Mismatch-containing oligonucleotide duplexes bound by the E. coli mutS-encoded protein.

The binding of the mutS gene product, a protein involved in at least two E. coli mismatch correction pathways, to a series of synthetic DNA duplexes containing mismatches or mismatch analogues of the purine/pyrimidine type was studied in order to establish whether a correlation exists between the recognition of these mispairs and the efficiency of their correction in vivo. Experiments using nitrocellulose filter binding or band-shift assays revealed that duplexes containing a G/T mismatch or its analogues I/T and DI/T were bound by the protein with affinities correlating to the efficiency of their repair in vivo. In contrast, the A/C mismatch, contained within the same sequence, was bound only poorly, despite being efficiently corrected in vivo. The analogues of the A/C mispair, uncorrected in vivo, were not detectably bound under the conditions of these assays.     

Repair of Single- and Multiple-Substitution Mismatches during Recombination in Streptococcus Pneumoniae

The use as genetic markers, during transformation of Streptococcus pneumoniae, of 19 sequences differing from wild type, located throughout the amiA locus, enabled us to examine the fate of 24 single- and 11 multiple-mismatches during recombination. Tentative mismatch ranking as a function of decreasing repair efficiency by the Hex mismatch repair system is G/T = A/C = G/G (maximum repair: 90-95%) greater than C/T (mostly 75 to 90% repair) greater than A/A (from 50 to 90% repair) greater than T/T (50-65% repair) greater than A/G (from 0 to 20% repair) greater than C/C. No indication of correction of the latter has been obtained. Over the limited number of samples examined, we observed no influence of the base composition of the surrounding sequence on correction efficiency for both transition mismatches and for G/G and C/C. Variations in the surrounding sequence affect repair of A/G and C/T, and, even more strongly, of A/A and T/T. No simple correlation to the G:C content of the surrounding sequence is apparent from our results, in contrast to the conclusion drawn for the Mut mismatch repair system of Escherichia coli. Examination of the fate of multiple mismatches suggests that C/C may sometimes impede recognition of otherwise corrected mismatches.     

Heteroduplex DNA correction in Saccharomyces cerevisiae is mismatch specific and requires functional PMS genes.

In vitro-constructed heteroduplex DNAs with defined mismatches were corrected in Saccharomyces cerevisiae cells with efficiencies that were dependent on the mismatch. Single-nucleotide loops were repaired very efficiently; the base/base mismatches G/T, A/C, G/G, A/G, G/A, A/A, T/T, T/C, and C/T were repaired with a high to intermediate efficiency. The mismatch C/C and a 38-nucleotide loop were corrected with low efficiency. This substrate specificity pattern resembles that found in Escherichia coli and Streptococcus pneumoniae, suggesting an evolutionary relationship of DNA mismatch repair in pro- and eucaryotes. Repair of the listed mismatches was severely impaired in the putative S. cerevisiae DNA mismatch repair mutants pms1 and pms2. Low-efficiency repair also characterized pms3 strains, except that correction of single-nucleotide loops occurred with an efficiency close to that of PMS wild-type strains. A close correlation was found between the repair efficiencies determined in this study and the observed postmeiotic segregation frequencies of alleles with known DNA sequence. This suggests an involvement of DNA mismatch repair in recombination and gene conversion in S. cerevisiae.     

Glutathione mixed disulfides and heterogeneity of chicken hemoglobins.

1. Adult chicken hemoglobins Hb A and Hb D interact with glutathione disulfide, GSSG. The major hemoglobin, Hb A, forms at least two new components, termed GHb AI and GHb AII, and Hb D forms at least one, GHb DI. 2. At pH 8.0 and 5 degrees C, glutathione disulfide (GSSG) in a molar excess of 50 x took 6 days to complete the reaction, although at pH 8.6 and 41 degrees C only 1 hr was needed, where the hemoglobins Hb A and Hb D were converted to their most mobile forms GHb AII and GHb DI. 3. Slight molar excess (2.7 GSSG/Hb, pH 7.4, 41 degrees C), reacting for 1 hr, showed extensive formation of GHb AI and some GHb AII. 4. Electrophoretic patterns, from the reaction products of 54 GSSG/Hb excess at different times, showed a marked pH dependence. 5. Titration with pCMB (p-chloromercuribezoic acid) of DTE (dithioerythrytol)-reduced samples showed 8.0 +/- 0.4 (N = 5) -SH (sulfhydryl) per tetramer. In hemolysates not reacted with DTE, 6.0 +/- 0.4 (N = 3) -SH were detected. 6. DTE-reduced and GSSG-reacted hemoglobins showed 4.6 +/- 0.5 (N = 7) -SH and 1.5 +/- 0.4 (N = 6) -SH, respectively, as titrated by DTNB, pH 8.0. DTE-reduced hemoglobins showed four fast-reacting -SH groups, no longer present in GSSG-reacted hemoglobins. 7. Our data indicate that chicken GHb AI and GHb DI probably have two glutathionyl residues per tetramer whereas GHb AII has four.(ABSTRACT TRUNCATED AT 250 WORDS)     

Processing of mispaired and unpaired bases in heteroduplex DNA in E. coli

Bacteriophage lambda and phi X 174 DNAs, carrying sequenced mutations, have been used to construct in vitro defined species of heteroduplex DNA. Such heteroduplex DNAs were introduced by transfection, as single copies, into E. coli host cells. The progeny of individual heteroduplex molecules from each infective center was analyzed. The effect of the presence of GATC sequences (phi X 174 system) and of their methylation (lambda system) was tested. The following conclusions can be drawn: some mismatched base pairs trigger the process of mismatch repair, causing a localized strand-to-strand information transfer in heteroduplex DNA: transition mismatches G:T and A:C are efficiently repaired, whereas the six transversion mismatches are not always readily recognized and/or repaired. The recognition of transversion mismatches appears to depend on the neighbouring nucleotide sequence; single unpaired bases (frameshift mutation "mismatches") are recognized and repaired, some equally efficiently on both strands (longer and shorter), some more efficiently on the shorter (-1) strand; large non-homologies (about 800 bases) are not repaired by the Mut H, L, S, U system, but some other process repairs the non-homology with a relatively low efficiency; full methylation of GATC sequences inhibits mismatch repair on the methylated strand: this is the chemical basis of strand discrimination (old/new) in mismatch correction; unmethylated GATC sequences appear to improve mismatch repair of a G:T mismatch in phi X 174 DNA, but there may be some residual mismatch repair in GATC-free phi X 174, at least for some mismatches.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cyclic analogues of Tyr-W-MIF-1 with prolonged analgesic activity and potency comparable to DAMGO and morphine

Two cyclic analogues of the brain peptide Tyr-W-MIF-1 (Tyr-Pro-Trp-Gly-NH₂) were synthesized and tested for analgesic activity in the rat tail flick test after intracerebroventricular (ICV) injection. The analogues were about 200-fold more potent than the parent peptide. Analgesia was dose dependent, and at 1 μg the two analogues, the mu-selective enkephalin analogue DAMGO (

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), and morphine, all produced analgesia lasting between 40 and 60 min. Analgesia of longer duration was evident at higher doses of the analogues and lasted more than 6 h after 100 μg, the highest dose tested. The results show that peptide analogues based on the structure of the endogenously occurring Tyr-W-MIF-1 can produce potent and long-lasting effects on nociception.     

Raman study of potential "antisense" drugs: nonamer oligonucleotide duplexes with a central mismatch as a model system for the binding selectivity evaluation

A set of four 9-mer oligonucleotide duplexes formed between the 5'-GCATNTCAC-3', N=A,C,T,G, and the 5'-GTGATATGC-3' complement has been proposed as a model system for the investigation of novel oligonucleotide analogues (candidates for antisense use) binding selectivity. Raman measurements were carried out on a set of natural DNA 9-mer in order to verify suitability of the model and to obtain reference spectral data. Difference Raman spectra between the mismatch and match duplexes obtained at 15 degrees C exhibited numerous spectral features sensitively indicating the structural changes. All the three mismatches only very weakly disturb the overall B-form conformation of the duplex. Significant structural changes that occurred at the mismatch site are reflected mainly by the neighboring thymidine Raman bands at 1377, 1650, and 1675 cm(-1). The intensity change of the two latter bands is almost the same for the T:G and the T:T mismatch while in the case of the T:C mismatch it is just opposite, demonstrating a very different arrangement of the mismatched pair.     

Thermodynamic contributions for the incorporation of GTA triplets within canonical TAT/TAT and C+GC/C+GC base-triplet stacks of DNA triplexes

Nucleic acid triple helices may be used in the control of gene expression. One limitation of using triplex-forming oligonucleotides as therapeutic agents is that their target sequences are limited to homopurine tracts. To increase the repertoire of sequences that can be targeted, it has been postulated that a guanine can target a thymidine forming a stable GTA mismatch triplet. In this work, we have used a combination of optical and calorimetric techniques to determine thermodynamic unfolding profiles of two triplexes containing a single GTA triplet, d(A(3)TA(3)C(5)T(3)AT(3)C(5)T(3)GT(3)) (ATA) and d(AGTGAC(5)TCACTC(5)TCGCT) (GTG), and their control triplexes, d(A(7)C(5)T(7)C(5)T(7)) (TAT7) and d(AGAGAC(5)TCTCTC(5)TCTCT) (AG5T). In general, the presence of a GTA mismatch in DNA triplexes is destabilizing; however, this destabilization is greater when placed in a C(+)GC/C(+)GC base-triplet stack than between a TAT/TAT stack. These destabilizations are accompanied by a reduced unfolding enthalpy of approximately 10 kcal/mol, suggesting a decrease in the base stacking contributions surrounding the mismatch. Relative to their corresponding control triplexes, the folding of ATA is accompanied by a lower counterion uptake and a similar proton uptake, while GTG folding is accompanied by an increase in the counterion and proton uptakes. These effects are consistent with the observed decrease in stacking interactions. The overall results indicate that the main difficulty of targeting pyrimidine interruptions is that the decrease in stacking contributions, due to the incorporation of a GTA mismatch, affects the stability of the neighboring base triplets. This suggests that nucleotide analogues that increase the strength of these base-triplet stacks will result in a more effective targeting of pyrimidine interruptions.     

Mammalian assay for site-specific DNA damage processing using the human H-ras proto-oncogene.

The human genomic H-ras proto-oncogene was inserted into an Epstein-Barr virus (EBV) vector (p220.2) that replicates synchronously with the cell cycle. Unique restriction enzyme sites, 30 bp apart, were created on either side of codon 12 to enable the construction of gapped heteroduplex (GHD) DNA. Depending upon experimental protocol, the gap could be located either on the coding (non-transcribed) strand or the non-coding (transcribed) strand. GHD DNA was created using a 1.8 kb segment of H-ras DNA containing exon 1, into which a synthetic 30 nucleotide oligomer containing a strand- and site-specific mismatched nucleotide was annealed. The 1.8 kb segment of H-ras DNA containing a codon 12; middle G:T, A:C or T:C mismatch has been religated with high efficiency into the EBV vector and transfected into NIH 3T3 cells using a mild liposome-mediated protocol. Subsequent hygromycin resistant NIH 3T3 colonies have been PCR amplified and sequenced. In this study, codon 12; middle nucleotide mismatch correction rates to wild-type G:C during replication in NIH 3T3 cells were 96.4% of G:T mismatches, 87.5% of A:C mismatches and 67% of T:C mismatches.     

A kinetic and conformational study on the interaction of tetrahydropteridines with tyrosine hydroxylase

Tetrahydropterins are obligatory cofactors for tyrosine hydroxylase (TH), the rate-limiting enzyme of catecholamine biosynthesis. A series of synthetic analogues of 6(R)-L-erythro-5,6,7, 8-tetrahydrobiopterin (BH(4)) with different substituents in positions C2, N3, C4, N5, C6, C7, and N8 on the ring were used as active site probes for recombinant human TH. The enzyme tolerates rather bulky substituents at C6, as seen by the catalytic efficiency (V(max)/K(m)) and the coupling efficiency (mol of L-DOPA produced/mol of tetrahydropterin oxidized) of the cofactors. Substitutions at C2, C4, N5, and N8 abolish the cofactor activity of the pterin analogues. Molecular docking of BH(4) into the crystal structure of the catalytic domain of ligand-free rat TH results in complexes in which the pteridine ring pi-stacks with Phe300 and the N3 and the amino group at C2 hydrogen bonds with Glu332. The pteridine ring also establishes interactions with Leu294 and Gln310. The distance between C4a in the pteridines and the active site iron was 4.2 +/- 0.5 A for the ensemble of docked conformers. Docking of BH(4) analogues into TH also shows that the most bulky substituents at C6 can be well-accommodated within the large hydrophobic pocket surrounded by Ala297, Ser368, Tyr371, and Trp372, without altering the positioning of the ring. The pterin ring of 7-BH(4) shows proper stacking with Phe300, but the distance between the C4a and the active site iron is 0.6 A longer than for bound BH(4), a finding that may be related to the high degree of uncoupling observed for 7-BH(4).     

Interaction of MTHFR 1298C with ACE D allele augments the risk of diabetic nephropathy in Western Iran

The aim of the current study was to examine the influence of interaction between polymorphisms of methylenetetrahydrofolate reductase (MTHFR) C677T and A1298C with angiotensin converting enzyme insertion/deletion (ACE I/D) polymorphism on the risk of diabetic nephropathy (DN). In a case control study using polymerase chain reaction (PCR)- and PCR-restriction fragment length polymorphism (RFLP), the presence of three polymorphisms in 140 patients with type 2 diabetes mellitus (T2DM) with nephropathy including patients with micro- and macro-albuminuria and 72 patients with normoalbuminuria from Western Iran were investigated. In the presence of both MTHFR 677 T and ACE D alleles, there was a trend toward increased risk of DN 2.68-fold (p=0.054). The possession of both MTHFR 677 T and ACE D alleles increased the risk of macro-albuminuria four times (p=0.035). The concomitant presence of both MTHFR 1298 C and ACE D alleles increased the risk of macro-albuminuria 7.8-fold (p=0.012). In addition, the risk of progression from micro- to macro-albuminuria in the presence of both alleles tended to be increased (4.1-fold, p=0.09). Our study for the first time demonstrated a synergistic effect between ACE I/D with either MTHFR C677T or A1298C polymorphism on the increased risk of DN among patients with T2DM. We found that MTHFR 1298 C strongly interacts with the ACE D allele and augments the risk of DN in our population.     

Mismatch repair proteins collaborate with methyltransferases in the repair of O(6)-methylguanine

DNA repair is essential for combatting the adverse effects of damage to the genome. One example of base damage is O(6)-methylguanine (O(6)mG), which stably pairs with thymine during replication and thereby creates a promutagenic O(6)mG:T mismatch. This mismatch has also been linked with cellular toxicity. Therefore, in the absence of repair, O(6)mG:T mismatches can lead to cell death or result in G:C-->A:T transition mutations upon the next round of replication. Cysteine thiolate residues on the Ada and Ogt methyltransferase (MTase) proteins directly reverse the O(6)mG base damage to yield guanine. When a cytosine is opposite the lesion, MTase repair restores a normal G:C pairing. However, if replication past the lesion has produced an O(6)mG:T mismatch, MTase conversion to a G:T mispair must still undergo correction to avoid mutation. Two mismatch repair pathways in E. coli that convert G:T mispairs to native G:C pairings are methyl-directed mismatch repair (MMR) and very short patch repair (VSPR). This work examined the possible roles that proteins in these pathways play in coordination with the canonical MTase repair of O(6)mG:T mismatches. The possibility of this repair network was analyzed by probing the efficiency of MTase repair of a single O(6)mG residue in cells deficient in individual mismatch repair proteins (Dam, MutH, MutS, MutL, or Vsr). We found that MTase repair in cells deficient in Dam or MutH showed wild-type levels of MTase repair. In contrast, cells lacking any of the VSPR proteins MutS, MutL, or Vsr showed a decrease in repair of O(6)mG by the Ada and Ogt MTases. Evidence is presented that the VSPR pathway positively influences MTase repair of O(6)mG:T mismatches, and assists the efficiency of restoring these mismatches to native G:C base pairs.     

Expansion of the population of double negative CD4-8- T alpha beta-cells in the liver is a common feature of autoimmune mice.

There have been several reports that double negative (DN) CD4-8- T alpha beta-cells might be responsible for the onset of autoimmune diseases in humans and mice. We previously revealed that such DN T alpha beta-cells are generated in the liver of autoimmune MRL-lpr/lpr mice. In the present study, we further characterize the histology of the liver in these mice by light and electron microscopic studies. An intensive accumulation of mononuclear cells in the liver was demonstrated and a significant proportion of these mononuclear lymphocytes was found to intimately interact with Kupffer cells or endothelial cells of the hepatic sinusoids. The majority of such lymphocytes were TcR+CD4-8-Pgp-1+ alpha beta-cells. Identification of DN T alpha beta-cells was then performed in various autoimmune model mice. Interestingly, all autoimmune mice tested (i.e., MRL-lpr/lpr, C3H/HeJ-gld/gld, BXSB, NOD, MRL(-)+/+ and NZB/W F1 mice), showed an increased proportion of DN T alpha beta-cells (greater than 11% among all MNC) in the liver when they became old and diseased. On the other hand, young and old normal mice and young autoimmune mice before the onset of disease did not have such a high proportion of DN T alpha beta-cells (less than 10%) in the liver. Among autoimmune mice, MRL-lpr/lpr and C3H/HeJ-gld/gld mice had lymphadenopathy, which consisted of DN T alpha beta-cells (greater than 25%), after the onset of disease. Autoimmune mice of the other strains had neither lymphadenopathy nor DN T alpha beta-cells in the periphery, even when they were diseased. These results suggest that the expansion of the DN T alpha beta-cell population in the liver is a common feature of autoimmune mice, irrespective of the information of lymphadenopathy.     

Pulse sequences for detection of NH2···N hydrogen bonds in sheared G⋅A mismatches via remote, non-exchangeable protons

The non-detectability of NH...N hydrogen bonds in nucleic acids due to exchange broadened imino/amino protons has recently been addressed via the use of non-exchangeable protons for detecting internucleotide 2hJ(NN) couplings. In these applications, the appropriate non-exchangeable proton is separated by two bonds from the NH...N bond. In this paper, we extend the scope of this approach to protons which are separated by four bonds from the NH...N moiety. Specifically, we consider the case of the commonly occurring sheared G x A mismatch alignment, in which we use the adenine H2 proton to report on the (A)N6H6(1.2)...N3(G) hydrogen bond, in the presence of undetectable, exchange broadened N6H6(1.2) protons. Two sequences, the 'straight-through' (H6)N6N3H2 and 'out-and-back' H2N6N3 experiments, are presented for observing these correlations in H2O and D2O solution, respectively. The sequences are demonstrated on two uniformly 15N,13C labelled DNA samples: d(G1G2G3T4T5C6A7G8G9)2, containing a G3 x (C6-A7) triad involving a sheared G3 x A7 mismatch, and d(G1G2G3C4A5G6G7T8)4, containing an A5 x (G3 x G6 x G3 x G6) x A5 hexad involving a sheared G3 x A5 mismatch.     

Base mismatch-specific endonuclease activity in extracts from Saccharomyces cerevisiae.

An endonuclease activity (called MS-nicking) for all possible base mismatches has been detected in the extracts of yeast, Saccharomyces cerevisiae. DNAs with twelve possible base mismatches at one defined position are cleaved at different efficiencies. DNA fragments with A/G, G/A, T/G, G/T, G/G, or A/A mismatches are nicked with greater efficiencies than C/T, T/C, C/A, and C/C. DNA with an A/C or T/T mismatch is nicked with an intermediate efficiency. The MS-nicking is only on one particular DNA strand, and this strand disparity is not controlled by methylation, strand break, or nature of the mismatch. The nicks have been mapped at 2-3 places at second, third, and fourth phosphodiester bonds 5' to the mispaired base; from the time course study, the fourth phosphodiester bond probably is the primary incision site. This activity may be involved in mismatch repair during genetic recombination.     

DNA mismatch correction by Very Short Patch repair may have altered the abundance of oligonucleotides in the E. coli genome.

A base mismatch correction process in E. coli K-12 called Very Short Patch (VSP) repair corrects T:G mismatches to C:G when found in certain sequence contexts. Two of the substrate mismatches (5'-CTWGG/3'-GGW'CC; W = A or T) occur in the context of cytosine methylation in DNA and reduce the mutagenic effects of 5-methylcytosine deamination to thymine. However, VSP repair is also known to repair T:G mismatches that are not expected to arise from 5-methylcytosine deamination (example--CTAG/GGT-C). In these cases, if the original base pair were a T:A, VSP repair would cause a T to C transition. We have carried out Markov chain analysis of an E. coli sequence database to determine if repair at the latter class of sites has altered the abundance of the relevant tetranucleotides. The results are consistent with the prediction that VSP repair would tend to deplete the genome of the 'T' containing sequences (example--CTAG), while enriching it for the corresponding 'C' containing sequences (CCAG). Further, they provide an explanation for the known scarcity of CTAG containing restriction enzyme sites among the genomes of enteric bacteria and identify VSP repair as a force in shaping the sequence composition of bacterial genomes.     

Mismatches in DNA double strands: thermodynamic parameters and their correlation to repair efficiencies.

The helix-coil transitions of the 16 octadecameric DNA duplexes dCGTCGTTTXACAACGTCG X dCGACGTTGTX1AAACGACG with A, T, G, and C for X and X1 were measured by UV-absorption. This sequence was taken from former studies of in vivo determination of efficiencies of mismatch repair (Kramer, Kramer, and Fritz (1984) Cell 38, 879-887). The thermodynamic parameters for double strand and mismatch formation have been obtained by evaluating the partition function of a stack model which allowed for loop formation. As a result the mismatches could be classified into wobble base pairs (T/G, G/G, C/A, A/A, A/G), open base pairs, i.e. permanent loops (T/T, C/T, T/C, C/C), and intermediate or weak base pairs (G/T, A/C, G/A). There is no correlation between Tm and the biological repair efficiency of X/X1. The structure classes, however, as described above show a close correlation: Open base pairs show the lowest repair efficiencies, whereas mismatches with high repair efficiency always belong to the structural class of wobble base pairs. Because of the palindromic nearest neighbors of the variation site X/X1, the influence of next-nearest neighbor interactions could be detected and be estimated to about 1 kJ/mol for one stack.     

Exonuclease proofreading by human mitochondrial DNA polymerase

We have examined the ability of the human mitochondrial DNA polymerase to correct errors in DNA sequence using single turnover kinetic methods. The rate of excision of single-stranded DNA ranged from 0.07 to 0.17 x s(-1), depending on the identity of the 3'-base. Excision of the 3'-terminal base from correctly base paired DNA occurred at a rate of 0.05 x s(-1), indicating that the cost of proofreading is minimal, as defined by the ratio of the k(exo) for correctly base-paired DNA divided by the rate of forward polymerization (0.05/37 = 0.14%). Excision of duplex DNA containing 1-7 mismatches was biphasic, and the rate and amplitude of the fast phase increased with the number of mismatches, reaching a maximum of 9 x s(-1). We showed that transfer of DNA from the polymerase to the exonuclease active site and back again occurs through an intramolecular reaction, allowing for a complete cycle of reactions for error correction. For DNA containing a buried mismatch (T:T followed by C:G base pairs), the 3' base was removed at a rate of 3 x s(-1). The addition of nucleotide to the reaction that is identical to the 3' base increased the rate of excision 7-fold to 21 x s(-1). We propose that the free nucleotide enhances the rate of transfer of the DNA to the exonuclease active site by interrupting the correct 3' base pair through interaction with the template base. The exonuclease contribution to fidelity is minimal if the calculation is based on hydrolysis of a single mismatch: (k(exo) + k(pol,over))/(k(pol,over)) = 10, but this value increases to approximately 200 when examining error correction in the presence of nucleotides.     

Repair of Single Base-Pair Transversion Mismatches of Escherichia Coli in Vitro: Correction of Certain a/G Mismatches Is Independent of Dam Methylation and Host Muthls Gene Functions

Six different base-pair transversion mismatches are repaired with different efficiencies in an in vitro mismatch repair system. In particular, the T/T and C/C mismatches appear to be less efficiently repaired than the A/A and G/G mismatches. Four A/G and four C/T mismatches at different positions are repaired to different extents. One of the A/G mismatches is repaired equally efficiently when DNA heteroduplexes are fully methylated or hemi-methylated at the d(GATC) sequences. This type of mismatch repair appears to be unidirectional with A to C conversion by acting at A/G mispairs to restore the C/G pairs. This methylation-independent correction is not controlled by the mutH, mutL, mutS, uvrE, uvrB, phr, recA, recF, and recJ gene products. The independence of the transversion mismatch repair of these genes and methylation distinguishes this from the known mismatch repair pathways.