Isolating Contributions from Intersegmental Transfer to DNA Searching by Alkyladenine DNA Glycosylase

Large genomes pose a challenge to DNA repair pathways because rare sites of damage must be efficiently located from among a vast excess of undamaged sites. Human alkyladenine DNA glycosylase (AAG) employs nonspecific DNA binding interactions and facilitated diffusion to conduct a highly redundant search of adjacent sites. This ensures that every site is searched, but could be a detriment if the protein is trapped in a local segment of DNA. Intersegmental transfer between DNA segments that are transiently in close proximity provides an elegant solution that balances global and local searching processes. It has been difficult to detect intersegmental transfer experimentally; therefore, we developed biochemical assays that allowed us to observe and measure the rates of intersegmental transfer by AAG. AAG has a flexible amino terminus that tunes its affinity for nonspecific DNA, but we find that it is not required for intersegmental transfer. As AAG has only a single DNA binding site, this argues against the bridging model for intersegmental transfer. The rates of intersegmental transfer are strongly dependent on the salt concentration, supporting a jumping mechanism that involves microscopic dissociation and capture by a proximal DNA site. As many DNA-binding proteins have only a single binding site, jumping may be a common mechanism for intersegmental transfer.     

DNA Sequence Context Effects on the Glycosylase Activity of Human 8-Oxoguanine DNA Glycosylase

Human 8-oxoguanine DNA glycosylase (OGG1) is a key enzyme involved in removing 7,8-dihydro-8-oxoguanine (8-oxoG), a highly mutagenic DNA lesion generated by oxidative stress. The removal of 8-oxoG by OGG1 is affected by the local DNA sequence, and this feature most likely contributes to observed mutational hot spots in genomic DNA. To elucidate the influence of local DNA sequence on 8-oxoG excision activity of OGG1, we conducted steady-state, pre-steady-state, and single turnover kinetic evaluation of OGG1 in alternate DNA sequence contexts. The sequence context effect was studied for a mutational hot spot at a CpG dinucleotide. Altering either the global DNA sequence or the 5′-flanking unmodified base pair failed to influence the excision of 8-oxoG. Methylation of the cytosine 5′ to 8-oxoG also did not affect 8-oxoG excision. In contrast, a 5′-neighboring mismatch strongly decreased the rate of 8-oxoG base removal. Substituting the 5′-C in the CpG dinucleotide with T, A, or tetrahydrofuran (i.e. T:G, A:G, and tetrahydrofuran:G mispairs) resulted in a 10-, 13-, and 4-fold decrease in the rate constant for 8-oxoG excision, respectively. A greater loss in activity was observed when T:C or A:C was positioned 5′ of 8-oxoG (59- and 108-fold, respectively). These results indicate that neighboring structural abnormalities 5′ to 8-oxoG deter its repair thereby enhancing its mutagenic potential.     

Microsatellite Instability in Chicken Lymphoma Induced by Gallid Herpesvirus 2

Microsatellite instability (MSI) has been found in a range of human tumors, and little is known of the links between MSI and herpesvirus. In order to investigate the relationship between MSI and Gallid herpesvirus 2 (GaHV-2)-induced lymphoma, fifteen Marek’s disease (MD) lymphomas were analyzed through using 46 microsatellite markers, which were amplified by PCR from DNA specimens of lymphoma and normal muscular tissues from the same chicken. PCR products were evaluated by denaturing polyacrylamide gel electrophoresis for MSI analysis. MSI was proved in all lymphomas, at least in one locus. Thirty of the 46 microsatellite markers had microsatellite alterations. These results suggested that GaHV-2-induced lymphoma in chickens is related to MSI, and this is the first report to demonstrate that MSI is associated with the GaHV-2 induced lymphoma in chicken.     

Conformational Dynamics of Damage Processing by Human DNA Glycosylase NEIL1

Endonuclease VIII-like protein 1 (NEIL1) is a DNA repair enzyme found in higher eukaryotes, including humans. It belongs to the helix–two turn–helix (H2TH) structural superfamily together with Escherichia coli formamidopyrimidine–DNA glycosylase (Fpg) and endonuclease VIII (Nei), and removes a variety of oxidized purine and pyrimidine bases from DNA. Structural, modeling and kinetic studies have established that the bacterial H2TH superfamily enzymes proceed through several conformational intermediates while recognizing and removing their cognate lesions. Here we apply stopped-flow kinetics with detection of intrinsic Trp fluorescence and Förster resonance energy transfer fluorescence to follow the conformational dynamics of human NEIL1 and DNA when the enzyme interacts with undamaged DNA, or DNA containing cleavable or non-cleavable abasic sites, or dihydrouracil lesions. NEIL1 processed a natural abasic site and a damaged base in DNA equally well but showed an additional fluorescently discernible step when DHU was present, likely reflecting additional rearrangements during base eversion into the enzyme's active site. With undamaged DNA and DNA containing a non-cleavable abasic site analog, (3-hydroxytetrahydrofuran-2-yl)methyl phosphate, NEIL1 was diverted to a non-productive DNA conformation early in the reaction. Our results support the view of NEIL1 as an enzyme that actively destabilizes damaged DNA and uses multiple checkpoints along the reaction coordinate to drive substrate lesions into the active site while rejecting normal bases and non-substrate lesions.     

A Germline Polymorphism of Thymine DNA Glycosylase Induces Genomic Instability and Cellular Transformation

Thymine DNA glycosylase (TDG) functions in base excision repair, a DNA repair pathway that acts in a lesion-specific manner to correct individual damaged or altered bases. TDG preferentially catalyzes the removal of thymine and uracil paired with guanine, and is also active on 5-fluorouracil (5-FU) paired with adenine or guanine. The rs4135113 single nucleotide polymorphism (SNP) of TDG is found in 10% of the global population. This coding SNP results in the alteration of Gly199 to Ser. Gly199 is part of a loop responsible for stabilizing the flipped abasic nucleotide in the active site pocket. Biochemical analyses indicate that G199S exhibits tighter binding to both its substrate and abasic product. The persistent accumulation of abasic sites in cells expressing G199S leads to the induction of double-strand breaks (DSBs). Cells expressing the G199S variant also activate a DNA damage response. When expressed in cells, G199S induces genomic instability and cellular transformation. Together, these results suggest that individuals harboring the G199S variant may have increased risk for developing cancer.     

A Major Role for Bacteriophage T4 DNA Polymerase in Frameshift Mutagenesis

T4 DNA polymerase strongly influences the frequency and specificity of frameshift mutagenesis. Fifteen of 19 temperature-sensitive alleles of the DNA polymerase gene substantially influenced the reversion frequencies of frameshift mutations measured in the T4 rII genes. Most polymerase mutants increased frameshift frequencies, but a few alleles (previously noted as antimutators for base substitution mutations) decreased the frequencies of certain frameshifts while increasing the frequencies of others. The various patterns of enhanced or decreased frameshift mutation frequencies suggest that T4 DNA polymerase is likely to play a variety of roles in the metabolic events leading to frameshift mutation. A detailed genetic study of the specificity of the mutator properties of three DNA polymerase alleles (tsL56, tsL98 and tsL88) demonstrated that each produces a distinctive frameshift spectrum. Differences in frameshift frequencies at similar DNA sequences within the rII genes, the influence of mutant polymerase alleles on these frequencies, and the presence or absence of the dinucleotide sequence associated with initiation of Okazaki pieces at the frameshift site has led us to suggest that the discontinuities associated with discontinuous DNA replication may contribute to spontaneous frameshift mutation frequencies in T4.     

DNA Sequences of Frameshift and Other Mutations Induced by Icr-170 in Yeast

ICR-170-induced mutations in the CYC1 gene of the yeast Saccharomyces cerevisiae were investigated by genetic and DNA sequence analyses. Genetic analysis of 33 cyc1 mutations induced by ICR-170 and sequence analysis of eight representatives demonstrated that over one-third were frameshift mutations that occurred at one site corresponding to amino acid positions 29-30, whereas the remaining mutations were distributed more-or-less randomly, and a few of these were not frameshift mutations. The sequence results indicate that ICR-170 primarily induces G.C additions at sites containing monotonous runs of three G.C base pairs. However, some (Formula: see text) sites within the CYC1 gene were not mutated by ICR-170. Thus, ICR-170 is a relatively specific mutagen that preferentially acts on certain sites with monotonous runs of G.C base pairs.     

Highly Frequent Frameshift DNA Synthesis by Human DNA Polymerase μ

DNA polymerase mu (Polmu) is a newly identified member of the polymerase X family. The biological function of Polmu is not known, although it has been speculated that human Polmu may be a somatic hypermutation polymerase. To help understand the in vivo function of human Polmu, we have performed in vitro biochemical analyses of the purified polymerase. Unlike any other DNA polymerases studied thus far, human Polmu catalyzed frameshift DNA synthesis with an unprecedentedly high frequency. In the sequence contexts examined, -1 deletion occurred as the predominant DNA synthesis mechanism opposite the single-nucleotide repeat sequences AA, GG, TT, and CC in the template. Thus, the fidelity of DNA synthesis by human Polmu was largely dictated by the sequence context. Human Polmu was able to efficiently extend mismatched bases mainly by a frameshift synthesis mechanism. With the primer ends, containing up to four mismatches, examined, human Polmu effectively realigned the primer to achieve annealing with a microhomology region in the template several nucleotides downstream. As a result, human Polmu promoted microhomology search and microhomology pairing between the primer and the template strands of DNA. These results show that human Polmu is much more prone to cause frameshift mutations than base substitutions. The biochemical properties of human Polmu suggest a function in nonhomologous end joining and V(D)J recombination through its microhomology searching and pairing activities but do not support a function in somatic hypermutation.     

Accelerated Repair and Reduced Mutagenicity of DNA Damage Induced by Cigarette Smoke in Human Bronchial Cells Transfected with E.coli Formamidopyrimidine DNA Glycosylase

Cigarette smoke (CS) is associated to a number of pathologies including lung cancer. Its mutagenic and carcinogenic effects are partially linked to the presence of reactive oxygen species and polycyclic aromatic hydrocarbons (PAH) inducing DNA damage. The bacterial DNA repair enzyme formamidopyrimidine DNA glycosylase (FPG) repairs both oxidized bases and different types of bulky DNA adducts. We investigated in vitro whether FPG expression may enhance DNA repair of CS-damaged DNA and counteract the mutagenic effects of CS in human lung cells. NCI-H727 non small cell lung carcinoma cells were transfected with a plasmid vector expressing FPG fused to the Enhanced Green Fluorescent Protein (EGFP). Cells expressing the fusion protein EGFP-FPG displayed accelerated repair of adducts and DNA breaks induced by CS condensate. The mutant frequencies induced by low concentrations of CS condensate to the Na⁺K⁺-ATPase locus (oua^r) were significantly reduced in cells expressing EGFP-FPG. Hence, expression of the bacterial DNA repair protein FPG stably protects human lung cells from the mutagenic effects of CS by improving cells’ capacity to repair damaged DNA.     

Regulation of Human MutYH DNA Glycosylase by the E3 Ubiquitin Ligase Mule

Oxidation of DNA is a frequent and constantly occurring event. One of the best characterized oxidative DNA lesions is 7,8-dihydro-8-oxoguanine (8-oxo-G). It instructs most DNA polymerases to preferentially insert an adenine (A) opposite 8-oxo-G instead of the appropriate cytosine (C) thus showing miscoding potential. The MutY DNA glycosylase homologue (MutYH) recognizes A:8-oxo-G mispairs and removes the mispaired A giving way to the canonical base excision repair that ultimately restores undamaged guanine (G). Here we characterize for the first time in detail a posttranslational modification of the human MutYH DNA glycosylase. We show that MutYH is ubiquitinated in vitro and in vivo by the E3 ligase Mule between amino acids 475 and 535. Mutation of five lysine residues in this region significantly stabilizes MutYH, suggesting that these are the target sites for ubiquitination. The endogenous MutYH protein levels depend on the amount of expressed Mule. Furthermore, MutYH and Mule physically interact. We found that a ubiquitination-deficient MutYH mutant shows enhanced binding to chromatin. The mutation frequency of the ovarian cancer cell line A2780, analyzed at the HPRT locus can be increased upon oxidative stress and depends on the MutYH levels that are regulated by Mule. This reflects the importance of tightly regulated MutYH levels in the cell. In summary our data show that ubiquitination is an important regulatory mechanism for the essential MutYH DNA glycosylase in human cells.     

Association of Induced Frameshift Mutagenesis and DNA Replication in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The induction of frameshifts in E. coli seems to be associated with chromosome replication.     

DNA Damage Processing by Human 8-Oxoguanine-DNA Glycosylase Mutants with the Occluded Active Site

8-Oxoguanine-DNA glycosylase (OGG1) removes premutagenic lesion 8-oxoguanine (8-oxo-G) from DNA and then nicks the nascent abasic (apurinic/apyrimidinic) site by β-elimination. Although the structure of OGG1 bound to damaged DNA is known, the dynamic aspects of 8-oxo-G recognition are not well understood. To comprehend the mechanisms of substrate recognition and processing, we have constructed OGG1 mutants with the active site occluded by replacement of Cys-253, which forms a wall of the base-binding pocket, with bulky leucine or isoleucine. The conformational dynamics of OGG1 mutants were characterized by single-turnover kinetics and stopped-flow kinetics with fluorescent detection. Additionally, the conformational mobility of wild type and the mutant OGG1 substrate complex was assessed using molecular dynamics simulations. Although pocket occlusion distorted the active site and greatly decreased the catalytic activity of OGG1, it did not fully prevent processing of 8-oxo-G and apurinic/apyrimidinic sites. Both mutants were notably stimulated in the presence of free 8-bromoguanine, indicating that this base can bind to the distorted OGG1 and facilitate β-elimination. The results agree with the concept of enzyme plasticity, suggesting that the active site of OGG1 is flexible enough to compensate partially for distortions caused by mutation.     

Changes in DNA Base Sequence Induced by Gamma-Ray Mutagenesis of Lambda Phage and Prophage

Mutations in the cI (repressor) gene were induced by gamma-ray irradiation of lambda phage and of prophage, and 121 mutations were sequenced. Two-thirds of the mutations in irradiated phage assayed in recA host cells (no induction of the SOS response) were G:C to A:T transitions; it is hypothesized that these may arise during DNA replication from adenine mispairing with a cytosine product deaminated by irradiation. For irradiated phage assayed in host cells in which the SOS response had been induced, 85% of the mutations were base substitutions, and in 40 of the 41 base changes, a preexisting base pair had been replaced by an A:T pair; these might come from damaged bases acting as AP (apurinic or apyrimidinic) sites. The remaining mutations were 1 and 2 base deletions. In irradiated prophage, base change mutations involved the substitution of both A:T and of G:C pairs for the preexisting pairs; the substitution of G:C pairs shows that some base substitution mechanism acts on the cell genome but not on the phage. In the irradiated prophage, frameshifts and a significant number of gross rearrangements were also found.     

Frameshift mutagenesis by eucaryotic DNA polymerases in vitro

The frequency and specificity of frameshift errors produced during a single round of in vitro DNA synthesis by DNA polymerases-alpha, -beta, and -gamma (pol-alpha, -beta, and -gamma, respectively) have been determined. DNA polymerase-beta is the least accurate enzyme, producing frameshift errors at an average frequency of one error for each 1,000-3,000 nucleotides polymerized, a frequency similar to its average base substitution accuracy. DNA polymerase-alpha is approximately 10-fold more accurate, producing frameshifts at an average frequency of one error for every 10,000-30,000 nucleotides polymerized, a frequency which is about 2- to 6-fold lower than the average pol-alpha base substitution accuracy. DNA polymerase-gamma is highly accurate, producing on the average less than one frameshift error for every 200,000-400,000 nucleotides polymerized. This represents a more than 10-fold higher fidelity than for base substitutions. Among the collection of sequenced frameshifts produced by DNA polymerases-alpha and beta, both common features and distinct specificities are apparent. These specificities suggest a major role for eucaryotic DNA polymerases in modulating frameshift fidelity. Possible mechanisms for production of frameshifts are discussed in relation to the observed biases. One of these models has been experimentally supported using site-directed mutagenesis to change the primary DNA sequence of the template. Alteration of a pol-beta frameshift hotspot sequence TTTT to CTCT reduced the frequency of pol-beta-dependent minus-one-base errors at this site by more than 30-fold, suggesting that more than 97% of the errors at the TTTT run involve a slippage mechanism.     

人巨细胞病毒DNA疫苗免疫效果的初步研究

人巨细胞病毒(HCMV)是广泛感染人类的重要病原体之一,在人群中有较高的感染率,胎儿、婴儿、器官移植及免疫缺陷者等更易感染.现有的抗HCMV药物治疗及被动免疫由于毒性大、价格昂贵及短效性等原因,应用大受限制,为此研制安全、有效的疫苗即成为防治HCMV疾病的重要手段.HCMV具有潜在的致癌作用,不宜发展活疫苗或含完整病毒DNA的死疫苗;亚单位疫苗虽然比较安全,但所用抗原不能在宿主细胞内表达,只能诱导体液免疫,这对于胞内感染的HCMV预防效果较差;通过新佐剂的应用,虽可引发细胞免疫,但免疫原性较差,且成本较高.因此,目前倾向于研制具有免疫原性的HCMV DNA疫苗.     

The Development of Chronic Obstructive Pulmonary Diseases Correlates with Microsatellite DNA Instability

Allele distribution at a highly polymorphic minisatellite adjacent to the c-Hras1 gene as well as deletions of microsatellite markers, D3S966, D3S1298, D9S171, and a microsatellite within p53 gene, were examined in bronchial epithelium specimens obtained from 53 chronic obstructive pulmonary disease (COPD) patients and healthy donors. A higher frequency of rare Hras1minisatellite alleles in COPD patients than in the individuals without pulmonary pathology (6.6% versus 2.2%; P < 0.05) was shown. This difference was most pronounced in the group of ten COPD patients with idiopathic pulmonary fibrosis. Three of these patients had rare Hras1 minisatellite allele (P < 0.02 in comparison with healthy controls). Alterations in at least one of the microsatellite markers (deletions or microsatellite instability) were detected in bronchial epithelium samples obtained from: 4 of 10 COPD patients with pneumofibrosis (40%); 15 of 43 COPD patients (34.9%) without pneumofibrosis; and 8 of 20 tobacco smokers (40%) without pulmonary pathology. These defects were not observed in the analogous samples obtained from healthy nonsmoking individuals. No statistically significant differences were revealed between COPD patients and healthy smokers upon comparison of both the total number of molecular defects and the number of defects in the individual chromosomal loci. The total number of molecular defects revealed in bronchial epithelium samples from the individuals of two groups examined correlated with the intensity of exposure to tobacco smoke carcinogens (r = 0.28; P < 0.05). These findings suggest that rare alleles at theHras1 locus may be associated with hereditary predisposition to COPD and the development of pneumofibrosis, while mutations in microsatellite markers result from exposure to tobacco smoke carcinogens and are not associated with the appearance of these pathologies.     

Role of Two Strictly Conserved Residues in Nucleotide Flipping and N-Glycosylic Bond Cleavage by Human Thymine DNA Glycosylase

Thymine DNA glycosylase (TDG) promotes genomic integrity by excising thymine from mutagenic G·T mismatches arising by deamination of 5-methylcytosine, and follow-on base excision repair enzymes restore a G·C pair. TDG cleaves the N-glycosylic bond of dT and some other nucleotides, including 5-substituted 2′-deoxyuridine analogs, once they have been flipped from the helix into its active site. We examined the role of two strictly conserved residues; Asn¹⁴⁰, implicated in the chemical step, and Arg²⁷⁵, implicated in nucleotide flipping. The N140A variant binds substrate DNA with the same tight affinity as wild-type TDG, but it has no detectable base excision activity for a G·T substrate, and its excision rate is vastly diminished (by ∼10^4.4-fold) for G·U, G·FU, and G·BrU substrates. Thus, Asn¹⁴⁰ does not contribute substantially to substrate binding but is essential for the chemical step, where it stabilizes the transition state by ∼6 kcal/mol (compared with 11.6 kcal/mol stabilization provided by TDG overall). Our recent crystal structure revealed that Arg²⁷⁵ penetrates the DNA minor groove, filling the void created by nucleotide flipping. We found that the R275A and R275L substitutions weaken substrate binding and substantially decrease the base excision rate for G·T and G·BrU substrates. Our results indicate that Arg²⁷⁵ promotes and/or stabilizes nucleotide flipping, a role that is most important for target nucleotides that are relatively large (dT and bromodeoxyuridine) and/or have a stable N-glycosylic bond (dT). Arg²⁷⁵ does not contribute substantially to the binding of TDG to abasic DNA product, and it cannot account for the slow product release exhibited by TDG.     

Dynamics and Conformational Changes in Human NEIL2 DNA Glycosylase Analyzed by Hydrogen/Deuterium Exchange Mass Spectrometry

Base excision DNA repair (BER) is necessary for removal of damaged nucleobases from the genome and their replacement with normal nucleobases. BER is initiated by DNA glycosylases, the enzymes that cleave the N-glycosidic bonds of damaged deoxynucleotides. Human endonuclease VIII-like protein 2 (hNEIL2), belonging to the helix–two-turn–helix structural superfamily of DNA glycosylases, is an enzyme uniquely specific for oxidized pyrimidines in non-canonical DNA substrates such as bubbles and loops. The structure of hNEIL2 has not been solved; its closest homologs with known structures are NEIL2 from opossum and from giant mimivirus. Here we analyze the conformational dynamics of free hNEIL2 using a combination of hydrogen/deuterium exchange mass spectrometry, homology modeling and molecular dynamics simulations. We show that a prominent feature of vertebrate NEIL2 – a large insert in its N-terminal domain absent from other DNA glycosylases – is unstructured in solution. It was suggested that helix–two-turn–helix DNA glycosylases undergo open–close transition upon DNA binding, with the large movement of their N- and C-terminal domains, but the open conformation has been elusive to capture. Our data point to the open conformation as favorable for free hNEIL2 in solution. Overall, our results are consistent with the view of hNEIL2 as a conformationally flexible protein, which may be due to its participation in the repair of non-canonical DNA structures and/or to the involvement in functional and regulatory protein–protein interactions.