Studies on the molecular species of DNA polymerase extracted from rat ascites hepatoma cells.

DNA polymerase [EC 2.7.7.7] activities present in hypotonic extract from rat ascites hepatoma AH130 cells were eluted in three separable peaks on DEAE-cellulose column chromatography. Peak I activity had an alkaline pH optimum, and was relatively resistant to SH-blocking reagents and salt concentration. These properties of DEAE peak I are typical of low molecular weight DNA polymerase. DEAE peak II and peak III activities possessed properties corresponding to high molecular weight (6-8 S) polymerase; they showed maximal activity at neutral pH, and were sensitive to SH-blocking reagents and salt. No low molecular weight polymerase activity was released from DEAE peak II or peak III by salt treatment, though partial conversion from DEAE peak II to peak III was observed on the same treatment.     

DNA synthesis on discontinuous templates by human DNA polymerases: implications for non-homologous DNA recombination.

DNA polymerases catalyze the synthesis of DNA using a continuous uninterrupted template strand. However, it has been shown that a 3'-->5' exonuclease-deficient form of the Klenow fragment of Escherichia coli DNA polymerase I as well as DNA polymerase of Thermus aquaticus can synthesize DNA across two unlinked DNA templates. In this study, we used an oligonucleotide-based assay to show that discontinuous DNA synthesis was present in HeLa cell extracts. DNA synthesis inhibitor studies as well as fractionation of the extracts revealed that most of the discontinuous DNA synthesis was attributable to DNA polymerase alpha. Additionally, discontinuous DNA synthesis could be eliminated by incubation with an antibody that specifically neutralized DNA polymerase alpha activity. To test the relative efficiency of each nuclear DNA polymerase for discontinuous synthesis, equal amounts (as measured by DNA polymerase activity) of DNA polymerases alpha, beta, delta (+/- PCNA) and straightepsilon (+/- PCNA) were used in the discontinuous DNA synthesis assay. DNA polymerase alpha showed the most discontinuous DNA synthesis activity, although small but detectable levels were seen for DNA polymerases delta (+PCNA) and straightepsilon (- PCNA). Klenow fragment and DNA polymerase beta showed no discontinuous DNA synthesis, although at much higher amounts of each enzyme, discontinuous synthesis was seen for both. Discontinuous DNA synthesis by DNA polymerase alpha was seen with substrates containing 3 and 4 bp single-strand stretches of complementarity; however, little synthesis was seen with blunt substrates or with 1 bp stretches. The products formed from these experiments are structurally similar to that seen in vivo for non-homologous end joining in eukaryotic cells. These data suggest that DNA polymerase alpha may be able to rejoin double-strand breaks in vivo during replication.     

Non-disruptive detection of DNA polymerases in nondenaturing polyacrylamide gels

A non-disruptive method is described with which DNA polymerases can be detected in homogeneous preparations and unfractionated cell extracts after electrophoresis in nondenaturing polyacrylamide gradient gels. The technique involves diffusion of DNA polymerase activity into an overlay assay agarose gel, the synthesis of radioactive DNA, removal of excess substrates and autoradiography. Cell extracts from a variety of organisms were studied using this method. The activity from Escherichia coli crude extracts migrated in a position corresponding to a higher molecular mass than did purified preparations of DNA polymerase I. DNA polymerases of higher organisms generally migrated in positions corresponding to 400--900 kDa, in some cases, close to 200 kDA.     

The Escherichia coli UVM response is accompanied by an SOS-independent error-prone DNA replication activity demonstrable in vitro

UVM is an SOS-independent inducible response characterized by elevated mutagenesis at a site-specific 3, N4-ethenocytosine (epsilonC) residue borne on M13 single-stranded DNA transfected into Escherichia coli cells pretreated with DNA-damaging agents. By constructing and using E. coli strain AM124 (polA polB umuDC dinB lexA1[Ind-]), we show here that the UVM response is manifested in cells deficient for SOS induction, as well as for all four of the 'non-replicative' DNA polymerases, namely DNA polymerase I (polA), II (polB), IV (dinB) and V (umuDC). These results confirm that UVM represents a novel, previously unidentified cellular response to DNA-damaging agents. To address the question as to whether the UVM response is accompanied by an error-prone DNA replication activity, we applied a newly developed in vitro replication assay coupled to an in vitro mutation analysis system. In the assay, circular M13 single-stranded DNA bearing a site-specific lesion is converted to circular double-stranded replicative-form DNA in the presence of cell extracts and nucleotide precursors under conditions that closely mimic M13 replication in vivo. The newly synthesized (minus) DNA strand is selectively amplified by ligation-mediated polymerase chain reaction (LM-PCR), followed by a multiplex sequence analysis to determine the frequency and specificity of mutations. Replication of DNA bearing a site-specific epsilonC lesion by cell extracts from uninduced E. coli AM124 cells results in a mutation frequency of about 13%. Mutation frequency is elevated fivefold (to 58%) in cell extracts from UVM-induced AM124 cells, with C --> A mutations predominating over C --> T mutations, a specificity similar to that observed in vivo. These results, together with previously reported data, suggest that the UVM response is mediated through the induction of a transient error-prone DNA replication activity and that a modification of DNA polymerase III or the expression of a previously unidentified DNA polymerase may account for the UVM phenotype.     

A cell-free system for the replication fo bacteriophage M-13 duplex DNA.

Cell-free extracts from M-13 am5 infected Escherichia coli cells which are highly concentrated on cellophane membrane disks replicate efficiently endogenous M-13 duplex DNA. If the reaction is carried out in the presence of bromodeoxyuridine triphosphate, the majority of the label is found in two classes of hybrid DNA molecules in which either the viral or the complementary strand is newly synthesized. A minor portion of the label is incorporated into fully synthetic duplex DNA. DNA synthesis requires ATP and is inhibited by nalidixic acid, novobiocin, and arabinosylnucleoside triphosphates. Rifampicin blocks preferentially the synthesis of molecules with labeled complementary strands. A similar effect is observed upon addition of the helix-destabilising M-13 gene V protein. In contrast, addition of E. coli helix-destabilising protein (Eco HD-protein) stimulates the synthesis of both types of hybrid DNA molecules as well as the formation of fully synthetic duplex DNA.     

Isolation of the gene encoding yeast DNA polymerase I

A yeast genomic DNA expression library in lambda gt11 antibody prepared against yeast DNA polymerase I were used to isolate the gene encoding DNA polymerase I. The identity of the DNA polymerase I gene was determined by several criteria. First, the clone-encoded protein is immunologically related to DNA polymerase I. Second, cells containing the gene cloned in the high copy number plasmid YEp24 overproduce the polymerase activity 4- to 5-fold as measured in yeast extracts. Finally, insertion of the gene downstream from a bacteriophage T7 promoter allows synthesis of yeast DNA polymerase I in Escherichia coli. Gene disruption and Southern hybridization experiments show that the polymerase is encoded by an essential, single copy gene. Examination of the germinated spores containing the disrupted gene reveals a defect in nuclear division and a terminal phenotype typical of replication mutants.     

Purification of DNA polymerase delta as an essential simian virus 40 DNA replication factor.

DNA replication from the SV40 origin can be reconstituted in vitro using purified SV40 large T antigen, cellular topoisomerases I and II, replication factor A (RF-A), proliferating cell nuclear antigen (PCNA), replication factor C (RF-C), and a phosphocellulose fraction (IIA) made from human cell extracts (S100). Fraction IIA contains all DNA polymerase activity required for replication in vitro in addition to other factors. A newly identified factor has been purified from fraction IIA. This factor is required for complete reconstitution of SV40 DNA replication and co-purifies with a PCNA-stimulated DNA polymerase activity. This DNA polymerase activity is sensitive to aphidicolin, but is not inhibited by butylanilinodeoxyadenosine triphosphate or by monoclonal antibodies which block synthesis by DNA polymerase alpha. The polymerase activity is synergistically stimulated by the combination of RF-A, PCNA, and RF-C in an ATP-dependent manner. Purified calf thymus polymerase delta can fully replace the purified factor in DNA replication assays. We conclude that this factor, required for reconstitution of SV40 DNA replication in vitro, corresponds to human DNA polymerase delta.     

Multiple forms of DNA-dependent DNA polymerase during early development and in somatic cells of Xenopus laevis.

Four distinct DNA-dependent DNA polymerase activities (DNA polymerases I, II, III and IV according to the order of elution from a DEAE column) have been separated from extracts of unfertilized Xenopus laevis eggs. The same activities, on the basis of their chromatographic properties, template specificities and sedimentation coefficients, have been found in embryos at least until the gastrula stage. On the other hand, Xenopus kidney cells grown in culture, as well as full grown oocytes lack DNA polymerase I. These data suggest the DNA polymerase I might be a special DNA polymerase activity involved in the extremely rapid DNA synthesis which takes place during early development of X. laevis.     

DNA repair synthesis during base excision repair in vitro is catalyzed by DNA polymerase epsilon and is influenced by DNA polymerases alpha and delta in Saccharomyces cerevisiae.

Base excision repair is an important mechanism for correcting DNA damage produced by many physical and chemical agents. We have examined the effects of the REV3 gene and the DNA polymerase genes POL1, POL2, and POL3 of Saccharomyces cerevisiae on DNA repair synthesis is nuclear extracts. Deletional inactivation of REV3 did not affect repair synthesis in the base excision repair pathway. Repair synthesis in nuclear extracts of pol1, pol2, and pol3 temperature-sensitive mutants was normal at permissive temperatures. However, repair synthesis in pol2 nuclear extracts was defective at the restrictive temperature of 37 degrees C and could be complemented by the addition of purified yeast DNA polymerase epsilon. Repair synthesis in pol1 nuclear extracts was proficient at the restrictive temperature unless DNA polymerase alpha was inactivated prior to the initiation of DNA repair. Thermal inactivation of DNA polymerase delta in pol3 nuclear extracts enhanced DNA repair synthesis approximately 2-fold, an effect which could be specifically reversed by the addition of purified yeast DNA polymerase delta to the extract. These results demonstrate that DNA repair synthesis in the yeast base excision repair pathway is catalyzed by DNA polymerase epsilon but is apparently modulated by the presence of DNA polymerases alpha and delta.     

The DNA sequence specificity of stimulation of DNA polymerases by factor D

The mechanism of enhancement of DNA polymerase activity by the murine DNA-binding protein factor D was investigated. Extension by Escherichia coli DNA polymerase I and calf thymus DNA polymerase-alpha of 5'-32P-labeled oligodeoxynucleotide primers that are complementary to poly(dT) or to bacteriophage M13 DNA was measured in the absence or presence of factor D. With 5'-[32P](dA)9.poly(dT), factor D enables E. coli polymerase I to fill approximately 15-nucleotide gaps between adjacent primers; whereas in the absence of the stimulatory protein, poly(dT) is not copied significantly. In order to study the nucleotide specificity of synthesis enhancement, we used M13mp10 DNA containing 4 consecutive thymidine residues downstream from the 3-hydroxyl terminus of an oligonucleotide primer. Upon addition of factor D, both polymerase I and polymerase-alpha can traverse this sequence more efficiently and thus generate longer DNA products. Densitometric analysis of nonextended and elongated 5'-32P-labeled M13 primer indicates that, without changing the frequency of primer utilization, factor D enhances the activity of these DNA polymerases by increasing their apparent processivity. By positioning oligonucleotide primers 4, 8, and 12 bases upstream from the (dT)4 template sequence, we show that the enhancement of synthesis by factor D is independent of the position of the oligothymidine cluster. We hypothesize that factor D interacts with oligo(dT).oligo(dA) domains in DNA to alter their conformation, which may normally obstruct the progression of DNA polymerases.     

DNA polymerase I and DNA primase complex in yeast

Chromatographic analysis of poly(dT) replication activity in fresh yeast extracts showed that the activities required co-fractionate with the yeast DNA polymerase I. Since poly(dT) replication requires both a primase and a DNA polymerase, the results of the fractionation studies suggest that these two enzymes might exist as a complex in the yeast extract. Sucrose gradient analysis of concentrated purified yeast DNA polymerase I preparations demonstrates that the yeast DNA polymerase I does sediment as a complex with DNA primase activity. Two DNA polymerase I peptides estimated at 78,000 and 140,000 Da were found in the complex that were absent from the primase-free DNA polymerase fraction. Rabbit anti-yeast DNA polymerase I antibody inhibits DNA polymerase I but not DNA primase although rabbit antibodies are shown to remove DNA primase activity from solution by binding to the complex. Mouse monoclonal antibody to yeast DNA polymerase I binds to free yeast DNA polymerase I as well as the complex, but not to the free DNA primase activity. These results suggest that these two activities exist as a complex and reside on the different polypeptides. Replication of poly(dT) and single-stranded circular phage DNA by yeast DNA polymerase I and primase requires ATP and dNTPs. The size of the primer produced is 8 to 9 nucleotides in the presence of dNTPs and somewhat larger in the absence of dNTPs. Aphidicolin, an inhibitor of yeast DNA polymerase I, is not inhibitory to the yeast DNA primase activity. The primase activity is inhibited by adenosine 5'-(3-thio)tri-phosphate but not by alpha-amanitin. The association of yeast DNA polymerase I and yeast DNA primase can be demonstrated directly by isolation of the complex on a column containing yeast DNA polymerase I mouse monoclonal antibody covalently linked to Protein A-Sepharose. Both DNA polymerase I and DNA primase activities are retained by the column and can be eluted with 3.5 M MgCl2. Part of the primase activity can be dissociated from DNA polymerase on the column with 1 M MgCl2 and this free primase activity can be detected as poly(dT) replication activity in the presence of Escherichia coli polymerase I.     

Fidelity of DNA polymerase I and the DNA polymerase I-DNA primase complex from Saccharomyces cerevisiae.

We have determined the fidelity of DNA synthesis by DNA polymerase I (yPol I) from Saccharomyces cerevisiae. To determine whether subunits other than the polymerase catalytic subunit influence fidelity, we measured the accuracy of yPol I purified by conventional procedures, which yields DNA polymerase with a partially proteolyzed catalytic subunit and no associated primase activity, and that of yPol I purified by immunoaffinity chromatography, which yields polymerase having a single high-molecular-weight species of the catalytic subunit, as well as three additional polypeptides and DNA primase activity. In assays that score polymerase errors within the lacZ alpha-complementation gene in M13mp2 DNA, yPol I and the yPol I-primase complex produced single-base substitutions, single-base frameshifts, and larger deletions. For specific errors and template positions, the two forms of polymerase exhibited differences in fidelity that could be as large as 10-fold. Nevertheless, results for the overall error frequency and the spectrum of errors suggest that the yPol I-DNA primase complex is not highly accurate and that, just as for the polymerase alone, its fidelity is not sufficient to account for a low spontaneous mutation rate in vivo. The specificity data also suggest models to explain -1 base frameshifts in nonrepeated sequences and certain complex deletions by a direct repeat mechanism involving aberrant loop-back synthesis.     

Fidelity of uracil-initiated base excision DNA repair in DNA polymerase beta-proficient and -deficient mouse embryonic fibroblast cell extracts

Uracil-initiated base excision DNA repair was conducted using homozygous mouse embryonic fibroblast DNA polymerase beta (+/+) and (-/-) cells to determine the error frequency and mutational specificity associated with the completed repair process. Form I DNA substrates were constructed with site-specific uracil residues at U.A, U.G, and U.T targets contained within the lacZalpha gene of M13mp2 DNA. Efficient repair was observed in both DNA polymerase beta (+/+) and (-/-) cell-free extracts. Repair was largely dependent on uracil-DNA glycosylase activity because addition of the PBS-2 uracil-DNA glycosylase inhibitor (Ugi) protein reduced ( approximately 88%) the initial rate of repair in both types of cell-free extracts. In each case, the DNA repair patch size was primarily distributed between 1 and 8 nucleotides in length with 1 nucleotide repair patch constituting approximately 20% of the repair events. Addition of p21 peptide or protein to DNA polymerase beta (+/+) cell-free extracts increased the frequency of short-patch (1 nucleotide) repair by approximately 2-fold. The base substitution reversion frequency associated with uracil-DNA repair of M13mp2op14 (U.T) DNA was determined to be 5.7-7.2 x 10(-4) when using DNA polymerase beta (+/+) and (-/-) cell-free extracts. In these two cases, the error frequency was very similar, but the mutational spectrum was noticeably different. The presence or absence of Ugi did not dramatically influence either the error rate or mutational specificity. In contrast, the combination of Ugi and p21 protein promoted an increase in the mutation frequency associated with repair of M13mp2 (U.G) DNA. Examination of the mutational spectra generated by a forward mutation assay revealed that errors in DNA repair synthesis occurred predominantly at the position of the U.G target and frequently involved a 1-base deletion or incorporation of dTMP.     

Species-specific functional interactions of DNA polymerase alpha-primase with simian virus 40 (SV40) T antigen require SV40 origin DNA.

Physical and functional interactions of simian virus 40 (SV40) and polyomavirus large-T antigens with DNA polymerase alpha-primase were analyzed to elucidate the molecular basis for the species specificity of polymerase alpha-primase in viral DNA replication. SV40 T antigen associated more efficiently with polymerase alpha-primase in crude human extracts than in mouse extracts, while polyomavirus T antigen interacted preferentially with polymerase alpha-primase in mouse extracts. The apparent species specificity of complex formation was not observed when purified polymerase alpha-primases were substituted for the crude extracts. Several functional interactions between T antigen and purified polymerase alpha-primase, including stimulation of primer synthesis and primer elongation on M13 DNA in the presence or absence of the single-stranded DNA binding protein RP-A, also proved to be independent of the species from which polymerase alpha-primase had been purified. However, the human DNA polymerase alpha-primase was specifically required for primosome assembly and primer synthesis on SV40 origin DNA in the presence of T antigen and RP-A.     

Effects of base damages on DNA replication.

Understanding the response of DNA polymerase to the encountered damage in a template is a key to assessing lethal and mutagenic events of cells exposed to genotoxic agents. In the present study M13 (or f1) DNA templates containing 4 types of thymine damages were prepared, and DNA synthesis was carried out in vitro with the templates. The extent of inhibition of DNA synthesis by the damages was evaluated by measuring [3H]dTMP incorporation. Furthermore, newly synthesized DNA was analyzed on a sequencing gel to determine termination sites of DNA synthesis. The results showed that DNA synthesis was differentially inhibited by the damages, and the termination sites of DNA synthesis were dependent on the structures of the damages and the 3'-5' exonuclease activity of DNA polymerase used.     

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.     

Appearance of DNA polymerase activities during early development of Xenopus laevis

Extracts of large oocytes of Xenopus laevis contain high levels of one major DNA polymerase activity. After maturation into eggs, the overall level of DNA polymerase activity in extracts increases fourfold and a second major activity appears on Sephadex G-200 or DEAE cellulose columns. Although intense DNA synthesis occurs as the number of cells increase from one to over 100,000, no further increases in the level of either DNA polymerase activity are observed in cleavage, gastrula or early neurula stage embryos. In extracts of late neurulae or hatched embryos, however, a third major DNA polymerase activity appears coincident with an increase in the ability of the extracts to utilise native DNA templates in vitro.     

Further biochemical characterization of wheat DNA primase: possible functional implication of copurification with DNA polymerase A.

DNA primase has been partially purified from wheat germ. This enzyme, like DNA primases characterized from many procaryotic and eucaryotic sources, catalyses the synthesis of primers involved in DNA replication. However, the wheat enzyme differs from animal DNA primase in that it is found partially associated with a DNA polymerase which differs greatly from DNA polymerase alpha. Moreover, the only wheat DNA polymerase able to initiate on a natural or synthetic RNA primer is DNA polymerase A. In this report we describe in greater detail the chromatographic behaviour of wheat DNA primase and its copurification with DNA polymerase A. Some biochemical properties of wheat DNA primase such as pH optimum, Mn + 2 or Mg + 2 optima, and temperature optimum have been determined. The enzyme is strongly inhibited by KCI, cordycepine triphosphate and dATP, and to a lesser extent by cAMP and formycine triphosphate. The primase product reaction is resistant to DNAse digestion and sensitive to RNAse digestion. Primase catalyses primer synthesis on M13 ssDNA as template allowing E.coli DNA polymerase I to replicate the primed M13 single-stranded DNA leading to double-stranded M13 DNA (RF). M13 replication experiments were performed with wheat DNA polymerases A, B, CI and CII purified in our laboratory. Only DNA polymerase A is able to recognize RNA-primed M13 ssDNA.     

DNA polymerases, deoxyribonucleases, and recombination during meiosis in Saccharomyces cerevisiae.

We utilized strains of Saccharomyces cerevisiae that exhibit high efficiency of synchrony of meiosis to examine several aspects of meiosis including sporulation, recombination, DNA synthesis, DNA polymerase I and II, and Mg2+-dependent alkaline DNases. The kinetics of commitment to intragenic recombination and sporulation are similar. The synthesis of DNA, as measured directly with diphenylamine, appears to precede the commitment to recombination. Both DNA polymerase I and II activities and total DNA-synthesizing activity in crude extracts increase two- to threefold before the beginning of meiotic DNA synthesis. Increases of 10- to 20-fold over mitotic levels are found for Mg2+-dependent alkaline DNase activity in crude extracts before and during the commitment to meiotic intragenic recombination. Of particular interest is the comparable increase in a nuclease under the control of the RAD52 gene; this enzyme has been identified by the use of antibody raised against a similar enzyme from Neurospora crassa. Since the RAD52 gene is essential for meiotic recombination, the nuclease is implicated in the high levels of recombination observed during meiosis. The effects observed in this report are meiosis specific since they are not observed in an alpha alpha strain.     

Escherichia coli uracil- and ethenocytosine-initiated base excision DNA repair: rate-limiting step and patch size distribution

The rate, extent, and DNA synthesis patch size of base excision repair (BER) were measured using Escherichia coli GM31 cell-free extracts and a pGEM (form I) DNA substrate containing a site-specific uracil or ethenocytosine target. The rate of complete BER was stimulated (approximately 3-fold) by adding exogenous E. coli DNA ligase to the cell-free extract, whereas addition of E. coli Ung, Nfo, Fpg, or Pol I did not stimulate BER. Hence, DNA ligation was identified as the rate-limiting step in the E. coli BER pathway. The addition of exogenous DNA polymerase I caused modest inhibition of BER, which was overcome by concomitant addition of DNA ligase. Repair patch size determinations were performed to assess the distribution of DNA synthesis associated with both uracil- and ethenocytosine-initiated BER. During the early phase (0-5 min) of the BER reaction, the large majority of repair events resulted from short patch (1-nucleotide) DNA synthesis. However, during the late phase (>10 min) both short and long (2-20 nucleotide) patches were observed, with long patch BER progressively dominating the repair process. In addition, the patch size distribution was influenced by the ratio of DNA polymerase I to DNA ligase activity in the reaction. A novel mode of BER was identified that involved DNA synthesis tracts of >205 nucleotides in length and termed very-long patch BER. This BER process was dependent upon DNA polymerase I since very-long patch BER was inhibited by DNA polymerase I antibody and addition of excess DNA polymerase I reversed this inhibition.