Lack of strand bias in UV-induced mutagenesis in Escherichia coli

We have investigated whether UV-induced mutations are created with equal efficiency on the leading and lagging strands of DNA replication. We employed an assay system that permits measurement of mutagenesis in the lacZ gene in pairs of near-identical strains. Within each pair, the strains differ only in the orientation of the lacZ gene with respect to the origin of DNA replication. Depending on this orientation, any lacZ target sequence will be replicated in one orientation as a leading strand and as a lagging strand in the other orientation. In contrast to previous results obtained for mutations resulting from spontaneous replication errors or mutations resulting from the spontaneous SOS mutator effect, measurements of UV-induced mutagenesis in uvrA strains fail to show significant differences between the two target orientations. These data suggest that SOS-mediated mutagenic translesion synthesis on the Escherichia coli chromosome may occur with equal or similar probability on leading and lagging strands.     

A new in vivo termination function for DNA polymerase I of Escherichia coli K12

Escherichia coli deleted for the tus gene are viable. Thus there must be at least one other mechanism for terminating chromosome synthesis. The tus deletion strain yielded a small fraction of cells that overproduce DNA, as determined by flow cytometry after run-out chromosome replication in the presence of rifampicin and cephalexin. A plasmid, paraBAD tus+, prevented the excess DNA replication only when arabinose was added to the medium to induce the synthesis of the Tus protein. Transduction studies were done to test whether or not additional chromosomal deletions could enhance the excess chromosome replication in the tus deletion strain. A strain containing a second deletion in metE udp overproduced DNA at a high level during run-out replication. Further studies demonstrated that a spontaneous unknown mutation had occurred during the transduction. This mutation was mapped and sequenced. It is polA(G544D). Transduction of polA(G544D) alone into the tus deletion strain produced the high DNA overproduction phenotype. The polA(G544D) and six other polA alleles were then tested in wild-type and in tus deletion backgrounds. The two alleles with low levels of 5'-->3' exonuclease (exo) overproduced DNA while those with either high or normal exo overproduce much less DNA in run-out assays in the wild-type background. In contrast, all seven mutant polA alleles caused the high DNA overproduction phenotype in a tus deletion background. To explain these results we propose a new in vivo function for wild-type DNA polymerase I in chromosome termination at site(s) not yet identified.     

Repair of cross-linked DNA and survival of Escherichia coli treated with psoralen and light: effects of mutations influencing genetic recombination and DNA metabolism.

Repair of cross-linked DNA was studied in Escherichia coli strains carrying mutations affecting DNA metabolism. In wild-type cells, DNA strands cut during cross-link removal were rejoined during a subsequent incubation into high-molecular-weight molecules. This rejoining was dependent on gene products involved in genetic recombination. A close correlation was found relating recombination proficiency, the rate of strand rejoining, and formation of viable progeny after DNA cross-linking by treatment with psoralen and light. Wild-type cells and other mutants which were Rec+ (sbcB, recL, recL sbcB, recB recC sbcA, recB recC sbcB, xthA1, and xthA11) rejoined cut DNA strands at a rate of 0.8 +/- 0.1 min -1 at 37 degrees C and survived 53 to 71 cross-links per chromosome. recB, recC, recB recC, recF, or polA strains showed reduced rates of strand rejoining and survived 4 to 13 cross-links per chromosome. Recombination-deficient strains (recA, recB recC sbcB recF, recB recL) and lexA failed to rejoin DNA strands after crosslink removal and were unable to form colonies after treatments producing as few as one to two cross-links per chromosome. Strand rejoining occurred normally in cells with mutations affecting DNA replication (dnaA, danB, dnaG, and dnaE) under both permissive and nonpermissive conditions for chromosome replication. In a polA polB dnaE strain strand rejoining occurred at 32 degree C but not at 42 degree C, indicating that some DNA synthesis was required for formation of intact recombinant molecules.     

Evidence for preferential mismatch repair of lagging strand DNA replication errors in yeast

Duplex DNA is replicated in the 5'-3' direction by coordinated copying of leading and lagging strand templates with somewhat different proteins and mechanics, providing the potential for differences in the fidelity of replication of the two strands. We previously showed that in Saccharomyces cerevisiae, active replication origins establish a strand bias in the rate of base substitutions resulting from replication of unrepaired 8-oxo-guanine (GO) in DNA. Lower mutagenesis was associated with replicating lagging strand templates. Here, we test the hypothesis that this bias is due to more efficient repair of lagging stand mismatches by measuring mutation rates in ogg1 strains with a reporter allele in two orientations at loci on opposite sides of a replication origin on chromosome III. We compare a MMR-proficient strain to strains deleted for the MMR genes MSH2, MSH6, MLH1, or EXOI. Loss of MMR reduces the strand bias by preferentially increasing mutagenesis for lagging strand replication. We conclude that GO-A mismatches generated during lagging strand replication are more efficiently repaired. This is consistent with the hypothesis that 5' ends of Okazaki fragments and PCNA, present at high density during lagging strand replication, are used as strand discrimination signals for mismatch repair in vivo.     

Replication strand preference for deletions associated with DNA palindromes

We have isolated and sequenced a set of deletions stimulated by DNA palindromes in Escherichia coli . All of the deletions are asymmetric with respect to the parental sequence and have occurred at short direct repeats. This is consistent with deletion by strand slippage during DNA replication. The orientation of the asymmetry in such deletion products is diagnostic of the direction of the strand slippage event. It is therefore also diagnostic of its occurrence on the leading or lagging strand of the replication fork when the direction of replication is known. In all cases in which the orientation of the asymmetry could be determined with respect to DNA replication, the products were consistent with a preference for deletion on the lagging strand of the fork. The data include replication slippage in three situations: on the chromosome of E . coli , in bacteriophage λ and in high-copy-number pUC-based plasmids.     

In vitro deletion mapping of the viral strand replication origin of Pseudomonas bacteriophage Pf3.

The origin of viral strand replication of the filamentous bacteriophage Pf3 has been characterized in Escherichia coli by in vitro deletion mapping techniques. The origin region was functionally identified by its ability to convey replicative properties to a recombinant plasmid in a polA host in which the replication origin of the vector plasmid is not functional. The origin of Pf3 viral strand replication is contained within a DNA sequence of 139 bp. This sequence covers almost completely one of the intergenic regions of the Pf3 genome, and it specifies both replication initiation and termination functions. Although no nucleotide sequence homology is present between the Pf3 origin of viral strand replication and that of the E. coli filamentous phages Ff (M13, f1, and fd) and IKe, their map positions and functional properties are very similar.     

Escherichia coli mutator (Delta)polA is defective in base mismatch correction: the nature of in vivo DNA replication errors

We constructed a set of Escherichia coli strains containing deletions in genes encoding three SOS polymerases, and defective in MutS and DNA polymerase I (PolI) mismatch repair, and estimated the rate and specificity of spontaneous endogenous tonB(+)-->tonB- mutations. The rate and specificity of mutations in strains proficient or deficient in three SOS polymerases was compared and found that there was no contribution of SOS polymerases to the chromosomal tonB mutations. MutS-deficient strains displayed elevated spontaneous mutation rates, consisting of dominantly minus frameshifts and transitions. Minus frameshifts are dominated by warm spots at run-bases. Among 57 transitions (both G:C-->A:T and A:T-->G:C), 35 occurred at two hotspot sites. PolI-deficient strains possessed an increased rate of deletions and frameshifts, because of a deficiency in postreplicative deletion and frameshift mismatch corrections. Frameshifts in PolI-deficient strains occurred within the entire tonB gene at non-run and run sequences. MutS and PolI double deficiency indicated a synergistic increase in the rate of deletions, frameshifts and transitions. In this case, mutS-specific hotspots for frameshifts and transitions disappeared. The results suggested that, unlike the case previously known pertaining to postreplicative MutS mismatch repair for frameshifts and transitions and PolI mismatch repair for frameshifts and deletions, PolI can recognize and correct transition mismatches. Possible mechanisms for distinct MutS and PolI mismatch repair are discussed. A strain containing deficiencies in three SOS polymerases, MutS mismatch repair and PolI mismatch repair was also constructed. The spectrum of spontaneous mutations in this strain is considered to represent the spectrum of in vivo DNA polymerase III replication errors. The mutation rate of this strain was 219x10(-8), about a 100-fold increase relative to the wild-type strain. Uncorrected polymerase III replication errors were predominantly frameshifts and base substitutions followed by deletions.     

Asymmetry of frameshift mutagenesis during leading and lagging-strand replication in Escherichia coli

Mutations in DNA, including frameshifts, may arise during DNA replication as a result of mistakes made by the DNA polymerase in copying the DNA template strands. In our efforts to better understand the factors that contribute to the accuracy of DNA replication, we have investigated whether frameshift mutations on the Escherichia coli chromosome occur differentially within the leading and lagging-strands of replication. The experimental system involves measurement of the reversion frequency for several defined lac frameshift alleles in pairs of strains in which the lac target is oriented in the two possible directions relative to the origin of chromosomal replication. Within these pairs any defined lac sequence will be subject to leading-strand replication in one orientation and to lagging-strand replication in the other. Fidelity differences between the two modes of replication can be observed as a differential lac reversion between the two strains. Our results, obtained with a series of lac alleles in a mismatch-repair-defective background, indicate that for at least some of the alleles there is indeed a difference in the fidelity of replication between the two modes of replication.     

Deletion analysis of the cloned replication origin region from bacteriophage M13.

A cloned 270-nucleotide fragment from the origin region of the M13 duplex replicative form DNA confers an M13-dependent replication mechanism upon the plasmid vector pBR322. This M13 insert permits M13 helper-dependent replication of the hybrid plasmid in polA cells which are unable to replicate the pBR322 replicon alone. Using in vitro techniques, we have constructed several plasmids containing deletions in the M13 DNa insert. The endpoints of these deletions have been determined by DNA sequence analysis and correlated with the transformation and replication properties of each plasmid. Characterization of these deletion plasmids allows the following conclusions. (i) The initiation site for M13 viral strand replication is required for helper-dependent propagation of the chimeric plasmid. (ii) A DNA sequence in the M13 insert, localized between 89 and 129 nucleotides from the viral strand initiation site, is necessary for efficient transformation of polA cells. A chimeric plasmid containing the viral strand initiation site, but lacking this additional 40 nucleotide M13 sequence, transforms helper-infected cells at a frequency approximately 10(4)-fold less than that of plasmids containing this additional DNA segment. (iii) The entire M13 complementary strand origin can be deleted without affecting M13-dependent transformation by the hybrid plasmids. We propose a model in which replication of one strand of duplex chimera initiates by nicking at the gene II protein nicking site in the viral strand of the M13 insert, followed by asymmetric single-strand synthesis. Initiation of the complementary strand possibly occurs within plasmid sequences.     

Influence of Chromosome Structure on the Frequency of tonB trp Deletions in Escherichia coli

The frequency of tonB trp deletions varies in different strains and substrains of Escherichia coli. Studies with chromosomal hybrids constructed by transducing various segments of the cysB-trp-suIII region from K-12(Ymel) into K-12(W3110) indicate that the characteristic low deletion frequency of K-12(Ymel) is determined largely by the (genetic) structure of the trp-suIII region of the chromosome. Transduction of the trp region from K-12(W3110) or K-12(Ymel) into strain B has little effect on the frequency of tonB trp deletions in that strain. When tonB trp deletions occur at 42 C rather than at 37 C, there is a significant reduction in the frequency of deletions in all strains examined except K-12(Ymel) and hybrids exhibiting a Ymel deletion pattern. The magnitude of this temperature effect in different K-12 strains increases proportionally with the frequency of tonB trp deletions at 37 C. At 42 C the frequency of tonB trp deletions in all K-12 strains approaches the low frequency observed for Ymel at 37 or 42 C. In contrast, spontaneous deletions in another region of the genome which simultaneously result in resistance to phages T7 and lambda and in proline auxotrophy (tfrA pro deletions) occur at a constant frequency regardless of growth temperature or the structure of the chromosome in the trp region. Two mutants of strain KB30 obtained after treatment with nitrosoguanidine show very low tonB trp deletion frequencies. The alterations in both mutants map in the trp region of the chromosome. These studies indicate that the structure of the cysB-trp-suIII region is responsible for many of the characteristic deletion frequencies observed.     

The fidelity of the human leading and lagging strand DNA replication apparatus with 8-oxodeoxyguanosine triphosphate.

A product of oxidative metabolism, 8-oxodeoxyguanosine triphosphate (8-O-dGTP), readily pairs with adenine during DNA replication, ultimately causing A.T-->C.G transversions. This study utilized 8-O-dGTP as a probe to examine the fidelity of the leading and lagging strand replication apparatus in extracts of HeLa cells. Simian virus (SV) 40 T antigen-dependent DNA replication reactions were performed with two M13mp2 vectors with the SV40 origin located on opposite sides of the lacZ alpha sequence used to score replication errors. The presence of 8-O-dGTP at equimolar concentration with each of the 4 normal dNTPs resulted in a > 46-fold increase in error rate for A.T-->C.G transversion over that observed in the absence of 8-O-dGTP. A similar average error rate was observed on the (+) and (-) strands in both vectors, suggesting that the fidelity of replication by leading and lagging strand replication proteins is similar for the dA.8-O-dGMP mispair. Replication fidelity in the presence of 8-O-dGTP was reduced on both strands when an inhibitor of exonucleolytic proofreading (dGMP) was added to the reaction. These data suggest that the majority of dA.8-O-dGMP mispairs are proofread by both leading and lagging strand replication proteins.     

DNA sequence analysis of spontaneous tonB deletion mutations in a polA1 strain of Escherichia coli K12.

By DNA sequence analysis, we have determined a spectrum of 61 spontaneous mutations occurring in the endogenous tonB gene in the polA1 strain of Escherichia coli. The overall mutation frequency was approximately 2.4-fold higher in the polA1 strain and this was attributable to enhanced rates of deletion and frameshift mutations. Among 39 deletions, a hot spot (17 mutations) was detected: a 13-bp deletion presumably directed by a 3-bp repeated sequence at its end points. The remaining 22 were distributed among 19 different mutations either flanked (16/19) or not flanked (3/19) by repeated sequences. Single-base frameshifts accounted for 8 mutations of either repeated (3/8) or nonrepeated (5/8) bases among which 6 were minus one frameshift. In contrast to previous reports, we did not frequently observe a 5'-GTGG-3' sequence in the vicinity of the deletions and frameshifts. The results presented here indicated an anti-deletion and anti-frameshift role for DNA polymerase I.     

Both heavy strand replication origins are active in partially duplicated human mitochondrial DNAs

The replication of human mitochondrial DNA (mtDNA) is initiated from a pair of displaced origins, one priming continuous synthesis of daughter-strand DNA from the heavy strand (OH) and the other priming continuous synthesis from the light strand (OL). In patients with sporadic large-scale rearrangements of mitochondrial DNA (i.e., partially-deleted [Delta-mtDNA] and partially-duplicated [dup-mtDNA] molecules), the dup-mtDNAs typically contain extra origins of replication, but it is unknown at present whether they are competent for initiation of replication. Using cybrids harboring each of two types of dup-mtDNAs-one containing two OHs and two OLs, and one containing two OHs and one OL-we used ligation-mediated polymerase chain reaction (LMPCR) to measure the presence and relative amounts of nascent heavy strands originating from each OH. We found that the nascent heavy strands originated almost equally from the two OHs in each cell line, indicating that the extra OH present on a partially duplicated mtDNA is competent for heavy strand synthesis. This extra OH could potentially confer a replicative advantage to dup-mtDNAs, as these molecules may have twice as many opportunities to initiate replication compared to wild-type (or partially deleted) molecules.     

Specific strand loss in N-2-acetylaminofluorene-modified DNA

N-2-Acetylaminofluorene (AAF), a well-known chemical carcinogen, when covalently linked to guanine residues constitutes a premutagenic lesion that is converted in vivo into frameshift mutations. In Escherichia coli, it is thought that -AAF adducts block the replication fork and that the mutagenic processing of the -AAF adducts is mediated by the SOS response. The construction in vitro of plasmids containing -AAF adducts in one strand only of a double-stranded DNA molecule enabled us to investigate the segregation of the strands and the mutagenicity of the lesions in vivo. The two DNA strands were "genetically labelled" by means of a single base-pair mismatch in the tetracycline-resistance gene, one strand carrying the wild-type allele and the other strand a mutant tetracycline-sensitive allele. The two strands contained either no -AAF adducts, -AAF adducts in one strand or -AAF adducts in both strands. When such constructions are used to transform bacterial cells the following are found. When no -AAF adducts are present on either strand of the DNA, a mixture of plasmids having information from both parent strands is found in 80% of the transformed bacterial clones. With -AAF adducts present in one strand only, in 90% of the transformants there is a consistent loss of the parent strand information that contained the -AAF adducts. In the constructions having -AAF adducts in both strands, the transformed bacteria carry either one or the other allele in a pure form. Our results suggest that when blocking lesions (-AAF adducts) are present in one strand only, they trigger the specific loss of that strand. The forward mutation frequency (i.e. the tetracycline-resistance gene inactivation frequency) was found to be more than ten times lower when the -AAF adducts are bound to one strand only compared with the situation where both strands carry the premutagenic lesions. Moreover, when the isolated mutants were sequenced, the mutations were found to consist of a mixture of true -AAF-induced mutations (i.e. -1 or -2 frameshift mutation at previously determined mutation hot spots) and of mutations that are not targeted at -AAF adducts. We suggest that these "background" mutants arose from the mutagenic processing of cryptic lesions present in our DNA. The low mutagenic efficiency of -AAF adducts, when present in one strand only of a duplex DNA, most probably results from the above-described loss of the damaged strand.(ABSTRACT TRUNCATED AT 400 WORDS)     

Different mechanisms inferred from sequences of human mitochondrial DNA deletions in ocular myopathies.

We have sequenced the deletion borders of the muscle mitochondrial DNA from 24 patients with heteroplasmic deletions. The length of these deletions varies from 2.310 bp to 8.476 bp and spans from position 5.786 to 15.925 of the human mitochondrial genome preserving the heavy chain and light chain origins of replication. 12 cases are common deletions identical to the mutation already described by other workers and characterized by 13 bp repeats at the deletion boundaries, one of these repeats being retained during the deletion process. The other cases (10 out of 12) have shown deletions which have not been previously described. All these deletions are located in the H strand DNA region which is potentially single stranded during mitochondrial DNA replication. In two cases, the retained Adenosine from repeat closed to the heavy strand origin of replication would indicate slippage mispairing. Furthermore in one patient two mt DNA molecules have been cloned and their sequences showed the difference of four nucleotides in the breakpoint of the deletion, possibly dued to slippage mispairing. Taken together our results suggest that deletions occur either by slippage mispairing or by internal recombination at the direct repeat level. They also suggest that different mechanisms account for the deletions since similarly located deletions may display different motives at the boundaries including the absence of any direct repeat.     

Chromosomal ARS1 has a single leading strand start site

Initiation sites for DNA synthesis in the chromosomal autonomously replicating sequence (ARS)1 of Saccharomyces cerevisiae were detected at the nucleotide level. The transition from discontinuous to continuous synthesis defines the origin of bidirectional replication (OBR), which mapped adjacent to the origin recognition complex binding site. To ascertain which sites represented starts for leading or lagging strands, we characterized DNA replication from ARS1 in a cdc9 (DNA ligase I) mutant, defective for joining Okazaki fragments. Leading strand synthesis in ARS1 initiated at only a single site, the OBR. Thus, replication in S. cerevisiae is not initiated stochastically by choosing one out of multiple possible sites but, rather, is a highly regulated process with one precise start point.     

Replication of the lagging strand: a concert of at least 23 polypeptides.

DNA replication is one of the most important events in living cells, and it is still a key problem how the DNA replication machinery works in its details. A replication fork has to be a very dynamic apparatus since frequent DNA polymerase switches from the initiating DNA polymerase alpha to the processive elongating DNA polymerase delta occur at the leading strand (about 8 x 10(4) fold on both strands in one replication round) as well as at the lagging strand (about 2 x 10(7) fold on both strands in one replication round) in mammalian cells. Lagging strand replication involves a very complex set of interacting proteins that are able to frequently initiate, elongate and process Okazaki fragments of 180 bp. Moreover, key proteins of this important process appear to be controlled by S-phase check-point proteins. It became furthermore clear in the last few years that DNA replication cannot be considered uncoupled from DNA repair, another very important event for any living organism. The reconstitution of nucleotide excision repair and base excision repair in vitro with purified components clearly showed that the DNA synthesis machinery of both of these macromolecular events are similar and do share many components of the lagging strand DNA synthesis machinery. In this minireview we summarize our current knowledge of the components involved in the execution and regulation of DNA replication at the lagging strand of the replication fork.     

Deletions in Plasmid Pbr322: Replication Slippage Involving Leading and Lagging Strands

We test here whether a class of deletions likely to result from errors during DNA replication arise preferentially during synthesis of either the leading or the lagging DNA strand. Deletions were obtained by reversion of particular insertion mutant alleles of the pBR322 amp gene. The alleles contain insertions of palindromic DNAs bracketed by 9-bp direct repeats of amp sequence; in addition, bp 2 to 5 in one arm of the palindrome form a direct repeat with 4 bp of adjoining amp sequence. Prior work had shown that reversion to Ampr results from deletions with endpoints in the 8- or 4-bp repeat, and that the 4-bp repeats are used preferentially because one of them is in the palindrome. To test the role of leading and lagging strand synthesis in deletion formation, we reversed the direction of replication of the amp gene by inverting the pBR322 replication origin, and also constructed new mutant alleles with a 4-bp repeat starting counterclockwise rather than clockwise of the insertion. In both cases the 4-bp repeats were used preferentially as deletion endpoints. A model is presented in which deletions arise during elongation of the strand that copies the palindrome before the adjoining 4-bp repeat, and in which preferential use of the 4-bp repeats independent of the overall direction of replication implies that deletions arise during syntheses of both leading and lagging strands.