Nuclear ribonucleoproteins as inhibitors of mammalian RNA polymerase.

A ribonucleoprotein complex isolated from rabbit thymus nuclear lysates was found to be an inhibitor of DNA-dependent RNA polymerase II. The inhibition appeared to be of a competitive type and was completely reversed by high concentration of DNA. Highest inhibition was observed when enzyme and complex were preincubated before addition of DNA while there was little inhibition after enzyme had started synthesis on the DNA template. The RNA isolated from the complex was equally inhibitory and was a more effective inhibitor than either tRNA or rRNA.     

The functional roles of mammalian DNA polymerase.

The viral DNA polymerases, with their probable role in viral DNA replication, point up the delicate control of DNA replication. Each cellular or viral induced DNA polymerase seems to have a role which is specific for the synthesis of a designated DNA and/or a place in a specialized replicative or repair process. A full understanding of the function of the eucaryotic DNA polymerases now depends on the clarification of the intimate mechanisms of DNA synthesis in its various modes. Identification of the accessory proteins, cofactors, and replicative DNA structures within a given replication complex, as has been accomplished in certain procaryotes (53), may help in this task.     

Nuclear location of all three influenza polymerase proteins and a nuclear signal in polymerase PB2.

In order to re-examine the sub-cellular location of the three influenza A/NT/60/68 polymerase proteins PB1, PB2 and PA in infected cells, specific antisera for each polymerase component have been prepared by immunizing rabbits with polymerase-beta-galactosidase fusion proteins synthesized in Escherichia coli. We show that polymerase PB1, PB2, and PA are predominantly associated with the nucleus of influenza-infected MDCK cells by immunocytochemical techniques. In the case of polymerase PB2 we investigate the possibility that nuclear accumulation is an intrinsic property of the PB2 protein. Using a vaccinia-PB2 recombinant virus, we show that PB2 accumulates intra-nuclearly in monkey CV-1 cells in the absence of any other influenza protein, suggesting it contains an intrinsic nuclear signal.     

Exonucleolytic proofreading by a mammalian DNA polymerase

Porcine liver DNA polymerase gamma contains exonuclease activity capable of digesting DNA in the 3'----5' direction, releasing deoxyribonucleoside 5'-monophosphates. The exonuclease activity excises 3'-terminal bases from both matched and mismatched primer termini, with a preference for mismatched bases. Under polymerization conditions, mismatch excision by the exonuclease occurs prior to polymerization by polymerase gamma, and this excision can be inhibited by adding to the reaction a high concentration of dNTP substrates and/or nucleoside 5'-monophosphates. In an M13mp2-based reversion assay for detecting single-base substitution errors, porcine liver polymerase gamma is highly accurate; the estimated base substitution error rate is less than one error for each 500,000 bases polymerized. Lower fidelity is observed using reaction conditions that inhibit the exonuclease activity, strongly suggesting that the exonuclease proofreads errors during polymerization. However, in a forward mutation assay capable of detecting all 12 mispairs at a variety of template positions, certain base substitution errors are readily detected even using unperturbed polymerization conditions. Thus, for some errors, polymerase gamma is not highly accurate, suggesting that proofreading is not equally active against all mispairs. To examine if the polymerase and exonuclease activities are physically as well as functionally associated, both activities were monitored during purification by four procedures, each based on a different separation principle. The two activities copurify during chromatography using phosphocellulose, heparin-agarose, or double-strand DNA-cellulose, and during velocity sedimentation in a glycerol gradient containing 0.5 M KCl. These results suggest that the polymerase and exonuclease activities are physically associated. It remains to be determined if they reside in the same subunit.     

Separation of DNA-dependent DNA polymerase activities in Micrococcus radiodurans.

DNA polymerase activities in Micrococcus radiodurans were separated into two fractions after purification more than 2000 fold. They differ in pH optimum and residual activities in the absence of a full deoxyribonucleoside triphosphates complement. NAD partly inhibited one of the activities. Both activities were eluted as a single peak on gel filtration and sedimented at the same rate on glycerol gradient centrifugation. Molecular weight 140000 was calculated from Stokes radius and sedimentation constant. Deoxyribonuclease activity was detected on one of the polymerase activities which preferentially degraded double-stranded DNA. Priming activity of nicked DNA was reduced by gamma-irradiation. These results have been related to the possible rolls in repair synthesis in vivo or DNA synthesis in permeable cells of M. radiodurans.     

Nuclear organization of DNA replication initiation proteins in mammalian cells.

Origin recognition complex (ORC), CDC6, and MCM proteins assemble sequentially to form prereplication chromatin. However, their organization remains largely unclear in mammalian cells. Here we show that ORC1 proteins are associated with non-chromatin nuclear structures and assemble in nuclear foci in mammalian cells using an in vivo chemical cross-linking method. CDC6 proteins were also found to assemble in nuclear foci on non-chromatin nuclear structures, although their physical association with ORC1 has been undetectable. In contrast to the situation in yeast cells, CDC6 was found to remain associated with non-chromatin nuclear structures even after cells entered into S phase. Instead, ORC1 proteins were found to be degraded by a proteasome-dependent pathway during S phase. We also found that some ORC2 proteins are associated with non-chromatin nuclear structures like ORC1, although the remainder binds to nuclease-sensitive chromatin. Further analyses indicate that ORC2 physically interacts with ORC1 on non-chromatin nuclear structures. On the other hand, our results suggest that although a small proportion of MCM complexes are loaded onto chromatin regions near ORC foci, most of them are more widely distributed. Possible relations between such organization of prereplication chromatin and complicated origin specification in higher eukaryotic cells are discussed.     

Dehydroaltenusin, a mammalian DNA polymerase alpha inhibitor

Dehydroaltenusin was found to be an inhibitor of mammalian DNA polymerase alpha (pol alpha) in vitro. Surprisingly, among the polymerases and DNA metabolic enzymes tested, dehydroaltenusin inhibited only mammalian pol alpha. Dehydroaltenusin did not influence the activities of the other replicative DNA polymerases, such as delta and epsilon; it also showed no effect even on the pol alpha activity from another vertebrate (fish) or plant species. The inhibitory effect of dehydroaltenusin on mammalian pol alpha was dose-dependent, and 50% inhibition was observed at a concentration of 0.5 microm. Dehydroaltenusin-induced inhibition of mammalian pol alpha activity was competitive with the template-primer and non-competitive with the dNTP substrate. BIAcore analysis demonstrated that dehydroaltenusin bound to the core domain of the largest subunit, p180, of mouse pol alpha, which has catalytic activity, but did not bind to the smallest subunit or the DNA primase p46 of mouse pol alpha. These results suggest that the dehydroaltenusin molecule competes with the template-primer molecule on its binding site of the catalytic domain of mammalian pol alpha, binds to the site, and simultaneously disturbs dNTP substrate incorporation into the template-primer.     

Induction of DNA polymerase activities in the regenerating rat liver.

The levels of DNA polymerase alpha, DNA polymerase delta, and its accessory protein, proliferating cell nuclear antigen (PCNA) were examined in the regenerating rat liver. The levels of DNA polymerase alpha and delta activities in regenerating liver extracts were determined by the use of the DNA polymerase alpha specific inhibitor, BuAdATP [2-(p-n-butylanilino)-9-(2-deoxy-beta-D-ribofuranosyl) adenine 5'-triphosphate], and monoclonal antibodies. These reagents showed that the total DNA polymerase activities increased ca. 4-fold during regeneration and that the fraction of DNA polymerase delta activity at the peak was 40% of the total DNA polymerase activity. Immunoblots and inhibition studies using specific antibodies showed that DNA polymerase delta and epsilon and PCNA were concomitantly induced after partial hepatectomy. The levels of both DNA polymerase delta and epsilon and PCNA reached their maxima at 24-36 h post hepatectomy, i.e., at the same time that in vivo DNA synthesis reached its peak. Partial purification and characterization of DNA polymerases delta and epsilon from the regenerating rat liver were also performed. These observations suggest that the variation of DNA polymerase delta and epsilon and PCNA during liver regeneration is closely related to DNA synthesis and is consistent with their involvement in DNA replication.     

Control of DNA polymerase alpha, beta and gamma activities in heat- and cold-sensitive mammalian cell-cycle mutants

Two heat-sensitive (arrested in G1 at 39.5 degrees C) and two cold-sensitive (arrested in G1 at 33 degrees C) clonal cell-cycle mutants of the murine P-815-X2 mastocytoma line were tested for DNA polymerase alpha, beta and gamma activities. After transfer of mutant cells to the respective nonpermissive temperature, DNA polymerase alpha activities decreased more slowly than relative numbers of cells in S phase. Furthermore, numbers of DNA-synthesizing cells decreased to near-zero levels, whereas polymerase alpha activities in arrested cells were as high as 15-40% of control values. After return of arrested cells to the permissive temperature, polymerase alpha activities increased essentially in parallel with relative numbers of cells in S phase. In contrast to the changes in thymidine kinase (Schneider, E., Müller, B. and Schindler, R. (1983) Biochim. Biophys. Acta 741, 77-85), the decrease of polymerase alpha during entry of cells into proliferative quiescence thus appears to be under rather relaxed control, while after return of arrested cells to the permissive temperature the increase in polymerase alpha is tightly coupled with reentry of cells into S phase. For DNA polymerase beta and gamma activities, no obvious correlation with changes in the proliferative state of cells was detected.     

Control of DNA polymerase α, β and γ activities in heat- and cold-sensitive mammalian cell-cycle mutants

Two heat-sensitive (arrested in G₁ at 39.5°C) and two cold-sensitive (arrested in G₁ at 33°C) clonal cell-cycle mutants of the murine P-815-X2 mastocytoma line were tested for DNA polymerase α, β and γ activities. After transfer of mutant cells to the respective nonpermissive temperature, DNA polymerase α activities decreased more slowly than relative numbers of cells in S phase. Furthermore, numbers of DNA-synthesizing cells decreased to near-zero levels, whereas polymerase α activities in arrested cells were as high as 15–40% of control values. After return of arrested cells to the permissive temperature, polymerase α activities increased essentially in parallel with relative numbers of cells in S phase. In contrast to the changes in thymidine kinase (Schneider, E., Müller, B. and Schindler, R. (1983) Biochim. Biophys. Acta 741, 77–85), the decrease of polymerase α during entry of cells into proliferative quiescence thus appears to be under rather relaxed control, while after return of arrested cells to the permissive temperature the increase in polymerase α is tightly coupled with reentry of cells into S phase. For DNA polymerase β and γ activities, no obvious correlation with changes in the proliferative state of cells was detected.     

Nuclear membranes from mammalian liver : IV. Characterization of membrane-attached DNA

DNA associated with nuclear membranes isolated from liver tissue of mice and rats (sucklings and partially hepatectomized adults) has been analysed and directly demonstrated by electron microscopy using spreading techniques. The sensitivity of this DNA-membrane association to DNAse, to 4 M CsCl-centrifugation, urea, and to detergent has been examined and compared with that of ‘microsomal DNA’. The DNA has been purified from nuclear membrane fractions, and the purity and molecular size distribution of the preparations has been determined. The characteristics of this DNA with respect to buoyant density, melting behaviour, content of repetitive sequences, nucleotide composition, molecular configuration, and turnover and labelling kinetics with various precursors (thymidine, deoxycytidine, phosphate) have been examined and compared with the corresponding properties of DNA from whole nuclei and other nuclear subfractions. Most properties of membrane DNA are identical or similar to those of bulk nuclear DNA. It is, however, enriched in satelite DNA and other repetitive sequences to a moderate extent and differs from it in its replication rate and time. The results reflect the close relationship between the nuclear envelope and (constitutive) heterochromatin, but also indicate that membrane binding is not restricted to this material. The data speak against a preferential localization of replicating points in the nuclear membrane DNA, as well as against an initiation of replication at the nuclear envelope.     

Oxanine DNA glycosylase activities in mammalian systems

DNA bases carrying an exocyclic amino group, namely adenine (A), guanine (G) and cytosine (C), encounter deamination under nitrosative stress. Oxanine (O), derived from deamination of guanine, is a cytotoxic and potentially mutagenic lesion and studies of its enzymatic repair are limited. Previously, we reported that the murine alkyladenine glycosylase (Aag) acts as an oxanine DNA glycosylase (JBC (2004), 279: 38177). Here, we report our recent findings on additional oxanine DNA glycosylase (ODG) activities in Aag knockout mouse tissues and other mammalian tissues. Analysis of the partially purified proteins from the mammalian cell extracts indicated the existence of ODG enzymes in addition to Aag. Data obtained from oxanine DNA cleavage assays using purified human glycosylases demonstrated that two known glycosylases, hNEIL1 and hSMUG1, contained weak but detectable ODG activities. ODG activity was the highest in hAAG and lowest in hSMUG1.     

A novel stimulating protein of mammalian DNA polymerase alpha

A DNA polymerase alpha-primase complex, which had been purified by means of immunoaffinity column chromatography, showed little activity in a reaction mixture composed of Tris-HCl buffer, but showed full activity in potassium phosphate buffer. It was found that potassium ion is required for the reaction by the immunoaffinity-purified enzyme. On the other hand, the DNA polymerase alpha purified by the orthodox biochemical method showed full activity in both buffer systems. A protein factor, which could restore the activity of immunoaffinity-purified DNA polymerase alpha-primase complex in the potassium-free reaction mixture, was separated from biochemically purified DNA polymerase alpha. The factor, designated as factor T, was stable to heat up to 70 degrees C, but was sensitive to trypsin. It sedimented at about 4S through a glycerol gradient. SDS-polyacrylamide gel electrophoresis revealed two polypeptide bands at 56 and 54 kDa. By immunoprecipitation, the factor T was shown to be physically associated with DNA polymerase alpha-primase complex. The stimulation was also observed with poly[d(A-T)], primed M13 DNA, and heat-denatured DNA.     

Affinity labeling the DNA polymerase alpha complex. I. Pyridoxal 5'-phosphate inhibition of DNA polymerase and DNA primase activities of the DNA polymerase alpha complex from Drosophila melanogaster embryos

DNA polymerase alpha from Drosophila melanogaster embryos is a multisubunit enzyme complex which can exhibit DNA polymerase, 3'----5' exonuclease, and DNA primase activities. Pyridoxal 5'-phosphate (PLP) inhibition of DNA polymerase activity in this complex is time dependent and exhibits saturation kinetics. Inhibition can be reversed by incubation with an excess of a primary amine unless the PLP-enzyme conjugate is first reduced with NaBH4. These results indicate that PLP inhibition occurs via imine formation at a specific site(s) on the enzyme. Results from substrate protection experiments are most consistent with inhibition of DNA polymerase activity by PLP binding to either one of two sites. One site (PLP site 1) can be protected from PLP inhibition by any nucleoside triphosphate in the absence or presence of template-primer, suggesting that PLP site 1 defines a nucleotide-binding site which is important for DNA polymerase activity but which is distinct from the DNA polymerase active site. PLP also inhibits DNA primase activity of the DNA polymerase alpha complex, and primase activity can be protected from PLP inhibition by nucleotide alone, arguing that PLP site 1 lies within the DNA primase active site. The second inhibitory PLP-binding site (PLP site 2) is only protected from PLP inhibition when the enzyme is bound to both template-primer and correct dNTP in a stable ternary complex. Since binding of PLP at site 2 is mutually exclusive with template-directed dNTP binding at the DNA polymerase active site, PLP site 2 appears to define the dNTP binding domain of the active site. Results from initial velocity analysis of PLP inhibition argue that there is a rate-limiting step in the polymerization cycle during product release and/or translocation.     

Lesion bypass activities of human DNA polymerase mu

DNA polymerase mu (Polmu) is a newly discovered member of the polymerase X family with unknown cellular function. The understanding of Polmu function should be facilitated by an understanding of its biochemical activities. By using purified human Polmu for biochemical analyses, we discovered the lesion bypass activities of this polymerase in response to several types of DNA damage. When it encountered a template 8-oxoguanine, abasic site, or 1,N(6)-ethenoadenine, purified human Polmu efficiently bypassed the lesion. Even bulky DNA adducts such as N-2-acetylaminofluorene-adducted guanine, (+)- and (-)-trans-anti-benzo[a]pyrene-N(2)-dG were unable to block the polymerase activity of human Polmu. Bypass of these simple base damage and bulky adducts was predominantly achieved by human Polmu through a deletion mechanism. The Polmu specificity of nucleotide incorporation indicates that the deletion resulted from primer realignment before translesion synthesis. Purified human Polmu also effectively bypassed a template cis-syn TT dimer. However, this bypass was achieved in a mainly error-free manner with AA incorporation opposite the TT dimer. These results provide new insights into the biochemistry of human Polmu and show that efficient translesion synthesis activity is not strictly confined to the Y family polymerases.