Cell-cycle-dependent expression of DNA primase activity

Protein extracts were prepared at various times after serum stimulation of growth-arrested mouse 3T3 fibroblasts. The extracts were fractionated by sucrose gradient centrifugation and used to determine the activities of DNA polymerase alpha and DNA primase. We found that polymerase and primase appeared in close association in one homogeneous 8.2-S peak. Neither polymerase, free of associated primase, nor primase, free of polymerase, could be detected at any time after serum stimulation. The activities of both enzymes started to increase concomitantly at the beginning of the DNA replication phase of the cell cycle. We found five to six times more DNA primase activity in replicating than in resting 3T3 cells. Besides DNA primase, a second additional priming activity could be detected. This activity sedimented at 12.5 S and corresponded most probably to RNA polymerase I.     

Contribution of DNA polymerase delta to DNA replication in permeable CHO cells synchronized in S phase.

To evaluate the relative contributions of DNA polymerase alpha and DNA polymerase delta in chromosome replication during the S phase of the cell cycle, we have used the permeable cell system for replication as a functional assay. We carried out the analysis of DNA polymerases both in quiescent cells stimulated to proliferate and progress through the cell cycle (monolayers) and in actively growing cells separated into progressive stages of the cell cycle by centrifugal elutriation (suspension cultures). DNA polymerase alpha was measured by using the inhibitor butylphenyl dGTP at low concentrations. Using several inhibitors such as aphidicolin, ddTTP and butylphenyl dGTP, we found that DNA polymerase alpha and delta activity were coordinately increased during S phase and declined at the end. However, DNA polymerase delta was performing about 80% of the total replication and DNA polymerase alpha performed only 20%. This high ratio of DNA polymerase delta to DNA polymerase alpha replication activity was maintained throughout S phase in two entirely different experimental approaches.     

Activity levels of mouse DNA polymerase alpha-primase complex (DNA replicase) and DNA polymerase alpha, free from primase activity in synchronized cells, and a comparison of their catalytic properties

To asses the possible roles of the two active forms of mouse DNA polymerase alpha: primase--DNA-polymerase alpha complex (DNA replicase) and DNA polymerase alpha free from primase activity (7.3S polymerase), in nuclear DNA replication the correlation of their activity levels with the rate of nuclear DNA replication was determined and a comparison made of their catalytic properties. The experiments using either C3H2K cells, synchronized by serum starvation, or Ehrlich culture cells, arrested at the S phase by aphidicolin, showed DNA replicase to increase in cells in the S phase to at least six times that of the G0-phase cells but 7.3S polymerase to increase but slightly in this phase. This increase in DNA replicase activity most likely resulted from synthesis of a new enzyme, as shown by experiments using a specific monoclonal antibody, aphidicolin and cycloheximide. Not only with respect to the presence or absence of primase activity, but in other points as well the catalytic properties of these two forms were found to differ; DNA replicase preferred the activated calf thymus DNA with wide gaps of about 100 nucleotides long as a template-primer, while the optimal gap size for 7.3S polymerase was 40-50 nucleotides long. Size analysis of the products synthesized on M13 single-stranded circular DNA with a single 17-nucleotide primer by DNA replicase and 7.3S polymerase suggested the ability of DNA replicase to overcome a secondary structure formed in single-stranded DNA to be greater than that of 7.3S polymerase.     

Identification of DNA polymerase delta in CV-1 cells: studies implicating both DNA polymerase delta and DNA polymerase alpha in DNA replication

DNA polymerases delta and alpha were purified from CV-1 cells, and their sensitivities to the inhibitors aphidicolin, (p-n-butylphenyl)deoxyguanosine triphosphate (BuPdGTP), and monoclonal antibodies directed against DNA polymerase alpha were determined. The effects of these inhibitors on DNA replication in permeabilized CV-1 cells were studied to investigate the potential roles of polymerases delta and alpha in DNA replication. Aphidicolin was shown to be a more potent inhibitor of DNA replication than of DNA polymerase alpha or delta activity. Inhibition of DNA replication by various concentrations of BuPdGTP was intermediate between inhibition of purified polymerase alpha or delta activity. Concentrations of BuPdGTP which totally abolished DNA polymerase alpha activity were much less effective in reducing DNA replication, as well as the activity of DNA polymerase delta. Monoclonal antibodies which specifically inhibited polymerase alpha activity reduced, but did not abolish, DNA replication in permeable cells. BuPdGTP, as well as anti-polymerase alpha antibodies, inhibited DNA replication in a nonlinear manner as a function of time. Depending upon the initial or final rates of inhibition of replication by BuPdGTP and anti-alpha antibodies, as little as 50%, or as much as 80%, of the replication activity can be attributed to polymerase alpha. The remaining replication activity (20-50%) is tentatively attributed to polymerase delta, because it was aphidicolin sensitive and resistant to both anti-polymerase alpha antibodies and low concentrations of BuPdGTP. A concentration of BuPdGTP which abolished polymerase alpha activity reduced, but did not abolish, both the synthesis and maturation of nascent DNA fragments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Hydrolysis of 3'-terminal mispairs in vitro by the 3'----5' exonuclease of DNA polymerase delta permits subsequent extension by DNA polymerase alpha

Purified DNA polymerase alpha, the major replicating enzyme found in mammalian cells, lacks an associated 3'----5' proofreading exonuclease that, in bacteria, contributes significantly to the accuracy of DNA replication. Calf thymus DNA polymerase alpha cannot remove mispaired 3'-termini, nor can it extend them efficiently. We designed a biochemical assay to search in cell extracts for a putative proofreading exonuclease that might function in concert with DNA polymerase alpha in vivo but dissociates from it during purification. Using this assay, we purified a 3'----5' exonuclease from calf thymus that preferentially hydrolyzes mispaired 3'-termini, permitting subsequent extension of the correctly paired 3'-terminus by DNA polymerase alpha. This exonuclease copurifies with a DNA polymerase activity that is biochemically distinct from DNA polymerase alpha and exhibits characteristics described for a second replicative DNA polymerase, DNA polymerase delta. In related studies, we showed that the 3'----5' exonuclease of authentic DNA polymerase delta, like the purified exonuclease, removes terminal mispairs, allowing extension by DNA polymerase alpha. These data suggest that a single proofreading exonuclease could be shared by DNA polymerases alpha and delta, functioning at the site of DNA replication in mammalian cells.     

Calmodulin-specific monoclonal antibodies inhibit DNA replication in mammalian cells.

The involvement of calmodulin in the proliferation of Chinese hamster embryo fibroblast cells has been studied with a specific monoclonal antibody to calmodulin. We observed that calmodulin levels increase 2-fold in the late G1 period in these cells, and this coincides with the increase in DNA polymerase alpha activity as the cells progress synchronously from a quiescent state in the G1 to the S phase. However, there is a concurrent 10-fold enhancement of thymidine kinase activity, which is tightly coupled to the entry of cells into the S phase. Incubation of permeabilized S-phase cells with calmodulin-specific murine monoclonal antibody resulted in a dose-dependent inhibition of DNA replication. This inhibitory effect of anti-calmodulin antibodies on DNA replication is completely reversed by the addition of exogenously purified calmodulin. These observations provide evidence for the involvement of calmodulin in DNA replication and, therefore, in cell proliferation during the S phase.     

Immunocytochemical localization of chick DNA polymerases alpha and beta +

An immunofluorescent method using specific antibodies was employed to detect DNA polymerases alpha and beta in chick cells. With monoclonal antibodies produced by four independent hybridoma clones, most of the DNA polymerase alpha was shown to be present in nuclei of cultured chick embryonic cells. With a polyclonal, but highly specific, antibody against DNA polymerase beta, this enzyme was also shown to be present in nuclei. DNA polymerase alpha was detected in proliferating cells before cell contact and in lesser amount in resting cells after cell contact, indicating that its content is closely correlated with cell proliferation. On the other hand, similar amounts of DNA polymerase beta were detected in proliferating and resting cells. Furthermore, DNA polymerase beta was detected in nuclei of most cells, while DNA polymerase alpha was detected only in large round nuclei in seminiferous tubules of chick testis. DNA polymerase alpha is presumably present in cells that are capable of DNA replication, and during the cell cycle it seems to remain in the nuclei during the G1, S, and G2 phases, but to leave from condensed chromatin for the cytoplasm during the mitotic phase.     

DNA polymerase alpha and the regulation of entry into S phase in heterokaryons

We have previously reported that the DNA polymerase alpha activity/unit cellular protein is decreased in late-passage (senescent) human diploid fibroblast-like (HDFL) cultures due to the cellular enlargement associated with in vitro aging. In the studies described here, we have used cell fusion technology to investigate the formal kinetic relationship between the concentration of DNA polymerase alpha and the rate of reinitiation of DNA synthesis in nuclei from senescent cells. Heterokaryons were derived from the fusion of senescent cells to a series of actively dividing cell types with inherently different DNA polymerase alpha activities per cell. A kinetic analysis revealed a first-order relationship between the entry into S phase of senescent nuclei and the concentration of DNA polymerase alpha activity calculated to be in heterokaryons. This result suggests that increases in cell volume may be related to the decline in proliferative activity of late-passage HDFL cells, via "dilution" of factors essential for cellular replication.     

Characterization of DNA polymerase alpha activity from a mouse DNA temperature-sensitive mutant, strain tsFT20, which shows a defect in DNA polymerase alpha activity at restrictive temperatures

tsFT20 cells derived from mouse FM3A cells are DNA temperature-sensitive mutants, which have heat-labile DNA polymerase alpha activity. When tsFT20 cells were incubated at restrictive temperatures, intracellular levels of DNA polymerase alpha activity changed biphasically, showing an initial fast decrease (phase I) and a subsequent slow decrease (phase II). The activity of DNA polymerase alpha from tsFT20 cells cultured at a permissive temperature (33 degrees C) was greatly increased by the addition of glycerol or ethylene glycol to the reaction mixture, while little increase in enzyme activity was observed at any concentration of glycerol or ethylene glycol tested with the enzyme from the cells cultured at a restrictive temperature (39 degrees C) for 8 h (phase II). The activity of DNA polymerase alpha from wild-type cells was also increased by the addition of glycerol but the increase was much less than that in the tsFT20 cells. An in vitro preincubation experiment showed that DNA polymerase alpha from tsFT20 cells cultured at 33 degrees C very rapidly lost its ability to be stimulated by glycerol. Furthermore, the experiment using the extracts prepared from tsFT20 cells cultured at 39 degrees C for various periods showed that the ability to be stimulated by glycerol decreased with the duration of incubation time at 39 degrees C. DNA polymerase alpha from the revertants, which can grow at 39 degrees C and exhibit a partial recovery in heat stability of DNA polymerase alpha activity, showed an intermediate response to glycerol, between those of DNA polymerase alpha from tsFT20 and from the wild-type cells. Finally, it was observed that the level of enzyme activity that can be stimulated by glycerol correlated well with the DNA synthesizing ability of tsFT20 cells.     

Exposure of HeLa DNA polymerase alpha to protein kinase C affects its catalytic properties

Protein kinase C (Ca2+/phospholipid-dependent protein kinase) purified from rat brain or endogenous to cell-free extracts from HeLa cells stimulates, by a factor of 2-3, HeLa DNA polymerase alpha but not beta or gamma. Monoclonal antibody to the kinase prevents the stimulation, and monoclonal antibody to human DNA polymerase alpha neutralizes the enhanced activity. Reduced DNA polymerase alpha activity is obtained from noncycling HeLa cells and this activity has lower fidelity when copying synthetic primer-templates than that obtained from log phase cultures. After exposure to the kinase, the fidelities and activities of the polymerase from both sources increase by 2- to 3-fold. This improved accuracy is not accompanied by the appearance of triphosphatase or DNase activities. Exposure to the protein kinase reduces the Km for activated DNA and for poly(dA-dT) but not for dNTPs. Moreover, the Vmax for activated DNA but not for poly(dA-dT) is increased approximately 2- to 3-fold. These alterations suggest a role for protein phosphorylation in modulating DNA polymerase alpha.     

Cell cycle-dependent phosphorylation of human DNA polymerase alpha

The expression of DNA polymerase alpha, a principal chromosome replication enzyme, is constitutive during the cell cycle. We show in this report that DNA polymerase alpha catalytic polypeptide p180 is phosphorylated throughout the cell cycle and is hyperphosphorylated in G2/M phase. The p70 subunit is phosphorylated only in G2/M phase. This cell cycle-dependent phosphorylation is due to cell cycle-dependent kinase(s) and not to phosphatase(s). In vitro evidence indicates the involvement of p34cdc2 kinase in the mitotic phosphorylation of DNA polymerase alpha. Tryptic phosphopeptide maps demonstrate that peptides phosphorylated in vitro are identical to those phosphorylated in vivo. DNA polymerase alpha from mitotic cells is found to have lower affinity for single-stranded DNA than does polymerase alpha from G1/S phase cells. These results imply that the mitotic phosphorylation of polymerase alpha may affect its physical interaction with other replicative proteins and/or with DNA at the replication fork.     

The effect of in vitro heat exposure on the recovery of nuclear matrix-bound DNA polymerase alpha activity during the different phases of the cell cycle in synchronized HeLa S3 cells.

HeLa S3 cells were synchronized by a double thymidine block or aphidicolin treatment and the levels of nuclear matrix-bound DNA polymerase alpha activity were then measured using activated calf thymus DNA as template. The nuclear matrix was obtained by 2 M NaCl extraction and DNase I digestion of isolated nuclei incubated at 37 degrees C for 45 min prior to subfractionation. In all phases of the cell cycle 25-30% of nuclear DNA polymerase alpha activity remained matrix-bound, even when cells were in the G1 phase. No dynamic association of DNA polymerase alpha activity with the matrix was seen, at variance with previous results obtained in regenerating rat liver. The variations measured in matrix-bound activity closely followed those detected in isolated nuclei throughout the cell cycle. If nuclei were not heat-stabilized very low levels of DNA polymerase alpha activity were measured in the matrix (1-2% of total nuclear activity). Heat incubation of nuclei failed to produce any enrichment in matrix-associated newly replicated DNA, whereas the sulfhydryl cross-linking chemical sodium tetrathionate did. Therefore the results obtained after the heat stabilization procedure do not completely fit with the model that envisions the nuclear matrix as the active site where eucaryotic DNA replication takes place.     

Studies of Schizosaccharomyces pombe DNA polymerase alpha at different stages of the cell cycle.

The status of Schizosaccharomyces pombe (fission yeast) DNA polymerase alpha was investigated at different stages of the cell cycle. S.pombe DNA polymerase alpha is a phosphoprotein, with serine being the exclusive phosphoamino acid. By in vivo pulse labeling experiments DNA polymerase alpha was found to be phosphorylated to a 3-fold higher level in late S phase cells compared with cells in the G2 and M phases, but the steady-state level of phosphorylation did not vary significantly during the cell cycle. Tryptic phosphopeptide mapping demonstrated that the phosphorylation sites of DNA polymerase alpha from late S phase cells were not the same as that from G2/M phase cells. DNA polymerase alpha partially purified from G1/S cells had a different mobility in native gels from that from G2/M phase cells. The partially purified polymerase alpha from G1/S phase cells had a higher affinity for single-stranded DNA than that from G2/M phase cells. Despite the apparent differences in cell cycle-dependent phosphorylation, mobility in native gels and affinity for DNA, the in vitro enzymatic activity of the partially purified DNA polymerase alpha did not appear to vary during the cell cycle. The possible biological significance of these cell cycle-dependent characteristics of DNA polymerase alpha is discussed.     

Microtubule-associated protein-2 stimulates DNA synthesis catalyzed by the nuclear matrix

Microtubule-associated protein-2 (MAP-2) isolated from porcine brains stimulated DNA synthesis catalyzed by the nuclear matrix isolated from Physarum polycephalum in the presence of activated DNA as exogenous templates. The degree of the stimulation depended on the amount of the nuclear matrix, but not on that of the template. MAP-2 also stimulated DNA polymerase alpha activity solubilized from nuclei, but not DNA polymerase beta activity. These results suggest that MAP-2 stimulates DNA synthesis by interacting with the putative DNA replication machinery including DNA polymerase alpha bound to the matrix. Similar stimulation occurred in the nuclear matrix isolated from HeLa and rat ascites hepatoma cells, which strongly suggests that MAP-2 is involved in the control of DNA replication in eukaryotic cells.     

Calmodulin regulates DNA polymerase alpha activity during proliferative activation of NRK cells.

When Normal Rat Kidney cells are allowed to reenter the cell cycle after quiescence they start to replicate DNA around 12 h, reaching a maximum at 20 h. Activation of DNA polymerase alpha parallels the increase in DNA synthesis. The addition of two different anti-calmodulin drugs, trifluoroperazine (7.5 microM) or W13 (10 micrograms/ml), to the media at 4 h after proliferative activation, inhibits DNA synthesis by 55% and 80%, respectively. The blockade of calmodulin produced by trifluoroperazine allows the cells to progress through G1 phase but stops progression through S phase as determined by 5-Bromo deoxyuridine labeling. Both anti-calmodulin drugs also inhibit by more than 50% the increase in DNA polymerase alpha activity observed at 20 h. These results indicate that a calmodulin-dependent event, essential for the activation of DNA polymerase alpha and subsequently for DNA replication, is produced during G1. Therefore, the control of DNA polymerase alpha activation is one of the ways by which calmodulin is regulating the progression of NRK cells through S phase.     

Role of the second-largest subunit of DNA polymerase alpha in the interaction between the catalytic subunit and hyperphosphorylated retinoblastoma protein in late S phase

DNA polymerase alpha (pol-alpha) is a heterotetrameric enzyme (p180-p68-p58-p48 in mouse) that is essential for the initiation of chain elongation during DNA replication. The catalytic (p180) and p68 subunits of pol-alpha are phosphorylated by Cdk-cyclin complexes, with p68 being hyperphosphorylated by cyclin-dependent kinases in G(2) phase of the cell cycle. The activity of Cdk2-cyclin A increases during late S phase and peaks in G(2) phase. We have now examined the role of p68 in the interaction between the catalytic subunit of pol-alpha and hyperphosphorylated retinoblastoma protein (ppRb) and in the stimulation of the polymerase activity of pol-alpha by ppRb. With the use of recombinant proteins, we found that nonphosphorylated p68 inhibited the stimulation of pol-alpha activity by ppRb, suggesting that p68 might impede the association of ppRb with p180. Phosphorylation of p68 by Cdk2-cyclin A greatly reduced its inhibitory effect. Immunofluorescence analysis also revealed that ppRb localized at sites of DNA replication specifically in late S phase. These results suggest that Cdk-cyclin A can phosphorylate pol-alpha which may result in a conformational change in pol-alpha facilitating its interaction with and activation by ppRb.     

Inhibition of DNA replication and DNA polymerase alpha activity by monoclonal anti-(DNA polymerase alpha) immunoglobulin G and F(ab) fragments

The effect of monoclonal anti-(DNA polymerase alpha) immunoglobulin G (IgG) and F(ab) fragments on DNA replication in lysolecithin-permeabilized human cells and on DNA polymerase alpha activity was determined. DNA polymerase alpha activity in vitro was inhibited equally by the same concentrations of monoclonal IgGs and F(ab) fragments. However, the IgGs and F(ab) fragments were not equally potent in inhibiting DNA replication in permeable cells. In general, the F(ab) fragments were approximately equal to 10-fold more potent than IgGs in inhibiting DNA replication, suggesting the F(ab) fragments cross the nuclear membrane more readily than IgGs. Immunocytochemical studies demonstrated that at least a fraction of anti-(DNA polymerase alpha) IgGs entered the nucleus of permeable cells. For most antibodies tested, the IgG or F(ab) concentration needed to inhibit replication was several orders of magnitude higher than that needed to neutralize polymerase alpha activity extracted from the same number of cells. Anti-(DNA polymerase alpha) F(ab) fragments were shown to inhibit the discontinuous synthesis of Okazaki DNA, as well as the maturation of Okazaki DNA to larger DNA, thereby implicating DNA polymerase alpha in both of these processes.     

Synthesis of DNA polymerase alpha analyzed by immunoprecipitation from synchronously proliferating cells

Synchronously proliferating TC7 monkey and 3T3 mouse cells were pulse labeled with [35S]methionine. Radioactively labeled DNA polymerase alpha was immunoprecipitated with polymerase-specific monoclonal antibodies. The precipitated polypeptides were identified by gel electrophoresis and fluorography. The increase in DNA polymerase alpha activity during S phase was accompanied by an increased synthesis of the enzyme. Some DNA polymerase alpha was synthesized in growth-arrested TC7 cells whereas the synthesis of the large polymerase subunit in 3T3 cells was strictly coupled to the replicative phase of the cell cycle. We also found that DNA polymerase alpha was more prone to proteolysis in TC7 cells than in 3T3 cells. In 3T3 cells, a polymerase subunit with an apparent molecular weight of 186 000 was observed; this subunit was most probably associated with two smaller subunits of Mr 74 000 and 52 000. Synthesis of these three polymerase-associated polypeptides appeared to be regulated differently.     

Further characterization of a murine temperature-sensitive mutant, tsFT20 strain, containing heat-labile DNA polymerase alpha-activity

tsFT20 cells, which have temperature-sensitive DNA polymerase alpha-activity, were characterized mainly at the cellular level. The cells lost their ability to synthesize DNA immediately after a shift to non-permissive temperature. The extent of decrease in the activity of DNA polymerase alpha in whole-cell extracts was the same as that of the decrease in the DNA replication ability determined by [3H]thymidine incorporation. At 39 degrees C, tsFT20 cells lost most of their colony-forming ability in one doubling time (16 h). The cells could not grow at higher than 38 degrees C, but could grow at 37 degrees C. When tsFT20 cells were synchronized at the G1/S boundary and incubated at 39 degrees C, they could not complete the S phase, ceasing cell cycle progression in mid-S phase. A temperature shift (33 degrees C----39 degrees C) experiment indicated that the whole S phase was temperature-sensitive, whereas the G2 and M phases were not. These results confirmed that DNA polymerase alpha plays a key role in DNA replication in mammalian cells.     

Palm mutants in DNA polymerases alpha and eta alter DNA replication fidelity and translesion activity

We isolated active mutants in Saccharomyces cerevisiae DNA polymerase alpha that were associated with a defect in error discrimination. Among them, L868F DNA polymerase alpha has a spontaneous error frequency of 3 in 100 nucleotides and 570-fold lower replication fidelity than wild-type (WT) polymerase alpha. In vivo, mutant DNA polymerases confer a mutator phenotype and are synergistic with msh2 or msh6, suggesting that DNA polymerase alpha-dependent replication errors are recognized and repaired by mismatch repair. In vitro, L868F DNA polymerase alpha catalyzes efficient bypass of a cis-syn cyclobutane pyrimidine dimer, extending the 3' T 26000-fold more efficiently than the WT. Phe34 is equivalent to residue Leu868 in translesion DNA polymerase eta, and the F34L mutant of S. cerevisiae DNA polymerase eta has reduced translesion DNA synthesis activity in vitro. These data suggest that high-fidelity DNA synthesis by DNA polymerase alpha is required for genomic stability in yeast. The data also suggest that the phenylalanine and leucine residues in translesion and replicative DNA polymerases, respectively, might have played a role in the functional evolution of these enzyme classes.