Inhibitors of DNA synthesis cause excessive DNA synthesis in dnaA mutants of Escherichia coli K12.

The relative rate of net DNA synthesis was stimulated when cells of dnaA mutants of Escherichia coli K12 were grown in the presence of low concentrations of DNA synthesis inhibitors. This led to a supernormal DNA/cell mass ratio. The excessive DNA was similar to the normal chromosomal DNA in size and stability in vivo. However, the cells did not divide but turned into long filaments. Excessive DNA synthesis in the presence of inhibitors of DNA synthesis was observed in the cultures of two independent dnaA mutants of E. coli, but dnaB and dnaC mutants behaved like the wild type in this respect.     

Nonradioactive detection of DNA repair synthesis

DNA repair is essential for the surveillance and maintenance of the integrity of the genome in response to various insults that damage DNA. The development of cell-free repair systems using radiolabeled nucleotide to monitor repair synthesis of exogenously introduced damaged-plasmid DNA has enabled the analysis of specific proteins required for repair synthesis. However, the hazards and the burgeoning cost of using radioisotopes have become significant factors in the laboratory. We describe here the use of digoxigenin-dUTP in place of radioactivity in a nonradioactive cell-free repair assay to detect DNA repair.     

DNA synthesis and repair in permeable cells of Micrococcus radiodurans.

Cells permeable to deoxyribonucleoside triphosphate were prepared from Micrococcus radiodurans, and DNA synthesis and rejoining of strand scissions induced by gamma-rays were investigated. DNA synthesis was stimulated by ATP at an optimal concentration of 1mM. This reaction requires four deoxyribonucleoside triphosphates and MgCl2. NAD inhibited the reaction, but no rejoining of primer DNA was observed. Even in the presence of NAD, DNA which was synthesized in the unirradiated permeable cells had a peak molecular weight of only 1.3 - 10(6). DNA synthesis was stimulated by irradiation of the permeable cells with gamma-rays, but this stimulatory effect was eliminated by the addition of NAD. Both primer and synthesized DNA in the irradiated permeable cells were rejoined in vitro in the presence of NAD and deoxyribonucleoside triphosphates, while those in the unirradiated permeable cells were not rejoined.     

Enhanced DNA repair synthesis in hyperacetylated nucleosomes

We have investigated the level of "early" DNA repair synthesis in nucleosome subpopulations, varying in histone acetylation, from normal human fibroblasts treated with sodium butyrate. We find that repair synthesis occurring during the first 30 min after UV irradiation is significantly enhanced in hyperacetylated mononucleosomes. Nucleosomes with an average of 2.3 acetyl residues/H4 molecule contained approximately 1.8-fold more repair synthesis than nucleosomes with an average of 1.5 or 1.0 acetyl residues/H4 molecule. Fractionation of highly acetylated nucleosomes by two-dimensional gel electrophoresis yielded an additional 2.0-fold enrichment of repair synthesis in nucleosomes containing 2.7 acetyl residues/H4 molecule as compared to nucleosomes containing 1.9 acetyl residues/H4 molecule. This enhanced repair synthesis is associated primarily with nucleosome core regions and does not appear to result from increased UV damage in hyperacetylated chromatin. In addition, the distribution of repair synthesis within nucleosome core DNA from hyperacetylated chromatin is nonrandom, showing a bias toward the 5' end which is similar to that obtained for bulk (unfractionated) chromatin. These results provide strong evidence that enhanced repair occurs within nucleosome cores of hyperacetylated chromatin in butyrate-treated human cells. Finally, pulse-chase experiments demonstrate that the association of enhanced repair synthesis with hyperacetylated nucleosomes is transient, lasting only about 12 h after UV damage.     

DNA polymerase I-mediated ultraviolet repair synthesis in toluene-treated Escherichia coli.

DNA synthesis after ultraviolet irradiation is low in wild type toluene-treated cells. The level of repair incorporation is greater in strains deficient in DNA polymerase I. The low level of repair synthesis is attributable to the concerted action of DNA polymerase I and polynucleotide ligase. Repair synthesis is stimulated by blocking ligase activity with the addition of nicotinamide mononucleotide (NMN) or the use of a ligase temperature-sensitive mutant. NMN stimulation is specific for DNA polymerase I-mediated repair synthesis, as it is absent in isogenic strains deficient in the polymerase function or the 5' leads to 3' exonuclease function associated with DNA polymerase I. DNA synthesis that is stimulated by NMN is proportional to the ultraviolet exposure at low doses, nonconservative in nature, and is dependent on the uvrA gene product but is independent of the recA gene product. These criteria place this synthesis in the excision repair pathway. The NMN-stimulated repair synthesis requires ATP and is N-ethylmaleimide-resistant. The use of NMN provides a direct means for evaluating the involvement of DNA polymerase I in excision repair.     

Error-prone DNA repair and translesion DNA synthesis. II: The inducible SOS hypothesis

Evelyn Witkin hypothesized in 1967 that bacterial cell division is controlled by a repressor which, like the lambda repressor, is inactivated by a complex process that starts with the presence of replication-blocking lesions in the DNA. She further suggested that this might not be the only cellular function to show induction by DNA damage. Three years later, Miroslav Radman, in a privately circulated note, proposed that one such function might be an inaccurate (mutation-prone) DNA polymerase under the control of the recA and lexA genes. Thus was born the SOS hypothesis.     

In vitro repair synthesis of BCNU-induced DNA damage

The nitrosoureas including BCNU are potent chemotherapeutic drugs and have been used extensively for treatment of brain tumors and other neoplasias but the mechanisms of action for the DNA lesions created and their repair are still unclear. We have recently determined the in vitro repair of BCNU-treated DNA with cellular extracts and with DNA modifying enzymes. BCNU not only caused an increase in breaks in plasmid DNA, but an increase in cross-linked DNA was also observed after restriction enzyme digestion followed by gel electrophoresis. When HeLa cell-extracts were incubated with BCNU-treated DNA, 5-10 fold increases in DNA repair synthesis were observed as compared with untreated control. Substantial increases in 5'OH and 3'OH sites of the breaks were also found in BCNU-treated DNA as determined by the 10-20 fold increases in labeling with T4-DNA kinase and by endogenous polymerases, while the amount of ligatable sites were at a minimal. When the repair capacity of two glioma cell lines (UWR1 and UWR3) with differential BCNU sensitivity, and cells from a chromosomal breakage disease, Bloom's syndrome (BS), were assessed, the activities of the two glioma cells were about 20-30% of the normal lymphoblastoid cells and HeLa cells, whereas no difference was observed in BS cells. However, differential patterns of DNA bands were observed in the glioma samples suggesting cell-type specific capacities of repair synthesis. These data are in accordance with the concept that BCNU creates multiple DNA lesions and suggests different cell types may develop a variety of repair capabilities.     

Dependence of DNA dark repair on protein synthesis in Escherichia coli.

Summary We investigated the influence of aminoacidless treatments applied prior and after UV irradiation on survival, dimer excision, postirradiation DNA degradation, DNA synthesis and sedimentation profiles of parental DNA ofE. coli B/r Hcr⁺ cells. In dependence on the treatment applied, the fluence 50 J/m² yielded distinctly different fractions of survivors within 0,03–85%. In all cases dimers were completely excised. The rate of DNA degradation was similar during a 30–40 min period after UV during which the bulk of dimers was excised. Degradation ceased, however, earlier in the prestarved cells than in exponentially growing ones; it was prolonged by aminoacidless postincubation. Sedimentation profiles of parental DNA did not differ during the whole period of dimer excision. In cells DNA synthesis was not restored for several hours after addition of amino acids. In cells addition of amino acids resulted in a fast resumption of DNA synthesis. We conclude that removal of dimers and repair of gaps were similar in all cases. We believe that aminoacidless treatments influence production and repair of damage to the sites of DNA replication. The treatment appears to prevent this damage when applied before UV irradiation, but interferes with its restoration when applied after UV irradiation. Consequently, the former treatment increases survival of cells while the latter produces an opposite effects.     

DNA repair synthesis in human fibroblasts requires DNA polymerase delta

When UV-irradiated cultured diploid human fibroblasts were permeabilized with Brij-58 then separated from soluble material by centrifugation, conservative DNA repair synthesis could be restored by a soluble factor obtained from the supernatant of similarly treated HeLa cells. Extensive purification of this factor yielded a 10.2 S, 220,000-dalton polypeptide with the DNA polymerase and 3'- to 5'-exonuclease activities reported for DNA polymerase delta II (Crute, J. J., Wahl, A. F., and Bambara, R. A. (1986) Biochemistry 25, 26-36). Monoclonal antibody to KB cell DNA polymerase alpha, while binding to HeLa DNA polymerase alpha, did not bind to the HeLa DNA polymerase delta. Moreover, at micromolar concentrations N2-(p-n-butylphenyl)-2'-deoxyguanosine 5'-triphosphate (BuPdGTP) and 2-(p-n-butylanilino)-2'-deoxyadenosine 5'-triphosphate (BuAdATP) were potent inhibitors of DNA polymerase alpha, but did not inhibit the DNA polymerase delta. Neither purified DNA polymerase alpha nor beta could promote repair DNA synthesis in the permeabilized cells. Furthermore, under conditions which inhibited purified DNA polymerase alpha by greater than 90%, neither monoclonal antibodies to DNA polymerase alpha, BuPdGTP, nor BuAdATP was able to inhibit significantly the DNA repair synthesis mediated by the DNA polymerase delta. Thus, it appears that a major portion of DNA repair synthesis induced by UV irradiation might be catalyzed by DNA polymerase delta. When xeroderma pigmentosum human diploid fibroblasts were utilized, DNA repair synthesis dependent upon ultraviolet light could be restored by addition of both T4 endonuclease V and DNA polymerase delta, but not by addition of either one alone. This result suggests that cytosol-depleted permeabilized DNA repair-defective human fibroblasts and HeLa DNA polymerase delta might be exploited to provide a functional assay for purifying active DNA repair factors from DNA repair-proficient cells without a preknowledge of their function.     

Long-patch DNA repair synthesis during base excision repair in mammalian cells

The base excision repair (BER) process removes base damage such as oxidation, alkylation or abasic sites. Two BER sub-pathways have been characterized using in vitro methods, and have been classified according to the length of the repair patch as either 'short-patch' BER (one nucleotide) or 'long-patch' BER (LP-BER; more than one nucleotide). To investigate the occurrence of LP-BER in vivo, we developed an assay using a plasmid containing a single modified base in the transcribed strand of the enhanced green fluorescent protein (EGFP) gene and a stop codon, based on a single-nucleotide mismatch, at varying distances on the 3' side of the lesion. The reversion of the stop codon occurs after DNA repair synthesis and restores EGFP expression after transfection of mismatch-repair-deficient cells. Repair patches longer than one nucleotide were observed for 55-80% or 80-100% of the plasmids with a mean length of 2-6 or 6-12 nucleotides for 8-oxo-7,8-dihydroguanine or a synthetic abasic site, respectively. These data show the existence of LP-BER in vivo, and emphasize the effect of the type of BER substrate lesion on both the yield and the extent of the LP-BER sub-pathway.     

DNA polymerase I-mediated translesion synthesis in RecA-independent DNA interstrand cross-link repair in E. coli

DNA interstrand cross-links (ICLs) are mainly repaired by the combined action of nucleotide excision repair and homologous recombination in E. coli. Genetic data also suggest the existence of a nucleotide excision repair-dependent, homologous recombination-independent ICL repair pathway. The involvement of translesion synthesis in this pathway has been postulated; however, the molecular mechanism of this pathway is not understood. To examine the role of translesion synthesis in ICL repair, we generated a defined substrate with a single psoralen ICL that mimics a postincision structure generated by nucleotide excision repair. We demonstrated that the Klenow fragment (DNA polymerase I) performs translesion synthesis on this model substrate. This in vitro translesion synthesis assay will help in understanding the basic mechanism of a postincision translesion synthesis process in ICL repair.     

Increase of uv-induced DNA repair synthesis during blast transformation of human lymphocytes.

UV-induced DNA repair synthesis, measured as unscheduled DNA synthesis, was studied in human peripheral lymphocytes in various phases of the cell cycle. Mitogen transformation of the lymphocytes was effected with phytohemagglutinin (PHA), and the stage in the cell cycle was determined by measuring the Feulgen DNA content and the dry mass in individual cells by cytophotometry. The initial rate of repair was determined by autoradiography after UV-light irradiation (19.2 J/m²) and incubation of the cells for 30 min with [³H]thymidine. When the cells progressed from the G0 to the G1 phase there was a 3-fold increase in the grain count. The correlation between the grain count and the dry mass indicated an increase in the initial rate of repair during the progression of cells from G0 to G2 phase. G2 cells were more heavily labelled than those in G1, but there did not seem to be any difference between these two phases as regards the relationship between grain count and DNA content. The results indicate that the initial rate of UV-induced DNA repair may differ in various phases of the lymphocyte cell cycle.     

D-ribose inhibits DNA repair synthesis in human lymphocytes

D-ribose is cytotoxic for quiescent human lymphocytes and severely inhibits their PHA-induced proliferation at concentrations (25-50 mM) at which other simple sugars are ineffective. In order to explain these effects, DNA repair synthesis was evaluated in PHA-stimulated human lymphocytes treated with hydroxyurea and irradiated. D-ribose, in contrast to other reducing sugars, did not induce repair synthesis and therefore did not apparently damage DNA in a direct way, although it markedly inhibited gamma ray-induced repair. Taking into account that lymphocytes must rejoin physiologically-formed DNA strand breaks in order to enter the cell cycle, we suggest that D-ribose exerts its cytotoxic activity by interfering with metabolic pathways critical for the repair of DNA breaks.     

DNA repair synthesis in mouse spermatogenesis involves DNA polymerase beta activity

The role of DNA polymerase alpha-DNA primase complex and DNA polymerase beta in DNA replication and ultraviolet-induced DNA repair synthesis has been analyzed in mouse spermatogenesis. Autoradiographic experiments with germ cells in culture, indicating an involvement of DNA polymerase alpha and/or delta in DNA replication, and of DNA polymerase beta in DNA repair synthesis, have been confirmed by studying partially purified enzymes. These findings support the idea that, different from other biological systems, in meiotic and post meiotic male mouse germ cells DNA polymerase beta is the main DNA polymerase form needed for DNA repair.     

Neocarzinostatin induction of DNA repair synthesis in HeLa cells and isolated nuclei.

The antitumor antibiotic neocarzinostatin that causes DNA strand breaks in vivo and in vitro is shown to induce DNA repair synthesis in HeLa S3 cells. In the repair assay, the parental DNA was prelabeled with 32P and a density label (bromodeoxyuridine) was introduced into the new synthesized DNA. Quantitation of the repair synthesis as measured by the incorporation of [3H]thymidine into the light parental DNA at varying doses of the drug indicate that there is a significant repair response at low levels of the drug (0.2--0.5 microgram/ml) which cause DNA strand breakage and inhibition of DNA synthesis. In isolated HeLa nuclei neocarzinostatin stimulates the incorporation of dTMP many-fold. This enhancement of dTMP incorporation, which requires the presence of a sulfhydryl agent, is a consequence of the drug-induced DNA strand breakage and is in the parental DNA. These results suggest that an intact cell membrane is not required for DNA strand breakage and its subsequent repair.