Mutations in human DNA polymerase eta motif II alter bypass of DNA lesions.

Human DNA polymerase eta (hPol eta) is one of the newly identified Y-family of DNA polymerases. These polymerases synthesize past template lesions that are postulated to block replication fork progression. hPol eta accurately bypasses UV-associated cis-syn cyclobutane thymine dimers in vitro and contributes to normal resistance to sunlight-induced skin cancer. We describe here mutational analysis of motif II, a highly conserved sequence, recently reported to reside in the fingers domain and to form part of the active site in Y-family DNA polymerases. We used a yeast-based complementation system to isolate biologically active mutants created by random sequence mutagenesis, synthesized the mutant proteins in vitro and assessed their ability to bypass thymine dimers. The mutability of motif II in 210 active mutants has parallels with natural evolution and identifies Tyr52 and Ala54 as prime candidates for involvement in catalytic activity or bypass. We describe the ability of hPol eta S62G, a mutant polymerase with enhanced activity, to bypass five other site-specific lesions. Our results may serve as a prototype for studying other members of the Y-family DNA polymerases.     

Deoxynucleotide triphosphate binding mode conserved in Y family DNA polymerases

Although DNA polymerase eta (Pol eta) and other Y family polymerases differ in sequence and function from classical DNA polymerases, they all share a similar right-handed architecture with the palm, fingers, and thumb domains. Here, we examine the role in Saccharomyces cerevisiae Pol eta of three conserved residues, tyrosine 64, arginine 67, and lysine 279, which come into close contact with the triphosphate moiety of the incoming nucleotide, in nucleotide incorporation. We find that mutational alteration of these residues reduces the efficiency of correct nucleotide incorporation very considerably. The high degree of conservation of these residues among the various Y family DNA polymerases suggests that these residues are also crucial for nucleotide incorporation in the other members of the family. Furthermore, we note that tyrosine 64 and arginine 67 are functionally equivalent to the deoxynucleotide triphosphate binding residues arginine 518 and histidine 506 in T7 DNA polymerase, respectively.     

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.     

Structure of the catalytic core of S. cerevisiae DNA polymerase eta: implications for translesion DNA synthesis.

DNA polymerase eta is unique among eukaryotic polymerases in its proficient ability to replicate through a variety of distorting DNA lesions. We report here the crystal structure of the catalytic core of S. cerevisiae DNA polymerase eta, determined at 2.25A resolution. The structure reveals a novel polydactyl right hand-shaped molecule with a unique polymerase-associated domain. We identify the catalytic residues and show that the fingers and thumb domains are unusually small and stubby. In particular, the unexpected absence of helices "O" and "O1" in the fingers domain suggests that openness of the active site is the critical feature which enables DNA polymerase eta to replicate through DNA lesions such as a UV-induced cis-syn thymine-thymine dimer.     

Insights into DNA replication: the crystal structure of DNA polymerase B1 from the archaeon Sulfolobus solfataricus

To minimize the large number of mispairs during genome duplication owing to the large amount of DNA to be synthesized, many replicative polymerases have accessory domains with complementary functions. We describe the crystal structure of replicative DNA polymerase B1 from the archaeon Sulfolobus solfataricus. Comparison between other known structures indicates that although the protein is folded into the typical N-terminal, editing 3'-5'exonuclease, and C-terminal right-handed polymerase domains, it is characterized by the unusual presence of two extra alpha helices in the N-terminal domain interacting with the fingers helices to form an extended fingers subdomain, a structural feature that can account for some functional features of the protein. We explore the structural basis of specific lesion recognition, the initial step in DNA repair, describing how the N-terminal subdomain pocket of archaeal DNA polymerases could allow specific recognition of deaminated bases such as uracil and hypoxanthine in addition to the typical DNA bases.     

The efficiency and specificity of apurinic/apyrimidinic site bypass by human DNA polymerase eta and Sulfolobus solfataricus Dpo4

One of the most common DNA lesions arising in cells is an apurinic/apyrimidinic (AP) site resulting from base loss. Although a template strand AP site impedes DNA synthesis, translesion synthesis (TLS) DNA polymerases can bypass an AP site. Because this bypass is expected to be highly mutagenic because of loss of base coding potential, here we quantify the efficiency and the specificity of AP site bypass by two Y family TLS enzymes, Sulfolobus solfataricus DNA polymerase 4 (Dpo4) and human DNA polymerase eta (Pol eta). During a single cycle of processive DNA synthesis, Dpo4 and Pol eta bypass synthetic AP sites with 13-30 and 10-13%, respectively, of the bypass efficiency for undamaged bases in the same sequence contexts. These efficiencies are higher than for the A family, exonuclease-deficient Klenow fragment of Escherichia coli DNA polymerase I. We then determined AP site bypass specificity for complete bypass, requiring insertion or misalignment at the AP site followed by multiple incorporations using the aberrant primer templates. Although Dpo4, Pol eta, and Klenow polymerase have different fidelity when copying undamaged DNA, bypass of AP sites lacking A or G by all three polymerases is nearly 100% mutagenic. The majority (70-80%) of bypass events made by all three polymerases are insertion of dAMP opposite the AP site. Single base deletion errors comprise 10-25% of bypass events, with other base insertions observed at lower rates. Given that mammalian cells contain five polymerases implicated in TLS, and given that a large number of AP sites are generated per mammalian cell per day, even moderately efficient AP site bypass could be a source of substitution and frameshift mutagenesis in vivo.     

Human DNA polymerase kappa encircles DNA: implications for mismatch extension and lesion bypass

Human DNA polymerase kappa (Pol kappa) is a proficient extender of mispaired primer termini on undamaged DNAs and is implicated in the extension step of lesion bypass. We present here the structure of Pol kappa catalytic core in ternary complex with DNA and an incoming nucleotide. The structure reveals encirclement of the DNA by a unique "N-clasp" at the N terminus of Pol kappa, which augments the conventional right-handed grip on the DNA by the palm, fingers, and thumb domains and the PAD and provides additional thermodynamic stability. The structure also reveals an active-site cleft that is constrained by the close apposition of the N-clasp and the fingers domain, and therefore can accommodate only a single Watson-Crick base pair. Together, DNA encirclement and other structural features help explain Pol kappa's ability to extend mismatches and to promote replication through various minor groove DNA lesions, by extending from the nucleotide incorporated opposite the lesion by another polymerase.     

Stepwise translocation of Dpo4 polymerase during error-free bypass of an oxoG lesion

7,8-dihydro-8-oxoguanine (oxoG), the predominant lesion formed following oxidative damage of DNA by reactive oxygen species, is processed differently by replicative and bypass polymerases. Our kinetic primer extension studies demonstrate that the bypass polymerase Dpo4 preferentially inserts C opposite oxoG, and also preferentially extends from the oxoG•C base pair, thus achieving error-free bypass of this lesion. We have determined the crystal structures of preinsertion binary, insertion ternary, and postinsertion binary complexes of oxoG-modified template-primer DNA and Dpo4. These structures provide insights into the translocation mechanics of the bypass polymerase during a complete cycle of nucleotide incorporation. Specifically, during noncovalent dCTP insertion opposite oxoG (or G), the little-finger domain–DNA phosphate contacts translocate by one nucleotide step, while the thumb domain–DNA phosphate contacts remain fixed. By contrast, during the nucleotidyl transfer reaction that covalently incorporates C opposite oxoG, the thumb-domain–phosphate contacts are translocated by one nucleotide step, while the little-finger contacts with phosphate groups remain fixed. These stepwise conformational transitions accompanying nucleoside triphosphate binding and covalent nucleobase incorporation during a full replication cycle of Dpo4-catalyzed bypass of the oxoG lesion are distinct from the translocation events in replicative polymerases.     

Amino acid substitutions at conserved tyrosine 52 alter fidelity and bypass efficiency of human DNA polymerase eta

DNA polymerase eta (Pol eta) is a member of a new class of DNA polymerases that is able to copy DNA containing damaged nucleotides. These polymerases are highly error-prone during copying of unaltered DNA templates. We analyzed the relationship between bypass efficiency and fidelity of DNA synthesis by introducing substitutions for Tyr-52, a highly conserved amino acid, within the human DNA polymerase eta (hPol eta) finger domain. Most substitutions for Tyr-52 caused reduction in bypass of UV-associated damage, measured by the ability to rescue the viability of UV-sensitive yeast cells at a high UV dose. For most mutants, the reduction in bypass ability paralleled the reduction in polymerization activity. Interestingly, the hPol eta Y52E mutant exhibited a greater reduction in bypass efficiency than polymerization activity. The reduction in bypass efficiency was accompanied by an up to 11-fold increase in the incorporation of complementary nucleotides relative to non-complementary nucleotides. The fidelity of DNA synthesis, measured by copying a gapped M13 DNA template in vitro, was also enhanced as much as 15-fold; the enhancement resulted from a decrease in transitions, which were relatively frequent, and a large decrease in transversions. Our demonstration that an amino acid substitution within the active site enhances the fidelity of DNA synthesis by hPol eta, one of the most inaccurate of DNA polymerases, supports the hypothesis that even error-prone DNA polymerases function in base selection.     

Solution structure of a viral DNA polymerase X and evidence for a mutagenic function.

The African swine fever virus DNA polymerase X (ASFV Pol X or Pol X), the smallest known nucleotide polymerase, has recently been reported to be an extremely low fidelity polymerase that may be involved in strategic mutagenesis of the viral genome. Here we report the solution structure of Pol X. The structure, unique within the realm of nucleotide polymerases, consists of only palm and fingers subdomains. Despite the absence of a thumb subdomain, which is important for DNA binding in other polymerases, we show that Pol X binds DNA with very high affinity. Further structural analyses suggest a novel mode of DNA binding that may contribute to low fidelity synthesis. We also demonstrate that the ASFV DNA ligase is a low fidelity ligase capable of sealing a nick that contains a G-G mismatch. This supports the hypothesis of a virus-encoded, mutagenic base excision repair pathway consisting of a tandem Pol X/ligase mutator.     

Structure of the replicating complex of a pol alpha family DNA polymerase

We describe the 2.6 A resolution crystal structure of RB69 DNA polymerase with primer-template DNA and dTTP, capturing the step just before primer extension. This ternary complex structure in the human DNA polymerase alpha family shows a 60 degrees rotation of the fingers domain relative to the apo-protein structure, similar to the fingers movement in pol I family polymerases. Minor groove interactions near the primer 3' terminus suggest a common fidelity mechanism for pol I and pol alpha family polymerases. The duplex product DNA orientation differs by 40 degrees between the polymerizing mode and editing mode structures. The role of the thumb in this DNA motion provides a model for editing in the pol alpha family.     

Crystal structures of the RNA-dependent RNA polymerase genotype 2a of hepatitis C virus reveal two conformations and suggest mechanisms of inhibition by non-nucleoside inhibitors

Crystal structures of the RNA-dependent RNA polymerase genotype 2a of hepatitis C virus (HCV) from two crystal forms have been determined. Similar to the three-dimensional structures of HCV polymerase genotype 1b and other known polymerases, the structures of the HCV polymerase genotype 2a in both crystal forms can be depicted in the classical right-hand arrangement with fingers, palm, and thumb domains. The main structural differences between the molecules in the two crystal forms lie at the interface of the fingers and thumb domains. The relative orientation of the thumb domain with respect to the fingers and palm domains and the beta-flap region is altered. Structural analysis reveals that the NS5B polymerase in crystal form I adopts a "closed" conformation that is believed to be the active form, whereas NS5B in crystal form II adopts an "open" conformation and is thus in the inactive form. In addition, we have determined the structures of two NS5B polymerase/non-nucleoside inhibitor complexes. Both inhibitors bind at a common binding site, which is nearly 35 A away from the polymerase active site and is located in the thumb domain. The binding pocket is predominantly hydrophobic in nature, and the enzyme inhibitor complexes are stabilized by hydrogen bonding and van der Waals interactions. Inhibitors can only be soaked in crystal form I and not in form II; examination of the enzyme-inhibitor complex reveals that the enzyme has undergone a dramatic conformational change from the form I (active) complex to the form II (inactive).     

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.     

Mouse Rev1 protein interacts with multiple DNA polymerases involved in translesion DNA synthesis

Pol kappa and Rev1 are members of the Y family of DNA polymerases involved in tolerance to DNA damage by replicative bypass [translesion DNA synthesis (TLS)]. We demonstrate that mouse Rev1 protein physically associates with Pol kappa. We show too that Rev1 interacts independently with Rev7 (a subunit of a TLS polymerase, Pol zeta) and with two other Y-family polymerases, Pol iota and Pol eta. Mouse Pol kappa, Rev7, Pol iota and Pol eta each bind to the same approximately 100 amino acid C-terminal region of Rev1. Furthermore, Rev7 competes directly with Pol kappa for binding to the Rev1 C-terminus. Notwithstanding the physical interaction between Rev1 and Pol kappa, the DNA polymerase activity of each measured by primer extension in vitro is unaffected by the complex, either when extending normal primer-termini, when bypassing a single thymine glycol lesion, or when extending certain mismatched primer termini. Our observations suggest that Rev1 plays a role(s) in mediating protein-protein interactions among DNA polymerases required for TLS. The precise function(s) of these interactions during TLS remains to be determined.     

Lesion bypass in yeast cells: Pol eta participates in a multi-DNA polymerase process

Replication through (6-4)TT and G-AAF lesions was compared in Saccharomyces cerevisiae strains proficient and deficient for the RAD30-encoded DNA polymerase eta (Pol eta). In the RAD30 strain, the (6-4)TT lesion is replicated both inaccurately and accurately 60 and 40% of the time, respectively. Surprisingly, in a rad30 Delta strain, the level of mutagenic bypass is essentially suppressed, while error-free bypass remains unchanged. Therefore, Pol eta is responsible for mutagenic replication through the (6-4)TT photoproduct, while another polymerase mediates its error-free bypass. Deletion of the RAD30 gene also reduces the levels of both accurate and inaccurate bypass of AAF lesions within two different sequence contexts up to 8-fold. These data show that, in contrast to the accurate bypass by Pol eta of TT cyclobutane dimers, it is responsible for the mutagenic bypass of other lesions. In conclusion, this paper shows that, in yeast, translesion synthesis involves the combined action of several polymerases.     

New structural and mechanistic insight into the A-rule and the instructional and non-instructional behavior of DNA photoproducts and other lesions

The A-rule in mutagenesis was originally proposed to explain the preponderance of X-->T mutations observed for abasic sites and UV damaged sites. It was deduced that when a polymerase was faced with a non-instructional lesion, typified by an abasic site, it would preferentially incorporate an A. In the absence of any other compelling explanation, any lesion causing an X-->T mutation has often been classified as non-instructional to account for its apparent lack of instructional ability. The A-rule and the classification of lesions as non-instructional were formulated before the active sites of any polymerases or the mechanism by which they synthesized DNA were known. Since then, much structural and kinetic data on DNA polymerases has emerged to suggest mechanistic explanations for the A-rule and the instructive and non-instructive behavior of lesions such as cis-syn dimers. Polymerases involved in the replication of undamaged DNA have highly constrained active sites that evolved to only accommodate the templating base and the complementary nucleotide and as a result are relatively intolerant of modifications that alter the size and shape of the nascent base pair. On the other hand, DNA damage bypass polymerases have much more open and less constrained active sites, which are much more tolerant of modifications. An otherwise instructional lesion would become non-instructional if it were unable to fit into the active site, and thereby behave transiently like an abasic site, leading to the insertion of whichever nucleotide is favored by the polymerase, generally an A. In this review, what is known about the active sites and mechanisms of replicative and DNA damage bypass polymerases will be discussed with regard to the A-rule and non-instructive behavior of lesions, typified by dipyrimidine photoproducts.     

Crystal structure of a DinB lesion bypass DNA polymerase catalytic fragment reveals a classic polymerase catalytic domain.

The UmuC/DinB family of bypass polymerases is responsible for translesion DNA synthesis and includes the human polymerases eta, iota, and kappa. We determined the 2.3 A resolution crystal structure of a catalytic fragment of the DinB homolog (Dbh) polymerase from Sulfolobus solfataricus and show that it is nonprocessive and can bypass an abasic site. The structure of the catalytic domain is nearly identical to those of most other polymerase families. Homology modeling suggests that there is minimal contact between protein and DNA, that the nascent base pair binding pocket is quite accessible, and that the enzyme is already in a closed conformation characteristic of ternary polymerase complexes. These observations afford insights into the sources of low fidelity and low processivity of the UmuC/DinB polymerases.     

Structural Mechanism of Replication Stalling on a Bulky Amino-Polycyclic Aromatic Hydrocarbon DNA Adduct by a Y Family DNA Polymerase

Polycyclic aromatic hydrocarbons and their nitro derivatives are culprits of the detrimental health effects of environmental pollution. These hydrophobic compounds metabolize to reactive species and attach to DNA producing bulky lesions, such as N-[deoxyguanosine-8-yl]-1-aminopyrene (APG), in genomic DNA. The bulky adducts block DNA replication by high-fidelity polymerases and compromise replication fidelities and efficiencies by specialized lesion bypass polymerases. Here we present three crystal structures of the DNA polymerase Dpo4, a model translesion DNA polymerase of the Y family, in complex with APG-lesion-containing DNA in pre-insertion and extension stages. APG is captured in two conformations in the pre-insertion complex; one is highly exposed to the solvent, whereas the other is harbored in a shallow cleft between the finger and unique Y family little finger domain. In contrast, APG is in a single conformation at the extension stage, in which the pyrene ring is sandwiched between the little finger domain and a base from the turning back single-stranded template strand. Strikingly, a nucleotide intercalates the DNA helix to form a quaternary complex with Dpo4, DNA, and an incoming nucleotide, which stabilizes the distorted DNA structure at the extension stage. The unique APG DNA conformations in Dpo4 inhibit DNA translocation through the polymerase active site for APG bypass. We also modeled an insertion complex that illustrates a solvent-exposed pyrene ring contributing to an unstable insertion state. The structural work combined with our lesion replication assays provides a novel structural mechanism on bypass of DNA adducts containing polycyclic aromatic hydrocarbon moieties.