Activation of the p34 CDC2 protein kinase at the start of S phase in the human cell cycle.

Using a protocol for selecting cells on the basis of both size and age (with respect to the preceding mitosis), we isolated highly synchronous human G1 cells. With this procedure, we demonstrated that the p34 CDC2 kinase was activated at the start of S phase. Cyclin A synthesis began at the same time, and activation of the p34 CDC2 kinase at the start of S phase was, at least in part, due to its association with cyclin A. Furthermore, cells synchronized in late G1 by exposure to the drug mimosine contain active cyclin A/p34 CDC2 kinase, indicating that p34 CDC2 activation can occur before DNA synthesis begins. Thus, the cyclin A/CDC2 complex, which previously has been shown to be sufficient to start SV40 DNA synthesis in vitro, assembles and is activated at the start of S phase in vivo.

Cell cycle control of DNA replication by a homologue from human cells of the p34cdc2 protein kinase.

The regulation of DNA replication during the eukaryotic cell cycle was studied in a system where cell free replication of simian virus 40 (SV40) DNA was used as a model for chromosome replication. A factor, RF-S, was partially purified from human S phase cells based on its ability to activate DNA replication in extracts from G1 cells. RF-S contained a human homologue of the Schizosaccharomyces pombe p34cdc2 kinase, and this kinase was necessary for RF-S activity. The limiting step in activation of the p34 kinase at the G1 to S transition may be its association with a cyclin since addition of cyclin A to a G1 extract was sufficient to start DNA replication. These observations suggest that the role of p34cdc2 in controlling the start of DNA synthesis has been conserved in evolution.

Requirement for proliferating cell nuclear antigen expression during stages of the Chinese hamster ovary cell cycle.

Proliferating cell nuclear antigen (PCNA/cyclin) is a nuclear protein that can stimulate purified DNA polymerase delta in vitro, and its synthesis correlates with the proliferation rate of cells. We have attempted to determine whether synthesis of PCNA/cyclin in Chinese hamster ovary cells is necessary to regulate entry into S phase. We have measured cellular PCNA/cyclin concentration of the mRNA or protein throughout the cell cycle. Cells were separated by centrifugal elutriation into populations enriched for G-1, S, and G-2/M phases. Quantitative Northern hybridization analysis was performed on RNA isolated from each cell population by using a cDNA clone of PCNA/cyclin as a probe. Results demonstrated that although intact PCNA/cyclin mRNA is present during all phases of the cell cycle, an induction of about 3-fold occurs during S phase. Two-parameter staining for PCNA/cyclin and DNA, and analysis by flow cytometry, confirmed that the quantity of PCNA/cyclin protein in the cells increases severalfold in G-1 or early S phase but generally is invariant in S and G-2/M phases. This cell cycle dependence of PCNA/cyclin expression suggests that the observed synthesis is a prerequisite for initiation of DNA replication. Introduction of an antisense oligonucleotide complementary to the PCNA/cyclin mRNA to inhibit PCNA/cyclin synthesis effectively prevented entry of G-1 phase cells into S phase. A complementary sense oligonucleotide used as a control did not have an inhibitory effect. This result suggests that a threshold concentration of PCNA/cyclin is necessary for entry into S phase.

Calf thymus DNA polymerases alpha and delta are capable of highly processive DNA synthesis.

We have demonstrated that calf thymus DNA polymerases alpha and delta are capable of highly processive DNA synthesis. Processivity values between 300 and 2000 nucleotides were observed when poly(dA)-oligo(dT) or singly primed single-stranded circular bacteriophage M13 DNA at pH 6.0 and 1 mM magnesium chloride was used. These conditions do not correlate with conditions, pH 7.0 and 5 mM magnesium chloride, that support the maximum synthetic rate. Lowering the pH and magnesium concentration lowers the Km value of the reaction with respect to primer terminus concentration. Furthermore, under these same conditions, both polymerases become insensitive to dissociation from the template as a result of encountering the 5' ends of primers. Overall, these results suggest that the affinity of the polymerases for the primer termini is higher throughout the polymerization reaction of pH and magnesium concentrations are lowered from those favoring maximum synthetic rate. Experiments with short primer templates, however, indicate that this higher affinity does not cause the DNA polymerase to remain stably bound after synthesizing up to the end of the template.

Cell cycle dependent activities of DNA polymerases alpha and delta in Chinese hamster ovary cells.

The activities of DNA polymerases alpha and delta, in extracts from Chinese hamster ovary (CHO) cells, were assayed in order to determine whether these polymerases are regulated during the cell cycle. An exponential population of CHO cells was separated into enriched populations of G-1, S, and G-2/M phases of cell cycle by centrifugal elutriation. Total cell homogenates from each population were assayed for DNA polymerase activity by measuring labeled nucleotide incorporation into the exogenous templates oligo(dT).poly(dA) and DNase I activated calf thymus DNA. In these experiments, specific DNA polymerase inhibitors were added to assays of the cellular extracts to allow for the independent measurement of activities of DNA polymerases alpha and delta. Comparisons of total DNA polymerase activity from cellular extracts, sampled from each portion of the cell cycle, demonstrated no significant change with respect to the concentration of total protein. However, results indicate that the activity of DNA polymerase delta increases with respect to that of DNA polymerase alpha in the G-2/M portion of the cell cycle. This difference in relative activities of DNA polymerases alpha and delta suggests a coordinate regulation of a specific species of DNA polymerase during the cell cycle.

Properties of two forms of DNA polymerase delta from calf thymus.

Purified calf thymus DNA polymerases delta I and II each have an associated 3' to 5' exonuclease but otherwise resemble DNA polymerase alpha in size, biochemical kinetic parameters, and the presence of DNA primase [Crute, J. J., Wahl, A. F., & Bambara, R. A. (1986) Biochemistry 25, 26-36]. Here we demonstrate a functional association of polymerase and exonuclease with each delta form. Furthermore, we show that the exonuclease can be dissociated from DNA polymerase delta I but does not appear to be removable from DNA polymerase delta II. Polymerases delta I, delta II, and alpha are equally sensitive to the inhibitor aphidicolin, suggesting a similarity in active site structure. In comparison with DNA polymerase alpha and delta II, DNA polymerase delta I has intermediate sensitivity to 2-(p-n-butylanilino)-2'-deoxyadenosine 5'-triphosphate (BuAdATP) or N2-(p-n-butylphenyl)-2'-deoxyguanosine 5'-triphosphate (BuPdGTP). The activity of the DNA primase of the delta II enzyme is insensitive to BuAdATP whereas 1.0 microM of this inhibitor will decrease the activity of the DNA primase of the alpha and delta I enzymes approximately 50%. Two monoclonal antibodies that potently inhibit DNA polymerase alpha are only slightly inhibitory to DNA polymerase delta I and are ineffective at inhibiting DNA polymerase delta II. DNA polymerase delta II had been previously found to be nearly inactive on nuclease-treated calf thymus DNA, relative to its activity on homopolymeric DNA. We find that addition of purified calf histone proteins or spermidine can greatly enhance synthesis by this enzyme on activated calf DNA.