Analysis of the mechanism of ATP stimulation of calf thymus DNA alpha-polymerase

Effects of aging and dietary restriction on DNA polymerase expression in mice

DNA polymerase alpha was isolated from livers of 6-month-, 16-month-, or 26-month-old mice fed ad libitum, or calorically restricted. The enzymes differed in chromatographic characteristics, binding affinity for DNA, and activity, with both total activity and specific activity of DNA polymerase alpha decreasing as a function of age. A positive correlation was observed between polymerase alpha specific activity and the affinity of enzyme binding to activated DNA template-primer. The age-associated decline in enzyme activity was modified by dietary restriction, with measurably higher activity seen for polymerases from dietary restricted animals compared with ad libitum animals of all ages. The data suggest that dietary restriction could act to delay the age-associated decrease in cellular capacity for DNA synthesis, which may play a significant role in prolonging the onset of age-related diseases in which decreased DNA synthesis is a potential component.

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.

Age-related changes in DNA polymerase alpha expression

DNA polymerase alpha isozymes differing in specific activity and affinity of binding to DNA were purified from human fibroblasts derived from donors of different ages. Fetal-derived fibroblasts expressed a single, high-activity enzyme (A2), with high affinity of binding to DNA. Adult-derived fibroblasts exhibited two forms of DNA polymerase alpha, one identical to the fetal enzyme, and a second with about tenfold less activity showing low affinity of binding to DNA (A1). The ratio of DNA polymerase A2/A1 decreased dramatically with age, from 100% A2 in fetal-derived fibroblasts to about 94% A1 in fibroblasts derived from a 66-year-old donor. The DNA binding affinity of polymerase alpha A1 from adult-derived fibroblasts increased concomitant with a significant increase in activity when the enzyme was treated with phosphatidylinositol-4-monophosphate (PIP), or with inositol-1, 4-bisphosphate (I(1,4)P2). The enzyme reverted back to a less active form, with loss of the noncovalently bound I(1,4)P2, as a function of time. When permeabilized human fibroblasts with low DNA excision repair capacity were treated with 7,8-dihydrodiol-9,10-epoxybenzo(a)-pyrene (BPDE) in the presence of 32P-ATP, phosphatidylinositol, and cycloheximide, excision repair was initiated and 32P-labeled DNA polymerase alpha was recovered in the absence of de novo protein synthesis. DNA synthesis associated with either scheduled DNA synthesis or BPDE-initiated excision repair declined as a function of increased age in human cells. The data suggest that the decline in both DNA excision repair-associated and mitogen-activated DNA synthesis may be correlated with decreased total intracellular levels of DNA polymerase and with the decline in polymerase alpha activity as a function of age, that DNA repair-associated initiation of DNA synthesis in adult-derived cells may increase with activation of a pool of low activity DNA polymerase alpha, and that DNA polymerase alpha activity increases as a function of enzyme interaction with a component of the PI phosphorylation cascade.

Purification of Norman Murine Sarcoma DNA polymerase alpha forms with different DNA template primer binding affinity and different specific activity

1. DNA polymerase alpha was isolated from Norman Murine Myxosarcoma cells using ion exchange, immunoaffinity, and DNA affinity chromatography, showing two distinct enzyme forms designated A1 and A2. 2. Chromatographic analysis of polymerase alpha forms A1 and A2 indicate a charge difference and a difference in affinity of binding to DNA between polymerase alpha forms which were equally reactive to anti-DNA polymerase alpha monoclonal IgG. 3. Polymerase A1 specific activity was about 3600 U/mg while A2 specific activity was about 40,000 U/mg.

Intracellular compartmentation of diadenosine tetraphosphate (Ap4A) and dTTP in rat liver

1. The intracellular compartmentation of diadenosine tetraphosphate (Ap4A) and of dTTP was studied in rat liver cells using non-aqueous glycerol for the isolation of cell nuclei. 2. This method allows a stepwise removal of cytoplasm from the nuclei. 3. The decrease in Ap4A or dTTP during the process was compared to the simultaneous decrease in RNA, which was taken to represent the cytoplasm. 4. In regenerating liver excised 24 hr after partial hepatectomy, Ap4A was almost equally distributed between the nucleus and cytoplasm. 5. In livers from unoperated control rats, the nuclear concentration of Ap4A was slightly elevated compared to that of whole cells. dTTP was only investigated in regenerating liver. 6. Significantly higher concentrations were found in the nuclear fractions. 7. The purest nuclei contained about 26% of whole cell levels of dTTP, while their RNA values had decreased to 7% of the whole cell RNA. 8. Considering that the liver cell nucleus comprises about 7% of the entire cell mass, a nuclear dTTP concentration of 26% indicates significantly higher dTTP levels in the nuclear compartment than in the cytoplasm of regenerating rat liver cells.

Interaction of phosphatidylinositol-4-monophosphate with a low activity form of DNA polymerase alpha: a potential mechanism for enzyme activation

1. DNA polymerase alpha isolated from Norman murine myxosarcoma exhibited two isozyme forms, one with low specific activity and low DNA binding affinity (A1), and one with high specific activity and high DNA binding affinity (A2). 2. DNA polymerase alpha A1, but not A2, showed a significant increase in specific activity after treatment with phosphatidylinositol, ATP and phosphatidylinositol kinase, or with phosphatidylinositol-4-monophosphate. 3. Treatment of DNA polymerase alpha A1 with the phospholipase C hydrolysis product of phosphatidylinositol-4-monophosphate, inositol-1,4-bisphosphate, was sufficient to effect the transient increase in activity of polymerase A1 to a form not chromatographically distinguishable from isozyme form A2.

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)

Apparent stimulation of calf thymus DNA polymerase alpha by ATP

The mechanism by which millimolar concentrations of ATP stimulate the activity and increase the processivity of calf thymus DNA polymerase alpha has been investigated with poly(dA)/oligo(dT) as template/primer to eliminate possible effects due to primer synthesis. The effect of ATP on the rate of DNA synthesis with this template/primer was found to be dependent upon whether or not the ATP was neutralized and the species of buffer used in the reaction. The present studies suggest that ATP stimulation of calf thymus DNA polymerase can be attributed to changes in the pH of the reaction mixture, a shift in the magnesium ion optimum, or both. Furthermore, effects of ATP on the processivity of DNA polymerase alpha could be mimicked by lowering the pH of the reaction mixture.

In vivo levels of diadenosine tetraphosphate and adenosine tetraphospho-guanosine in Physarum polycephalum during the cell cycle and oxidative stress

Cellular levels of diadenosine tetraphosphate (Ap4A) and adenosine tetraphospho-guanosine (Ap4G) were specifically measured during the cell cycle of Physarum polycephalum by a high-pressure liquid chromatographic method. Ap4A was also measured indirectly by a coupled phosphodiesterase-luciferase assay. No cell cycle-specific changes in either Ap4A or Ap4G were detected in experiments involving different methods of assay, different strains of P. polycephalum, or different methods of fixation of macroplasmodia. Our results on Ap4A are in contrast with those reported previously (C. Weinmann-Dorsch, G. Pierron, R. Wick, H. Sauer, and F. Grummt, Exp. Cell Res. 155:171-177, 1984). Weinmann-Dorsch et al. reported an 8- to 30-fold increase in Ap4A in early S phase in P. polycephalum, as measured by the phosphodiesterase-luciferase assay. We also measured levels of Ap4A, Ap4G, and ATP in macroplasmodia treated with 0.1 mM dinitrophenol. Ap4A and Ap4G transiently increased three- to sevenfold after 1 h and then decreased concomitantly with an 80% decrease in the level of ATP after 2 h in the presence of dinitrophenol. These results do not support the hypothesis that Ap4A is a positive pleiotypic activator that modulates DNA replication, but they are consistent with the hypothesis proposed for procaryotes that Ap4A and Ap4G are signal nucleotides or alarmones of oxidative stress (B.R. Bochner, P.C. Lee, S.W. Wilson, C.W. Cutler, and B.N. Ames, Cell 37:225-232, 1984).

Monoclonal antibody that blocks phosphoinositide-dependent activation of mouse tumor DNA polymerase alpha

A monoclonal antibody (MaB) against mouse sarcoma DNA polymerase alpha was isolated from the culture medium of an IgG-secreting hybridoma. The MaB demonstrated reactivity against two murine DNA polymerase alpha preparations and a calf thymus DNA polymerase alpha. Murine sarcoma polymerase was activated in vitro by phosphatidylinositol-4-monophosphate (PIP) showing increased deoxynucleotidyltransferase activity and enhanced binding affinity to activated DNA template. The MaB did not neutralize polymerase activity, but blocked further activation of the enzyme by PIP. Treatment of polymerase with MaB prior to treatment with PIP inhibited both increased enzyme activation and increased binding of the enzyme to DNA template. Treatment of polymerase with MaB subsequent to treatment with PIP did not block enzyme activation or increased DNA template binding. The data suggest that this anti-DNA polymerase alpha IgG is directed against a regulatory subunit of the polymerase rather than the catalytic subunit. The antibody may serve to distinguish between DNA polymerase alpha preparations with distinctly different regulatory subunits.

In vivo levels of diadenosine tetraphosphate and adenosine tetraphospho-guanosine in Physarum polycephalum during the cell cycle and oxidative stress

Cellular levels of diadenosine tetraphosphate (Ap4A) and adenosine tetraphospho-guanosine (Ap4G) were specifically measured during the cell cycle of Physarum polycephalum by a high-pressure liquid chromatographic method. Ap4A was also measured indirectly by a coupled phosphodiesterase-luciferase assay. No cell cycle-specific changes in either Ap4A or Ap4G were detected in experiments involving different methods of assay, different strains of P. polycephalum, or different methods of fixation of macroplasmodia. Our results on Ap4A are in contrast with those reported previously (C. Weinmann-Dorsch, G. Pierron, R. Wick, H. Sauer, and F. Grummt, Exp. Cell Res. 155:171-177, 1984). Weinmann-Dorsch et al. reported an 8- to 30-fold increase in Ap4A in early S phase in P. polycephalum, as measured by the phosphodiesterase-luciferase assay. We also measured levels of Ap4A, Ap4G, and ATP in macroplasmodia treated with 0.1 mM dinitrophenol. Ap4A and Ap4G transiently increased three- to sevenfold after 1 h and then decreased concomitantly with an 80% decrease in the level of ATP after 2 h in the presence of dinitrophenol. These results do not support the hypothesis that Ap4A is a positive pleiotypic activator that modulates DNA replication, but they are consistent with the hypothesis proposed for procaryotes that Ap4A and Ap4G are signal nucleotides or alarmones of oxidative stress (B.R. Bochner, P.C. Lee, S.W. Wilson, C.W. Cutler, and B.N. Ames, Cell 37:225-232, 1984).

Phosphatidylinositol-dependent activation of DNA polymerase alpha

DNA polymerase alpha was activated in vitro by cAMP-independent, phospholipid-dependent, protein kinase catalytic subunit. Of the phospholipids examined, phosphatidylinositol showed the greatest potential for interaction with protein kinase and ATP to activate DNA polymerase alpha in vitro. DNA polymerase alpha was directly activated by phosphorylated phosphatidylinositol in the absence of protein kinase and ATP. Activation of DNA polymerase alpha as a function of phosphorylation was demonstrated using 32P-ATP as the phosphate donor. In vitro treatment of the enzyme with phosphatidylinositol produced Linweaver-Burk plots showing noncompetitive kinetics of enzyme activation, suggesting that activation occurs prior to binding of the enzyme to DNA template/primer. These data indicate that DNA polymerase alpha may be activated in vitro in the presence of protein kinase, ATP, and phosphatidylinositol, and suggest that phosphorylation of the enzyme may constitute an intracellular mechanism of enzyme activation.

Purification and characterization of two new high molecular weight forms of DNA polymerase delta

Two high molecular weight DNA polymerases, which we have designated delta I and delta II, have been purified from calf thymus tissue. Using Bio Rex-70, DEAE-Sephadex A-25, and DNA affinity resin chromatography followed by sucrose gradient sedimentation, we purified DNA polymerase delta I 1400-fold to a specific activity of 10 000 nmol of nucleotide incorporated h-1 mg-1, and DNA polymerase delta II was purified 4100-fold to a final specific activity of 30 000 nmol of nucleotide incorporated h-1 mg-1. The native molecular weights of DNA polymerase delta I and DNA polymerase delta II are 240 000 and 290 000, respectively. Both enzymes have similarities to other purified delta-polymerases previously reported in their ability to degrade single-stranded DNA in a 3' to 5' direction, affinity for an AMP-hexane-agarose matrix, high activity on poly(dA) X oligo(dT) template, and relative resistance to the polymerase alpha inhibitors N2-(p-n-butylphenyl)dATP and N2-(p-n-butylphenyl)dGTP. These two forms of DNA polymerase delta also share several common features with alpha-type DNA polymerases. Both calf DNA polymerase delta I and DNA polymerase delta II are similar to calf DNA polymerase alpha in molecular weight, are inhibited by the alpha-polymerase inhibitors N-ethylmaleimide and aphidicolin, contain an active DNA-dependent RNA polymerase or primase activity, display a similar extent of processive DNA synthesis, and are stimulated by millimolar concentrations of ATP. We propose that calf DNA polymerase delta I, which also has a template specificity essentially identical with that of calf DNA polymerase alpha, could be an exonuclease-containing form of a DNA replicative enzyme.

Is Ap4A an activator of eukaryotic DNA replication?

The most well established fact concerning Ap4A metabolism is that the concentration of this compound is cell cycle and cell proliferation dependent. An additional intriguing fact is that Ap4A can stimulate DNA synthesis in cell extracts, and when injected into living cells. In view of these facts, it is not surprising that Ap4A has been postulated to regulate the initiation of DNA replication. However, in our opinion, experimental efforts designed to test this hypothesis do not conclusively link Ap4A to DNA replication. Work on the mechanism of stimulation of DNA synthesis in vitro indicates that Ap4A and a variety of adenylated nucleotides increase DNA synthetic rates by acting as primers. Thus far there is no evidence that this primer function plays a role in the initiation of normal DNA replication in vivo, or that Ap4A is unique in this capacity to stimulate initiation processes. Additional experiments have shown an association of partially purified DNA alpha polymerase with both tryptophanyl-tRNA synthetase and a protein capable of binding Ap4A. The Ap4A-binding protein appears to be necessary for Ap4A to assume the correct conformation for priming, since physiological levels of Ap4A are not stimulatory for highly purified DNA alpha polymerase. The relevance of tRNA synthetases to the regulation hypothesis is their ability to produce Ap4A. Ironically, mammalian tryptophanyl-tRNA synthetase does not appear to have this capacity. Furthermore, the association of alpha polymerase with either Ap4A-binding protein or tryptophanyl-tRNA synthetase in vivo has not been conclusively demonstrated. Although Ap4A has been postulated to regulate many phenomena in eukaryotes and bacteria, such as entry into S phase and the response to oxygen deprivation, the links between Ap4A and these processes are still only circumstantial. It is tempting to extrapolate from the alarmone and stringent responses of bacteria to other systems, but these phenomena are not known to occur in eukaryotic cells. Similar deprivation and inhibition experiments in mammalian cells have been shown to stop growth at a synchronous position in cell cycle, and the Ap4A concentration has been found simply to vary accordingly. The addition or depletion of Ap4A from intracellular pools has not been shown to alter cell cycle. Therefore, while the speculation concerning the role of Ap4A in vivo is a good source of future experiments, at this point its role as an important regulatory compound is far from demonstrated.