Human DNA polymerase alpha gene expression is cell proliferation dependent and its primary structure is similar to both prokaryotic and eukaryotic replicative DNA polymerases.

We have isolated cDNA clones encoding the human DNA polymerase alpha catalytic polypeptide. Studies of the human DNA polymerase alpha steady-state mRNA levels in quiescent cells stimulated to proliferate, or normal cells compared to transformed cells, demonstrate that the polymerase alpha mRNA, like its enzymatic activity and de novo protein synthesis, positively correlates with cell proliferation and transformation. Analysis of the deduced 1462-amino-acid sequence reveals six regions of striking similarity to yeast DNA polymerase I and DNA polymerases of bacteriophages T4 and phi 29, herpes family viruses, vaccinia virus and adenovirus. Three of these conserved regions appear to comprise the functional active site required for deoxynucleotide interaction. Two putative DNA interacting domains are also identified.     

The fidelity of DNA synthesis by eukaryotic replicative and translesion synthesis polymerases

In their seminal publication describing the structure of the DNA double helix , Watson and Crick wrote what may be one of the greatest understatements in the scientific literature, namely that ＂It has not escaped our notice that the specific pairing we have postulated immediately suggests a possible copying mechanism for the genetic material.＂ Half a century later, we more fully appreciate what a huge challenge it is to replicate six billion nucleotides with the accuracy needed to stably maintain the human genome over many generations. This challenge is perhaps greater than was realized 50 years ago, because subsequent studies have revealed that the genome can be destabilized not only by environmental stresses that generate a large number and variety of potentially cytotoxic and mutagenic lesions in DNA but also by various sequence motifs of normal DNA that present challenges to replication. Towards a better understanding of the many determinants of genome stability, this chapter reviews the fidelity with which undamaged and damaged DNA is copied, with a focus on the eukaryotic B- and Y-family DNA polymerases, and considers how this fidelity is achieved.     

The DNA polymerase III holoenzyme: an asymmetric dimeric replicative complex with leading and lagging strand polymerases.

The DNA Polymerase III holoenzyme forms initiation complexes on primed DNA in an ATP-dependent reaction. We demonstrate that the nonhydrolyzable ATP analog, ATP gamma S, supports the formation of an isolable leading strand complex that loads and replicates the lagging strand only in the presence of ATP, beta, and the single-stranded DNA binding protein. The single endogenous DnaX complex within DNA polymerase III holoenzyme assembles beta onto both the leading and lagging strand polymerases by an ordered mechanism. The dimeric replication complex disassembles in the opposite order from which it assembled. Upon ATP gamma S-induced dissociation, the leading strand polymerase is refractory to disassembly allowing cycling to occur exclusively on the lagging strand. These results establish holoenzyme as an intrinsic asymmetric dimer with distinguishable leading and lagging strand polymerases.     

Human DNA polymerase epsilon is expressed during cell proliferation in a manner characteristic of replicative DNA polymerases.

In order to shed light on the role of mammalian DNA polymerase epsilon we studied the expression of mRNA for the human enzyme during cell proliferation and during the cell cycle. Steady-state levels of mRNA encoding DNA polymerase epsilon were elevated dramatically when quiescent (G0) cells were stimulated to proliferate (G1/S) in a similar manner to those of DNA polymerase alpha. Message levels of DNA polymerase beta were unchanged in similar experiments. The concentration of immunoreactive DNA polymerase epsilon was also much higher in extracts from proliferating tissues than in those from non-proliferating or slowly proliferating tissues. The level of DNA polymerase epsilon mRNA in actively cycling cells synchronized with nocodazole and in cells fractionated by counterflow centrifugal elutriation showed weaker variation, being at its highest at the G1/S stage boundary. The results presented strongly suggest that mammalian DNA polymerase epsilon is involved in the replication of chromosomal DNA and/or in a repair process that may be substantially activated during the replication of chromosomal DNA. A hypothetical role for DNA polymerase epsilon in a repair process coupled to replication is discussed.     

Crystal structure of the catalytic alpha subunit of E. coli replicative DNA polymerase III

Bacterial replicative DNA polymerases such as Polymerase III (Pol III) share no sequence similarity with other polymerases. The crystal structure, determined at 2.3 A resolution, of a large fragment of Pol III (residues 1-917), reveals a unique chain fold with localized similarity in the catalytic domain to DNA polymerase beta and related nucleotidyltransferases. The structure of Pol III is strikingly different from those of members of the canonical DNA polymerase families, which include eukaryotic replicative polymerases, suggesting that the DNA replication machinery in bacteria arose independently. A structural element near the active site in Pol III that is not present in nucleotidyltransferases but which resembles an element at the active sites of some canonical DNA polymerases suggests that, at a more distant level, all DNA polymerases may share a common ancestor. The structure also suggests a model for interaction of Pol III with the sliding clamp and DNA.     

DNA polymerase III holoenzyme of Escherichia coli. III. Distinctive processive polymerases reconstituted from purified subunits

The 10 distinctive polypeptides of DNA polymerase III holoenzyme, purified as individual subunits or complexes, could be reconstituted to generate a polymerase with the high catalytic rate of the isolated intact holoenzyme. Functions and interactions of the subunits can be inferred from partial assemblies of the pol III core (alpha, epsilon, and theta subunits) with auxiliary subunits. The core possesses the polymerase and proofreading activities; the auxiliary subunits provide the core with processivity, the capacity to replicate long stretches of DNA without dissociating from the template. In a sequence of reconstruction steps, the beta subunit binds the primed template in an ATP-dependent manner through the catalytic action of a complex made up of the gamma, delta, delta', chi, and psi polypeptides. With the beta subunit in place, a processive polymerase is produced upon addition of the core. When the tau subunit is lacking, binding of polymerase to the primed template is less efficient and stable. The tau-less reconstituted polymerase is more prone to dissociation upon encountering secondary structures in the template in its path, such as a hairpin region in the single strand or a duplex region formed by a strand annealed to the template. With the tau subunit present, the interaction of the core.beta complex (the basic unit of a processive polymerase) with the primed template is strengthened. The tau-containing reconstituted polymerase can replicate DNA continuously through secondary structures in the template. The two distinctive kinds of processivity demonstrated by the tau-less and tau-containing reconstituted polymerases fit nicely into a scheme in which, organized as an asymmetric dimeric holoenzyme, the tau half is responsible for continuous synthesis of one strand, and the less stable half for discontinuous synthesis of the other.     

Primary structure of T4 DNA polymerase. Evolutionary relatedness to eucaryotic and other procaryotic DNA polymerases

Bacteriophage T4 gene 43 codes for the viral DNA polymerase. We report here the sequence of gene 43 and about 70 nucleotides of 5'- and 3'-flanking sequences, determined by both DNA and RNA sequencing. We have also purified T4 DNA polymerase from T4 infected Escherichia coli and from E. coli containing a gene 43 overexpression vector. A major portion of the deduced amino acid sequence has been verified by peptide mapping and sequencing of the purified DNA polymerase. All these results are consistent with T4 DNA polymerase having 898 amino acids with a calculated Mr = 103,572. Comparison of the primary structure of T4 DNA polymerase with the sequence of other procaryotic and eucaryotic DNA polymerases indicates that T4 DNA polymerase has regions of striking similarity with animal virus DNA polymerases and human DNA polymerase alpha. Surprisingly, T4 DNA polymerase shares only limited similarity with E. coli polymerase I and no detectable similarity with T7 DNA polymerase. Based on the location of specific mutations in T4 DNA polymerase and the conservation of particular sequences in T4 and eucaryotic DNA polymerases, we propose that the NH2-terminal half of T4 DNA polymerase forms a domain that carries out the 3'----5' exonuclease activity whereas the COOH-terminal half of the polypeptide contains the dNTP-binding site and is necessary for DNA synthesis.     

Fidelity of mammalian DNA replication and replicative DNA polymerases.

Current models suggest that two or more DNA polymerases may be required for high-fidelity semiconservative DNA replication in eukaryotic cells. In the present study, we directly compare the fidelity of SV40 origin-dependent DNA replication in human cell extracts to the fidelity of mammalian DNA polymerases alpha, delta, and epsilon using lacZ alpha of M13mp2 as a reporter gene. Their fidelity, in decreasing order, is replication greater than or equal to pol epsilon greater than pol delta greater than pol alpha. DNA sequence analysis of mutants derived from extract reactions suggests that replication is accurate when considering single-base substitutions, single-base frameshifts, and larger deletions. The exonuclease-containing calf thymus DNA polymerase epsilon is also highly accurate. When high concentrations of deoxynucleoside triphosphates and deoxyguanosine monophosphate are included in the pol epsilon reaction, both base substitution and frameshift error rates increase. This response suggests that exonucleolytic proofreading contributes to the high base substitution and frameshift fidelity. Exonuclease-containing calf thymus DNA polymerase delta, which requires proliferating cell nuclear antigen for efficient synthesis, is significantly less accurate than pol epsilon. In contrast to pol epsilon, pol delta generates errors during synthesis at a relatively modest concentration of deoxynucleoside triphosphates (100 microM), and the error rate did not increase upon addition of adenosine monophosphate. Thus, we are as yet unable to demonstrate that exonucleolytic proofreading contributes to accuracy during synthesis by DNA polymerase delta. The four-subunit DNA polymerase alpha-primase complex from both HeLa cells and calf thymus is the least accurate replicative polymerase. Fidelity is similar whether the enzyme is assayed immediately after purification or after being stored frozen.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA polymerase III from Saccharomyces cerevisiae. II. Inhibitor studies and comparison with DNA polymerases I and II

The newly identified yeast DNA polymerase III was compared to DNA polymerases I and II and the mitochondrial DNA polymerase. Inhibition by aphidicolin (I50) of DNA polymerases I, II, and III was 4, 6, and 0.6 micrograms/ml, respectively. The mitochondrial enzyme was insensitive to the drug. N2-(p-n-butylphenyl)-2'-deoxyguanosine 5'-triphosphate strongly inhibited DNA polymerase I (I50 = 0.3 microM), whereas DNA polymerase III was less sensitive (I50 = 80 microM). Conditions that allowed proteolysis to proceed during the preparation of extracts converted DNA polymerase II from a sensitive form (I50 = 2.4 microM) to a resistant form (I50 = 2 mM). The mitochondrial DNA polymerase is insensitive (I50 greater than 5 mM). With most other inhibitors tested (N-ethylmaleimide, heparin, salt) only small differences were observed between the three nuclear DNA polymerases. Polyclonal antibodies to DNA polymerase III did not inhibit DNA polymerases I and II, nor were those polymerases recognized by Western blotting. Monoclonal antibodies to DNA polymerase I did not crossreact with DNA polymerases II and III. The results show that DNA polymerase III is distinct from DNA polymerase I and II.     

Design and characterization of N2-arylaminopurines which selectively inhibit replicative DNA synthesis and replication-specific DNA polymerases: guanine derivatives active on mammalian DNA polymerase alpha and bacterial DNA polymerase III

The 2-amino substituted derivatives of guanine, N2-(p-n-butylphenyl)guanine (BuPG) and N2-(3',4'-trimethylenephenyl) guanine (TMPG), were synthesized and found to selectively inhibit, respectively, HeLa cell DNA polymerase alpha (po1 alpha) and B. subtilis DNA polymerase III (po1 III). Both purines, like their corresponding uracil analogs, BuAu and TMAU (2,9), were specifically competitive with dGTP in their inhibitory action on their target polymerases. BuPG, the pol alpha-specific purine, was also toxic for HeLa cells in vivo, selectively inhibiting DNA synthesis. These N2-substituted purines, in contrast to the 6-substituted uracils, provide a structural basis for the synthesis of nucleosides and nucleotides with considerable potential as probes for the analysis of the structure of specific replicative DNA polymerases and their function in cellular DNA metabolism.     

SOS-inducible DNA polymerase II of E coli is homologous to replicative DNA polymerase of eukaryotes

The polB gene of Escherichia coli encodes DNA polymerase II whose role in vivo is not defined. The polB gene has been cloned and shown to be identical to a DNA damage-inducible gene dinA which is regulated by the LexA repressor. Nucleotide sequencing of polB reveals that E coli DNA polymerase II is highly homologous to replicative DNA polymerases of eukaryotes which include human DNA polymerase alpha and Saccharomyces cerevisiae DNA polymerases I, II and III. The polB gene is not required for growth, UV-repair and UV-mutagenesis.     

High fidelity DNA synthesis by the Thermus aquaticus DNA polymerase.

We demonstrate that despite lacking a 3'----5' proofreading exonuclease, the Thermus aquaticus (Taq) DNA polymerase can catalyze highly accurate DNA synthesis in vitro. Under defined reaction conditions, the error rate per nucleotide polymerized at 70 degrees C can be as low as 10(-5) for base substitution errors and 10(-6) for frameshift errors. The frequency of mutations produced during a single round of DNA synthesis of the lac Z alpha gene by Taq polymerase responds to changes in dNTP concentration, pH, and the concentration of MgCl2 relative to the total concentration of deoxynucleotide triphosphates present in the reaction. Both base substitution and frameshift error rates of less than 1/100,000 were observed at pH 5-6 (70 degrees C) or when MgCl2 and deoxynucleotide triphosphates were present at equimolar concentrations. These high fidelity reaction conditions for DNA synthesis by the Taq polymerase may be useful for specialized uses of DNA amplified by the polymerase chain reaction.