Automated AFM analysis of DNA bending reveals initial lesion sensing strategies of DNA glycosylases

Base excision repair is the dominant DNA repair pathway of chemical modifications such as deamination, oxidation, or alkylation of DNA bases, which endanger genome integrity due to their high mutagenic potential. Detection and excision of these base lesions is achieved by DNA glycosylases. To investigate the remarkably high efficiency in target site search and recognition by these enzymes, we applied single molecule atomic force microscopy (AFM) imaging to a range of glycosylases with structurally different target lesions. Using a novel, automated, unbiased, high-throughput analysis approach, we were able to resolve subtly different conformational states of these glycosylases during DNA lesion search. Our results lend support to a model of enhanced lesion search efficiency through initial lesion detection based on altered mechanical properties at lesions. Furthermore, its enhanced sensitivity and easy applicability also to other systems recommend our novel analysis tool for investigations of diverse, fundamental biological interactions.

Oxidative stress induces different tissue dependent effects on Mutyh-deficient mice

8-oxoguanine (8-oxoG) is one of the most prevalent genotoxic lesions, and it is generated in DNA attacked by reactive oxygen species (ROS). Adenine misincorporated opposite to 8-oxoG during replication is excised by MutY homolog (MUTYH), an important protein of the base excision repair (BER) system. Mutyh plays an important role in the maintenance of genomic integrity, but the functional consequences of Mutyh deficiency are not fully understood. In the current study, we investigated the histological and functional changes of five tissues (hippocampus, heart, liver, kidney and lung) and their molecular basis in Mutyh^-/- and wild-type mice exposed to D-galactose (D-gal). Our data indicated that Mutyh deficiency hindered the weight gain of experimental mice and induced substantial alterations of 8-oxoG content and superoxide dismutase (SOD) activity, but no significant histological and functional impairment appeared in the investigated tissues of Mutyh- deficient mice without D-gal exposure. Under low-dose D-gal exposure, Mutyh deficiency altered expression of genes involved in mitochondrial unfolded protein response (UPR^mt) in the heart, liver and lung, and caused an enhanced expression of mitochondrial dynamics proteins (MDPs) in hippocampus and liver. The stress responses could maintain mitochondrial proteostasis and function. However, such responses were not noted when experiencing excessive damage burden induced by high-dose D-gal exposure, in which Mutyh deficiency increased accumulation of 8-oxoG and aggravated mitonuclear protein imbalance, as well as histological lesions in heart, liver and kidney. A higher sensitivity to ROS-induced cardiotoxicity with high-dose D-gal exposure was noticed in Mutyh^-/- mice. However, no differences in learning and memory impairments were observed between Mutyh^-/- and wild-type mice with high-dose D-gal exposure. In conclusion, our data demonstrated that Mutyh deficiency has different impacts on various tissues based on the degree of oxidative stress.

Enhanced mitochondrial DNA repair of the common disease-associated variant, Ser326Cys, of hOGG1 through small molecule intervention

The common oxidatively generated lesion, 8-oxo-7,8-dihydroguanine (8-oxoGua), is removed from DNA by base excision repair. The glycosylase primarily charged with recognition and removal of this lesion is 8-oxoGuaDNA glycosylase 1 (OGG1). When left unrepaired, 8-oxodG alters transcription and is mutagenic. Individuals homozygous for the less active OGG1 allele, Ser326Cys, have increased risk of several cancers. Here, small molecule enhancers of OGG1 were identified and tested for their ability to stimulate DNA repair and protect cells from the environmental hazard paraquat (PQ). PQ-induced mtDNA damage was inversely proportional to the levels of OGG1 expression whereas stimulation of OGG1, in some cases, entirely abolished its cellular effects. The PQ-mediated decline of mitochondrial membrane potential or nuclear condensation were prevented by the OGG1 activators. In addition, in Ogg1-/- mouse embryonic fibroblasts complemented with hOGG1S326C, there was increased cellular and mitochondrial reactive oxygen species compared to their wild type counterparts. Mitochondrial extracts from cells expressing hOGG1S326C were deficient in mitochondrial 8-oxodG incision activity, which was rescued by the OGG1 activators. These data demonstrate that small molecules can stimulate OGG1 activity with consequent cellular protection. Thus, OGG1-activating compounds may be useful in select humans to mitigate the deleterious effects of environmental oxidants and mutagens.

Loss of NEIL1 causes defects in olfactory function in mice

Oxidative DNA damage accumulation has been implicated in neurodegenerative diseases such as Alzheimer's disease and Parkinson's disease. The base excision repair pathway is a primary responder to oxidative DNA damage. Effects of loss of base excision repair on normal brain function is a relatively nascent area of research that needs further exploration for better understanding of related brain diseases. Recently, we found that loss of a versatile DNA glycosylase endonuclease 8-like 1 (NEIL1) causes deficits in spatial memory retention using the Morris water maze test. Furthermore, we found that there is a significant loss of NEIL1 enzyme levels and its activity in postmortem Alzheimer's disease brains. Based on the Allen Brain Atlas in situ hybridization data, the expression levels of Neil1 messenger RNA are higher in the olfactory bulb compared with other areas of the brain. Olfaction in mice is a central brain function that involves many central nervous system pathways. Here, we studied the effect of complete loss of Neil1 gene on olfactory function. We explored olfactory function in mice with 3 different behavioral tests namely, olfactory sensitivity, performance, and buried food tests. Neil1(-/-) mice performed poorly compared with wild-type mice in all 3 tests. Our data indicate that loss of Neil1 causes olfactory function deficits supporting our previous findings and that normal brain function requires robust DNA repair.

Oxidative DNA damage in the in utero initiation of postnatal neurodevelopmental deficits by normal fetal and ethanol-enhanced oxidative stress in oxoguanine glycosylase 1 knockout mice

Studies in mice with deficient antioxidative enzymes have shown that physiological levels of reactive oxygen species (ROS) can adversely affect the developing embryo and fetus. Herein, DNA repair-deficient progeny of oxoguanine glycosylase 1 (ogg1)-knockout mice lacking repair of the oxidative DNA lesion 8-oxo-2'-deoxyguanosine (8-oxodGuo) exhibited enhanced postnatal neurodevelopmental deficits, revealing the pathogenic potential of 8-oxodGuo initiated by physiological ROS production in fetal brain and providing the first evidence of a pathological phenotype for ogg1-knockout mice. Moreover, when exposed in utero to ethanol (EtOH), ogg1-knockout progeny exhibited higher levels of 8-oxodGuo in fetal brain and more severe postnatal neurodevelopmental deficits than wild-type littermates, both of which were blocked by pretreatment with the free radical trapping agent phenylbutylnitrone. These results suggest that ROS-initiated DNA oxidation, as distinct from altered signal transduction, contributes to neurodevelopmental deficits caused by in utero EtOH exposure, and fetal DNA repair is a determinant of risk.

NEIL2 protects against oxidative DNA damage induced by sidestream smoke in human cells

Secondhand smoke (SHS) is a confirmed lung carcinogen that introduces thousands of toxic chemicals into the lungs. SHS contains chemicals that have been implicated in causing oxidative DNA damage in the airway epithelium. Although DNA repair is considered a key defensive mechanism against various environmental attacks, such as cigarette smoking, the associations of individual repair enzymes with susceptibility to lung cancer are largely unknown. This study investigated the role of NEIL2, a DNA glycosylase excising oxidative base lesions, in human lung cells treated with sidestream smoke (SSS), the main component of SHS. To do so, we generated NEIL2 knockdown cells using siRNA-technology and exposed them to SSS-laden medium. Representative SSS chemical compounds in the medium were analyzed by mass spectrometry. An increased production of reactive oxygen species (ROS) in SSS-exposed cells was detected through the fluorescent detection and the induction of HIF-1α. The long amplicon–quantitative PCR (LA-QPCR) assay detected significant dose-dependent increases of oxidative DNA damage in the HPRT gene of cultured human pulmonary fibroblasts (hPF) and BEAS-2B epithelial cells exposed to SSS for 24 h. These data suggest that SSS exposure increased oxidative stress, which could contribute to SSS-mediated toxicity. siRNA knockdown of NEIL2 in hPF and HEK 293 cells exposed to SSS for 24 h resulted in significantly more oxidative DNA damage in HPRT and POLB than in cells with control siRNA. Taken together, our data strongly suggest that decreased repair of oxidative DNA base lesions due to an impaired NEIL2 expression in non-smokers exposed to SSS would lead to accumulation of mutations in genomic DNA of lung cells over time, thus contributing to the onset of SSS-induced lung cancer.

Mammalian MutY homolog (MYH or MUTYH) protects cells from oxidative DNA damage

MutY DNA glycosylase homologs (MYH or MUTYH) reduce G:C to T:A mutations by removing misincorporated adenines or 2-hydroxyadenines paired with guanine or 8-oxo-7,8-dihydroguanine (8-oxo-G). Mutations in the human MYH (hMYH) gene are associated with the colorectal cancer predisposition syndrome MYH-associated polyposis. To examine the function of MYH in human cells, we regulated MYH gene expression by knockdown or overproduction. MYH knockdown human HeLa cells are more sensitive to the killing effects of H2O2 than the control cells. In addition, hMYH knockdown cells have altered cell morphology, display enhanced susceptibility to apoptosis, and have altered DNA signaling activation in response to oxidative stress. The cell cycle progression of hMYH knockdown cells is also different from that of the control cells following oxidative stress. Moreover, hMYH knockdown cells contain higher levels of 8-oxo-G lesions than the control cells following H2O2 treatment. Although MYH does not directly remove 8-oxo-G, MYH may generate favorable substrates for other repair enzymes. Overexpression of mouse Myh (mMyh) in human mismatch repair defective HCT15 cells makes the cells more resistant to killing and refractory to apoptosis by oxidative stress than the cells transfected with vector. In conclusion, MYH is a vital DNA repair enzyme that protects cells from oxidative DNA damage and is critical for a proper cellular response to DNA damage.

The impact of single-nucleotide polymorphisms (SNPs) in OGG1 and XPC on the age at onset of Huntington disease

The age at onset of Huntington disease (HD) shows a strong, negative correlation with the number of CAG repeats within the huntingtin (HTT) gene. However, this does not account for all the inter-individual variability seen among patients. In order to assess whether single-nucleotide polymorphisms (SNPs) in the OGG1 and XPC genes, both implicated in responses to oxidative stress, are associated with the age of onset of HD, 9 SNPs have been genotyped in 299 individuals with HD and 582 controls. After correction for multiple testing, two OGG1/XPC haplotypes were found to be associated with younger age at onset independently of the number of CAG repeats within the HTT gene. Both haplotypes contain XPC coding variants that would be expected to impact on protein function and/or variants in the 3'UTR that could result in altered protein levels via allele-specific mIR binding. One haplotype also contains the OGG1-326Cys (rs1052133) allele that has been associated with a lower 8-oxoG repair activity and is particularly sensitive to the cellular redox status. These results highlight the potential role of oxidative stress in determining the age at onset of HD.

8-Oxoguanine DNA glycosylase-1 links DNA repair to cellular signaling via the activation of the small GTPase Rac1

8-Oxo-7,8-dihydroguanine (8-oxoG) is one of the most abundant DNA base lesions induced by reactive oxygen species (ROS). Accumulation of 8-oxoG in the mammalian genome is considered a marker of oxidative stress, to be causally linked to inflammation, and is thought to contribute to aging processes and various aging-related diseases. Unexpectedly, mice that lack 8-oxoguanine DNA glycosylase-1 (OGG1) activity and accumulate 8-oxoG in their genome have a normal phenotype and longevity; in fact, they show increased resistance to both inflammation and oxidative stress. OGG1 excises and generates free 8-oxoG base during DNA base-excision repair (BER) processes. In the present study, we report that in the presence of the 8-oxoG base, OGG1 physically interacts with guanine nucleotide-free and GDP-bound Rac1 protein. This interaction results in rapid GDP→GTP, but not GTP→GDP, exchange in vitro. Importantly, a rise in the intracellular 8-oxoG base levels increases the proportion of GTP-bound Rac1. In turn Rac1-GTP mediates an increase in ROS levels via nuclear membrane-associated NADPH oxidase type 4. These results show a novel mechanism by which OGG1 in complex with 8-oxoG is linked to redox signaling and cellular responses.

8-Oxoguanine DNA glycosylase (OGG1) deficiency increases susceptibility to obesity and metabolic dysfunction

Oxidative damage to DNA is mainly repaired via base excision repair, a pathway that is catalyzed by DNA glycosylases such as 8-oxoguanine DNA glycosylase (OGG1). While OGG1 has been implicated in maintaining genomic integrity and preventing tumorigenesis, we report a novel role for OGG1 in altering cellular and whole body energy homeostasis. OGG1-deficient (Ogg1(-/-)) mice have increased adiposity and hepatic steatosis following exposure to a high-fat diet (HFD), compared to wild-type (WT) animals. Ogg1(-/-) animals also have higher plasma insulin levels and impaired glucose tolerance upon HFD feeding, relative to WT counterparts. Analysis of energy expenditure revealed that HFD-fed Ogg1(-/-) mice have a higher resting VCO(2) and consequently, an increased respiratory quotient during the resting phase, indicating a preference for carbohydrate metabolism over fat oxidation in these mice. Additionally, microarray and quantitative PCR analyses revealed that key genes of fatty acid oxidation, including carnitine palmitoyl transferase-1, and the integral transcriptional co-activator Pgc-1α were significantly downregulated in Ogg1(-/-) livers. Multiple genes involved in TCA cycle metabolism were also significantly reduced in livers of Ogg1(-/-) mice. Furthermore, hepatic glycogen stores were diminished, and fasting plasma ketones were significantly reduced in Ogg1(-/-) mice. Collectively, these data indicate that OGG1 deficiency alters cellular substrate metabolism, favoring a fat sparing phenotype, that results in increased susceptibility to obesity and related pathologies in Ogg1(-/-) mice.

8-Oxoguanine causes neurodegeneration during MUTYH-mediated DNA base excision repair

8-Oxoguanine (8-oxoG), a common DNA lesion caused by reactive oxygen species, is associated with carcinogenesis and neurodegeneration. Although the mechanism by which 8-oxoG causes carcinogenesis is well understood, the mechanism by which it causes neurodegeneration is unknown. Here, we report that neurodegeneration is triggered by MUTYH-mediated excision repair of 8-oxoG-paired adenine. Mutant mice lacking 8-oxo-2'-deoxyguanosine triphosphate-depleting (8-oxo-dGTP-depleting) MTH1 and/or 8-oxoG-excising OGG1 exhibited severe striatal neurodegeneration, whereas mutant mice lacking MUTYH or OGG1/MUTYH were resistant to neurodegeneration under conditions of oxidative stress. These results indicate that OGG1 and MTH1 are protective, while MUTYH promotes neurodegeneration. We observed that 8-oxoG accumulated in the mitochondrial DNA of neurons and caused calpain-dependent neuronal loss, while delayed nuclear accumulation of 8-oxoG in microglia resulted in PARP-dependent activation of apoptosis-inducing factor and exacerbated microgliosis. These results revealed that neurodegeneration is a complex process caused by 8-oxoG accumulation in the genomes of neurons and microglia. Different signaling pathways were triggered by the accumulation of single-strand breaks in each type of DNA generated during base excision repair initiated by MUTYH, suggesting that suppression of MUTYH may protect the brain under conditions of oxidative stress.

Cancer-associated variants and a common polymorphism of MUTYH exhibit reduced repair of oxidative DNA damage using a GFP-based assay in mammalian cells

Biallelic germline mutations in the base excision repair enzyme gene MUTYH lead to multiple colorectal adenomas and carcinomas referred to as MUTYH-associated polyposis. MUTYH removes adenine misincorporated opposite the DNA oxidation product, 8-oxoguanine (OG), thereby preventing accumulation of G:C to T:A transversion mutations. The most common cancer-associated MUTYH variant proteins when expressed in bacteria exhibit reduced OG:A mismatch affinity and adenine removal activity. However, direct evaluation of OG:A mismatch repair efficiency in mammalian cells has not been assessed due to the lack of an appropriate assay. To address this, we developed a novel fluorescence-based assay of OG:A repair and measured the repair capacity of MUTYH-associated polyposis variants expressed in Mutyh-/- mouse embryonic fibroblasts (MEFs). The repair of a single site-specific synthetic lesion in a green fluorescent protein reporter leads to green fluorescent protein expression with co-expression of a red fluorescent protein serving as the transfection control. Cell lines that stably express the MUTYH-associated polyposis variants G382D and Y165C have significantly lower OG:A repair versus wild-type MEFs and MEFs expressing human wild-type MUTYH. The MUTYH allele that encodes the Q324H variant is found at a frequency above 40% in samples from different ethnic groups and has long been considered phenotypically silent but has recently been associated with increased cancer risk in several clinical studies. In vitro analysis of Q324H MUTYH expressed in insect cells showed that it has reduced enzyme activity similar to that of the known cancer variant G382D. Moreover, we find that OG:A repair in MEFs expressing Q324H was significantly lower than wild-type controls, establishing that Q324H is functionally impaired and providing further evidence that this common variant may lead to increased cancer risk.

Modulation of oxidative DNA damage by repair enzymes XRCC1 and hOGG1

The influence of DNA repair gene polymorphisms (XRCC1: Arg194Trp, Arg280His, Arg399Gln; APE1: Asp148Glu; hOGG1: Ser326Cys) on oxidative DNA damage is controversial and was investigated in 214 German workers with occupational exposure to vapors and aerosols of bitumen,compared to 87 German construction workers without exposure, who were part of the Human Bitumen Study. Genotypes were determined by real-time polymerase chain reaction (PCR), and actual smoking habits by a questionnaire and cotinine analysis. Oxidative DNA damage in white blood cells (WBC) collected pre- and postshift was measured as 8-oxodGuo adducts/10(6) dGuo by a hjigh-performance liquid chromatography electron capture detection (HPLC-ECD) method, followed by calculation of the difference between post- and preshift values (Δ8-oxodGuo/10(6) dGuo). The 214 bitumen exposed workers showed higher median Δ8-oxodGuo values than the 87 references. In the whole study group (n=301) there was a trend for increasing adduct values for XRCC1 Arg(GG)399Gln(AA) during a shift, especially in nonsmokers (n=108. Referents (n=87) displayed a similar trend for hOGG1 Ser(CC)326Cys(GG). In contrast, XRCC1 Arg(GG)280His(AA) showed a decrease of median Δ8-oxodGuo/10(6) dGuo values in workers with exposure to vapors and aerosols of bitumen (n=214), especially in smokers (n=145). XRCC1 Arg194Trp and APE1 Asp148Glu displayed no marked association with Δ8-oxodGuo levels. Data indicate that the combination of different variants in DNA damage repair enzymes may modulate the production of 8-oxoguanine adducts in WBC produced by xenobiotics during a shift.

Establishment of a non-radioactive cleavage assay to assess the DNA repair capacity towards oxidatively damaged DNA in subcellular and cellular systems and the impact of copper

Oxidative stress is involved in many diseases, and the search for appropriate biomarkers is one major focus in molecular epidemiology. 8-Oxoguanine (8-oxoG), a potentially mutagenic DNA lesion, is considered to be a sensitive biomarker for oxidative stress. Another approach consists in assessing the repair capacity towards 8-oxoG, mediated predominantly by the human 8-oxoguanine DNA glycosylase 1 (hOGG1). With respect to the latter, during the last few years so-called cleavage assays have been described, investigating the incision of (32)P-labelled and 8-oxoG damaged oligonucleotides by cell extracts. Within the present study, a sensitive non-radioactive test system based on a Cy5-labelled oligonucleotide has been established. Sources of incision activity are isolated proteins or extracts prepared from cultured cells and peripheral blood mononuclear cells (PBMC). After comparing different oligonucleotide structures, a hairpin-like structure was selected which was not degraded by cell extracts. Applying this test system the impact of copper on the activity of isolated hOGG1 and on hOGG activity in A549 cells was examined, showing a distinct inhibition of the isolated protein at low copper concentration as compared to a modest inhibition of hOGG activity in cells at beginning cytotoxic concentrations. For investigating PBMC, all reaction conditions, including the amounts of oligonucleotide and cell extract as well as the reaction time have been optimized. The incision activities of PBMC protein extracts obtained from different donors have been investigated, and inter-individual differences have been observed. In summary, the established method is as sensitive and even faster than the radioactive technique, and additionally, offers the advantage of reduced costs and low health risk.

A screen for modifiers of notch signaling uncovers Amun, a protein with a critical role in sensory organ development

Notch signaling is an evolutionarily conserved pathway essential for many cell fate specification events during metazoan development. We conducted a large-scale transposon-based screen in the developing Drosophila eye to identify genes involved in Notch signaling. We screened 10,447 transposon lines from the Exelixis collection for modifiers of cell fate alterations caused by overexpression of the Notch ligand Delta and identified 170 distinct modifier lines that may affect up to 274 genes. These include genes known to function in Notch signaling, as well as a large group of characterized and uncharacterized genes that have not been implicated in Notch pathway function. We further analyze a gene that we have named Amun and show that it encodes a protein that localizes to the nucleus and contains a putative DNA glycosylase domain. Genetic and molecular analyses of Amun show that altered levels of Amun function interfere with cell fate specification during eye and sensory organ development. Overexpression of Amun decreases expression of the proneural transcription factor Achaete, and sensory organ loss caused by Amun overexpression can be rescued by coexpression of Achaete. Taken together, our data suggest that Amun acts as a transcriptional regulator that can affect cell fate specification by controlling Achaete levels.

Repeated inhalations of diesel exhaust particles and oxidatively damaged DNA in young oxoguanine DNA glycosylase (OGG1) deficient mice

DNA repair may prevent increased levels of oxidatively damaged DNA from prolonged oxidative stress induced by, e.g. exposure to diesel exhaust particles (DEP). We studied oxidative damage to DNA in broncho-alveolar lavage cells, lungs, and liver after 4 x 1.5 h inhalations of DEP (20 mg/m3) in Ogg1-/- and wild type (WT) mice with similar extent of inflammation. DEP exposure increased lung levels of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG) in Ogg1-/- mice, whereas no effect on 8-oxodG or oxidized purines in terms of formamidopyrimidine DNA glycosylase (FPG) sites was observed in WT mice. In both unexposed and exposed Ogg1-/- mice the level of FPG sites in the lungs was 3-fold higher than in WT mice. The high basal level of FPG sites in Ogg1-/- mice probably saturated the assay and prevented detection of DEP-generated damage. In conclusion, Ogg1-/- mice have elevated pulmonary levels of FPG sites and accumulate genomic 8-oxodG after repeated inhalations of DEP.

[The role of glycosylases of the base excision DNA repair in pathogenesis of hereditary and infectious human diseases]

DNA glycosylases are enzymes that initiate base excision repair, a process of removal of damaged bases from the cellular DNA. Recent data show that variants of two human DNA glycosylases, MUTYH and OGG1, are associated with an increased risk of cancer. In addition, activities of various DNA glycosylases have been implicated in protection of humans from neurodegenerative diseases, immune disorders and viral infections. On the other hand, DNA glycosylases from pathogenic microorganisms help them to avoid the host defensive systems. Thus, DNA glycosylases represent both potential therapeutic agents and drug targets.

Arabidopsis DEMETER-LIKE proteins DML2 and DML3 are required for appropriate distribution of DNA methylation marks

Cytosine DNA methylation is a stable epigenetic mark for maintenance of gene silencing across cellular divisions, but it is a reversible modification. Genetic and biochemical studies have revealed that the Arabidopsis DNA glycosylase domain-containing proteins ROS1 (REPRESSOR OF SILENCING 1) and DME (DEMETER) initiate erasure of 5-methylcytosine through a base excision repair process. The Arabidopsis genome encodes two paralogs of ROS1 and DME, referred to as DEMETER-LIKE proteins DML2 and DML3. We have found that DML2 and DML3 are 5-methylcytosine DNA glycosylases that are expressed in a wide range of plant organs. We analyzed the distribution of methylation marks at two methylated loci in wild-type and dml mutant plants. Mutations in DML2 and/or DML3 lead to hypermethylation of cytosine residues that are unmethylated or weakly methylated in wild-type plants. In contrast, sites that are heavily methylated in wild-type plants are hypomethylated in mutants. These results suggest that DML2 and DML3 are required not only for removing DNA methylation marks from improperly-methylated cytosines, but also for maintenance of high methylation levels in properly targeted sites.

MUTYH-null mice are susceptible to spontaneous and oxidative stress induced intestinal tumorigenesis

MUTYH is a mammalian DNA glycosylase that initiates base excision repair by excising adenine opposite 8-oxoguanine and 2-hydroxyadenine opposite guanine, thereby preventing G:C to T:A transversion caused by oxidative stress. Recently, biallelic germ-line mutations of MUTYH have been found in patients predisposed to a recessive form of hereditary multiple colorectal adenoma and carcinoma with an increased incidence of G:C to T:A somatic mutations in the APC gene. In the present study, a systematic histologic examination revealed that more spontaneous tumors had developed in MUTYH-null mice (72 of 121; 59.5%) than in the wild type (38 of 109; 34.9%). The increased incidence of intestinal tumors in MUTYH-null mice (11 tumors in 10 of 121 mice) was statistically significant compared with the wild type (no intestinal tumors in 109 mice). Two adenomas and seven adenocarcinomas were observed in the small intestines, and two adenomas but no carcinomas were found in the colons. In MUTYH-null mice treated with KBrO(3), the occurrence of small intestinal tumors dramatically increased. The mean number of polyps induced in the small intestines of these mice was 61.88 (males, 72.75; females, 51.00), whereas it was 0.85 (males, 0.50; females, 1.00) in wild-type mice. The tumors developed predominantly in the duodenum and in the upper region of the (jejunum) small intestines. We conclude that MUTYH suppresses spontaneous tumorigenesis in mammals, thus providing experimental evidence for the association between biallelic germ-line MUTYH mutations and a recessive form of human hereditary colorectal adenoma and carcinoma.

Transcription through 8-oxoguanine in DNA repair-proficient and Csb /Ogg1 DNA repair-deficient mouse embryonic fibroblasts is dependent upon promoter strength and sequence context

Cells from Cockayne syndrome patients are characterized by a deficiency in transcription-coupled repair (TCR) of UV-induced lesions. These cells have also been shown to be sensitive to oxidative stress and defective in TCR of some oxidative lesions. Because some discrepancies about this pathway have been recently reported in the literature, we describe here a system that allows us to analyze the effect of a unique 8-oxoguanine (8-oxoG) lesion on gene transcription in vivo. We have constructed nonreplicative shuttle vectors containing a single 8-oxoG in the transcribed strand of the luciferase reporter gene. We have positioned this unique lesion in different sequence contexts and we have tested the effect of two promoters with different transcriptional strength on the level of transcriptional bypass/pause due to the presence of the lesion. When we transfected DNA repair-deficient mouse cell lines with these shuttle vectors, we found a approximately 50% decrease in relative luciferase activity in Ogg1(-/-) and Csb(-/-) embryonic mouse cell lines. In Csb(-/-)/Ogg1(-/-) cells, this decrease was even more important achieving eventually up to 90% inhibition of luciferase expression depending upon the promoter strength and the position of the lesion. These results show clearly that a unique 8-oxoG exhibits different effect on gene expression depending upon the nucleotidic sequence around it and needs the wild-type activities of Csb and Ogg1 proteins to be fully repaired.

The capacity to remove 8-oxoG is enhanced in newborn neural stem/progenitor cells and decreases in juvenile mice and upon cell differentiation

In mammalian cells, 8-oxoguanine DNA glycosylase-1 (OGG1) is the main DNA glycosylase for the removal of 8-oxoguanine (8-oxoG). 8-oxoG, one of the most common products of the oxidative attack of DNA, is a premutagenic lesion that accumulates spontaneously at high frequencies in the genome. In this study, Ogg1 mRNA expression was detected throughout embryonic development in mice. In situ hybridization showed that in the neonatal brain, Ogg1 expression was detected in a distinct layer of cells in the medial wall of the lateral ventricle, which may correspond to ependymal cells, and in some scattered cells in the subventricular zone (SVZ), a brain region rich in neural stem/progenitor cells. Using neurospheres as a model for the study of neural stem/progenitor cells, we found that both the expression and activity of Ogg1 were high in neurospheres derived from newborn mice and decreased in adults and upon induction of cell differentiation. Furthermore, Ogg1 was shown to be the major DNA glycosylase initiating 8-oxoG repair in neurospheres. Our results strongly indicate that enhanced DNA repair capacity is an important mechanism by which neural stem/progenitor cells maintain their genome.

Oxidative DNA damage defense systems in avoidance of stationary-phase mutagenesis in Pseudomonas putida

Oxidative damage of DNA is a source of mutation in living cells. Although all organisms have evolved mechanisms of defense against oxidative damage, little is known about these mechanisms in nonenteric bacteria, including pseudomonads. Here we have studied the involvement of oxidized guanine (GO) repair enzymes and DNA-protecting enzyme Dps in the avoidance of mutations in starving Pseudomonas putida. Additionally, we examined possible connections between the oxidative damage of DNA and involvement of the error-prone DNA polymerase (Pol)V homologue RulAB in stationary-phase mutagenesis in P. putida. Our results demonstrated that the GO repair enzymes MutY, MutM, and MutT are involved in the prevention of base substitution mutations in carbon-starved P. putida. Interestingly, the antimutator effect of MutT was dependent on the growth phase of bacteria. Although the lack of MutT caused a strong mutator phenotype under carbon starvation conditions for bacteria, only a twofold increased effect on the frequency of mutations was observed for growing bacteria. This indicates that MutT has a backup system which efficiently complements the absence of this enzyme in actively growing cells. The knockout of MutM affected only the spectrum of mutations but did not change mutation frequency. Dps is known to protect DNA from oxidative damage. We found that dps-defective P. putida cells were more sensitive to sudden exposure to hydrogen peroxide than wild-type cells. At the same time, the absence of Dps did not affect the accumulation of mutations in populations of starved bacteria. Thus, it is possible that the protective role of Dps becomes essential for genome integrity only when bacteria are exposed to exogenous agents that lead to oxidative DNA damage but not under physiological conditions. Introduction of the Y family DNA polymerase PolV homologue rulAB into P. putida increased the proportion of A-to-C and A-to-G base substitutions among mutations, which occurred under starvation conditions. Since PolV is known to perform translesion synthesis past damaged bases in DNA (e.g., some oxidized forms of adenine), our results may imply that adenine oxidation products are also an important source of mutation in starving bacteria.

The substrate specificity of MutY for hyperoxidized guanine lesions in vivo

The DNA damage product 7,8-dihydro-8-oxo-2'-deoxyguanine (8-oxoG) is a commonly used biomarker of oxidative stress. The mutagenic potential of this DNA lesion is mitigated in Escherichia coli by multiple enzymes. One of these enzymes, MutY, excises an A mispaired with 8-oxoG as part of the process to restore the original G:C base pair. However, numerous studies have shown that 8-oxoG is chemically labile toward further oxidation. Here, we examine the activity of MutY on the 8-oxoG oxidation products guanidinohydantoin (Gh), two diastereomers of spiroiminodihydantoin (Sp1 and Sp2), oxaluric acid (Oa), and urea (Ur). Single-stranded viral genomes containing a site-specific lesion were constructed and replicated in E. coli that are either proficient in DNA repair or that lack MutY. These lesions were found previously to be potently mutagenic in repair competent bacteria, and we report here that these 8-oxoG-derived lesions are equally miscoding when replicated in E. coli lacking MutY; no significant change in mutation identity or frequency is observed. Interestingly, however, in the presence of MutY, Sp1 and Sp2 are more toxic than in cells lacking this repair enzyme.

Virion-associated uracil DNA glycosylase-2 and apurinic/apyrimidinic endonuclease are involved in the degradation of APOBEC3G-edited nascent HIV-1 DNA

Cellular cytidine deaminases APOBEC3 family is a group of potent inhibitors for many exogenous and endogenous retroviruses. It has been demonstrated that they induce G to A hypermutations in the nascent retroviral DNA, resulting from the cytosine (C) to uracil (U) conversions in minus-stranded viral DNA. In this report, we have demonstrated that the result of C to U conversion in minus-stranded DNA of human immunodeficiency virus type 1 (HIV-1) could trigger a degradation of nascent viral DNA mediated by uracil DNA glycosylases-2 (UNG2) and apurinic/apyrimidinic endonuclease (APE). Since antiviral activity of APOBEC3G is partially affected by UNG2 inhibitor Ugi or UNG2-specific short-interfering RNA in virus-producing cells but not target cells, the virion-associated UNG2 most likely mediates this process. Interestingly, as APE-specific short-interfering RNA can also partially inhibit the anti-HIV-1 activity of APOBEC3G in virus-producing cells but not in target cells and APE molecules can be detected within HIV-1 virions, it seems that the required APE is also virion-associated. Furthermore, the in vitro cleavage experiment using uracil-containing single-stranded DNA as a template has demonstrated that the uracil-excising catalytic activity of virion-associated UNG2 can remove dU from the uracil-containing viral DNA and leave an abasic site, which could be further cleaved by virion-associated APE. Based upon our observations, we propose that the degradation of APOBEC3G-edited viral DNA mediated by virion-associated UNG2 and APE during or after reverse transcription could be partially responsible for the potent anti-HIV-1 effect by APOBEC3G in the absence of vif.

Estimating the effect of human base excision repair protein variants on the repair of oxidative DNA base damage

Epidemiologic studies have revealed a complex association between human genetic variance and cancer risk. Quantitative biological modeling based on experimental data can play a critical role in interpreting the effect of genetic variation on biochemical pathways relevant to cancer development and progression. Defects in human DNA base excision repair (BER) proteins can reduce cellular tolerance to oxidative DNA base damage caused by endogenous and exogenous sources, such as exposure to toxins and ionizing radiation. If not repaired, DNA base damage leads to cell dysfunction and mutagenesis, consequently leading to cancer, disease, and aging. Population screens have identified numerous single-nucleotide polymorphism variants in many BER proteins and some have been purified and found to exhibit mild kinetic defects. Epidemiologic studies have led to conflicting conclusions on the association between single-nucleotide polymorphism variants in BER proteins and cancer risk. Using experimental data for cellular concentration and the kinetics of normal and variant BER proteins, we apply a previously developed and tested human BER pathway model to (i) estimate the effect of mild variants on BER of abasic sites and 8-oxoguanine, a prominent oxidative DNA base modification, (ii) identify ranges of variation associated with substantial BER capacity loss, and (iii) reveal nonintuitive consequences of multiple simultaneous variants. Our findings support previous work suggesting that mild BER variants have a minimal effect on pathway capacity whereas more severe defects and simultaneous variation in several BER proteins can lead to inefficient repair and potentially deleterious consequences of cellular damage.

Somatic Hypermutation and Class Switch Recombination in Msh6−/−Ung−/−Double-Knockout Mice

Somatic hypermutation (SHM) and class switch recombination (CSR) are initiated by activation-induced cytosine deaminase (AID). The uracil, and potentially neighboring bases, are processed by error-prone base excision repair and mismatch repair. Deficiencies in Ung, Msh2, or Msh6 affect SHM and CSR. To determine whether Msh2/Msh6 complexes which recognize single-base mismatches and loops were the only mismatch-recognition complexes required for SHM and CSR, we analyzed these processes in Msh6(-/-)Ung(-/-) mice. SHM and CSR were affected in the same degree and fashion as in Msh2(-/-)Ung(-/-) mice; mutations were mostly C,G transitions and CSR was greatly reduced, making Msh2/Msh3 contributions unlikely. Inactivating Ung alone reduced mutations from A and T, suggesting that, depending on the DNA sequence, varying proportions of A,T mutations arise by error-prone long-patch base excision repair. Further, in Msh6(-/-)Ung(-/-) mice the 5' end and the 3' region of Ig genes was spared from mutations as in wild-type mice, confirming that AID does not act in these regions. Finally, because in the absence of both Ung and Msh6, transition mutations from C and G likely are "footprints" of AID, the data show that the activity of AID is restricted drastically in vivo compared with AID in cell-free assays.

Subcellular compartmentalization of glutathione: correlations with parameters of oxidative stress related to genotoxicity

Glutathione (GSH) is a major component of the antioxidant defence system of mammalian cells and is found in subcellular pools within the cytoplasm, nucleus and mitochondria. To evaluate the relationships between these pools and parameters of oxidative stress related to genotoxicity, wild type (WT) and 8-oxo-2'-deoxyguanosine glycosylase 1 (OGG1)-null (mOGG1(-/-)) mouse embryonic fibroblasts (MEF) were treated with buthionine sulphoximine (BSO; 0-1000 microM, 24 h), an inhibitor of GSH biosynthesis. BSO treatment resulted in a concentration-dependent depletion of GSH from the cytoplasm, but depletion of mitochondrial and nuclear GSH occurred only at concentrations > or =100 microM. GSH levels were correlated with reactive oxygen species (ROS), lipid peroxidation (measured as the increase in the genotoxic end-product malondialdehyde (MDA)) and oxidative DNA modifications, measured as both frank DNA strand-breaks (FSB) and oxidized purine lesions (OxP) using the alkaline comet assay with formamidopyrimidine DNA glycosylase (FPG) modification; this system allowed for the identification of BSO-induced DNA modifications as primarily mutagenic 8-oxo-2'-deoxyguanosine lesions. A number of significant correlations were observed. First, negative linear correlations were observed between mitochondrial GSH and ROS (r = -0.985 and r = -0.961 for WT and mOGG1(-/-) MEF, respectively), and mitochondrial GSH and MDA (r = -0.967 and r = -0.963 for WT and mOGG1(-/-) MEF, respectively). Second, positive linear correlations were observed between ROS and MDA (r = 0.996 and r = 0.935 for WT and mOGG1(-/-) MEF, respectively), and ROS and OxP (r = 0.938 and r = 0.981 for WT and mOGG1(-/-) MEF, respectively). Finally, oxidative DNA modifications displayed a negative linear correlation with nuclear GSH (r = -0.963 and -0.951 between nuclear GSH and FSB and OxP, respectively, for WT MEF and r = -0.960 between nuclear GSH and OxP in mOGG1(-/-) MEF), thus, demonstrating the genotoxic potential of compounds that deplete GSH. The findings highlight the critical roles of the mitochondrial and nuclear GSH pools in protecting cellular components, particularly DNA, from oxidative modification.

Role of a MutY DNA glycosylase in combating oxidative DNA damage in Helicobacter pylori

MutY is an adenine glycosylase that has the ability to efficiently remove adenines from adenine/7,8-dihydro-8-oxoguanine (8-oxo-G) or adenine/guanine mismatches, and plays an important role in oxidative DNA damage repair. The human gastric pathogen Helicobacter pylori has a homolog of the MutY enzyme. To investigate the physiological roles of MutY in H. pylori, we constructed and characterized a mutY mutant. H. pylori mutY mutants incubated at 5% O2 have a 325-fold higher spontaneous mutation rate than its parent. The mutation rate is further increased by exposing the mutant to atmospheric levels of oxygen, an effect that is not seen in an E. coli mutY mutant. Most of the mutations that occurred in H. pylori mutY mutants, as examined by rpoB sequence changes that confer rifampicin resistance, are GC to TA transversions. The H. pylori enzyme has the ability to complement an E. coli mutY mutant, restoring its mutation frequency to the wild-type level. Pure H. pylori MutY has the ability to remove adenines from A/8-oxo-G mismatches, but strikingly no ability to cleave A/G mismatches. This is surprising because E. coli MutY can more rapidly turnover A/G than A/8-oxo-G. Thus, H. pylori MutY is an adenine glycosylase involved in the repair of oxidative DNA damage with a specificity for detecting 8-oxo-G. In addition, H. pylori mutY mutants are only 30% as efficient as wild-type in colonizing the stomach of mice, indicating that H. pylori MutY plays a significant role in oxidative DNA damage repair in vivo.

Effects of ectopic expression of Drosophila DNA glycosylases dOgg1 and RpS3 in mitochondria

The main purpose of this study was to determine whether enhancement of repair capacity would attenuate mitochondrial DNA oxidative damage and result in greater cell survival under stressful conditions. The repair of oxidative damage is initiated by DNA glycosylases, which catalyze the excision of oxidized bases, such as 8-hydroxydeoxyguanosine (8-oxodG). Drosophila DNA glycosylases, dOgg1 and RpS3, were ectopically expressed within the mitochondrial matrix in Drosophila S2 cells, causing a severalfold decrease in the levels of 8-oxodG in mitochondrial DNA. Unexpectedly, cells did not show increased resistance to oxidative stress, but instead became more susceptible to treatment with hydrogen peroxide or paraquat. Even in the absence of oxidative challenge, cells expressing RpS3 or dOgg1 in mitochondria exhibited increased apoptosis relative to controls, as determined by flow-cytometric analysis of Annexin V and DNA degradation measured by the Comet assay. Another notable finding was that ectopic expression of either dOgg1 or RpS3 in mitochondria increased cell survival after exposure to the nitric oxide donor SNAP. These results suggest that ectopic expression of one of the constituents of the DNA repair system in mitochondria may cause a perturbation in the base excision repair pathway and lower, rather than enhance, survivability.

The roles of specific glycosylases in determining the mutagenic consequences of clustered DNA base damage

The potential for genetic change arising from specific single types of DNA lesion has been thoroughly explored, but much less is known about the mutagenic effects of DNA lesions present in clustered damage sites. Localized clustering of damage is a hallmark of certain DNA-damaging agents, particularly ionizing radiation. We have investigated the potential of a non-mutagenic DNA base lesion, 5,6-dihydrothymine (DHT), to influence the mutagenicity of 8-oxo-7,8-dihydroguanine (8-oxoG) when the two lesions are closely opposed. Using a bacterial plasmid-based assay we present the first report of a significantly higher mutation frequency for the clustered DHT and 8-oxoG lesions than for single 8-oxoG in wild-type and in glycosylase-deficient strains. We propose that endonuclease III has an important role in the initial stages of processing DHT/8-oxoG clusters, removing DHT to give an intermediate with an abasic site or single-strand break opposing 8-oxoG. We suggest that this mutagenic intermediate is common to several different combinations of base lesions forming clustered DNA damage sites. The MutY glycosylase, acting post-replication, is most important for reducing mutation formation. Recovered plasmids commonly gave rise to both wild-type and mutant progeny, suggesting that there is differential replication of the two DNA strands carrying specific forms of base damage.

Repair and mutagenesis at oxidized DNA lesions in the developing brain of wild-type and Ogg1-/- mice

OGG1 (8-oxoguanine DNA glycosylase-1) is one of the main DNA glycosylases present in mammalian cells. The enzyme removes 7,8-dihydro-8-oxoguanine (8-oxoG) lesions, believed to be the most important oxidized lesions due to their relatively high incidence and their miscoding properties. This study shows that in prenatal mice brains the repair capacity for 8-oxoG is 5-10-fold higher than in adult mice brains. Western blot analysis and repair activity in extracts from Ogg1(-/-) mice revealed that OGG1 was responsible for the efficient 8-oxoG removal from prenatal mice. To investigate how OGG1 protects against oxidative stress-induced mutagenesis, pregnant Big Blue/wild-type and Big Blue/Ogg1(-/-) mice were exposed to nontoxic doses of gamma radiation. A 2.5-fold increase in the mutation frequency in Ogg1(-/-) mouse brains was obtained by exposure to 3.5 Gy at day 19 postfertilization. This was largely due to GC to TA transversions, believed to originate from 8-oxoG mispairing with A during replication. Furthermore, rapid cell divisions seemed to be required for fixation of mutations, as a similar dose of radiation did not increase the mutation frequency, or the frequency of GC to TA transversion, in the adult brain.

Cytosine methylation and DNA repair

Cytosine methylation is a common form of post-replicative DNA modification seen in both bacteria and eukaryotes. Modified cytosines have long been known to act as hotspots for mutations due to the high rate of spontaneous deamination of this base to thymine, resulting in a G/T mismatch. This will be fixed as a C-->T transition after replication if not repaired by the base excision repair (BER) pathway or specific repair enzymes dedicated to this purpose. This hypermutability has led to depletion of the target dinucleotide CpG outside of special CpG islands in mammals, which are normally unmethylated. We review the importance of C-->T transitions at non-island CpGs in human disease: When these occur in the germline, they are a common cause of inherited diseases such as epidermolysis bullosa and mucopolysaccharidosis, while in the soma they are frequently found in the genes for tumor suppressors such as p53 and the retinoblastoma protein, causing cancer. We also examine the specific repair enzymes involved, namely the endonuclease Vsr in Escherichia coli and two members of the uracil DNA glycosylase (UDG) superfamily in mammals, TDG and MBD4. Repair brings its own problems, since it will require remethylation of the replacement cytosine, presumably coupling repair to methylation by either the maintenance methylase Dnmt1 or a de novo enzyme such as Dnmt3a. Uncoupling of methylation from repair may be one way to remove methylation from DNA. We also look at the possible role of specific cytosine deaminases such as Aid and Apobec in accelerating deamination of methylcytosine and consequent DNA demethylation.

Uracil DNA glycosylase is dispensable for human immunodeficiency virus type 1 replication and does not contribute to the antiviral effects of the cytidine deaminase Apobec3G

It is well established that many host factors are involved in the replication of human immunodeficiency virus (HIV) type 1. One host protein, uracil DNA glycosylase 2 (UNG2), binds to multiple viral proteins and is packaged into HIV type 1 virions. UNG initiates the removal of uracils from DNA, and this has been proposed to be important both for reverse transcription and as a mediator to the antiviral effect of virion-incorporated Apobec3G, a cytidine deaminase that generates numerous uracils in the viral DNA during virus replication. We used a natural human UNG-/- cell line as well as cells that express a potent catalytic active-site inhibitor of UNG to assess the effects of removing UNG activity on HIV infectivity. In both cases, we find UNG2 activity and protein to be completely dispensable for virus replication. Moreover, we find that virion-associated UNG2 does not affect the loss of infectivity caused by Apobec3G.

Saccharomyces cerevisiae Ogg1 prevents poly(GT) tract instability in the mitochondrial genome

Reactive oxygen species can attack the mitochondrial genome to produce a vast array of oxidative DNA lesions including 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dGuo). We assess the role of the Saccharomyces cerevisiae 8-oxo-dGuo DNA glycosylase, Ogg1, in the maintenance of a poly(GT) tract reporter system present in the mitochondrial genome. Deletion in the poly(GT) tract causes the reporter system to produce arginine-independent (Arg+) colonies. We show that the mitochondrial form of Ogg1 is functionally active at processing 8-oxo-dGuo lesions and that Ogg1-deficient cells exhibit nearly six-fold elevated rate of Arg+ mutants under normal growth condition, as compared to the parent. Overexpression of Ogg1 completely suppressed the high rate of Arg+ mutations to levels lower than the parental, suggesting that Ogg1 function could be limited in the mitochondria. Further analysis revealed that the Arg+ mutations can be prevented if the cells are grown under anaerobic conditions. These findings provide in vivo evidence that oxidative stress induces the formation of lesions, most likely 8-oxo-dGuo, which must be repaired by Ogg1, otherwise the lesions can trigger poly(GT) tract instability in the mitochondrial genome. We also demonstrate that overproduction of the major apurinic/apyrimidinic (AP) endonuclease Apn1, a nuclear and mitochondrial enzyme with multiple DNA repair activities, substantially elevated the rate of Arg+ mutants, but which was counteracted by Ogg1 overexpression. We suggest that Ogg1 might bind to AP sites and protect this lesion from the spurious action of Apn1 overproduction. Thus, cleavage of AP site located within or in the vicinity of the poly(GT) tract could destabilize this repeat.

Repair of formamidopyrimidines in DNA involves different glycosylases: role of the OGG1, NTH1, and NEIL1 enzymes

The oxidatively induced DNA lesions 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyG) and 4,6-diamino-5-formamidopyrimidine (FapyA) are formed abundantly in DNA of cultured cells or tissues exposed to ionizing radiation or to other free radical-generating systems. In vitro studies indicate that these lesions are miscoding, can block the progression of DNA polymerases, and are substrates for base excision repair. However, no study has yet addressed how these lesions are metabolized in cellular extracts. The synthesis of oligonucleotides containing FapyG and FapyA at defined positions was recently reported. These constructs allowed us to investigate the repair of Fapy lesions in nuclear and mitochondrial extracts from wild type and knock-out mice lacking the two major DNA glycosylases for repair of oxidative DNA damage, OGG1 and NTH1. The background level of FapyG/FapyA in DNA from these mice was also determined. Endogenous FapyG levels in liver DNA from wild type mice were significantly higher than 8-hydroxyguanine levels. FapyG and FapyA were efficiently repaired in nuclear and mitochondrial extracts from wild type animals but not in the glycosylase-deficient mice. Our results indicated that OGG1 and NTH1 are the major DNA glycosylases for the removal of FapyG and FapyA, respectively. Tissue-specific analysis suggested that other DNA glycosylases may contribute to FapyA repair when NTH1 is poorly expressed. We identified NEIL1 in liver mitochondria, which could account for the residual incision activity in the absence of OGG1 and NTH1. FapyG and FapyA levels were significantly elevated in DNA from the knock-out mice, underscoring the biological role of OGG1 and NTH1 in the repair of these lesions.

No Major Role for 7,8-Dihydro-8-oxoguanine in Ultraviolet Light-Induced Mutagenesis

Oxidative DNA damage, in particular 7,8-dihydro-8-oxoguanine (8-oxoG), has been suggested to mediate mutation formation and malignant transformation after exposure of the skin to long-wave ultraviolet (UVA) light. It is processed primarily by the base excision repair (BER) pathway. The initial step of BER is the removal of the damaged base by a damage-specific DNA-glycosylase, which is 8-oxoG DNA glycosylase (OGG1) for 8-oxoG. To study the contribution of 8-oxoG to UVA-light mutagenesis, we compared UVA- and UVB-light-induced mutation frequencies in mouse embryonal fibroblasts from OGG1 knockout mice and their OGG1-intact littermates using the ouabain mutagenesis assay. After irradiation with various doses of UVA or UVB radiation, mutations in the Na,K-ATPase gene of single cells were detected by testing for colony-forming ability in a selective medium. OGG1-/- cells did not exhibit an increased frequency of UV-light-induced mutations compared to OGG1+/+ cells after exposure to either UVA or UVB radiation. This indicates that 8-oxoG, which is processed by OGG1, does not contribute significantly to either UVA- or UVB-light-induced mutagenesis.

B cells from hyper-IgM patients carrying UNG mutations lack ability to remove uracil from ssDNA and have elevated genomic uracil

The generation of high-affinity antibodies requires somatic hypermutation (SHM) and class switch recombination (CSR) at the immunoglobulin (Ig) locus. Both processes are triggered by activation-induced cytidine deaminase (AID) and require UNG-encoded uracil-DNA glycosylase. AID has been suggested to function as an mRNA editing deaminase or as a single-strand DNA deaminase. In the latter model, SHM may result from replicative incorporation of dAMP opposite U or from error-prone repair of U, whereas CSR may be triggered by strand breaks at abasic sites. Here, we demonstrate that extracts of UNG-proficient human B cell lines efficiently remove U from single-stranded DNA. In B cell lines from hyper-IgM patients carrying UNG mutations, the single-strand–specific uracil-DNA glycosylase, SMUG1, cannot complement this function. Moreover, the UNG mutations lead to increased accumulation of genomic uracil. One mutation results in an F251S substitution in the UNG catalytic domain. Although this UNG form was fully active and stable when expressed in Escherichia coli, it was mistargeted to mitochondria and degraded in mammalian cells. Our results may explain why SMUG1 cannot compensate the UNG2 deficiency in human B cells, and are fully consistent with the DNA deamination model that requires active nuclear UNG2. Based on our findings and recent information in the literature, we present an integrated model for the initiating steps in CSR.

Induction of the human oxidized base-specific DNA glycosylase NEIL1 by reactive oxygen species

NEIL1, a mammalian DNA glycosylase and ortholog of Escherichia coli Nei/Fpg, is involved in the repair of oxidatively damaged bases in mammalian cells. Exposure of HCT116 human colon carcinoma cells to reactive oxygen species, generated by glucose oxidase (GO), enhanced the levels of NEIL1 mRNA and polypeptide by 2-4-fold by 6 h after GO treatment. A similar oxidative stress-induced increase in human NEIL1 (hNEIL1) promoter-dependent luciferase expression in HCT116 cells indicates that reactive oxygen species activates NEIL1 transcription. The transcriptional start site of hNEIL1 was mapped, and the upstream promoter sequence was characterized via luciferase reporter assay. Two identical CRE/AP-1-binding sites were identified in the promoter that binds transcription factors c-Jun and CREB/ATF2. This binding was significantly enhanced in extracts of cells treated with GO. Furthermore, a simultaneous increase in the level of phosphorylated c-Jun suggests its involvement in up-regulating the NEIL1 promoter. Oxidative stress-induced activation of NEIL1 appears to be involved in the feedback regulation of cellular repair activity needed to handle an increase in the level of oxidative base damage.

Roles of base excision repair enzymes Nth1p and Apn2p from Schizosaccharomyces pombe in processing alkylation and oxidative DNA damage

Schizosaccharomyces pombe Nthpl, an ortholog of the endonuclease III family, is the sole bifunctional DNA glycosylase encoded in its genome. The enzyme removes oxidative pyrimidine and incises 3' to the apurinic/apyrimidinic (AP) site, leaving 3'-alpha,beta-unsaturated aldehyde. Analysis of nth1 cDNA revealed an intronless structure including 5'- and 3'-untranslated regions. An Nth1p-green fluorescent fusion protein was predominantly localized in the nuclei of yeast cells, indicating a nuclear function. Deletion of nth1 confirmed that Nth1p is responsible for the majority of activity for thymine glycol and AP site incision in the absence of metal ions, while nth1 mutants exhibit hypersensitivity to methylmethanesulfonate (MMS). Complementation of sensitivity by heterologous expression of various DNA glycosylases showed that the methyl-formamidopyrimidine (me-fapy) and/or AP sites are plausible substrates for Nth1p in repairing MMS damage. Apn2p, the major AP endonuclease in S. pombe, also greatly contributes to the repair of MMS damage. Deletion of nth1 from an apn2 mutant resulted in tolerance to MMS damage, indicating that Nth1p-induced 3'-blocks are responsible for MMS sensitivity in apn2 mutants. Overexpression of Apn2p in nth1 mutants failed to suppress MMS sensitivity. These results indicate that Nth1p, not Apn2p, primarily incises AP sites and that the resultant 3'-blocks are removed by the 3'-phosphodiesterase activity of Apn2p. Nth1p is dispensable for cell survival against low levels of oxidative stress, but wild-type yeast became more sensitive than the nth1 mutant at high levels. Overexpression of Nth1p in heavily damaged cells probably induced cell death via the formation of 3'-blocked single-strand breaks.

Antimutator role of DNA glycosylase MutY in pathogenic Neisseria species

Genome alterations due to horizontal gene transfer and stress constantly generate strain on the gene pool of Neisseria meningitidis, the causative agent of meningococcal (MC) disease. The DNA glycosylase MutY of the base excision repair pathway is involved in the protection against oxidative stress. MC MutY expressed in Escherichia coli exhibited base excision activity towards DNA substrates containing A:7,8-dihydro-8-oxo-2'-deoxyguanosine and A:C mismatches. Expression in E. coli fully suppressed the elevated spontaneous mutation rate found in the E. coli mutY mutant. An assessment of MutY activity in lysates of neisserial wild-type and mutY mutant strains showed that both MC and gonococcal (GC) MutY is expressed and active in vivo. Strikingly, MC and GC mutY mutants exhibited 60- to 140-fold and 20-fold increases in mutation rates, respectively, compared to the wild-type strains. Moreover, the differences in transitions and transversions in rpoB conferring rifampin resistance observed with the wild type and mutants demonstrated that the neisserial MutY enzyme works in preventing GC-->AT transversions. These findings are important in the context of models linking mutator phenotypes of disease isolates to microbial fitness.

Gardening the genome: DNA methylation in Arabidopsis thaliana

DNA methylation has two essential roles in plants and animals - defending the genome against transposons and regulating gene expression. Recent experiments in Arabidopsis thaliana have begun to address crucial questions about how DNA methylation is established and maintained. One cardinal insight has been the discovery that DNA methylation can be guided by small RNAs produced through RNA-interference pathways. Plants and mammals use a similar suite of DNA methyltransferases to propagate DNA methylation, but plants have also developed a glycosylase-based mechanism for removing DNA methylation, and there are hints that similar processes function in other organisms.

Substantial decrease of urinary 8-oxo-7,8-dihydroguanine, a product of the base excision repair pathway, in DNA glycosylase defective mice

Genome integrity is maintained via removal (repair) of DNA lesions and an increased load of such DNA damage has been linked to numerous pathological conditions, including carcinogenesis and ageing. 8-Oxo-7,8-dihydroguanine is one of the most critical lesions of this type. The free 8-oxo-7,8-dihydroguanine produced by the action of a specific DNA glycosylase is a potential source of this compound in urine. To date, there has been no direct, experimental evidence demonstrating that urinary 8-oxo-7,8-dihydroguanine is produced by the base excision repair pathway. For clarification of this issue, we applied a recently developed methodology which involved high performance liquid chromatography pre-purification followed by gas chromatography with isotope dilution mass spectrometric detection to compare the urinary excretion rate of 8-oxo-7,8-dihydroguanine in wild type and OGG1 glycosylase knock out mice. Our study revealed a 26% reduction in urinary level of 8-oxo-7,8-dihydroguanine in OGG1 deficient mice in comparison with the wild type strain. This clearly indicates that the mouse OGG1 glycosylase contributes significantly to the generation of urinary 8-oxo-7,8-dihydroguanine. Therefore, urinary measurements of 8-oxo-7,8-dihydroguanine may be attributed to DNA damage and repair, which in turn suggests that they may be useful in studying associations between DNA repair and disease.

Induction of OGG1 gene expression by HIV-1 Tat

To identify the cellular gene target for Tat, we performed gene expression profile analysis and found that Tat up-regulates the expression of the OGG1 (8-oxoguanine-DNA glycosylase-1) gene, which encodes an enzyme responsible for repairing the oxidatively damaged guanosine, 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dG). We observed that Tat induced OGG1 gene expression by enhancing its promoter activity without changing its mRNA stability. We found that the upstream AP-4 site within the OGG1 promoter is responsible and that Tat interacted with AP-4 and removed AP-4 from the OGG1 promoter by in vivo chromatin immunoprecipitation assay. Thus, Tat appears to activate OGG1 expression by sequestrating AP-4. Interestingly, although Tat induces oxidative stress known to generate 8-oxo-dG, which causes the G:C to T:A transversion, we observed that the amount of 8-oxo-dG was reduced by Tat. When OGG1 was knocked down by small interfering RNA, Tat increased the amount of 8-oxo-dG, thus confirming the role of OGG1 in preventing the formation of 8-oxo-dG. These findings collectively indicate the possibility that Tat may play a role in maintenance of the genetic integrity of the proviral and host cellular genomes by up-regulating OGG1 as a feed-forward mechanism.

The contested role of uracil DNA glycosylase in immunoglobulin gene diversification

Class switch recombination (CSR) and somatic hypermutation (SHM) of immunoglobulin (Ig) genes are initiated by the activation-induced cytosine deaminase AID. The resulting uracils in Ig genes were believed to be removed by the uracil glycosylase (UNG) and the resulting abasic sites treated in an error-prone fashion, creating breaks in the Ig switch regions and mutations in the variable regions. A recent report suggests that UNG does not act as a glycosylase in CSR and SHM but rather has unknown activity subsequent to DNA breaks that were created by other mechanisms.

Increased Flexibility as a Strategy for Cold Adaptation

Uracil DNA glycosylase (UDG) is a DNA repair enzyme in the base excision repair pathway and removes uracil from the DNA strand. Atlantic cod UDG (cUDG), which is a cold-adapted enzyme, has been found to be up to 10 times more catalytically active in the temperature range 15-37 degrees C as compared with the warm-active human counterpart. The increased catalytic activity of cold-adapted enzymes as compared with their mesophilic homologues are partly believed to be caused by an increase in the structural flexibility. However, no direct experimental evidence supports the proposal of increased flexibility of cold-adapted enzymes. We have used molecular dynamics simulations to gain insight into the structural flexibility of UDG. The results from these simulations show that an important loop involved in DNA recognition (the Leu(272) loop) is the most flexible part of the cUDG structure and that the human counterpart has much lower flexibility in the Leu(272) loop. The flexibility in this loop correlates well with the experimental k(cat)/K(m) values. Thus, the data presented here add strong support to the idea that flexibility plays a central role in adaptation to cold environments.