Inhibition of DNA polymerase activity by methyl methanesulfonate

Methyl methanesulfonate (MMS) inhibits both thymidine incorporation into DNA in mitogen-activated human lymphocytes and deoxythymidine triphosphate incorporation into template DNA by DNA polymerase-alpha in a cell-free system. When MMS-modified DNA was used as the template for DNA synthesis utilizing unmodified DNA polymerase-alpha, nucleotide incorporation into template DNA was not inhibited. When unmodified DNA was used as the template for DNA synthesis utilizing MMS-modified DNA polymerase-alpha, nucleotide incorporation was differentially inhibited dependent on the MMS concentration. An analysis of the kinetics of DNA polymerase-alpha inhibition showed that incorporation of all 4 deoxynucleoside triphosphates into DNA template was noncompetitively inhibited by MMS, which is consistent with nonspecific MMS modification of the enzyme. These data indicate that MMS modification of DNA polymerase-alpha alone is sufficient to inhibit the incorporation of deoxynucleoside triphosphates into template DNA in vitro. The data further indicate that alkylation of both DNA polymerase-alpha and DNA template synergistically increases inhibition of DNA synthesis.     

Circular single stranded phage M13-DNA as a template for DNA synthesis in protein extracts from Xenopus laevis eggs: evidence for a eukaryotic DNA priming activity.

Unfractionated protein extracts from activated Xenopus laevis eggs contain all functions required for the chain elongation reactions in replicative DNA synthesis (A.Richter, B.Otto and R.Knippers, 1981, Nucl.Ac.Res. 9, 3793-3807). In order to further explore the DNA synthesizing capacity of this in vitro system and to obtain information on the DNA priming activity in these extracts single stranded phage M13-DNA was used as template for in vitro DNA synthesis. The main results of this investigation are: (i) single stranded circular template DNA is converted to a double stranded DNA form in an alpha-amanitin-insensitive reaction which is absolutely dependent on ribonucleoside triphosphates; (ii) the in vitro synthesized complementary strands are DNA fragments of 1000-2000 nucleotides lengths; (iii) the DNA primase activity copurifies through several column steps and sucrose gradient centrifugation with a DNA polymerase alpha. These activities may therefore be closely associated in a quarternary enzyme complex.     

Coordinated leading- and lagging-strand synthesis at the Escherichia coli DNA replication fork. II. Frequency of primer synthesis and efficiency of primer utilization control Okazaki fragment size.

To investigate the role of the priming apparatus at the replication fork in determining Okazaki fragment size, the products of primer synthesis generated in vitro during rolling-circle DNA replication catalyzed by the DNA polymerase III holoenzyme, the single-stranded DNA binding protein, and the primosome on a tailed form II DNA template were isolated and characterized. The abundance of oligoribonucleotide primers and the incidence of covalent DNA chain extension of the primer population was measured under different reaction conditions known to affect the size of the products of lagging-strand DNA synthesis. These analyses demonstrated that the factors affecting Okazaki fragment length could be distinguished by either their effect on the frequency of primer synthesis or by their influence on the efficiency of initiation of DNA synthesis from primer termini. Primase and the ribonucleoside triphosphates were found to stimulate primer synthesis. The observed trend toward smaller fragment size as the concentration of these effectors was raised was apparently a direct consequence of the increased frequency of primer synthesis. The beta subunit of the DNA polymerase III holoenzyme and the deoxyribonucleoside triphosphates did not alter the priming frequency; instead, the concentration of these factors influenced the ability of the lagging-strand DNA polymerase to efficiently utilize primers to initiate DNA synthesis. Maximum utilization of the available primers correlated with the lowest mean value of Okazaki fragment length. These data were used to draw general conclusions concerning the temporal order of enzymatic steps that operate during a cycle of Okazaki fragment synthesis on the lagging-strand DNA template.     

Enhanced processivity of nuclear matrix bound DNA polymerase alpha from regenerating rat liver

Translocation of DNA during in vitro DNA synthesis on nuclear matrix bound replicational assemblies from regenerating rat liver was determined by measuring the processivity (average number of nucleotides added following one productive binding event of the polymerase to the DNA template) of nuclear matrix bound DNA polymerase alpha with poly(dT).oligo(A)10 as template primer. The matrix-bound polymerase had an average processivity (28.4 nucleotides) that was severalfold higher than the bulk nuclear DNA polymerase alpha activity extracted during nuclear matrix preparation (8.9 nucleotides). ATP at 1 mM markedly enhanced the activity and processivity of the matrix-bound polymerase but not the corresponding salt-soluble enzyme. The majority of the ATP-dependent activity and processivity enhancement was completed by 100 microM ATP and included products ranging up to full template length (1000-1200 nucleotides). Average processivity of the net ATP-stimulated polymerase activity exceeded 80 nucleotides with virtually all the DNA products greater than 50 nucleotides. Release of nuclear matrix bound DNA polymerase alpha by sonication resulted in a loss of ATP stimulation of activity and a corresponding decrease in processivity to a level similar to that of the salt-soluble polymerase (6.8 nucleotides). All nucleoside di- and triphosphates were as effective as ATP. Stimulation of both activity and processivity by the nonhydrolyzable ATP analogues adenosine 5'-O-(3-thiotriphosphate), 5'-adenylyl imidodiphosphate, and adenosine 5'-O-(1-thiotriphosphate) further suggested that the hydrolysis of ATP is not required for enhancement to occur.(ABSTRACT TRUNCATED AT 250 WORDS)     

N.BspD6I DNA nickase strongly stimulates template-independent synthesis of non-palindromic repetitive DNA by Bst DNA polymerase

Highly efficient DNA synthesis without template and primer DNAs occurs when N.BspD6I DNA nickase is added to a reaction mixture containing deoxynucleoside triphosphates and the large fragment of Bst DNA polymerase. Over a period of 2 h, virtually all the deoxynucleoside triphosphates (dNTPs) become incorporated into DNA. Inactivation of N.BspD6I nickase by heating inhibits DNA synthesis. Optimal N.BspD6I activity is required to achieve high yields of synthesized DNA. Electron microscopy data revealed that the majority of DNA molecules have a branched structure. Cloning and sequencing of the fragments synthesized demonstrated that the DNA product mainly consists of multiple hexanucleotide non-palindromic tandem repeats containing nickase recognition sites. A possible mechanism is discussed that addresses template-independent DNA synthesis stimulated by N.BspD6I nickase.     

Studies of the DNA helicase-RNA primase unit from bacteriophage T4. A trinucleotide sequence on the DNA template starts RNA primer synthesis

The purified DNA replication proteins encoded by genes 41 and 61 of bacteriophage T4 catalyze efficient RNA primer synthesis on a single-stranded DNA template. In the presence of additional T4 replication proteins, we demonstrate that the template sequences 5'-GTT-3' and 5'-GCT-3' serve as necessary and sufficient signals for RNA primer-dependent initiation of new DNA chains. These chains start with primers that have the sequences pppApCpNpNpN and pppGpCpNpNpN, where N can be any one of the four ribonucleotides. Each primer is initiated from the T (A-start primers) or C (G-start primers) in the center of the recognized template sequence. A subset of the DNA chain starts is observed when one of the four ribonucleoside triphosphates used as the substrates for primer synthesis is omitted; the starts observed reveal that both pentaribonucleotide and tetraribonucleotide primers can be used for efficient initiation of new DNA chains, whereas primers that are only 3 nucleotides long are inactive. It was known previously that, when 61 protein is present in catalytic amounts, the 41 and 61 proteins are both required for observing RNA primer synthesis. However, by raising the concentration of the 61 protein to a much higher level, a substantial amount of RNA-primed DNA synthesis is obtained in the absence of 41 protein. The DNA chains made are initiated by primers that seem to be identical to those made when both 41 and 61 proteins are present; however, only those template sites containing the 5'-GCT-3' sequence are utilized. The 61 protein is, therefore, the RNA primase, whereas the 41 protein should be viewed as a DNA helicase that is required (presumably via a 41/61 complex) for efficient primase recognition of both the 5'-GCT-3' and 5'-GTT-3' DNA template sequences.     

Bacteriophage-T7-induced DNA-priming protein. A novel enzyme involved in DNA replication.

The T7gene-4 protein has been purified to near homogeneity using a complementation assay in vitro, and it is designated T7 DNA-priming protein (DNA primase). The purified enzyme enables T7 DNA polymerase to initate DNA synthesis on various circular single-stranded DNA templates by a mechanism which involes the synthesis of a very short RNA primer. The oligoribonucleotide, which is linked to the product DNA via a 3':5'-phosphodiester bond, starts with pppA-C and terminates predominantly with AMP. When only ATP and CPT are precursors, the RNA primer is found to be primarily a tetranucleotide of the sequence pppA-C-C-A. Using oligoribonucleotides in place of ribonucleoside triphosphates as chain initators, T7 DNA-priming protein drastically increases the efficiency with which T7 DNA polymerase can utilize particular tetranucleotide primers containing A and C residues. T7 DNA-priming protein also enables T7 DNA polymerase to make use of native or nicked duplex T7 DNA as template-primer. This reaction does not require ribonucleoside triphosphates, although their addition enhances DNA synthesis 2--4 fold. The product formed in their absence is covalently attached to the template DNA and is found to contain a few long branches when examined by electron microscopy. In the presence of ribonucleoside triphosphates most of the newly made product arises from imitation of DNA chains de novo. Incubation of three proteins: T7 DNA-priming protein, T7 DNA polymerase, and T7 DNA-binding protein, with ribonucleoside and deoxyribonucleoside triphosphates, and with phiX174DNA as template leads to the generation of 'rolling circle-like' structures as visualized in the electron microscope. Single-stranded regions at the tail-circle junction indicate that initations can occur de novo on the displaced complementary strand. This is consistent with a discontinuous mode of 'lagging' strand synthesis and suggests that the same proteins may also be responsible for fork propagation in vivo.     

Studies on bacteriophage T7 DNA synthesis in vitro. II. Reconstitution of the T7 replication system using purified proteins.

Summary DNA synthesis in vitro using intact duplex T7 DNA as template is dependent on a novel group of three phage T7-induced proteins: DNA-priming protein (activity which complements a cell extract lacking the T7 gene 4-protein), T7 DNA polymerase (gene 5-protein plus host factor), and T7 DNA-binding protein. The reaction requires, in addition to the four deoxyribonucleoside triphosphates, all four ribonucleoside triphosphates and is inhibited by low concentrations of actinomycin D. Evidence is presented that the priming protein serves as a novel RNA polymerase to form a priming segment which is subsequently extended by T7 DNA polymerase. T7 RNA polymerase (gene 1-protein) can only partially substitute for the DNA-priming protein. At 30°C, deoxyribonucleotide incorporation proceeds for more than 2 hours and the amount of newly synthesized DNA can exceed the amount of template DNA by 10-fold. The products of synthesis are not covalently attached to the template and sediment as short (12S) DNA chains in alkaline sucrose gradients. Sealing of these fragments into DNA of higher molecular weight requires the presence of E. coli DNA polymerase I and T7 ligase. Examination of the products in the electron microscope reveals many large, forked molecules and a few eye-shaped structures resembling the early replicative intermediates normally observed in vivo.     

Priming of superhelical SV40 DNA by Escherichia coli RNA polymerase for in vitro DNA synthesis.

When closed circular SV40 DNA containing 58 negative superhelical turns is used as a template for RNA synthesis with Escherichia coli RNA polymerase, a fraction of the RNA product remains complexed with the DNA. The RNA in the complex is resistant to ribonuclease in high salt, and the Tm indicates that it is hydrogen bonded to the DNA. The mole ratio of RNA to DNA nucleotides in the complex ranges from 0.01 to 0.08; the RNA ranges in length from 80 to 600 nucleotides. The formation of the complex is dependent on the circular DNA being topologically underwound since no complex is formed when closed circular DNA containing zero superhelical turns is used as the template. The DNA-RNA complex can serve as a primer-template combination for in vitro DNA synthesis by E. coli DNA polymerase I. After synthesis with (alpha-32P)-labeled deoxyribonucleoside triphosphates followed by alkaline hydrolysis, the isolation of 32P-labeled ribonucleotides is evidence for a covalent linkage between the RNA and the DNA synthesized. During the in vitro DNA synthesis, the template is nicked at a low rate, and the nicked molecules support extensive DNA synthesis. This observation indicates that only limited synthesis can occur on unnicked molecules possibly owing to the topological constraints against unwinding of the helix. Possible models for in vivo priming of double-stranded DNA by E. coli RNA polymerase are discussed.     

DNA primase associated with 10 S DNA polymerase alpha from calf thymus

Among multiple subspecies of DNA polymerase alpha of calf thymus, only 10 S DNA polymerase alpha had a capacity to initiate DNA synthesis on an unprimed single-stranded, circular M13 phage DNA in the presence of ribonucleoside triphosphates (DNA primase activity). The primase was copurified with 10 S DNA polymerase alpha through the purification and both activities cosedimented at 10 S through gradients of either sucrose or glycerol. Furthermore, these two activities were immunoprecipitated at a similar efficiency by a monoclonal antibody directed against calf thymus DNA polymerase alpha. These results indicate that the primase is tightly bound to 10 S DNA polymerase alpha. The RNA polymerizing activity was resistant to alpha-amanitin, required high concentration of all four ribonucleoside triphosphates (800 microM) for its maximal activity, and produced the limited length of oligonucleotides (around 10 nucleotides long) which were necessary to serve as a primer for DNA synthesis. Covalent bonding to RNA to DNA was strongly suggested by the nearest neighbour frequency analysis and the DNAase treatment. The DNA synthesis primed by the RNA oligomers may be carried out by the associating DNA polymerase alpha because it was strongly inhibited by araCTP, resistant to d2TTP, and was also inhibited by aphidicolin but at relatively high concentration. The primase preferred single-stranded DNA as a template, but it also showed an activity on the double-stranded DNA from calf thymus at an efficiency of approx. 10% of that with single-stranded DNA.     

Generation of DNA nanocircles containing mismatched bases

The DNA mismatch repair (MMR) system recognizes and repairs errors that escaped the proofreading function of DNA polymerases. To study molecular details of the MMR mechanism, in vitro biochemical assays require specific DNA substrates carrying mismatches and strand discrimination signals. Current approaches used to generate MMR substrates are time-consuming and/or not very flexible with respect to sequence context. Here we report an approach to generate small circular DNA containing a mismatch (nanocircles). Our method is based on the nicking of PCR products resulting in single-stranded 3' overhangs, which form DNA circles after annealing and ligation. Depending on the DNA template, one can generate mismatched circles containing a single hemimethylated GATC site (for use with the bacterial system) and/or nicking sites to generate DNA circles nicked in the top or bottom strand (for assays with the bacterial or eukaryotic MMR system). The size of the circles varied (323 to 1100 bp), their sequence was determined by the template DNA, and purification of the circles was achieved by ExoI/ExoIII digestion and/or gel extraction. The quality of the nanocircles was assessed by scanning-force microscopy and their suitability for in vitro repair initiation was examined using recombinant Escherichia coli MMR proteins.     

Characterization of an Endogenous RNA-Dependent DNA Polymerase Associated with Murine Intracisternal A Particles

An RNA-dependent DNA polymerase associated with intracisternal A particles has been characterized. The enzyme required Mg(2+) or Mn(2+), dithiothreitol and the presence of all four deoxyribonucleoside triphosphates for the expression of maximal activity. Sensitivity of the endogenous RNA-dependent DNA polymerase activity to a low concentration of pancreatic ribonuclease in the presence of a high concentration of NaCl suggested that the enzyme might be utilizing the A particle endogenous RNA as template. Evidence in support of this was provided by analyses of early and late DNA products of the endogenous reaction by Cs(2)SO(4) isopycnic gradient centrifugation and hybridization of purified 60 to 70S and 35S RNAs of A particles with the purified DNA product.     

Enzymatic assay for deoxyribonucleoside triphosphates using synthetic oligonucleotides as template primers

The enzymatic assay for deoxyribonucleoside triphosphates has been improved by using synthetic oligonucleotides of a carefully defined sequence as template primers for DNA polymerase. High backgrounds, which limit the sensitivity of the assay when calf thymus DNA or alternating copolymers are used as template primers, were eliminated with these oligonucleotide template primers. Sensitivity was further increased by designing the template primer to incorporate multiple labeled deoxyribonucleotides per limiting unlabeled deoxyribonucleotide. Each of several DNA polymerases exhibited unique reaction characteristics with the oligonucleotide template primers, which was attributed to the differing exonuclease activities associated with these various enzymes. Assay optimization therefore included matching the polymerase with the template primer to obtain the lowest background reaction and highest sensitivity. This modified assay is particularly well suited for keeping cell sample size to a minimum in experimental protocols which generate large numbers of data points or require careful timing of sampling. With this technique, we measured the levels of all four deoxyribonucleoside triphosphates in extracts from as few as 2 x 10(4) cultured cells.     

Stimulation of DNA polymerase alpha by hypergravity generated by centrifugal acceleration.

Gravity alteration is known to influence cell proliferation. Here we tested the effects of hypergravity on the action of DNA polymerase alpha, one of the DNA replication enzymes in eukaryotes. Hypergravity was produced by horizontal centrifugal acceleration with a hand-made rotator. The reaction rate of DNA polymerase alpha in centrifuge tubes increased along with the acceleration up to 4g, when a plateau was reached. In contrast, no stimulation was observed with primase, DNA polymerase epsilon, and the E. coli DNA polymerase I Klenow fragment. Kinetic analysis of DNA polymerase alpha reactions revealed that, under high gravity conditions, the K(m) value for template DNA decreased while the V(max) stayed constant. In contrast, the centrifugal acceleration did not affect the K(m) values for deoxyribonucleoside triphosphates. These results suggest that the hypergravity enhances the activity of DNA polymerase alpha by increasing the affinity of the enzyme for template DNA. Such enhancement was more prominent with a low concentration of DNA polymerase alpha under low ionic conditions.     

Initiation of DNA synthesis by the calf thymus DNA polymerase-primase complex

The calf thymus DNA polymerase-alpha-primase complex purified by immunoaffinity chromatography catalyzes the synthesis of RNA initiators on phi X174 single-stranded viral DNA that are efficiently elongated by the DNA polymerase. Trace amounts of ATP and GTP are incorporated into products that are full length double-stranded circular DNAs. When synthetic polydeoxynucleotides are used as templates, initiation and DNA synthesis occurs with both poly(dT) and poly(dC), but neither initiation nor DNA synthesis was observed with poly(dA) and poly(dI) templates. Nitrocellulose filter binding and sucrose gradient centrifugation studies show that the DNA polymerase-primase complex binds to deoxypyrimidine polymers, but not to deoxypurine polymers. Using d(pA)-50 with 3'-oligo(dC) tails and d(pI)-50 with 3'-oligo(dT) tails, initiator synthesis and incorporation of deoxynucleotide can be demonstrated when the average pyrimidine sequence lengths are 8 and 4, respectively. These results suggest that purine polydeoxynucleotides are used as templates by the DNA polymerase only after initiation has occurred on the oligodeoxypyrimidine sequence and that the pyrimidine stretch required by the primase activity is relatively short. Analysis of initiator chain length with poly(dC) as template showed a series of oligo(G) initiators of 19-27 nucleotides in the absence of dGTP, and 5-13 nucleotides in the presence of dGTP. The chain length of initiators synthesized by the complex when poly(dT) or oligodeoxythymidylate-tailed poly(dI) was used can be as short as a dinucleotide. Analysis of the products of replication of oligo(dC)-tailed poly(dA) shows that initiator with chain length as low as 4 can be used for initiation by the polymerase-primase complex.     

Mechanism of stimulation by a specific protein factor of de novo DNA synthesis by mouse DNA replicase with fd phage single stranded circular DNA.

Mouse DNA replicase is a functional multienzyme complex consisting of DNA polymerase and DNA primase. The DNA and initiator RNA syntheses by DNA replicase with single stranded DNA as template are stimulated by a stimulating factor (T. Yagura, T. Kozu and T. Seno, 1982, J. Biochem. (Tokyo).91, 607-618). The action mechanism of the stimulating factor on this novel DNA synthesis with fd phage single stranded circular DNA as template was studied. The stimulating factor directly stimulated initiator RNA synthesis but did not change the length of either initiator RNA (8 to 10 nucleotides long) or the product DNA (300 to 1,000 nucleotides long). Kinetic studies and analysis of the products by neutral agarose gel electrophoresis show that the stimulating factor increased the affinity of DNA replicase for template DNA without changing the apparent Km values for deoxy- and ribonucleotide substrates. Thus, in combination with a sufficient amount of the stimulating factor, DNA replicase quantitatively converted the template DNA to the position of double-stranded circular replicative form II DNA, as shown by agarose gel electrophoresis.     

DNA polymerases of ascites hepatoma cells. I. Purification and properties of a DNA polymerase from soluble fraction

DNA polymerase from soluble fraction of ascites hepatoma cells has been purified about 490-fold. The polymerase requires template DNA, all four deoxyribonucleoside triphosphates, and magnesium ions for the reaction. Optimal activity was found at pH 7.0 – 7.5, with 3 – 8 mM magnesium chloride, and 20 – 40 mM potassium phosphate. The purified enzyme utilizes preferentially DNA treated with pancreatic DNase as template.