Phosphoesterase domains associated with DNA polymerases of diverse origins.

Computer analysis of DNA polymerase protein sequences revealed previously unidentified conserved domains that belong to two distinct superfamilies of phosphoesterases. The alpha subunits of bacterial DNA polymerase III and two distinct family X DNA polymerases are shown to contain an N-terminal domain that defines a novel enzymatic superfamily, designated PHP, after polymerase and histidinol phosphatase. The predicted catalytic site of the PHP superfamily consists of four motifs containing conserved histidine residues that are likely to be involved in metal-dependent catalysis of phosphoester bond hydrolysis. The PHP domain is highly conserved in all bacterial polymerase III alpha subunits, but in proteobacteria and mycoplasmas, the conserved motifs are distorted, suggesting a loss of the enzymatic activity. Another conserved domain, found in the small subunits of archaeal DNA polymerase II and eukaryotic DNA polymerases alpha and delta, is shown to belong to the superfamily of calcineurin-like phospho-esterases, which unites a variety of phosphatases and nucleases. The conserved motifs required for phospho-esterase activity are intact in the archaeal DNA polymerase subunits, but are disrupted in their eukaryotic orthologs. A hypothesis is proposed that bacterial and archaeal replicative DNA polymerases possess intrinsic phosphatase activity that hydrolyzes the pyrophosphate released during nucleotide polymerization. As proposed previously, pyrophosphate hydrolysis may be necessary to drive the polymerization reaction forward. The phosphoesterase domains with disrupted catalytic motifs may assume an allosteric, regulatory function and/or bind other subunits of DNA polymerase holoenzymes. In these cases, the pyrophosphate may be hydrolyzed by a stand-alone phosphatase, and candidates for such a role were identified among bacterial PHP superfamily members.     

Novel structure of an N-terminal domain that is crucial for the dimeric assembly and DNA-binding of an archaeal DNA polymerase D large subunit from Pyrococcus horikoshii

Archaea-specific D-family DNA polymerase forms a heterotetramer consisting of two large polymerase subunits and two small exonuclease subunits. The N-terminal (1–300) domain structure of the large subunit was determined by X-ray crystallography, although ∼50 N-terminal residues were disordered. The determined structure consists of nine alpha helices and three beta strands. We also identified the DNA-binding ability of the domain by SPR measurement. The N-terminal (1–100) region plays crucial roles in the folding of the large subunit dimer by connecting the ∼50 N-terminal residues with their own catalytic region (792–1163).

Structured summary

DP2binds to DP2 by molecular sieving(View interaction)DP2binds to DP2 by fluorescence technology(View interaction)DP2binds to DP2 by circular dichroism(View interaction)     

Characterization of two DNA polymerases from the hyperthermophilic euryarchaeon Pyrococcus abyssi.

The complete genome sequence of the hyperthermophilic archaeon Pyrococcus abyssi revealed the presence of a family B DNA polymerase (Pol I) and a family D DNA polymerase (Pol II). To extend our knowledge about euryarchaeal DNA polymerases, we cloned the genes encoding these two enzymes and expressed them in Escherichia coli. The DNA polymerases (Pol I and Pol II) were purified to homogeneity and characterized. Pol I had a molecular mass of approximately 90 kDa, as estimated by SDS/PAGE. The optimum pH and Mg(2+) concentration of Pol I were 8.5-9.0 and 3 mm, respectively. Pol II is composed of two subunits that are encoded by two genes arranged in tandem on the P. abyssi genome. We cloned these genes and purified the Pol II DNA polymerase from an E. coli strain coexpressing the cloned genes. The optimum pH and Mg(2+) concentration of Pol II were 6.5 and 15-20 mm, respectively. Both P. abyssi Pol I and Pol II have associated 3'-->5' exonuclease activity although the exonuclease motifs usually found in DNA polymerases are absent in the archaeal family D DNA polymerase sequences. Sequence analysis has revealed that the small subunit of family D DNA polymerase and the Mre11 nucleases belong to the calcineurin-like phosphoesterase superfamily and that residues involved in catalysis and metal coordination in the Mre11 nuclease three-dimensional structure are strictly conserved in both families. One hypothesis is that the phosphoesterase domain of the small subunit is responsible for the 3'-->5' exonuclease activity of family D DNA polymerase. These results increase our understanding of euryarchaeal DNA polymerases and are of importance to push forward the complete understanding of the DNA replication in P. abyssi.     

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.     

Mapping of Rpb3 and Rpb5 contact sites on two large subunits, Rpb1 and Rpb2, of the RNA polymerase II from fission yeast

[Rpb1 and Rpb2] Mapping of the contact sites␣on two large subunits of the fission yeast Schizosaccharomyces pombe RNA polymerase II with two small subunits, Rpb3 and Rpb5, was carried out using the two-hybrid screening system in the budding yeast Saccharomyces cerevisiae. Rpb5 was found to interact with any fragment of Rpb1 that contained the region H, which is conserved among the subunit 1 homologues of all RNA polymerases, including the β' subunit of prokaryotic RNA polymerases. In agreement with the fact that Rpb5 is shared among all three forms of eukaryotic RNA polymerases, the region H of RNA polymerase I subunit 1 (Rpa190) was also found to interact with Rpb5. On the other hand, two-hybrid screening of Rpb2 fragments from RNA polymerase II indicated the presence of an Rpb3 contact site in the region H which is conserved among the subunit 2 homologues of all RNA polymerases, including the β subunit of prokaryotic RNA polymerases. Possible functions of the regions H in the subunits 1 and 2 are discussed. Received: 10 December 1997 / Accepted: 14 April 1998     

Unstructured N terminus of the RNA polymerase II subunit Rpb4 contributes to the interaction of Rpb4.Rpb7 subcomplex with the core RNA polymerase II of Saccharomyces cerevisiae

Two subunits of eukaryotic RNA polymerase II, Rpb7 and Rpb4, form a subcomplex that has counterparts in RNA polymerases I and III. Although a medium resolution structure has been solved for the 12-subunit RNA polymerase II, the relative contributions of the contact regions between the subcomplex and the core polymerase and the consequences of disrupting them have not been studied in detail. We have identified mutations in the N-terminal ribonucleoprotein-like domain of Saccharomyces cerevisiae Rpb7 that affect its role in certain stress responses, such as growth at high temperature and sporulation. These mutations increase the dependence of Rpb7 on Rpb4 for interaction with the rest of the polymerase. Complementation analysis and RNA polymerase pulldown assays reveal that the Rpb4.Rbp7 subcomplex associates with the rest of the core RNA polymerase II through two crucial interaction points: one at the N-terminal ribonucleoprotein-like domain of Rpb7 and the other at the partially ordered N-terminal region of Rpb4. These findings are in agreement with the crystal structure of the 12-subunit polymerase. We show here that the weak interaction predicted for the N-terminal region of Rpb4 with Rpb2 in the crystal structure actually plays a significant role in interaction of the subcomplex with the core in vivo. Our mutant analysis also suggests that Rpb7 plays an essential role in the cell through its ability to interact with the rest of the polymerase.     

Cloning and chromosomal mapping of the human DNA polymerase theta (POLQ), the eighth human DNA polymerase.

We have cloned the cDNA for the eighth human DNA polymerase, DNA polymerase θ. The human cDNA encodes a putative DNA polymerase of 1762 amino acids with a calculated molecular mass of 198 kDa. The derived protein sequence is homologous to the Drosophila melanogaster mus308 protein product, a putative DNA polymerase-helicase involved in repair of interstrand crosslinks. The C-terminal region contains the canonical DNA polymerase motifs A, B, and C found in the family A type of DNA polymerases, which includes Escherichia coli polymerase I. The N-terminal region contains a putative ATP binding domain but not motifs for a helicase. The gene was mapped by radiation hybrid analysis to chromosome 3q within an interval flanked by proximal marker D3S1303 and distal marker D3S3576 and, based on proximity to a gene that has been mapped cytogenetically, within band 3q13.31.     

Three Residues of the Interdomain Linker Determine the Conformation and Single-base Deletion Fidelity of Y-family Translesion Polymerases

Dpo4 and Dbh are from two closely related Sulfolobus species and are well studied archaeal homologues of pol IV, an error prone Y-family polymerase from Escherichia coli. Despite sharing 54% amino acid identity, these polymerases display distinct mutagenic and translesion specificities. Structurally, Dpo4 and Dbh adopt different conformations because of the difference in relative orientation of their N-terminal catalytic and C-terminal DNA binding domains. Using chimeric constructs of these two polymerases, we have previously demonstrated that the interdomain linker is a major determinant of polymerase conformation, base-substitution fidelity, and abasic-site translesion synthesis. Here we find that the interdomain linker also affects the single-base deletion frequency and the mispair extension efficiency of these polymerases. Exchanging just three amino acids in the linkers of Dbh and Dpo4 is sufficient to change the fidelity by up to 30-fold, predominantly by altering the rate of correct (but not incorrect) nucleotide incorporation. Additionally, from a 2.4 Å resolution crystal structure, we have found that the three linker amino acids from Dpo4 are sufficient to allow Dbh to adopt the standard conformation of Dpo4. Thus, a small region of the interdomain linker, located more than 11 Å away from the catalytic residues, determines the fidelity of these Y-family polymerases, by controlling the alignment of substrates at the active site.     

Comparison of the kinetic parameters of the truncated catalytic subunit and holoenzyme of human DNA polymerase ɛ

Numerous genetic studies have provided compelling evidence to establish DNA polymerase ɛ (Polɛ) as the primary DNA polymerase responsible for leading strand synthesis during eukaryotic nuclear genome replication. Polɛ is a heterotetramer consisting of a large catalytic subunit that contains the conserved polymerase core domain as well as a 3′ → 5′ exonuclease domain common to many replicative polymerases. In addition, Polɛ possesses three small subunits that lack a known catalytic activity but associate with components involved in a variety of DNA replication and maintenance processes. Previous enzymatic characterization of the Polɛ heterotetramer from budding yeast suggested that the small subunits slightly enhance DNA synthesis by Polɛ in vitro. However, similar studies of the human Polɛ heterotetramer (hPolɛ) have been limited by the difficulty of obtaining hPolɛ in quantities suitable for thorough investigation of its catalytic activity. Utilization of a baculovirus expression system for overexpression and purification of hPolɛ from insect host cells has allowed for isolation of greater amounts of active hPolɛ, thus enabling a more detailed kinetic comparison between hPolɛ and an active N-terminal fragment of the hPolɛ catalytic subunit (p261N), which is readily overexpressed in Escherichia coli. Here, we report the first pre-steady-state studies of fully-assembled hPolɛ. We observe that the small subunits increase DNA binding by hPolɛ relative to p261N, but do not increase processivity during DNA synthesis on a single-stranded M13 template. Interestingly, the 3′ → 5′ exonuclease activity of hPolɛ is reduced relative to p261N on matched and mismatched DNA substrates, indicating that the presence of the small subunits may regulate the proofreading activity of hPolɛ and sway hPolɛ toward DNA synthesis rather than proofreading.     

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.     

Evidence favouring the hypothesis of a conserved 3'-5' exonuclease active site in DNA-dependent DNA polymerases.

The complete amino acid (aa) alignment of the N-terminal domain of 33 DNA-dependent DNA polymerases encompassing the putative segments Exo I, Exo II and Exo III, proposed by Bernad et al. [Cell 59 (1989) 219-228] to form a conserved 3'-5' exonuclease active site in prokaryotic and eukaryotic DNA polymerases, allowed us to identify and/or correct some of the most conserved segments (Exo I, II and III) in certain DNA polymerases. In particular, the aa region of T4 DNA polymerase and other eukaryotic (viral and cellular) DNA polymerases previously proposed as Exo I segment 1, did not align with the Exo I segment of Escherichia coli DNA polymerase I (PolI)-like and protein-primed DNA polymerases; instead, a new conserved region of aa similarity was identified in T4 DNA polymerase and eukaryotic (viral and cellular) DNA polymerases as their corresponding Exo I segment. Therefore, according to our alignment, the recently reported T4 DNA polymerase site-directed mutants, D189A and E191A [Reha-Krantz et al., Proc. Natl. Acad. Sci. USA 88 (1991) 2417-2421], do not correspond to what we now consider the critical Exo I motif of PolI. As discussed in this communication, the functional importance of conserved segments Exo I, Exo II and Exo III is supported by site-directed mutagenesis in PolI, and in phi 29, T7 and delta(Sc) DNA polymerases. Furthermore, genetically selected T4 DNA polymerase mutator mutants form two main clusters, centered in the conserved segment Exo III and in the newly identified Exo I segment.     

The herpes simplex virus DNA polymerase: Analysis of the functional domains

The structural and functional organization of the herpes simplex virus type I (HSV-1) DNA polymerase enzyme of strain ANG was studied by a combination of sequence and immunobiochemical analyses. Comparison of the HSV-1 ANG DNA polymerase sequence with those of pro- and eukaryotic DNA polymerases resulted in the allocation of eleven conserved regions within the HSV-1 DNA polymerase. From the analysis of all currently identified mutations of temperature-sensitive and drug-resistant HSV-1 DNA polymerase mutants as well as from the degree of conservancy observed, it could be deduced that the amino-acid residues 597–961, comprising the homologous sequence regions IV–IX, constitute the major structural components of the catalytic domain of the enzyme which should accommodate the sites for polymerizing and 3′-to-5′ exonucleolytic functions. Further insight into the structural organization was gained by the use of polyclonal antibodies responding specifically to the N-terminal, central and C-terminal polypeptide domains of the ANG polymerase. Each of the antisera was able to immunostain as well as to immunoprecipitate a viral polypeptide of 132 ± 5 kDa that corresponded well to the molecular mass of 136 kDa predicted from the coding sequences. Enzyme-binding and neutralization studies confirmed that both functions, polymerase and 3′-to-5′ exonuclease, are intimately related to each other, and revealed that, in addition to the sequences of the proposed catalytic domain, the very C-terminal sequences, except for amino-acid residues 1072–1146, are important for the catalytic functions of the enzyme, most likely effecting the binding to DNA.     

Immunological relationships between Artemia RNA polymerases and between RNA polymerases II from different eukaryotic organisms

Summary Rabbit antibodies against Artemia RNA polymerase II have been raised and utilized to study the immunological relationships between the subunits from RNA polymerases I, II and III from this organism and RNA polymerase II from other eukaryotes. We describe here for the first time the subunit structure of Artemia RNA polymerases I and III. These enzymes have 9 and 13 subunits respectively. The anti-RNA polymerase II antibodies recognize two subunits of 19.4 and 18 kDa common to the three enzymes, and another subunit of 25.6 kDa common to RNA polymerases II and III. The antibodies against Artemia RNA polymerase II also react with the subunits of high molecular weight and with subunits of around 25 and 33 kDa of RNA polymerase II from other eukaryotes (Drosophila melanogaster, Chironomus thummi, triticum (wheat) and Rattus (rat)). This interspecies relatedness is a common feature of eukaryotic RNA polymerases.Abbreviations RNAp RNA polymerase - DPT diazophenylthioether - SDS sodium dodecylsulfate     

X-ray structure of the complex of regulatory subunits of human DNA polymerase delta

The eukaryotic DNA polymerase delta (Pol delta) participates in genome replication, homologous recombination, DNA repair and damage tolerance. Regulation of the plethora of Pol delta functions depends on the interaction between the second (p50) and third (p66) non-catalytic subunits. We report the crystal structure of p50p66N complex featuring oligonucleotide binding and phosphodiesterase domains in p50 and winged helix-turn-helix N-terminal domain in p66. Disruption of the interaction between the yeast orthologs of p50 and p66 by strategic amino acid changes leads to cold-sensitivity, sensitivity to hydroxyurea and to reduced UV mutagenesis, mimicking the phenotypes of strains where the third subunit of Pol delta is absent. The second subunits of all B-family replicative DNA polymerases in archaea and eukaryotes, except Pol delta, share a three-domain structure similar to p50p66N, raising the possibility that a portion of the gene encoding p66 was derived from the second subunit gene relatively late in evolution.     

Constitution of the twin polymerase of DNA polymerase III holoenzyme

It is speculated that DNA polymerases which duplicate chromosomes are dimeric to provide concurrent replication of both leading and lagging strands. DNA polymerase III holoenzyme (holoenzyme), is the 10-subunit replicase of the Escherichia coli chromosome. A complex of the alpha (DNA polymerase) and epsilon (3'-5' exonuclease) subunits of the holoenzyme contains only one of each protein. Presumably, one of the eight other subunit(s) functions to dimerize the alpha epsilon polymerase within the holoenzyme. Based on dimeric subassemblies of the holoenzyme, two subunits have been elected as possible agents of polymerase dimerization, one of which is the tau subunit (McHenry, C. S. (1982) J. Biol. Chem. 257, 2657-2663). Here, we have used pure alpha, epsilon, and tau subunits in binding studies to determine whether tau can dimerize the polymerase. We find tau binds directly to alpha. Whereas alpha is monomeric, tau is a dimer in its native state and thereby serves as an efficient scaffold to dimerize the polymerase. The epsilon subunit does not associate directly with tau but becomes dimerized in the alpha epsilon tau complex by virtue of its interaction with alpha. We have analyzed the dimeric alpha epsilon tau complex by different physical methods to increase the confidence that this complex truly contains a dimeric polymerase. The tau subunit is comprised of the NH2-terminal two-thirds of tau but does not bind to alpha epsilon, identifying the COOH-terminal region of tau as essential to its polymerase dimerization function. The significance of these results with respect to the organization of subunits within the holoenzyme is discussed.     

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.