Processive DNA synthesis by DNA polymerase II mediated by DNA polymerase III accessory proteins

The diverse spectrum of sliding clamp interacting proteins

DNA polymerase sliding clamps are a family of ring-shaped proteins that play essential roles in DNA metabolism. The proteins from the three domains of life, Bacteria, Archaea and Eukarya, as well as those from bacteriophages and viruses, were shown to interact with a large number of cellular factors and to influence their activity. In the last several years a large number of such proteins have been identified and studied. Here the various proteins that have been shown to interact with the sliding clamps of Bacteria, Archaea and Eukarya are summarized.

Ordered ATP hydrolysis in the gamma complex clamp loader AAA+ machine

The gamma complex couples ATP hydrolysis to the loading of beta sliding clamps onto DNA for processive replication. The gamma complex structure shows that the clamp loader subunits are arranged as a circular heteropentamer. The three gamma motor subunits bind ATP, the delta wrench opens the beta ring, and the delta' stator modulates the delta-beta interaction. Neither delta nor delta' bind ATP. This report demonstrates that the delta' stator contributes a catalytic arginine for hydrolysis of ATP bound to the adjacent gamma(1) subunit. Thus, the delta' stator contributes to the motor function of the gamma trimer. Mutation of arginine 169 of gamma, which removes the catalytic arginines from only the gamma(2) and gamma(3) ATP sites, abolishes ATPase activity even though ATP site 1 is intact and all three sites are filled. This result implies that hydrolysis of the three ATP molecules occurs in a particular order, the reverse of ATP binding, where ATP in site 1 is not hydrolyzed until ATP in sites 2 and/or 3 is hydrolyzed. Implications of these results to clamp loaders of other systems are discussed.

Error-prone repair DNA polymerases in prokaryotes and eukaryotes

DNA repair is crucial to the well-being of all organisms from unicellular life forms to humans. A rich tapestry of mechanistic studies on DNA repair has emerged thanks to the recent discovery of Y-family DNA polymerases. Many Y-family members carry out aberrant DNA synthesis-poor replication accuracy, the favored formation of non-Watson-Crick base pairs, efficient mismatch extension, and most importantly, an ability to replicate through DNA damage. This review is devoted primarily to a discussion of Y-family polymerase members that exhibit error-prone behavior. Roles for these remarkable enzymes occur in widely disparate DNA repair pathways, such as UV-induced mutagenesis, adaptive mutation, avoidance of skin cancer, and induction of somatic cell hypermutation of immunoglobulin genes. Individual polymerases engaged in multiple repair pathways pose challenging questions about their roles in targeting and trafficking. Macromolecular assemblies of replication-repair "factories" could enable a cell to handle the complex logistics governing the rapid migration and exchange of polymerases.

Comparative mutagenesis of the C8-guanine adducts of 1-nitropyrene and 1,6- and 1,8-dinitropyrene in a CpG repeat sequence. A slipped frameshift intermediate model for dinucleotide deletion

In the Ames Salmonella typhimurium reversion assay 1,6- and 1,8-dinitropyrenes (1,6- and 1,8-DNPs) are much more potent mutagens than 1-nitropyrene (1-NP). Genetic experiments established that certain differences in the metabolism of the DNPs, which in turn result in increased DNA adduction, play a role. It remained unclear, however, if the DNP adducts, N-(guanin-8-yl)-1-amino-6 ()-nitropyrene (Gua-C8-1,6-ANP and Gua-C8-1,8-ANP), which contain a nitro group on the pyrene ring covalently linked to the guanine C8, are more mutagenic than the major 1-NP adduct, N-(guanin-8-yl)-1-aminopyrene (Gua-C8-AP). In order to address this, we have compared the mutation frequency of the three guanine C8 adducts, Gua-C8-AP, Gua-C8-1,6-ANP, and Gua-C8-1,8-ANP in a CGCG*CG sequence. Single-stranded M13mp7L2 vectors containing these adducts and a control were constructed and replicated in Escherichia coli. A remarkable difference in the induced CpG deletion frequency between these adducts was noted. In repair-competent cells the 1-NP adduct induced 1.7% CpG deletions without SOS, whereas the 1,6- and 1,8-DNP adducts induced 6.8 and 10.0% two-base deletions, respectively. With SOS, CpG deletions increased up to 1.9, 11.1, and 15.1% by 1-NP, 1,6-, and 1,8-DNP adducts, respectively. This result unequivocally established that DNP adducts are more mutagenic than the 1-NP adduct in the repetitive CpG sequence. In each case the mutation frequency was significantly increased in a mutS strain, which is impaired in methyl-directed mismatch repair, and a dnaQ strain, which carries a defect in proofreading activity of the DNA polymerase III. Modeling studies showed that the nitro group on the pyrene ring at the 8-position can provide additional stabilization to the two-nucleotide extrahelical loop in the promutagenic slipped frameshift intermediate through its added hydrogen-bonding capability. This could account for the increase in CpG deletions in the M13 vector with the nitro-containing adducts compared with the Gua-C8-AP adduct itself.

SOS-induced DNA polymerases enhance long-term survival and evolutionary fitness

Escherichia coli encodes three SOS-induced DNA polymerases: pol II, pol IV, and pol V. We show here that each of these polymerases confers a competitive fitness advantage during the stationary phase of the bacterial life cycle, in the absence of external DNA-damaging agents known to induce the SOS response. When grown individually, wild-type and SOS pol mutants exhibit indistinguishable temporal growth and death patterns. In contrast, when grown in competition with wild-type E. coli, mutants lacking one or more SOS polymerase suffer a severe reduction in fitness. These mutants also fail to express the "growth advantage in stationary phase" phenotype as do wild-type strains, instead expressing two additional new types of "growth advantage in stationary phase" phenotype. These polymerases contribute to survival by providing essential functions to ensure replication of the chromosome and by generating genetic diversity.

Resolving a fidelity paradox: why Escherichia coli DNA polymerase II makes more base substitution errors in AT- compared with GC-rich DNA

The activity of DNA polymerase-associated proofreading 3'-exonucleases is generally enhanced in less stable DNA regions leading to a reduction in base substitution error frequencies in AT- versus GC-rich sequences. Unexpectedly, however, the opposite result was found for Escherichia coli DNA polymerase II (pol II). Nucleotide misincorporation frequencies for pol II were found to be 3-5-fold higher in AT- compared with GC-rich DNA, both in the presence and absence of polymerase processivity subunits, beta dimer and gamma complex. In contrast, E. coli pol III holoenzyme, behaving "as expected," exhibited 3-5-fold lower misincorporation frequencies in AT-rich DNA. A reduction in fidelity in AT-rich regions occurred for pol II despite having an associated 3'-exonuclease proofreading activity that preferentially degrades AT-rich compared with GC-rich DNA primer-template in the absence of DNA synthesis. Concomitant with a reduction in fidelity, pol II polymerization efficiencies were 2-6-fold higher in AT-rich DNA, depending on sequence context. Pol II paradoxical fidelity behavior can be accounted for by the enzyme's preference for forward polymerization in AT-rich sequences. The more efficient polymerization suppresses proofreading thereby causing a significant increase in base substitution error rates in AT-rich regions.

Replication restart in UV-irradiated Escherichia coli involving pols II, III, V, PriA, RecA and RecFOR proteins

In Escherichia coli, UV-irradiated cells resume DNA synthesis after a transient inhibition by a process called replication restart. To elucidate the role of several key proteins involved in this process, we have analysed the time dependence of replication restart in strains carrying a combination of mutations in lexA, recA, polB (pol II), umuDC (pol V), priA, dnaC, recF, recO or recR. We find that both pol II and the origin-independent primosome-assembling function of PriA are essential for the immediate recovery of DNA synthesis after UV irradiation. In their absence, translesion replication or 'replication readthrough' occurs approximately 50 min after UV and is pol V-dependent. In a wild-type, lexA+ background, mutations in recF, recO or recR block both pathways. Similar results were obtained with a lexA(Def) recF strain. However, lexA(Def) recO or lexA(Def) recR strains, although unable to facilitate PriA-pol II-dependent restart, were able to perform pol V-dependent readthrough. The defects in restart attributed to mutations in recF, recO or recR were suppressed in a recA730 lexA(Def) strain expressing constitutively activated RecA (RecA*). Our data suggest that in a wild-type background, RecF, O and R are important for the induction of the SOS response and the formation of RecA*-dependent recombination intermediates necessary for PriA/Pol II-dependent replication restart. In con-trast, only RecF is required for the activation of RecA that leads to the formation of pol V (UmuD'2C) and facilitates replication readthrough.

The processivity factor beta controls DNA polymerase IV traffic during spontaneous mutagenesis and translesion synthesis in vivo

The dinB-encoded DNA polymerase IV (Pol IV) belongs to the recently identified Y-family of DNA polymerases. Like other members of this family, Pol IV is involved in translesion synthesis and mutagenesis. Here, we show that the C-terminal five amino acids of Pol IV are essential in targeting it to the beta-clamp, the processivity factor of the replicative DNA polymerase (Pol III) of Escherichia coli. In vivo, the disruption of this interaction obliterates the function of Pol IV in both spontaneous and induced mutagenesis. These results point to the pivotal role of the processivity clamp during DNA polymerase trafficking in the vicinity of damaged-template DNA.

Interplay of clamp loader subunits in opening the beta sliding clamp of Escherichia coli DNA polymerase III holoenzyme

The Escherichia coli beta dimer is a ring-shaped protein that encircles DNA and acts as a sliding clamp to tether the replicase, DNA polymerase III holoenzyme, to DNA. The gamma complex (gammadeltadelta'chipsi) clamp loader couples ATP to the opening and closing of beta in assembly of the ring onto DNA. These proteins are functionally and structurally conserved in all cells. The eukaryotic equivalents are the replication factor C (RFC) clamp loader and the proliferating cell nuclear antigen (PCNA) clamp. The delta subunit of the E. coli gamma complex clamp loader is known to bind beta and open it by parting one of the dimer interfaces. This study demonstrates that other subunits of gamma complex also bind beta, although weaker than delta. The gamma subunit like delta, affects the opening of beta, but with a lower efficiency than delta. The delta' subunit regulates both gamma and delta ring opening activities in a fashion that is modulated by ATP interaction with gamma. The implications of these actions for the workings of the E. coli clamp loading machinery and for eukaryotic RFC and PCNA are discussed.

A universal protein-protein interaction motif in the eubacterial DNA replication and repair systems

The interaction between DNA polymerases and sliding clamp proteins confers processivity in DNA synthesis. This interaction is critical for most DNA replication machines from viruses and prokaryotes to higher eukaryotes. The clamp proteins also participate in a variety of dynamic and competing protein-protein interactions. However, clamp-protein binding sequences have not so far been identified in the eubacteria. Here we show from three lines of evidence, bioinformatics, yeast two-hybrid analysis, and inhibition of protein-protein interaction by modified peptides, that variants of a pentapeptide motif (consensus QL[SD]LF) are sufficient to enable interaction of a number of proteins with an archetypal eubacterial sliding clamp (the beta subunit of Escherichia coli DNA polymerase III holoenzyme). Representatives of this motif are present in most sequenced members of the eubacterial DnaE, PolC, PolB, DinB, and UmuC families of DNA polymerases and the MutS1 mismatch repair protein family. The component tripeptide DLF inhibits the binding of the alpha (DnaE) subunit of E. coli DNA polymerase III to beta at microM concentration, identifying key residues. Comparison of the eubacterial, eukaryotic, and archaeal sliding clamp binding motifs suggests that the basic interactions have been conserved across the evolutionary landscape.

Mechanism of DNA polymerase II-mediated frameshift mutagenesis

Escherichia coli possesses three SOS-inducible DNA polymerases (Pol II, IV, and V) that were recently found to participate in translesion synthesis and mutagenesis. Involvement of these polymerases appears to depend on the nature of the lesion and its local sequence context, as illustrated by the bypass of a single N-2-acetylaminofluorene adduct within the NarI mutation hot spot. Indeed, error-free bypass requires Pol V (umuDC), whereas mutagenic (-2 frameshift) bypass depends on Pol II (polB). In this paper, we show that purified DNA Pol II is able in vitro to generate the -2 frameshift bypass product observed in vivo at the NarI sites. Although the Delta polB strain is completely defective in this mutation pathway, introduction of the polB gene on a low copy number plasmid restores the -2 frameshift pathway. In fact, modification of the relative copy number of polB versus umuDC genes results in a corresponding modification in the use of the frameshift versus error-free translesion pathways, suggesting a direct competition between Pol II and V for the bypass of the same lesion. Whether such a polymerase competition model for translesion synthesis will prove to be generally applicable remains to be confirmed.

Interaction of the beta sliding clamp with MutS, ligase, and DNA polymerase I

The beta and proliferating cell nuclear antigen (PCNA) sliding clamps were first identified as components of their respective replicases, and thus were assigned a role in chromosome replication. Further studies have shown that the eukaryotic clamp, PCNA, interacts with several other proteins that are involved in excision repair, mismatch repair, cellular regulation, and DNA processing, indicating a much wider role than replication alone. Indeed, the Escherichia coli beta clamp is known to function with DNA polymerases II and V, indicating that beta also interacts with more than just the chromosomal replicase, DNA polymerase III. This report demonstrates three previously undetected protein-protein interactions with the beta clamp. Thus, beta interacts with MutS, DNA ligase, and DNA polymerase I. Given the diverse use of these proteins in repair and other DNA transactions, this expanded list of beta interactive proteins suggests that the prokaryotic beta ring participates in a wide variety of reactions beyond its role in chromosomal replication.

Genetic interactions between the Escherichia coli umuDC gene products and the beta processivity clamp of the replicative DNA polymerase

The Escherichia coli umuDC gene products encode DNA polymerase V, which participates in both translesion DNA synthesis (TLS) and a DNA damage checkpoint control. These two temporally distinct roles of the umuDC gene products are regulated by RecA-single-stranded DNA-facilitated self-cleavage of UmuD (which participates in the checkpoint control) to yield UmuD' (which enables TLS). In addition, even modest overexpression of the umuDC gene products leads to a cold-sensitive growth phenotype, apparently due to the inappropriate expression of the DNA damage checkpoint control activity of UmuD(2)C. We have previously reported that overexpression of the epsilon proofreading subunit of DNA polymerase III suppresses umuDC-mediated cold sensitivity, suggesting that interaction of epsilon with UmuD(2)C is important for the DNA damage checkpoint control function of the umuDC gene products. Here, we report that overexpression of the beta processivity clamp of the E. coli replicative DNA polymerase (encoded by the dnaN gene) not only exacerbates the cold sensitivity conferred by elevated levels of the umuDC gene products but, in addition, confers a severe cold-sensitive phenotype upon a strain expressing moderately elevated levels of the umuD'C gene products. Such a strain is not otherwise normally cold sensitive. To identify mutant beta proteins possibly deficient for physical interactions with the umuDC gene products, we selected for novel dnaN alleles unable to confer a cold-sensitive growth phenotype upon a umuD'C-overexpressing strain. In all, we identified 75 dnaN alleles, 62 of which either reduced the expression of beta or prematurely truncated its synthesis, while the remaining alleles defined eight unique missense mutations of dnaN. Each of the dnaN missense mutations retained at least a partial ability to function in chromosomal DNA replication in vivo. In addition, these eight dnaN alleles were also unable to exacerbate the cold sensitivity conferred by modestly elevated levels of the umuDC gene products, suggesting that the interactions between UmuD' and beta are a subset of those between UmuD and beta. Taken together, these findings suggest that interaction of beta with UmuD(2)C is important for the DNA damage checkpoint function of the umuDC gene products. Four possible models for how interactions of UmuD(2)C with the epsilon and the beta subunits of DNA polymerase III might help to regulate DNA replication in response to DNA damage are discussed.

The beta clamp targets DNA polymerase IV to DNA and strongly increases its processivity

The recent discovery of a new family of ubiquitous DNA polymerases involved in translesion synthesis has shed new light onto the biochemical basis of mutagenesis. Among these polymerases, the dinB gene product (Pol IV) is involved in mutagenesis in Escherichia coli. We show here that the activity of native Pol IV is drastically modified upon interaction with the beta subunit, the processivity factor of DNA Pol III. In the absence of the beta subunit Pol IV is strictly distributive and no stable complex between Pol IV and DNA could be detected. In contrast, the beta clamp allows Pol IV to form a stable initiation complex (t 1/2 approximately 2.3 min), which leads to a dramatic increase in the processivity of PoI IV reaching an average of 300-400 nucleotides. In vivo, the beta processivity subunit may target DNA Pol IV to its substrate, generating synthesis tracks much longer than previously thought.

The DNA replication machine of a gram-positive organism

This report outlines the protein requirements and subunit organization of the DNA replication apparatus of Streptococcus pyogenes, a Gram-positive organism. Five proteins coordinate their actions to achieve rapid and processive DNA synthesis. These proteins are: the PolC DNA polymerase, tau, delta, delta', and beta. S. pyogenes dnaX encodes only the full-length tau, unlike the Escherichia coli system in which dnaX encodes two proteins, tau and gamma. The S. pyogenes tau binds PolC, but the interaction is not as firm as the corresponding interaction in E. coli, underlying the inability to purify a PolC holoenzyme from Gram-positive cells. The tau also binds the delta and delta' subunits to form a taudeltadelta' "clamp loader." PolC can assemble with taudeltadelta' to form a PolC.taudeltadelta' complex. After PolC.taudeltadelta' clamps beta to a primed site, it extends DNA 700 nucleotides/second in a highly processive fashion. Gram-positive cells contain a second DNA polymerase, encoded by dnaE, that has homology to the E. coli alpha subunit of E. coli DNA polymerase III. We show here that the S. pyogenes DnaE polymerase also functions with the beta clamp.

Cross-utilization of the beta sliding clamp by replicative polymerases of evolutionary divergent organisms

Chromosomal replicases are multiprotein machines comprised of a DNA polymerase, a sliding clamp, and a clamp loader. This study examines replicase components for their ability to be switched between Gram-positive and Gram-negative organisms. These two cell types diverged over 1 billion years ago, and their sequences have diverged widely. Yet the Escherichia coli beta clamp binds directly to Staphylococcus aureus PolC and makes it highly processive, confirming and extending earlier results (Low, R. L., Rashbaum, S. A. , and Cozzarelli, N. R. (1976) J. Biol. Chem. 251, 1311-1325). We have also examined the S. aureus beta clamp. The results show that it functions with S. aureus PolC, but not with E. coli polymerase III core. PolC is a rather potent polymerase by itself and can extend a primer with an intrinsic speed of 80-120 nucleotides per s. Both E. coli beta and S. aureus beta converted PolC to a highly processive polymerase, but surprisingly, beta also increased the intrinsic rate of DNA synthesis to 240-580 nucleotides per s. This finding expands the scope of beta function beyond a simple mechanical tether for processivity to include that of an effector that increases the intrinsic rate of nucleotide incorporation by the polymerase.

Fidelity of eucaryotic DNA polymerase delta holoenzyme from Schizosaccharomyces pombe

The fidelity of Schizosaccharomyces pombe DNA polymerase delta was measured in the presence or absence of its processivity subunits, proliferating cell nuclear antigen (PCNA) sliding clamp and replication factor C (RFC) clamp-loading complex, using a synthetic 30-mer primer/100-mer template. Synthesis by pol delta alone was distributive. Processive synthesis occurred in the presence of PCNA, RFC, and Escherichia coli single strand DNA-binding protein (SSB) and required the presence of ATP. "Passive" self-loading of PCNA onto DNA takes place in the absence of RFC, in an ATP-independent reaction, which was strongly inhibited by SSB. The nucleotide substitution error rate for pol delta holoenzyme (HE) (pol delta + PCNA + RFC) was 4.6 x 10(-4) for T.G mispairs, 5.3 x 10(-5) for G.G mispairs, and 4.5 x 10(-6) for A.G mispairs. The T.G misincorporation frequency for pol delta without the accessory proteins was unchanged. The fidelity of pol delta HE was between 1 and 2 orders of magnitude lower than that measured for the E. coli pol III HE at the same template position. This relatively low fidelity was caused by inefficient proofreading by the S. pombe polymerase-associated proofreading exonuclease. The S. pombe 3'-exonuclease activity was also extremely inefficient in excising primer-3'-terminal mismatches in the absence of dNTP substrates and in hydrolyzing single-stranded DNA. A comparison of pol delta HE with E. coli pol IIIalpha HE (lacking the proofreading exonuclease subunit) showed that both holoenzymes exhibit similar error rates for each mispair.

Coping with replication 'train wrecks' in Escherichia coli using Pol V, Pol II and RecA proteins

DNA replication machineries tend to stall when confronted with damaged DNA template sites, causing the biochemical equivalent of a major 'train wreck'. A newly discovered bacterial DNA polymerase, Escherichia coli Pol V, acting in conjunction with the RecA protein, can exchange places with the stalled replicative Pol III core and catalyse 'error-prone' translesion synthesis. In contrast to Pol V-catalysed 'brute-force, sloppier copying', another SOS-induced DNA polymerase, Pol II, plays a pivotal role in an 'error-free', replication-restart DNA repair pathway and probably involves RecA-mediated homologous recombination.

DNA polymerase of the T4-related bacteriophages

The DNA polymerase of bacteriophage T4, product of phage gene 43 (gp43), has served as a model replicative DNA polymerase in nucleic acids research for nearly 40 years. The base-selection (polymerase, or Pol) and editing (3'-exonuclease, or Exo) functions of this multifunctional protein, which have counterparts in the replicative polymerases of other organisms, are primary determinants of the high fidelity of DNA synthesis in phage DNA replication. T4 gp43 is considered to be a member of the "B family" of DNA-dependent DNA polymerases (those resembling eukaryotic Pol alpha) because it exhibits striking similarities in primary structure to these enzymes. It has been extensively analyzed at the genetic, physiological, and biochemical levels; however, relationships between the in vivo properties of this enzyme and its physical structure have not always been easy to explain due to a paucity of structural data on the intact molecule. However, gp43 from phage RB69, a phylogenetic relative of T4, was crystallized and its structure solved in a complex with single-stranded DNA occupying the Exo site, as well as in the unliganded form. Analyses with these crystals, and crystals of a T4 gp43 proteolytic fragment harboring the Exo function, are opening new avenues to interpret existing biological and biochemical data on the intact T4 enzyme and are revealing new aspects of the microanatomy of gp43 that can now be explored further for functional significance. We summarize our current understanding of gp43 structure and review the physiological roles of this protein as an essential DNA-binding component of the multiprotein T4 DNA replication complex and as a nucleotide-sequence-specific RNA-binding translational repressor that controls its own biosynthesis and activity in vivo. We also contrast the properties of the T4 DNA replication complex to the functionally analogous complexes of other organisms, particularly Escherichia coli, and point out some of the unanswered questions about gp43 and T4 DNA replication.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

Replication slippage of different DNA polymerases is inversely related to their strand displacement efficiency

Replication slippage is a particular type of error caused by DNA polymerases believed to occur both in bacterial and eukaryotic cells. Previous studies have shown that deletion events can occur in Escherichia coli by replication slippage between short duplications and that the main E. coli polymerase, DNA polymerase III holoenzyme is prone to such slippage. In this work, we present evidence that the two other DNA polymerases of E. coli, DNA polymerase I and DNA polymerase II, as well as polymerases of two phages, T4 (T4 pol) and T7 (T7 pol), undergo slippage in vitro, whereas DNA polymerase from another phage, Phi29, does not. Furthermore, we have measured the strand displacement activity of the different polymerases tested for slippage in the absence and in the presence of the E. coli single-stranded DNA-binding protein (SSB), and we show that: (i) polymerases having a strong strand displacement activity cannot slip (DNA polymerase from Phi29); (ii) polymerases devoid of any strand displacement activity slip very efficiently (DNA polymerase II and T4 pol); and (iii) stimulation of the strand displacement activity by E. coli SSB (DNA polymerase I and T7 pol), by phagic SSB (T4 pol), or by a mutation that affects the 3' --> 5' exonuclease domain (DNA polymerase II exo(-) and T7 pol exo(-)) is correlated with the inhibition of slippage. We propose that these observations can be interpreted in terms of a model, for which we have shown that high strand displacement activity of a polymerase diminishes its propensity to slip.

A phenotype for enigmatic DNA polymerase II: a pivotal role for pol II in replication restart in UV-irradiated Escherichia coli

DNA synthesis in Escherichia coli is inhibited transiently after UV irradiation. Induced replisome reactivation or "replication restart" occurs shortly thereafter, allowing cells to complete replication of damaged genomes. At the present time, the molecular mechanism underlying replication restart is not understood. DNA polymerase II (pol II), encoded by the dinA (polB) gene, is induced as part of the global SOS response to DNA damage. Here we show that pol II plays a pivotal role in resuming DNA replication in cells exposed to UV irradiation. There is a 50-min delay in replication restart in mutant cells lacking pol II. Although replication restart appears normal in DeltaumuDC strains containing pol II, the restart process is delayed for >90 min in cells lacking both pol II and UmuD'(2)C. Because of the presence of pol II, a transient replication-restart burst is observed in a "quick-stop" temperature-sensitive pol III mutant (dnaE486) at nonpermissive temperature. However, complete recovery of DNA synthesis requires the concerted action of both pol II and pol III. Our data demonstrate that pol II and UmuD'(2)C act in independent pathways of replication restart, thereby providing a phenotype for pol II in the repair of UV-damaged DNA.

Archaeal DNA replication: identifying the pieces to solve a puzzle

Archaeal organisms are currently recognized as very exciting and useful experimental materials. A major challenge to molecular biologists studying the biology of Archaea is their DNA replication mechanism. Undoubtedly, a full understanding of DNA replication in Archaea requires the identification of all the proteins involved. In each of four completely sequenced genomes, only one DNA polymerase (Pol BI proposed in this review from family B enzyme) was reported. This observation suggested that either a single DNA polymerase performs the task of replicating the genome and repairing the mutations or these genomes contain other DNA polymerases that cannot be identified by amino acid sequence. Recently, a heterodimeric DNA polymerase (Pol II, or Pol D as proposed in this review) was discovered in the hyperthermophilic archaeon, Pyrococcus furiosus. The genes coding for DP1 and DP2, the subunits of this DNA polymerase, are highly conserved in the Euryarchaeota. Euryarchaeotic DP1, the small subunit of Pol II (Pol D), has sequence similarity with the small subunit of eukaryotic DNA polymerase delta. DP2 protein, the large subunit of Pol II (Pol D), seems to be a catalytic subunit. Despite possessing an excellent primer extension ability in vitro, Pol II (Pol D) may yet require accessory proteins to perform all of its functions in euryarchaeotic cells. This review summarizes our present knowledge about archaeal DNA polymerases and their relationship with those accessory proteins, which were predicted from the genome sequences.

Displacement of cellular proteins by functional analogues from plasmids or viruses could explain puzzling phylogenies of many DNA informational proteins

Comparative genomics has revealed many examples in which the same function is performed by unrelated or distantly related proteins in different cellular lineages. In some cases, this has been explained by the replacement of the original gene by a paralogue or non-homologue, a phenomenon known as non-orthologous gene displacement. Such gene displacement probably occurred early on in the history of proteins involved in DNA replication, repair, recombination and transcription (DNA informational proteins), i.e. just after the divergence of archaea, bacteria and eukarya from the last universal cellular ancestor (LUCA). This would explain why many DNA informational proteins are not orthologues between the three domains of life. However, in many cases, the origin of the displacing genes is obscure, as they do not even have detectable homologues in another domain. I suggest here that the original cellular DNA informational proteins have often been replaced by proteins of viral or plasmid origin. As viral and plasmid-encoded proteins are usually very divergent from their cellular counterparts, this would explain the puzzling phylogenies and distribution of many DNA informational proteins between the three domains of life.

The beta subunit sliding DNA clamp is responsible for unassisted mutagenic translesion replication by DNA polymerase III holoenzyme

The replication of damaged nucleotides that have escaped DNA repair leads to the formation of mutations caused by misincorporation opposite the lesion. In Escherichia coli, this process is under tight regulation of the SOS stress response and is carried out by DNA polymerase III in a process that involves also the RecA, UmuD' and UmuC proteins. We have shown that DNA polymerase III holoenzyme is able to replicate, unassisted, through a synthetic abasic site in a gapped duplex plasmid. Here, we show that DNA polymerase III*, a subassembly of DNA polymerase III holoenzyme lacking the beta subunit, is blocked very effectively by the synthetic abasic site in the same DNA substrate. Addition of the beta subunit caused a dramatic increase of at least 28-fold in the ability of the polymerase to perform translesion replication, reaching 52% bypass in 5 min. When the ssDNA region in the gapped plasmid was extended from 22 nucleotides to 350 nucleotides, translesion replication still depended on the beta subunit, but it was reduced by 80%. DNA sequence analysis of translesion replication products revealed mostly -1 frameshifts. This mutation type is changed to base substitution by the addition of UmuD', UmuC, and RecA, as demonstrated in a reconstituted SOS translesion replication reaction. These results indicate that the beta subunit sliding DNA clamp is the major determinant in the ability of DNA polymerase III holoenzyme to perform unassisted translesion replication and that this unassisted bypass produces primarily frameshifts.

A broadening view of recombinational DNA repair in bacteria

Recombinational DNA repair is both the most complex and least understood of DNA repair pathways. In bacterial cells grown under normal laboratory conditions (without a DNA damaging treatment other than an aerobic environment), a substantial number (10-50%) of the replication forks originating at oriC encounter a DNA lesion or strand break. When this occurs, repair is mediated by an elaborate set of recombinational DNA repair pathways which encompass most of the enzymes involved in DNA metabolism. Four steps are discussed: (i) The replication fork stalls and/or collapses. (ii) Recombination enzymes are recruited to the location of the lesion, and function with nearly perfect efficiency and fidelity. (iii) Additional enzymatic systems, including the phiX174-type primosome (or repair primosome), then function in the origin-independent reassembly of the replication fork. (iv) Frequent recombination associated with recombinational DNA repair leads to the formation of dimeric chromosomes, which are monomerized by the XerCD site-specific recombination system.

Lack of correlation between in vitro and in vivo replication of precisely defined benz-a-anthracene adducted DNAs

Like other polycyclic aromatic hydrocarbons, certain metabolites of benz[a]anthracene have been implicated as potent carcinogens. These effects are thought to be caused by the covalent binding of these species to nucleophilic groups on the bases of DNA. To address the molecular mechanisms by which these molecules induce mutations, this study employed oligonucleotides containing four site-specific N6 adenine-benz[a]anthracene diol epoxide adducts. Using a prokaryotic in vivo replication system, we have shown that both non-bay region anti-trans-benz[a]anthracene adducts are essentially nonmutagenic. In contrast, the bay region anti-trans-benz[a]anthracene lesions do induce point mutations at the adduct site. The mutagenic frequency of these bay region lesions is dependent on the stereochemistry about the adduct-forming bond, as well as the strain of Escherichia coli in which they are replicated. The ability of the bacterial replication machinery to bypass the lesions does not correlate with the differences observed in their mutagenesis. While both non-bay region adducts are readily bypassed in vivo, the bay region adducts are both blocking to approximately the same degree. In vitro studies of the interactions of E. coli DNA polymerase III with these adducts have also been undertaken to further dissect the relationship between adduct structure and biological activity.

Genetic requirements and mutational specificity of the Escherichia coli SOS mutator activity

To better understand the mechanisms of SOS mutagenesis in the bacterium Escherichia coli, we have undertaken a genetic analysis of the SOS mutator activity. The SOS mutator activity results from constitutive expression of the SOS system in strains carrying a constitutively activated RecA protein (RecA730). We show that the SOS mutator activity is not enhanced in strains containing deficiencies in the uvrABC nucleotide excision-repair system or the xth and nfo base excision-repair systems. Further, recA730-induced errors are shown to be corrected by the MutHLS-dependent mismatch-repair system as efficiently as the corresponding errors in the rec+ background. These results suggest that the SOS mutator activity does not reflect mutagenesis at so-called cryptic lesions but instead represents an amplification of normally occurring DNA polymerase errors. Analysis of the base-pair-substitution mutations induced by recA730 in a mismatch repair-deficient background shows that both transition and transversion errors are amplified, although the effect is much larger for transversions than for transitions. Analysis of the mutator effect in various dnaE strains, including dnaE antimutators, as well as in proofreading-deficient dnaQ (mutD) strains suggests that in recA730 strains, two types of replication errors occur in parallel: (i) normal replication errors that are subject to both exonucleolytic proofreading and dnaE antimutator effects and (ii) recA730-specific errors that are not susceptible to either proofreading or dnaE antimutator effects. The combined data are consistent with a model suggesting that in recA730 cells error-prone replication complexes are assembled at sites where DNA polymerization is temporarily stalled, most likely when a normal polymerase insertion error has created a poorly extendable terminal mismatch. The modified complex forces extension of the mismatch largely at the exclusion of proofreading and polymerase dissociation pathways. SOS mutagenesis targeted at replication-blocking DNA lesions likely proceeds in the same manner.

The Escherichia coli polB locus is identical to dinA, the structural gene for DNA polymerase II. Characterization of Pol II purified from a polB mutant

Escherichia coli DNA polymerase II (Pol II) is a member of the group B, "alpha-like" family of DNA polymerases. Pol II is encoded by the damage-inducible dinA gene and exhibits SOS induction under the control of Lex A repressor. The polB gene was originally designated as the structural gene for Pol II based on the absence of detectable Pol II activity in cell lysates prepared from a strain containing the mutant polB100 allele. Because polB and dinA mapped at different chromosomal locations, it remained an open question whether polB, in addition to lexA, might be involved in regulating the expression of Pol II. We have cloned and sequenced the polB100 mutant allele, including adjacent surrounding sequences, and have expressed the mutant dinA gene from Pol B100 on a high copy number plasmid. Our sequence data reveal that polB and dinA represent the same gene and that the original transduction mapping of polB was inaccurate. We purified the mutant Pol B100 polymerase and show that it retains 5 to 10% of the wild-type level of polymerase activity. The Pol B100 mutation, Gly401 --> Asp401, is not located within any of the five conserved domains that define group B polymerases. Pol B100 retains a wild-type level of 3' --> 5' exonuclease activity. We suggest that the normal level of exonucleolytic proofreading associated with the mutant Pol B100 enzyme may explain the repeated failures, over the past two decades, to detect phenotypes in polB mutant strains.

Escherichia coli DNA polymerase II catalyzes chromosomal and episomal DNA synthesis in vivo

We have investigated a role for Escherichia coli DNA polymerase II (Pol II) in copying chromosomal and episomal DNA in dividing cells in vivo. Forward mutation frequencies and rates were measured at two chromosomal loci, rpoB and gyrA, and base substitution and frameshift mutation frequencies were measured on an F'(lacZ) episome. To amplify any differences in polymerase error rates, methyl-directed mismatch repair was inactivated. When wild-type Pol II (polB+) was replaced on the chromosome by a proofreading-defective Pol II exo- (polBex1), there was a significant increase in mutation frequencies to rifampicin resistance (RifR) (rpoB) and nalidixic acid resistance (NalR) (gyrA). This increased mutagenesis occurred in the presence of an antimutator allele of E. coli DNA polymerase III (Pol III) (dnaE915), but not in the presence of wild-type Pol III (dnaE+), suggesting that Pol II can compete effectively with DnaE915 but not with DnaE+. Sequencing the RifR mutants revealed a G --> A hot spot highly specific to Pol II exo-. Pol II exo- caused a significant increase in the frequency of base substitution and frameshift mutations on F' episomes, even in dnaE+ cells, suggesting that Pol II is able to compete with Pol III for DNA synthesis on F episomes.

Dynamics of loading the beta sliding clamp of DNA polymerase III onto DNA

A "minimal" DNA primer-template system, consisting of an 80-mer template and 30-mer primer, supports processive DNA synthesis by DNA polymerase III core in the presence of the beta sliding clamp, gamma complex clamp loader, and single-stranded binding protein from Escherichia coli. This primer-template system was used to measure the loading of the beta sliding clamp by the gamma complex in an ATP-dependent reaction. Bound protein-DNA complexes were detected by monitoring fluorescence depolarization of DNA. Steady state and time-resolved anisotropies were measured, and stopped-flow pre-steady state fluorescence measurements allowed visualization of the loading reactions in real time. The rate of loading beta onto DNA was 12 s-1, demonstrating that clamp assembly is rapid on the time scale required for lagging strand Okazaki fragment synthesis. The association rate appears to be limited by an intramolecular step occurring prior to the clamp-loading reaction, possibly the opening of the toroidal beta dimer.

Strained template under the thumbs. How reverse transcriptase of human immunodeficiency virus type 1 moves along its template

In retroviruses, such as human immunodeficiency virus type 1 (HIV-1), the reverse transcriptase (RT) copies single-stranded viral RNA into complementary DNA, which is then used as a template for synthesis of the second DNA strand. The resulting double-stranded DNA is integrated into the host genome. How RT translocates on the different templates is the subject of this study. We have developed a theoretical model for RT translocation during processive DNA synthesis. The model is based on the assumption that there are two template-binding sites, namely the helix clamps, located in the thumb subdomains of RT subunits p66 and p51. Flexibility of the p66 thumb provides undisrupted template-binding during polymerase translocation. Coordinated association and dissociation of the template at the thumbs, triggered by nucleotide incorporation, is assumed, which ensures template contact with at least one subdomain throughout translocation. We suggest that coordination between the sites is effected by stress in the template region located between the thumbs. Translocation of HIV-1 RT proceeds continuously but with different processivities on RNA and DNA templates. These findings are explained in detail by the proposed model.

Mechanism of translesion DNA synthesis by DNA polymerase II. Comparison to DNA polymerases I and III core

Bypass synthesis by DNA polymerase II was studied using a synthetic 40-nucleotide-long gapped duplex DNA containing a site-specific abasic site analog, as a model system for mutagenesis associated with DNA lesions. Bypass synthesis involved a rapid polymerization step terminating opposite the nucleotide preceding the lesion, followed by a slow bypass step. Bypass was found to be dependent on polymerase and dNTP concentrations, on the DNA sequence context, and on the size of the gap. A side-by-side comparison of DNA polymerases I, II, and III core revealed the following. 1) Each of the three DNA polymerases bypassed the abasic site analog unassisted by other proteins. 2) In the presence of physiological-like salt conditions, only DNA polymerase II bypassed the lesion. 3) Bypass by each of the three DNA polymerases increased dramatically in the absence of proofreading. These results support a model (Tomer, G., Cohen-Fix, O. , O'Donnell, M., Goodman, M. and Livneh, Z. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 1376-1380) by which the RecA, UmuD, and UmuC proteins are accessory factors rather than being absolutely required for the core mutagenic bypass reaction in induced mutagenesis in Escherichia coli.

Purification and properties of wild-type and exonuclease-deficient DNA polymerase II from Escherichia coli

Wild-type DNA polymerase II (pol II) and an exonuclease-deficient pol II mutant (D155A/E157A) have been overexpressed and purified in high yield from Escherichia coli. Wild-type pol II exhibits a high proofreading 3'-exonuclease to polymerase ratio, similar in magnitude to that observed for bacteriophage T4 DNA polymerase. While copying a 250-nucleotide region of the lacZ alpha gene, the fidelity of wild-type pol II is high, with error rates for single-base substitution and frameshift errors being < or = 10(-6). In contrast, the pol II exonuclease-deficient mutant generated a variety of base substitution and single base frameshift errors, as well as deletions between both perfect and imperfect directly repeated sequences separated by a few to hundreds of nucleotides. Error rates for the pol II exonuclease-deficient mutant were from > or = 13- to > or = 240-fold higher than for wild-type pol II, depending on the type of error considered. These data suggest that from 90 to > 99% of base substitutions, frameshifts, and large deletions are efficiently proofread by the enzyme. The results of these experiments together with recent in vivo studies suggest an important role for pol II in the fidelity of DNA synthesis in cells.

Involvement of Escherichia coli DNA polymerase II in response to oxidative damage and adaptive mutation

DNA polymerase II (Pol II) is regulated as part of the SOS response to DNA damage in Escherichia coli. We examined the participation of Pol II in the response to oxidative damage, adaptive mutation, and recombination. Cells lacking Pol II activity (polB delta 1 mutants) exhibited 5- to 10-fold-greater sensitivity to mode 1 killing by H2O2 compared with isogenic polB+ cells. Survival decreased by about 15-fold when polB mutants containing defective superoxide dismutase genes, sodA and sodB, were compared with polB+ sodA sodB mutants. Resistance to peroxide killing was restored following P1 transduction of polB cells to polB+ or by conjugation of polB cells with an F' plasmid carrying a copy of polB+. The rate at which Lac+ mutations arose in Lac- cells subjected to selection for lactose utilization, a phenomenon known as adaptive mutation, was increased threefold in polB backgrounds and returned to wild-type rates when polB cells were transduced to polB+. Following multiple passages of polB cells or prolonged starvation, a progressive loss of sensitivity to killing by peroxide was observed, suggesting that second-site suppressor mutations may be occurring with relatively high frequencies. The presence of suppressor mutations may account for the apparent lack of a mutant phenotype in earlier studies. A well-established polB strain, a dinA Mu d(Apr lac) fusion (GW1010), exhibited wild-type (Pol II+) sensitivity to killing by peroxide, consistent with the accumulation of second-site suppressor mutations. A high titer anti-Pol II polyclonal antibody was used to screen for the presence of Pol II in other bacteria and in the yeast Saccharomyces cerevisiae. Cross-reacting material was found in all gram-negative strains tested but was not detected in gram-positive strains or in S. cerevisiae. Induction of Pol II by nalidixic acid was observed in E. coli K-12, B, and C, in Shigella flexneri, and in Salmonella typhimurium.

An explanation for lagging strand replication: polymerase hopping among DNA sliding clamps

The replicase of E. coli, DNA polymerase III holoenzyme, is tightly fastened to DNA by its ring-shaped beta sliding clamp. However, despite being clamped to DNA, the polymerase must rapidly cycle on and off DNA to synthesize thousands of Okazaki fragments on the lagging strand. This study shows that DNA polymerase III holoenzyme cycles from one DNA to another by a novel mechanism of partial disassembly of its multisubunit structure and then reassembly. Upon completing a template, the polymerase disengages from its beta clamp, hops off DNA, and reassociates with another beta clamp at a new primed site. The original beta clamp is left on DNA and may be harnessed by other machineries to coordinate their action with chromosome replication.

DNA polymerase arrest by adducted trivalent chromium

Carcinogenic chromium (Cr6+) enters cells via the sulfate transport system and undergoes intracellular reduction to trivalent chromium, which strongly adducts to DNA. In this study, the effect of adducted trivalent chromium on in vitro DNA synthesis was analyzed with a polymerase-arrest assay in which prematurely terminated replication products were separated on a DNA sequencing gel. A synthetic DNA replication template was treated with increasing concentrations of chromium(III) chloride. The two lowest chromium doses used resulted in biologically relevant adduct levels (6 and 21 adducts per 1,000 DNA nucleotides) comparable with those measured in nuclear matrix DNA from cells treated with a 50% cytotoxic dose of sodium chromate in vivo. In vitro replication of the chromium-treated template DNA using the Sequenase version 2.0 T7 DNA polymerase (United States Biochemical Corp., Cleveland, OH) resulted in dose-dependent polymerase arrest beginning at the lowest adduct levels analyzed. The pattern of polymerase arrest remained consistent as chromium adduct levels increased, with the most intense arrest sites occurring 1 base upstream of guanine residues on the template strand. Replication by the DNA polymerase I large (Klenow) fragment as well as by unmodified T7 DNA polymerase also resulted in similar chromium-induced polymerase arrest. Interstrand cross-linking between complementary strands was detected in template DNA containing 62, 111, and 223 chromium adducts per 1,000 DNA nucleotides but not in template containing 6 or 21 adducts per 1,000 DNA nucleotides, in which arrest nevertheless did occur. Low-level, dose-dependent interstrand cross-linking between primer and template DNA, however, was detectable even at the lowest chromium dose analyzed. Since only 9% of chromium adducts resulted in polymerase arrest in this system, we hypothesized that arrest occurred when the enzyme encountered chromium-mediated interstrand DNA-DNA cross-links between either the template and a separate DNA molecule or the template and its complementary strand in the same molecule. These results suggest that the obstruction of DNA replication by chromium-mediated DNA-DNA cross-links is a potential mechanism of chromium-induced genotoxicity in vivo.

The Escherichia coli DNA polymerase III holoenzyme contains both products of the dnaX gene, tau and gamma, but only tau is essential

The replicative polymerase of Escherichia coli, DNA polymerase III, consists of a three-subunit core polymerase plus seven accessory subunits. Of these seven, tau and gamma are products of one replication gene, dnaX. The shorter gamma is created from within the tau reading frame by a programmed ribosomal -1 frameshift over codons 428 and 429 followed by a stop codon in the new frame. Two temperature-sensitive mutations are available in dnaX. The 2016(Ts) mutation altered both tau and gamma by changing codon 118 from glycine to aspartate; the 36(Ts) mutation affected the activity only of tau because it altered codon 601 (from glutamate to lysine). Evidence which indicates that, of these two proteins, only the longer tau is essential includes the following. (i) The 36(Ts) mutation is a temperature-sensitive lethal allele, and overproduction of wild-type gamma cannot restore its growth. (ii) An allele which produced tau only could be substituted for the wild-type chromosomal gene, but a gamma-only allele could not substitute for the wild-type dnaX in the haploid state. Thus, the shorter subunit gamma is not essential, suggesting that tau can be substitute for the usual function(s) of gamma. Consistent with these results, we found that a functional polymerase was assembled from nine pure subunits in the absence of the gamma subunit. However, the possibility that, in cells growing without gamma, proteolysis of tau to form a gamma-like product in amounts below the Western blot (immunoblot) sensitivity level cannot be excluded.

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.

Absence of a role for DNA polymerase II in SOS-induced translesion bypass of phi X174

In order to examine the possible role of Escherichia coli DNA polymerase II in SOS-induced translesion bypass, Weigle reactivation and mutation induction were measured with single-stranded phi X174 transfecting DNA containing individual lesions. No decrease in bypass of thymine glycol or cyclobutane pyrimidine dimers in the absence of DNA polymerase II was observed. Furthermore, DNA polymerase II did not affect bypass of abasic sites when either survival or mutagenesis was the endpoint. Lastly, repair of gapped DNA molecules, intermediates in methyl-directed mismatch repair, was also unaffected by the presence or absence of DNA polymerase II.