The mode of inhibitory action by pyridoxal 5-phosphate on DNA polymerase-alpha and -beta.

The kinetics of the inhibition of DNA polymerases-alpha and -beta from sea urchin embryos by pyridoxal 5-phosphate were studied. The inhibition of DNA polymerase-alpha activity by pyridoxal 5-phosphate was competitive with activated DNA but noncompetitive with each deoxynucleoside triphosphate. With poly(dC)-oligo(dG)12-18 as a template-primer, however, the inhibition of DNA polymerase-alpha was competitive with dGTP but noncompetitive with the template-primer. These results suggest that DNA polymerase-alpha interacts with activated DNA and poly(dC)-oligo(dG)12-18 in different ways. The inhibition of DNA polymerase-beta by pyridoxal 5-phosphate was competitive with deoxynucleoside triphosphate using activated DNA as a template-primer and noncompetitive with activated DNA. Using poly(rA)-oligo(dT)12-18 as a template-primer, DNA polymerase-beta activity yielded sigmoid curves against both dTTP and the template-primer concentrations and was inhibited by pyridoxal 5-phosphate noncompetitively with respect to both dTTP and the template-primer. These results indicate that the inhibitory mode of DNA polymerase-alpha by pyridoxal 5-phosphate is different from that of DNA polymerase-beta.     

Distinctive properties of mammalian DNA polymerases.

DNA polymerase-alpha and -beta can be distinguished from one another by the differential effects of N-ethylmaleimide, KCl, ara-CTP and temperature, as well as on the basis of sedimentation. The sensitivity of DNA polymerase-beta to elevated temperatures as compared to DNA polymerase-alpha provides a new means of distinguishing between these two enzymes even in crude extracts and a possible probe for determining their function. DNA polymerase-alpha and -beta share several properties in common, including the ability to readily incorporate dUTP in place of dTTP. The Km for dUTP varies from 10 to 30 micron with different preparations of DNA polymerase-alpha and -beta. Thus, in mammalian cells, dUMP could be incorporated into DNA, and if excised by an endonuclease, would lead to discontinuities. Initial analyses of fidelity in direct comparative studies indicate that beta-class DNA polymerases are highly accurate in base selection when copying poly[d(A-T)]. Less than one molecule of dGMP is incorporated for every 12 000-45 000 molecules of dAMP and dTMP polymerized. DNA polymerase-alpha is somewhat less accurate, making one mistake for every 4000-10 000 correct nucleotides incorporated. Since both polymerases lack an exonucleolytic activity, this accuracy must be the result of selectivity for the complementary nucleotide by the polymerase.     

Evidences for the function of DNA polymerase-beta in unscheduled DNA synthesis.

The activities of DNA polymerase-alpha and -beta isolated from pig spleen were determined at different temperatures and in the presence of different concentrations of inhibitors. The results were compared with parallel estimations of replicative DNA synthesis and UV-induced repair synthesis in spleen cells. In respect to pCMB and aCTP, polymerase-alpha is more sensitive than polymerase-beta and similarly is replication more sensitive than repair. Repair synthesis and the activity of polymerase-beta decreases at temperatures higher than 40 degrees C whereas both replication and the activity of polymerase-alpha are greatly stimulated at elevated temperatures with optima of 45 degrees C (polymerase-alpha) and 41 degrees C (replication). The results favour the hypothesis that polymerase-beta is involved in repair synthesis.     

Differential inhibition of rat liver DNA polymerases in vitro by direct-acting carcinogens and the protective effect of a thiol reducing agent.

The direct-acting carcinogens acetoxyacetylaminofluorene, methylnitrosourea, and N-methyl-N'-nitro-N-nitrosoguanidine were tested for their ability to inhibit rat liver DNA polymerase-alpha, -beta, and -gamma activity in vitro. DNA polymerase-alpha was the most sensitive, polymerase-beta was the most resistant, and polymerase-gamma exhibited an intermediate response. When the reactions were reassayed in the presence and absence of dithiothreitol, a thiol reducing agent, it was shown that the inhibition by carcinogens was generally reversible with increasing dithiothreitol, except that polymerase-beta recovered only 80-90% of control values. These and binding data suggest that DNA polymerase-beta, the putative repair enzyme, is highly resistant to carcinogen damage. This resistance may contribute to the retention of normal function and fidelity of the repair enzyme during carcinogen exposure in vivo and to a normal cellular repair.     

Effect of drugs on deoxyribonucleic acid synthesis in isolated mammalian cell nuclei. Comparison with partially purified deoxyribonucleic acid polymerases.

In order to ascertain the identity of the DNA-dependent DNA polymerase responsible for the observed DNA synthesis in nuclei isolated from baby-hamster kidney (BHK-21/C13) cells a comparative study was carried out on the effects of some drugs, reported to influence DNA synthesis, on DNA synthesis catalysed by these nuclei and by partially purified DNA polymerase-alpha and -beta. In all cases DNA synthesis by isolated nuclei and polymerase-alpha was inhibited to similar extents by N-ethylmaleimide, p-hydroxymercuribenzoate, novobiocin, heparin and phosphonoacetic acid; polymerase-beta was much less affected by these compounds. Ethidium bromide inhibited all DNA synthesis to similar extents, although at low concentrations (about 2 microgram/ml) synthesis in isolated nuclei was stimulated. The results are discussed in relation to the proposal that DNA polymerase-alpha catalyses the covalent extension of Okazaki fragments that these nuclei carry out in vitro.     

Regenerating rat liver DNA polymerases: disimilitude or relationship between nuclear and cytoplasmic enzymes?

The possible relationship between the nuclear and cytoplasmic DNA polymerases of regenerating rat liver was studied by sucrose gradient analysis, salt dissociation, and with specific inhibitors. After aqueous subcellular fractionation and removal of the nuclear membranes, three species of DNA-dependent DNA polymerases were characterized: 1) a DNA polymerase-beta in the nuclei. 2) a DNA polymerase-alpha in the cytosol which was not dissociated at high salt concentrations; and 3) an intermediate form in the cytosol and in the Triton wash containing the nuclear membranes. The latter form behaved like DNA polymerase-alpha et low salt concentration but was dissociated at high salt concentrations to a low molecular weight species with properties like DNA polymerase-beta (resistance to inhibition by N-ethylmaleimide, heparin and KCL). In vitro reassociation experiments suggest that this intermediate form corresponds to the association of DNA polymerase-beta with a membrane component or cytoplasmic protein(s) which appear(s) in regenerating rat liver.     

Delayed and reduced cell replication and diminishing levels of DNA polymerase-alpha in regenerating liver of aging mice

Kinetics of cell replication was compared in regenerating livers of Mus musculus at ages ranging between 6 and 32 months. Incorporation of [3H]-thymidine into DNA and autoradiographic analysis showed that the maximal extent of DNA replication following partial hepatectomy became delayed with age. Furthermore, the total fraction of parenchymal and nonparenchymal cells in S phase at different intervals during regeneration diminished as mice aged. The specific activity of DNA polymerase-alpha, the putative replicative enzyme, declined progressively during aging. The specific activity of DNA polymerase-beta, the purported repair enzyme, declined to an appreciably lesser extent during the lifespan of the mouse. No evidence was found for the appearance of a specific inhibitor of polymerase-alpha in senescent mouse liver. Also, the bulk of the activities of both hepatic DNA polymerase-alpha and -beta remained localized in the cell nucleus throughout the lifetime of the animal and were mainly associated with chromatin.     

Immunological reagents for comparisons of DNA polymerase-alpha and DNA polymerase-beta

Antibodies to homogeneous calf thymus DNA polymerase-beta and calf thymus DNA polymerase-alpha preparations were raised in rabbits. The antiserum against calf thymus DNA polymerase-beta cross-reacts with all vertebrate DNA polymerase-beta preparations tested, but does not cross-react with trypanosome DNA polymerase-beta, DNA polymerase-gamma, terminal transferase, yeast DNA polymerases, and Escherichia coli DNA polymerase I. The antibodies against calf thymus DNA polymerase-alpha cross-react with DNA polymerase-alpha from mouse, human, and chicken, but do not cross-react with DNA polymerase-alpha from sea urchin embryos and Drosophila embryos, DNA polymerase-beta, DNA polymerase-gamma, terminal transferase, yeast DNA polymerases, and E. coli DNA polymerase I.     

Inhibition of polymerases-alpha and -beta completely blocks DNA repair induced by UV irradiation in cultured mouse neuronal cells

The effects of hydroxyurea, aphidicolin and dideoxythymidine on UV-induced DNA repair of mouse neuronal granular cells were studied. Aphidicolin, which is considered a specific inhibitor of polymerase-alpha, decreased spontaneous DNA synthesis by 93% and totally suppressed DNA repair. Dideoxythymidine, an inhibitor of polymerase-beta, was more potent in decreasing scheduled DNA synthesis than aphidicolin, and also completely blocked the UV-induced DNA repair. Hydroxyurea, a specific inhibitor of ribonucleotide reductase, inhibited scheduled DNA synthesis, but unscheduled DNA synthesis after UV irradiation was always well detectable. Our data suggest that in neuronal cells from 5 to 10 days old mice both polymerases-alpha and -beta are required for both DNA synthesis and repair. These two enzymes may act jointly in filling up the gaps along the DNA molecule and elongating the DNA chain.     

DNA polymerase activity in a repair-deficient human cell line

A human low-density-lipoprotein (LDL) receptor-deficient diploid fibroblast cell line (GM1915) was determined to be short patch competent (DNA polymerase-beta) and long patch deficient (DNA polymerase-alpha) for DNA excision repair. Analysis of DNA from GM1915 cells or from WI38 control cells, following treatment with a mutagen known to initiate long patch excision repair, showed that GM1915 cells exhibited decreased resynthesis of oligonucleotide segments excised during repair. When cells deficient in DNA polymerase-alpha activity were permeabilized to permit LDL entry, repair synthesis immediately increased. These data suggest that DNA polymerase-alpha is not activated by mutagen treatment in GM1915 cells and that introduction of LDL into the cells results in activation of the enzyme.     

Studies on the purification and properties of a 6.8-S DNA polymerase activity found in calf-thymus DNA polymerase-alpha fraction.

The heterogeneity of calf thymus DNA polymerase-alpha has been further investigated. In particular, an enzyme (enzyme D) which exhibits higher activity on poly(dA) . (dT)10 (A:T = 20:1) compared with that on activated DNA, has been further purified and its properties compared with two other activities of the DNA polymerase-alpha fraction (enzymes A1 and C) which do not show a preference for poly(dA) . (dT)10 over activated DNA. As with A1 and C, enzyme D was shown to have many of the characteristic properties of DNA polymerase-alpha in that it is an acidic protein as judged by its binding to DEAE-cellulose, has a molecular weight of about 140000, does not use a poly (A) . (dT)10 template-initiator complex and is inhibited by N-ethylmaleimide. It exhibits anomalous gel filtration behaviour on Sepharose 6B and it binds relatively weakly to DNA-cellulose compared with DNA polymerase-beta. The extreme sensitivity of enzyme D to inhibtion by N-ethylmaleimide distinguishes it from A1 and C, as does its elution position from a DEAE-cellulose column. On the other hand enzymes C and D are readily inactivated by heating at 45 degrees C unlike enzyme A1. The possible interrelationships of the multiple activities of calf thymus DNA polymerase-alpha are discussed.     

Stockpiling of DNA polymerases during oogenesis and embryogenesis in the frog, Xenopus laevis

The amounts of the various forms of DNA polymerase (alpha 1, alpha 2, beta, and gamma) have been determined in oocytes, eggs, and embryos of the frog, Xenopus laevis. During oogenesis the relative proportions and absolute levels of all forms changed dramatically. In stage I (early) oocytes, DNA polymerase-gamma, the "mitochondrial" polymerase, was the predominant form. During oocyte growth, DNA polymerase-alpha 1 and -alpha 2 increased by more than 100-fold, DNA polymerase-beta by 15-fold, and DNA polymerase-gamma by only 8-fold. During oocyte maturation and ovulation, the levels of all forms of DNA polymerase roughly doubled. The mature stage VI oocyte contained 5 orders of magnitude more DNA polymerase activity than is found in an individual somatic cell. DNA polymerase-alpha 1 and -alpha 2, the "replicative" polymerases, were the predominant forms in mature oocytes and ovulated unfertilized eggs. During fertilization, the relative proportions and absolute levels of the four forms remained constant. During subsequent stages of embryogenesis, the total amounts of DNA polymerase-alpha 1 and -alpha 2 declined slightly from cleavage through gastrulation, the stages of most rapid chromosomal DNA replication. The rapid increase in cell number during early embryogenesis establishes the same levels of DNA polymerase/cell as are present in adult somatic cells. After neurulation, the absolute levels of DNA polymerase-alpha 1 and -alpha 2 increased in proportion to increases in cell number. The absolute levels of DNA polymerase-beta remained constant, and the levels of DNA polymerase-gamma increased 2-fold throughout embryogenesis.     

Frameshift mutagenesis by eucaryotic DNA polymerases in vitro

The frequency and specificity of frameshift errors produced during a single round of in vitro DNA synthesis by DNA polymerases-alpha, -beta, and -gamma (pol-alpha, -beta, and -gamma, respectively) have been determined. DNA polymerase-beta is the least accurate enzyme, producing frameshift errors at an average frequency of one error for each 1,000-3,000 nucleotides polymerized, a frequency similar to its average base substitution accuracy. DNA polymerase-alpha is approximately 10-fold more accurate, producing frameshifts at an average frequency of one error for every 10,000-30,000 nucleotides polymerized, a frequency which is about 2- to 6-fold lower than the average pol-alpha base substitution accuracy. DNA polymerase-gamma is highly accurate, producing on the average less than one frameshift error for every 200,000-400,000 nucleotides polymerized. This represents a more than 10-fold higher fidelity than for base substitutions. Among the collection of sequenced frameshifts produced by DNA polymerases-alpha and beta, both common features and distinct specificities are apparent. These specificities suggest a major role for eucaryotic DNA polymerases in modulating frameshift fidelity. Possible mechanisms for production of frameshifts are discussed in relation to the observed biases. One of these models has been experimentally supported using site-directed mutagenesis to change the primary DNA sequence of the template. Alteration of a pol-beta frameshift hotspot sequence TTTT to CTCT reduced the frequency of pol-beta-dependent minus-one-base errors at this site by more than 30-fold, suggesting that more than 97% of the errors at the TTTT run involve a slippage mechanism.     

Nuclear location of mammalian DNA polymerase activities.

Nuclei were isolated from monolayer cultures of mouse and human cells using a nonaqueous procedure of cell fractionation in which lyophilized cells were homogenized and centrifuged in 100% glycerol. In previous work we have shown that the nuclear pellet and cytoplasmic supernatant fraction contained 10% or less of the nucleic acids characteristic of the other cell fraction. Aqueous extracts made from fresh cultures and from nonaqueous material at each step of the fractionation procedure were assayed fro DNA polymerase activity. Activities were normalized to DNA contents of extracted material. Specific activity was preserved quantitatively through freezing and drying the cells, but was found to be unstable in glycerol suspensions with approximate half-lives and 1 h at 23 degrees and 4 h at 0-4 degrees. Activities were relatively stable at -25 degrees, however, so that by homogenizing only 15 min at 4 degrees and centrifuging at -25 degrees we preserved approximately 85% of the specific activity of fresh cultures in the nonaqueous nuclear fraction. Sedimentation analyses showed that the nuclear fraction contained both DNA polymerase-alpha and-beta in approximately the proportions expected if all polymerase activities were confined to the nucleus in living cells. DNA polymerase-alpha was found to be more unstable in glycerol suspensions than DNA polymerase-beta. Nuclear location of both activities was found in exponential cultures and in 3T3 mouse cultures synchronized in the G1 and S phases of the cell division cycle. We found no evidence for cytoplasmic factors affecting nuclear polymerase activities. We have concluded that the two major DNA polymerases are nuclear although one, DNA polymerase-alpha, frequently is present as a weakly bound nuclear protein.     

Differential susceptibilities of DNA polymerases-alpha and -beta to polyanions.

The effects of various polyanions including synthetic polynucleotides on DNApolymerases-alpha and -beta from blastulae of the sea urchin Hemicentrotus pulcherrimus and HeLa cells were studied. Only DNA polymerase-alpha was inhibited by polyanions, such as polyvinyl sufate, dextran sulfate, heparin, poly(G), poly(I), poly(U) and poly(ADP-Rib). Of the various polynucleotides tested, poly(G) and poly(I) were the strongest inhibitors. Kinetic studies showed that the Ki value for poly(G) was 0.3 microgram/ml and that poly(G) had 20-fold higher affinity than activated DNA for the template-primer site of DNA polymerase-alpha. Poly(U) and poly(ADP-Rib) were also inhibitory, but they were one hundredth as inhibitory as poly(G) or poly(I). Poly(A), poly(C), poly(A).poly(U) AND POLY(I).poly(C) were not inhibitory to DNA polymerase-alpha. In contrast, DNA olymerase-beta was not affected at all by these polyanions under the same conditions.     

Inhibition of mouse myeloma DNA polymerase alpha by 5-triphosphates of 1-beta-D-arabinofuranosylthymine and 1-beta-D-arabinofuranosylcytosine

This is the first report dealing with the effect of 1-beta-D-arabinofuranosylthymine 5'-triphosphate (araTTP), synthesized by a new method, on eukaryotic DNA polymerase [EC 2.7.7.7]. AraTTP was tested for the inhibition of DNA synthesis in vitro using highly purified mouse myeloma DNA polymerase alpha in comparison with 1-beta-D-arabinofuranosylcytosine 5'-triphosphate (araCTP). AraTTP was found to inhibit competitively the incorporation of [3H]dTTP into DNA and non-competitively the incorporation of [3H]dCTP, while the mode of the inhibition by araCTP was non-competitive with respect to dTTP and competitive with respect to dCTP. Neither araTTP nor araCTP was utilized as a substrate in place of dTTP or dCTP in DNA synthesis by DNA polymerase alpha.     

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.