Analysis of translesion replication across an abasic site by DNA polymerase IV of Escherichia coli

Unrepaired replication-blocking DNA lesions are bypassed by specialized DNA polymerases, members of the Y super-family. In Escherichia coli the major lesion bypass DNA polymerase is pol V, whereas the function of its homologue, pol IV, is not fully understood. In vivo analysis showed that pol V has a major role in bypass across an abasic site analog, with little or no involvement of pol IV. This can result from the inability of pol IV to bypass the abasic site, or from in vivo regulation of its activity. In vitro analysis revealed that purified pol IV, in the presence of the beta subunit DNA sliding clamp, and the gamma complex clamp loader, bypassed a synthetic abasic site with very high efficiency, reaching 73% in 2 min. Bypass was observed also in the absence of the processivity proteins, albeit at a 10- to 20-fold lower rate. DNA sequence analysis revealed that pol IV skips over the abasic site, producing primarily small deletions. The RecA protein inhibited bypass by pol IV, but this inhibition was alleviated by single-strand binding protein (SSB). The fact that the in vitro bypass ability of pol IV is not manifested under in vivo conditions suggests the presence of a regulatory factor, which might be involved in controlling the access of the bypass polymerases to the damaged site in DNA.     

Analysis of unassisted translesion replication by the DNA polymerase III holoenzyme

DNA damage-induced mutations are formed when damaged nucleotides present in single-stranded DNA are replicated. We have developed a new method for the preparation of gapped plasmids containing site-specific damaged nucleotides, as model DNA substrates for translesion replication. Using these substrates, we show that the DNA polymerase III holoenzyme from Escherichia coli can bypass a synthetic abasic site analogue with high efficiency (30% bypass in 16 min), unassisted by other proteins. The theta and tau subunits of the polymerase were not essential for bypass. No bypass was observed when the enzyme was assayed on a synthetic 60-mer oligonucleotide carrying the same lesion, and bypass on a linear gapped plasmid was 3-4-fold slower than on a circular gapped plasmid. There was no difference in the bypass when standing-start and running-start replication were compared. A comparison of translesion replication by DNA polymerase I, DNA polymerase II, the DNA polymerase III core, and the DNA polymerase III holoenzyme clearly showed that the DNA polymerase III holoenzyme was by far the most effective in performing translesion replication. This was not only due to the high processivity of the pol III holoenzyme, because increasing the processivity of pol II by adding the gamma complex and beta subunit, did not increase bypass. These results support the model that SOS regulation was imposed on a fundamentally constitutive translesion replication reaction to achieve tight control of mutagenesis.     

Lesion bypass by the Escherichia coli DNA polymerase V requires assembly of a RecA nucleoprotein filament

Translesion replication is carried out in Escherichia coli by the SOS-inducible DNA polymerase V (UmuC), an error-prone polymerase, which is specialized for replicating through lesions in DNA, leading to the formation of mutations. Lesion bypass by pol V requires the SOS-regulated proteins UmuD' and RecA and the single-strand DNA-binding protein (SSB). Using an in vitro assay system for translesion replication based on a gapped plasmid carrying a site-specific synthetic abasic site, we show that the assembly of a RecA nucleoprotein filament is required for lesion bypass by pol V. This is based on the reaction requirements for stoichiometric amounts of RecA and for single-stranded gaps longer than 100 nucleotides and on direct visualization of RecA-DNA filaments by electron microscopy. SSB is likely to facilitate the assembly of the RecA nucleoprotein filament; however, it has at least one additional role in lesion bypass. ATPgammaS, which is known to strongly increase binding of RecA to DNA, caused a drastic inhibition of pol V activity. Lesion bypass does not require stoichiometric binding of UmuD' along RecA filaments. In summary, the RecA nucleoprotein filament, previously known to be required for SOS induction and homologous recombination, is also a critical intermediate in translesion replication.     

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

An interesting property of the Escherichia coli DNA polymerase II is the stimulation in DNA synthesis mediated by the DNA polymerase III accessory proteins beta,gamma complex. In this paper we have studied the basis for the stimulation in pol II activity and have concluded that these accessory proteins stimulate pol II activity by increasing the processivity of the enzyme between 150- and 600-fold. As is the case with pol III, processive synthesis by pol II requires both beta,gamma complex and SSB protein. Whereas the intrinsic velocity of synthesis by pol II is 20-30 nucleotides per s with or without the accessory proteins, the processivity of pol II is increased from approximately five nucleotides to greater than 1600 nucleotides incorporated per template binding event. The effect of the accessory proteins on the rate of replication is far greater on pol III than on pol II; pol III holoenzyme is able to complete replication of circular single-stranded M13 DNA in less than 20 s, whereas pol II in the presence of the gamma complex and beta requires approximately 5 min. We have investigated the effect of beta,gamma complex proteins on bypass of a site-specific abasic lesion by E. coli DNA polymerases I, II, and III. All three polymerases are extremely inefficient at bypass of the abasic lesion. We find limited bypass by pol I with no change upon addition of accessory proteins. pol II also shows limited bypass of the abasic site, dependent on the presence of beta,gamma complex and SSB. pol III shows no significant bypass of the abasic site with or without beta,gamma complex.     

The biochemical requirements of DNA polymerase V-mediated translesion synthesis revisited

In addition to replicative DNA polymerases, cells contain specialized DNA polymerases involved in processes such as lesion tolerance, mutagenesis and immunoglobulin diversity. In Escherichia coli, DNA polymerase V (Pol V), encoded by the umuDC locus, is involved in translesion synthesis (TLS) and mutagenesis. Genetic studies have established that mutagenesis requires both UmuC and a proteolytic product of UmuD (UmuD'). In addition, RecA protein and the replication processivity factor, the beta-clamp, were genetically found to be essential co-factors for mutagenesis. Here, we have reconstituted Pol V-mediated bypass of three common replication-blocking lesions, namely the two major UV-induced lesions and a guanine adduct formed by a chemical carcinogen (G-AAF) under conditions that fulfil these in vivo requirements. Two co-factors are essential for efficient Pol V-mediated lesion bypass: (i) a DNA substrate onto which the beta-clamp is stably loaded; and (ii) an extended single-stranded RecA/ATP filament assembled downstream from the lesion site. For efficient bypass, Pol V needs to interact simultaneously with the beta-clamp and the 3' tip of the RecA filament. Formation of an extended RecA/ATP filament and stable loading of the beta-clamp are best achieved on long single-stranded circular DNA templates. In contrast to previously published data, the single-stranded DNA-binding protein (SSB) is not absolutely required for Pol V-mediated lesion bypass provided ATP, instead of ATPgammaS, activates the RecA filament. Further discrepancies with the existing literature are explainable by the use of either inadequate DNA substrates or a UmuC fusion protein instead of native Pol V.     

RecFOR proteins are essential for Pol V-mediated translesion synthesis and mutagenesis

When the replication fork moves through the template DNA containing lesions, daughter-strand gaps are formed opposite lesion sites. These gaps are subsequently filled-in either by translesion synthesis (TLS) or by homologous recombination. RecA filaments formed within these gaps are key intermediates for both of the gap-filling pathways. For instance, Pol V, the major lesion bypass polymerase in Escherichia coli, requires a functional interaction with the tip of the RecA filament. Here, we show that all three recombination mediator proteins RecFOR are needed to build a functionally competent RecA filament that supports efficient Pol V-mediated TLS in the presence of ssDNA-binding protein (SSB). A positive contribution of RecF protein to Pol V lesion bypass is demonstrated. When Pol III and Pol V are both present, Pol III imparts a negative effect on Pol V-mediated lesion bypass that is counteracted by the combined action of RecFOR and SSB. Mutations in recF, recO or recR gene abolish induced mutagenesis in E. coli.     

Specific amino acid residues in the beta sliding clamp establish a DNA polymerase usage hierarchy in Escherichia coli

Escherichia coli dnaN159 strains encode a mutant form of the beta sliding clamp (beta159), causing them to display altered DNA polymerase (pol) usage. In order to better understand mechanisms of pol selection/switching in E. coli, we have further characterized pol usage in the dnaN159 strain. The dnaN159 allele contains two amino acid substitutions: G66E (glycine-66 to glutamic acid) and G174A (glycine-174 to alanine). Our results indicated that the G174A substitution impaired interaction of the beta clamp with the alpha catalytic subunit of pol III. In light of this finding, we designed two additional dnaN alleles. One of these dnaN alleles contained a G174A substitution (beta-G174A), while the other contained D173A, G174A and H175A substitutions (beta-173-175). Examination of strains bearing these different dnaN alleles indicated that each conferred a distinct UV sensitive phenotype that was dependent upon a unique combination of Delta polB (pol II), Delta dinB (pol IV) and/or Delta umuDC (pol V) alleles. Taken together, these findings indicate that mutations in the beta clamp differentially affect the functions of these three pols, and suggest that pol II, pol IV and pol V are capable of influencing each others' abilities to gain access to the replication fork. These findings are discussed in terms of a model whereby amino acid residues in the vicinity of those mutated in beta159 (G66 and G174) help to define a DNA polymerase usage hierarchy in E. coli following UV irradiation.     

The Escherichia coli dnaN159 mutant displays altered DNA polymerase usage and chronic SOS induction

The Escherichia coli beta sliding clamp, which is encoded by the dnaN gene, is reported to interact with a variety of proteins involved in different aspects of DNA metabolism. Recent findings indicate that many of these partner proteins interact with a common surface on the beta clamp, suggesting that competition between these partners for binding to the clamp might help to coordinate both the nature and order of the events that take place at a replication fork. The purpose of the experiments discussed in this report was to test a prediction of this model, namely, that a mutant beta clamp protein impaired for interactions with the replicative DNA polymerase (polymerase III [Pol III]) would likewise have impaired interactions with other partner proteins and hence would display pleiotropic phenotypes. Results discussed herein indicate that the dnaN159-encoded mutant beta clamp protein (beta159) is impaired for interactions with the alpha catalytic subunit of Pol III. Moreover, the dnaN159 mutant strain displayed multiple replication and repair phenotypes, including sensitivity to UV light, an absolute dependence on the polymerase activity of Pol I for viability, enhanced Pol V-dependent mutagenesis, and altered induction of the global SOS response. Furthermore, epistasis analyses indicated that the UV sensitivity of the dnaN159 mutant was suppressed by (not epistatic with) inactivation of Pol IV (dinB gene product). Taken together, these findings suggest that in the dnaN159 mutant, DNA polymerase usage, and hence DNA replication, repair, and translesion synthesis, are altered. These findings are discussed in terms of a model to describe how the beta clamp might help to coordinate protein traffic at the replication fork.     

Mutant forms of the Escherichia colibeta sliding clamp that distinguish between its roles in replication and DNA polymerase V-dependent translesion DNA synthesis

The Escherichia colibeta sliding clamp is proposed to play an important role in regulating DNA polymerase traffic at the replication fork. As part of an ongoing effort to understand how organisms manage the actions of their multiple DNA polymerases, we examined the ability of several mutant forms of the beta clamp to function in DNA polymerase V- (pol V-) dependent translesion DNA synthesis (TLS) in vivo. Our results indicate that a dnaN159 strain, which expresses a temperature sensitive form of the beta clamp, was impaired for pol V-dependent TLS at the permissive temperature of 37 degrees C. This defect was complemented by a plasmid that expressed near-physiological levels of the wild-type clamp. Using a dnaN159 mutant strain, together with various plasmids expressing mutant forms of the clamp, we determined that residues H148 through R152, which comprise a portion of a solvent exposed loop, as well as position P363, which is located in the C-terminal tail of the beta clamp, are critically important for pol V-dependent TLS in vivo. In contrast, these same residues appear to be less critical for pol III-dependent replication. Taken together, these findings indicate that: (i) the beta clamp plays an essential role in pol V-dependent TLS in vivo and (ii) pol III and pol V interact with non-identical surfaces of the beta clamp.     

Effects of accessory proteins on the bypass of a cis-syn thymine-thymine dimer by Saccharomyces cerevisiae DNA polymerase eta

Among several hypotheses to explain how translesion synthesis (TLS) by DNA polymerase eta (pol eta) suppresses ultraviolet light-induced mutagenesis in vivo despite the fact that pol eta copies DNA with low fidelity, here we test whether replication accessory proteins enhance the fidelity of TLS by pol eta. We first show that the single-stranded DNA binding protein RPA, the sliding clamp PCNA, and the clamp loader RFC slightly increase the processivity of yeast pol eta and its ability to recycle to new template primers. However, these increases are small, and they are similar when copying an undamaged template and a template containing a cis-syn TT dimer. Consequently, the accessory proteins do not strongly stimulate the already robust TT dimer bypass efficiency of pol eta. We then perform a comprehensive analysis of yeast pol eta fidelity. We show that it is much less accurate than other yeast DNA polymerases and that the accessory proteins have little effect on fidelity when copying undamaged templates or when bypassing a TT dimer. Thus, although accessory proteins clearly participate in pol eta functions in vivo, they do not appear to help suppress UV mutagenesis by improving pol eta bypass fidelity per se.     

The mutagenesis protein UmuC is a DNA polymerase activated by UmuD', RecA, and SSB and is specialized for translesion replication.

Replication of DNA lesions leads to the formation of mutations. In Escherichia coli this process is regulated by the SOS stress response, and requires the mutagenesis proteins UmuC and UmuD'. Analysis of translesion replication using a recently reconstituted in vitro system (Reuven, N. B., Tomer, G., and Livneh, Z. (1998) Mol. Cell 2, 191-199) revealed that lesion bypass occurred with a UmuC fusion protein, UmuD', RecA, and SSB in the absence of added DNA polymerase. Further analysis revealed that UmuC was a DNA polymerase (E. coli DNA polymerase V), with a weak polymerizing activity. Upon addition of UmuD', RecA, and SSB, the UmuC DNA polymerase was greatly activated, and replicated a synthetic abasic site with great efficiency (45% bypass in 6 min), 10-100-fold higher than E. coli DNA polymerases I, II, or III holoenzyme. Analysis of bypass products revealed insertion of primarily dAMP (69%), and to a lesser degree dGMP (31%) opposite the abasic site. The UmuC104 mutant protein was defective both in lesion bypass and in DNA synthesis. These results indicate that UmuC is a UmuD'-, RecA-, and SSB-activated DNA polymerase, which is specialized for lesion bypass. UmuC is a member of a new family of DNA polymerases which are specialized for lesion bypass, and include the yeast RAD30 and the human XP-V genes, encoding DNA polymerase eta.     

Translesion replication by DNA polymerase delta depends on processivity accessory proteins and differs in specificity from DNA polymerase beta

Mutations caused by DNA damage lead to the development of cancer. The critical step in the formation of these mutations is the replication of unrepaired lesions in DNA by DNA polymerases, a process termed translesion replication. Using a newly developed method for preparation of gapped plasmids, containing a site-specific synthetic abasic site, we analyzed translesion replication with purified mammalian DNA polymerases delta and beta. DNA polymerase delta was found to be unable to replicate through the abasic site. Addition of the sliding DNA clamp PCNA, the clamp loader RFC, and ATP caused a drastic 30-fold increase in translesion replication. Thus, similar to Escherichia coli DNA polymerase III, the processivity accessory proteins enable DNA polymerase delta to bypass blocking lesions. Under comparable conditions, DNA polymerase beta was unable to bypass the abasic site, unless its concentration was greatly increased. Analysis of translesion replication products revealed a marked difference in the specificity of bypass: whereas 90% of bypass events by DNA polymerase delta holoenzyme involved insertion of a dAMP residue opposite the abasic site, DNA polymerase beta tended to skip over the abasic site, producing mainly minus frameshifts (73%). The significance of these results for in vivo translesion replication is discussed.     

DNA polymerase V and RecA protein, a minimal mutasome

A hallmark of the Escherichia coli SOS response is the large increase in mutations caused by translesion synthesis (TLS). TLS requires DNA polymerase V (UmuD'2C) and RecA. Here, we show that pol V and RecA interact by two distinct mechanisms. First, pol V binds to RecA in the absence of DNA and ATP and second, through its UmuD' subunit, requiring DNA and ATP without ATP hydrolysis. TLS occurs in the absence of a RecA nucleoprotein filament but is inhibited in its presence. Therefore, a RecA nucleoprotein filament is unlikely to be required for SOS mutagenesis. Pol V activity is severely diminished in the absence of RecA or in the presence of RecA1730, a mutant defective for pol V mutagenesis in vivo. Pol V activity is strongly enhanced with RecA mutants constitutive for mutagenesis in vivo, suggesting that RecA is an obligate accessory factor that activates pol V for SOS mutagenesis.     

Roles of the Escherichia coli RecA protein and the global SOS response in effecting DNA polymerase selection in vivo

The Escherichia coli beta sliding clamp protein is proposed to play an important role in effecting switches between different DNA polymerases during replication, repair, and translesion DNA synthesis. We recently described how strains bearing the dnaN159 allele, which encodes a mutant form of the beta clamp (beta159), display a UV-sensitive phenotype that is suppressed by inactivation of DNA polymerase IV (M. D. Sutton, J. Bacteriol. 186:6738-6748, 2004). As part of an ongoing effort to understand mechanisms of DNA polymerase management in E. coli, we have further characterized effects of the dnaN159 allele on polymerase usage. Three of the five E.coli DNA polymerases (II, IV, and V) are regulated as part of the global SOS response. Our results indicate that elevated expression of the dinB-encoded polymerase IV is sufficient to result in conditional lethality of the dnaN159 strain. In contrast, chronically activated RecA protein, expressed from the recA730 allele, is lethal to the dnaN159 strain, and this lethality is suppressed by mutations that either mitigate RecA730 activity (i.e., DeltarecR), or impair the activities of DNA polymerase II or DNA polymerase V (i.e., DeltapolB or DeltaumuDC). Thus, we have identified distinct genetic requirements whereby each of the three different SOS-regulated DNA polymerases are able to confer lethality upon the dnaN159 strain, suggesting the presence of multiple mechanisms by which the actions of the cell's different DNA polymerases are managed in vivo.     

Stationary phase induction of dnaN and recF, two genes of Escherichia coli involved in DNA replication and repair.

The beta subunit of DNA polymerase III holoenzyme, the Escherichia coli chromosomal replicase, is a sliding DNA clamp responsible for tethering the polymerase to DNA and endowing it with high processivity. The gene encoding beta, dnaN, maps between dnaA and recF, which are involved in initiation of DNA replication at oriC and resumption of DNA replication at disrupted replication forks, respectively. In exponentially growing cells, dnaN and recF are expressed predominantly from the dnaA promoters. However, we have found that stationary phase induction of the dnaN promoters drastically changes the expression pattern of the dnaA operon genes. As a striking consequence, synthesis of the beta subunit and RecF protein increases when cell metabolism is slowing down. Such an induction is dependent on the stationary phase sigma factor, RpoS, although the accumulation of this factor alone is not sufficient to activate the dnaN promoters. These promoters are located in DNA regions without static bending, and the -35 hexamer element is essential for their RpoS-dependent induction. Our results suggest that stationary phase-dependent mechanisms have evolved in order to coordinate expression of dnaN and recF independently of the dnaA regulatory region. These mechanisms might be part of a developmental programme aimed at maintaining DNA integrity under stress conditions.     

Devoted to the lagging strand-the subunit of DNA polymerase III holoenzyme contacts SSB to promote processive elongation and sliding clamp assembly.

Escherichia coli DNA polymerase III holoenzyme contains 10 different subunits which assort into three functional components: a core catalytic unit containing DNA polymerase activity, the beta sliding clamp that encircles DNA for processive replication, and a multisubunit clamp loader apparatus called gamma complex that uses ATP to assemble the beta clamp onto DNA. We examine here the function of the psi subunit of the gamma complex clamp loader. Omission of psi from the holoenzyme prevents contact with single-stranded DNA-binding protein (SSB) and lowers the efficiency of clamp loading and chain elongation under conditions of elevated salt. We also show that the product of a classic point mutant of SSB, SSB-113, lacks strong affinity for psi and is defective in promoting clamp loading and processive replication at elevated ionic strength. SSB-113 carries a single amino acid replacement at the penultimate residue of the C-terminus, indicating the C-terminus as a site of interaction with psi. Indeed, a peptide of the 15 C-terminal residues of SSB is sufficient to bind to psi. These results establish a role for the psi subunit in contacting SSB, thus enhancing the clamp loading and processivity of synthesis of the holoenzyme, presumably by helping to localize the holoenzyme to sites of SSB-coated ssDNA.     

Arrest of cell division and nucleoid partition by genetic alterations in the sliding clamp of the replicase and in DnaA

In Escherichia coli, an interaction between the replication initiator DnaA and the sliding clamp protein, the beta subunit (DnaN) of DNA polymerase III, is required to regulate the chromosomal replication cycle. We report here that colony formation by, and cell division of, the temperature (42 degrees C)-sensitive dnaN59 mutant are inhibited at 34-35 degrees C when DnaA is moderately (4-to 8-fold ) overexpressed, although chromosomal replication and the beta subunit-dependent regulation of DnaA activity are not significantly inhibited. Immunoblotting analysis revealed that the beta subunit is abundant (present at a level of about 5000 dimers per cell) at 34 degrees C, and its concentration per unit cell volume was practically unaffected in the dnaN59 mutant by the overexpression of DnaA. The dnaN mutant cells that overexpress DnaA become filamentous at 34 degrees C via an sfiA-independent pathway, different from that activated by the SOS response. This filamentation is accompanied by inhibition of nucleoid partition and FtsZ ring formation. In the dnaN59 mutant, oversupply of DnaA may disturb the coordinated action of cell cycle-regulating molecules, thus leading to the inhibition of these events.     

A new model for SOS-induced mutagenesis: how RecA protein activates DNA polymerase V

In Escherichia coli, cell survival and genomic stability after UV radiation depends on repair mechanisms induced as part of the SOS response to DNA damage. The early phase of the SOS response is mostly dominated by accurate DNA repair, while the later phase is characterized with elevated mutation levels caused by error-prone DNA replication. SOS mutagenesis is largely the result of the action of DNA polymerase V (pol V), which has the ability to insert nucleotides opposite various DNA lesions in a process termed translesion DNA synthesis (TLS). Pol V is a low-fidelity polymerase that is composed of UmuD′₂C and is encoded by the umuDC operon. Pol V is strictly regulated in the cell so as to avoid genomic mutation overload. RecA nucleoprotein filaments (RecA*), formed by RecA binding to single-stranded DNA with ATP, are essential for pol V-catalyzed TLS both in vivo and in vitro. This review focuses on recent studies addressing the protein composition of active DNA polymerase V, and the role of RecA protein in activating this enzyme. Based on unforeseen properties of RecA*, we describe a new model for pol V-catalyzed SOS-induced mutagenesis.     

Defining the position of the switches between replicative and bypass DNA polymerases

Cells contain specialized DNA polymerases that are able to copy past lesions with an associated risk of generating mutations, the major cause of cancer. Here, we reconstitute translesion synthesis (TLS) using the replicative (Pol III) and major bypass (Pol V) DNA polymerases from Escherichia coli in the presence of accessory factors. When the replicative polymerase disconnects from the template in the vicinity of a lesion, Pol V binds the blocked replication intermediate and forms a stable complex by means of a dual interaction with the tip of the RecA filament and the beta-clamp, the processivity factor donated by the blocked Pol III holoenzyme. Both interactions are required to confer to Pol V the processivity that will allow it synthesize, in a single binding event, a TLS patch long enough to support further extension by Pol III. In the absence of these accessory factors, the patch synthesized by Pol V is too short, being degraded by the Pol III-associated exonuclease activity that senses the distortion induced by the lesion, thus leading to an aborted bypass process.