Interactions of the human, rat, Saccharomyces cerevisiae and Escherichia coli 3-methyladenine-DNA glycosylases with DNA containing dIMP residues

Adenine transversion editors enable precise, efficient A•T-to-C•G base editing in mammalian cells and embryos

Base editors have substantial promise in basic research and as therapeutic agents for the correction of pathogenic mutations. The development of adenine transversion editors has posed a particular challenge. Here we report a class of base editors that enable efficient adenine transversion, including precise A•T-to-C•G editing. We found that a fusion of mouse alkyladenine DNA glycosylase (mAAG) with nickase Cas9 and deaminase TadA-8e catalyzed adenosine transversion in specific sequence contexts. Laboratory evolution of mAAG significantly increased A-to-C/T conversion efficiency up to 73% and expanded the targeting scope. Further engineering yielded adenine-to-cytosine base editors (ACBEs), including a high-accuracy ACBE-Q variant, that precisely install A-to-C transversions with minimal Cas9-independent off-targeting effects. ACBEs mediated high-efficiency installation or correction of five pathogenic mutations in mouse embryos and human cell lines. Founder mice showed 44-56% average A-to-C edits and allelic frequencies of up to 100%. Adenosine transversion editors substantially expand the capabilities and possible applications of base editing technology.

Structural and functional coupling in cross-linking uracil-DNA glycosylase UDGX

Enzymes in uracil-DNA glycosylase (UDG) superfamily are involved in removal of deaminated nucleobases such as uracil, methylcytosine derivatives such as formylcytosine and carboxylcytosine, and other base damage in DNA repair. UDGX is the latest addition of a new class to the UDG superfamily with a sporadic distribution in bacteria. UDGX type enzymes have a distinct biochemical property of cross-linking itself to the resulting AP site after uracil removal. Built on previous biochemical and structural analyses, this work comprehensively investigated the kinetic and enzymatic properties of Mycobacterium smegmatis UDGX. Kinetics and mutational analyses, coupled with structural information, defined the roles of E52, D56, D59, F65 of motif 1, H178 of motif 2 and N91, K94, R107 and H109 of motif 3 play in uracil excision and cross-linking. More importantly, a series of quantitative analyses underscored the structural coupling through inter-motif and intra-motif interactions and subsequent functional coupling of the uracil excision and cross-linking reactions. A catalytic model is proposed, which underlies this catalytic feature unique to UDGX type enzymes. This study offers new insight on the catalytic mechanism of UDGX and provides a unique example of enzyme evolution.

Biochemical characterization and mutational studies of a novel 3-methlyadenine DNA glycosylase II from the hyperthermophilic Thermococcus gammatolerans

The hyperthermophilic and radioresistant euryarchaeon Thermococcus gammatolerans encodes a putative 3-methlyadenine DNA glycosylase II (Tg-AlkA). Herein, we report biochemical characterization and catalytic mechanism of Tg-AlkA. The recombinant Tg-AlkA can excise hypoxanthine (Hx) and 1-methlyadenine (1-meA) from dsDNA with varied efficiencies at high temperature. Notably, Tg-AlkA is a bi-functional glycosylase, which is sharply distinct from all the reported AlkAs. Biochemical data show that the optimal temperature and pH of Tg-AlkA for removing Hx from dsDNA are ca.70 °C and ca.7.0-8.0, respectively. Furthermore, the Tg-AlkA activity is independent of a divalent metal ion, and Mg²⁺ stimulates the Tg-AlkA activity whereas other divalent ions inhibit the enzyme activity with varied degrees. Mutational studies show that the Tg-AlkA W204A and D223A mutants abolish completely the excision activity, thereby suggesting that residues W204 and D223 are involved in catalysis. Surprisingly, the mutations of W204, D223, Y139 and W256 to alanine in Tg-AlkA lead to the increased affinity for binding DNA substrate with varied degrees, suggesting that these residues are flexible for conformational change of the enzyme. Therefore, Tg-AlkA is a novel AlkA that can remove Hx and 1-meA from dsDNA, thus providing insights into repair of deaminated and alkylated bases in DNA from hyperthermophilic Thermococcus.

Deoxyinosine triphosphate induces MLH1/PMS2- and p53-dependent cell growth arrest and DNA instability in mammalian cells

Deoxyinosine (dI) occurs in DNA either by oxidative deamination of a previously incorporated deoxyadenosine residue or by misincorporation of deoxyinosine triphosphate (dITP) from the nucleotide pool during replication. To exclude dITP from the pool, mammals possess specific hydrolysing enzymes, such as inosine triphosphatase (ITPA). Previous studies have shown that deficiency in ITPA results in cell growth suppression and DNA instability. To explore the mechanisms of these phenotypes, we analysed ITPA-deficient human and mouse cells. We found that both growth suppression and accumulation of single-strand breaks in nuclear DNA of ITPA-deficient cells depended on MLH1/PMS2. The cell growth suppression of ITPA-deficient cells also depended on p53, but not on MPG, ENDOV or MSH2. ITPA deficiency significantly increased the levels of p53 protein and p21 mRNA/protein, a well-known target of p53, in an MLH1-dependent manner. Furthermore, MLH1 may also contribute to cell growth arrest by increasing the basal level of p53 activity.

The formation of catalytically competent enzyme-substrate complex is not a bottleneck in lesion excision by human alkyladenine DNA glycosylase

Human alkyladenine DNA glycosylase (AAG) protects DNA from alkylated and deaminated purine lesions. AAG flips out the damaged nucleotide from the double helix of DNA and catalyzes the hydrolysis of the N-glycosidic bond to release the damaged base. To understand better, how the step of nucleotide eversion influences the overall catalytic process, we performed a pre-steady-state kinetic analysis of AAG interaction with specific DNA-substrates, 13-base pair duplexes containing in the 7th position 1-N6-ethenoadenine (εA), hypoxanthine (Hx), and the stable product analogue tetrahydrofuran (F). The combination of the fluorescence of tryptophan, 2-aminopurine, and 1-N6-ethenoadenine was used to record conformational changes of the enzyme and DNA during the processes of DNA lesion recognition, damaged base eversion, excision of the N-glycosidic bond, and product release. The thermal stability of the duplexes characterized by the temperature of melting, T_m, and the rates of spontaneous opening of individual nucleotide base pairs were determined by NMR spectroscopy. The data show that the relative thermal stability of duplexes containing a particular base pair in position 7, (T_m(F/T) < T_m(εA/T) < T_m(Hx/T) < T_m(A/T)) correlates with the rate of reversible spontaneous opening of the base pair. However, in contrast to that, the catalytic lesion excision rate is two orders of magnitude higher for Hx-containing substrates than for substrates containing εA, proving that catalytic activity is not correlated with the stability of the damaged base pair. Our study reveals that the formation of the catalytically competent enzyme-substrate complex is not the bottleneck controlling the catalytic activity of AAG.

High resolution mapping of modified DNA nucleobases using excision repair enzymes

The incorporation and creation of modified nucleobases in DNA have profound effects on genome function. We describe methods for mapping positions and local content of modified DNA nucleobases in genomic DNA. We combined in vitro nucleobase excision with massively parallel DNA sequencing (Excision-seq) to determine the locations of modified nucleobases in genomic DNA. We applied the Excision-seq method to map uracil in E. coli and budding yeast and discovered significant variation in uracil content, wherein uracil is excluded from the earliest and latest replicating regions of the genome, possibly driven by changes in nucleotide pool composition. We also used Excision-seq to identify sites of pyrimidine dimer formation induced by UV light exposure, where the method could distinguish between sites of cyclobutane and 6-4 photoproduct formation. These UV mapping data enabled analysis of local sequence bias around pyrimidine dimers and suggested a preference for an adenosine downstream from 6-4 photoproducts. The Excision-seq method is broadly applicable for high precision, genome-wide mapping of modified nucleobases with cognate repair enzymes.

Endonuclease V cleaves at inosines in RNA

Endonuclease V orthologues are highly conserved proteins found in all kingdoms of life. While the prokaryotic enzymes are DNA repair proteins for removal of deaminated adenosine (inosine) from the genome, no clear role for the eukaryotic counterparts has hitherto been described. Here we report that human endonuclease V (ENDOV) and also Escherichia coli endonuclease V are highly active ribonucleases specific for inosine in RNA. Inosines are normal residues in certain RNAs introduced by specific deaminases. Adenosine-to-inosine editing is essential for proper function of these transcripts and defects are linked to various human disease. Here we show that human ENDOV cleaves an RNA substrate containing inosine in a position corresponding to a biologically important site for deamination in the Gabra-3 transcript of the GABA(A) neurotransmitter. Further, human ENDOV specifically incises transfer RNAs with inosine in the wobble position. This previously unknown RNA incision activity may suggest a role for endonuclease V in normal RNA metabolism.

ITPA (inosine triphosphate pyrophosphatase): from surveillance of nucleotide pools to human disease and pharmacogenetics

Cellular nucleotide pools are often contaminated by base analog nucleotides which interfere with a plethora of biological reactions, from DNA and RNA synthesis to cellular signaling. An evolutionarily conserved inosine triphosphate pyrophosphatase (ITPA) removes the non-canonical purine (d)NTPs inosine triphosphate and xanthosine triphosphate by hydrolyzing them into their monophosphate form and pyrophosphate. Mutations in the ITPA orthologs in model organisms lead to genetic instability and, in mice, to severe developmental anomalies. In humans there is genetic polymorphism in ITPA. One allele leads to a proline to threonine substitution at amino acid 32 and causes varying degrees of ITPA deficiency in tissues and plays a role in patients' response to drugs. Structural analysis of this mutant protein reveals that the protein is destabilized by the formation of a cavity in its hydrophobic core. The Pro32Thr allele is thought to cause the observed dominant negative effect because the resulting active enzyme monomer targets both homo- and heterodimers to degradation.

Modulation of mutagenesis in eukaryotes by DNA replication fork dynamics and quality of nucleotide pools

The rate of mutations in eukaryotes depends on a plethora of factors and is not immediately derived from the fidelity of DNA polymerases (Pols). Replication of chromosomes containing the anti-parallel strands of duplex DNA occurs through the copying of leading and lagging strand templates by a trio of Pols α, δ and ϵ, with the assistance of Pol ζ and Y-family Pols at difficult DNA template structures or sites of DNA damage. The parameters of the synthesis at a given location are dictated by the quality and quantity of nucleotides in the pools, replication fork architecture, transcription status, regulation of Pol switches, and structure of chromatin. The result of these transactions is a subject of survey and editing by DNA repair.

Human endonuclease V as a repair enzyme for DNA deamination

The human endonuclease V gene is located in chromosome 17q25.3 and encodes a 282 amino acid protein that shares about 30% sequence identity with bacterial endonuclease V. This study reports biochemical properties of human endonuclease V with respect to repair of deaminated base lesions. Using soluble proteins fused to thioredoxin at the N-terminus, we determined repair activities of human endonuclease V on deoxyinosine (I)-, deoxyxanthosine (X)-, deoxyoxanosine (O)- and deoxyuridine (U)-containing DNA. Human endonuclease V is most active with deoxyinosine-containing DNA but with minor activity on deoxyxanthosine-containing DNA. Endonuclease activities on deoxyuridine and deoxyoxanosine were not detected. The endonuclease activity on deoxyinosine-containing DNA follows the order of single-stranded I>G/I>T/I>A/I>C/I. The preference of the catalytic activity correlates with the binding affinity of these deoxyinosine-containing DNAs. Mg(2+) and to a much less extent, Mn(2+), Ni(2+), Co(2+) can support the endonuclease activity. Introduction of human endonuclease V into Escherichia coli cells deficient in nfi, mug and ung genes caused three-fold reduction in mutation frequency. This is the first report of deaminated base repair activity for human endonuclease V. The relationship between the endonuclease activity and deaminated deoxyadenosine (deoxyinosine) repair is discussed.

ITPA protein, an enzyme that eliminates deaminated purine nucleoside triphosphates in cells

Inosine triphosphate pyrophosphatase (ITPA protein) (EC 3.6.1.19) hydrolyzes deaminated purine nucleoside triphosphates, such as ITP and dITP, to their corresponding purine nucleoside monophosphate and pyrophosphate. In mammals, this enzyme is encoded by the Itpa gene. Using the Itpa gene-disrupted mouse as a model, we have elucidated the biological significance of the ITPA protein and its substrates, ITP and dITP. Itpa(-/-) mice exhibited peri- or post-natal lethality dependent on the genetic background. The heart of the Itpa(-/-) mouse was found to be structurally and functionally abnormal. Significantly higher levels of deoxyinosine and inosine were detected in nuclear DNA and RNA prepared from Itpa(-/-) embryos compared to wild type embryos. In addition, an accumulation of ITP was observed in the erythrocytes of Itpa(-/-) mice. We found that Itpa(-/-) primary mouse embryonic fibroblasts (MEFs), which have no detectable ability to generate IMP from ITP in whole cell extracts, exhibited a prolonged population-doubling time, increased chromosome abnormalities and accumulation of single-strand breaks in their nuclear DNA, in comparison to primary MEFs prepared from wild type embryos. These results revealed that (1) ITP and dITP are spontaneously produced in vivo and (2) accumulation of ITP and dITP is responsible for the harmful effects observed in the Itpa(-/-) mouse. In addition to its effect as the precursor nucleotide for RNA transcription, ITP has the potential to influence the activity of ATP/GTP-binding proteins. The biological significance of ITP and dITP in the nucleotide pool remains to be elucidated.

Evolution of the mutation rate

Understanding the mechanisms of evolution requires information on the rate of appearance of new mutations and their effects at the molecular and phenotypic levels. Although procuring such data has been technically challenging, high-throughput genome sequencing is rapidly expanding knowledge in this area. With information on spontaneous mutations now available in a variety of organisms, general patterns have emerged for the scaling of mutation rate with genome size and for the likely mechanisms that drive this pattern. Support is presented for the hypothesis that natural selection pushes mutation rates down to a lower limit set by the power of random genetic drift rather than by intrinsic physiological limitations, and that this has resulted in reduced levels of replication, transcription, and translation fidelity in eukaryotes relative to prokaryotes.

NUDT16 is a (deoxy)inosine diphosphatase, and its deficiency induces accumulation of single-strand breaks in nuclear DNA and growth arrest

Nucleotides function in a variety of biological reactions; however, they can undergo various chemical modifications. Such modified nucleotides may be toxic to cells if not eliminated from the nucleotide pools. We performed a screen for modified-nucleotide binding proteins and identified human nucleoside diphosphate linked moiety X-type motif 16 (NUDT16) protein as an inosine triphosphate (ITP)/xanthosine triphosphate (XTP)/GTP-binding protein. Recombinant NUDT16 hydrolyzes purine nucleoside diphosphates to the corresponding nucleoside monophosphates. Among 29 nucleotides examined, the highest k_cat/K_m values were for inosine diphosphate (IDP) and deoxyinosine diphosphate (dIDP). Moreover, NUDT16 moderately hydrolyzes (deoxy)inosine triphosphate ([d]ITP). NUDT16 is mostly localized in the nucleus, and especially in the nucleolus. Knockdown of NUDT16 in HeLa MR cells caused cell cycle arrest in S-phase, reduced cell proliferation, increased accumulation of single-strand breaks in nuclear DNA as well as increased levels of inosine in RNA. We thus concluded that NUDT16 is a (deoxy)inosine diphosphatase that may function mainly in the nucleus to protect cells from deleterious effects of (d)ITP.

Human AP endonuclease 1 stimulates multiple-turnover base excision by alkyladenine DNA glycosylase

Human alkyladenine DNA glycosylase (AAG) locates and excises a wide variety of damaged purine bases from DNA, including hypoxanthine that is formed by the oxidative deamination of adenine. We used steady state, pre-steady state, and single-turnover kinetic assays to show that the multiple-turnover excision of hypoxanthine in vitro is limited by release of the abasic DNA product. This suggests the possibility that the product release step is regulated in vivo by interactions with other base excision repair (BER) proteins. Such coordination of BER activities would protect the abasic DNA repair intermediate and ensure its correct processing. AP endonuclease 1 (APE1) is the predominant enzyme for processing abasic DNA sites in human cells. Therefore, we have investigated the functional effects of added APE1 on the base excision activity of AAG. We find that APE1 stimulates the multiple-turnover excision of hypoxanthine by AAG but has no effect on single-turnover excision. Since the amino terminus of AAG has been implicated in other protein-protein interactions, we also characterize the deletion mutant lacking the first 79 amino acids. We find that APE1 fully stimulates the multiple-turnover glycosylase activity of this mutant, demonstrating that the amino terminus of AAG is not strictly required for this functional interaction. These results are consistent with a model in which APE1 displaces AAG from the abasic site, thereby coordinating the first two steps of the base excision repair pathway.

Recognition and processing of a new repertoire of DNA substrates by human 3-methyladenine DNA glycosylase (AAG)

The human 3-methyladenine DNA glycosylase (AAG) recognizes and excises a broad range of purines damaged by alkylation and oxidative damage, including 3-methyladenine, 7-methylguanine, hypoxanthine (Hx), and 1,N(6)-ethenoadenine (epsilonA). The crystal structures of AAG bound to epsilonA have provided insights into the structural basis for substrate recognition, base excision, and exclusion of normal purines and pyrimidines from its substrate recognition pocket. In this study, we explore the substrate specificity of full-length and truncated Delta80AAG on a library of oligonucleotides containing structurally diverse base modifications. Substrate binding and base excision kinetics of AAG with 13 damaged oligonucleotides were examined. We found that AAG bound to a wide variety of purine and pyrimidine lesions but excised only a few of them. Single-turnover excision kinetics showed that in addition to the well-known epsilonA and Hx substrates, 1-methylguanine (m1G) was also excised efficiently by AAG. Thus, along with epsilonA and ethanoadenine (EA), m1G is another substrate that is shared between AAG and the direct repair protein AlkB. In addition, we found that both the full-length and truncated AAG excised 1,N(2)-ethenoguanine (1,N(2)-epsilonG), albeit weakly, from duplex DNA. Uracil was excised from both single- and double-stranded DNA, but only by full-length AAG, indicating that the N-terminus of AAG may influence glycosylase activity for some substrates. Although AAG has been primarily shown to act on double-stranded DNA, AAG excised both epsilonA and Hx from single-stranded DNA, suggesting the possible significance of repair of these frequent lesions in single-stranded DNA transiently generated during replication and transcription.

Repair of deaminated base damage by Schizosaccharomyces pombe thymine DNA glycosylase

Thymine DNA glycosylases (TDG) in eukaryotic organisms are known for their double-stranded glycosylase activity on guanine/uracil (G/U) base pairs. Schizosaccharomyces pombe (Spo) TDG is a member of the MUG/TDG family that belongs to a uracil DNA glycosylase superfamily. This work investigates the DNA repair activity of Spo TDG on all four deaminated bases: xanthine (X) and oxanine (O) from guanine, hypoxanthine (I) from adenine, and uracil from cytosine. Unexpectedly, Spo TDG exhibits glycosylase activity on all deaminated bases in both double-stranded and single-stranded DNA in the descending order of X>I>U>>O. In comparison, human TDG only excises deaminated bases from G/U and, to a much lower extent, A/U and G/I base pairs. Amino acid substitutions in motifs 1 and 2 of Spo TDG show a significant impact on deaminated base repair activity. The overall mutational effects are characterized by a loss of glycosylase activity on oxanine in all five mutants. L157I in motif 1 and G288M in motif 2 retain xanthine DNA glycosylase (XDG) activity but reduce excision of hypoxanthine and uracil, in particular in C/I, single-stranded hypoxanthine (ss-I), A/U, and single-stranded uracil (ss-U). A proline substitution at I289 in motif 2 causes a significant reduction in XDG activity and a loss of activity on C/I, ss-I, A/U, C/U, G/U, and ss-U. S291G only retains reduced activity on T/I and G/I base pairs. S163A can still excise hypoxanthine and uracil in mismatched base pairs but loses XDG activity, making it the closest mutant, functionally, to human TDG. The relationship among amino acid substitutions, binding affinity and base recognition is discussed.

Substrate specificity and sequence-dependent activity of the Saccharomyces cerevisiae 3-methyladenine DNA glycosylase (Mag)

DNA glycosylases initiate base excision repair by first binding, then excising aberrant DNA bases. Saccharomyces cerevisiae encodes a 3-methyladenine (3MeA) DNA glycosylase, Mag, that recognizes 3MeA and various other DNA lesions including 1,N6-ethenoadenine (epsilon A), hypoxanthine (Hx) and abasic (AP) sites. In the present study, we explore the relative substrate specificity of Mag for these lesions and in addition, show that Mag also recognizes cisplatin cross-linked adducts, but does not catalyze their excision. Through competition binding and activity studies, we show that in the context of a random DNA sequence Mag binds epsilon A and AP-sites the most tightly, followed by the cross-linked 1,2-d(ApG) cisplatin adduct. While epsilon A binding and excision by Mag was robust in this sequence context, binding and excision of Hx was extremely poor. We further studied the recognition of epsilon A and Hx by Mag, when these lesions are present at different positions within A:T and G:C tracts. Overall, epsilon A was slightly less well excised from each position within the A:T and G:C tracts compared to excision from the random sequence, whereas Hx excision was greatly increased in these sequence contexts (by up to 7-fold) compared to the random sequence. However, given most sequence contexts, Mag had a clear preference for epsilon A relative to Hx, except in the TTXTT (X=epsilon A or Hx) sequence context from which Mag removed both lesions with almost equal efficiency. We discuss how DNA sequence context affects base excision by various 3MeA DNA glycosylases.

Interaction of the family-B DNA polymerase from the archaeon Pyrococcus furiosus with deaminated bases

The interaction of archaeal family B DNA polymerases with deaminated bases has been examined. As determined previously by our group, the polymerase binds tightly to uracil (the deamination product of cytosine), in single-stranded DNA, and stalls replication on encountering this base. DNA polymerisation was also inhibited by the presence of hypoxanthine, the deamination product of adenine. Quantitative binding assays showed that the polymerase bound DNA containing uracil 1.5-4.5-fold more strongly than hypoxanthine and site-directed mutagenesis suggested that the same pocket was used for interaction with both deaminated bases. In contrast the polymerase was insensitive to xanthine, the deamination product of guanine. Traces of uracil and hypoxanthine in DNA can lead to inhibition of the PCR by archaeal DNA polymerases, an important consideration for biotechnology applications. Dual recognition of uracil and hypoxanthine may be facilitated by binding the bases with the glycosidic bond in the anti and syn conformation, respectively.

Hypoxanthine incorporation is nonmutagenic in Escherichia coli

Endonuclease V, encoded by the nfi gene, initiates removal of the base analogs hypoxanthine and xanthine from DNA, acting to prevent mutagenesis from purine base deamination within the DNA. On the other hand, the RdgB nucleotide hydrolase in Escherichia coli is proposed to prevent hypoxanthine and xanthine incorporation into DNA by intercepting the noncanonical DNA precursors dITP and dXTP. Because many base analogs are mutagenic when incorporated into DNA, it is intuitive to think of RdgB as acting to prevent similar mutagenesis from deaminated purines in the DNA precursor pools. To test this idea, we used a set of Claire Cupples' strains to detect changes in spontaneous mutagenesis spectra, as well as in nitrous acid-induced mutagenesis spectra, in wild-type cells and in rdgB single, nfi single, and rdgB nfi double mutants. We found neither a significant increase in spontaneous mutagenesis in rdgB and nfi single mutants or the double mutant nor any changes in nitrous acid-induced mutagenesis for rdgB mutant strains. We conclude that incorporation of deaminated purines into DNA is nonmutagenic.

Development of enzymatic probes of oxidative and nitrosative DNA damage caused by reactive nitrogen species

Chronic inflammation is associated with a variety of human diseases, including cancer, with one possible mechanistic link involving over-production of nitric oxide (NO*) by activated macrophages. Subsequent reaction of NO* with superoxide in the presence of carbon dioxide yields nitrosoperoxycarbonate (ONOOCO2-), a strong oxidant that reacts with guanine in DNA to form a variety of oxidation and nitration products, such 2'-deoxy-8-oxoguanosine. Alternatively, the reaction of NO and O2 leads to the formation of N2O3, a nitrosating agent that causes nucleobase deamination to form 2'-deoxyxanthosine (dX) and 2'-deoxyoxanosine (dO) from dG; 2'-deoxyinosine (dI) from dA; and 2'-deoxyuridine (dU) from dC, in addition to abasic sites and dG-dG cross-links. The presence of both ONOOCO2- and N2O3 at sites of inflammation necessitates definition of the relative roles of oxidative and nitrosative DNA damage in the genetic toxicology of inflammation. To this end, we sought to develop enzymatic probes for oxidative and nitrosative DNA lesions as a means to quantify the two types of DNA damage in in vitro DNA damage assays, such as the comet assay and as a means to differentially map the lesions in genomic DNA by the technique of ligation-mediated PCR. On the basis of fragmentary reports in the literature, we first systematically assessed the recognition of dX and dI by a battery of DNA repair enzymes. Members of the alkylpurine DNA glycosylase family (E. coli AlkA, murine Aag, and human MPG) all showed repair activity with dX (k(cat)/Km 29 x 10(-6), 21 x 10(-6), and 7.8 x 10(-6) nM(-1) min(-1), respectively), though the activity was considerably lower than that of EndoV (8 x 10(-3) nM(-1) min(-1)). Based on these results and other published studies, we focused the development of enzymatic probes on two groups of enzymes, one with activity against oxidative damage (formamidopyrimidine-DNA glycosylase (Fpg); endonuclease III (EndoIII)) and the other with activity against nucleobase deamination products (uracil DNA glycosylase (Udg); AlkA). These combinations were assessed for recognition of DNA damage caused by N2O3 (generated with a NO*/O2 delivery system) or ONOOCO2- using a plasmid nicking assay and by LC-MS analysis. Collectively, the results indicate that a combination of AlkA and Udg react selectively with DNA containing only nitrosative damage, while Fpg and EndoIII react selectively with DNA containing oxidative base lesions caused by ONOOCO2-. The results suggest that these enzyme combinations can be used as probes to define the location and quantity of the oxidative and nitrosative DNA lesions produced by chemical mediators of inflammation in systems, such as the comet assay, ligation-mediated polymerase chain reaction, and other assays of DNA damage and repair.

Repair activity of base and nucleotide excision repair enzymes for guanine lesions induced by nitrosative stress

Nitric oxide (NO) induces deamination of guanine, yielding xanthine and oxanine (Oxa). Furthermore, Oxa reacts with polyamines and DNA binding proteins to form cross-link adducts. Thus, it is of interest how these lesions are processed by DNA repair enzymes in view of the genotoxic mechanism of NO. In the present study, we have examined the repair capacity for Oxa and Oxa–spermine cross-link adducts (Oxa–Sp) of enzymes involved in base excision repair (BER) and nucleotide excision repair (NER) to delineate the repair mechanism of nitrosative damage to guanine. Oligonucleotide substrates containing Oxa and Oxa–Sp were incubated with purified BER and NER enzymes or cell-free extracts (CFEs), and the damage-excising or DNA-incising activity was compared with that for control (physiological) substrates. The Oxa-excising activities of Escherichia coli and human DNA glycosylases and HeLa CFEs were 0.2–9% relative to control substrates, implying poor processing of Oxa by BER. In contrast, DNA containing Oxa–Sp was incised efficiently by UvrABC nuclease and SOS-induced E.coli CFEs, suggesting a role of NER in ameliorating genotoxic effects associated with nitrosative stress. Analyses of the activity of CFEs from NER-proficient and NER-deficient human cells on Oxa–Sp DNA confirmed further the involvement of NER in the repair of nitrosative DNA damage.

Oxidative DNA damage and disease: induction, repair and significance

The generation of reactive oxygen species may be both beneficial to cells, performing a function in inter- and intracellular signalling, and detrimental, modifying cellular biomolecules, accumulation of which has been associated with numerous diseases. Of the molecules subject to oxidative modification, DNA has received the greatest attention, with biomarkers of exposure and effect closest to validation. Despite nearly a quarter of a century of study, and a large number of base- and sugar-derived DNA lesions having been identified, the majority of studies have focussed upon the guanine modification, 7,8-dihydro-8-oxo-2'-deoxyguanosine (8-OH-dG). For the most part, the biological significance of other lesions has not, as yet, been investigated. In contrast, the description and characterisation of enzyme systems responsible for repairing oxidative DNA base damage is growing rapidly, being the subject of intense study. However, there remain notable gaps in our knowledge of which repair proteins remove which lesions, plus, as more lesions identified, new processes/substrates need to be determined. There are many reports describing elevated levels of oxidatively modified DNA lesions, in various biological matrices, in a plethora of diseases; however, for the majority of these the association could merely be coincidental, and more detailed studies are required. Nevertheless, even based simply upon reports of studies investigating the potential role of 8-OH-dG in disease, the weight of evidence strongly suggests a link between such damage and the pathogenesis of disease. However, exact roles remain to be elucidated.

Oxanine DNA glycosylase activity from Mammalian alkyladenine glycosylase

Oxanine (Oxa) is a deaminated base lesion derived from guanine in which the N(1)-nitrogen is substituted by oxygen. This work reports the mutagenicity of oxanine as well as oxanine DNA glycosylase (ODG) activities in mammalian systems. Using human DNA polymerase beta, deoxyoxanosine triphosphate is only incorporated opposite cytosine (Cyt). When an oxanine base is in a DNA template, Cyt is efficiently incorporated opposite the template oxanine; however, adenine and thymine are also incorporated opposite Oxa with an efficiency approximately 80% of a Cyt/Oxa (C/O) base pair. Guanine is incorporated opposite Oxa with the least efficiency, 16% compared with cytosine. ODG activity was detected in several mammalian cell extracts. Among the known human DNA glycosylases tested, human alkyladenine glycosylase (AAG) shows ODG activity, whereas hOGG1, hNEIL1, or hNEIL2 did not. ODG activity was detected in spleen cell extracts of wild type age-matched mice, but little activity was observed in that of Aag knock-out mice, confirming that the ODG activity is intrinsic to AAG. Human AAG can excise Oxa from all four Oxa-containing double-stranded base pairs, Cyt/Oxa, Thy/Oxa, Ade/Oxa, and Gua/Oxa, with no preference to base pairing. Surprisingly, AAG can remove Oxa from single-stranded Oxa-containing DNA as well. Indeed, AAG can also remove 1,N(6)-ethenoadenine from single-stranded DNA. This study extends the deaminated base glycosylase activities of AAG to oxanine; thus, AAG is a mammalian enzyme that can act on all three purine deamination bases, hypoxanthine, xanthine, and oxanine.

Repairing DNA-methylation damage

Methylating agents modify DNA at many different sites, thereby producing lethal and mutagenic lesions. To remove all the main harmful base lesions, at least three types of DNA-repair activities can be used, each of which involves a different reaction mechanism. These activities include DNA-glycosylases, DNA-methyltransferases and the recently characterized DNA-dioxygenases. The Escherichia coli AlkB dioxygenase and the two human homologues, ABH2 and ABH3, represent a novel mechanism of DNA repair. They use iron-oxo intermediates to oxidize stable methylated bases in DNA and directly revert them to the unmodified form.

Identification of alkA gene related to virulence of Shigella flexneri 2a by mutational analysis

AIM: In vivo induced genes are thought to play an important role during infection of host. AlkA was identified as an in vivo-induced gene by in vivo expression technology (IVET), but its virulence in Shigella flexneri was not reported. The purpose of this study was to identify the role of alkA gene in the pathogenesis of S. flexneri.

METHODS: PCR was used to amplify alkA gene of S. flexneri 2a and fragment 028pKm. The fragment was then transformed into 2457T05 strain, a S flexneri 2a strain containing Red recombination system, which was constructed with a recombinant suicide plasmid pXLkd46. By in vivo homologous recombination, alkA mutants were obtained and verified by PCR and sequencing. Intracellular survival assay and virulence assay were used to test the intracellular survival ability in HeLa cell model and the virulence in mice lung infection model respectively.

RESULTS: Deletion mutant of S. flexneri 2a alkA was successfully constructed by λ Red recombination system. The mutant exhibited significant survival defects and much significant virulence defects in mice infection assay.

CONCLUSION: AlkA gene plays an important role in the infection of epithelial cells and is a virulent gene of Shigella spp.

RdgB acts to avoid chromosome fragmentation in Escherichia coli

Bacterial RecA protein is required for repair of two-strand DNA lesions that disable whole chromosomes. recA mutants are viable, suggesting a considerable cellular capacity to avoid these chromosome-disabling lesions. recA-dependent mutants reveal chromosomal lesion avoidance pathways. Here we characterize one such mutant, rdgB/yggV, deficient in a putative inosine/xanthosine triphosphatase, conserved throughout kingdoms of life. The rdgB recA lethality is suppressed by inactivation of endonuclease V (gpnfi) specific for DNA-hypoxanthines/xanthines, suggesting that RdgB either intercepts improper DNA precursors dITP/dXTP or works downstream of EndoV in excision repair of incorporated hypoxathines/xanthines. We find that DNA isolated from rdgB mutants contains EndoV-recognizable modifications, whereas DNA from nfi mutants does not, substantiating the dITP/dXTP interception by RdgB. rdgB recBC cells are inviable, whereas rdgB recF cells are healthy, suggesting that chromosomes in rdgB mutants suffer double-strand breaks. Chromosomal fragmentation is indeed observed in rdgB recBC mutants and is suppressed in rdgB recBC nfi mutants. Thus, one way to avoid chromosomal lesions is to prevent hypoxanthine/xanthine incorporation into DNA via interception of dITP/dXTP.

Characterisation of Archaeglobus fulgidus AlkA hypoxanthine DNA glycosylase activity

The AlkA protein from the archaebacterium Archaeglobus fulgidus was characterised with respect to release of hypoxanthine from DNA. The hypoxanthine glycosylase activity had optimal activity at 60 degrees C at pH 5.0. The enzyme released hypoxanthine from substrates with a preference for dI:dG >> dI:dT > dI:dC > dI:dA. The presence of a mismatch on either side of the dIMP in the substrate reduced excision efficiency of the hypoxanthine residue at neutral pH, while a mismatch on both sides of the dIMP resulted in total loss of excision. Release of hypoxanthine from DNA required a minimum of two bases on the 5' side and four bases on the 3' side of the dIMP residue.

A Novel GT-Mismatch Binding Protein That Recognizes Strict DNA Sequences with High Affinity

Mismatched or damaged base pairs in DNA are mutagenic and both eukaryotes and prokaryotes have a series of repair systems that decrease a spontaneous mutation rate. All exocyclic amino groups of cytosine(C), adenine(A), and guanine(G) contribute to hydrogen bonds for base pairing. High temperature and oxidative stresses increase the deamination of these bases and methylated C. These deaminated sites would be initially recognized by components of DNA repair system. We discovered a novel G/thymine(T)-mismatch binding protein (nGTBP) that bound, with high affinity, to a minimal 14-mer DNA heteroduplex with a strict 5'-TRT GNB-3' sequence (R for purine, N for any bases, and B for "not A," namely for C, G, or T ). This italicized G position mismatched with T could be replaced by hypoxanthine, the deaminated A. The nGTBP, however, barely recognized DNA duplexes individually containing 8-oxo-G, thymine glycol, and 5-methylcytosine.

Identification of the dITP- and XTP-hydrolyzing protein from Escherichia coli

A hypothetical 21.0 kDa protein (ORF O197) from Escherichia coli K-12 was cloned, purified, and characterized. The protein sequence of ORF O197 (termed EcO197) shares a 33.5% identity with that of a novel NTPase from Methanococcus jannaschii. The EcO197 protein was purified using Ni-NTA affinity chromatography, protease digestion, and gel filtration column. It hydrolyzed nucleoside triphosphates with an O6 atom-containing purine base to nucleoside monophosphate and pyrophosphate. The EcO197 protein had a strong preference for deoxyinosine triphosphate (dITP) and xanthosine triphosphate (XTP), while it had little activity in the standard nucleoside triphosphates (dATP, dCTP, dGTP, and dTTP). These aberrant nucleotides can be produced by oxidative deamination from purine nucleotides in cells; they are potentially mutagenic. The mutation protection mechanisms are caused by the incorporation into DNA of unwelcome nucleotides that are formed spontaneously. The EcO197 protein may function to eliminate specifically damaged purine nucleotide that contains the 6-keto group. This protein appears to be the first eubacterial dITP- and XTPhydrolyzing enzyme that has been identified.

Repair of deaminated bases in DNA

Deamination of DNA bases can occur spontaneously, generating highly mutagenic lesions such as uracil, hypoxanthine, and xanthine. When cells are under oxidative stress that is induced either by oxidizing agents or by mitochondrial dysfunction, additional deamination products such as 5-hydroxymethyluracil (5-HMU) and 5-hydroxyuracil (5-OH-Ura) are formed. The cellular level of these highly mutagenic lesions is increased substantially when cells are exposed to DNA damaging agent, such as ionizing radiation, redox reagents, nitric oxide, and others. The cellular repair of deamination products is predominantly through the base excision repair (BER) pathway, a major cellular repair pathway that is initiated by lesion specific DNA glycosylases. In BER, the lesions are removed by the combined action of a DNA glycosylase and an AP endonuclease, leaving behind a one-base gap. The gapped product is then further repaired by the sequential action of DNA polymerase and DNA ligase. DNA glycosylases that recognize uracil, 5-OH-Ura, 5-HMU (derived from 5-methylcytosine) and a T/G mismatch (derived from a 5-methylcytosine/G pair) are present in most cells. Many of these glycosylases have been cloned and well characterized. In yeast and mammalian cells, hypoxanthine is efficiently removed by methylpurine N-glycosylase, and it is thought that BER might be an important pathway for the repair of hypoxanthine. In contrast, no glycosylase that can recognize xanthine has been identified in either yeast or mammalian cells. In Escherichia coli, the major enzyme activity that initiates the repair of hypoxanthine and xanthine is endonuclease V. Endonuclease V is an endonuclease that hydrolyzes the second phosphodiester bond 3' to the lesion. It is hypothesized that the cleaved DNA is further repaired through an alternative excision repair (AER) pathway that requires the participation of either a 5' endonuclease or a 3'-5' exonuclease to remove the damaged base. The repair process is then completed by the sequential actions of DNA polymerase and DNA ligase. Endonuclease V sequence homologs are present in all kingdoms, and it is conceivable that endonuclease V might also be a major enzyme that initiates the repair of hypoxanthine and xanthine in mammalian cells.

Active-site clashes prevent the human 3-methyladenine DNA glycosylase from improperly removing bases

The human 3-methyladenine DNA glycosylase (AAG, MPG) removes a diverse array of damaged purines via a nucleotide-flipping mechanism. In the crystal structure of AAG bound to DNA containing 1,N(6) ethenoadenine, an asparagine (N169) occupies the active-site floor, in close proximity to the C-2 position of the flipped-out 1,N(6) ethenoadenine. We engineered site-specific AAG mutants to determine whether N169 prevents normal bases from mistakenly entering the active site. Substituting alanine or serine resulted in mutants that excised substrates at a faster rate than wild-type. Furthermore, these mutants acquired the ability to excise normal guanine within mispairs but not opposite cytosine. The results suggest that AAG can recognize helical deformations, such as mispairs. However, the active site then prevents the mistaken excision of bases, which prevents AAG from acquiring a mutator activity.

1,N(2)-ethenoguanine, a mutagenic DNA adduct, is a primary substrate of Escherichia coli mismatch-specific uracil-DNA glycosylase and human alkylpurine-DNA-N-glycosylase

The promutagenic and genotoxic exocyclic DNA adduct 1,N(2)-ethenoguanine (1,N(2)-epsilonG) is a major product formed in DNA exposed to lipid peroxidation-derived aldehydes in vitro. Here, we report that two structurally unrelated proteins, the Escherichia coli mismatch-specific uracil-DNA glycosylase (MUG) and the human alkylpurine-DNA-N-glycosylase (ANPG), can release 1,N(2)-epsilonG from defined oligonucleotides containing a single modified base. A comparison of the kinetic constants of the reaction indicates that the MUG protein removes the 1,N(2)-epsilonG lesion more efficiently (k(cat)/K(m) = 0.95 x 10(-3) min(-1) nm(-1)) than the ANPG protein (k(cat)/K(m) = 0.1 x 10(-3) min(-1) nm(-1)). Additionally, while the nonconserved, N-terminal 73 amino acids of the ANPG protein are not required for activity on 1,N(6)-ethenoadenine, hypoxanthine, or N-methylpurines, we show that they are essential for 1,N(2)-epsilonG-DNA glycosylase activity. Both the MUG and ANPG proteins preferentially excise 1,N(2)-epsilonG when it is opposite dC; however, unlike MUG, ANPG is unable to excise 1,N(2)-epsilonG when it is opposite dG. Using cell-free extracts from genetically modified E. coli and murine embryonic fibroblasts lacking MUG and mANPG activity, respectively, we show that the incision of the 1,N(2)-epsilonG-containing duplex oligonucleotide has an absolute requirement for MUG or ANPG. Taken together these observations suggest a possible role for these proteins in counteracting the genotoxic effects of 1,N(2)-epsilonG residues in vivo.

A novel uracil-DNA glycosylase with broad substrate specificity and an unusual active site

Uracil-DNA glycosylases (UDGs) catalyse the removal of uracil by flipping it out of the double helix into their binding pockets, where the glycosidic bond is hydrolysed by a water molecule activated by a polar amino acid. Interestingly, the four known UDG families differ in their active site make-up. The activating residues in UNG and SMUG enzymes are aspartates, thermostable UDGs resemble UNG-type enzymes, but carry glutamate rather than aspartate residues in their active sites, and the less active MUG/TDG enzymes contain an active site asparagine. We now describe the first member of a fifth UDG family, Pa-UDGb from the hyperthermophilic crenarchaeon Pyrobaculum aerophilum, the active site of which lacks the polar residue that was hitherto thought to be essential for catalysis. Moreover, Pa-UDGb is the first member of the UDG family that efficiently catalyses the removal of an aberrant purine, hypoxanthine, from DNA. We postulate that this enzyme has evolved to counteract the mutagenic threat of cytosine and adenine deamination, which becomes particularly acute in organisms living at elevated temperatures.

Survey of the year 2000 commercial optical biosensor literature

We have compiled a comprehensive list of the articles published in the year 2000 that describe work employing commercial optical biosensors. Selected reviews of interest for the general biosensor user are highlighted. Emerging applications in areas of drug discovery, clinical support, food and environment monitoring, and cell membrane biology are emphasized. In addition, the experimental design and data processing steps necessary to achieve high-quality biosensor data are described and examples of well-performed kinetic analysis are provided.

The HAP1 protein stimulates the turnover of human mismatch-specific thymine-DNA-glycosylase to process 3,N(4)-ethenocytosine residues

When present in DNA, 3,N(4)-ethenocytosine (epsilon C) residues are potentially mutagenic and carcinogenic in vivo. The enzymatic activity responsible for the repair of the epsilon C residues in human cells is the hTDG protein, the human thymine-DNA-glycosylase that removes thymine in a T/G base pair [Proc. Natl. Acad. Sci., U.S.A., 95 (1998) 8508]. One of the distinctive properties of the hTDG protein is that it remains tightly bound to the AP-site resulting from its glycosylase activity. In this paper we report that the human AP endonuclease, the HAP1 (Ape1, APEX Ref-1) protein, stimulates the processing of epsilon C residues by the hTDG protein in vitro, in a dose-dependent manner. This property of HAP1 protein is specific since E.coli Fpg, Nfo and Nth proteins, all endowed with an AP nicking activity, do not show similar features. The results suggest that the HAP1 protein displaces the hTDG protein bound to the AP-site and therefore increases the turnover of the hTDG protein. However, using a variety of techniques including gel retardation assay, surface plasmon resonance and two-hybrid system, it was not possible to detect evidence for a complex including the substrate, the hTDG and HAP1 proteins.

Biochemical characterization of a novel hypoxanthine/xanthine dNTP pyrophosphatase from Methanococcus jannaschii

A novel dNTP pyrophosphatase, Mj0226 from Methanococcus jannaschii, which catalyzes the hydrolysis of nucleoside triphosphates to the monophosphate and PPi, has been characterized. Mj0226 protein catalyzes hydrolysis of two major substrates, dITP and XTP, suggesting that the 6-keto group of hypoxanthine and xanthine is critical for interaction with the protein. Under optimal reaction conditions the k(ca)(t) /K(m) value for these substrates was approximately 10 000 times that with dATP. Neither endonuclease nor 3'-exonuclease activities were detected in this protein. Interestingly, dITP was efficiently inserted opposite a dC residue in a DNA template and four dNTPs were also incorporated opposite a hypoxanthine residue in template DNA by DNA polymerase I. Two protein homologs of Mj0226 from Escherichia coli and Archaeoglobus fulgidus were also cloned and purified. These have catalytic activities similar to Mj0226 protein under optimal conditions. The implications of these results have significance in understanding how homologous proteins, including Mj0226, act biologically in many organisms. It seems likely that Mj0226 and its homologs have a major role in preventing mutations caused by incorporation of dITP and XTP formed spontaneously in the nucleotide pool into DNA. This report is the first identification and functional characterization of an enzyme hydrolyzing non-canonical nucleotides, dITP and XTP.

Human endonuclease III acts preferentially on DNA damage opposite guanine residues in DNA

The human endonuclease III homologue (hNTH1) removes premutagenic cytosine damage from DNA. This includes 5-hydroxycytosine, which has increased potential for pairing with adenine, resulting in C --> T transition mutations. Here we report that hNTH1 acts on both 5-hydroxycytosine and abasic sites preferentially when these are situated opposite guanines in DNA. Discrimination against other opposite bases is strongly dependent on the presence of magnesium. To further elucidate this effect, we have introduced mutations in the helix-hairpin-helix domain of hNTH1 (K212S, P211R, +G212, and DeltaP211), and measured the kinetics of 5-hydroxycytosine removal of the mutants relative to wild type. The K212S and DeltaP211 (truncated hairpin) mutant proteins were both inactive, whereas the extended hairpin in the +G212 mutant diminished recognition and binding to 5-hydroxycytosine-containing DNA. The P211R mutant resembled native hNTH1, except for decreased specificity of binding. Despite the altered kinetic parameters, the active mutants retained the ability to discriminate against the pairing base, indicating that enzyme interactions with the opposite strand relies on other domains than the active site helix-hairpin-helix motif.