Human MutY homolog, a DNA glycosylase involved in base excision repair, physically and functionally interacts with mismatch repair proteins human MutS homolog 2/human MutS homolog 6.

Adenines mismatched with guanines or 7,8-dihydro-8-oxo-deoxyguanines that arise through DNA replication errors can be repaired by either base excision repair or mismatch repair. The human MutY homolog (hMYH), a DNA glycosylase, removes adenines from these mismatches. Human MutS homologs, hMSH2/hMSH6 (hMutSalpha), bind to the mismatches and initiate the repair on the daughter DNA strands. Human MYH is physically associated with hMSH2/hMSH6 via the hMSH6 subunit. The interaction of hMutSalpha and hMYH is not observed in several mismatch repair-defective cell lines. The hMutSalpha binding site is mapped to amino acid residues 232-254 of hMYH, a region conserved in the MutY family. Moreover, the binding and glycosylase activities of hMYH with an A/7,8-dihydro-8-oxo-deoxyguanine mismatch are enhanced by hMutSalpha. These results suggest that protein-protein interactions may be a means by which hMYH repair and mismatch repair cooperate in reducing replicative errors caused by oxidized bases.     

Electrochemical detection of nucleic base mismatches with ferrocenyl naphthalene diimide

Electrochemical detection of nucleic base mismatches was attempted successfully with ferrocenyl naphthalene diimide (FND) in a model system with 20-meric double-stranded oligonucleotides with or without a mismatch(es). Thus, dA(20) or a 20-meric sequence of the lac Z gene was immobilized on a gold electrode and complementary oligonucleotides with different numbers of mismatches were allowed to hybridize in the presence of FND to give rise to an electrochemical signal. The signal intensity varied depending on the number of unpaired bases on the DNA duplex. From experiments with a quartz crystal microbalance, eight molecules of FND were found to bind to the 20-meric double-stranded oligos and this number decreased as the number of mismatches increased. These findings were further supported by matrix-assisted laser desorption ionization time-of-flight mass spectroscopy. This novel method will be useful for the analysis of single-nucleotide polymorphisms present on human genes.     

Detection of single DNA base mutations with mismatch repair enzymes.

A novel method for identifying DNA point mutations has been developed by using mismatch repair enzymes. The high specificity of the Escherichia coli MutY protein has permitted the development of a reliable and sensitive method for the detection and characterization of point mutations in the human genome. The MutY protein is involved in a repair pathway that can convert A/G or A/C mismatches to C/G or G/C basepairs, respectively. A/G or A/C mismatches formed by hybridization between two amplified genomic DNA samples or between specific DNA probes and target DNA are nicked at the mispaired adenine strand by MutY protein. As little as 1% of the mutant sequence can be detected by the mismatch repair enzyme cleavage (MREC) method in a mixture of normal and mutated DNAs (e.g., mutant cells are only present in 1% of the normal cell background). By using different probes, the assay also can determine the nucleotide sequence of the mutation. We have applied this method to detect single-base substitutions in human oncogenes.     

Chemical cleavage of DNA duplexes with single base mismatches as a basis for detection of random point mutations

The most promising approaches to detection of random point mutations are based on chemical cleavage of mismatches and other noncomplementarities. To demonstrate the specificity of this method, a model system was obtained for the first time as sets of 50-mer imperfect DNA duplexes containg all variants of mismatched and unpaired internal residues located in an invariant context and flanked by either A · T or G · C base pairs. Chemical cleavage of DNA duplexes immobilized on magnetic beads via the biotin-streptavidin interaction was accomplished using potassium permanganate or hydroxylamine, which are sensitive to the secondary DNA structure and react with thymine and cytosine, respectively. The reactivity of different mismatches was connected with the local duplex structure and depended on their type, orientation, and flanking nucleotides. The use of potassium permanganate and hydroxylamine to modify a heteroduplex mixture makes it possible to unambiguously detect a mismatch and, based on the type of reagent and the size of the cleavage products, to suppose the type and position of the mismatch and the flanking nucleotides. The model system can be used to evaluate the sensitivity of a chemical cleavage method and to control false-positive and false-negative results when different protocols are applied to the detection of DNA point mutations.     

Characterization of a thermostable DNA glycosylase specific for U/G and T/G mismatches from the hyperthermophilic archaeon Pyrobaculum aerophilum

U/G and T/G mismatches commonly occur due to spontaneous deamination of cytosine and 5-methylcytosine in double-stranded DNA. This mutagenic effect is particularly strong for extreme thermophiles, since the spontaneous deamination reaction is much enhanced at high temperature. Previously, a U/G and T/G mismatch-specific glycosylase (Mth-MIG) was found on a cryptic plasmid of the archaeon Methanobacterium thermoautotrophicum, a thermophile with an optimal growth temperature of 65 degrees C. We report characterization of a putative DNA glycosylase from the hyperthermophilic archaeon Pyrobaculum aerophilum, whose optimal growth temperature is 100 degrees C. The open reading frame was first identified through a genome sequencing project in our laboratory. The predicted product of 230 amino acids shares significant sequence homology to [4Fe-4S]-containing Nth/MutY DNA glycosylases. The histidine-tagged recombinant protein was expressed in Escherichia coli and purified. It is thermostable and displays DNA glycosylase activities specific to U/G and T/G mismatches with an uncoupled AP lyase activity. It also processes U/7,8-dihydro-oxoguanine and T/7,8-dihydro-oxoguanine mismatches. We designate it Pa-MIG. Using sequence comparisons among complete bacterial and archaeal genomes, we have uncovered a putative MIG protein from another hyperthermophilic archaeon, Aeropyrum pernix. The unique conserved amino acid motifs of MIG proteins are proposed to distinguish MIG proteins from the closely related Nth/MutY DNA glycosylases.     

Molecular cloning and functional analysis of the MutY homolog of Deinococcus radiodurans

The mutY homolog gene (mutY(Dr)) from Deinococcus radiodurans encodes a 39.4-kDa protein consisting of 363 amino acids that displays 35% identity to the Escherichia coli MutY (MutY(Ec)) protein. Expressed MutY(Dr) is able to complement E. coli mutY mutants but not mutM mutants to reduce the mutation frequency. The glycosylase and binding activities of MutY(Dr) with an A/G-containing substrate are more sensitive to high salt and EDTA concentrations than the activities with an A/7,8-dihydro-8-oxoguanine (GO)-containing substrate are. Like the MutY(Ec) protein, purified recombinant MutY(Dr) expressed in E. coli has adenine glycosylase activity with A/G, A/C, and A/GO mismatches and weak guanine glycosylase activity with a G/GO mismatch. However, MutY(Dr) exhibits limited apurinic/apyrimidinic lyase activity and can form only weak covalent protein-DNA complexes in the presence of sodium borohydride. This may be due to an arginine residue that is present in MutY(Dr) at the position corresponding to the position of MutY(Ec) Lys142, which forms the Schiff base with DNA. The kinetic parameters of MutY(Dr) are similar to those of MutY(Ec). Although MutY(Dr) has similar substrate specificity and a binding preference for an A/GO mismatch over an A/G mismatch, as MutY(Ec) does, the binding affinities for both mismatches are slightly lower for MutY(Dr) than for MutY(Ec). Thus, MutY(Dr) can protect the cell from GO mutational effects caused by ionizing radiation and oxidative stress.     

Dimer of 2,7-diamino-1,8-naphthyridine for the detection of mismatches formed by pyrimidine nucleotide bases

Discrimination of base mismatches from normal Watson-Crick base pairs in duplex DNA constitutes a key approach to the detection of single nucleotide polymorphisms (SNPs). We have developed a sensor for a surface plasmon resonance (SPR) assay system to detect G-G, A-A, and C-C mismatch duplexes by employing a surface upon which mismatch-binding ligands (MBLs) are immobilized. We synthesized a new MBL consisting of 2,7-diamino-1,8-naphthyridine (damND) and immobilized it onto a CM5 sensor chip to carry out the SPR assay of DNA duplexes containing a single-base mismatch. The SPR sensor with damND revealed strong responses to all C-C mismatches, and sequence-dependent C-T and T-T mismatches. Compared to ND- and naphthyridine-azaquinolone hybrid (NA)-immobilized sensor surfaces, with affinity to mismatches composed of purine nucleotide bases, the damND-immobilized surface was useful for the detection of the mismatches composed of pyrimidine nucleotide bases.     

Chemical reactivity of matched cytosine and thymine bases near mismatched and unmatched bases in a heteroduplex between DNA strands with multiple differences.

The chemical reactivity of matched T and C bases to osmium tetroxide and hydroxylamine near mismatched and unmatched bases in a heteroduplex between two strands of DNA with multiple differences was examined. Data was available for matched bases one or two positions away from 24 mismatches. Reactive bases were found near 16 of the mismatches and were usually one or two bases away. This reactivity is consistent with structural studies indicating perturbation of the duplex around mismatches and will allow another mode of study of the effect of mismatches. The reactivity of these bases was found not to be strongly correlated with mismatch type or GC basepair content of the basepairs around the mismatches. Extra reactivity may have been promoted by the presence of either T or C in the mismatch allowing increased reactivity of nearby T or C. The utility of the phenomenon for the detection of mutations is discussed. Unmatched bases in the heteroduplex also gives rise to reactive matched bases nearby.     

Evidence that MutY is a monofunctional glycosylase capable of forming a covalent Schiff base intermediate with substrate DNA.

The Escherichia coli adenine glycosylase MutY is involved in the repair of 7,8-dihydro-8-oxo-2'-deoxyguanosine (OG):A and G:A mispairs in DNA. DNA strand cleavage via beta-elimination (beta-lyase) activity coupled with MutY's removal of misincorporated adenine bases was sought using both qualitative and quantitative methods. The qualitative assays demonstrate formation of a Schiff base intermediate which is characteristic of DNA glycosylases catalyzing a concomitant beta-lyase reaction. Borohydride reduction of the Schiff base results in the formation of a covalent DNA-MutY adduct which is easily detected in SDS-PAGE experiments. However, quantitative activity assays which monitor DNA strand scission accompanying base release suggest MutY behaves as a simple monofunctional glycosylase. Treatment with base effects DNA strand cleavage at apurinic/apyrimidinic (AP) sites arising via simple glycosylase activity. The amount of cleaved DNA in MutY reactions treated with base is much greater than that in non-base treated reactions, indicating that AP site generation by MutY is not associated with a concomitant beta-lyase step. As standards, identical assays were performed with a known monofunctional enzyme (uracil DNA glycosylase) and a known bifunctional glycosylase/lyase (FPG), the results of which were used in comparison with those of the MutY experiments. The apparent inconsistency between the data obtained for MutY by the qualitative and quantitative methods underscores the current debate surrounding the catalytic activity of this enzyme, and a detailed explanation of this controversy is proposed. The work presented here lays ground for the identification of specific active site residues responsible for the chemical mechanism of MutY enzyme catalysis.     

Single base mismatches in DNA. Long- and short-range structure probed by analysis of axis trajectory and local chemical reactivity

We have devised a procedure to generate any single base mismatch in a constant sequence context, and have studied these from two points of view. (1) We have examined electrophoretic mobility of 458 base-pair fragments containing approximately centrally located single mismatches, in polyacrylamide gels, compared to fully matched DNA fragments. We found that no single mismatch caused a significant perturbation of gel mobility, and we conclude that all the mismatches may be accommodated within a helical geometry such that there is no alteration of the path of the helix axis in a straight DNA molecule. (2) We have studied all the single mismatches with respect to reactivity to a number of chemical probes. We found that: (a) No mispaired adenine bases are reactive to diethyl pyrocarbonate and are therefore not simply unpaired such that N-7 is exposed. (b) A number of mispaired thymine bases are reactive to osmium tetroxide, and cytosine bases to hydroxylamine. (c) Where crystal or nuclear magnetic resonance structures are available, the reactivity correlates with exposure of the pyrimidine 5,6 double bonds to attack in the major groove as a result of wobble base-pair formation. This is particularly clear for G.T and I.T base-pairs. (d) Reactivity of bases in mismatched pairs can be dependent on sequence context. (e) Reactivity of the C.C mismatch to hydroxylamine is suppressed at low pH, suggesting that a rearrangement of base-pairing occurs on protonation. The results overall are consistent with the formation of stacked intrahelical base-pairs wherever possible, resulting in no global distortion of the DNA structure, but specific enhancement of chemical reactivity in some cases.     

Mutation detection by electrocatalysis at DNA-modified electrodes

Detection of mutations and damaged DNA bases is important for the early diagnosis of genetic disease. Here we describe an electrocatalytic method for the detection of single-base mismatches as well as DNA base lesions in fully hybridized duplexes, based on charge transport through DNA films. Gold electrodes modified with preassembled DNA duplexes are used to monitor the electrocatalytic signal of methylene blue, a redox-active DNA intercalator, coupled to [Fe(CN)6]3-. The presence of mismatched or damaged DNA bases substantially diminishes the electrocatalytic signal. Because this assay is not a measure of differential hybridization, all single-base mismatches, including thermodynamically stable GT and GA mismatches, can be detected without stringent hybridization conditions. Furthermore, many common DNA lesions and "hot spot" mutations in the human p53 genome can be distinguished from perfect duplexes. Finally, we have demonstrated the application of this technology in a chip-based format. This system provides a sensitive method for probing the integrity of DNA sequences and a completely new approach to single-base mismatch detection.     

Comparative reactivity of mismatched and unpaired bases in relation to their type and surroundings. Chemical cleavage of DNA mismatches in mutation detection analysis

Systematic study of chemical reactivity of non-Watson–Crick base pairs depending on their type and microenvironment was performed on a model system that represents two sets of synthetic DNA duplexes with all types of mismatched and unmatched bases flanked by T·A or G·C pairs. Using comparative cleavage pattern analysis, we identified the main and additional target bases and performed quantitative study of the time course and efficacy of DNA modification caused by potassium permanganate or hydroxylamine. Potassium permanganate in combination with tetraethylammonium chloride was shown to induce DNA cleavage at all mismatched or bulged T residues, as well as at thymines of neighboring canonical pairs. Other mispaired (bulged) bases and thymine residues located on the second position from the mismatch site were not the targets for KMnO₄ attack. In contrast, hydroxylamine cleaved only heteroduplexes containing mismatched or unmatched C residues, and did not modify adjacent cytosines. However when G·C pairs flank bulged C residue, neighboring cytosines are also attacked by hydroxylamine due to defect migration. Chemical reactivity of target bases was shown to correlate strongly with the local disturbance of DNA double helix at mismatch or bulge site. With our model system, we were able to prove the absence of false-negative and false-positive results. Portion of heteroduplex reliably revealed in a mixture with corresponding homoduplex consists of 5% for bulge bases and “open” non-canonical pairs, and 10% for wobble base pairs giving minimal violations in DNA structure. This study provides a complete understanding of the principles of mutation detection methodology based on chemical cleavage of mismatches and clarifies the advantages and limitations of this approach in various biological and conformational studies of DNA.     

Adenine release is fast in MutY-catalyzed hydrolysis of G:A and 8-Oxo-G:A DNA mismatches

MutY, a DNA repair enzyme, is unusual in that it binds exceedingly tightly to its products after the chemical steps of catalysis. Until now it was not known whether the product being released in the rate-limiting step was DNA, adenine, or both. MutY hydrolyzes adenine from 8-oxo-G:A (OG:A) base pair mismatches as the first step in the base excision repair pathway, as well as from G:A mismatches. The products are adenine and DNA containing an apurinic (AP) site. Tight product binding may have a physiological role in preventing further damage at the OG:AP site. We developed a rate assay using [8-14C]adenine in OG:A or G:A mismatches that distinguishes between adenine hydrolysis and adenine release. [8-14C]Adenine was released quickly from the MutY.AP-DNA.[8-14C]adenine complex, with a rate constant greater than 5 min-1. This was much faster than the rate-limiting step, at 0.006-0.015 min-1. Gel retardation experiments showed that AP-DNA release was very slow, consistent with it being the rate-limiting step. Thus, the kinetic mechanism involves fast adenine release after hydrolysis followed by rate-limiting AP-DNA release. Adenine appears to be buried deep in the protein.DNA interface, but there is enough flexibility or open space for it to dissociate from the MutY.APDNA.adenine complex. These results have implications for the catalytic mechanism of MutY.     

Physical and functional interactions between Escherichia coli MutY glycosylase and mismatch repair protein MutS

Escherichia coli MutY and MutS increase replication fidelity by removing adenines that were misincorporated opposite 7,8-dihydro-8-oxo-deoxyguanines (8-oxoG), G, or C. MutY DNA glycosylase removes adenines from these mismatches through a short-patch base excision repair pathway and thus prevents G:C-to-T:A and A:T-to-G:C mutations. MutS binds to the mismatches and initiates the long-patch mismatch repair on daughter DNA strands. We have previously reported that the human MutY homolog (hMYH) physically and functionally interacts with the human MutS homolog, hMutSalpha (Y. Gu et al., J. Biol. Chem. 277:11135-11142, 2002). Here, we show that a similar relationship between MutY and MutS exists in E. coli. The interaction of MutY and MutS involves the Fe-S domain of MutY and the ATPase domain of MutS. MutS, in eightfold molar excess over MutY, can enhance the binding activity of MutY with an A/8-oxoG mismatch by eightfold. The MutY expression level and activity in mutS mutant strains are sixfold and twofold greater, respectively, than those for the wild-type cells. The frequency of A:T-to-G:C mutations is reduced by two- to threefold in a mutS mutY mutant compared to a mutS mutant. Our results suggest that MutY base excision repair and mismatch repair defend against the mutagenic effect of 8-oxoG lesions in a cooperative manner.     

Exposure and removal of stainable groups during Feulgen acid hydrolysis of fixed chromatin at different temperatures

Summary Hyperdiploid Ehrlioh's ascites tumour cells grown in male mice (strain NMRI) were labeled with radioactive nucleotides. The nucleic acids were extracted from fixed, air-dried smears by fractionated hydrolysis and their radioactivity measured by liquid scintillation. The experiments showed that the exposure of aldehydes through removal of purine bases and the elimination of these aldehydes through depolymerisation of DNA were the two main processes responsible for the Feulgen hydrolysis curve. They were shown to be independent and overlapping. The depurination can be described as a simple hydrolytic reaction, while the extraction of DNA depends on a number of different factors. This entails that, in the Feulgen acid hydrolysis procedure, the part of DNA measured is dependent upon the stability of the chromatin. It was found that it is possible accurately to determine the depolymerisation process and thereby roughly correct the measured amount of Feulgen DNA.     

Rapid photometric detection of thymine residues partially flipped out of double helix as a method for direct scanning of point mutations and apurinic DNA sites

A spectroscopic assay for detection of extrahelical thymine residues in DNA heteroduplexes under their modification by potassium permanganate has been developed. The assay is based on increase in absorbance at 420 nm due to accumulation of thymidine oxidation intermediates and soluble manganese dioxide. The analysis was carried out using a set of 19-bp DNA duplexes containing unpaired thymidines opposite tetrahydrofuranyl derivatives mimicking a widespread DNA damage (apurinic (AP) sites) and a library of 50-bp DNA duplexes containing all types of base mismatches in different surroundings. The relation between the selectivity of unpaired T oxidation and the thermal stability of DNA double helix was investigated. The method described here was shown to discriminate between DNA duplexes with one or two AP sites and to reveal thymine-containing mismatches and all noncanonical base pairs in AT-surroundings. Comparative results of CCM analysis and the rapid photometric assay for mismatch detection are demonstrated for the first time in the same model system. The chemical reactivity of target thymines was shown to correlate with local disturbance of double helix at the mismatch site. As the spectroscopic assay does not require the DNA cleavage reaction and gel electrophoresis, it can be easily automated and used for primary screening of somatic mutations.     

A distinct TthMutY bifunctional glycosylase that hydrolyzes not only adenine but also thymine opposite 8-oxoguanine in the hyperthermophilic bacterium, Thermus thermophilus

Oxidative damage represents a major threat to genomic stability because the major product of DNA oxidation, 8-oxoguanine (GO), frequently mispairs with adenine during replication. We were interested in finding out how hyperthermophilic bacteria under goes the process of excising mispaired adenine from A/GO to deal with genomic oxidative damage. Herein we report the properties of an Escherichia coli MutY (EcMutY) homolog, TthMutY, derived from a hyperthermophile Thermus thermophilus. TthMutY preferentially excises on A/GO and G/GO mispairs and has additional activities on T/GO and A/G mismatches. TthMutY has significant sequence homology to the A/G and T/G mismatch recognition motifs, respectively, of MutY and Mig.MthI. A substitution from Tyr112 to Ser or Ala (Y112S and Y112A) in the putative thymine-binding site of TthMutY showed significant decrease in DNA glycosylase activity. A mutant form of TthMutY, R134K, could form a Schiff base with DNA and fully retained its DNA glycosylase activity against A/GO and A/G mispair. Interestingly, although TthMutY cannot form a trapped complex with substrate in the presence of NaBH(4), it expressed AP lyase activity, suggesting Tyr112 in TthMutY may be the key residue for AP lyase activity. These results suggest that TthMutY may be an example of a novel class of bifunctional A/GO mismatch DNA glycosylase that can also remove thymine from T/GO mispair.     

P1 nuclease cleavage is dependent on length of the mismatches in DNA

P1 nuclease is one of the most extensively used single-strand DNA specific nucleases in molecular biology. In modern biology, it is used as an enzymatic probe to detect altered DNA conformations. It is well documented that P1 cleaves single-stranded nucleic acids and single-stranded DNA regions. The fact that P1 can act under a wide range of conditions, including physiological pH and temperature make it the most commonly used enzymatic probe in DNA structural studies. Surprisingly, to this date, there is no study to characterize the influence of length of mismatches on P1 sensitivity. Using a series of radioactively labeled oligomeric DNA substrates-containing mismatches, we find that P1 nuclease cleavage is dependent on the length of mismatches. P1 does not cleave DNA when there is a single-base mismatch. P1 cleavage efficiency is optimum when mismatch length is 3 nt or more. Changing the position of the mismatches also does not make any difference in cleavage efficacy. These novel findings on P1 properties have implications for its use in DNA structure and DNA repair studies.     

Intact MutY and its catalytic domain differentially contact with A/8-oxoG-containing DNA

Escherichia coli MutY is an adenine and a weak guanine DNA glycosylase active on DNA substrates containing A/G, A/8-oxoG, A/C or G/8-oxoG mismatches. A truncated form of MutY (M25, residues 1–226) retains catalytic activity; however, the C-terminal domain of MutY is required for specific binding to the 8-oxoG and is critical for mutation avoidance of oxidative damage. Using alkylation interference experiments, the determinants of the truncated and intact MutY were compared on A/8-oxoG-containing DNA. Several purines within the proximity of mismatched A/8-oxoG show differential contact by the truncated and intact MutY. Most importantly, methylation at the N7 position of the mismatched 8-oxoG and the N3 position of mismatched A interfere with intact MutY but not with M25 binding. The electrostatic contacts of MutY and M25 with the A/8-oxoG-containing DNA substrates are drastically different as shown by ethylation interference experiments. Five consecutive phosphate groups surrounding the 8-oxoG (one on the 3′ side and four on the 5′ side) interact with MutY but not with M25. The activities of the truncated and intact MutY are modulated differently by two minor groove-binding drugs, distamycin A and Hoechst 33258. Both distamycin A and Hoechst 33258 can inhibit, to a similar extent, the binding and glycosylase activities of MutY and M25 on A/G mismatch. However, binding and glycosylase activities on A/8-oxoG mismatch of intact MutY are inhibited to a lesser degree than those of M25. Overall, these results suggest that the C-terminal domain of MutY specifies additional contact sites on A/GO-containing DNA that are not found in MutY–A/G and M25–A/8-oxoG interactions.     

Non-Enzymatic Depurination of Nucleic Acids: Factors and Mechanisms

Depurination has attracted considerable attention since a long time for it is closely related to the damage and repair of nucleic acids. In the present study, depurination using a pool of 30-nt short DNA pieces with various sequences at diverse pH values was analyzed by High Performance Liquid Chromatography (HPLC). Kinetic analysis results showed that non-enzymatic depurination of oligodeoxynucleotides exhibited typical first-order kinetics, and its temperature dependence obeyed Arrhenius’ law very well. Our results also clearly showed that the linear relationship between the logarithms of rate constants and pH values had a salient point around pH 2.5. Interestingly and unexpectedly, depurination depended greatly on the DNA sequences. The depurination of poly (dA) was found to be extremely slow, and thymine rich sequences depurinated faster than other sequences. These results could be explained to some extent by the protonation of nucleotide bases. Moreover, two equations were obtained based on our data for predicting the rate of depurination under various conditions. These results provide basic data for gene mutagenesis and nucleic acids metabolism in acidic gastric juice and some acidic organelles, and may also help to rectify some misconceptions about depurination.