The relationship between the radiosensitivity of DNA replicative synthesis and the formation of sister chromatid exchanges]

It has been found that irradiation in doses 0.5-2.0 Gy does not enhance the frequency of sister chromatid exchanges in cells of patients with Down's syndrome and ataxia-telangiectasia compared to the normal cells. In the case of ataxia, this phenomenon was accompanied with radioresistant replicative DNA synthesis, whereas in two cases of Down's syndrome the replicative DNA synthesis was found to be as radiosensitive as in the norm. According to these data, the mechanism of sister chromatid exchanges proposed in our previous publication (Pleskach et al., 1988) seems to be rather doubtful.     

Stimulation of replicative DNA synthesis by eukaryotic proteins bound to single-stranded DNA]

The paper deals with the effect of the single-strand (ss) DNA-binding proteins (SSB-proteins) from the Ehrlich ascites tumor (EAT) cells and from the eggs of silkworm, as well as the mouse serum blood proteins, having preferential affinity to ss DNA, on the DNA replicative synthesis in the EAT cells permeable for the macromolecules, and, for the silkworm proteins and on the DNA replicative synthesis in the nuclei from the eggs of silkworm proteins and on the DNA replicative synthesis in the nuclei from the eggs of silkworm permeable for macromolecules. SSB-proteins of EAT to considerable extent stimulated the DNA synthesis. At the same time, the other proteins (from the silkworm and from the serum) activated the DNA synthesis in the permeable cells to the less extent. It was found that SSB-proteins from the silkworm had a 1.5-13 fold stimulating effect on the DNA replicative synthesis in the homologous system (in the permeable nuclei). If the permeability for the macromolecules of the cells and nuclei treatment with Triton X-100 may be different, it is supposed that the activation of the DNA synthesis by the exogenous proteins depends on the homologous system of the DNA replicative complex. It is possible that the effect of the serum proteins on the DNA synthesis is connected with the masking of the ss regions of DNA which inhibited DNA-polymerase alpha. Perhaps the mechanisms of the activation of the DNA replicative synthesis by the proteins in vitro with the purified DNA polymerase alpha and in vivo are of different nature and are conditioned by homology of the deoxyribonucleoproteins.     

Transcriptional organization of the Drosophila melanogaster ribosomal RNA genes.

Five distinct DNA replicating intermediates have been separated from lysates of bacteriophage G4-infected cells pulse-labelled during the period of replicative form synthesis using propidium diiodide/caesium chloride gradients. These are a partially single-stranded theta structure that is labelled in both the viral and complementary DNA strands; partially single-stranded circles, some with an unfinished viral DNA strand (25%) and some with an unfinished complementary DNA strand (75%); replicative form II(RFII) and replicative form I(RFI) DNA labelled only in the complementary DNA strand. To explain the pulse-label data a model is proposed in which G4 replicative form replication takes place by a displacement mechanism in which synthesis of the new viral DNA strand displaces the old viral DNA strand as a single-stranded DNA loop (D-loop) and when the displacement reaches half way round the molecule (the origin of synthesis of the G4 viral and complementary DNA strands are on opposite sides of the genome, Martin &; Godson 1977) synthesis of the complementary DNA strand starts, but in the opposite direction. Strand separation of the parent helix runs ahead of DNA synthesis, releasing two partially single-stranded circles from the replicating structure which then complete their replication as free single-stranded DNA circles. No evidence was found to support a rolling circle displacement mechanism of G4 replicative form synthesis.     

Genotoxicity and cell proliferative activity of omeprazole in rat stomach mucosa.

Induction of unscheduled DNA synthesis (UDS) as a marker of genotoxicity and induction of ornithine decarboxylase (ODC) activity as a marker of cell proliferative activity by omeprazole were determined in the glandular stomach mucosa of male F344 rats after oral administration. Commercial enteric-coated omeprazole (Losec) at doses of 30 and 100 mg/kg body weight induced a dose-dependent increase in UDS but not replicative DNA synthesis in the pyloric mucosa of rat stomach 4 h after its administration. Dose-dependent significant induction of ODC activity was observed in fundic and pyloric mucosa with a maximum 8 h after administration of omeprazole at doses of 37.5-100 mg/kg body weight. These results show that omeprazole has genotoxicity and cell proliferative activity in the rat glandular stomach mucosa.     

Induction of unscheduled DNA synthesis in the nuclear matrix of rat hepatocytes after whole-body gamma irradiation of the animals

DNA synthesis in hepatocytes was studied by incorporation of [3H]thymidine administered to portal vein of gamma-irradiated (80 Gy) rats. It was shown that the rate of replicative DNA synthesis decreased in hepatocytes of the regenerating liver and unscheduled DNA synthesis was induced at the nuclear matrix of resting cells of the intact liver. In addition to repair synthesis, DNA synthesis resembling replicative one ("aberrant" DNA synthesis) accounts for a considerable fraction of gamma-radiation-induced synthesis of DNA at the nuclear matrix.     

Cytophotometric determination of unscheduled DNA synthesis

We describe a cytophotometric assay for unscheduled DNA synthesis (UDS) in asynchronously growing cells. Monolayer cultures of human HEp-2 and mouse MCa-11 cells were incubated with the carcinogen methyl-methane sulfonate (MMS), as well as with hydroxyurea and (3H)thymidine. Slides were prepared, and the DNA contents and areas of nuclei were measured by absorption cytophotometry. The labeling of the nuclei, determined on the basis of their DNA content to be in G0/G1, was selectively measured after the preparation of autoradiographs. The labeling of the G0/G1 cells increased with increasing doses of MMS. We also found that the increased nuclear labeling after MMS treatment was not due to induction of replicative DNA synthesis or selective destruction of G0/G1 cells. The results of this assay compared favorably with a standard biochemical method for measuring unscheduled DNA synthesis by benzoylated naphthoylated DEAE cellulose chromatography.     

Testing of hydralazine in in vivo-in vitro hepatocyte assays for UDS and stimulation of replicative DNA synthesis

The vasodilator hydralazine was tested for induction of DNA-repair synthesis and stimulation of replicative DNA synthesis in rat hepatocytes after administration in vivo, either once or repetitively. No increase in unscheduled or replicative DNA synthesis was observed. By contrast, positive controls clearly induced DNA-repair synthesis, either after a single treatment (4-aminobiphenyl, dimethylnitrosamine and methyl methanesulphonate) or after repetitive treatment (benzo[a]pyrene), or stimulated replicative DNA synthesis (carbon tetrachloride and dimethylnitrosamine). Thus, hydralazine displayed no genotoxic and no tumour-promoting activity in these in vivo-in vitro test systems.     

Sister chromatid exchanges, during x-irradiation, in the blood lymphocytes of patients with hereditary diseases and radioresistant DNA synthesis

X-ray irradiation induced sister chromatid exchanges (SCE) in blood lymphocytes from patient with Down's syndrome and adult progeria (in both the cases radioresistant DNA synthesis takes place). In these diseases, likely as upon form II of xeroderma pigmentosum (the replicative DNA synthesis is radioresistant), X-ray irradiation lowers the rate of SCE compared with that in the control, then the SCE rate rises with the increase in radiation dose, reaching the rate of SCE in non-irradiated cells. In normal lymphocytes (in which ionizing radiation inhibits the replicative synthesis of DNA) the rate of SCE rises with the rise of radiation dose. Thus, the rate of SCE in X-ray irradiated lymphocytes is in reverse dependence with radioresistance of replicative synthesis of DNA. The data obtained are explained in accordance with the replicative hypothesis of the SCE nature (Painter, 1980a): in cells of patients with Down's syndrome, xeroderma pigmentosum form II and progeria of adults the time of existence of partly replicated clusters of replicons is decreased due to radioresistant replicative synthesis of DNA, but the presence of partly replicated clusters of replicons is necessary for SCE formation. Therefore the rate of SCE in X-irradiated cells of these patients decreases.     

Hydroxyurea-Induced Accumulation of Short Fragments During Polyoma DNA Replication II. Behavior During Incubation of Isolated Nuclei

The synthesis of polyoma DNA was studied in isolated nuclei from hydroxyurea-inhibited 3T6 cells infected with polyoma virus. During incubation of nuclei under conditions suitable for polyoma DNA synthesis in vitro, the short DNA fragments with a sedimentation coefficient of 4S formed in vivo (hydroxyurea fragments) became associated with preformed, replicating DNA strands. Centrifugation in dye-buoyant density gradients showed that the fragments formed part of the structure of the replicative intermediate of polyoma DNA. The proportion of "young" replicative intermediates was larger after hydroxyurea inhibition than in uninhibited controls. Hydroxyurea fragments appear to be closely related to the 4S fragments formed as normal intermediates during discontinuous synthesis of polyoma DNA.     

Human cytomegalovirus DNA replicates after early circularization by concatemer formation, and inversion occurs within the concatemer.

To determine the replicative mechanism for human cytomegalovirus (HCMV) DNA, field inversion gel electrophoresis was used to separate HCMV replicative DNAs during lytic infection. Unit-length circular HCMV genomes lacking terminal restriction fragments were detected starting 4 h after infection even when cells were treated with aphidicolin, phosphonoacetic acid, or cycloheximide. Viral DNA synthesis began 24 h after infection and produced large amounts of high-molecular-weight replicative DNA that was a precursor of progeny genomes. Replicative DNA contained rare terminal restriction fragments, and long-arm termini were much less frequent than short-arm termini. Replicative DNA was not composed of unit-length circles because low-dose gamma irradiation of replicative DNA generated numerous random high-molecular-weight fragments rather than unit-length molecules. PacI digestion of replicative DNA from a recombinant HCMV with two closely spaced PacI sites revealed that replicative DNA is concatemeric and genome segment inversion occurs after concatemer synthesis. These results show that after circularization of the parental genome, DNA synthesis produces concatemers and genomic inversion occurs within concatemeric DNA. The results further suggest that concatemers acquire genomic termini during the cleavage/packaging process which preferentially inserts short-arm termini into empty capsids, causing a predominance of short-arm termini on the concatemer.     

Accumulation of ColE1 early replicative intermediates catalyzed by extracts of Escherichia coli dnaG mutant strains.

To investigate the events occurring at the replication forks during DNA synthesis, we studied the replication of plasmid ColE1 DNA in vivo and in vitro, using strains of Escherichia coli carrying either the dnaG3(Ts) or dnaG308(Ts) mutation. Extracts of both mutant strains supported in vitro DNA synthesis, but the amount of [3H]TMP incorporated into DNA was always less for mutant extracts than for extracts of revertant strains, which were able to grow at 42 degrees C. Sucrose gradient analysis, Southern blot analysis, and electron microscopy showed that mutant extracts synthesize a large number of early replicative intermediates containing one or two (one on each template strand) fragments at the origin of replication and some completed molecules, either open circles or covalently closed circles. The revertant extracts synthesized more completed molecules although the fraction of templates used was about the same, 0.27 for mutant extracts and 0.21 for revertant extracts. Our results show that a mutation in dnaG causes a block in the synthesis of both leading and lagging strands after initiation, which results in the accumulation of early replicative intermediates. The average size of the newly replicated region in the early replicative intermediates is 730 bases as measured from electron micrographs of early replicative intermediates. We conclude that the DnaG protein functions in lagging strand synthesis and may be necessary for the continuation of leading strand synthesis as well.     

Psoralen plus near-ultraviolet light: a possible new method for measuring DNA repair synthesis

A new method is proposed to inhibit semiconservative DNA synthesis in cultured cells while DNA repair synthesis is being measured. The cells are treated with the DNA-crosslinking agent Trioxalen (4,5,8-trimethylpsoralen) plus near-ultraviolet light, and consequently 99.5% inhibition of replicative DNA synthesis is achieved. Additional DNA-damaging agents induce thymidine incorporation into the double-stranded regions of the DNA. The new method gave results very similar to those obtained with the benzoylated naphthoylated DEAE (BND) cellulose method using three human fibroblast strains, of which one had deficient capacity for DNA repair synthesis following treatment with gamma rays and methyl methanesulfonate. The advantages of the new method are simplicity and rapidity, as well as the high extent to which replicative DNA synthesis is inhibited.     

Synthesis and phosphorylation of histones and nonhistone proteins as affected by irradiation and serotonin in cycloheximide-synchronized hepatocytes

Phosphorylation and synthesis of histones and nonhistone proteins were studied after the inhibition of translation by sublethal cycloheximide doses. Activation of the chromatin protein phosphorylation was noted: (1) at the stage of recovery and stimulation of the protein synthesis (18-24 h), and (2) at the stage of activation of the replicative DNA synthesis (30-60 h). Phosphorylation and synthesis of the chromatin proteins depended upon the individual or combined effect of X-radiation and serotonin. The authors discuss the possible role of the chromatin protein phosphorylation in the response of the nuclear apparatus to the effect of radiation and serotonin the latter being used as a radioprotective agent.     

Conversion of bacteriophage G4 single-stranded viral DNA to double-stranded replicative form in dna mutants of Escherichia coli.

Host functions involved in synthesis of parental replicative form of bacteriophage G4 were investigated using various replication mutants of Escheria coli. In dna+ bacteria, conversion of single-stranded viral DNA to replicative form DNA was insensitive to 200 microng/ml of rifampicin or 25 microng/ml of chloramphenicol. At high temperature, synthesis of parental replicative form was unaffected in mutants thermosensitive for dnaA, dnaB, dnaC(D), dnaE or dnaH. In dnaG or dnaZ mutants, however, parental replicative from DNA synthesis was clearly thermosensitive at 43 degrees C. Although the host rep product was essential for viral multiplication, the conversion of single stranded to replicative form was independent of the rep function.     

Comparative cytotoxic characteristics of the interferon-inducing yeast RNA-tilorone complex]

Cytotoxicity of the yeast RNA-tilorona molecular complex (MC) with interferonogenic properties and its influence on the DNA replicative synthesis were studied in experiments with human lymphocytes and 3 cell lines. It was shown that the MC doses of 25, 100 and 250 micrograms/ml were absolutely nontoxic for all the cell lines. The main parameters of the MC toxicity based on the cell viability were calculated. The parameters were found to correlate in the order of their magnitude with those relating to interferonogens of the polynucleotide nature. Within the dose ranges of 10 to 100 micrograms/ml the MC had a stimulating effect on replicative processes in the cells. It was concluded that the use of the MC as an inductor in large-scale manufacture of human and animal interferons of type 1 was promising.     

Kinetics of the decamer - dimer dissociation of arginine decarboxylase.

Aurintricarboxylic acid inhibited replicative DNA synthesis in nucleotide-permeable mouse ascites sarcoma cells. DNA polymerase activity assayed with activated DNA template and DNA polymerase purified partially from sarcoma cells was also inhibited by aurintricarboxylic acid. The inhibition of DNA polymerase activity was probably due to the inhibitory interaction of aurintricarboxylic acid with DNA polymerase. The replicative DNA synthesis might be inhibited by aurintricarboxylic acid interacting with some essential protein component(s), such as DNA polymerase of the replication machinery.     

Qualitative differences between replicative and repair synthesis of DNA in normal and transformed mouse cells as measured by precursor discrimination

Inhibitors of DNA polymerase alpha such as aphidicolin (APC) or 1-beta-D-arabinofuranosyl-cytosine (araC) cause DNA-strand breaks to accumulate after UV-irradiation, at sites where repair resynthesis is inhibited. Transformed cells accumulate fewer such breaks than normal cells do; this may be due to differences in the extent, or the nature, of excision-repair synthesis in transformed and in normal cells. We have looked for differences in the nature of repair synthesis, comparing the labelling of DNA by deoxycytidine (dC) and araC through UV-induced repair in normal and transformed mouse cells. We have made parallel determinations of precursor discrimination in replicative synthesis, and find that normal cells discriminate better against araC in replicative synthesis than do transformed cells. But repair synthesis discriminates against araC less than normal replicative synthesis does, to a similar extent in both cell types. Thus, there are qualitative differences between the DNA polymerases engaged in UV excision repair and replication in normal and transformed mouse cells; but there is no evidence for a predominantly araC-insensitive repair synthesis in transformed cells, such as might account for the difference in break accumulation.     

Effects of 2',3'-dideoxythymidine triphosphate on replicative DNA synthesis and unscheduled DNA synthesis in permeable mouse sarcoma cells

2',3'-Dideoxythymidine triphosphate differentially inhibited replicative DNA synthesis in permeable mouse ascites sarcoma cells and unscheduled DNA synthesis in bleomycin-treated permeable cells or in isolated rat liver nuclei. The mode of inhibition of 2',3'-dideoxythymidine triphosphate was competitive with respect to deoxythymidine triphosphate. 2',3'-Dideoxythymidine triphosphate inhibited replicative DNA synthesis with a Ki of 8 microM, whereas unscheduled DNA synthesis was more sensitive, the Ki being 0.5 microM. Referring to the differential sensitivity of DNA polymerases alpha and beta to 2',3'-dideoxythymidine triphosphate and to other related information reported previously, the present results suggested that DNA polymerase alpha is playing a major role in replicative DNA synthesis, and DNA polymerase beta in unscheduled DNA synthesis.     

Effect of tryptophan on isolated hepatocytes of rats

The addition of tryptophan to adult rat hepatocyte cultures stimulated DNA synthesis. The increase in DNA synthesis as measured by 3H-thymidine incorporation into DNA was observed on treatment of the cultures with tryptophan for 48 h but also as short as for 6 h in comparison with control cultures. An increase was also apparent at 30 h which was maintained for up to 48 h post treatment with tryptophan. The increase in DNA synthesis by tryptophan cannot be attributed to cell injury or to increased DNA degradation. Of the degradative enzymes added after harvesting the hepatocytes, only DNase decreased incorporation of 3H-thymidine. The observed effect was specific for tryptophan since treatment with kynurenine, isoleucine, methionine or serine failed to show a significant effect. Pretreatment of cultured hepatocytes with hydroxyurea prevented the tryptophan stimulated increase in DNA synthesis suggesting that the latter was due to replicative and not to reparative DNA synthesis. Experiments performed with the addition of diethylnitrosamine also alluded to tryptophan's role in replicative DNA synthesis. The mechanism of tryptophan-induced DNA synthesis is discussed.     

Molecular interaction of [2,3-14C] acrylonitrile with DNA in gastric tissue of rat

Acrylonitrile (VCN) is used extensively in polymer industries, and is known to induce gastric cancer following oral administration, A paucity of information exists regarding the mechanism(s) by which acrylonitrile induces gastric neoplasia. The time course for uptake of radioactivity by gastric tissue and covalent binding of [2,3-¹⁴C] VCN or its metabolites to gastric DNA were determined following a single oral dose of 46.5 mg/kg. The rates of DNA synthesis and repair, as measured by unscheduled DNA synthesis in the gastric tissue of VCN-treated rats, were also studied. Maximum tissue uptake and covalent binding of radioactivity to gastric DNA were observed at 15 minutes following [2,3-¹⁴C] VCN administration. At 6 hours following VCN administration, significant inhibition (37% of control) in gastric replicative DNA synthesis was observed. A rebound followed by an increase (211% of control) in replicative DNA synthesis was observed at 24 hours. A three-fold elevation in unscheduled DNA synthesis was observed at 24 hours following treatment with VCN. These results indicate that VCN or its metabolites irreversibly interact with gastric DNA, causing DNA damage. The results also indicate that the delayed VCN-induced DNA repair, determined as unscheduled DNA synthesis, is inefficient for the removal of the resulting DNA lesions.