A conserved 3'----5' exonuclease active site in prokaryotic and eukaryotic DNA polymerases

The 3'----5' exonuclease active site of E. coli DNA polymerase I is predicted to be conserved for both prokaryotic and eukaryotic DNA polymerases based on amino acid sequence homology. Three amino acid regions containing the critical residues in the E. coli DNA polymerase I involved in metal binding, single-stranded DNA binding, and catalysis of the exonuclease reaction are located in the amino-terminal half and in the same linear arrangement in several prokaryotic and eukaryotic DNA polymerases. Site-directed mutagenesis at the predicted exonuclease active site of the phi 29 DNA polymerase, a model enzyme for prokaryotic and eukaryotic alpha-like DNA polymerases, specifically inactivated the 3'----5' exonuclease activity of the enzyme. These results reflect a high evolutionary conservation of this catalytic domain. Based on structural and functional data, a modular organization of enzymatic activities in prokaryotic and eukaryotic DNA polymerases is also proposed.     

Template recognition and chain elongation in DNA synthesis in vitro.

DNA polymerase from Escherichia coli (Pol I) and from avian myeloblastosis virus (AMV polymerase) were compared for the manner in which they catalyze the polymerization of deoxynucleotides upon a variety of synthetic and natural templates. It was found that the rates of nucleotide incorporation with different natural RNAs were similar. Both polymerases have an associated RNA endonuclease which hydrolyses RNA templates containing double-stranded regions. This activity depends on the presence of the complementary deoxynucleoside triphosphates, and/or polymerization. Both enzymes copy natural DNA, which has been sonicated and treated with E. coli exonuclease III, at the same rate. However, avian myeloblastosis virus DNA polymerase, which has no associated DNA exonuclease activity, is unable to copy double-stranded DNA and copies DNAase-treated DNA only 10% as well as Pol I. Pol I copied all the homopolymers investigated at a greater rate than AMV polymerase with the exception of poly(C) · oligo(dG). However, the initial rate of chain elongation, as measured by gel electrophoresis, was the same for the two polymerases, approximately 300 nucleotides incorporated per minute. Template saturation experiments show a stoichiometric relationship between template and enzyme at optimal rates of nucleotide incorporation which suggests that all enzyme molecules are potential catalysts. Enzyme saturation experiments indicate that not all enzyme molecules are “effectively” bound to a template. Fewer AMV polymerase than Pol I molecules are functionally bound to a particular template. From these data, it is concluded that the two polymerases elongate DNA chains in a similar way and that the manner in which the polymerases bind to a particular template accounts for the discrepancies found in their turnover numbers.     

Isolation and partial characterization of the multiple forms of deoxyribonucleic acid-dependent ribonucleic acid polymerase in the fungus Podospora anserina

Three DNA-dependent RNA polymerases have been isolated and partially purified from the mycelium of the fungus Podospora anserina. Separated by DEAE-Sephadex chromatography, they have been designated RNA polymerases I, II, and III according to their order of elution. Their catalytic properties and alpha-amanitin sensitivity are in agreement with those of the homologous enzymes found in other eukaryotic organisms. The three enzymes exhibit rather sharp monophasic ammonium sulfate dependence with optima which are, respectively, 0.035 M, 0.050 M, and 0.075 M. Enzyme I has the largest Mn2+/Mg2+ activity ratio, shows a marked preference for native DNA, and is insensitive to alpha-amanitin. Enzyme III uses poly(dA-dT) in preference to native DNA as template and is only partially sensitive to alpha-amanitin. Enzyme II is sensitive to alpha-amanitin, but high concentrations of the toxin are required for inhibition compared to other eukaryotic class II enzymes. Three similar RNA polymerases with comparable levels of activity were found in the temperature-dependent VR strain when cellular incompatibility, leading to a rapid cessation of RNA synthesis, was induced.     

Inhibition of DNA polymerase by captan

Captan inhibits DNA polymerases of both eukaryotic and prokaryotic sources. When polymerases were employed in assays with various polynucleotides as template-primer, no specificity in the base sequence of polynucleotide was required for inhibition. Sucrose gradient centrifugation and preincubation studies showed the inhibition was caused by an irreversible alteration of the polymerase. Captan and DNA compete for the same site on the polymerase, thus DNA can serve a protective role in the elimination of captan's action. The pyrophosphate exchange activity associated with the polymerase is not inhibited by captan and the fidelity with which DNA polymerase I copies the DNA template also is not altered by captan treatment.     

DNA polymerase epsilon: the latest member in the family of mammalian DNA polymerases

DNA polymerase epsilon is a mammalian polymerase that has a tightly associated 3'----5' exonuclease activity. Because of this readily detectable exonuclease activity, the enzyme has been regarded as a form of DNA polymerase delta, an enzyme which, together with DNA polymerase alpha, is in all probability required for the replication of chromosomal DNA. Recently, it was discovered that DNA polymerase epsilon is both catalytically and structurally distinct from DNA polymerase delta. The most striking difference between the two DNA polymerases is that processive DNA synthesis by DNA polymerase delta is dependent on proliferating cell nuclear antigen (PCNA), a replication factor, while DNA polymerase epsilon is inherently processive. DNA polymerase epsilon is required at least for the repair synthesis of UV-damaged DNA. DNA polymerases are highly conserved in eukaryotic cells. Mammalian DNA polymerases alpha, delta and epsilon are counterparts of yeast DNA polymerases I, III and II, respectively. Like DNA polymerases I and III, DNA polymerase II is also essential for the viability of cells, which suggests that DNA polymerase II (and epsilon) may play a role in DNA replication.     

Purification of DNA polymerase II, a distinct DNA polymerase, from Saccharomyces cerevisiae

Yeast DNA polymerases I and III have been well characterized physically, biochemically, genetically and immunologically. DNA polymerase II is present in very small amounts, and only partially purified preparations have been available for characterization, making comparison with DNA polymerases I and III difficult. Recently, we have shown that DNA polymerases II and III are genetically distinct (Sitney et al., 1989). In this work, we show that polymerase II is also genetically distinct from polymerase I, since polymerase II can be purified in equal amounts from wild-type and mutant strains completely lacking DNA polymerase I activity. Thus, yeast contains three major nuclear DNA polymerases. The core catalytic subunit of DNA polymerase II was purified to near homogeneity using a reconstitution assay. Two factors that stimulate the core polymerase were identified and used to monitor activity during purification and analysis. The predominant species of the most highly purified preparation of polymerase II is 132,000 Da. However, polymerase activity gels suggest that the 132,000-Da form of DNA polymerase II is probably an active proteolytic fragment derived from a 170,000-Da protein. The highly purified polymerase fractions contain a 3'----5'-exonuclease activity that purifies at a constant ratio with polymerase during the final two purification steps. However, DNA polymerase II does not copurify with a DNA primase activity.     

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.     

On the fidelity of DNA replication: herpes DNA polymerase and its associated exonuclease.

Procaryotic DNA polymerases contain an associated 3'----5' exonuclease activity which provides a proofreading function and contributes substantially to replication fidelity. DNA polymerases of the eucaryotic herpes-type viruses contain similar associated exonuclease activities. We have investigated the fidelity of polymerases purified from wild type herpes simplex virus, as well as from mutator and antimutator strains. On synthetic templates, the herpes enzymes show greater relative exonuclease activities, and greater ability to excise a terminal mismatched base, than procaryotic DNA polymerases which proofread. On a phi X174 natural DNA template, the herpes enzymes are more accurate than purified eucaryotic DNA polymerases; the error rate is similar to E. coli polymerase I. However, conditions which abnegate proofreading by E. coli polymerase I have little effect on the herpes enzymes. We conclude that either these viral polymerases are accurate in the absence of proofreading, or the conditions examined have little effect on proofreading by the herpes DNA polymerases.     

The hyperthermophilic archaeon Pyrodictium occultum has two alpha-like DNA polymerases.

We cloned two genes encoding DNA polymerases from the hyperthermophilic archaeon Pyrodictium occultum. The deduced primary structures of the two gene products have several amino acid sequences which are conserved in the alpha-like (family B) DNA polymerases. Both genes were expressed in Escherichia coli, and highly purified gene products, DNA polymerases I and II (pol I and pol II), were biochemically characterized. Both DNA polymerase activities were heat stable, but only pol II was sensitive to aphidicolin. Both pol I and pol II have associated 5'-->3' and 3'-->5' exonuclease activities. In addition, these DNA polymerases have higher affinity to single-primed single-stranded DNA than to activated DNA; even their primer extension abilities by themselves were very weak. A comparison of the complete amino acid sequences of pol I and pol II with two alpha-like DNA polymerases from yeast cells showed that both pol I and pol II were more similar to yeast DNA polymerase III (ypol III) than to yeast DNA polymerase II (ypol II), in particular in the regions from exo II to exo III and from motif A to motif C. However, comparisons region by region of each polymerase showed that pol I was similar to ypol II and pol II was similar to ypol III from motif C to the C terminus. In contrast, pol I and pol II were similar to ypol III and ypol II, respectively, in the region from exo III to motif A. These findings suggest that both enzymes from P. occultum play a role in the replication of the genomic DNA of this organism and, furthermore, that the study of DNA replication in this thermophilic archaeon may lead to an understanding of the prototypical mechanism of eukaryotic DNA replication.     

A DNA polymerase from a thermoacidophilic archaebacterium: evolutionary and technological interests

The archaebacteria constitute a group of prokaryotes with an intermediate phylogenetic position between eukaryotes and eubacteria. The study of their DNA polymerases may provide valuable information about putative evolutionary relationships between prokaryotic and eukaryotic DNA polymerases. As a first step towards this goal, we have purified to near homogeneity a DNA polymerase from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius. This enzyme is a monomeric protein of 100 kDa which can catalyze DNA synthesis using either activated calf thymus DNA or oligonucleotide-primed single-stranded DNA as a template. The activity is optimal at 70 degrees C and the enzyme is thermostable up to 80 degrees C; however, it can still polymerize up to 200 nucleotides at 100 degrees C. These remarkable thermophilic properties and thermostability permit examination of the mechanism of DNA synthesis under conditions of decreased stability of the DNA helix. Furthermore, these properties make S. acidocaldarius DNA polymerase a very efficient enzyme to be used in DNA amplification by the recently developed polymerase chain reaction method (PCR) as well as in the Sanger DNA sequencing technique.     

DNA polymerase delta: a second eukaryotic DNA replicase

During the past few years significant progress has been made in our understanding of the structure and function of the proteins involved in eukaryotic DNA replication. Data from several laboratories suggest that, in contrast to prokaryotic DNA replication, two distinct DNA polymerases are required for eukaryotic DNA replication, i.e. DNA polymerase delta for the synthesis of the leading strand and DNA polymerase alpha for the lagging strand. Several accessory proteins analogous to prokaryotic replication factors have been identified and some of these are specific for pol delta whereas others affect both DNA replicases. The replicases and their accessory proteins appear to be highly conserved in eukaryotes, as homologous proteins have been found in species ranging from humans to yeast.     

Phosphorylation of yeast DNA-dependent RNA polymerases in vivo and in vitro. Isolation of enzymes and identification of phosphorylated subunits.

Yeast DNA-dependent RNA polymerases I, II, and III are phosphorylated in vivo. Yeast cells were grown continuously in 32Pi and the RNA polymerases were isolated by a new procedure which allows the simultaneous purification of these enzymes from small quantities (35 to 60 g) of cells. Each of the RNA polymerases was phosphorylated. The following phosphorylated polymerase polypeptides were identified: polymerase I subunits of 185,000, 44,000, 36,000, 24,000, and 20,000 daltons; a polymerase II subunit of 24,000 daltons; and polymerase III subunits of 24,000 and 20,000 daltons. The incorporated 32P was acid-stable but base-labile. Phosphoserine and phosphothreonine were identified after partial acid hydrolysis of purified [32P]polymerase I. A yeast protein kinase that co-purifies with polymerase I during part of the isolation procedure was partially purified and characterized. This protein kinase phosphorylates the subunits of the purified polymerases that are phosphorylated in vivo and, in addition, a polymerase I subunit of 48,000 daltons and a polymerase II subunit of 33,500 daltons. Phosphorylation of the purified enzymes with this protein kinase had no substantial effect on polymerase activity in simple assays using native yeast DNA as a template. Preincubation of purified polymerase I with acid or alkaline phosphatase also had no detectable effect on polymerase activity.     

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.     

DNA polymerase III, a second essential DNA polymerase, is encoded by the S. cerevisiae CDC2 gene

Three nuclear DNA polymerases have been described in yeast: DNA polymerases I, II, and III. DNA polymerase I is encoded by the POL1 gene and is essential for DNA replication. Since the S. cerevisiae CDC2 gene has recently been shown to have DNA sequence similarity to the active site regions of other known DNA polymerases, but to nevertheless be different from DNA polymerase I, we examined cdc2 mutants for the presence of DNA polymerases II and III. DNA polymerase II was not affected by the cdc2 mutation. DNA polymerase III activity was significantly reduced in the cdc2-1 cell extracts. We conclude that the CDC2 gene encodes yeast DNA polymerase III and that DNA polymerase III, therefore, represents a second essential DNA polymerase in yeast.     

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     

DNA polymerase I is required for premeiotic DNA replication and sporulation but not for X-ray repair in Saccharomyces cerevisiae.

We have used a set of seven temperature-sensitive mutants in the DNA polymerase I gene of Saccharomyces cerevisiae to investigate the role of DNA polymerase I in various aspects of DNA synthesis in vivo. Previously, we showed that DNA polymerase I is required for mitotic DNA replication. Here we extend our studies to several stages of meiosis and repair of X-ray-induced damage. We find that sporulation is blocked in all of the DNA polymerase temperature-sensitive mutants and that premeiotic DNA replication does not occur. Commitment to meiotic recombination is only 2% of wild-type levels. Thus, DNA polymerase I is essential for these steps. However, repair of X-ray-induced single-strand breaks is not defective in the DNA polymerase temperature-sensitive mutants, and DNA polymerase I is therefore not essential for repair of such lesions. These results suggest that DNA polymerase II or III or both, the two other nuclear yeast DNA polymerases for which roles have not yet been established, carry out repair in the absence of DNA polymerase I, but that DNA polymerase II and III cannot compensate for loss of DNA polymerase I in meiotic replication and recombination. These results do not, however, rule out essential roles for DNA polymerase II or III or both in addition to that for DNA polymerase I.