NORMAL GENOMIC

• Hashimoto H et al.
• Crystal structure of DNA polymerase from hyperthermophilic archaeon Pyrococcus kodakaraensis KOD1.
• J Mol Biol. 2001; 306: 469-77
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• 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.

• Zheng R et al.
• The novel function of a short region K253xRxxxD259 conserved in the exonuclease domain of hyperthermostable DNA polymerase I from Pyrococcus horikoshii.
• Extremophiles. 2001; 5: 111-7
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• The DNA polymerase gene of the hyperthermophile Pyrococcus horikoshii was successfully overexpressed after removing an intein. The importance of an amino acid sequence around a highly conserved Asp was studied by site-directed mutagenesis. The results indicated that Lys253, Arg255, and Asp259 form a novel functional motif, K253xRxxxD259 (outside known motifs Exo I, II, and III), that is important not only for exonuclease activity but also for polymerizing activity, confirming functional interdependence between the polymerase and exonuclease domains. The short loop region, K253G254R255, probably contributes to binding to DNA substrates. Moreover, the negative charge and the side-chain length of D259 might play a supporting role in coordinating the conserved Mg2+ to the correct position at the active center in the exonuclease domain.

• Patel PH, Loeb LA
• DNA polymerase active site is highly mutable: evolutionary consequences.
• Proc Natl Acad Sci U S A. 2000; 97: 5095-100
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• DNA polymerases contain active sites that are structurally superimposable and highly conserved in sequence. To assess the significance of this preservation and to determine the mutational burden that active sites can tolerate, we randomly mutated a stretch of 13 amino acids within the polymerase catalytic site (motif A) of Thermus aquaticus DNA polymerase I. After selection, by using genetic complementation, we obtained a library of approximately 8, 000 active mutant DNA polymerases, of which 350 were sequenced and analyzed. This is the largest collection of physiologically active polymerase mutants. We find that all residues of motif A, except one (Asp-610), are mutable while preserving wild-type activity. A wide variety of amino acid substitutions were obtained at sites that are evolutionarily maintained, and conservative substitutions predominate at regions that stabilize tertiary structures. Several mutants exhibit unique properties, including DNA polymerase activity higher than the wild-type enzyme or the ability to incorporate ribonucleotide analogs. Bacteria dependent on these mutated polymerases for survival are fit to replicate repetitively. The high mutability of the polymerase active site in vivo and the ability to evolve altered enzymes may be required for survival in environments that demand increased mutagenesis. The inherent substitutability of the polymerase active site must be addressed relative to the constancy of nucleotide sequence found in nature.

• Singh K, Modak MJ
• A unified DNA- and dNTP-binding mode for DNA polymerases.
• Trends Biochem Sci. 1998; 23: 277-81
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• Crystal structures of various DNA polymerases show a common structural topology that resembles a right hand and has distinct finger, palm and thumb subdomains. Early models of the klenow fragment (KF) of Escherichia coli polymerase I showed DNA entering a large cleft that faces the palm subdomain where the catalytic site is situated1,2. However, subsequent resolution of the structures of HIV-1 reverse transcriptase, KF and polymerase beta (pol beta) bound to DNA3-5 yielded conflicting data that suggested a different orientation for DNA bound to pol beta compared with DNA bound to other polymerases. The debate, on the correct orientation of the template-primer DNA, that followed failed to reach a consensus. Using an alternative superposition scheme, we now provide convincing evidence for a common DNA-binding mode that is applicable to all polymerases, including pol beta.

• Zhu W, Ito J
• Family A and family B DNA polymerases are structurally related: evolutionary implications.
• Nucleic Acids Res. 1994; 22: 5177-83
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• 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.

• Delarue M, Poch O, Tordo N, Moras D, Argos P
• An attempt to unify the structure of polymerases.
• Protein Eng. 1990; 3: 461-7
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• With the great availability of sequences from RNA- and DNA-dependent RNA and DNA polymerases, it has become possible to delineate a few highly conserved regions for various polymerase types. In this work a DNA polymerase sequence from bacteriophage SPO2 was found to be homologous to the polymerase domain of the Klenow fragment of polymerase I from Escherichia coli, which is known to be closely related to those from Staphylococcus pneumoniae, Thermus aquaticus and bacteriophages T7 and T5. The alignment of the SPO2 polymerase with the other five sequences considerably narrowed the conserved motifs in these proteins. Three of the motifs matched reasonably all the conserved motifs of another DNA polymerase type, characterized by human polymerase alpha. It is also possible to find these three motifs in monomeric DNA-dependent RNA polymerases and two of them in DNA polymerase beta and DNA terminal transferases. These latter two motifs also matched two of the four motifs recently identified in 84 RNA-dependent polymerases. From the known tertiary architecture of the Klenow fragment of E. coli pol I, a spatial arrangement can be implied for these motifs. In addition, numerous biochemical experiments suggesting a role for the motifs in a common function (dNTP binding) also support these inferences. This speculative hypothesis, attempting to unify polymerase structure at least locally, if not globally, under the pol I fold, should provide a useful model to direct mutagenesis experiments to probe template and substrate specificity in polymerases.