In vitro effects of a C4'-oxidized abasic site on DNA polymerases

Oxidative damage to DNA produces abasic sites resulting from the formal hydrolysis of the nucleotides' glycosidic bonds, along with a variety of oxidized abasic sites. The C4'-oxidized abasic site (C4-AP) is produced by several DNA-damaging agents. This lesion accounts for approximately 40% of the DNA damage produced by bleomycin. The effect of a C4'-oxidized abasic site incorporated at a defined site in a template was examined on Klenow fragments with and without 3' --> 5' exonuclease activity. Both enzymes preferentially incorporated dA > dG > dC, T opposite C4-AP. Neither enzyme is able to extend the primer past the lesion. Experiments with regular AP sites in an otherwise identical template indicate that Klenow does not differentiate between these two disparate abasic sites. Extension of the primer by alternative polymerases pol II, pol II exo(-), pol IV, and pol V was examined. Pol II exo(-) was most efficient. Qualitative translesion synthesis experiments showed that pol II exo(-) preferentially incorporates T opposite C4-AP, followed in order by dG, dA, and dC. Thymidine incorporation opposite C4'-AP is distinct from the pol II exonuclease interaction with a regular AP site in an otherwise identical template. These in vitro experiments suggest that bypass polymerases may play a crucial role in survival of cells in which C4-AP is produced, and unlike a typical AP site, the C4-AP lesion may not follow the "A-rule". The interaction between bypass polymerases and a C4-AP lesion could explain the high levels of G:C --> T:A transversions in cells treated with bleomycin.     

Frameshifts and deletions during in vitro translesion synthesis past Pt-DNA adducts by DNA polymerases beta and eta

DNA polymerases beta (pol beta ) and eta (pol eta ) are the only two eukaryotic polymerases known to efficiently bypass cisplatin and oxaliplatin adducts in vitro. Frameshift errors are an important aspect of mutagenesis. We have compared the types of frameshifts that occur during translesion synthesis past cisplatin and oxaliplatin adducts in vitro by pol beta and pol eta on a template containing multiple runs of nucleotides flanking a single platinum-GG adduct. Translesion synthesis past platinum adducts by pol beta resulted in approximately 50% replication products containing single-base deletions. For both adducts the majority of -1 frameshifts occurred in a TTT sequence 3-5 bp upstream of the DNA lesion. For pol eta, all of the bypass products for both cisplatin and oxaliplatin adducts contained -1 frameshifts in the upstream TTT sequence and most of the products of replication on oxaliplatin-damaged templates had multiple replication errors, both frameshifts and misinsertions. In addition, on platinated templates both polymerases generated replication products 4-8 bp shorter than the full-length products. The majority of short cisplatin-induced products contained an internal deletion which included the adduct. In contrast, the majority of oxaliplatin-induced short products contained a 3' terminal deletion. The implications of these in vitro results for in vivo mutagenesis are discussed.     

DNA polymerase V allows bypass of toxic guanine oxidation products in vivo

Reactive oxygen and nitrogen radicals produced during metabolic processes, such as respiration and inflammation, combine with DNA to form many lesions primarily at guanine sites. Understanding the roles of the polymerases responsible for the processing of these products to mutations could illuminate molecular mechanisms that correlate oxidative stress with cancer. Using M13 viral genomes engineered to contain single DNA lesions and Escherichia coli strains with specific polymerase (pol) knockouts, we show that pol V is required for efficient bypass of structurally diverse, highly mutagenic guanine oxidation products in vivo. We also find that pol IV participates in the bypass of two spiroiminodihydantoin lesions. Furthermore, we report that one lesion, 5-guanidino-4-nitroimidazole, is a substrate for multiple SOS polymerases, whereby pol II is necessary for error-free replication and pol V for error-prone replication past this lesion. The results spotlight a major role for pol V and minor roles for pol II and pol IV in the mechanism of guanine oxidation mutagenesis.     

Mutagenic effects of 2-deoxyribonolactone in Escherichia coli. An abasic lesion that disobeys the A-rule

Abasic sites are often referred to as noninstructive lesions. The C1'-oxidized abasic site (2-deoxyribonolactone, L) is produced by several DNA damaging agents, including gamma-radiolysis and the neocarzinostatin chromophore (NCS). The effects of a C1'-oxidized abasic site incorporated at a defined site in single-stranded plasmid were examined in SOS polymerase-proficient and -deficient Escherichia coli. For comparison, experiments utilizing plasmids containing an abasic site (AP) were carried out side by side. In contrast to plasmid containing AP, dA and dG were incorporated most often when plasmid containing L was replicated. The ratio of dG:dA incorporation depended upon local sequence and varied from 0.9 to 2.2. High levels of translesion incorporation of dA are consistent with previous observations that treatment of DNA with the neocarzinostatin chromophore resulted in large amounts of G.C --> A.T transitions [Povirk and Goldberg (1986) Nucleic Acids Res. 14, 1417] and support the proposal that L is the source of these mutations. Both abasic lesions were 100% lethal in triple knockout cells lacking pol II, pol IV, and pol V. Analysis of translesion synthesis in repair-deficient cells revealed that pol V played a significant role in replication of L and AP. Significant levels of -1 frameshifts were formed in 5'-d(CL) sequences in the presence of pol V and were the exclusive product in pol V-deficient cells. Frameshift products were not formed when the nucleotide on the 5'-side of L was either dT or dG. Deleting pol II or pol IV had only modest effects on replication of L-containing plasmid but significantly decreased the amount of -1 frameshift product formed from an AP lesion. Experiments carried out side by side using otherwise identical plasmids containing an AP site illustrate the distinct properties of these two abasic lesions and that neither should be thought of as noninstructive.     

In vitro replication and repair of DNA containing a C2'-oxidized abasic site

Abasic lesions are unable to form Watson-Crick hydrogen bonds with nucleotides. Nonetheless, polymerase and repair enzymes distinguish between various oxidized abasic lesions, as well as from nonoxidized abasic sites (AP). The C2-AP lesion is produced when DNA is exposed to gamma-radiolysis. Its effects on polymerases and repair enzymes are unknown. A recently reported method for the chemical synthesis of oligonucleotides containing C2-AP at a defined site was utilized for studying the activity of Klenow exo(-) and repair enzymes on templates containing the lesion. The C2-AP lesion has a similar effect on Klenow exo(-) as do AP and C4-AP sites. Deoxyadenosine is preferentially incorporated opposite C2-AP, but extension of the primer past the lesion is strongly blocked. C2-AP is incised less efficiently by exonuclease III and endonuclease IV than are other abasic lesions. Furthermore, although a Schiff base between C2-AP and endonuclease III can be chemically trapped, the location of the 3'-phosphate alpha with respect to the aldehyde prevents beta-elimination associated with the lyase activity of type I base excision repair enzymes. The interactions of the C2'-oxidized abasic site with Klenow exo(-) and repair enzymes suggest that the lesion will be mutagenic and that it will be removed by strand displacement synthesis and flap endonuclease processing via a long patch repair mechanism.     

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.     

Sloppy bypass of an abasic lesion catalyzed by a Y-family DNA polymerase

DNA damage that eludes cellular repair pathways can arrest the replication machinery and stall the cell cycle. However, this damage can be bypassed by the Y-family DNA polymerases. Here, Dpo4, an archetypal Y-family member from the thermophilic Sulfolobus solfataricus, was used to extend our kinetic studies of the bypass of an abasic site, one of the most mutagenic and ubiquitous cellular lesions. A short oligonucleotide sequencing assay is developed to directly sequence DNA bypass products synthesized by Dpo4. Our results show that incorporation upstream of the abasic lesion is replicated error-free; yet dramatically, once Dpo4 encounters the lesion, synthesis became sloppy, with bypass products containing a myriad of mutagenic events. Incorporation of dAMP (29%) and dCMP (53%) opposite the abasic lesion at 37 degrees C correlates exceptionally well with our kinetic results and demonstrates two dominant bypass pathways via the A-rule and the lesion loop-out mechanism. Interestingly, the percentage of overall frameshift mutations increased from 71 (37 degrees C) to 87% (75 degrees C). Further analysis indicates that lesion bypass via the A-rule is strongly preferred over the lesion loop-out mechanism at higher temperatures and concomitantly reduces the occurrence of "-1 deletion" mutations observed opposite the lesion at lower temperatures. The bypass percentage via the latter pathway is confirmed by an enzymatic digestion assay, verifying the reliability of our sequencing assay. Our results demonstrate that an abasic lesion causes Dpo4 and possibly all Y-family members to switch from a normal to a very mutagenic mode of replication.     

Repair of oxidized abasic sites by exonuclease III, endonuclease IV, and endonuclease III

2-Deoxyribonolactone (L) and the C4'-oxidized abasic site (C4-AP) are produced by a variety of DNA-damaging agents. If not repaired, these lesions can be mutagenic. Exonuclease III and endonuclease IV are the major enzymes in E. coli responsible for 5'-incision of abasic sites (APs), the first steps in AP repair. Endonuclease III efficiently excises AP lesions via intermediate Schiff-base formation. Incision of L and C4-AP lesions by exonuclease III and endonuclease IV was determined under steady-state conditions using oligonucleotide duplexes containing the lesions at defined sites. An abasic lesion (AP) in an otherwise identical DNA sequence was incised by exonuclease III or endonuclease IV approximately 6-fold more efficiently than either of the oxidized abasic sites (L, C4-AP). Endonuclease IV incision efficiency of 2-deoxyribonolactone or C4-AP was independent of whether the lesion was opposite dA or dG. 2-Deoxyribonolactone is known to cross-link to endonuclease III (Hashimoto, M. (2001) J. Am. Chem. Soc. 123, 3161.). However, the C4-AP lesion is efficiently excised by endonuclease III. Oxidized abasic site repair by endonuclease IV and endonuclease III (C4-AP only) is approximately 100-fold less efficient than repair by exonuclease III. These results suggest that the first step of C4-AP and L oxidized abasic site repair will be the same as that of regular AP lesions in E. coli.     

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

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

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.     

Genetic requirement for mutagenesis of the G[8,5-Me]T cross-link in Escherichia coli: DNA polymerases IV and V compete for error-prone bypass

γ-Radiation generates a variety of complex lesions in DNA, including the G[8,5-Me]T intrastrand cross-link in which C8 of guanine is covalently linked to the 5-methyl group of the 3'-thymine. We have investigated the toxicity and mutagenesis of this lesion by replicating a G[8,5-Me]T-modified plasmid in Escherichia coli with specific DNA polymerase knockouts. Viability was very low in a strain lacking pol II, pol IV, and pol V, the three SOS-inducible DNA polymerases, indicating that translesion synthesis is conducted primarily by these DNA polymerases. In the single-polymerase knockout strains, viability was the lowest in a pol V-deficient strain, which suggests that pol V is most efficient in bypassing this lesion. Most mutations were single-base substitutions or deletions, though a small population of mutants carrying two point mutations at or near the G[8,5-Me]T cross-link was also detected. Mutations in the progeny occurred at the cross-linked bases as well as at bases near the lesion site, but the mutational spectrum varied on the basis of the identity of the DNA polymerase that was knocked out. Mutation frequency was the lowest in a strain that lacked the three SOS DNA polymerases. We determined that pol V is required for most targeted G → T transversions, whereas pol IV is required for the targeted T deletions. Our results suggest that pol V and pol IV compete to carry out error-prone bypass of the G[8,5-Me]T cross-link.     

NGS-based analysis of base-substitution signatures created by yeast DNA polymerase eta and zeta on undamaged and abasic DNA templates in vitro

Translesion synthesis (TLS) is the mechanism in which DNA polymerases (TLS polymerases) bypass unrepaired template damage with high error rates. DNA polymerase η and ζ (Polη and Polζ) are major TLS polymerases that are conserved from yeast to humans. In this study, we quantified frequencies of base-substitutions by yeast Polη and Polζ on undamaged and abasic templates in vitro. For accurate quantification, we used a next generation sequencing (NGS)-based method where DNA products were directly analyzed by parallel sequencing. On undamaged templates, Polη and Polζ showed distinct base-substitution profiles, and the substitution frequencies were differently influenced by the template sequence. The base-substitution frequencies were influenced mainly by the adjacent bases both upstream and downstream of the substitution sites. Thus we present the base-substitution signatures of these polymerases in a three-base format. On templates containing abasic sites, Polη created deletions at the lesion in more than 50% of the TLS products, but the formation of the deletions was suppressed by the presence of Polζ. Polζ and Polη cooperatively facilitated the TLS reaction over an abasic site in vitro, suggesting that these two polymerases can cooperate in efficient and high fidelity TLS.     

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.     

The essential C family DnaE polymerase is error-prone and efficient at lesion bypass

DnaE-type DNA polymerases belong to the C family of DNA polymerases and are responsible for chromosomal replication in prokaryotes. Like most closely related Gram-positive cells, Streptococcus pyogenes has two DnaE homologs Pol C and DnaE; both are essential to cell viability. Pol C is an established replicative polymerase, and DnaE has been proposed to serve a replicative role. In this report, we characterize S. pyogenes DnaE polymerase and find that it is highly error-prone. DnaE can bypass coding and noncoding lesions with high efficiency. Error-prone extension is accomplished by either of two pathways, template-primer misalignment or direct primer extension. The bypass of abasic sites is accomplished mainly through "dNTP-stabilized" misalignment of template, thereby generating (-1) deletions in the newly synthesized strand. This mechanism may be similar to the dNTP-stabilized misalignment mechanism used by the Y family of DNA polymerases and is the first example of lesion bypass and error-prone synthesis catalyzed by a C family polymerase. Thus, DnaE may function in an error-prone capacity that may be essential in Gram-positive cells but not Gram-negative cells, suggesting a fundamental difference in DNA metabolism between these two classes of bacteria.     

Translesion Synthesis of Abasic Sites by Yeast DNA Polymerase ?

Studies of replicative DNA polymerases have led to the generalization that abasic sites are strong blocks to DNA replication. Here we show that yeast replicative DNA polymerase ϵ bypasses a model abasic site with comparable efficiency to Pol η and Dpo4, two translesion polymerases. DNA polymerase ϵ also exhibited high bypass efficiency with a natural abasic site on the template. Translesion synthesis primarily resulted in deletions. In cases where only a single nucleotide was inserted, dATP was the preferred nucleotide opposite the natural abasic site. In contrast to translesion polymerases, DNA polymerase ϵ with 3′–5′ proofreading exonuclease activity bypasses only the model abasic site during processive synthesis and cannot reinitiate DNA synthesis. This characteristic may allow other pathways to rescue leading strand synthesis when stalled at an abasic site.     

Inactivation of the 3'-5' exonuclease of the replicative T4 DNA polymerase allows translesion DNA synthesis at an abasic site

Here, we have investigated the consequences of the loss of proof-reading exonuclease function on the ability of the replicative T4 DNA polymerase (gp43) to elongate past a single abasic site located on model DNA substrates. Our results show that wild-type T4 DNA polymerase stopped at the base preceding the lesion on two linear substrates having different sequences, whereas the gp43 D219A exonuclease-deficient mutant was capable of efficient bypass when replicating the same substrates. The structure of the DNA template did not influence the behavior of the exonuclease-proficient or deficient T4 DNA polymerases. In fact, when replicating a damaged "minicircle" DNA substrate constructed by circularizing one of the linear DNA, elongation by wild-type enzyme was still completely blocked by the abasic site, while the D219A mutant was capable of bypass. During DNA replication, the T4 DNA polymerase associates with accessory factors whose combined action increases the polymerase-binding capacity and processivity, and could modulate the behavior of the enzyme towards an abasic site. We thus performed experiments measuring the ability of wild-type and exonuclease-deficient T4 DNA polymerases, in conjunction with these replicative accessory proteins, to perform translesion DNA replication on linear or circular damaged DNA substrates. We found no evidence of either stimulation or inhibition of the bypass activities of the wild-type and exonuclease-deficient forms of T4 DNA polymerase following addition of the accessory factors, indicating that the presence or absence of the proof-reading activity is the major determinant in dictating translesion synthesis of an abasic site by T4 DNA polymerase.     

Efficiency and accuracy of SOS-induced DNA polymerases replicating benzo[a]pyrene-7,8-diol 9,10-epoxide A and G adducts.

Nucleotide incorporation fidelity, mismatch extension, and translesion DNA synthesis efficiencies were determined using SOS-induced Escherichia coli DNA polymerases (pol) II, IV, and V to copy 10R and 10S isomers of trans-opened benzo[a]pyrene-7,8-diol 9,10-epoxide (BaP DE) A and G adducts. A-BaP DE adducts were bypassed by pol V with moderate accuracy and considerably higher efficiency than by pol II or IV. Error-prone pol V copied G-BaP DE-adducted DNA poorly, forming A*G-BaP DE-S and -R mismatches over C*G-BaP DE-S and -R correct matches by factors of approximately 350- and 130-fold, respectively, even favoring G*G-BaP DE mismatches over correct matches by factors of 2-4-fold. In contrast, pol IV bypassed G-BaP DE adducts with the highest efficiency and fidelity, making misincorporations with a frequency of 10(-2) to 10(-4) depending on sequence context. G-BaP DE-S-adducted M13 DNA yielded 4-fold fewer plaques when transfected into SOS-induced DeltadinB (pol IV-deficient) mutant cells compared with the isogenic wild-type E. coli strain, consistent with the in vitro data showing that pol IV was most effective by far at copying the G-BaP DE-S adduct. SOS polymerases are adept at copying a variety of lesions, but the relative contribution of each SOS polymerase to copying damaged DNA appears to be determined by the lesion's identity.     

In vitro gap-directed translesion DNA synthesis of an abasic site involving human DNA polymerases epsilon, lambda, and beta

DNA polymerase (pol) ε is thought to be the leading strand replicase in eukaryotes, whereas pols λ and β are believed to be mainly involved in re-synthesis steps of DNA repair. DNA elongation by the human pol ε is halted by an abasic site (apurinic/apyrimidinic (AP) site). In this study, we present in vitro evidence that human pols λ, β, and η can perform translesion synthesis (TLS) of an AP site in the presence of pol ε, likely by initiating the 3'OHs created at the lesion by the arrested pol ε. However, in the case of pols λ and β, this TLS requires the presence of a DNA gap downstream from the product synthesized by the pol ε, and the optimal gap for efficient TLS is different for the two polymerases. The presence of gaps did not affect the TLS capacity of human pol η. Characterization of the reaction products showed that pol β inserted dAMP opposite the AP site, whereas gap filling synthesis by pol λ resulted in single or double deletions opposite the lesion. The synthesis up to the AP site by pol ε and the subsequent TLS by pols λ and β are not influenced by human processivity factor proliferating cell nuclear antigen and human single-stranded DNA-binding protein replication protein A. The bypass capacity of pol λ at the AP site is greatly reduced when a truncated form of the enzyme, which has lost the BRCA1 C-terminal and proline-rich domains, is used. Collectively, our in vitro results support the existence of a mechanism of gap-directed TLS at an AP site involving a switch between the replicative pol ε and the repair pols λ and β.     

Roles of replicative and specialized DNA polymerases in frameshift mutagenesis: mutability of Salmonella typhimurium strains lacking one or all of SOS-inducible DNA polymerases to 26 chemicals

Progression of DNA replication is occasionally blocked by endogenous and exogenous DNA damage. To circumvent the stalling of DNA replication, cells possess a variety of specialized DNA polymerases that replicate through DNA damage. Salmonella typhimurium strain TA1538 has six DNA polymerases and four of them are encoded by damage-inducible SOS genes, i.e. polB(ST) (pol II), dinB(ST) (pol IV), umuDC(ST) (pol V) and samAB. The strain has been used for the detection of a variety of chemical mutagens because of the high sensitivity to -2 frameshift occurring in CGCGCGCG sequence. To assign the role of each DNA polymerase in the frameshift mutagenesis, we have constructed the derivatives lacking one or all of SOS-inducible DNA polymerases and examined the mutability to 26 chemical mutagens. Interestingly, the chemicals could be categorized into four classes: class I whose mutagenicity was reduced by the deletion of dinB(ST) (1-aminoanthracene and other four chemicals); class II whose mutagenicity was reduced by the deletion of either dinB(ST) or umuDC(ST) plus samAB (7,12-dimethylbenz[a]anthracene and other three chemicals); class III whose mutagenicity largely depended on the presence of umuDC(ST) plus samAB (1-N-6-azabenzo[a]pyrene and other three chemicals) and class IV whose mutagenicity was not reduced by deletion of any of the genes encoding SOS-inducible DNA polymerases (Glu-P-1 and other 12 chemicals). Deletion of polB(ST) reduced by 30-60% the mutagenicity of six chemicals of classes II and III. These results suggest that multiple DNA polymerases including the replicative DNA polymerase, i.e. DNA polymerase III holoenzyme, play important roles in chemically induced -2 frameshift and also that different sets of DNA polymerases are engaged in the translesion bypass of different DNA lesions.