Effects of mitomycin C on the rate of DNA synthesis in normal and Faconi anaemia cells

THe effect of low doses mitomycin C (MMC) on DNA synthesis of fibroblast cell lines derived from normal individuals or patient with Fanconi anaemia (FA) was studied. Using low doses of MMC (12 ng/ml), little or no effect was observed on DNA synthesis of normal cells, whereas DNA synthesis of FA cells was greatly inhibited 24 and 48 h after treatment. This was due to a decrease in the number of DNA-synthesizing cells, while the amount of radioactivity incorporated per cell (as measured with grain counting in autoradiograms) remained the same. These findings indicate that the inhibition of semiconservative DNA synthesis induced by MMC in FA cells is not due to an inhibitory effect of unrepaired lesions on the rate of DNA synthesis but rather to a block in cell cycle progression.     

Effects of mitomycin C on the rate of DNA synthesis in normal and Fanconi anaemia cells

The effect of low doses mitomycin C (MMC) on DNA synthesis of fibroblast cell lines derived from normal individuals or patients with Fanconi anaemia (FA) was studied. Using low doses of MMC (12 ng/ml), little or no effect was observed on DNA synthesis of normal cells, whereas DNA synthesis of FA cells was greatly inhibited 24 and 48 h after treatment. This effect was due to a decrease in the number of DNA-synthesizing cells, while the amount of radioactivity incorporated per cell (as measured with grain counting in autoradiograms) remained the same. These findings indicate that the inhibition of semiconservative DNA synthesis induced by MMC in FA cells is not due to an inhibitory effect of unrepaired lesions on the rate of DNA synthesis but rather to a block in cell cycle progression.     

Two complementation groups of Fanconi's anemia differ in their phenotypic response to a DNA-crosslinking treatment

Summary The two genetic complementation groups reported for Fanconi's anemia (FA) correspond to two phenotypic classes as characterized by measurements of the rate of DNA semiconservative synthesis after 8-methoxypsoralen photo-addition. This test allows a rapid genetic classification of FA patients which appears to be a prerequisite for investigations of the biochemical defect(s) in FA.     

The fate of 8-methoxypsoralen-photoinduced DNA interstrand crosslinks in Fanconi's anemia cells of defined genetic complementation groups

The fate of 8-methoxypsoralen (8-MOP)-photoinduced DNA interstrand crosslinks was followed by alkaline elution in Fanconi's anemia (FA) fibroblasts belonging to complementation groups A (FA 150 and FA 402) and B (FA 145) in comparison to a normal (1 BR/3) and a heterozygote (F 311) cell line. Clonogenic cell survival to 8-MOP photoaddition was established in parallel for all cell lines. In comparison to normal cells, group A FA cells demonstrated a higher photosensitivity than group B cells (sensitivity index 2.3 and 1.5, respectively), the heterozygote cell line being only slightly more sensitive. FA cells from both groups A and B demonstrated an incision capacity of crosslinks, the kinetics and extent of which being, however, different from that of normal or heterozygote cells. The incision is slower in FA cells and, at 24 h of post-treatment incubation, the amount of crosslinks incised is clearly lower than that observed in normal cells for group A cells, whereas in group B cells incision approaches the level of normal cells. These results correlate with survival as well as with rates of DNA semi-conservative synthesis after 8-MOP photoaddition.     

REPAIR DNA SYNTHESIS IN DIFFERENTIATED EMBRYONIC MUSCLE CELLS

The differentiation of embryonic skeletal muscle cells is closely coupled with the cessation of normal DNA replication. Once these cells begin to differentiate, they normally never undergo semiconservative replication of DNA during the entire life time of the muscle cell. Cessation of DNA synthesis has been shown to be accompanied by a loss of 80–90% of the replicative DNA polymerase activity of these cells. Despite this loss the studies reported here demonstrate that muscle cells retain the ability to synthesize DNA of a repair type after UV irradiation. These results suggest that the control exercised over semiconservative DNA synthesis during differentiation of these cells does not extend to repair synthesis after UV irradiation.     

Role for deoxyribonucleic acid ligase in deoxyribonucleic acid polymerase i-dependent repair synthesis in toluene-treated escherichia coli.

In a toluene-treated mutant of Escherichia coli K-12 having a temperature-sensitive, conditionally lethal mutation in the structural gene for deoxyribonucleic acid (DNA) ligase, an extensive DNA repair synthesis occurred in X-irradiated cells at the nonpermissive temperature, 42 C. At the permissive temperature, 30 C, nearly normal semiconservative synthesis and limited repair synthesis were observed when DNA ligase was activated by the addition of nicotinamide adenine dinucleotide.     

Age-related alterations in plasma membrane glycoprotein content and scheduled or unscheduled DNA synthesis.

WI-38 cells of various ages and SV40-transformed WI-38 cells were examined for differences in plasma membrane composition of glycoproteins and DNA synthesis. Sialic acid per milligram of protein content of the membranes of WI-38 cells decreased with passage of time in culture. Other glycoprotein fractions and alkaline phosphatase activity disappeared in the WI-38 cells with passage of time in culture (Phase III). Studies of DNA repair correlated with changes observed in the plasma membrane glycoprotein content of WI-38 cells over a passage of time in culture were also reported. Both the extent and rate of ultraviolet-induced unscheduled DNA synthesis remained relatively constant during the passage of the WI-38 cells until late phase III. At that time the extent of unscheduled DNA synthesis was measurably reduced. The number of cells in a population of phase III cells able to perform semiconservative DNA synthesis diminished with age in culture but not to an extent capable of explaining the observed changes seen in membrane composition of semiconservative DNA synthesis during passage of the cells in culture. Cells with an extended lifespan SV40-transformed WI-38 (VA 13.2 RA) cells, did not vary in membrane composition, semiconservative DNA synthesis, or unscheduled DNA synthesis over 200 serial subpassages of the cells in culture.     

DNA semi-conservative synthesis in normal and Fanconi anemia fibroblasts following treatment with 8-methoxypsoralen and near ultraviolet light or with X-rays

Summary The effect of treatment with 8-methoxypsoralen (8-MOP) plus near-UV radiation (UVA) or with X-rays on the rate of DNA semi-conservative synthesis of fibroblasts from 10 Fanconi anemia (FA), two heterozygous, and three normal cell lines was studied. Following treatments with either X-rays or low doses of 8-MOP plus UVA leading to a majority of monoadducts over cross-links per genome, the FA and hetcrozygous cell lines were indistinguishable from normals: the transient inhibition of semi-conservative DNA synthesis was followed by the recovery of a nomral rate of synthesis. In contrast treatment with higher (but not saturating) doses of 8-MOP plus UVA allowed us to distinguish two classes among the FA cell lines. One class demonstrated a pattern of recovery similar to that of heterozygous and normal cell lines. This indicates that in such cell lines, the predominant lesion in this condition, the cross-links, do not arrest DNA synthesis and are likely to be normally repaired. Another class of FA cell lines did not show a recovery of a normal rate of DNA synthesis even after prolonged post-treatment incubation and although the proportion of cells in S phase was similar to that of the strains of the first category. This indicates that in such cell lines the repair of cross-links is inhibited at some step which is not necessarily the incision one.     

Semiconservative and unscheduled DNA synthesis on mammalian cells and its modification by glyoxylic compounds

The interaction of glyoxal and four other glyoxylic compounds with semiconservative DNA synthesis and with unscheduled DNA synthesis induced by 25-G X-rays on TC-SV40 hamster cells has been studied. Both syntheses were evaluated by measuring the incorporation of [3H-methyl]-thymidine into the newly synthetized DNA. The unscheduled DNA synthesis amounts to 4% of semiconservative synthesis. The modification of both syntheses by the glyoxylic compounds was tested using the products at non-toxic concentrations for the cells. All the glyoxals inhibited semiconservative DNA synthesis and potentiated unscheduled DNA synthesis at rather similar levels. These effects have been compared with the radiosensitizing activity of these glyoxals in the same TC-SV40 cells and no relationship could be established.     

Stimulation of cellular DNA synthesis by human cytomegalovirus

Human cytomegalovirus (CMV) is able to induce cellular DNA synthesis in both permissive (human embryonic lung) and nonpermissive (Vero) cells. The induction of cell DNA synthesis was assayed by the incorporation of [methyl-³H]thymidine into macromolecules having the buoyant density characteristics of cell DNA. The DNA synthesis induced by CMV infection appears to represent normal semiconservative replication as opposed to repair synthesis. Both strains of CMV tested were capable of inducing cell DNA synthesis. Virus exposed to heat or UV light prior to infection lost the ability to induce DNA synthesis, indicating that a virus-coded function expressed after infection is responsible for stimulation of cell DNA synthesis.     

DNA synthesis in competent Bacillus subtilis cells.

Competent cells of Bacillus subtilis incorporate degradation products from transfecting DNA into their chromosomal DNA. The sensitivity of this incorporation to inhibitors of bacterial DNA synthesis [phage infection or 6-(p-hydroxyphenylazo)-uracil] suggests that semiconservative DNA synthesis can occur in competent cells.     

Radiation-stimulated DNA synthesis in cultured mammalian cells

A type of DNA synthesis in mammalian cells that is stimulated by ultraviolet light has been studied by means of radioautography and density gradient centrifugation. The characteristics of this synthesis are: (a) it is not semiconservative; (b) it is enhanced by the presence of 5-bromodeoxyuridine in the DNA molecule; (c) the degree of stimulation is dose dependent; (d) there is less variability in the rate of incorporation of H³-thymidine during this synthesis than during normal DNA synthesis; (e) it occurs in cells that are not in the normal DNA synthesis phase (G₁ and G₂ cells). This kind of synthesis has been found in cultured cell lines from five different species; however, in some strains, the presence of bromouracil in the DNA is required before it can be demonstrated by radioautography.     

The effect of deoxyadenosine plus deoxycoformycin on replicative and repair synthesis of DNA in human lymphoblasts and isolated nuclei

Deoxyadenosine plus deoxycoformycin (dCf) causes increased DNA breaks in lymphoid cells. This study explored the possible inhibition of repair synthesis of DNA by dAdo plus dCf as a cause of DNA breakage. It was shown that DNA breaks accumulated in a human T-lymphoblast cell line, CCRF-CEM, following incubation with dAdo plus dCf and were not fully repaired 20 h after their removal. Analysis of the density distribution of radiolabeled DNA on alkaline CsCl gradient showed that incubation of CCRF-CEM cells with dAdo plus dCf caused inhibition of semiconservative, but not repair synthesis of DNA. Semiconservative synthesis of DNA was also inhibited in CCRF-CEM nuclei isolated from cells pretreated with dAdo and dCf, suggesting damage to DNA replicative machinery. However, no such inhibition was observed in the nuclei of a similarly treated CCRF-CEM mutant that was deficient in adenosine kinase and deoxycytidine kinase. This suggests that dAdo must be phosphorylated in intact cells to exert its effect. Using [3H]dTTP incorporation in isolated CCRF-CEM nuclei to measure DNA synthesis, it was found that a high concentration (greater than 100 microM) of dATP inhibits semiconservative but not repair synthesis of DNA. The present studies thus indicate that accumulation of DNA strand breaks induced by dAdo plus dCf is not the consequence of inhibition of repair DNA synthesis. This implies the mechanism may involve perturbation of DNA ligation or activation of a certain process which causes DNA strand breaks. In addition, dATP may interfere with some steps of semiconservative DNA synthesis, but not the repair synthesis of DNA.     

DNA synthesis in BalB/C-3T3 ts 2 cells is restricted by a temperature-sensitive function of late G1 phase

ts 2 BalB/C-3T3 mouse fibroblasts are cdc mutants, which arrest late in G1, at or near the G1/S traverse, upon full expression of the heat-sensitive lesion. The kinetics of temperature inhibition of DNA synthesis in logarithmically growing cultures reveal three stages of heat inactivation. During the first generation time equivalent, normal semiconservative, semidiscontinuous replication proceeds but is reduced as cells exit and do not reenter S phase. During a second such period, a minimal rate of normal DNA synthesis is maintained. Thereafter, as the cells move into a third aborted cell division cycle, the rate of DNA synthesis increases. However, all semiconservative synthesis is then replaced by DNA repair replication. Temperature inactivation of the ts 2 protein results in shutdown of nuclear DNA synthesis. In contrast, normal replication of mitochondrial DNA proceeds at control rate throughout the first stage of temperature inactivation. Synthesis of this organellar genome is quantitatively reduced as the cells move into the second phase of heat inhibition. Titration of chromatin-bound DNA with ethidium bromide revealed that wild-type cells exhibit a changing DNA topology as the temperature is raised. Temperature-inactivated ts 2 cells behave as though their DNA has been topologically frozen in the configuration of control cells at or near entry into S phase.     

Deoxyribonucleic Acid Repair Replication after Ultraviolet Light or X-Ray Exposure of Bacteria

A comparison of repair synthesis after ultraviolet light (UV) or X-ray exposure was made in Escherichia coli strains 15T(-) (555-7) and B/r by use of a D, (15)N, (13)C density labeling system. During the initial 15 min of incubation after UV irradiation, both a "repair" synthesis and a reduced semiconservative deoxyribonucleic acid (DNA) synthesis occurred. In the so-called "physiological" dose range used, the latter was greater than the former. X-irradiation of cells, at doses producing similar levels of cell death as in the UV-exposed cultures, did not lead to a similar repair replication process. However, a density heterogeneity of the DNA synthesized in the initial 10 min after exposure was observed. This is interpreted in terms of X ray-induced DNA degradation. Normal cells showed only a semiconservative type of replication and, therefore, within the limits of resolution of the system used (the incorporation of 1,000 to 5,000 nucleotides per replicating chromosome could be measured), DNA in normal cells did not appear to undergo a repair synthesis involving thymine exchange. These results indicate that not all repair mechanisms mimic that found after UV exposure.     

Arrest of S-phase progression is impaired in Fanconi anemia cells

Fanconi anemia (FA) is an inherited cancer-susceptibility disorder, characterized by genomic instability, hypersensitivity to DNA cross-linking agents, and a prolonged G2 phase of the cell cycle. We observed a marked dose-dependent accumulation of FA cells in the G2 compartment after treatment with 4,5',8-trimethylpsoralen (Me(3)Pso) in combination with 365 nm irradiation. Using bivariate DNA distribution methodology, we determined the proportion of replicating and arresting S-phase cells and observed that, whereas normal cells arrested DNA replication in the presence of Me(3)Pso cross-links and monoadducts, FA lymphoblasts failed to arrest DNA synthesis. Taken together, the above data suggest that, in response to damage induced by DNA cross-linking agents, the S-phase checkpoint is inefficient in FA cells. This would lead to accumulation of secondary lesions, such as single- and double-strand breaks and gaps. The prolonged time in G2 phase seen in FA cells therefore exists in order to allow the cells to remove lesions which accumulated during the preceding abnormal S phase.     

Deoxyribonucleic acid excision repair in chromatin after ultraviolet irradiation of human fibroblasts in culture.

We have exposed confluent normal human fibroblasts to ultraviolet (UV) fluences of 5, 14, or 40 J/m2 and monitored the specific activity of post-UV repair synthesis in chromatin with [3H]thymidine pulses. We have shown that under conditions where no semiconservative deoxyribonucleic acid (DNA) synthesis is detectable, the specific activity of repair label in micrococcal nuclease resistant (core particle) DNA is about one-fifth that in bulk DNA at all three UV fluences. On the other hand, the distribution of thymine-containing pyrimidine dimers in bulk and nuclease-resistant regions measured either immediately after irradiation or at later times showed no significant differences; preferential labeling of linker (nuclease-sensitive) DNA during repair synthesis is thus apparently not due to a predominance of UV-induced photoproducts in linker relative to core particle DNA in the nucleosome. Pulse and pulse--chase experiments at 14 or 40 J/m2 with normal human or repair-deficient xeroderma pigmentosum (XP) cells showed that at most 30% of repair label in all these cells shifts from nuclease-sensitive (linker) DNA to nuclease-resistant (core particle) DNA.     

Novobiocin—A specific inhibitor of semiconservative DNA replication in permeabilized Escherichia coli cells

The effect of novobiocin on macromolecule synthesis was investigated in Escherichia coli cells permeabilized by treatment with toluene or 2 m-sucrose. It was found that (1) semiconservative DNA replication is strongly and immediately inhibited and (2) ATP-independent DNA repair as well as RNA and protein synthesis are not affected.     

DNA-repair synthesis in ataxia telangiectasia lymphoblastoid cells

The ability of a number of Epstein-Barr virus-transformed lymphoblastoid cells from ataxia telangiectasia (AT) patients to repair γ-radiation damage to DNA was determined. All of these AT cells were previously shown to be hypersensitive to γ-irradiation. Two methods were used to determine DNA-repair synthesis: isopycnic gradient analysis and a method employing hydroxyurea to inhibit semiconservative DNA synthesis. Control, AT heterozygote and AT homozygote cells were demonstrateed to have similar capacities for repair of radiation damage to DNA. In addition at high radiation doses (10–40 krad) the extent of inhibition of DNA synthesis was similar in the different cell types.     

DNA synthesis and mitotic activity in short-term cultures of hepatocytes isolated from regenerating rat liver

Cell suspensions were prepared from normal and regenerating liver of adult rats by perfusion with a calcium-chelating agent (EGTA), collagenase and hyaluronidase, and the cells were incubated in culture medium. In cultures prepared from regenerating liver at 20 h after partial hepatectomy, 23 ± 4% of parenchymal cells initially incorporated [³H]TdR. This incorporation was shown to reflect semiconservative DNA replication. At least some parenchymal cells were able to complete their DNA synthesis and to progress through G2 and mitosis. Numbers of hepatocytes in mitosis increased up to 12 h of culture. On the other hand, no entry of hepatocytes into the S period was detectable in cultures prepared from normal or regenerating liver.