A strong mutator effect caused by an amino acid change in the alpha subunit of DNA polymerase III of Escherichia coli

A Single Nucleotide Change in the polC DNA Polymerase III in Clostridium thermocellum Is Sufficient To Create a Hypermutator Phenotype

Clostridium thermocellum is a thermophilic, anaerobic bacterium that natively ferments cellulose to ethanol and is a candidate for cellulosic biofuel production. Recently, we identified a hypermutator strain of C. thermocellum with a C669Y mutation in the polC gene, which encodes a DNA polymerase III enzyme. Here, we reintroduced this mutation using recently developed CRISPR tools to demonstrate that this mutation is sufficient to recreate the hypermutator phenotype. The resulting strain shows an approximately 30-fold increase in the mutation rate. This mutation is hypothesized to function by interfering with metal ion coordination in the PHP (polymerase and histidinol phosphatase) domain, which is responsible for proofreading. The ability to selectively increase the mutation rate in C. thermocellum is a useful tool for future directed evolution experiments. IMPORTANCE Cellulosic biofuels are a promising approach to decarbonize the heavy-duty-transportation sector. A longstanding barrier to cost-effective cellulosic biofuel production is the recalcitrance of cellulose to solubilization. Native cellulose-consuming organisms, such as Clostridium thermocellum, are promising candidates for cellulosic biofuel production; however, they often need to be genetically modified to improve product formation. One approach is adaptive laboratory evolution. Our findings demonstrate a way to increase the mutation rate in this industrially relevant organism, which can reduce the time needed for adaptive evolution experiments.

Pyrophosphate release acts as a kinetic checkpoint during high-fidelity DNA replication by the Staphylococcus aureus replicative polymerase PolC

Bacterial replication is a fast and accurate process, with the bulk of genome duplication being catalyzed by the α subunit of DNA polymerase III within the bacterial replisome. Structural and biochemical studies have elucidated the overall properties of these polymerases, including how they interact with other components of the replisome, but have only begun to define the enzymatic mechanism of nucleotide incorporation. Using transient-state methods, we have determined the kinetic mechanism of accurate replication by PolC, the replicative polymerase from the Gram-positive pathogen Staphylococcus aureus. Remarkably, PolC can recognize the presence of the next correct nucleotide prior to completing the addition of the current nucleotide. By modulating the rate of pyrophosphate byproduct release, PolC can tune the speed of DNA synthesis in response to the concentration of the next incoming nucleotide. The kinetic mechanism described here would allow PolC to perform high fidelity replication in response to diverse cellular environments.

Coupling of the engineered DNA "mutator" to a biosensor as a new paradigm for activation of silent biosynthetic gene clusters in Streptomyces

DNA replication fidelity in Streptomyces bacteria, prolific producers of many medically important secondary metabolites, is understudied, while in Escherichia coli it is controlled by DnaQ, the ϵ subunit of DNA polymerase III (DNA PolIII). Manipulation of dnaQ paralogues in Streptomyces lividans TK24, did not lead to increased spontaneous mutagenesis in this bacterium suggesting that S. lividans DNA PolIII uses an alternative exonuclease activity for proofreading. In Mycobacterium tuberculosis, such activity is attributed to the DnaE protein representing α subunit of DNA PolIII. Eight DnaE mutants designed based on the literature data were overexpressed in S. lividans, and recombinant strains overexpressing two of these mutants displayed markedly increased frequency of spontaneous mutagenesis (up to 1000-fold higher compared to the control). One of these ‘mutators’ was combined in S. lividans with a biosensor specific for antibiotic coelimycin, which biosynthetic gene cluster is present but not expressed in this strain. Colonies giving a positive biosensor signal appeared at a frequency of ca 10^–5, and all of them were found to produce coelimycin congeners. This result confirmed that our approach can be applied for chemical- and radiation-free mutagenesis in Streptomyces leading to activation of orphan biosynthetic gene clusters and discovery of novel bioactive secondary metabolites.

Novel Escherichia coli active site dnaE alleles with altered base and sugar selectivity

The Escherichia coli dnaE gene encodes the α‐catalytic subunit (pol IIIα) of DNA polymerase III, the cell’s main replicase. Like all high‐fidelity DNA polymerases, pol III possesses stringent base and sugar discrimination. The latter is mediated by a so‐called “steric gate” residue in the active site of the polymerase that physically clashes with the 2′‐OH of an incoming ribonucleotide. Our structural modeling data suggest that H760 is the steric gate residue in E.coli pol IIIα. To understand how H760 and the adjacent S759 residue help maintain genome stability, we generated DNA fragments in which the codons for H760 or S759 were systematically changed to the other nineteen naturally occurring amino acids and attempted to clone them into a plasmid expressing pol III core (α‐θ‐ε subunits). Of the possible 38 mutants, only nine were successfully sub‐cloned: three with substitutions at H760 and 6 with substitutions at S759. Three of the plasmid‐encoded alleles, S759C, S759N, and S759T, exhibited mild to moderate mutator activity and were moved onto the chromosome for further characterization. These studies revealed altered phenotypes regarding deoxyribonucleotide base selectivity and ribonucleotide discrimination. We believe that these are the first dnaE mutants with such phenotypes to be reported in the literature.

Bacterial EndoMS/NucS acts as a clamp-mediated mismatch endonuclease to prevent asymmetric accumulation of replication errors

Mismatch repair (MMR) systems based on MutS eliminate mismatches originating from replication errors. Despite extensive conservation of mutS homologues throughout the three domains of life, Actinobacteria and some archaea do not have genes homologous to mutS. Here, we report that EndoMS/NucS of Corynebacterium glutamicum is the mismatch-specific endonuclease that functions cooperatively with a sliding clamp. EndoMS/NucS function in MMR was fully dependent on physical interaction between EndoMS/NucS and sliding clamp. A combination of endoMS/nucS gene disruption and a mutation in dnaE, which reduced the fidelity of DNA polymerase, increased the mutation rate synergistically and confirmed the participation of EndoMS in replication error correction. EndoMS specifically cleaved G/T, G/G and T/T mismatches in vitro, and such substrate specificity was consistent with the mutation spectrum observed in genome-wide analyses. The observed substrate specificity of EndoMS, together with the effects of endoMS gene disruption, led us to speculate that the MMR system, regardless of the types of proteins in the system, evolved to address asymmetrically occurring replication errors in which G/T mismatches occur much more frequently than C/A mismatches.

Collision with duplex DNA renders Escherichia coli DNA polymerase III holoenzyme susceptible to DNA polymerase IV-mediated polymerase switching on the sliding clamp

Organisms possess multiple DNA polymerases (Pols) and use each for a different purpose. One of the five Pols in Escherichia coli, DNA polymerase IV (Pol IV), encoded by the dinB gene, is known to participate in lesion bypass at certain DNA adducts. To understand how cells choose Pols when the replication fork encounters an obstacle on template DNA, the process of polymerase exchange from the primary replicative enzyme DNA polymerase III (Pol III) to Pol IV was studied in vitro. Replicating Pol III forming a tight holoenzyme (Pol III HE) with the sliding clamp was challenged by Pol IV on a primed ssDNA template carrying a short inverted repeat. A rapid and lesion-independent switch from Pol III to Pol IV occurred when Pol III HE encountered a hairpin stem duplex, implying that the loss of Pol III-ssDNA contact induces switching to Pol IV. Supporting this idea, mutant Pol III with an increased affinity for ssDNA was more resistant to Pol IV than wild-type Pol III was. We observed that an exchange between Pol III and Pol IV also occurred when Pol III HE collided with primer/template duplex. Our data suggest that Pol III-ssDNA interaction may modulate the susceptibility of Pol III HE to Pol IV-mediated polymerase exchange.

Interactions of the Bacillus subtilis DnaE polymerase with replisomal proteins modulate its activity and fidelity

During Bacillus subtilis replication two replicative polymerases function at the replisome to collectively carry out genome replication. In a reconstituted in vitro replication assay, PolC is the main polymerase while the lagging strand DnaE polymerase briefly extends RNA primers synthesized by the primase DnaG prior to handing-off DNA synthesis to PolC. Here, we show in vivo that (i) the polymerase activity of DnaE is essential for both the initiation and elongation stages of DNA replication, (ii) its error rate varies inversely with PolC concentration, and (iii) its misincorporations are corrected by the mismatch repair system post-replication. We also found that the error rates in cells encoding mutator forms of both PolC and DnaE are significantly higher (up to 15-fold) than in PolC mutants. In vitro, we showed that (i) the polymerase activity of DnaE is considerably stimulated by DnaN, SSB and PolC, (ii) its error-prone activity is strongly inhibited by DnaN, and (iii) its errors are proofread by the 3' > 5' exonuclease activity of PolC in a stable template-DnaE-PolC complex. Collectively our data show that protein-protein interactions within the replisome modulate the activity and fidelity of DnaE, and confirm the prominent role of DnaE during B. subtilis replication.

Template-switching during replication fork repair in bacteria

Replication forks frequently are challenged by lesions on the DNA template, replication-impeding DNA secondary structures, tightly bound proteins or nucleotide pool imbalance. Studies in bacteria have suggested that under these circumstances the fork may leave behind single-strand DNA gaps that are subsequently filled by homologous recombination, translesion DNA synthesis or template-switching repair synthesis. This review focuses on the template-switching pathways and how the mechanisms of these processes have been deduced from biochemical and genetic studies. I discuss how template-switching can contribute significantly to genetic instability, including mutational hotspots and frequent genetic rearrangements, and how template-switching may be elicited by replication fork damage.

Development of potent in vivo mutagenesis plasmids with broad mutational spectra

Methods to enhance random mutagenesis in cells offer advantages over in vitro mutagenesis, but current in vivo methods suffer from a lack of control, genomic instability, low efficiency and narrow mutational spectra. Using a mechanism-driven approach, we created a potent, inducible, broad-spectrum and vector-based mutagenesis system in E. coli that enhances mutation 322,000-fold over basal levels, surpassing the mutational efficiency and spectra of widely used in vivo and in vitro methods. We demonstrate that this system can be used to evolve antibiotic resistance in wild-type E. coli in <24 h, outperforming chemical mutagens, ultraviolet light and the mutator strain XL1-Red under similar conditions. This system also enables the continuous evolution of T7 RNA polymerase variants capable of initiating transcription using the T3 promoter in <10 h. Our findings enable broad-spectrum mutagenesis of chromosomes, episomes and viruses in vivo, and are applicable to both bacterial and bacteriophage-mediated laboratory evolution platforms.

Random DNA mutagenesis provides genetic diversity both in nature and the laboratory. Here, Badran and Liu present a potent, inducible, broad-spectrum and vector-based mutagenesis system in E. coli that surpasses the mutational efficiency and spectra of the most widely used in vivo and in vitro mutagenesis methods.

Evidence for moonlighting functions of the θ subunit of Escherichia coli DNA polymerase III

The holE gene is an enterobacterial ORFan gene (open reading frame [ORF] with no detectable homology to other ORFs in a database). It encodes the θ subunit of the DNA polymerase III core complex. The precise function of the θ subunit within this complex is not well established, and loss of holE does not result in a noticeable phenotype. Paralogs of holE are also present on many conjugative plasmids and on phage P1 (hot gene). In this study, we provide evidence indicating that θ (HolE) exhibits structural and functional similarities to a family of nucleoid-associated regulatory proteins, the Hha/YdgT-like proteins that are also encoded by enterobacterial ORFan genes. Microarray studies comparing the transcriptional profiles of Escherichia coli holE, hha, and ydgT mutants revealed highly similar expression patterns for strains harboring holE and ydgT alleles. Among the genes differentially regulated in both mutants were genes of the tryptophanase (tna) operon. The tna operon consists of a transcribed leader region, tnaL, and two structural genes, tnaA and tnaB. Further experiments with transcriptional lacZ fusions (tnaL::lacZ and tnaA::lacZ) indicate that HolE and YdgT downregulate expression of the tna operon by possibly increasing the level of Rho-dependent transcription termination at the tna operon's leader region. Thus, for the first time, a regulatory function can be attributed to HolE, in addition to its role as structural component of the DNA polymerase III complex.

A single-molecule approach to DNA replication in Escherichia coli cells demonstrated that DNA polymerase III is a major determinant of fork speed

The replisome catalyses DNA synthesis at a DNA replication fork. The molecular behaviour of the individual replisomes, and therefore the dynamics of replication fork movements, in growing Escherichia coli cells remains unknown. DNA combing enables a single-molecule approach to measuring the speed of replication fork progression in cells pulse-labelled with thymidine analogues. We constructed a new thymidine-requiring strain, eCOMB (E. coli for combing), that rapidly and sufficiently incorporates the analogues into newly synthesized DNA chains for the DNA-combing method. In combing experiments with eCOMB, we found the speed of most replication forks in the cells to be within the narrow range of 550-750 nt s(-1) and the average speed to be 653 ± 9 nt s(-1) (± SEM). We also found the average speed of the replication fork to be only 264 ± 9 nt s(-1) in a dnaE173-eCOMB strain producing a mutant-type of the replicative DNA polymerase III (Pol III) with a chain elongation rate (300 nt s(-1) ) much lower than that of the wild-type Pol III (900 nt s(-1) ). This indicates that the speed of chain elongation by Pol III is a major determinant of replication fork speed in E. coli cells.

DNA replicases from a bacterial perspective

Bacterial replicases are complex, tripartite replicative machines. They contain a polymerase, polymerase III (Pol III), a β₂ processivity factor, and a DnaX complex ATPase that loads β₂ onto DNA and chaperones Pol III onto the newly loaded β₂. Bacterial replicases are highly processive, yet cycle rapidly during Okazaki fragment synthesis in a regulated way. Many bacteria encode both a full-length τ and a shorter γ form of DnaX by a variety of mechanisms. γ appears to be uniquely placed in a single position relative to two τ protomers in a pentameric ring. The polymerase catalytic subunit of Pol III, α, contains a PHP domain that not only binds to a prototypical ε Mg²⁺-dependent exonuclease, but also contains a second Zn²⁺-dependent proofreading exonuclease, at least in some bacteria. This review focuses on a critical evaluation of recent literature and concepts pertaining to the above issues and suggests specific areas that require further investigation.

The dnaE173 mutator mutation confers on the alpha subunit of Escherichia coli DNA polymerase III a capacity for highly processive DNA synthesis and stable binding to primer/template DNA

The strong mutator mutation dnaE173 which causes an amino-acid substitution in the alpha subunit of DNA polymerase III is unique in its ability to induce sequence-substitution mutations. We showed previously that multiple biochemical properties of DNA polymerase III holoenzyme of Escherichia coli are simultaneously affected by the dnaE173 mutation. These effects include a severely reduced proofreading capacity, an increased resistance to replication-pausing on the template DNA, a capability to readily promote strand-displacement DNA synthesis, a reduced rate of DNA chain elongation, and an ability to catalyze highly processive DNA synthesis in the absence of the beta-clamp subunit. Here we show that, in contrast to distributive DNA synthesis exhibited by wild-type alpha subunit, the dnaE173 mutant form of alpha subunit catalyzes highly processive DNA chain elongation without the aid of the beta-clamp. More surprisingly, the dnaE173 alpha subunit appeared to form a stable complex with primer/template DNA, while no such affinity was detected with wild-type alpha subunit. We consider that the highly increased affinity of alpha subunit for primer/template DNA is the basis for the pleiotropic effects of the dnaE173 mutation on DNA polymerase III, and provides a clue to the molecular mechanisms underlying sequence substitution mutagenesis.

Roles of RecA protein in spontaneous mutagenesis in Escherichia coli

To verify the extent of contribution of spontaneous DNA lesions to spontaneous mutagenesis, we have developed a new genetic system to examine simultaneously both forward mutations and recombination events occurring within about 600 base pairs of a transgenic rpsL target sequence located on Escherichia coli chromosome. In a wild-type strain, the recombination events were occurring at a frequency comparable to that of point mutations within the rpsL sequence. When the cells were UV-irradiated, the recombination events were induced much more sharply than point mutations. In a recA null mutant, no recombination event was observed. These data suggest that the blockage of DNA replication, probably caused by spontaneous DNA lesions, occurs often in normally growing E. coli cells and is mainly processed by cellular functions requiring the RecA protein. However, the recA mutant strain showed elevated frequencies of single-base frameshifts and large deletions, implying a novel mutator action of this strain. A similar mutator action of the recA mutant was also observed with a plasmid-based rpsL mutation assay. Therefore, if the recombinogenic problems in DNA replication are not properly processed by the RecA function, these would be a potential source for mutagenesis leading to single-base frameshift and large deletion in E. coli. Furthermore, the single-base frameshifts induced in the recA-deficient cells appeared to be efficiently suppressed by the mutS-dependent mismatch repair system. Thus, it seems likely that the single-base frameshifts are derived from slippage errors that are not directly caused by DNA lesions but made indirectly during some kind of error-prone DNA synthesis in the recA mutant cells.

A quest to understand molecular mechanisms for genetic stability

In the midst of the post-war turmoil in Japan, I fortunately followed a path to become a scientist. Sometime at an early stage of my career, I encountered the problem of the cellular response to DNA damage and had the chance to discover a DNA repair enzyme. This event greatly influenced the subsequent course of my research, and I extended my studies toward elucidating the molecular mechanisms of mutagenesis as well as of carcinogenesis. Through these studies I came to understand the importance of mechanisms for dealing with the actions of reactive oxygen species to the living systems. These recollections deal with these endeavors with emphasis on the early part of my scientific career.

A role for replication repair in the genesis of templated mutations

Replication repair mediates error-free bypass of DNA damage in a series of steps that include regression of the replication fork, primer-terminus switching to use the other daughter strand as an undamaged template, primer extension, primer switching back to its cognate template with the primer terminus now having bypassed the damage, and fork rearrangement to a normal configuration. By both genetic and biochemical criteria, bacteriophage T4 catalyzes replication repair with two alternative sets of proteins, one including the gp32 SSB and the gp41 DNA helicase and the other including the UvsX recombinase. In each pathway, synthesis is conducted by the gp43 DNA polymerase. Here we show that defects in gp32, gp41 or UvsX that impair replication repair also increase mutation rates generally, but especially for templated mutations. Such templated mutations are associated with palindromic or direct repeats that are either perfect or imperfect. Models of templated mutagenesis require that the primer terminus switches to an ectopic template, but one that yields mutations instead of error-free bypass. We suggest that the proteins that conduct replication repair normally direct a blocked primer strand specifically to the other daughter strand with considerable accuracy, but that strand switching becomes promiscuous when these proteins are mutationally impaired, thus promoting templated mutations.

Dysfunctional proofreading in the Escherichia coli DNA polymerase III core

The epsilon-subunit contains the catalytic site for the 3'-->5' proofreading exonuclease that functions in the DNA pol III (DNA polymerase III) core to edit nucleotides misinserted by the alpha-subunit DNA pol. A novel mutagenesis strategy was used to identify 23 dnaQ alleles that exhibit a mutator phenotype in vivo. Fourteen of the epsilon mutants were purified, and these proteins exhibited 3'-->5' exonuclease activities that ranged from 32% to 155% of the activity exhibited by the wild-type epsilon protein, in contrast with the 2% activity exhibited by purified MutD5 protein. DNA pol III core enzymes constituted with 11 of the 14 epsilon mutants exhibited an increased error rate during in vitro DNA synthesis using a forward mutation assay. Interactions of the purified epsilon mutants with the alpha- and theta;-subunits were examined by gel filtration chromatography and exonuclease stimulation assays, and by measuring polymerase/exonuclease ratios to identify the catalytically active epsilon511 (I170T/V215A) mutant with dysfunctional proofreading in the DNA pol III core. The epsilon511 mutant associated tightly with the alpha-subunit, but the exonuclease activity of epsilon511 was not stimulated in the alpha-epsilon511 complex. Addition of the theta;-subunit to generate the alpha-epsilon511-theta; DNA pol III core partially restored stimulation of the epsilon511 exonuclease, indicating a role for the theta;-subunit in co-ordinating the alpha-epsilon polymerase-exonuclease interaction. The alpha-epsilon511-theta; DNA pol III core exhibited a 3.5-fold higher polymerase/exonuclease ratio relative to the wild-type DNA pol III core, further indicating dysfunctional proofreading in the alpha-epsilon511-theta; complex. Thus the epsilon511 mutant has wild-type 3'-->5' exonuclease activity and associates physically with the alpha- and theta;-subunits to generate a proofreading-defective DNA pol III enzyme.

The theta subunit of Escherichia coli DNA polymerase III: a role in stabilizing the epsilon proofreading subunit

The function of the theta subunit of Escherichia coli DNA polymerase III holoenzyme is not well established. theta is a tightly bound component of the DNA polymerase III core, which contains the alpha subunit (polymerase), the epsilon subunit (3'-->5' exonuclease), and the theta subunit, in the linear order alpha-epsilon-theta. Previous studies have shown that the theta subunit is not essential, as strains carrying a deletion of the holE gene (which encodes theta) proved fully viable. No significant phenotypic effects of the holE deletion could be detected, as the strain displayed normal cell health, morphology, and mutation rates. On the other hand, in vitro experiments have indicated the efficiency of the 3'-exonuclease activity of epsilon to be modestly enhanced by the presence of theta. Here, we report a series of genetic experiments that suggest that theta has a stabilizing role for the epsilon proofreading subunit. The observations include (i) defined DeltaholE mutator effects in mismatch-repair-defective mutL backgrounds, (ii) strong DeltaholE mutator effects in certain proofreading-impaired dnaQ strains, and (iii) yeast two- and three-hybrid experiments demonstrating enhancement of alpha-epsilon interactions by the presence of theta. theta appears conserved among gram-negative organisms which have an exonuclease subunit that exists as a separate protein (i.e., not part of the polymerase polypeptide), and the presence of theta might be uniquely beneficial in those instances where the proofreading 3'-exonuclease is not part of the polymerase polypeptide.

Specificity of spontaneous mutations induced in mutA mutator cells

Escherichia coli cells expressing the mutA allele of a glyV (glycine tRNA) gene express a strong mutator phenotype. The mutA allele differs from the wild type glyV gene by a base substitution in the anticodon such that the resulting tRNA misreads certain aspartate codons as glycine, resulting in random, low-level Asp-->Gly substitutions in proteins. Subsequent work showed that many types of mistranslation can lead to a very similar phenotype, named TSM for translational stress-induced mutagenesis. Here, we have determined the specificity of forward mutations occurring in the lacI gene in mutA cells as well as in wild type cells. Our results show that in comparison to wild type cells, base substitutions are elevated 23-fold in mutA cells, as against a eight-fold increase in insertions and a five-fold increase in deletions. Among base substitutions, transitions are elevated 13-fold, with both G:C-->A:T and A:T-->G:C mutations showing roughly similar increases. Transversions are elevated 35-fold, with G:C-->T:A, G:C-->C:G and A:T-->C:G elevated 28-, 13- and 27-fold, respectively. A:T-->T:A mutations increase a striking 348-fold over parental cells, with most occurring at two hotspot sequences that share the G:C-rich sequence 5'-CCGCGTGG. The increase in transversion mutations is similar to that observed in cells defective for dnaQ, the gene encoding the proofreading function of DNA polymerase III. In particular, the relative proportions and sites of occurrence of A:T-->T:A transversions are similar in mutA and mutD5 (an allele of dnaQ) cells. Interestingly, transversions are also the predominant base substitutions induced in dnaE173 cells in which a missense mutation in the alpha subunit of polymerase III abolishes proofreading without affecting the 3'-->5' exonuclease activity of the epsilon subunit.

Hyper-processive and slower DNA chain elongation catalysed by DNA polymerase III holoenzyme purified from the dnaE173 mutator mutant of Escherichia coli

BACKGROUND

A strong mutator mutation, dnaE173, leads to a Glu612 --> Lys amino acid change in the alpha subunit of Escherichia coli DNA polymerase III (PolIII) holoenzyme and abolishes the proofreading function of the replicative enzyme without affecting the 3' --> 5' exonuclease activity of the epsilon subunit. The dnaE173 mutator is unique in its ability to induce sequence-substitution mutations, suggesting that an unknown function of the alpha subunit is hampered by the dnaE173 mutation.

RESULTS

A PolIII holoenzyme reconstituted from dnaE173 PolIII* (DNA polymerase III holoenzyme lacking the beta clamp subunit) and the beta subunit showed a strong resistance to replication-pausing on the template DNA and readily promoted strand-displacement DNA synthesis. Unlike wild-type PolIII*, dnaE173 PolIII* was able to catalyse highly processive DNA synthesis without the aid of the beta-clamp subunit. The rate of chain elongation by the dnaE173 holoenzyme was reduced to one-third of that determined for the wild-type enzyme. In contrast, an exonuclease-deficient PolIII holoenzyme was vastly prone to pausing, but had the same rate of chain elongation as the wild-type.

CONCLUSIONS

The hyper-processivity and slower DNA chain elongation rate of the dnaE173 holoenzyme are distinct effects caused by the dnaE173 mutation and are likely to be involved in the sequence-substitution mutagenesis. A link between the proofreading and chain elongation processes was suggested.

Sequence analysis and phenotypes of five temperature sensitive mutator alleles of dnaE, encoding modified alpha-catalytic subunits of Escherichia coli DNA polymerase III holoenzyme

In the 1970s, several thermosensitive alleles of dnaE (encoding the alpha-catalytic subunit of pol III) were isolated. Genetic characterization of these dnaE mutants revealed that some are mutator alleles at permissive temperature. We have determined the nucleotide changes of five such temperature sensitive mutator alleles (dnaE9, dnaE74, dnaE486, dnaE511, and dnaE1026) and find that most are single missense mutations. The exception is dnaE1026 which is a compound allele consisting of multiple missense mutations. When the previously characterized mutator alleles were moved into a lexA51(Def) recA730 strain, dnaE486, dnaE1026 and dnaE74 conferred a modest approximately two-six-fold increase in spontaneous mutagenesis when grown at the permissive temperature of 28 degrees C, while dnaE9 and dnaE511 actually resulted in a slight decrease in spontaneous mutagenesis. In isogenic DeltaumuDC derivatives, the level of spontaneous mutagenesis dropped significantly, although in each case, the overall mutator effect conferred by the dnaE allele was relatively larger, with all five dnaE alleles conferring an increased spontaneous mutation rate approximately 5-22-fold over the isogenic dnaE+ DeltaumuDC strain. Interestingly, the temperature sensitivity conferred by each allele varied considerably in the lexA51(Def) recA730 background and in many cases, this phenotype was dependent upon the presence of functional pol V (UmuD'2C). Our data suggest that pol V can compete effectively with the impaired alpha-subunit for a 3' primer terminus and as a result, a large proportion of the phenotypic effects observed with strains carrying missense temperature sensitive mutations in dnaE can, in fact, be attributed to the actions of pol V rather than pol III.

Directionality of DNA replication fork movement strongly affects the generation of spontaneous mutations in Escherichia coli

Using a pair of plasmids carrying the rpsL target sequence in different orientations to the replication origin, we analyzed a large number of forward mutations generated in wild-type and mismatch-repair deficient (MMR(-)) Escherichia coli cells to assess the effects of directionality of replication-fork movement on spontaneous mutagenesis and the generation of replication error. All classes of the mutations found in wild-type cells but not MMR(-) cells were strongly affected by the directionality of replication fork movement. It also appeared that the directionality of replication-fork movement governs the directionality of sequence substitution mutagenesis, which occurred in wild-type cells at a frequency comparable to base substitutions and single-base frameshift mutations. A very strong orientation-dependent hot-spot site for single-base frameshift mutations was discovered and demonstrated to be caused by the same process involved in sequence substitution mutagenesis. It is surprising that dnaE173, a potent mutator mutation specific for sequence substitution as well as single-base frameshift, did not enhance the frequency of the hot-spot frameshift mutation. Furthermore, the frequency of the hot-spot frameshift mutation was unchanged in the MMR(-) strain, whereas the mutHLS-dependent mismatch repair system efficiently suppressed the generation of single-base frameshift mutations. These results suggested that the hot-spot frameshift mutagenesis might be initiated at a particular location containing a DNA lesion, and thereby produce a premutagenic replication intermediate resistant to MMR. Significant numbers of spontaneous single-base frameshift mutations are probably caused by similar mechanisms.

Role of the dinB gene product in spontaneous mutation in Escherichia coli with an impaired replicative polymerase

We isolated several new mutator mutations of the Escherichia coli replicative polymerase dnaE subunit alpha and used them and a previously reported dnaE mutation to study spontaneous frameshift and base substitution mutations. Two of these dnaE strains produce many more mutants when grown on rich (Luria-Bertani) than on minimal medium. A differential effect of the medium was not observed when these dnaE mutations were combined with a mismatch repair mutation. The selection scheme for the dnaE mutations required that they be able to complement a temperature-sensitive strain. However, the ability to complement is not related to the mutator effect for at least one of the mutants. Comparison of the mutation rates for frameshift and base substitution mutations in mutS and dnaE mutS strains suggests that the mismatch repair proteins respond differently to the two types of change. Deletion of dinB from both chromosome and plasmid resulted in a four- to fivefold decrease in the rate of frameshift and base substitution mutations in a dnaE mutS double mutant background. This reduction indicates that most mistakes in replication occur as a result of the action of the auxiliary rather than the replicative polymerase in this dnaE mutant. Deletion of dinB from strains carrying a wild-type dnaE had a measurable effect, suggesting that a fraction of spontaneous mutations occur as a result of dinB polymerase action even in cells with a normal replicative polymerase.

Identification of Escherichia coli dnaE (polC) mutants with altered sensitivity to 2',3'-dideoxyadenosine

Bacteria with reduced DNA polymerase I activity have increased sensitivity to killing by chain-terminating nucleotides (S. A. Rashbaum and N. R. Cozzarelli, Nature 264:679-680, 1976). We have used this observation as the basis of a genetic strategy to identify mutations in the dnaE (polC) gene of Escherichia coli that alter sensitivity to 2',3'-dideoxyadenosine (ddA). Two dnaE (polC) mutant strains with increased sensitivity to ddA and one strain with increased resistance were isolated and characterized. The mutant phenotypes are due to single amino acid substitutions in the alpha subunit, the protein product of the dnaE (polC) gene. Increased sensitivity to ddA is produced by the L329F and H417Y substitutions, and increased resistance is produced by the G365S substitution. The L329F and H417Y substitutions also reduce the accuracy of DNA replication (the mutator phenotype), while the G365S substitution increases accuracy (the antimutator phenotype). All of the amino acid substitutions are in conserved regions near essential aspartate residues. These results prove the effectiveness of the genetic strategy in identifying informative dnaE (polC) mutations that can be used to elucidate the molecular basis of nucleotide interactions in the alpha subunit of the DNA polymerase III holoenzyme.

Strand asymmetry of +1 frameshift mutagenesis at a homopolymeric run by DNA polymerase III holoenzyme of Escherichia coli

We have recently shown that single-base frameshifts were predominant among mutations induced within the rpsL target sequence upon oriC plasmid DNA replication in vitro. We found that the occurrence of +1 frameshifts at a run of 6 residues of dA/dT could be increased proportionally by increasing the concentration of dATP present in the in vitro replication. Using single-stranded circular DNA containing either the coding sequence of the rpsL gene or its complementary sequence, the +1 frameshift mutagenesis by DNA polymerase III holoenzyme of Escherichia coli was extensively examined. A(6) --> A(7) frameshifts occurred 30 to 90 times more frequently during DNA synthesis with the noncoding sequence (dT tract) template than with the coding sequence (dA tract). Excess dATP enhanced the occurrence of +1 frameshifts during DNA synthesis with the dT tract template, but no other dNTPs showed such an effect. In the presence of 0.1 mM dATP, the A(6) --> A(7) mutagenesis with the dT tract template was not inhibited by 1.5 mM dCTP, which is complementary to the residue immediately upstream of the dT tract. These results strongly suggested that the A(6) --> A(7) frameshift mutagenesis possesses an asymmetric strand nature and that slippage errors leading to the +1 frameshift are made during chain elongation within the tract rather than by misincorporation of nucleotides opposite residues next to the tract.

Frameshift mutation, microsatellites and mismatch repair

The structure of eukaryotic DNA, with its repeated sequences, makes base addition and loss a major obstacle to the maintenance of genetic stability. As compared to the bacteria, much of the mismatch repair capacity of the eukaryotic cell must be devoted to the surveillance of frameshift changes. Any alteration in the activity of proteins which recognize frameshifts or which hold the DNA in place during replication is likely to result in genomic instability.

DNA replication errors produced by the replicative apparatus of Escherichia coli

It has been hard to detect forward mutations generated during DNA synthesis in vitro by replicative DNA polymerases, because of their extremely high fidelity and a high background level of pre-existing mutations in the single-stranded template DNA used. Using the oriC plasmid DNA replication in vitro system and the rpsL forward mutation assay, we examined the fidelity of DNA replication catalyzed by the replicative apparatus of Escherichia coli. Upon DNA synthesis by the fully reconstituted system, the frequency of rpsL-mutations in the product DNA was increased to 1.9x10(-4), 50-fold higher than the background level of the template DNA. Among the mutations generated in vitro, single-base frameshifts predominated and occurred with a pattern similar to those induced in mismatch-repair deficient E. coli cells, indicating that the major replication error was slippage at runs of the same nucleotide. Large deletions and other structural alterations of DNA appeared to be induced also during the action of the replicative apparatus.

Genetic factors affecting the impact of DNA polymerase delta proofreading activity on mutation avoidance in yeast

Base selectivity, proofreading, and postreplication mismatch repair are important for replication fidelity. Because proofreading plays an important role in error correction, we have investigated factors that influence its impact in the yeast Saccharomyces cerevisiae. We have utilized a sensitive mutation detection system based on homonucleotide runs of 4 to 14 bases to examine the impact of DNA polymerase delta proofreading on mutation avoidance. The contribution of DNA polymerase delta proofreading on error avoidance was found to be similar to that of DNA polymerase epsilon proofreading in short homonucleotide runs (A4 and A5) but much greater than the contribution of DNA polymerase epsilon proofreading in longer runs. We have identified an intraprotein interaction affecting mutation prevention that results from mutations in the replication and the proofreading regions, resulting in an antimutator phenotype relative to a proofreading defect. Finally, a diploid strain with a defect in DNA polymerase delta proofreading exhibits a higher mutation rate than a haploid strain. We suggest that in the diploid population of proofreading defective cells there exists a transiently hypermutable fraction that would be inviable if cells were haploids.

Fidelity and error specificity of the alpha catalytic subunit of Escherichia coli DNA polymerase III

Escherichia coli DNA polymerase III holoenzyme is the replicative enzyme primarily responsible for the duplication of the E. coli chromosome. This process occurs with high accuracy, less than 10(-9) to 10(-10) errors being committed per base pair per round of replication. As a first step in understanding the mechanisms responsible for the high fidelity of this process, we have purified the polymerase III alpha catalytic subunit, free of exonuclease activity, and analyzed its fidelity in vitro. We employed a newly developed gap-filling assay using the N-terminal 250 bases of the lacI gene as a forward mutational target. When synthesizing across this target, alpha subunit produced mutations at a frequency of 0.6%. DNA sequencing revealed that the mutants created in vitro consisted mostly of frameshift mutations, although some base substitutions were also observed. The frameshifts, occurring at more than 120-fold above the background, consisted largely of -1 deletions. Among them, about 80% were the deletion of a purine template base with a pyrimidine 5'-neighbor. These results suggest that the alpha subunit (i) has a relatively low ability to extend from misincorporated bases, accounting for the low level of observed base substitutions, and (ii) has a relatively high capability of extension after misalignment of a misincorporated base on the next (complementary) template base, accounting for the high level of frameshift mutations. This model is supported by an experiment in which alpha subunit was required to initiate DNA synthesis from a terminal mispair in a sequence context that allowed slippage on the next template base. Among the products of this reaction, frameshifts outnumbered base pair substitutions by greater than 70-fold. A comparison to in vivo mutational spectra suggests that the pol III accessory factors may play a major role in modulating the fidelity of DNA synthesis.

Isolation and characterization of ten mutator alleles of the mitochondrial DNA polymerase-encoding MIP1 gene from Saccharomyces cerevisiae

Ten mutator alleles of MIP1, the gene encoding mitochondrial (mt) DNA polymerase, have been isolated after in vitro random mutagenesis. Five mutations causing a 100-400-fold increase in the frequency of erythromycin-resistant (ErR) mt mutants in yeast mapped to the 3'-5' exonuclease (Exo) domain, and mainly to the three conserved motifs Exo1, Exo2 and Exo3 of this domain, highlighting the importance of proofreading in accurate mt DNA replication. The essential role of the invariant glutamate at the Exo1 site was confirmed and the participation of four amino acids (aa) in the 3'-5' Exo function revealed. Another mutation that is located between the Exo1 and Exo2 sites produced an extremely strong mutator phenotype associated with impaired DNA replication, but could be assigned neither to a conserved aa nor to a conserved portion of the 3'-5' exonuclease domain. The importance of the polymerization domain in accurate mt DNA replication was pointed out by three mutator mutations. Two of these severely impaired mt DNA replication and were assigned to a subdomain of the polymerase which probably corresponds to the 'fingers' module of the Klenow (large) fragment of Escherichia coli DNA polymerase I (PolIk). The third, which did not alter the efficiency of DNA replication, was located at the active center of the polymerization reaction. Finally, the mutation, R1001I, mapped to the C-terminal part of the MIP1 protein which has no counterpart in prokaryotic DNA polymerases.

Use of genetic analyses to probe structure, function, and dynamics of bacteriophage T4 DNA polymerase

Functionally distinct mutant DNA polymerases have been isolated by the genetic selection strategies described here. These methods can be supplemented by the use of targeted mutagenesis procedures to enhance mutagenesis of DNA polymerase genes and to direct mutagenesis to specific sites in cloned DNA polymerases (see [22-24, 28], this volume). The power of genetic selection is in the ability to identify amino acid residues that are critical for protein structure and function that may not be obvious from studies of structural data alone. For the study of DNA polymerases, it is essential to identify residues involved in the movement of the DNA polymerase along the DNA template and in shuttling the DNA between the polymerase and exonuclease active centers. Ongoing studies are directed toward these goals.

Replication of damaged DNA and the molecular mechanism of ultraviolet light mutagenesis

On UV irradiation of Escherichia coli cells, DNA replication is transiently arrested to allow removal of DNA damage by DNA repair mechanisms. This is followed by a resumption of DNA replication, a major recovery function whose mechanism is poorly understood. During the post-UV irradiation period the SOS stress response is induced, giving rise to a multiplicity of phenomena, including UV mutagenesis. The prevailing model is that UV mutagenesis occurs by the filling in of single-stranded DNA gaps present opposite UV lesions in the irradiated chromosome. These gaps can be formed by the activity of DNA replication or repair on the damaged DNA. The gap filling involves polymerization through UV lesions (also termed bypass synthesis or error-prone repair) by DNA polymerase III. The primary source of mutations is the incorporation of incorrect nucleotides opposite lesions. UV mutagenesis is a genetically regulated process, and it requires the SOS-inducible proteins RecA, UmuD, and UmuC. It may represent a minor repair pathway or a genetic program to accelerate evolution of cells under environmental stress conditions.

An Escherichia coli dnaE mutation with suppressor activity toward mutator mutD5

The Escherichia coli mutator mutD5 is a conditional mutator whose strength is moderate when the strain is growing in minimal medium but very strong when it is growing in rich medium. The primary defect of this strain resides in the dnaQ gene, which encodes the epsilon (exonucleolytic proofreading) subunit of the DNA polymerase III holoenzyme. In one of our mutD5 strains we discovered a mutation that suppressed the mutability of mutD5. Interestingly, the level of suppression was strong in minimal medium but weak in rich medium. The mutation was localized to the dnaE gene, which encodes the alpha (polymerase) subunit of the DNA polymerase III holoenzyme. This mutation, termed dnaE910, also conferred improved growth of the mutD5 strain and caused increased temperature sensitivity in both wild-type and dnaQ49 backgrounds. The reduction in mutator strength by dnaE910 was also observed when this allele was placed in a mutL, a mutT, or a dnaQ49 background. The results suggest that dnaE910 encodes an antimutator DNA polymerase whose effect might be mediated by improved insertion fidelity or by increased proofreading via its effect on the exonuclease activity.

Mutational specificity of the dnaE173 mutator associated with a defect in the catalytic subunit of DNA polymerase III of Escherichia coli

We developed a system to examine forward mutations that occurred in the rpsL gene of Escherichia coli placed on a multicopy plasmid. Using this system we determined the mutational specificity for a dnaE173 mutator strain in which the editing function of DNA polymerase III is impeded. The frequency of rpsL- mutations increased 32,000-fold, due to the dnaE173 mutator, and 87 independent rpsL- mutations in the mutator strain were analyzed by DNA sequencing, together with 100 mutants recovered from dnaE+ strain, as the control. While half the number of mutations that occurred in the wild-type strain were caused by insertion elements, no such mutations were recovered from the mutator strain. A novel class of mutation, named "sequence substitution" was present in mutants raised in the dnaE173 strain; seven sequence substitutions induced in the mutator strain occurred at six sites, and all were located in quasipalindromic sequences, carrying the GTG or CAC sequence at one or both endpoints. While other types of mutation were found in both strains, single-base frameshifts were the most frequent events in the mutator strain. Thus, the mutator effect on this class of mutation was 175,000-fold. A total of 95% of the single-base frameshifts in the mutator strain were additions, most of which occurred at runs of A or C bases so as to increase the number of identical residues. Base substitutions, the frequency of which was enhanced 25,000-fold by the mutator effect, occurred primarily at several hotspots in the mutator strain, whereas those induced in the wild-type strain were more randomly distributed throughout the rpsL sequence. The dnaE173 mutator also increased the frequency of duplications 28,000-fold. Of the three duplications recovered from the mutator strain, one was a simple duplication, the region of which was flanked by direct repeats. The other duplications were complex, one half part of which was in the inverted orientation of a region containing two sets of inverted repeats. The same duplications were also recovered from the wild-type strain. The present data suggest that dnaE173 is a novel class of mutator that sharply induces sequence-directed mutagenesis, yielding high frequencies of single base frameshifts, duplications with inversions, sequence substitutions and base substitutions at hotspots.