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 structure of an archaebacterial DNA polymerase.

BACKGROUND: Members of the Pol II family of DNA polymerases are responsible for chromosomal replication in eukaryotes, and carry out highly processive DNA replication when attached to ring-shaped processivity clamps. The sequences of Pol II polymerases are distinct from those of members of the well-studied Pol I family of DNA polymerases. The DNA polymerase from the archaebacterium Desulfurococcus strain Tok (D. Tok Pol) is a member of the Pol II family that retains catalytic activity at elevated temperatures. RESULTS: The crystal structure of D. Tok Pol has been determined at 2.4 A resolution. The architecture of this Pol II type DNA polymerase resembles that of the DNA polymerase from the bacteriophage RB69, with which it shares less than approximately 20% sequence identity. As in RB69, the central catalytic region of the DNA polymerase is located within the 'palm' subdomain and is strikingly similar in structure to the corresponding regions of Pol I type DNA polymerases. The structural scaffold that surrounds the catalytic core in D. Tok Pol is unrelated in structure to that of Pol I type polymerases. The 3'-5' proofreading exonuclease domain of D. Tok Pol resembles the corresponding domains of RB69 Pol and Pol I type DNA polymerases. The exonuclease domain in D. Tok Pol is located in the same position relative to the polymerase domain as seen in RB69, and on the opposite side of the palm subdomain compared to its location in Pol I type polymerases. The N-terminal domain of D. Tok Pol has structural similarity to RNA-binding domains. Sequence alignments suggest that this domain is conserved in the eukaryotic DNA polymerases delta and epsilon. CONCLUSIONS: The structure of D. Tok Pol confirms that the modes of binding of the template and extrusion of newly synthesized duplex DNA are likely to be similar in both Pol II and Pol I type DNA polymerases. However, the mechanism by which the newly synthesized product transits in and out of the proofreading exonuclease domain has to be quite different. The discovery of a domain that seems to be an RNA-binding module raises the possibility that Pol II family members interact with RNA.     

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.     

Pre-steady-state kinetics of RB69 DNA polymerase and its exo domain mutants: effect of pH and thiophosphoryl linkages on 3'-5' exonuclease activity

DNA polymerases from the A and B families with 3'-5' exonucleolytic activity have exonuclease domains with similar three-dimensional structures that require two divalent metal ions for catalysis. B family DNA polymerases that are part of a replicase generally have a more potent 3'-5' exonuclease (exo) activity than A family DNA polymerases that mainly function in DNA repair. To investigate the basis for these differences, we determined pH-activity profiles for the exonuclease reactions of T4, RB69, and phi29 DNA polymerases as representatives of B family replicative DNA polymerases and the Klenow fragment (KF) as an example of a repair DNA polymerase in the A family. We performed exo assays under single-turnover conditions and found that excision rates exhibited by the B family DNA polymerases were essentially independent of pH between pH 6.5 and 8.5, whereas the exo activity of KF increased 10-fold for each unit increase in pH. Three exo domain mutants of RB69 polymerase had much lower exo activities than the wild-type enzyme and exhibited pH-activity profiles similar to that of KF. On the basis of pH versus activity data and elemental effects obtained using short double-stranded DNA substrates terminating in phosphorothioate linkages, we suggest that the rate of the chemical step is reduced to the point where it becomes limiting with RB69 pol mutants K302A, Y323F, and E116A, in contrast to the wild-type enzyme where chemistry is faster than the rate-determining step that precedes it.     

Mutations in the spacer region of Drosophila mitochondrial DNA polymerase affect DNA binding, processivity, and the balance between Pol and Exo function

The catalytic subunit (alpha) of mitochondrial DNA polymerase (pol gamma) shares conserved DNA polymerase and 3'-5' exonuclease active site motifs with Escherichia coli DNA polymerase I and bacteriophage T7 DNA polymerase. A major difference between the prokaryotic and mitochondrial proteins is the size and sequence of the region between the exonuclease and DNA polymerase domains, referred to as the spacer in pol gamma-alpha. Four gamma-specific conserved sequence elements are located within the spacer region of the catalytic subunit in eukaryotic species from yeast to humans. To elucidate the functional roles of the spacer region, we pursued deletion and site-directed mutagenesis of Drosophila pol gamma. Mutant proteins were expressed from baculovirus constructs in insect cells, purified to near homogeneity, and analyzed biochemically. We find that mutations in three of the four conserved sequence elements within the spacer alter enzyme activity, processivity, and/or DNA binding affinity. In addition, several mutations affect differentially DNA polymerase and exonuclease activity and/or functional interactions with mitochondrial single-stranded DNA-binding protein. Based on these results and crystallographic evidence showing that the template-primer binds in a cleft between the exonuclease and DNA polymerase domains in family A DNA polymerases, we propose that conserved sequences within the spacer of pol gamma may position the substrate with respect to the enzyme catalytic domains.     

Use of 2-aminopurine fluorescence to study the role of the beta hairpin in the proofreading pathway catalyzed by the phage T4 and RB69 DNA polymerases

For DNA polymerases to proofread a misincorporated nucleotide, the terminal 3-4 nucleotides of the primer strand must be separated from the template strand before being bound in the exonuclease active center. Genetic and biochemical studies of the bacteriophage T4 DNA polymerase revealed that a prominent beta-hairpin structure in the exonuclease domain is needed to efficiently form the strand-separated exonuclease complexes. We present here further mutational analysis of the loop region of the T4 DNA polymerase beta-hairpin structure, which provides additional evidence that residues in the loop, namely, Y254 and G255, are important for DNA replication fidelity. The mechanism of strand separation was probed in in vitro reactions using the fluorescence of the base analogue 2-aminopurine (2AP) and mutant RB69 DNA polymerases that have modifications to the beta hairpin, to the exonuclease active site, or to both. We propose from these studies that the beta hairpin in the exonuclease domain of the T4 and RB69 DNA polymerases functions to facilitate strand separation, but residues in the exonuclease active center are required to capture the 3' end of the primer strand following strand separation.     

Caught bending the A-rule: crystal structures of translesion DNA synthesis with a non-natural nucleotide

Damage to DNA involving excision of the nucleobase at the N-glycosidic bond forms abasic sites. If a nucleotide becomes incorporated opposite an unrepaired abasic site during DNA synthesis, most B family polymerases obey the A-rule and preferentially incorporate dAMP without instruction from the template. In addition to being potentially mutagenic, abasic sites provide strong blocks to DNA synthesis. A previous crystal structure of an exonuclease deficient variant of the replicative B family DNA polymerase from bacteriophage RB69 (RB69 gp43 exo-) illustrated these properties, showing that the polymerase failed to translocate the DNA following insertion of dAMP opposite an abasic site. We examine four new structures depicting several steps of translesion DNA synthesis by RB69 gp43 exo-, employing a non-natural purine triphosphate analogue, 5-nitro-1-indolyl-2'-deoxyriboside-5'-triphosphate (5-NITP), that is incorporated more efficiently than dAMP opposite abasic sites. Our structures indicate that a dipole-induced dipole stacking interaction between the 5-nitro group and base 3' to the templating lesion explains the enhanced kinetics of 5-NITP. As with dAMP, the DNA fails to translocate following insertion of 5-NIMP, although distortions at the nascent primer terminus contribute less than previously thought in inducing the stall, given that 5-NIMP preserves relatively undistorted geometry at the insertion site following phosphoryl transfer. An open ternary configuration, novel in B family polymerases, reveals an initial template independent binding of 5-NITP adjacent to the active site of the open polymerase, suggesting that closure of the fingers domain shuttles the nucleotide to the active site while testing the substrate against the template.     

Crystal structure of DNA polymerase from hyperthermophilic archaeon Pyrococcus kodakaraensis KOD1

The crystal structure of family B DNA polymerase from the hyperthermophilic archaeon Pyrococcus kodakaraensis KOD1 (KOD DNA polymerase) was determined. KOD DNA polymerase exhibits the highest known extension rate, processivity and fidelity. We carried out the structural analysis of KOD DNA polymerase in order to clarify the mechanisms of those enzymatic features. Structural comparison of DNA polymerases from hyperthermophilic archaea highlighted the conformational difference in Thumb domains. The Thumb domain of KOD DNA polymerase shows an "opened" conformation. The fingers subdomain possessed many basic residues at the side of the polymerase active site. The residues are considered to be accessible to the incoming dNTP by electrostatic interaction. A beta-hairpin motif (residues 242-249) extends from the Exonuclease (Exo) domain as seen in the editing complex of the RB69 DNA polymerase from bacteriophage RB69. Many arginine residues are located at the forked-point (the junction of the template-binding and editing clefts) of KOD DNA polymerase, suggesting that the basic environment is suitable for partitioning of the primer and template DNA duplex and for stabilizing the partially melted DNA structure in the high-temperature environments. The stabilization of the melted DNA structure at the forked-point may be correlated with the high PCR performance of KOD DNA polymerase, which is due to low error rate, high elongation rate and processivity.     

Structural mechanism for coordination of proofreading and polymerase activities in archaeal DNA polymerases

A novel mechanism for controlling the proofreading and polymerase activities of archaeal DNA polymerases was studied. The 3'-5'exonuclease (proofreading) activity and PCR performance of the family B DNA polymerase from Thermococcus kodakaraensis KOD1 (previously Pyrococcus kodakaraensis KOD1) were altered efficiently by mutation of a "unique loop" in the exonuclease domain. Interestingly, eight different H147 mutants showed considerable variations in respect to their 3'-5'exonuclease activity, from 9% to 276%, as against that of the wild-type (WT) enzyme. We determined the 2.75A crystal structure of the H147E mutant of KOD DNA polymerase that shows 30% of the 3'-5'exonuclease activity, excellent PCR performance and WT-like fidelity. The structural data indicate that the properties of the H147E mutant were altered by a conformational change of the Editing-cleft caused by an interaction between the unique loop and the Thumb domain. Our data suggest that electrostatic and hydrophobic interactions between the unique loop of the exonuclease domain and the tip of the Thumb domain are essential for determining the properties of these DNA polymerases.     

A unique region in bacteriophage t7 DNA polymerase important for exonucleolytic hydrolysis of DNA

A crystal structure of the bacteriophage T7 gene 5 protein/Escherichia coli thioredoxin complex reveals a region in the exonuclease domain (residues 144-157) that is not present in other members of the E. coli DNA polymerase I family. To examine the role of this region, a genetically altered enzyme that lacked residues 144-157 (T7 polymerase (pol) Delta144-157) was purified and characterized biochemically. The polymerase activity and processivity of T7 pol Delta144-157 on primed M13 DNA are similar to that of wild-type T7 DNA polymerase implying that these residues are not important for DNA synthesis. The ability of T7 pol Delta144-157 to catalyze the hydrolysis of a phosphodiester bond, as judged from the rate of hydrolysis of a p-nitrophenyl ester of thymidine monophosphate, also remains unaffected. However, the 3'-5' exonuclease activity on polynucleotide substrates is drastically reduced; exonuclease activity on single-stranded DNA is 10-fold lower and that on double-stranded DNA is 20-fold lower as compared with wild-type T7 DNA polymerase. Taken together, our results suggest that residues 144-157 of gene 5 protein, although not crucial for polymerase activity, are important for DNA binding during hydrolysis of polynucleotides.     

Structural and biochemical investigation of the role in proofreading of a beta hairpin loop found in the exonuclease domain of a replicative DNA polymerase of the B family

Replicative DNA polymerases, as exemplified by the B family polymerases from bacteriophages T4 and RB69, not only replicate DNA but also have the ability to proofread misincorporated nucleotides. Because the two activities reside in separate protein domains, polymerases must employ a mechanism that allows for efficient switching of the primer strand between the two active sites to achieve fast and accurate replication. Prior mutational and structural studies suggested that a beta hairpin structure located in the exonuclease domain of family B polymerases might play an important role in active site switching in the event of a nucleotide misincorporation. We show that deleting the beta hairpin loop in RB69 gp43 affects neither polymerase nor exonuclease activities. Single binding event studies with mismatched primer termini, however, show that the beta hairpin plays a role in maintaining the stability of the polymerase/DNA interactions during the binding of the primer DNA in the exonuclease active site but not on the return of the corrected primer to the polymerase active site. In addition, the deletion variant showed a more stable incorporation of a nucleotide opposite an abasic site. Moreover, in the 2.4 A crystal structure of the beta hairpin deletion variant incorporating an A opposite a templating furan, all four molecules in the crystal asymmetric unit have DNA in the polymerase active site, despite the presence of DNA distortions because of the misincorporation, confirming that the primer strand is not stably bound within the exonuclease active site in the absence of the beta hairpin loop.     

In silico studies of the African swine fever virus DNA polymerase X support an induced-fit mechanism

The African swine fever virus DNA polymerase X (pol X), a member of the X family of DNA polymerases, is thought to be involved in base excision repair. Kinetics data indicate that pol X catalyzes DNA polymerization with low fidelity, suggesting a role in viral mutagenesis. Though pol X lacks the fingers domain that binds the DNA in other members of the X family, it binds DNA tightly. To help interpret details of this interaction, molecular dynamics simulations of free pol X at different salt concentrations and of pol X bound to gapped DNA, in the presence and in the absence of the incoming nucleotide, are performed. Anchors for the simulations are two NMR structures of pol X without DNA and a model of one NMR structure plus DNA and incoming nucleotide. Our results show that, in its free form, pol X can exist in two stable conformations that interconvert to one another depending on the salt concentration. When gapped double stranded DNA is introduced near the active site, pol X prefers an open conformation, regardless of the salt concentration. Finally, under physiological conditions, in the presence of both gapped DNA and correct incoming nucleotide, and two divalent ions, the thumb subdomain of pol X undergoes a large conformational change, closing upon the DNA. These results predict for pol X a substrate-induced conformational change triggered by the presence of DNA and the correct incoming nucleotide in the active site, as in DNA polymerase beta. The simulations also suggest specific experiments (e.g., for mutants Phe-102Ala, Val-120Gly, and Lys-85Val that may reveal crucial DNA binding and active-site organization roles) to further elucidate the fidelity mechanism of pol X.     

Kinetics of error generation in homologous B-family DNA polymerases

The kinetics of forming a proper Watson–Crick base pair as well incorporating bases opposite furan, an abasic site analog, have been well characterized for the B Family replicative DNA polymerase from bacteriophage T4. Structural studies of these reactions, however, have only been performed with the homologous enzyme from bacteriophage RB69. In this work, the homologous enzymes from RB69 and T4 were compared in parallel reactions to determine the relative abilities of the two polymerases to incorporate correct nucleotides as well as to form improper pairings. The kinetic rates for three different exonuclease mutants for each enzyme were measured for incorporation of an A opposite T and an A opposite furan as well as for the formation of A:C and T:T mismatches. The T4 exonuclease mutants were all ~2- to 7-fold more efficient than the corresponding RB69 exonuclease mutants depending on whether a T or furan was in the templating position and which exonuclease mutant was used. The rates for mismatch formation by T4 were significantly reduced compared with incorporation opposite furan, much more so than the corresponding RB69 mutant. These results show that there are kinetic differences between the two enzymes but they are not large enough to preclude structural assumptions for T4 DNA polymerase based on the known structure of the RB69 DNA polymerase.     

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.     

Characterization of a replicative DNA polymerase mutant with reduced fidelity and increased translesion synthesis capacity

Changing a highly conserved amino acid in motif A of any of the four yeast family B DNA polymerases, DNA polymerase alpha, delta, epsilon or zeta, results in yeast strains with elevated mutation rates. In order to better understand this phenotype, we have performed structure-function studies of homologous mutants of RB69 DNA polymerase (RB69 pol), a structural model for family B members. When Leu415 in RB69 pol is replaced with phenylalanine or glycine, the mutant polymerases retain high-catalytic efficiency for correct nucleotide incorporation, yet have increased error rates due to increased misinsertion, increased mismatch extension and inefficient proofreading. The Leu415Phe mutant also has increased dNTP insertion efficiency opposite a template 8-oxoG and opposite an abasic site. The 2.5 A crystal structure of a ternary complex of RB69 L415F pol with a correctly base-paired incoming dTTP reveals that the phenylalanine ring is accommodated within a cavity seen in the wild-type enzyme, without steric clash or major change in active site geometry, consistent with retention of high-catalytic efficiency for correct incorporation. In addition, slight structural differences were observed that could be relevant to the reduced fidelity of L415F RB69 pol.     

Family A and family B DNA polymerases are structurally related: evolutionary implications.

In order to establish the evolutionary relationship between the family A and B DNA polymerases, we have closely compared the 3'-->5' exonuclease domains between the Klenow fragment of E.coli DNA polymerase I (a family A DNA polymerase) and the bacteriophage PRD1 DNA polymerase, the smallest member of the DNA polymerase family B. Although the PRD1 DNA polymerase has a smaller 3'-->5' exonuclease domain, its active sites appear to be very similar to those of the Klenow fragment. Site-directed mutagenesis studies revealed that the residues important for the 3'-->5' exonuclease activity, particularly metal binding ligands for the Klenow fragment, are all conserved in the PRD1 DNA polymerase as well. The metal binding ligands are also essential for the strand-displacement activity of the PRD1 DNA polymerase. Based on these results and the studies by others in various systems, we conclude that family A and B DNA polymerases, at least in the 3'-->5' exonuclease domain, are structurally as well as evolutionarily related.     

The gamma subfamily of DNA polymerases: cloning of a developmentally regulated cDNA encoding Xenopus laevis mitochondrial DNA polymerase gamma.

We used the known sequence of the Saccharomyces cerevisiae DNA polymerase gamma to clone the genes or cDNAs encoding this enzyme in two other yeasts, Pychia pastoris and Schizosaccharomyces pombe, and one higher eukaryote, Xenopus laevis. To confirm the identity of the final X.laevis clone, two antisera raised against peptide sequences were shown to react with DNA polymerase gamma purified from X.laevis oocyte mitochondria. A developmentally regulated 4.6 kb mRNA is recognized on Northern blots of oocyte RNA using the X.laevis cDNA. Comparison of the four DNA polymerase gamma gene sequences revealed several highly conserved sequence blocks, comprising an N-terminal 3'-->5'exonuclease domain and a C-terminal polymerase active center interspersed with gamma-specific gene sequences. The consensus sequences for the DNA polymerase gamma exonuclease and polymerase domains show extensive sequence similarity to DNA polymerase I from Escherichia coli. Sequence conservation is greatest for residues located near the active centers of the exo and pol domains of the E.coli DNA polymerase I structure. The domain separating the exonuclease and polymerase active sites is larger in DNA polymerase gamma than in other members of family A (DNA polymerase I-like) polymerases. The S.cerevisiae DNA polymerase gamma is atypical in that it includes a 240 residue C-terminal extension that is not found in the other members of the DNA polymerase gamma family, or in other family A DNA polymerases.     

Domain exchange: chimeras of Thermus aquaticus DNA polymerase, Escherichia coli DNA polymerase I and Thermotoga neapolitana DNA polymerase

The intervening domain of the thermostable Thermus aquaticus DNA polymerase (TAQ: polymerase), which has no catalytic activity, has been exchanged for the 3'-5' exonuclease domain of the homologous mesophile Escherichia coli DNA polymerase I (E.coli pol I) and the homologous thermostable Thermotoga neapolitana DNA polymerase (TNE: polymerase). Three chimeric DNA polymerases have been constructed using the three-dimensional (3D) structure of the Klenow fragment of the E.coli pol I and 3D models of the intervening and polymerase domains of the TAQ: polymerase and the TNE: polymerase: chimera TaqEc1 (exchange of residues 292-423 from TAQ: polymerase for residues 327-519 of E.coli pol I), chimera TaqTne1 (exchange of residues 292-423 of TAQ: polymerase for residues 295-485 of TNE: polymerase) and chimera TaqTne2 (exchange of residues 292-448 of TAQ: polymerase for residues 295-510 of TNE: polymerase). The chimera TaqEc1 showed characteristics from both parental polymerases at an intermediate temperature of 50 degrees C: high polymerase activity, processivity, 3'-5' exonuclease activity and proof-reading function. In comparison, the chimeras TaqTne1 and TaqTne2 showed no significant 3'-5' exonuclease activity and no proof-reading function. The chimera TaqTne1 showed an optimum temperature at 60 degrees C, decreased polymerase activity compared with the TAQ: polymerase and reduced processivity. The chimera TaqTne2 showed high polymerase activity at 72 degrees C, processivity and less reduced thermostability compared with the chimera TaqTne1.     

Steady-state kinetic characterization of RB69 DNA polymerase mutants that affect dNTP incorporation.

The function of six highly conserved residues (Arg482, Lys483, Lys486, Lys560, Asn564, and Tyr567) in the fingers domain of bacteriophage RB69 DNA polymerase (RB69 gp43) were analyzed by kinetic studies with mutants in which each of these residues was replaced with Ala. Our results suggest that Arg482, Lys486, Lys560, and Asn564 contact the incoming dNTP during the nucleotidyl transfer reaction as judged by variations in apparent Km and kcat values for dNTP incorporation by these mutants compared to those for the exonuclease deficient parental polymerase under steady-state conditions. On the basis of our studies, as well as on the basis of the crystal structure of RB69 gp43, we propose that a conformational change in the fingers domain, which presumably occurs prior to polymerization, brings the side chains of Arg482, Lys486, Lys560, and Asn564 into the vicinity of the primer-template terminus where they can contact the triphosphate moiety of the incoming dNTP. In particular, on the basis of structural studies reported for the "closed" forms of two other DNA polymerases and from the kinetic studies reported here, we suggest that (i) Lys560 and Asn564 contact the nonbonding oxygens of the alpha and beta phosphates, respectively, and (ii) both Arg482 and Lys486 contact the gamma phosphate oxygens of the incoming dNTP of RB69 gp43 prior to the nucleotidyl transfer reaction. We also found that Ala substitutions at each of these four RB69 gp43 sites could incorporate dGDP as a substrate, although with markedly reduced efficiency compared to that with dGTP. In contrast in the parental exo- background, the K483A and Y567A substituted enzymes could not use dGDP as a substrate for primer extension. These results, taken together, are consistent with the putative roles of the four conserved residues in RB69 gp43 as stated above.     

Isolation and characterization of the thermostable DNA polymerase of the hyperthermophilic archaeum Thermococcus litoralis Sh1AM

Overall, 30 strains of hyperthermophilic archaea, representing seven species of the genera Thermococcus, Desulfurococcus, Thermoproteus, and Acidilobus, were tested for the presence of thermostable DNA polymerases. Thermostabilities of the polymerases varied distinctly among the strains within one species. Polymerases of five strains retained 60-100% activity upon incubation of the preparations at 95 degrees C for 120 min. A new DNA polymerase was isolated from the strain Thermococcus litoralis Sh1AM, possessing the enzyme with the most promising properties, and characterized. Molecular weight of the enzyme is 90-100 kDa. The purified DNA polymerase preserved 50% of the initial activity upon incubation at 95 degrees C for 120 min. The polymerase isolated displayed an associated 3'-5' exonuclease activity. The error rate when extending DNA strand was at least twofold lower compared with Taq polymerase. The main physicochemical and enzymatic properties of the new polymerase are similar to the known DNA polymerases of family B.