Repair replication in human cells. Simplified determination utilizing hydroxyurea.

A simplified and shortened procedure has been developed for the determination of repair replication of DNA in cultured mammalian cells. The procedure, using the bromodeoxyuridine density label and a radio-isotopic label has been applied to normal diploid human cells (WI38) and to their SV40 transformants (VA13). After incubation with the repair label the cells are lysed and digested for two hours at 50 degrees C with proteinase K. This digest can then be immediately subjected to alkaline cesium chloride density gradient centrifugation with no need for DNA extraction. Hydroxyurea is used to reduce the level of semi-conservative synthesis that a quantitative determination of repair replication can be accomplished by a single centrifugation. The method is not affected by variation in the effectiveness of the inhibitor although a small amount of semi-conservative synthesis normally occurs in the presence of the drug. The time course of repair replication in WI38 cells is unaffected by the drug. The apparent amount of repair synthesis in ultraviolet irradiated cells is increased 25 to 40% in the presence of hydroxyurea when thymidine is used as tracer. Under certain conditions in which the level of semiconservative synthesis is low (e.g., contact inhibited cells, high ultraviolet doses) the use of hydroxyurea is unnecessary.     

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.     

DNA excision repair in mammalian cell extracts.

The many genetic complementation groups of DNA excision-repair defective mammalian cells indicate the considerable complexity of the excision repair process. The cloning of several repair genes is taking the field a step closer to mechanistic studies of the actions and interactions of repair proteins. Early biochemical studies of mammalian DNA repair in vitro are now at hand. Repair synthesis in damaged DNA can be monitored by following the incorporation of radiolabelled nucleotides. Synthesis is carried out by mammalian cell extracts and is defective in extracts from cell lines derived from individuals with the excision-repair disorder xeroderma pigmentosum. Biochemical complementation of the defective extracts can be used to purify repair proteins. Repair of damage caused by agents including ultraviolet irradiation, psoralens, and platinating compounds has been observed. Neutralising antibodies against the human single-stranded DNA binding protein (HSSB) have demonstrated a requirement for this protein in DNA excision repair as well as in DNA replication.     

Postreplication repair of DNA in chick cells: studies using photoreactivation.

During replication of DNA after ultraviolet irradiation, gaps are left in the newly-synthesized DNA strands in both bacterial and animal cells and these gaps are subsequently sealed by a process known as postreplication repair. In order to test whether it is the ultraviolet-induced pyrimidine dimers which are responsible for the production of these daughter-strand gaps in animal cells, we have used chick embryo fibroblasts. In these cells the pyrimidine dimers are photoreactivable, i.e. they can be split by an enzymatic process dependent on visible or near ultraviolet light. Our results indicate that chick cells possess a postreplication repair system similar to that in mammalian cells; gaps are produced in the newly-synthesized strands and then filled in. If the ultraviolet-irradiated cells are first photoreactivated to remove most of the dimers, the number of daughter-strand gaps produced is much less than without photoreactivation. This suggests that the dimers are indeed responsible for the formation of many of the gaps in the newly-synthesized DNA. Ultraviolet light also inhibits the overall rate of DNA synthesis. This inhibition is, however, only partly overcome by photoreactivation.     

Various Levels of DNA Repair Synthesis in Xeroderma Pigmentosum Cells exposed to the Carcinogens N-Hydroxy and N-Acetoxy-2-acetyl-aminofluorene

IN assessing environmental health hazards, the question has arisen of whether “safe”, “tolerable” or “permissible” levels of carcinogens, mutagens or teratogens can be derived by extrapolation of bioassays using rodents exposed for various periods to very high concentrations of chemicals or using cultured mammalian cell lines. Variations in susceptibility are only rarely taken into account, if at all and doses which seem to be harmless to the average person may be harmful to susceptible people. The reduced capacity to repair ultraviolet-induced DNA lesions in xeroderma pigmentosum (XP) cells may exemplify a mechanism leading to an elevated neoplastic transformation rate in man^1–4. The question arises as to whether cells with deficient repair synthesis respond to chemical carcinogens in the same manner as cells with adequate repair systems. We report here the levels of DNA repair synthesis in XP cells of five patients exposed to the carcinogenic^5,6 and mutagenic⁷ compounds N-acetoxy or N-hydroxy-2-acetyl-aminofluorene, which are ultimate and proximate carcinogenic forms of 2-acetylaminofluorene (AAF). We were particularly interested in comparing the different levels of DNA repair synthesis following ultraviolet irradiation with those following treatment with chemical carcinogens.     

Molecular mechanisms of induced mutagenesis: Replication in vivo of bacteriophage φX174 single-stranded,ultraviolet light-irradiated DNA in intact and irradiated host cells

Genetic analysis has revealed that radiation and many chemical mutagens induce in bacteria an error-prone DNA repair process which is responsible for their mutagenic effect. The biochemical mechanism of this inducible error-prone repair has been studied by analysis of the first round of DNA synthesis on ultraviolet light-irradiated φX174 DNA in both intact and ultraviolet light-irradiated host cells. Intracellular φX174 DNA was extracted, subjected to isopycnic CsCl density-gradient analysis, hydroxylapatite chromatography and digestion by single-strand-specific endonuclease S₁. Ultraviolet light-induced photolesions in viral DNA cause a permanent blockage of DNA synthesis in intact Escherichia coli cells. However, when host cells are irradiated and incubated to fully induce the error-prone repair system, a significant fraction of irradiated φX174 DNA molecules can be fully replicated. Thus, inducible error-prone repair in E. coli is manifested by an increased capacity for DNA synthesis on damaged φX174 DNA. Chloramphenicol (100 μg/ml), which is an inhibitor of the inducible error-prone DNA repair, is also an inhibitor of this particular inducible DNA synthesis.     

Dependence of mammalian DNA synthesis on DNA supercoiling. III. Characterization of the inhibition of replicative and repair-type DNA synthesis by novobiocin and nalidixic acid

Novobiocin and nalidixic acid, inhibitors of the bacterial enzyme DNA gyrase, inhibit DNA, RNA and protein synthesis in several human and rodent cell lines. The sensitivity of DNA synthesis (both replicative and repair) to inhibition by novobiocin and nalidixic acid is greater than that of protein synthesis. Novobiocin inhibits RNA synthesis about half as effectively as it does DNA synthesis, whereas nalidixic acid inhibits both equally well. Replicative DNA synthesis, as measured by incorporation of [3H]thymidine, is blocked by novobiocin in a number of cell strains; the inhibition is reversible with respect to both DNA synthesis and cell killing, and continues for as long as 20--30 h if the cells are kept in novobiocin-containing growth medium. Both novobiocin and nalidixic acid inhibit repair DNA synthesis (measured by BND-cellulose chromatography) induced by ultraviolet light or N-methyl-N'-nitro-N-nitrosoguanidine (but not that induced by methyl methanesulfonate) at lower concentration (as low as 5 micrograms/ml) than those required to inhibit replicative DNA synthesis (50 micrograms/ml or greater). Neither novobiocin nor nalidixic acid alone induces DNA repair synthesis. Incubation of ultraviolet-irradiated cells with 10--100 micrograms/ml novobiocin results in little, if any, further reduction of colony-forming ability (beyond that caused by the ultraviolet irradiation). Novobiocin at sufficiently low concentrations (200 micrograms/ml) apparently generates a quiescent state (in terms of cellular DNA metabolism) from which recovery is possible. Under more drastic conditions of time in contact with cells and concentration, however, novobiocin itself induces mammalian cell killing.     

Repair of single nucleotide DNA mismatches transfected into mammalian cells can occur by short-patch excision

Synthetic DNA linkers containing a single mismatched nucleotide (C:A) are repaired without bias at high efficiency when introduced into mammalian cells on a SV40 shuttle vector. From the pattern of repair in vectors containing multiple linkers, it appears that DNA synthesis following mismatch excision can replace a length of DNA as short as 40 nucleotides. Furthermore, results from the introduction of linker molecules containing combinations of single-strand nicks suggest that transient unsealed nicks do not drive the direction of mismatch repair in mammalian cells, as has previously been proposed.     

A Comparison of Survival and Repair of Uv-Induced DNA Damage in Cultured Insect VERSUS Mammalian Cells

Survival and unscheduled DNA synthesis (UDS) were measured in a cultured insect cell line, TN-368, and a cultured mammalian cell line, V-79-4, following exposure to several fluences of ultraviolet light. TN-368 cells were approximately seven times more resistant to the lethal effects of UV than V-79 cells, as determined by colony formation. The amount of UDS per unit amount of DNA is about the same in both cell types 4 hr after 10–50 J/m² UV irradiations.     

Rearrangements of chromatin structure in newly repaired regions of deoxyribonucleic acid in human cells treated with sodium butyrate or hydroxyurea

The rate and extent of redistribution of repair-incorporated nucleotides within chromatin during very early times (10-45 min) after ultraviolet irradiation were examined in normal human fibroblasts treated with 20 mM sodium butyrate, or 2-10 mM hydroxyurea, and compared to results for untreated cells. Under these conditions, DNA replicative synthesis is reduced to very low levels in each case. However, DNA repair synthesis is stimulated by sodium butyrate and partially inhibited by hydroxyurea. Furthermore, in the sodium butyrate treated cells, the core histones are maximally hyperacetylated. Using methods previously described by us, it was found that treatment with sodium butyrate had little or no effect on either the rate or the extent of redistribution of repair-incorporated nucleotides during this early time interval. On the other hand, there was a 1.7-2.5-fold decrease in the rate of redistribution of these nucleotides in cells treated with hydroxyurea; the extent of redistribution was unchanged in these cells. Since hydroxyurea has been shown to decrease the rate of completion of "repair patches" in mammalian cells, these results indicate that nucleosome rearrangement in newly repaired regions of DNA does not occur until after the final stages of the excision repair process are completed. Furthermore, hyperacetylation of the core histones in a large fraction of the total chromatin prior to DNA damage and repair synthesis does not appear to alter the rate or extent of nucleosome core formation in newly repaired regions of DNA.     

Pollen DNA repair after treatment with the mutagens 4-nitroquinoline-1-oxide, ultraviolet and near-ultraviolet irradiation, and boron dependence of rapair

Summary Irradiation of dry, mature pollen from Petunia hybrida with near-ultraviolet light from an erythemal-sunlamp gave rise to a repair-like, unscheduled DNA synthesis during the early stages of in vitro germination. Like that brought about by farultraviolet light from a germicidal lamp, this DNA synthesis is enhanced by hydroxyurea added to the germination medium, and reduced by photoreactivating light given after ultraviolet irradiation and before germination begins. It is concluded that pollen, often receiving considerable exposure to sunlight, has, in addition to the protection afforded by the ultraviolet filtering effect of yellow pigments, also the capacity to repair ultraviolet produced changes in DNA, by both photoreactivation and dark repair processes.Because mature Petunia pollen is arrested at the G₂ stage of the cell cycle, germinating pollen provides us with a highly synchronous plant tissue with a very low background of DNA replicative synthesis suitable for sensitive measurement of DNA repair synthesis. Thus we have shown that 4-nitroquinoline-1-oxide, at concentrations greater than 0.001 mM, gives rise to an unscheduled DNA synthesis which is enhanced by hydroxyurea. Like that induced by ultraviolet radiation, the chemical mutagen brings about DNA repair only during the early stages of pollen germination, and further it has been possible to show that repair ceases at about the time that generative cell division and pollen tube elongation begins.Boron addition enhances both ultraviolet and 4-nitroquinoline-1-oxide induced repair synthesis. By delaying the chemical mutagen initiation of repair until after germination has begun, we have been able to show that boron is most beneficial during the first hour of germination. It is postulated that this is achieved through an as yet unknown effect of boron on the supply of precursors before pollen cell metabolism is fully committed to pollen tube synthesis later in the germination period.     

DNA replication and UV-induced DNA repair synthesis in human fibroblasts are much less sensitive than DNA polymerase alpha to inhibition by butylphenyl-deoxyguanosine triphosphate.

In mammalian cells, both semiconservative DNA replication and the DNA repair patch synthesis induced by high doses of ultraviolet radiation are known to be inhibited by aphidicolin, indicating the involvement in these processes of one or both of the aphidicolin-sensitive DNA polymerases, alpha and/or delta. In this paper, N2-(p-n-butylphenyl)-2'-deoxyguanosine-5'-triphosphate, a strong inhibitor of polymerase alpha and a weak inhibitor of polymerase delta, is used to further characterize the DNA polymerase(s) involved in these two forms of nuclear DNA synthesis. In permeable human fibroblasts, DNA replication and ultraviolet-induced DNA repair synthesis are more resistant to the inhibitor than DNA polymerase alpha by factors of approximately 500 and 3000, respectively. These findings are most consistent with the involvement of DNA polymerase delta in these processes.     

Rate of DNA synthesis in mammalian cells irradiated with ultraviolet light: a model based on the variations in the rate of movement of the replication fork and in the number of active replicons

A model is proposed to describe the rate of DNA synthesis observed under certain conditions in UV irradiated mammalian cells. It is assumed that shortly after irradiation the rate of DNA synthesis drops mainly as a consequence of the drop in the rate of movement of the replication fork. This in turn, is due to a pause at the dimer for a limited length of time. Later on, a recovery in the rate of DNA synthesis occurs, and it is proposed that one of the parameters contributing to that is an increase in the number of active replicons. This simple model enables one to predict variations in the rate of DNA synthesis as a function both of UV dose and of time after irradiation.     

Exploiting features of adenovirus replication to support mammalian kinase production

Faced with the current wealth of genomic data, it is essential to have robust and reliable methods of converting DNA sequences into their functional gene products. We demonstrate here that when conditions are established that take advantage of the replication-associated virus amplification, the virus-induced shutdown of host protein synthesis as well as the activation of signalling pathways that normally occur during virus replication, adenovirus biology can be exploited to generate a potent kinase expression system. Residual virus in the protein production has always been a limitation for adenovirus systems and we describe a DNA intercalator/ultraviolet light treatment that eliminates residual adenovirus in protein preparations that has no deleterious effect on enzyme activity. The use of mammalian cells in combination with adenovirus generated a variety of active enzymes which could not be produced in Escherichia coli or baculovirus-infected insect cells. Thus, the utility of adenovirus-mediated enzyme expression as a versatile alternative to established protein production technologies is demonstrated.     

Repair of DNA damage in shuttle vectors, virus, and chromosomal DNAs may depend on their biological imprinting--a 'Pygmalion' effect

We have created a cell line that can repair damage in chromosomal DNA and in herpes virus, while not repairing the same damage in shuttle vectors (pZ189 and pRSVcat). This cell line, a xeroderma pigmentosum (XP) revertant, repairs the minor (6-4)-photoproducts, but not cyclobutane dimers, in chromosomal DNA. The phenotype of this revertant after irradiation with ultraviolet (UV) light is the same as that of normal cells for survival, repair replication, recovery of rates of DNA and RNA synthesis, and sister-chromatid exchange formation, which indicates that a failure to mend cyclobutane dimers may be irrelevant to the fate of irradiated human cells. The two shuttle vectors were grown in Escherichia coli and assayed during transient passage in human cells, whereas the herpes virus was grown and assayed exclusively in mammalian cells. The ability of the XP revertant to distinguish between the shuttle vector and herpes virus DNA molecules according to their 'cultural background', i.e., bacterial or mammalian, may indicate that one component of the repair of UV damage involves gene products that recognize DNA markers that are uniquely mammalian, such as DNA methylation patterns. This component of excision repair may be involved in the original defect and the reversion of XP group A cells.     

Repair of pyrimidine dimer ultraviolet light photoproducts by human cell extracts

A newly developed method allows human cell extracts to carry out repair synthesis on ultraviolet light irradiated closed circular plasmid DNA [Wood, R. D., Robins, P., & Lindahl, T. (1988) Cell 53, 97-106]. The identity of the photodamage that leads to this repair replication was investigated. Removal of stable pyrimidine hydrates from irradiated plasmid pAT153 did not significantly affect the amount of repair replication in the fluence range of 0-450 J/m2, because of the low yield of these products and their short DNA repair patch size. Photoreactivation of irradiated DNA using purified Escherichia coli DNA photolyase to remove more than 95% of the cyclobutane dimers from the DNA reduced the observed repair synthesis by 20-40%. The greater part of the repair synthesis is highly likely to be caused by (6-4) pyrimidine dimer photoproducts. This class of lesions is rapidly repaired by mammalian cells, and their removal is known to be important for cell survival after ultraviolet irradiation.     

Repair of DNA damage in shuttle vectors,virus, and chromosomal DNAs may depend on their biological imprinting — a ‘Pygmalion’ effect

We have created a cell line that can repair damage in chromosomal DNA and in herpes virus, while not repairing the same damage in shuttle vectors (pZ189 and pRSVcat). This cell line, a xeroderma pigmentosum (XP) revertant, repairs the minor (6-4)-photoproducts, but not cyclobutane dimers, in chromosomal DNA. The phenotype of this revertant after irradiation with ultraviolet (UV) light is the same as that of normal cells for survival, repair replication, recovery of rates of DNA and RNA synthesis, and sister-chromatid exchange formation, which indicates that a failure to mend cyclobutane dimers may be irrelevant to the fate of irradiated human cells. The two shuttle vectors were grown in Escherichia coli and assayed during transient passage in human cells, whereas the herpes virus was grown and assayed exclusively in mammalian cells. The ability of the XP revertant to distinguish between the shuttle vector and herpes virus DNA molecules according to their ‘cultural background’, i.e., bacterial or mammalian, may indicate that one component of the repair of UV damage involves gene products that recognize DNA markers that are uniquely mammalian, such as DNA methylation patterns. This component of excision repair may be involved in the original defect and the reversion of XP group A cells.     

Characteristics of enzymatic DNA methylation in cultured cells of human and hamster origin,and the effect of DNA replication inhibition

In mammalian cells, inhibitors of DNA replication have been shown to induce chromosomal aberrations, cell death and changes in gene control. Inhibition of DNA synthesis has been reported to induce hypermethylation of mammalian DNA (enzymatic postsynthetic formation of 5-methylcytosine). These 5-methylcytosines in mammalian DNA have variously been suggested to be important in gene control, DNA repair, and control of DNA replication. In establishing the normal characteristics of enzymatic DNA methylation, we have demonstrated that, in asynchronously growing cells of both human and hamster origin, some cytosine methylation is delayed for several hours after strand synthesis and that this delayed methylation is completed before the DNA strand acts as a template for DNA replication in the next S-phase. Further, in testing whether the deleterious effects on mammalian cells of DNA synthesis inhibitors might be mediated via changes in enzymatic DNA methylation, we have found, contrary to some previous findings, no evidence for any change in the level of DNA methylation in DNA strands synthesized during 6 h of treatment of cells of human origin with high concentrations of four different inhibitors of DNA replication or during the 4 h following the 6 h treatment. Almost totally blocking DNA replication had no effect on the small amount of delayed methylation of DNA strands not involved in semi-conservative replication during the time of the experiment. This lack of effect on DNA methylation was obtained when the labelling medium contained normal, undialysed serum. In contrast, if dialysed serum was used in the labelling medium in order to maximize l-[Me-³H]methionine utilization, highly variable, totally irreproducible patterns of apparent DNA hypermethylation were obtained.