A novel nucleotide excision repair for the conversion of an A/G mismatch to C/G base pair in E. coli

A protein that binds specifically to A/G mismatches has been detected in E. coli by a gel electrophoresis DNA binding assay. A specific endonuclease is associated with the A/G mismatch-binding protein through two chromatographic steps. The endonuclease is specific for A/G-containing DNA fragments and has no cleavage activity on DNA containing the other seven possible mispairs or homoduplex DNA. The endonuclease simultaneously makes incisions at the first phosphodiester bond 3' to and the second phosphodiester bond 5' to the dA of the A/G mismatch. No incision site was detected on the other strand. These results are consistent with the unidirectional A to C conversion and short repair tract of a novel dam- and mutHLS-independent A/G repair pathway we have recently described. A nucleotide excision repair model is proposed for the conversion of an A/G mismatch to a C/G base pair.     

G/U lesions are efficiently corrected to G/C in SV40 DNA

Cytosine spontaneously deaminates to form uracil, generating G/U pairs in DNA. We studied the repair of these lesions by introducing specific G/U pairs into the genome of SV40 and determining the fate of the mispaired bases in Simian cells. Analysis of 135 plaques obtained after transfection of the modified viral DNA indicates that G/U lesions were repaired to G/C in every case. This result indicates that G/U lesions are corrected with greater efficiency and specificity than any combination of DNA base/base mispairs, in transfected SV40 DNA.     

60Co gamma-rays induce predominantly C/G to G/C transversions in double-stranded M13 DNA.

Upon irradiation with gamma rays of an oxygenated aqueous solution of double-stranded M13 DNA, a very specific mutation spectrum was found with respect to both the type and the positions in the DNA sequence. Of the 23 mutations, which were sequenced, 16 represent a C/G to G/C transversion. A C/G to T/A transition was found once and a G/C to T/A transversion twice. The remaining 4 mutations are frameshifts, 2 are identical and formed by the insertion of a G/C basepair; the other 2 mutations are due to a duplication of 10 basepairs situated at different positions but with a remarkable homology in base sequence. Fourteen mutations, including the 2 duplications are found in the neighbourhood of a TGCT/ACGA sequence.     

High G/C content of cohesive overhangs renders DNA end joining Ku-independent

Ku plays an important role in the repair of double strand DNA breaks by non-homologous DNA end joining (NHEJ). Ku is thought to exert its function by aligning the two DNA ends. A previous study showed that the joining of certain cohesive DNA ends in cell-free in vitro reactions was independent of Ku [Mol. Cell. Biol. 19 (1999) 2585]. To investigate a possible correlation between Ku-dependence of DNA end joining reactions and the strength of base pair interactions between cohesive ends, we constructed a series of repair substrates with either 3'- or 5'-overhangs, which consisted entirely of either A/T or G/C residues. We found that after Ku-immunodepletion of the extract, the joining of cohesive ends that associate by the formation of four A:T base pairs was reduced, while the joining of ends that associate through four G:C base pairs was unaffected or slightly stimulated. The precision of the repair was not reduced in Ku-independent reactions. Our results indicate that the requirement for Ku is dependent on how stably the two cohesive DNA ends can associate by base-pairing. Two independent assays for protein-DNA interactions did not reveal any differences in Ku binding to substrates with A/T and G/C overhangs, suggesting that in this system Ku is recruited to the repair site regardless of whether it is functionally required or not. The finding that Ku is dispensable for efficient and precise joining of ends with cohesive G/C overhangs also suggests that alignment of DNA ends may be the sole function of Ku during NHEJ.     

Identification of proteins of Escherichia coli and Saccharomyces cerevisiae that specifically bind to C/C mismatches in DNA

The pathways leading to G:C→C:G transversions and their repair mechanisms remain uncertain. C/C and G/G mismatches arising during DNA replication are a potential source of G:C→C:G transversions. The Escherichia coli mutHLS mismatch repair pathway efficiently corrects G/G mismatches, whereas C/C mismatches are a poor substrate. Escherichia coli must have a more specific repair pathway to correct C/C mismatches. In this study, we performed gel-shift assays to identify C/C mismatch-binding proteins in cell extracts of E.coli. By testing heteroduplex DNA (34mers) containing C/C mismatches, two specific band shifts were generated in the gels. The band shifts were due to mismatch-specific binding of proteins present in the extracts. Cell extracts of a mutant strain defective in MutM protein did not produce a low-mobility complex. Purified MutM protein bound efficiently to the C/C mismatch-containing heteroduplex to produce the low-mobility complex. The second protein, which produced a high-mobility complex with the C/C mismatches, was purified to homogeneity, and the amino acid sequence revealed that this protein was the FabA protein of E.coli. The high-mobility complex was not formed in cell extracts of a fabA mutant. From these results it is possible that MutM and FabA proteins are components of repair pathways for C/C mismatches in E.coli. Furthermore, we found that Saccharomyces cerevisiae OGG1 protein, a functional homolog of E.coli MutM protein, could specifically bind to the C/C mismatches in DNA.     

Hydrogen peroxide induces G:C to TA and G:C to C:G transversions in the supF gene of Escherichia coli

A vector plasmid, pZ189, carrying an Escherichia coli supF gene as a target for mutations, was treated with a combination of hydrogen peroxide and Fe³⁺/EDTA complex and propagated in E. coli host cells that had been induced for SOS functions by ultraviolet irradiation. The mutations frequency increased by up to 30-fold over spontaneous background levels with increasing concentrations of hydrogen peroxide. The increase in mutation frequency correlated with an increase in the formation of 8-hydroxydeoxyguanosine in the pZ189 DNA. Sequence analysis of 82 independent supF mutant plasmids revealed that 70 mutants contained base substitutions, with 63 of the 70 involving a G:C base pair, and with G:CC:G (28 cases) and G:CT:A (26 cases) transversions predominating. Investigation of the influence of the local DNA sequence on the transversions revealed that the guanine at the center of the triplet 5-PuGA-3 was five times more likely to mutate after treatment with hydrogen peroxide than that at the center of 5PyGN3. G:CT:A transversions presumably resulted from mispairing of an altered G (probably 8-hydroxydeoxyguanosine) with deoxyadenosine. The origin of the G:CC:G transversions may be an as yet unidentified lesion generated by hydrogen peroxide. Mutagenic hotspots for base substitutions were found at positions 133, 160 and 168. Mutation spectra and the positions of mutagenic hotspots, when compared with a previously determined spontaneous mutagenesis spectrum, also provide information on the mechanism of spontaneous mutagenesis.     

A DNA repair process in Escherichia coli corrects U:G and T:G mismatches to C:G at sites of cytosine methylation

Escherichia coli contains a base mismatch correction system called VSP repair that is known to correct T:G mismatches to C:G when they occur in certain sequence contexts. The preferred sequence context for this process is the site for methylation by the E. coli DNA cytosine methylase (Dcm). For this reason, VSP repair is thought to counteract potential mutagenic effects of deamination of 5-methylcytosine to thymine. We have developed a genetic reversion assay that quantitates the frequency of C to T mutations at Dcm sites and the removal of such mutations by DNA repair processes. Using this assay, we have studied the repair of U: G mismatches in DNA to C: G and have found that VSP repair is capable of correcting these mismatches. Although VSP repair substantially affects the reversion frequency, it may not be as efficient at correcting U: G mismatches as the uracil DNA glycosylase-mediated repair process.     

BseSI, a restriction endonuclease from Bacillus stearothermophilus Jo 10-553, which recognizes the novel hexanucleotide sequence 5'-G(G/T)GC(A/C)C-3'.

A new restriction endonuclease Bse SI has been isolated from Bacillus stearothermophilus Jo10-553. Bse SI recognizes a degenerate hexanucleotide sequence 5'-G(G/T)GC(A/C)C-3' and cleaves DNA to produce 3[prime]-protruding tetranucleotide ends.     

Hydrogen peroxide induces G:C to TA and G:C to C:G transversions in the supF gene of Escherichia coli

A vector plasmid, pZ189, carrying an Escherichia coli supF gene as a target for mutations, was treated with a combination of hydrogen peroxide and Fe³⁺/EDTA complex and propagated in E. coli host cells that had been induced for SOS functions by ultraviolet irradiation. The mutations frequency increased by up to 30-fold over spontaneous background levels with increasing concentrations of hydrogen peroxide. The increase in mutation frequency correlated with an increase in the formation of 8-hydroxydeoxyguanosine in the pZ189 DNA. Sequence analysis of 82 independent supF mutant plasmids revealed that 70 mutants contained base substitutions, with 63 of the 70 involving a G:C base pair, and with G:C→C:G (28 cases) and G:C→T:A (26 cases) transversions predominating. Investigation of the influence of the local DNA sequence on the transversions revealed that the guanine at the center of the triplet 5′-PuGA-3′ was five times more likely to mutate after treatment with hydrogen peroxide than that at the center of 5′PyGN3′. G:C→T:A transversions presumably resulted from mispairing of an altered G (probably 8-hydroxydeoxyguanosine) with deoxyadenosine. The origin of the G:C→C:G transversions may be an as yet unidentified lesion generated by hydrogen peroxide. Mutagenic hotspots for base substitutions were found at positions 133, 160 and 168. Mutation spectra and the positions of mutagenic hotspots, when compared with a previously determined spontaneous mutagenesis spectrum, also provide information on the mechanism of spontaneous mutagenesis.     

A mouse kidney cell line with a G:C --> C:G transversion mutator phenotype

We report the identification of a mouse kidney epithelial cell line (K435) in which G:C-->C:G transversion mutations occur at an elevated rate and are the predominant spontaneous events observed at the selectable Aprt locus. Of three genotoxins tested, ultraviolet radiation (UV), ionizing radiation, and hydrogen peroxide, only UV exposure was able to alter the spectrum of small mutational events. To determine if the G:C-->C:G mutator phenotype was due to a deficiency in the mismatch repair pathway, the K435 cells were tested for resistance to 6-thioguanine, cisplatin, and MNNG. Although the K435 cells were as resistant to 6-thioguanine and cisplatin as Pms2 and Mlh1 null kidney cells, they were hypersensitive to MNNG. Moreover, the K435 cells do not exhibit microsatellite instability, a hallmark of mismatch repair deficiency. These results suggest that a novel mechanism, which does not include a classical deficiency in mismatch repair, accounts for the G:C-->C:G mutator phenotype.     

A DNA repair process in Escherichia coli corrects U:G and T:G mismatches to C:G at sites of cytosine methylation

Escherichia coli contains a base mismatch correction system called VSP repair that is known to correct T:G mismatches to C:G when they occur in certain sequence contexts. The preferred sequence context for this process is the site for methylation by the E. coli DNA cytosine methylase (Dcm). For this reason, VSP repair is thought to counteract potential mutagenic effects of deamination of 5-methylcytosine to thymine. We have developed a genetic reversion assay that quantitates the frequency of C to T mutations at Dcm sites and the removal of such mutations by DNA repair processes. Using this assay, we have studied the repair of U: G mismatches in DNA to C: G and have found that VSP repair is capable of correcting these mismatches. Although VSP repair substantially affects the reversion frequency, it may not be as efficient at correcting U: G mismatches as the uracil DNA glycosylase-mediated repair process.     

Specific A/G-to-C.G mismatch repair in Salmonella typhimurium LT2 requires the mutB gene product.

An assay has been developed that permits analysis of repair of A/G mismatches to C.G base pairs in cell extracts of Salmonella typhimurium LT2. This A/G mismatch repair is independent of ATP, dam methylation, and mutS gene function. The gene product of mutB has been shown to be involved in the dam-independent pathway through the in vitro assay. Moreover, specific DNA-protein complexes and an endonuclease can be detected in S. typhimurium extracts by using DNA fragments containing an A/G mismatch. These activities are not observed with substrates which have a T/G mismatch or no mismatch. The S. typhimurium endonuclease, like the A/G endonuclease found in Escherichia coli (A-L. Lu and D.-Y. Chang, Cell 54:805-812, 1988), makes incisions at the first phosphodiester bond 3' to and the the second phosphodiester bond 5' to the dA of the A/G mismatch. No incision site was detected on the other DNA strand. Extracts prepared from mutB mutants cannot form A/G mismatch-specific DNA-protein complexes and do not contain the A/G endonuclease activity. Thus the A/G mismatch specific binding and nicking activities are probably involved in the A/G mismatch repair pathway. Preliminary analysis of the mutational spectrum of the mutB strain has indicated that this mutator allele causes an increase in C.G-to-A.T transversions without affecting the frequencies of other transversion or transition events. In addition, the mutB gene has been mapped to the 64-min region of the S. typhimurium chromosome. Together, this biochemical and genetic evidence suggests that the mutB gene product of S. typhimurium is the homolog of the E. coli micA (and/or mutY) gene product.     

Recognition sequences of type II restriction systems are constrained by the G + C content of host genomes

I show that the recognition sequences of Type II restriction systems are correlated with the G + C content of the host bacterial DNA. Almost all restriction systems with G + C rich tetranucleotide recognition sequences are found in species with A + T rich genomes, whereas G + C rich hexanucleotide and octanucleotide recognition sequences are found almost exclusively in species with G + C rich genomes. Most hexanucleotide recognition sequences found in species with A + T rich genomes are A + T rich. This distribution eliminates a substantial proportion of the potential variance in the frequency of restriction recognition sequences in the host genomes. As a consequence, almost all restriction recognition sequences, including those eight base pairs in length (Not I and Sfi I), are predicted to occur with a frequency ranging from once every 300 to once every 5,000 base pairs in the host genome. Since the G + C content of bacteriophage DNA and of the host genome are also correlated, the data presented is evidence that most Type II "restriction systems" are indeed involved in phage restriction.     

Polymorphisms of DNA Repair Genes: ERCC1 G19007A and ERCC2/XPD C22541A in a Northeastern Chinese Population

DNA repair systems are responsible for maintaining the integrity of the genome and have a critical role in protecting against mutations that can lead to cancer. DNA repair gene products of ERCC1 and ERCC2/XPD are involved in the nucleotide excision repair pathway. The allele frequencies of the polymorphisms ERCC1 G19007A and ERCC2/XPD C22541A were examined in a northeastern Chinese population. The allele frequencies were 0.21 (A) and 0.79 (G) for ERCC1 G19007A and 0.49 (A) and 0.51 (C) for ERCC2/XPD C22541A. Comparison with average frequencies from previously reported Caucasian studies demonstrated that the A-allele frequency of ERCC1 G19007A was much lower in the northeastern Chinese population, indicating a remarkable ethnic difference (chi((1)) (2) = 160.09, p < 0.001), and that allele frequencies of ERCC2/XPD C22541A showed marginal racial differences (chi((1)) (2) = 4.36, p = 0.04). We have previously reported that both homozygote carriers of the A-allele as well as homozygous carriers of a high-risk haplotype (which includes the AA genotype in ERCC1 G19007A) were at increased risk of basal cell carcinoma, breast cancer, and lung cancer among Caucasians. The low A-allele frequency of ERCC1 G19007A in the Chinese population may suggest that the genetic contribution to cancer risk differs substantially between ethnic groups.     

Speedy/Ringo C regulates S and G2 phase progression in human cells

Cyclin-dependent kinases (CDKs) control cell cycle transitions and progression. In addition to their activation via binding to cyclins, CDKs can be activated via binding to an unrelated class of cell cycle regulators termed Speedy/Ringo (S/R) proteins. Although mammals contain at least five distinct Speedy/Ringo homologues, the specific functions of members of this growing family of CDK activators remain largely unknown. We investigated the cell cycle roles of human Speedy/Ringo C in HEK293 cells. Down-regulation of Speedy/Ringo C by RNA interference delayed S and G2 progression whereas ectopic expression had the opposite effect, reducing S and G2/M populations. Double thymidine arrest and release experiments showed that overexpression of Speedy/Ringo C promoted late S phase progression. Using a novel three-color FACS protocol to determine the length of G2 phase, we found that the suppression of Speedy/Ringo C by RNAi prolonged G2 phase by ~30 min whereas ectopic expression of Speedy/Ringo C shortened G2 phase by ~25 min. In addition, overexpression of Speedy/Ringo C disrupted the G2 DNA damage checkpoint, increased cell death and caused a cell cycle delay at the G1-to-S transition. These observations indicate that CDK-Speedy/Ringo C complexes positively regulate cell cycle progression during the late S and G2 phases of the cell cycle.     

Escherichia coli MutY protein has a guanine-DNA glycosylase that acts on 7,8-dihydro-8-oxoguanine:guanine mispair to prevent spontaneous G:C-->C:G transversions.

Low rates of spontaneous G:C-->C:G transversions would be achieved not only by the correction of base mismatches during DNA replication but also by the prevention and removal of oxidative base damage in DNA. Escherichia coli must have several pathways to repair such mismatches and DNA modifications. In this study, we attempted to identify mutator loci leading to G:C-->C:G transversions in E.coli. The strain CC103 carrying a specific mutation in lacZ was mutagenized by random miniTn 10 insertion mutagenesis. In this strain, only the G:C-->C:G change can revert the glutamic acid at codon 461, which is essential for sufficient beta-galactosidase activity to allow growth on lactose. Mutator strains were detected as colonies with significantly increased rates of papillae formation on glucose minimal plates containing P-Gal and X-Gal. We screened approximately 40 000 colonies and selected several mutator strains. The strain GC39 showed the highest mutation rate to Lac+. The gene responsible for the mutator phenotypes, mut39 , was mapped at around 67 min on the E.coli chromosome. The sequencing of the miniTn 10 -flanking DNA region revealed that the mut39 was identical to the mutY gene of E.coli. The plasmid carrying the mutY + gene reduced spontaneous G:C-->T:A and G:C-->C:G mutations in both mutY and mut39 strains. Purified MutY protein bound to the oligonucleotides containing 7,8-dihydro-8-oxo-guanine (8-oxoG):G and 8-oxoG:A. Furthermore, we found that the MutY protein had a DNA glycosylase activity which removes unmodified guanine from the 8-oxoG:G mispair. These results demonstrate that the MutY protein prevents the generation of G:C-->C:G transversions by removing guanine from the 8-oxoG:G mispair in E.coli.     

Hydroxymethylated Cytosines Are Associated with Elevated C to G Transversion Rates

It has long been known that methylated cytosines deaminate at higher rates than unmodified cytosines and constitute mutational hotspots in mammalian genomes. The repertoire of naturally occurring cytosine modifications, however, extends beyond 5-methylcytosine to include its oxidation derivatives, notably 5-hydroxymethylcytosine. The effects of these modifications on sequence evolution are unknown. Here, we combine base-resolution maps of methyl- and hydroxymethylcytosine in human and mouse with population genomic, divergence and somatic mutation data to show that hydroxymethylated and methylated cytosines show distinct patterns of variation and evolution. Surprisingly, hydroxymethylated sites are consistently associated with elevated C to G transversion rates at the level of segregating polymorphisms, fixed substitutions, and somatic mutations in tumors. Controlling for multiple potential confounders, we find derived C to G SNPs to be 1.43-fold (1.22-fold) more common at hydroxymethylated sites compared to methylated sites in human (mouse). Increased C to G rates are evident across diverse functional and sequence contexts and, in cancer genomes, correlate with the expression of Tet enzymes and specific components of the mismatch repair pathway (MSH2, MSH6, and MBD4). Based on these and other observations we suggest that hydroxymethylation is associated with a distinct mutational burden and that the mismatch repair pathway is implicated in causing elevated transversion rates at hydroxymethylated cytosines.     

Hypermutation at A/T sites during G.U mismatch repair in vitro by human B-cell lysates

Somatic hypermutation in the variable regions of immunoglobulin genes is required to produce high affinity antibody molecules. Somatic hypermutation results by processing G.U mismatches generated when activation-induced cytidine deaminase (AID) deaminates C to U. Mutations at C/G sites are targeted mainly at deamination sites, whereas mutations at A/T sites entail error-prone DNA gap repair. We used B-cell lysates to analyze salient features of somatic hypermutation with in vitro mutational assays. Tonsil and hypermutating Ramos B-cells convert C-->U in accord with AID motif specificities, whereas HeLa cells do not. Using tonsil cell lysates to repair a G.U mismatch, A/T and G/C targeted mutations occur about equally, whereas Ramos cell lysates make fewer mutations at A/T sites (approximately 24%) compared with G/C sites (approximately 76%). In contrast, mutations in HeLa cell lysates occur almost exclusively at G/C sites (> 95%). By recapitulating two basic features of B-cell-specific somatic hypermutation, G/C mutations targeted to AID hot spot motifs and elevated A/T mutations dependent on error-prone processing of G.U mispairs, these cell free assays provide a practical method to reconstitute error-prone mismatch repair using purified B-cell proteins.