LGR5+ intestinal stem cells (ISCs). Gamma-aminobutyric acid (GABA) and its A receptors (GABAAR) are present in the gastrointestinal tract. However, the functioning of the GABAergic system in ISCs is poorly defined. We found that GABAAR α1 (GABRA1) levels increased in the murine intestine after chemoradiotherapy. GABRA1 depletion in LGR5+ ISCs protected the intestine from chemoradiotherapy-induced P53-dependent apoptosis and prolonged animal survival. The administration of bicuculline, a GABAAR antagonist, prevented chemoradiotherapy-induced ISC loss and intestinal damage without reducing the chemoradiosensitivity of tumors. Mechanistically, it was associated with the reduction of reactive oxygen species-induced DNA damage via the L-type voltage-dependent Ca2+ channels. Notably, flumazenil, a GABAAR antagonist approved by the U.S. Food and Drug Administration, rescued human colonic organoids from chemoradiotherapy-induced toxicity. Therefore, flumazenil may be a promising drug for reducing the gastrointestinal side effects of chemoradiotherapy.

Nerolidol inhibits proliferation of leiomyoma cells via reactive oxygen species-induced DNA damage and downregulation of the ATM/Akt pathway

Nerolidol (3,7,11-trimethyl-1,6,10-dodecatrien-3-ol), a sesquiterpene alcohol present in aromatic essential oils of numerous plants, has been reported to possess anticancer activity. The potential therapeutic effect of nerolidol on uterine fibroids (UF), the most common benign tumor of the uterus worldwide, is unknown. In this study, we examined the anti-UF potential of nerolidol in ELT3 cells, a rat leiomyoma cell line widely used as an in vitro model, to identify the potential therapeutic agents for UF. We observed that treatment with cis- or trans-nerolidol inhibited cell proliferation in a dose-dependent manner and induced cell cycle arrest in the G1 phase, which was accompanied by reduction in Akt phosphorylation and downregulation of cyclin D1, cyclin-dependent kinase 4 (CDK4), and CDK6 protein expression. The proliferation-inhibiting activity of nerolidol correlated with the generation of intracellular reactive oxygen species (ROS), which was suppressed by N-acetyl-l-cysteine, a ROS inhibitor. Nerolidol treatment also increased the percentage of cells for which tail moment could be calculated using an alkaline comet assay, and induced p-γH2AXser139 expression, which indicated induction of DNA damage. We also observed downregulation of ATM and its phosphorylation after nerolidol treatment; furthermore, treatment with KU-55933, an ATM kinase inhibitor, mimicked the inhibitory effects of nerolidol treatment on cell proliferation and Akt phosphorylation. In conclusion, nerolidol displayed anti-UF activity in a leiomyoma cell model via ROS-induced DNA damage and G1 phase cell cycle arrest by inhibiting the expression and activation of the ATM/Akt pathway. Our data suggests that nerolidol is a potential therapeutic agent for UF.

The oxidative stress responses caused by phthalate acid esters increases mRNA abundance of base excision repair (BER) genes in vivo and in vitro

The base excision repair (BER) pathway is an important defense response to oxidative DNA damage. It is known that exposures to phthalate esters (PAEs), including Dibutyl phthalate (DBP), Mono-(2-ethylhexyl) phthalate (MEHP), and Di-(2-ethylhexyl) phthalate (DEHP), cause reactive oxygen species-induced DNA damage and oxidative stress. Here, we determined the mRNA levels of BER pathway-related genes (ogg1, nthl1, apex1, parp1, xrcc1, lig3, ung, pcna, polb, pold, fen1, and lig1), pro-apoptotic gene (bax), and apoptotic suppressor gene (bcl2) in different PAEs-exposed zebrafish larvae and HEK293T cells. Further investigations were performed to examine reactive oxygen species (ROS) accumulation, superoxide dismutase (SOD) activity, developmental toxicity, and cell viability after PAEs exposure in vivo and in vitro. The results showed that PAEs exposure can induce developmental abnormalities in zebrafish larvae, and inhibit cell viability in HEK293T cells. Additionally, we found that PAEs exposure results in the accumulation of ROS and the inhibition of SOD activation in vivo and in vitro. Notably, the mRNA levels of BER pathway-related genes (OGG1, NTHL1, APEX1, XRCC1, UNG, POLB, POLD, FEN1) were significantly upregulated after DBP or MEHP exposure, whereas the mRNA levels of NTHL1, UNG, POLB, POLD, and FEN1 were significantly altered in DEHP-treated HEK293T cells. In zebrafish, the mRNA levels of ogg1, pcna, fen1 and lig1 genes were increased after DBP or DEHP exposure, whereas the mRNA levels of nthl1, apex1, parp1, lig3, pcna and polb were decreased after MEHP exposure, respectively. Thus, our findings indicated that PAEs exposure can induce developmental toxicity, cytotoxicity, and oxidative stress, as well as activate BER pathway in vivo and in vitro, suggesting that BER pathway might play critical roles in PAEs-induced oxidative stress through repairing oxidative DNA damage.

Janus Kinase Mutations in Mice Lacking PU.1 and Spi-B Drive B Cell Leukemia through Reactive Oxygen Species-Induced DNA Damage.

Precursor B cell acute lymphoblastic leukemia (B-ALL) is caused by genetic lesions in developing B cells that function as drivers for the accumulation of additional mutations in an evolutionary selection process. We investigated secondary drivers of leukemogenesis in a mouse model of B-ALL driven by PU.1/Spi-B deletion (Mb1-CreΔPB). Whole-exome-sequencing analysis revealed recurrent mutations in Jak3 (encoding Janus kinase 3), Jak1, and Ikzf3 (encoding Aiolos). Mutations with a high variant-allele frequency (VAF) were dominated by C→T transition mutations that were compatible with activation-induced cytidine deaminase, whereas the majority of mutations, with a low VAF, were dominated by C→A transversions associated with 8-oxoguanine DNA damage caused by reactive oxygen species (ROS). The Janus kinase (JAK) inhibitor ruxolitinib delayed leukemia onset, reduced ROS and ROS-induced gene expression signatures, and altered ROS-induced mutational signatures. These results reveal that JAK mutations can alter the course of leukemia clonal evolution through ROS-induced DNA damage.

The vanillin derivative VND3207 protects intestine against radiation injury by modulating p53/NOXA signaling pathway and restoring the balance of gut microbiota

The intestine is a highly radiosensitive tissue that is susceptible to structural and functional damage due to systemic as well as localized radiation exposure. Unfortunately, no effective prophylactic or therapeutic agents are available at present to manage radiation-induced intestinal injuries. We observed that the vanillin derivative VND3207 improved the survival of lethally irradiated mice by promoting intestinal regeneration and increasing the number of surviving crypts. Pre-treatment with VND3207 significantly increased the number of Lgr5+ intestinal stem cells (ISCs) and their daughter cells, the transient Ki67+ proliferating cells. Mechanistically, VND3207 decreased oxidative DNA damage and lipid peroxidation and maintained endogenous antioxidant status by increasing the level of superoxide dismutase and total antioxidant capacity. In addition, VND3207 maintained appropriate levels of activated p53 that triggered cell cycle arrest but were not sufficient to induce NOXA-mediated apoptosis, thus ensuring DNA damage repair in the irradiated small intestinal crypt cells. Furthermore, VND3207 treatment restores the intestinal bacterial flora structures altered by TBI exposure. In conclusion, VND3207 promoted intestinal repair following radiation injury by reducing reactive oxygen species-induced DNA damage and modulating appropriate levels of activated p53 in intestinal epithelial cells.

Insufficiency of melatonin in follicular fluid is a reversible cause for advanced maternal age-related aneuploidy in oocytes

Age-related decline in female fertility is a common feature that occurs in the fourth decade of women as a result of a reduction in both oocyte quality and quantity [1]. However, strategies to prevent the deterioration of maternal aged oocytes and relevant mechanisms are still underexplored. Here, we find that the reduced abundance of melatonin in the follicular fluid highly correlates with the advanced maternal age-related aneuploidy. Of note, we show that exposure of oocytes from aged mice both in vitro and in vivo to exogenous melatonin not only eliminates the accumulated reactive oxygen species-induced DNA damage and apoptosis, but also suppresses the occurrence of aneuploidy caused by spindle/chromosome defect that is frequently observed in aged oocytes. Importantly, we reveal that melatonin supplementation reverses the defective phenotypes in aged oocytes through a Sirt1/Sod2-dependent mechanism. Inhibition of Sirt1 activity abolishes the melatonin-mediated improvement of aged oocyte quality. Together our findings provide evidence that supplementation of melatonin is a feasible way to protect oocytes from advanced maternal age-related meiotic defects and aneuploidy, demonstrating the potential for improving the quality of oocytes from aged women and the efficiency of assisted reproductive technology.

Abstract 1365: NR1D1 enhances reactive oxygen species-induced DNA damage by inhibition of PARP1

Abstract Breast cancer is the most commonly diagnosed cancer in women worldwide. Cancer cells produce higher levels of intracellular reactive oxygen species (ROS) than their normal counterparts, because of their accelerated metabolism, mitochondrial dysfunction, and antioxidant deficit. The oxidative stress in cancer cells may provide clinical benefits, which can be associated with a better response to anticancer therapies. Therefore, identifying the regulatory pathway of oxidative stress in cancer cells is important in the development of therapeutic targets that enhance sensitivity to ROS-generating anticancer therapies. In this study, we identified that nuclear receptor subfamily 1, group D, member 1 (NR1D1; Rev-erbα) inhibited DNA repair of ROS-induced DNA damage in breast cancer cells. NR1D1 interacted with poly(ADP-ribose) polymerase 1 (PARP1) and subsequently inhibited catalytic activity of PARP1. NR1D1 enhanced accumulation of oxidative DNA damage, which increased sensitivity of breast cancer cells to the ROS-induced cell death. Our findings suggest that NR1D1 may provide better therapeutic options for breast cancer treatment, especially in those patients treated with ROS-inducing chemotherapeutic agents. Citation Format: Na-Lee Ka, Tae-Young Na, Mi-Ock Lee. NR1D1 enhances reactive oxygen species-induced DNA damage by inhibition of PARP1 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1365.

P-339 - Modulation of redox homeostasis in grade IV glioblastoma multiforme

A carbazole alkaloid, mahanine, isolated from an Indian Medicinal plant enhances intracellular reactive oxygen species (ROS) by the inhibition of complex-III of mitochondrial electron transport chain (ETC). Elevated ROS mediates apoptosis by damaging cellular homeostasis in several malignancies with various genetic mutations in multidimensional facets. We observed oxidative damage-induced dysfunction of oncogenic chaperone Hsp90 in pancreatic cancer, leukemia and activation of PTEN in colon cancer. This accumulated ROS induced DNA damage response, that mediated Chk1/Chk2 upregulation and activation which were essential factors for the G0/G1 arrest in glioblastoma multiforme (GBM) without effecting normal astrocytes. During G0/G1 arrest, cyclin D1/cyclin D3, CDK4/CDK6 and CDC25A were also downregulated. Mahanine-induced ROS in hypoxia responsible for higher G0/G1 arrest. Mahanine-treated G0/G1 arrested cells were less potent to form xenograft tumor. They exhibited reduced ability to migrate and form intracellular tubelike structures and became susceptible to differentiation. Astrocyte-like cells were generated from the epithelial lineage. Thus, we established that complex-III of ETC is one of the possible potential targets of this nontoxic chemotherapeutic molecule.

The Toxicological Mechanisms of Environmental Soot (Black Carbon) and Carbon Black: Focus on Oxidative Stress and Inflammatory Pathways.

The environmental soot and carbon blacks (CBs) cause many diseases in humans, but their underlying mechanisms of toxicity are still poorly understood. Both are formed after the incomplete combustion of hydrocarbons but differ in their constituents and percent carbon contents. For the first time, “Sir Percival Pott” described soot as a carcinogen, which was subsequently confirmed by many others. The existing data suggest three main types of diseases due to soot and CB exposures: cancer, respiratory diseases, and cardiovascular dysfunctions. Experimental models revealed the involvement of oxidative stress, DNA methylation, formation of DNA adducts, and Aryl hydrocarbon receptor activation as the key mechanisms of soot- and CB-induced cancers. Metals including Si, Fe, Mn, Ti, and Co in soot also contribute in the reactive oxygen species (ROS)-mediated DNA damage. Mechanistically, ROS-induced DNA damage is further enhanced by eosinophils and neutrophils via halide (Cl− and Br−) dependent DNA adducts formation. The activation of pulmonary dendritic cells, T helper type 2 cells, and mast cells is crucial mediators in the pathology of soot- or CB-induced respiratory disease. Polyunsaturated fatty acids (PUFAs) were also found to modulate T cells functions in respiratory diseases. Particularly, telomerase reverse transcriptase was found to play the critical role in soot- and CB-induced cardiovascular dysfunctions. In this review, we propose integrated mechanisms of soot- and CB-induced toxicity emphasizing the role of inflammatory mediators and oxidative stress. We also suggest use of antioxidants and PUFAs as protective strategies against soot- and CB-induced disorders.

Highlights of This Issue

Pancreatic adenocarcinoma (PDAC), with dismal survival rates, is the fourth-leading cause of cancer death in the United States. Very few therapeutic options exist for PDAC patients. Langdon and colleagues describe a combinatorial drug screen to identify therapeutic regimens that can inhibit the growth of PDAC cells. One of several effective combinations, consisting of bromodomain inhibitor, JQ1, and neddylation inhibitor MLN-4924, super-additively inhibited the growth of PDAC cells and xenografts. Dysregulation of reactive oxygen species-induced DNA damage responses contributed to the impact of this combination. These, and other high-ranking combinations including US FDA-approved agents, offer some promise for control of PDAC.Fibroblast growth factor receptors (FGFRs) are frequently activated by gene amplification, point mutation or chromosomal rearrangement in a variety of human cancers. FGFRs are recognized as an important oncogenic driver pathway for therapeutic intervention. In this study, Perera and colleagues report the discovery and pharmacologic characterization of erdafitinib (JNJ-42756493), a highly selective and potent pan-FGFR inhibitor. Erdafitinib demonstrated selective inhibition of FGFR-mediated signal transduction, proliferation and in vivo anti-tumor efficacy. These results support the ongoing clinical development of erdafitinib in malignancies and other disorders associated with constitutive FGFR activation.Paclitaxel is a commonly used chemotherapeutic drug. However, resistance to paclitaxel has limited its clinical application. ABCB1 and ABCC10 are the major transporters causing efflux of paclitaxel, leading to paclitaxel resistance. Here, Zhang, Patel and colleagues report that ibrutinib antagonized the efflux function of the transporters. Ibrutinib effectively enhanced the anti-tumor efficacy of ABCB1 and ABCC10-overexpressing resistant tumors in mice. Molecular docking analysis revealed that ibrutinib interacts with ABCB1 within its large cavity in the transmembrane region. This study demonstrated that combination of ibrutinib with paclitaxel can reverse ABCB1- or ABCC10-mediated paclitaxel resistance that could be of great clinical interest.Acute myeloid leukemia (AML) is the most common leukemia diagnosed in adults and a disease of high unmet need with few therapies delivering durable benefit to patients. Floc'h and colleagues report activity of a highly potent and selective Aurora kinase B inhibitor AZD2811 formulated in a nanoparticle. The AZD2811 nanoparticle delivered durable responses in pre-clinical models of AML, as monotherapy and combined with chemotherapy, including targeting tumor cells resident in the bone marrow. Targeting Aurora B with the AZD2811 nanoparticle formulation has the potential to build on the promising clinical activity seen with cell cycle agents in AML.

High level expression, efficient purification, and bioactivity of recombinant human metallothionein 3 (rhMT3) from methylotrophic yeast Pichia pastoris

Metallothionein 3 (MT3) is an important biochemical mediator regulating many physiological and pathophysiological processes including neuron cell protection, privation of reactive oxygen species-induced DNA damage, and protection against light induced retinal damage. In this study, a human gene encoding for MT3 with c-terminal extension of His6-tag was inserted into vector pPICZaA, and overexpressed in Pichia pastoris strain X-33. The rhMT3 was purified by one step Ni+-NTA affinity chromatography yielding 270mg/L of over 90% purity. Functional analysis of the purified rhMT3 using inductively coupled plasma mass spectrometry demonstrated that it has biological function, binding with metal ions Cd2+, Cu2+ and Zn2+. In summary, the experimental procedure we have developed facilitates production of large amounts of an active rhMT3 for further research and drug development.

OP0239 Systemic Sclerosis: A Pathological Model Linking Oxidative Stress, DNA Damage and Fibrosis

BackgroundFibroblasts isolated from lesional areas of Systemic Sclerosis (SSc) patients overproduce reactive oxygen species (ROS), overexpress type I collagen and a-smooth muscle actin (a-SMA) and show chromosomal aberrations (1, 2)....

Surface-Enhanced Raman Spectroscopy for Real-Time Monitoring of Reactive Oxygen Species-Induced DNA Damage and Its Prevention by Platinum Nanoparticles

We have successfully demonstrated the potential of surface-enhanced Raman spectroscopy (SERS) in monitoring the real time damage to genomic DNA. To reveal the capabilities of this technique, we exposed DNA to reactive oxygen species (ROS), an agent that has been implicated in causing DNA double-strand breaks, and the various stages of free radical-induced DNA damage have been monitored by using SERS. Besides this, we showed that prompt DNA aggregation followed by DNA double-strand scission and residual damage to the DNA bases caused by the ROS could be substantially reduced by the protective effect of Pt nanocages and nearly cubical Pt nanopartcles. The antioxidant activity of Pt nanoparticles was further confirmed by the cell viability studies. On the basis of SERS results, we identified various stages involved in the mechanism of action of ROS toward DNA damage, which involves the DNA double-strand scission and its aggregation followed by the oxidation of DNA bases. We found that Pt nanoparticles inhibit the DNA double-strand scission to a significant extent by the degradation of ROS. Our method illustrates the capability of SERS technique in giving vital information about the DNA degradation reactions at molecular level, which may provide insight into the effectiveness and mechanism of action of many drugs in cancer therapy.

Hace1 controls ROS generation of vertebrate Rac1-dependent NADPH oxidase complexes

The Hace1-HECT E3 ligase is a tumor suppressor that ubiquitylates the activated GTP-bound form of the Rho family GTPase Rac1, leading to Rac1 proteasomal degradation. Here we show that, in vertebrates, Hace1 targets Rac1 for degradation when Rac1 is localized to the nicotinamide adenine dinucleotide phosphate (NADPH) oxidase holoenzyme. This event blocks de novo reactive oxygen species generation by Rac1-dependent NADPH oxidases, and thereby confers cellular protection from reactive oxygen species-induced DNA damage and cyclin D1-driven hyper-proliferation. Genetic inactivation of Hace1 in mice or zebrafish, as well as Hace1 loss in human tumor cell lines or primary murine or human tumors, leads to chronic NADPH oxidase-dependent reactive oxygen species elevation, DNA damage responses and enhanced cyclin D1 expression. Our data reveal a conserved ubiquitin-dependent molecular mechanism that controls the activity of Rac1-dependent NADPH oxidase complexes, and thus constitutes the first known example of a tumor suppressor protein that directly regulates reactive oxygen species production in vertebrates.

Redox factor-1 may mediate the repair of multiple organ injuries after liver transplantation

Background Apurinic apyrimidinic endonuclease/redox effector factor 1 (APE1/Ref-1) is an important enzyme in the repair of reactive oxygen species-induced DNA damage, and its expression/activation can be induced by reactive oxygen species. The aim of this research was to investigate the relationship between multiple-organ injuries and expression of Ref-1 in the early period after liver transplantation. Methods One hundred and fifty adult male Wistar rats were divided randomly into three groups: liver transplantation, sham surgery, and untreated control. After liver transplantation, animals were sacrificed at different time points. Hepatic and renal functions were analyzed by serology. Histology, apoptotic levels, and Ref-1 expression were examined by immunohistochemistry in the liver, kidneys, intestines, and lungs. Results Serum levels of alanine aminotransferase and aspartate aminotransferase peaked 6 hours after liver transplantation and decreased appreciably after 12 hours in the transplantation group, suggesting that the degree of liver injury in the early period after transplantation peaked at 6 hours and then decreased. Pathological analyses showed that hepatic tissues were more severely injured in the transplantation group than in the sham and untreated groups. A considerable number of infiltrating inflammatory cells was observed around the portal vein in the transplantation group. Injuries to the kidneys, intestines, and lungs were milder after liver transplantation. Apoptotic levels increased after liver transplantation in all four organs examined. Ref-1 expression was higher in the transplantation group in the early period after liver transplantation than in the sham surgery and untreated control groups. Conclusion Ref-1 expression induced by ischemia-reperfusion injury may have a critical role in repairing multiple-organ injuries after liver transplantation.

Genetic variants of the APE1 gene and the risk of vitiligo in a Chinese population: A genotype–phenotype correlation study

Vitiligo is an acquired depigmentation disorder, and reactive oxygen species play an important role in melanocyte damage. Base excision repair is the major pathway responsible for removing reactive oxygen species-induced DNA damage, in which APE1, ADPRT, and XRCC1 play key roles. To investigate the association between genetic variations of these genes and the risk of vitiligo in Chinese populations, we genotyped APE1-Asp148Glu, ADPRT-Val762Ala, and XRCC1-Arg399Gln polymorphisms and measured serum 8-OHdG levels in a hospital-based case–control study. We found that a significantly increased risk of vitiligo was associated with the APE1 Asp/Glu (adjusted odds ratio (OR) 1.24; 95% confidence interval (CI) 1.02–1.52) and Glu/Glu genotypes (adjusted OR 1.48; 95% CI 1.13–1.93), compared with the APE1 Asp/Asp genotype, whereas no vitiligo risk was associated with the genotypes ADPRT-Val762Ala and XRCC1-Arg399Gln. Furthermore, serum 8-OHdG levels were elevated in the APE1-148Glu allele carriers (Asp/Glu+Glu/Glu), in an allele dose-response manner, with the risk of vitiligo (Ptrend<0.05). In addition, we found that the APE1-148Glu variant increased the 8-OHdG levels of cultured human melanocytes treated with H2O2, without any impact on the endonuclease activity. These data suggest that the APE1-Asp148Glu polymorphism aggravates oxidative stress in human melanocytes and contributes to genetic predisposition to vitiligo in Chinese people.

Evolution in Fast Forward: a Potential Role for Mutators in Accelerating Staphylococcus aureus Pathoadaptation

Pathogen evolution and subsequent phenotypic heterogeneity during chronic infection are proposed to enhance Staphylococcus aureus survival during human infection. We tested this theory by genetically and phenotypically characterizing strains with mutations constructed in the mismatch repair (MMR) and oxidized guanine (GO) system, termed mutators, which exhibit increased spontaneous-mutation frequencies. Analysis of these mutators revealed not only strain-dependent increases in the spontaneous-mutation frequency but also shifts in mutational type and hot spots consistent with loss of GO or MMR functions. Although the GO and MMR systems are relied upon in some bacterial species to prevent reactive oxygen species-induced DNA damage, no deficit in hydrogen peroxide sensitivity was found when either of these DNA repair pathways was lost in S. aureus. To gain insight into the contribution of increased mutation supply to S. aureus pathoadaptation, we measured the rate of α-hemolysin and staphyloxanthin inactivation during serial passage. Detection of increased rates of α-hemolysin and staphyloxanthin inactivation in GO and MMR mutants suggests that these strains are capable of modifying virulence phenotypes implicated in mediating infection. Accelerated derivation of altered virulence phenotypes, combined with the absence of increased ROS sensitivity, highlights the potential of mutators to drive pathoadaptation in the host and serve as catalysts for persistent infections.

Epistatic Roles for Pseudomonas aeruginosa MutS and DinB (DNA Pol IV) in Coping with Reactive Oxygen Species-Induced DNA Damage

Pseudomonas aeruginosa is especially adept at colonizing the airways of individuals afflicted with the autosomal recessive disease cystic fibrosis (CF). CF patients suffer from chronic airway inflammation, which contributes to lung deterioration. Once established in the airways, P. aeruginosa continuously adapts to the changing environment, in part through acquisition of beneficial mutations via a process termed pathoadaptation. MutS and DinB are proposed to play opposing roles in P. aeruginosa pathoadaptation: MutS acts in replication-coupled mismatch repair, which acts to limit spontaneous mutations; in contrast, DinB (DNA polymerase IV) catalyzes error-prone bypass of DNA lesions, contributing to mutations. As part of an ongoing effort to understand mechanisms underlying P. aeruginosa pathoadaptation, we characterized hydrogen peroxide (H2O2)-induced phenotypes of isogenic P. aeruginosa strains bearing different combinations of mutS and dinB alleles. Our results demonstrate an unexpected epistatic relationship between mutS and dinB with respect to H2O2-induced cell killing involving error-prone repair and/or tolerance of oxidized DNA lesions. In striking contrast to these error-prone roles, both MutS and DinB played largely accurate roles in coping with DNA lesions induced by ultraviolet light, mitomycin C, or 4-nitroquinilone 1-oxide. Models discussing roles for MutS and DinB functionality in DNA damage-induced mutagenesis, particularly during CF airway colonization and subsequent P. aeruginosa pathoadaptation are discussed.