Crystal structure of a Y-family DNA polymerase in action: a mechanism for error-prone and lesion-bypass replication

Expression and possible functions of DNA lesion bypass proteins in spermatogenesis

In mammalian cells, there is a complex interplay of different DNA damage response and repair mechanisms. Several observations suggest that, in particular in gametogenesis, proteins involved in DNA repair play an intricate role in and outside the context of DNA repair. Here, we discuss the possible roles of proteins that take part in replicative damage bypass (RDB) mechanisms, also known as post-replication DNA repair (PRR), in germ line development. In yeast, and probably also in mammalian somatic cells, RDB [two subpathways: damage avoidance and translesion synthesis (TLS)] prevents cessation of replication forks during the S phase of the cell cycle, in situations when the replication machinery encounters a lesion present in the template DNA. Many genes encoding proteins involved in RDB show an increased expression in testis, in particular in meiotic and post-meiotic spermatogenic cells. Several RDB proteins take part in protein ubiquitination, and we address relevant aspects of the ubiquitin system in spermatogenesis. RDB proteins might be required for damage avoidance and TLS of spontaneous DNA damage during gametogenesis. In addition, we consider the possible functional relation between TLS and the induction of mutations in spermatogenesis. TLS requires the activity of highly specialized polymerases, and is an error-prone process that may induce mutations. In evolutionary terms, controlled generation of a limited number of mutations in gametogenesis might provide a mechanism for evolvability.

How are specialized (low-fidelity) eukaryotic polymerases selected and switched with high-fidelity polymerases during translesion DNA synthesis?

Specialized DNA polymerases are required in both prokaryotic and eukaryotic cells for bypassing sites of template DNA damage that arrest high-fidelity DNA replication. Recent studies in the literature provide hints of the complexity of DNA switching between polymerases for translesion DNA synthesis (TLS) and those for normal DNA replication.

Structural insights into DNA polymerase beta deterrents for misincorporation support an induced-fit mechanism for fidelity

DNA polymerases generally select the correct nucleotide from a pool of structurally similar molecules to preserve Watson-Crick base-pairing rules. We report the structure of DNA polymerase beta with DNA mismatches situated in the polymerase active site. This was achieved by using nicked product DNA that traps the mispair (template-primer, A-C or T-C) in the nascent base pair binding pocket. The structure of each mispair complex indicates that the bases do not form hydrogen bonds with one another, but form a staggered arrangement where the bases of the mispair partially overlap. This prevents closure/opening of the N subdomain that is believed to be required for catalytic cycling. The partially open conformation of the N subdomain results in distinct hydrogen bonding networks that are unique for each mispair. These structures define diverse molecular aspects of misinsertion that are consistent with the induced-fit model for substrate specificity.

Portraits of a Y-family DNA polymerase

Members of the Y-family of DNA polymerases catalyze template-dependent DNA synthesis but share no sequence homology with other known DNA polymerases. Y-family polymerases exhibit high error rates and low processivity when copying normal DNA but are able to synthesize DNA opposite damaged templates. In the past three years, much has been learned about this family of polymerases including determination of more than a dozen crystal structures with various substrates. In this short review, I will summarize the biochemical properties and structural features of Y-family DNA polymerases.

Mutagenesis studies of the major benzo[a]pyrene N2-dG adduct in a 5'-TG versus a 5'-UG sequence: removal of the methyl group causes a modest decrease in the [G->T/G->A] mutational ratio

The potent mutagen/carcinogen benzo[a]pyrene (B[a]P) is metabolically activated to (+)-anti-B[a]PDE, which induces a full spectrum of mutations primarily at the G:C base pairs (e.g. GC-->TA, GC-->AT, etc.). Each of these mutations can be induced by its major adduct [+ta]-B[a]P-N(2)-dG, where DNA sequence context appears to influence both the quantitative and qualitative pattern of mutagenesis. We noted previously that 5'-TG sequences tend to have a higher fraction of G-->T mutations for both [+ta]-B[a]P-N(2)-dG and (+)-anti-B[a]PDE in comparison with 5'-CG, 5'-GG or 5'-AG sequences. To investigate a possible structural element for this trend, the role (if any) of the methyl group on the 5'-T is considered. Using adduct site-specific means, the [G-->T/G-->A] mutational ratio for [+ta]-B[a]P-N(2)-dG is determined to be approximately 1.08 in a 5'-TGT sequence, and approximately 0.60 in a 5'-UGT sequence. (G-->C mutations are minor.) Although this modest approximately 1.8-fold decrease in [G-->T/G-->A] ratio is statistically significant (P = 0.03), it suggests that the methyl group on the 5'-T is not the main reason why a 5'-T tends to enhance G-->T mutations. This study was prompted by an adduct conformational hypothesis, which predicted that the removal of the methyl group in a 5'-TG sequence would lower the fraction of G-->T mutations; however, the approximately 1.8-fold decrease is too small to do additional experiments to assess whether this conformational hypothesis, or other hypotheses, are the true cause of the decrease, which is discussed in this paper.

The crystal structure of the monomeric reverse transcriptase from Moloney murine leukemia virus

Reverse transcriptases (RTs) are multidomain enzymes of variable architecture that couple both RNA- and DNA-directed DNA polymerase activities with an RNase H activity specific for an RNA:DNA hybrid in order to replicate the single-stranded RNA genome of the retrovirus. Previous structural work has been reported for the heterodimeric HIV-1 and HIV-2 RTs. We now report the first crystal structure of the full-length Moloney murine leukemia virus (MMLV) RT at 3.0 A resolution. The structure reveals a clamp-shaped molecule resulting from the relative positions of the thumb, connection, and RNase H domains that is strikingly different from the HIV-1 RT and provides the first example of a monomeric reverse transcriptase. A comparative analysis with related DNA polymerases suggests a unique trajectory for the template-primer exiting the polymerase active site and provides insights regarding processive DNA synthesis by MMLV RT.

Highly organized but pliant active site of DNA polymerase beta: compensatory mechanisms in mutant enzymes revealed by dynamics simulations and energy analyses

To link conformational transitions noted for DNA polymerases with kinetic results describing catalytic efficiency and fidelity, we investigate the role of key DNA polymerase beta residues on subdomain motion through simulations of five single-residue mutants: Arg-283-Ala, Tyr-271-Ala, Asp-276-Val, Arg-258-Lys, and Arg-258-Ala. Since a movement toward a closed state was only observed for R258A, we suggest that Arg(258) is crucial in modulating motion preceding chemistry. Analyses of protein/DNA interactions in the mutant active site indicate distinctive hydrogen bonding and van der Waals patterns arising from compensatory structural adjustments. By comparing closed mutant complexes with the wild-type enzyme, we interpret experimentally derived nucleotide binding affinities in molecular terms: R283A (decreased), Y271A (increased), D276V (increased), and R258A (decreased). Thus, compensatory interactions (e.g., in Y271A with adjacent residues Phe(272), Asn(279), and Arg(283)) increase the overall binding affinity for the incoming nucleotide although direct interactions may decrease. Together with energetic analyses, we predict that R258G might increase the rate of nucleotide insertion and maintain enzyme fidelity as R258A; D276L might increase the nucleotide binding affinity more than D276V; and R283A/K280A might decrease the nucleotide binding affinity and increase misinsertion more than R283A. The combined observations regarding key roles of specific residues (e.g., Arg(258)) and compensatory interactions echo the dual nature of polymerase active site, namely versatility (to accommodate various basepairs) and specificity (for preserving fidelity) and underscore an organized but pliant active site essential to enzyme function.

Crystal structure of the catalytic core of human DNA polymerase kappa

We present the crystal structure of the catalytic core of human DNA polymerase kappa (hPolkappa), the first structure of a human Y-family polymerase. hPolkappa is implicated in the proficient extension of mispaired primer termini on undamaged DNAs, and in the extension step of lesion bypass. The structure reveals a stubby "fingers" subdomain, which despite its small size appears to be tightly restrained with respect to a putative templating base. The structure also reveals a novel "thumb" subdomain that provides a basis for the importance of the N-terminal extension unique to hPolkappa. And, most surprisingly, the structure reveals the polymerase-associated domain (PAD) juxtaposed on the dorsal side of the "palm" subdomain, as opposed to the fingers subdomain. Together, these properties suggest that the hPolkappa active site is constrained at the site of the templating base and incoming nucleotide, but the polymerase is less constrained following translocation of the lesion.

Structure and mechanism of DNA polymerases

DNA polymerases are molecular motors directing the synthesis of DNA from nucleotides. All polymerases have a common architectural framework consisting of three canonical subdomains termed the fingers, palm, and thumb subdomains. Kinetically, they cycle through various states corresponding to conformational transitions, which may or may not generate force. In this review, we present and discuss the kinetic, structural, and single-molecule works that have contributed to our understanding of DNA polymerase function.

On the role of proofreading exonuclease in bypass of a 1,2 d(GpG) cisplatin adduct by the herpes simplex virus-1 DNA polymerase

UL30, the herpes simplex virus type-1 DNA polymerase, stalls at the base preceding a cisplatin crosslinked 1,2 d(GpG) dinucleotide and engages in a futile cycle of incorporation and excision by virtue of its 3'-5' exonuclease. Therefore, we examined the translesion synthesis (TLS) potential of an exonuclease-deficient UL30 (UL30D368A). We found that UL30D368A did not perform complete translesion synthesis but incorporated one nucleotide opposite the first base of the adduct. This addition was affected by the propensity of the enzyme to dissociate from the damaged template. Consequently, addition of the polymerase processivity factor, UL42, increased nucleotide incorporation opposite the lesion. The addition of Mn(2+), which was previously shown to support translesion synthesis by wild-type UL30, also enabled limited bypass of the adduct by UL30D368A. We show that the primer terminus opposite the crosslinked d(GpG) dinucleotide and at least three bases downstream of the lesion is unpaired and not extended by the enzyme. These data indicate that the primer terminus opposite the lesion may be sequestered into the exonuclease site of the enzyme. Consequently, elimination of exonuclease activity alone, without disrupting binding, is insufficient to permit bypass of a bulky lesion by this enzyme.

Proliferating Cell Nuclear Antigen-dependent Coordination of the Biological Functions of Human DNA Polymerase ι

Y-family DNA polymerases are believed to facilitate the replicative bypass of damaged DNA in a process commonly referred to as translesion synthesis. With the exception of DNA polymerase eta (poleta), which is defective in humans with the Xeroderma pigmentosum variant (XP-V) phenotype, little is known about the cellular function(s) of the remaining human Y-family DNA polymerases. We report here that an interaction between human DNA polymerase iota (poliota) and the proliferating cell nuclear antigen (PCNA) stimulates the processivity of poliota in a template-dependent manner in vitro. Mutations in one of the putative PCNA-binding motifs (PIP box) of poliota or the interdomain connector loop of PCNA diminish the binding between poliota and PCNA and concomitantly reduce PCNA-dependent stimulation of poliota activity. Furthermore, although retaining its capacity to interact with poleta in vivo, the poliota-PIP box mutant fails to accumulate in replication foci. Thus, PCNA, acting as both a scaffold and a modulator of the different activities involved in replication, appears to recruit and coordinate replicative and translesion DNA synthesis polymerases to ensure genome integrity.

Insights into Strand Displacement and Processivity from the Crystal Structure of the Protein-Primed DNA Polymerase of Bacteriophage φ29

The DNA polymerase from phage phi29 is a B family polymerase that initiates replication using a protein as a primer, attaching the first nucleotide of the phage genome to the hydroxyl of a specific serine of the priming protein. The crystal structure of phi29 DNA polymerase determined at 2.2 A resolution provides explanations for its extraordinary processivity and strand displacement activities. Homology modeling suggests that downstream template DNA passes through a tunnel prior to entering the polymerase active site. This tunnel is too small to accommodate double-stranded DNA and requires the separation of template and nontemplate strands. Members of the B family of DNA polymerases that use protein primers contain two sequence insertions: one forms a domain not previously observed in polymerases, while the second resembles the specificity loop of T7 RNA polymerase. The high processivity of phi29 DNA polymerase may be explained by its topological encirclement of both the downstream template and the upstream duplex DNA.

Switching from high-fidelity replicases to low-fidelity lesion-bypass polymerases

Replication of damaged DNA often requires a DNA polymerase in addition to the cell's normal replicase. Recent research has begun to shed light on the switch from a high-fidelity replicative polymerase to a low-fidelity translesion polymerase that occurs at a stalled replication fork. A picture is emerging in which eukaryotic replicative clamps are posttranslationally modified by ubiquitination, SUMOylation or phosphorylation. It is believed that such modifications help to regulate the access of translesion polymerases to the nascent primer terminus.

In Vivo Bypass Efficiencies and Mutational Signatures of the Guanine Oxidation Products 2-Aminoimidazolone and 5-Guanidino-4-nitroimidazole

The in vivo mutagenic properties of 2-aminoimidazolone and 5-guanidino-4-nitroimidazole, two products of peroxynitrite oxidation of guanine, are reported. Two oligodeoxynucleotides of identical sequence, but containing either 2-aminoimidazolone or 5-guanidino-4-nitroimidazole at a specific site, were ligated into single-stranded M13mp7L2 bacteriophage genomes. Wild-type AB1157 Escherichia coli cells were transformed with the site-specific 2-aminoimidazolone- and 5-guanidino-4-nitroimidazole-containing genomes, and analysis of the resulting progeny phage allowed determination of the in vivo bypass efficiencies and mutational signatures of the DNA lesions. 2-Aminoimidazolone was efficiently bypassed and 91% mutagenic, producing almost exclusively G to C transversion mutations. In contrast, 5-guanidino-4-nitroimidazole was a strong block to replication and 50% mutagenic, generating G to A, G to T, and to a lesser extent, G to C mutations. The G to A mutation elicited by 5-guanidino-4-nitroimidazole implicates this lesion as a novel source of peroxynitrite-induced transition mutations in vivo. For comparison, the error-prone bypass DNA polymerases were overexpressed in the cells by irradiation with UV light (SOS induction) prior to transformation. SOS induction caused little change in the efficiency of DNA polymerase bypass of 2-aminoimidazolone; however, bypass of 5-guanidino-4-nitroimidazole increased nearly 10-fold. Importantly, the mutation frequencies of both lesions decreased during replication in SOS-induced cells. These data suggest that 2-aminoimidazolone and 5-guanidino-4-nitroimidazole in DNA are substrates for one or more of the SOS-induced Y-family DNA polymerases and demonstrate that 2-aminoimidazolone and 5-guanidino-4-nitroimidazole are potent sources of mutations in vivo.

Structural Insights into the Catalytic Mechanism of Phosphate Ester Hydrolysis by dUTPase

dUTPase is essential to keep uracil out of DNA. Crystal structures of substrate (dUTP and alpha,beta-imino-dUTP) and product complexes of wild type and mutant dUTPases were determined to reveal how an enzyme responsible for DNA integrity functions. A kinetic analysis of wild type and mutant dUTPases was performed to obtain relevant mechanistic information in solution. Substrate hydrolysis is shown to be initiated via in-line nucleophile attack of a water molecule oriented by an activating conserved aspartate residue. Substrate binding in a catalytically competent conformation is achieved by (i) multiple interactions of the triphosphate moiety with catalysis-assisting Mg2+, (ii) a concerted motion of residues from three conserved enzyme motifs as compared with the apoenzyme, and (iii) an intricate hydrogen-bonding network that includes several water molecules in the active site. Results provide an understanding for the catalytic role of conserved residues in dUTPases.

Crystal structure of the Pyrococcus horikoshii DNA primase-UTP complex: implications for the mechanism of primer synthesis

BACKGROUND

In chromosomal DNA replication, DNA primase initiates the synthesis of a dinucleotide on a single-stranded template DNA, and elongates it to form a primer RNA for the replicative DNA polymerase. Although the apo-structure of an archaeal primase has been reported, the mechanism of primer synthesis by the eukaryotic-type primase still remains to be elucidated.

RESULTS

In this study, we present the crystal structure of the eukaryotic-type DNA primase from the hyperthermophilic archaeon (Pyrococcus horikoshii) with the uridine 5'-triphosphate (UTP). In the present primase-UTP complex, the primase binds the triphosphate moiety of the UTP at the active site, which includes Asp95, Asp97, and Asp280, the essential residues for the nucleotidyl transfer reaction.

CONCLUSION

The nucleotide binding geometry in this complex explains the previous biochemical analyses of the eukaryotic primase. Based on the complex structure, we constructed a model between the DNA primase and a primer/template DNA for the primer synthesis. This model facilitates the comprehension of the reported features of DNA primase.

Stereochemical Features of Lewis Acid-Promoted Glycosidations Involving 4‘-Spiroannulated DNA Building Blocks

Tin tetrachloride-catalyzed glycosidation of persilylated nucleobases with acetate donor 6 in CH(2)Cl(2) solution followed by deprotection gave rise very predominantly to alpha-spironucleosides. These stereochemical assignments stem from the determination of NOE interactions and an X-ray crystallographic analysis of the latter product. Computational studies revealed that these results are consistent with the fact that the C5' substituent shields the beta-face of the oxonium ion involved in the coupling reaction while the C3' substituent is projected away from the alpha-underside. Attack from the more open direction is therefore kinetically favored. Entirely comparable calculations suggested that donor 19 should behave comparably. Experimentation involving this donor gave results consistent with this model although more equitable alpha/beta spironucleoside product ratios were seen when acetonitrile was employed as the reaction medium.

To slip or skip, visualizing frameshift mutation dynamics for error-prone DNA polymerases

Three models describing frameshift mutations are "classical" Streisinger slippage, proposed for repetitive DNA, and "misincorporatation misalignment" and "dNTP-stabilized misalignment," proposed for non-repetitive DNA. We distinguish between models using pre-steady state fluorescence kinetics to visualize transiently misaligned DNA intermediates and nucleotide incorporation products formed by DNA polymerases adept at making small frameshift mutations in vivo. Human polymerase (pol) mu catalyzes Streisinger slippage exclusively in repetitive DNA, requiring as little as a dinucleotide repeat. Escherichia coli pol IV uses dNTP-stabilized misalignment in identical repetitive DNA sequences, revealing that pol mu and pol IV use different mechanisms in repetitive DNA to achieve the same mutational end point. In non-repeat sequences, pol mu switches to dNTP-stabilized misalignment. pol beta generates -1 frameshifts in "long" repeats and base substitutions in "short" repeats. Thus, two polymerases can use two different frameshift mechanisms on identical sequences, whereas one polymerase can alternate between frameshift mechanisms to process different sequences.

Enzymatic switching for efficient and accurate translesion DNA replication

When cyclobutane pyrimidine dimers stall DNA replication by DNA polymerase (Pol) delta or epsilon, a switch occurs to allow translesion synthesis by DNA polymerase eta, followed by another switch that allows normal replication to resume. In the present study, we investigate these switches using Saccharomyces cerevisiae Pol delta, Pol epsilon and Pol eta and a series of matched and mismatched primer templates that mimic each incorporation needed to completely bypass a cis-syn thymine-thymine (TT) dimer. We report a complementary pattern of substrate use indicating that enzymatic switching involving localized translesion synthesis by Pol eta and mismatch excision and polymerization by a major replicative polymerase can account for the efficient and accurate dimer bypass known to suppress sunlight-induced mutagenesis and skin cancer.

Structural basis for the dual coding potential of 8-oxoguanosine by a high-fidelity DNA polymerase

Accurate DNA replication involves polymerases with high nucleotide selectivity and proofreading activity. We show here why both fidelity mechanisms fail when normally accurate T7 DNA polymerase bypasses the common oxidative lesion 8-oxo-7, 8-dihydro-2'-deoxyguanosine (8oG). The crystal structure of the polymerase with 8oG templating dC insertion shows that the O8 oxygen is tolerated by strong kinking of the DNA template. A model of a corresponding structure with dATP predicts steric and electrostatic clashes that would reduce but not eliminate insertion of dA. The structure of a postinsertional complex shows 8oG(syn).dA (anti) in a Hoogsteen-like base pair at the 3' terminus, and polymerase interactions with the minor groove surface of the mismatch that mimic those with undamaged, matched base pairs. This explains why translesion synthesis is permitted without proofreading of an 8oG.dA mismatch, thus providing insight into the high mutagenic potential of 8oG.

Replication by human DNA polymerase-iota occurs by Hoogsteen base-pairing

Almost all DNA polymerases show a strong preference for incorporating the nucleotide that forms the correct Watson-Crick base pair with the template base. In addition, the catalytic efficiencies with which any given polymerase forms the four possible correct base pairs are roughly the same. Human DNA polymerase-iota (hPoliota), a member of the Y family of DNA polymerases, is an exception to these rules. hPoliota incorporates the correct nucleotide opposite a template adenine with a several hundred to several thousand fold greater efficiency than it incorporates the correct nucleotide opposite a template thymine, whereas its efficiency for correct nucleotide incorporation opposite a template guanine or cytosine is intermediate between these two extremes. Here we present the crystal structure of hPoliota bound to a template primer and an incoming nucleotide. The structure reveals a polymerase that is 'specialized' for Hoogsteen base-pairing, whereby the templating base is driven to the syn conformation. Hoogsteen base-pairing offers a basis for the varied efficiencies and fidelities of hPoliota opposite different template bases, and it provides an elegant mechanism for promoting replication through minor-groove purine adducts that interfere with replication.

Altered translesion synthesis in E. coli Pol V mutants selected for increased recombination inhibition

Replication of damaged DNA, also termed as translesion synthesis (TLS), involves specialized DNA polymerases that bypass DNA lesions. In Escherichia coli, although TLS can involve one or a combination of DNA polymerases depending on the nature of the lesion, it generally requires the Pol V DNA polymerase (formed by two SOS proteins, UmuD' and UmuC) and the RecA protein. In addition to being an essential component of translesion DNA synthesis, Pol V is also an antagonist of RecA-mediated recombination. We have recently isolated umuD' and umuC mutants on the basis of their increased capacity to inhibit homologous recombination. Despite the capacity of these mutants to form a Pol V complex and to interact with the RecA polymer, most of them exhibit a defect in TLS. Here, we further characterize the TLS activity of these Pol V mutants in vivo by measuring the extent of error-free and mutagenic bypass at a single (6-4)TT lesion located in double stranded plasmid DNA. TLS is markedly decreased in most Pol V mutants that we analyzed (8/9) with the exception of one UmuC mutant (F287L) that exhibits wild-type bypass activity. Somewhat unexpectedly, Pol V mutants that are partially deficient in TLS are more severely affected in mutagenic bypass compared to error-free synthesis. The defect in bypass activity of the Pol V mutant polymerases is discussed in light of the location of the respective mutations in the 3D structure of UmuD' and the DinB/UmuC homologous protein Dpo4 of Sulfolobus solfataricus.

Translesion DNA synthesis: little fingers teach tolerance

DNA synthesis on a damaged template requires tolerant DNA polymerases. Crystallographic analysis has captured a Y-family polymerase synthesizing across an abasic site, providing insight into the mechanisms of DNA damage tolerance and mutation.

Critical role of magnesium ions in DNA polymerase beta's closing and active site assembly

To dissect the effects of the nucleotide-binding and catalytic metal ions on DNA polymerase mechanisms for DNA repair and synthesis, aside from the chemical reaction, we investigate their roles in the conformational transitions between closed and open states and assembly/disassembly of the active site of polymerase beta/DNA complexes before and after the chemical reaction of nucleotide incorporation. Using dynamics simulations, we find that closing before chemical reaction requires both divalent metal ions in the active site while opening after the chemical reaction is triggered by release of the catalytic metal ion. The critical closing is stabilized by the interaction of the incoming nucleotide with conserved catalytic residues (Asp190, Asp192, Asp256) and the two functional magnesium ions; without the catalytic ion, other protein residues (Arg180, Arg183, Gly189) coordinate the incomer's triphosphate group through the nucleotide-binding ion. Because we also note microionic heterogeneity near the active site, Mg(2+) and Na(+) ions can diffuse into the active site relatively rapidly, we suggest that the binding of the catalytic ion itself is not a rate-limiting conformational or overall step. However, geometric adjustments associated with functional ions and proper positioning in the active site, including subtle but systematic motions of protein side chains (e.g., Arg258), define slow or rate-limiting conformational steps that may guide fidelity mechanisms. These sequential rearrangements are likely sensitively affected when an incorrect nucleotide approaches the active site. Our suggestion that subtle and slow adjustments of the nucleotide-binding and catalytic magnesium ions help guide polymerase selection for the correct nucleotide extends descriptions of polymerase pathways and underscores the importance of the delicate conformational events both before and after the chemical reaction to polymerase efficiency and fidelity mechanisms.

Arabidopsis thaliana AtPOLK encodes a DinB-like DNA polymerase that extends mispaired primer termini and is highly expressed in a variety of tissues

Cell survival after DNA damage depends on specialized DNA polymerases able to perform DNA synthesis on imperfect templates. Most of these enzymes belong to the recently discovered Y-family of DNA polymerases, none of which has been previously described in plants. We report here the isolation, functional characterization and expression analysis of a plant representative of the Y-family. This polymerase, which we have termed AtPolkappa, is a homolog of Escherichia coli pol IV and human pol kappa, and thus belongs to the DinB subfamily. We purified AtPolkappa and found a template-directed DNA polymerase, endowed with limited processivity that is able to extend primer-terminal mispairs. The activity and processivity of AtPolkappa are enhanced markedly upon deletion of 193 amino acids (aa) from its carboxy (C)-terminal domain. Loss of this region also affects the nucleotide selectivity of the enzyme, leading to the incorporation of both dCTP and dTTP opposite A in the template. We detected three cDNA forms, which result from the alternative splicing of AtPOLK mRNA and have distinct patterns of expression in different plant organs. Histochemical localization of beta-glucuronidase (GUS) activity in transgenic plants revealed that the AtPOLK promoter is active in endoreduplicating cells, suggesting a possible role during consecutive DNA replication cycles in the absence of mitosis.

Pre-steady-state kinetic studies of the fidelity of Sulfolobus solfataricus P2 DNA polymerase IV

Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) is a thermostable archaeal enzyme and a member of the error-prone and lesion-bypass Y-family. In this paper, for the first time, the fidelity of a Y-family polymerase, Dpo4, was determined using pre-steady-state kinetic analysis of the incorporation of a single nucleotide into an undamaged DNA substrate 21/41-mer at 37 degrees C. We assessed single-turnover (with Dpo4 in molar excess over DNA) saturation kinetics for all 16 possible nucleotide incorporations. The fidelity of Dpo4 was estimated to be in the range of 10(-3)-10(-4). Interestingly, the ground-state binding affinity of correct nucleotides (70-230 microM) is 10-50-fold weaker than those of replicative DNA polymerases. Such a low affinity is consistent with the lack of interactions between Dpo4 and the bound nucleotides as revealed in the crystal structure of Dpo4, DNA, and a matched nucleotide. The affinity of incorrect nucleotides for Dpo4 is approximately 2-10-fold weaker than that of correct nucleotides. Intriguingly, the mismatched dCTP has an affinity similar to that of the matched nucleotides when it is incorporated against a pyrimidine template base flanked by a 5'-template guanine. The incoming dCTP likely skips the first available template base and base pairs with the 5'-template guanine, as observed in the crystal structure of Dpo4, DNA, and a mismatched nucleotide. The mismatch incorporation rates, regardless of the 5'-template base, were approximately 2-3 orders of magnitude slower than the incorporation rates for matched nucleotides, which is the predominant contribution to the fidelity of Dpo4.

Mechanism of DNA polymerization catalyzed by Sulfolobus solfataricus P2 DNA polymerase IV

The kinetic mechanism of DNA polymerization catalyzed by Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) is resolved by pre-steady-state kinetic analysis of single-nucleotide (dTTP) incorporation into a DNA 21/41-mer. Like replicative DNA polymerases, Dpo4 utilizes an "induced-fit" mechanism to select correct incoming nucleotides. The affinity of DNA and a matched incoming nucleotide for Dpo4 was measured to be 10.6 nM and 230 microM, respectively. Dpo4 binds DNA with an affinity similar to that of replicative polymerases due to the presence of an atypical little finger domain and a highly charged tether that links this novel domain to its small thumb domain. On the basis of the elemental effect between the incorporations of dTTP and its thio analogue S(p)-dTTPalphaS, the incorporation of a correct incoming nucleotide by Dpo4 was shown to be limited by the protein conformational change step preceding the chemistry step. In contrast, the chemistry step limited the incorporation of an incorrect nucleotide. The measured dissociation rates of the enzyme.DNA binary complex (0.02-0.07 s(-1)), the enzyme.DNA.dNTP ternary complex (0.41 s(-1)), and the ternary complex after the protein conformational change (0.004 s(-1)) are significantly different and support the existence of a bona fide protein conformational change step. The rate-limiting protein conformational change was further substantiated by the observation of different reaction amplitudes between pulse-quench and pulse-chase experiments. Additionally, the processivity of Dpo4 was calculated to be 16 at 37 degrees C from analysis of a processive polymerization experiment. The structural basis for both the protein conformational change and the low processivity of Dpo4 was discussed.

The spacious active site of a Y-family DNA polymerase facilitates promiscuous nucleotide incorporation opposite a bulky carcinogen-DNA adduct: elucidating the structure-function relationship through experimental and computational approaches

Y-family DNA polymerases lack some of the mechanisms that replicative DNA polymerases employ to ensure fidelity, resulting in higher error rates during replication of undamaged DNA templates and the ability to bypass certain aberrant bases, such as those produced by exposure to carcinogens, including benzo[a]pyrene (BP). A tumorigenic metabolite of BP, (+)-anti-benzo-[a]pyrene diol epoxide, attacks DNA to form the major 10S (+)-trans-anti-[BP]-N(2)-dG adduct, which has been shown to be mutagenic in a number of prokaryotic and eukaryotic systems. The 10S (+)-trans-anti-[BP]-N(2)-dG adduct can cause all three base substitution mutations, and the SOS response in Escherichia coli increases bypass of bulky adducts, suggesting that Y-family DNA polymerases are involved in the bypass of such lesions. Dpo4 belongs to the DinB branch of the Y-family, which also includes E. coli pol IV and eukaryotic pol kappa. We carried out primer extension assays in conjunction with molecular modeling and molecular dynamics studies in order to elucidate the structure-function relationship involved in nucleotide incorporation opposite the bulky 10S (+)-trans-anti-[BP]-N(2)-dG adduct by Dpo4. Dpo4 is able to bypass the 10S (+)-trans-anti-[BP]-N(2)-dG adduct, albeit to a lesser extent than unmodified guanine, and the V(max) values for insertion of all four nucleotides opposite the adduct by Dpo4 are similar. Computational studies suggest that 10S (+)-trans-anti-[BP]-N(2)-dG can be accommodated in the active site of Dpo4 in either the anti or syn conformation due to the limited protein-DNA contacts and the open nature of both the minor and major groove sides of the nascent base pair, which can contribute to the promiscuous nucleotide incorporation opposite this lesion.

Increased dNTP binding affinity reveals a nonprocessive role for Escherichia coli beta clamp with DNA polymerase IV

Replication forks often stall at undamaged or damaged template sites in Escherichia coli. Subsequent resumption of DNA synthesis occurs by replacing DNA polymerase III, which is bound to DNA by the beta-sliding clamp, with one of three damage-induced DNA polymerases II, IV, or V. The principal role of the beta clamp is to tether the normally weakly bound polmerases to DNA thereby increasing their processivities. DNA polymerase IV binds dNTP substrates with about 10-fold lower affinity compared with the other E. coli polymerases, which if left unchecked could hinder its ability to synthesize DNA in vivo. Here we report a new property for the beta clamp, which when bound to DNA polymerase IV results in a large increase in dNTP binding affinity that concomitantly increases the efficiency of nucleotide incorporation at normal and transiently slipped mispaired primer/template ends. Primer-template DNA slippage resulting in single nucleotide deletions is a biological hallmark of DNA polymerase IV infidelity responsible for enhancing cell fitness in response to stress. We show that the increased DNA polymerase IV-dNTP binding affinity is an intrinsic property of the DNA polymerase IV-beta clamp interaction and not an indirect consequence of an increased binding of DNA polymerase IV to DNA.

Error-prone replication for better or worse

Precise genome duplication requires accurate copying by DNA polymerases and the elimination of occasional mistakes by proofreading exonucleases and mismatch repair enzymes. The commonly held belief that 'if something is worth doing, then it's worth doing well' normally applies to DNA replication and repair, however, there are exceptions. This review describes elements that are crucial to cell fitness, evolution and survival in the recently discovered error-prone DNA polymerases. Large numbers of errant DNA polymerases, spanning microorganisms to humans, are used to rescue stalled replication forks by copying damaged DNA and even undamaged DNA to generate 'purposeful' mutations that generate genetic diversity in times of stress. Here we focus on low-fidelity polymerases from bacteria, comparing Escherichia coli, archeabacteria and those most recently discovered in Gram-positive Bacilli, Streptococcus, pathogenic Mycobacterium and intein-containing cyanobacteria.

Molecular genetics of Xeroderma pigmentosum variant

Xeroderma pigmentosum (XP) is an autosomal recessive disease characterized by sun sensitivity, early onset of freckling and subsequent neoplastic changes on sun-exposed skin. Skin abnormalities result from an inability to repair UV-damaged DNA because of defects in the nucleotide excision repair (NER) machinery. Xeroderma pigmentosum is genetically heterogeneous and is classified into seven complementation groups (XPA-XPG) that correspond to genetic alterations in one of seven genes involved in NER. The variant type of XP (XPV), first described in 1970 by Ernst G. Jung as 'pigmented xerodermoid', is caused by defects in the post replication repair machinery while NER is not impaired. Identification of the XPV gene was only achieved in 1999 by biochemical purification and sequencing of a protein from HeLa cell extracts complementing the PRR defect in XPV cells. The XPV protein, polymerase (pol)eta, represents a novel member of the Y family of bypass DNA polymerases that facilitate DNA translesion synthesis. The major function of (pol)eta is to allow DNA translesion synthesis of UV-induced TT-dimers in an error-free manner; it also possesses the capability to bypass other DNA lesions in an error-prone manner. Xeroderma pigmentosum V is caused by molecular alterations in the POLH gene, located on chromosome 6p21.1-6p12. Affected individuals are homozygous or compound heterozygous for a spectrum of genetic lesions, including nonsense mutations, deletions or insertions, confirming the autosomal recessive nature of the condition. Identification of POLH as the XPV gene provides an important instrument for improving molecular diagnostics in XPV families.

Generic expansion of the substrate spectrum of a DNA polymerase by directed evolution

DNA polymerases recognize their substrates with exceptionally high specificity, restricting the use of unnatural nucleotides and the applications they enable. We describe a strategy to expand the substrate range of polymerases. By selecting for the extension of distorting 3' mismatches, we obtained mutants of Taq DNA polymerase that not only promiscuously extended mismatches, but had acquired a generic ability to process a diverse range of noncanonical substrates while maintaining high catalytic turnover, processivity and fidelity. Unlike the wild-type enzyme, they bypassed blocking lesions such as an abasic site, a thymidine dimer or the base analog 5-nitroindol and performed PCR amplification with complete substitution of all four nucleotide triphosphates with phosphorothioates or the substitution of one with the equivalent fluorescent dye-labeled nucleotide triphosphate. Such 'unfussy' polymerases have immediate utility, as we demonstrate by the generation of microarray probes with up to 20-fold brighter fluorescence.

Investigating the role of the little finger domain of Y-family DNA polymerases in low fidelity synthesis and translesion replication

Dpo4 and Dbh are Y-family polymerases that originate from two closely related strains of Sulfolobaceae. Quite surprisingly, however, the two polymerases exhibit different enzymatic properties in vitro. For example, Dpo4 can replicate past a variety of DNA lesions, yet Dbh does so with a much lower efficiency. When replicating undamaged DNA, Dpo4 is prone to make base pair substitutions, whereas Dbh predominantly makes single-base deletions. Overall, the two proteins are 54% identical, but the greatest divergence is found in their respective little finger (LF) domains, which are only 41% identical. To investigate the role of the LF domain in the fidelity and lesion-bypassing abilities of Y-family polymerases, we have generated chimeras of Dpo4 and Dbh in which their LF domains have been interchanged. Interestingly, by replacing the LF domain of Dbh with that of Dpo4, the enzymatic properties of the chimeric enzyme are more Dpo4-like in that the enzyme is more processive, can bypass an abasic site and a thymine-thymine cyclobutane pyrimidine dimer, and predominantly makes base pair substitutions when replicating undamaged DNA. The converse is true for the Dpo4-LF-Dbh chimera, which is more Dbh-like in its processivity and ability to bypass DNA adducts and generate single-base deletion errors. Our studies indicate that the unique but variable LF domain of Y-family polymerases plays a major role in determining the enzymatic and biological properties of each individual Y-family member.

Palm mutants in DNA polymerases alpha and eta alter DNA replication fidelity and translesion activity

We isolated active mutants in Saccharomyces cerevisiae DNA polymerase alpha that were associated with a defect in error discrimination. Among them, L868F DNA polymerase alpha has a spontaneous error frequency of 3 in 100 nucleotides and 570-fold lower replication fidelity than wild-type (WT) polymerase alpha. In vivo, mutant DNA polymerases confer a mutator phenotype and are synergistic with msh2 or msh6, suggesting that DNA polymerase alpha-dependent replication errors are recognized and repaired by mismatch repair. In vitro, L868F DNA polymerase alpha catalyzes efficient bypass of a cis-syn cyclobutane pyrimidine dimer, extending the 3' T 26000-fold more efficiently than the WT. Phe34 is equivalent to residue Leu868 in translesion DNA polymerase eta, and the F34L mutant of S. cerevisiae DNA polymerase eta has reduced translesion DNA synthesis activity in vitro. These data suggest that high-fidelity DNA synthesis by DNA polymerase alpha is required for genomic stability in yeast. The data also suggest that the phenylalanine and leucine residues in translesion and replicative DNA polymerases, respectively, might have played a role in the functional evolution of these enzyme classes.

Structural and kinetic analyses of the interaction of anthrax adenylyl cyclase toxin with reaction products cAMP and pyrophosphate

Anthrax edema factor (EF) raises host intracellular cAMP to pathological levels through a calcium-calmodulin (CaM)-dependent adenylyl cyclase activity. Here we report the structure of EF.CaM in complex with its reaction products, cAMP and PP(i). Mutational analysis confirmed the interaction of EF with cAMP and PP(i) as depicted in the structural model. While both cAMP and PP(i) have access to solvent channels to exit independently, PP(i) is likely released first. EF can synthesize ATP from cAMP and PP(i), and the estimated rate constants of this reaction at two physiologically relevant calcium concentrations were similar to those of adenylyl cyclase activity of EF. Comparison of the conformation of adenosine in the structures of EF.CaM.cAMP.PP(i) with EF.CaM.3.dATP revealed about 160 degrees rotation in the torsion angle of N-glycosyl bond from the +anti conformation in 3.dATP to -syn in cAMP; such a rotation could serve to distinguish against substrates with the N-2 amino group of purine. The catalytic rate of EF for ITP was about 2 orders of magnitude better than that for GTP, supporting the potential role of this rotation in substrate selectivity of EF. The anomalous difference Fourier map revealed that two ytterbium ions (Yb(3+)) could bind the catalytic site of EF.CaM in the presence of cAMP and PP(i), suggesting the presence of two magnesium ions at the catalytic site of EF. We hypothesize that EF could use a "histidine and two-metal ion" hybrid mechanism to facilitate the cyclization reaction.

Accuracy, lesion bypass, strand displacement and translocation by DNA polymerases

The structures of DNA polymerases from different families show common features and significant differences that shed light on the ability of these enzymes to accurately copy DNA and translocate. The structure of a B family DNA polymerase from phage RB69 exhibits an active-site closing conformational change in the fingers domain upon forming a ternary complex with primer template in deoxynucleoside triphosphate. The rotation of the fingers domain alpha-helices by 60 degrees upon dNTP binding is analogous to the changes seen in other families of polymerases. When the 3' terminus is bound to the editing 3' exonuclease active site, the orientation of the DNA helix axis changes by 40 degrees and the thumb domain re-orients with the DNA. Structures of substrate and product complexes of T7 RNA polymerase, a structural homologue of T7 DNA polymerase, show that family polymerases use the rotation conformational change of the fingers domain to translocate down the DNA. The fingers opening rotation that results in translocation is powered by the release of the product pyrophosphate and also enables the Pol I family polymerases to function as a helicase in displacing the downstream non-template strand from the template strand.

Structures of mismatch replication errors observed in a DNA polymerase

Accurate DNA replication is essential for genomic stability. One mechanism by which high-fidelity DNA polymerases maintain replication accuracy involves stalling of the polymerase in response to covalent incorporation of mismatched base pairs, thereby favoring subsequent mismatch excision. Some polymerases retain a "short-term memory" of replication errors, responding to mismatches up to four base pairs in from the primer terminus. Here we a present a structural characterization of all 12 possible mismatches captured at the growing primer terminus in the active site of a polymerase. Our observations suggest four mechanisms that lead to mismatch-induced stalling of the polymerase. Furthermore, we have observed the effects of extending a mismatch up to six base pairs from the primer terminus and find that long-range distortions in the DNA transmit the presence of the mismatch back to the enzyme active site, suggesting the structural basis for the short-term memory of replication errors.

Snapshots of replication through an abasic lesion; structural basis for base substitutions and frameshifts

Dpo4 from S. Solfataricus, a DinB-like Y family polymerase, efficiently replicates DNA past an abasic lesion. We have determined crystal structures of Dpo4 complexed with five different abasic site-containing DNA substrates and find that translesion synthesis is template directed with the abasic site looped out and the incoming nucleotide is opposite the base 5' to the lesion. The ensuing DNA synthesis generates a -1 frameshift when the abasic site remains extrahelical. Template realignment during primer extension is also observed, resulting in base substitutions or even +1 frameshifts. In the case of a +1 frameshift, the extra nucleotide is accommodated in the solvent-exposed minor groove. In addition, the structure of an unproductive Dpo4 ternary complex suggests that the flexible little finger domain facilitates DNA orientation and translocation during translesion synthesis.

The structural mechanism of translocation and helicase activity in T7 RNA polymerase

RNA polymerase functions like a molecular motor that can convert chemical energy into the work of strand separation and translocation along the DNA during transcription. The structures of phage T7 RNA polymerase in an elongation phase substrate complex that includes the incoming nucleoside triphosphate and a pretranslocation product complex that includes the product pyrophosphate (PPi) are described here. These structures and the previously determined posttranslocation elongation complex demonstrate that two enzyme conformations exist during a cycle of single nucleotide addition. One orientation of a five-helix subdomain is stabilized by the phosphates of either the incoming NTP or by the product PPi. A second orientation of this subdomain is stable in their absence and is associated with translocation of the heteroduplex product as well as strand separation of the downstream DNA. We propose that the dissociation of the product PPi after nucleotide addition produces the protein conformational change resulting in translocation and strand separation.

Dpo4 is hindered in extending a G.T mismatch by a reverse wobble

The ability or inability of a DNA polymerase to extend a mispair directly affects the establishment of genomic mutations. We report here kinetic analyses of the ability of Dpo4, a Y-family polymerase from Sulfolobus solfataricus, to extend from all mispairs opposite a template G or T. Dpo4 is equally inefficient at extending these mispairs, which include, surprisingly, a G.T mispair expected to conform closely to Watson-Crick geometry. To elucidate the basis of this, we solved the structure of Dpo4 bound to G.T-mispaired primer template in the presence of an incoming nucleotide. As a control, we also determined the structure of Dpo4 bound to a matched A-T base pair at the primer terminus. The structures offer a basis for the low efficiency of Dpo4 in extending a G.T mispair: a reverse wobble that deflects the primer 3'-OH away from the incoming nucleotide.

Crystal structure of a benzo[a]pyrene diol epoxide adduct in a ternary complex with a DNA polymerase

The first occupation-associated cancers to be recognized were the sooty warts (cancers of the scrotum) suffered by chimney sweeps in 18th century England. In the 19th century, high incidences of skin cancers were noted among fuel industry workers. By the early 20th century, malignant skin tumors were produced in laboratory animals by repeatedly painting them with coal tar. The culprit in coal tar that induces cancer was finally isolated in 1933 and determined to be benzo[a]pyrene (BP), a polycyclic aromatic hydrocarbon. A residue of fuel and tobacco combustion and frequently ingested by humans, BP is metabolized in mammals to benzo[a]pyrene diol epoxide (BPDE), which forms covalent DNA adducts and induces tumor growth. In the 70 yr since its isolation, BP has been the most studied carcinogen. Yet, there has been no crystal structure of a BPDE DNA adduct. We report here the crystal structure of a BPDE-adenine adduct base-paired with thymine at a template-primer junction and complexed with the lesion-bypass DNA polymerase Dpo4 and an incoming nucleotide. Two conformations of the BPDE, one intercalated between base pairs and another solvent-exposed in the major groove, are observed. The latter conformation, which can be stabilized by organic solvents that reduce the dielectric constant, seems more favorable for DNA replication by Dpo4. These structures also suggest a mechanism by which mutations are generated during replication of DNA containing BPDE adducts.

Crystallographic snapshots of a replicative DNA polymerase encountering an abasic site

Abasic sites are common DNA lesions, which are strong blocks to replicative polymerases and are potentially mutagenic when bypassed. We report here the 2.8 A structure of the bacteriophage RB69 replicative DNA polymerase attempting to process an abasic site analog. Four different complexes were captured in the crystal asymmetric unit: two have DNA in the polymerase active site whereas the other two molecules are in the exonuclease mode. When compared to complexes with undamaged DNA, the DNA surrounding the abasic site reveals distinct changes suggesting why the lesion is so poorly bypassed: the DNA in the polymerase active site has not translocated and is therefore stalled, precluding extension. All four molecules exhibit conformations that differ from the previously published structures. The polymerase incorporates dAMP across the lesion under crystallization conditions, indicating that the different conformations observed in the crystal may be part of the active site switching reaction pathway.

Preferential cis-syn thymine dimer bypass by DNA polymerase eta occurs with biased fidelity

Human DNA polymerase eta (Pol eta) modulates susceptibility to skin cancer by promoting DNA synthesis past sunlight-induced cyclobutane pyrimidine dimers that escape nucleotide excision repair (NER). Here we have determined the efficiency and fidelity of dimer bypass. We show that Pol eta copies thymine dimers and the flanking bases with higher processivity than it copies undamaged DNA, and then switches to less processive synthesis. This ability of Pol eta to sense the dimer location as synthesis proceeds may facilitate polymerase switching before and after lesion bypass. Pol eta bypasses a dimer with low fidelity and with higher error rates at the 3' thymine than at the 5' thymine. A similar bias is seen with Sulfolobus solfataricus DNA polymerase 4, which forms a Watson-Crick base pair at the 3' thymine of a dimer but a Hoogsteen base pair at the 5' thymine (ref. 3). Ultraviolet-induced mutagenesis is also higher at the 3' base of dipyrimidine sequences. Thus, in normal people and particularly in individuals with NER-defective xeroderma pigmentosum who accumulate dimers, errors made by Pol eta during dimer bypass could contribute to mutagenesis and skin cancer.

Properties and functions of Escherichia coli: Pol IV and Pol V

Escherichia coli possesses two members of the newly discovered class of Y DNA polymerases (Ohmori et al., 2001): Pol IV (dinB) and Pol V (umuD'C). Polymerases that belong to this family are often referred to as specialized or error-prone DNA polymerases to distinguish them from the previously discovered DNA polymerases (Pol I, II, and III) that are essentially involved in DNA replication or error-free DNA repair. Y-family DNA polymerases are characterized by their capacity to replicate DNA, through chemically damaged template bases, or to elongate mismatched primer termini. These properties stem from their capacity to accommodate and use distorted primer templates within their active site and from the lack of an associated exonuclease activity. Even though both belong to the Y-family, Pol IV and Pol V appear to perform distinct physiological functions. Although Pol V is clearly the major lesion bypass polymerase involved in damage-induced mutagenesis, the role of Pol IV remains enigmatic. Indeed, compared to a wild-type strain, a dinB mutant exhibits no clear phenotype with respect to survival or mutagenesis following treatment with DNA-damaging agents. Subtler dinB phenotypes will be discussed below. Moreover, despite the fact that both dinB and umuDC loci are controlled by the SOS response, their constitutive and induced levels of expression are dramatically different. In noninduced cells, Pol V is undetectable by Western analysis. In contrast, it is estimated that there are about 250 copies of Pol IV per cell. On SOS induction, it is believed that only about 15 molecules of Pol V are assembled per cell (S. Sommer, personal communication), whereas Pol IV levels reach approximately 2500 molecules. In fact, despite extensive knowledge of the individual enzymatic properties of all five E. coli DNA polymerases, much more work is needed to understand how their activities are orchestrated within a living cell.

Structural basis for recruitment of translesion DNA polymerase Pol IV/DinB to the beta-clamp

Y-family DNA polymerases can extend primer strands across template strand lesions that stall replicative polymerases. The poor processivity and fidelity of these enzymes, key to their biological role, requires that their access to the primer-template junction is both facilitated and regulated in order to minimize mutations. These features are believed to be provided by interaction with processivity factors, beta-clamp or proliferating cell nuclear antigen (PCNA), which are also essential for the function of replicative DNA polymerases. The basis for this interaction is revealed by the crystal structure of the complex between the 'little finger' domain of the Y-family DNA polymerase Pol IV and the beta-clamp processivity factor, both from Escherichia coli. The main interaction involves a C-terminal peptide of Pol IV, and is similar to interactions seen between isolated peptides and other processivity factors. However, this first structure of an entire domain of a binding partner with an assembled clamp reveals a substantial secondary interface, which maintains the polymerase in an inactive orientation, and may regulate the switch between replicative and Y-family DNA polymerases in response to a template strand lesion.