Metronidazole (Flagyl): lack of induction of sister-chromatid exchanges in CHO-K1 cells

328 X-linked recessive lethal mutations induced in late spermatids by hycanthone methanesulfonate were tested for coverage by duplications that comprised, in total, about 24% of the euchromatic X chromosome; 78 lethals appeared to be covered. Crossover localization tests of a random sample of 38 non-covered lethals revealed 4 chromosomes carrying a lethal within a duplicated segment. Lethals localized to a particular region were crossed to reference deficiencies and single-locus mutations, and inter se, to ascertain their genetic extent. The proportion of multi-locus deletions among these 78 covered and 4 non-covered lethals was 3/48, 1/10 and 13/24 for the distal, medial and proximal regions, respectively. A storage period of 9 days did not noticeably influence these proportions. In the sample of 38 non-covered lethals, and among 17 of the covered single-site lethals, 4 cases of strong crossover suppression were detected. Comparison of these results with data obtained with other mutagens suggests that induction of multi-locus deletions, and possibly of other types of chromosome rearrangement, could in part depend on other mechanisms than those acting in the formation of translocations and chromosome loss. For the purpose of mutagen testing, these findings imply that, in Drosophila, results in the regular genetic tests for chromosome breakage events do not always accurately predict the capacity of a mutagen to induce multi-locus deletions. This is of importance since transmissible multi-locus deletions have been considered a significant source of genetic damage in man.     

Breakage by hydrodynamic shear of the bonds between cohered ends of lambda-DNA molecules

The rate of breakage by hydrodynamic shear of the cohered ends of λ-DNA molecules has been observed for the circular monomers, joined half molecules, and joined quarter molecules, in a capillary apparatus with known flow parameters. The rate constant for breakage has been measured as a function of shear stress, temperature, ionic strength, and molecular length. There is a large temperature coefficient, with an activation energy of 120 ± 20 kcal./mole. The values of d ln k/dG, where k is the rate constant for breaking and G is shear gradient, in aqueous solution at 25°C. are about 3.8 ± 0.3 × 10^?4 see. The shear stresses needed for breakage of joined quarter molecules and of circular monomers, respectively, are about equal, and about half that needed for breakage of joined half molecules. The rate of breakage at a given shear stress increases with decreasing ionic strength, approximately as [Na⁺]^?1.6. Self-protection effects are not observed for opening of circular monomers at a DNA concentration of 5 μg./ml. but are observed for breakage of joined half molecules at concentrations down to 0.5 μg./ml. The large temperature coefficient which is approximately equal to that of the thermal dissociation of the cohered ends is interpreted to mean that shear breakage is a mechanically assisted thermal reaction in which the thermal fluctuations provide most of the free energy of activation for breakage. A detailed model for this interpretation is presented. The self-protection effect implies that those molecules which break are not average molecules but exceptional ones which, due to some fluctuation, are more fully extended in the flow field.     

Author index

Properties of strand breakage in duplex and single-stranded DNA by the wheat germ type 1 DNA topoisomerase were investigated. Strand breakage in duplex DNA is dependent upon the use of denaturing conditions to inactivate the enzyme and terminate the reaction, whereas breakage of single-stranded DNA occurs under the normal reaction conditions and is not dependent upon denaturation. Breakage generates a free 5′ hydroxyl group and enzyme bound to the 3′ side of the break, presumably via the 3′ phosphate group. The location of sites of breakage with both duplex and single-stranded DNA is not random. In all these respects the wheat germ enzyme closely resembles the rat liver type 1 topoisomerase. A comparison of the locations of the sites of breakage in duplex DNA generated by the topoisomerases from wheat germ and rat liver indicates a number of common sites, although the patterns of breakage are not identical.     

Paradoxical role of lipid metabolism in heart function and dysfunction

The naturally occurring flavonoid, quercetin, in the presence of Cu(II) and molecular oxygen caused breakage of calf thymus DNA, supercoiled pBR322 plasmid DNA and single stranded M13 phage DNA. In the case of the plasmid, the product(s) were relaxed circles or a mixture of these and linear molecules depending upon the conditions. For the breakage reaction, Cu(II) could be replaced by Fe(III) but not by other ions tested [Fe(II), Co(II), Ni(II), Mn(II) and Ca(II)]. Structurally related flavonoids, rutin, galangin, apigenin and fisetin were effective or less effecive than quercetin in causing DNA breakage. In the case of the quercetin-Cu(II) reaction, Cu(I) was shown to be essential intermediate by using the Cu(1)-sequestering reagent, bathocuproine. By using Job plots we established that, in the absence of DNA, five Cu(II) ions were reduced by one quercetin molecule; in contrast two ions were reduced per quercetin molecule in the DNA breakage reaction. Equally neocuproine inhibited the DNA breakage reaction. The involvement of active oxygen in the reaction was established by the inhibition of DNA breakage by superoxide dismutase, iodide, mannitol, formate and catalase (the inhibition was complete in the last case). The strand scission reaction was shown to account for the biological activity of quercetin as assayed by bacteriophage inactivation. From these data we propose a mechanism for the DNA strand scission reaction of quercetin and related flavonoids.     

Strand scission in DNA by Gossypol and Cu(II): Role of Cu(I) and oxygen-free radicals

Gossypol, a polyphenolic binaphthyl dialdehyde found in cotton seeds, is a dietary mutagen and a potential male contraceptive. In the presence of Cu(II), gossypol caused breakage of supercoiled plasmid pBR322 DNA. The products were relaxed circles or a mixture of these and linear molecules. Other metal ions tested [Ni(II), Co(II), Mn(II), and Fe(II)] were ineffective or less effective in the DNA breakage reaction. In the case of gossypol-Cu(II) mediated cleavage, (Cu(I) was shown to be an essential intermediate by using the Cud) sequestering reagent bathocuproine. By using job plots, it was established that in the absence of DNA, eight Cu(II) ions can be reduced by one gossypol molecule. The involvement of active oxygen species, such as singlet oxygen and H₂O₂, was established by the inhibition of DNA breakage by catalase and by sodium azide. It was further shown that gossypol is capable of directly producing H₂O₂.     

Shear breakage of DNA.

Determinations were made of the mean length of fragments produced after shearing long (greater than 100 kb) native Hela DNA in a VirTis homogenizer. (VirTis Co., Inc., Gardiner, N.Y.). The mean length (L) is a function of the speed of rotation of the homogenizer blades (omega), time of shearing (t), water concentration ([H2O]), solvent viscosity (eta), temperature (T), and energy of activation (E*), but not a function of the initial length so long as the starting molecules sustain an average of three or more breaks. The relationship of the parameters is expressed by the equation L = (b/omegat1/2eta1/2[H2O])eE*/2kBT, where kB is the Boltzmann constant and b is a constant of proportionality. The breakage rate constant k was determined to have the relationship k = (omega2L2eta[H2O]2/2b2)e-E*/kBT. These equations are valid throughout large ranges of the parameters, and a simple method is described which chooses a final mean length between at least 0.15 and 36 kb by choosing the appropriate shearing conditions and initial fragment length. The heterogeneity of shearing conditions within the shearing vessel permits use of the equations at all breakage rates tested. Based on the work of others using more homogeneous shearing conditions and initial fragment lengths, more complicated forms of the equations are necessary at low breakage rates but not at high ones. A proposed model of the breakage mechanism suggests that molecules with stress-induced localized denaturations break at a rate different from that for native DNA.     

Single-Strand Breaks in Deoxyribonucleic Acid and Viability Loss During Deoxyribonucleic Acid Synthesis Inhibition in Escherichia coli

The effects of deoxyribonucleic acid (DNA) synthesis inhibition brought about in four different ways-thymidine starvation, nalidixic acid, hydroxyurea, and dnaB mutation-were examined in isogenic strains of Escherichia coli K-12. Three parameters were examined to determine whether there are strict correlations among them: (i) the extent of DNA synthesis inhibition; (ii) cell survival; and (iii) the rate of breakage of DNA molecules. There was no significant correlation between the extent of DNA synthesis inhibition and the rate of viability loss caused by the four DNA synthesis inhibitors, nor was there a strict correlation between the rate of occurrence of single-strand breaks in DNA and loss of viability. During treatment with hydroxyurea (0.1 M), no viability loss was observed and little, if any, single-strand breakage of DNA occurred. Both thymidine starvation and nalidixic-acid (20 mug/ml) treatment resulted in viability loss and breakage of DNA. For these latter two inhibitors, the two events appeared to be associated because greater rates of both viability loss and DNA breakage were observed for nalidixic acid compared with thymidine starvation. However, viability loss need not be associated with extensive breakage of DNA as demonstrated with a temperature-sensitive DNA synthesis mutant; at 39 C, viability loss occurred at a high rate without significant DNA breakage. With the other agents, the amount of DNA breakage accumulated when a cell population has sustained an average of one lethal hit was estimated to be about 30 single-strand breaks per genome. Differences in chromosomal and episomal breakage rates were observed.     

Hydrodynamic shear breakage of DNA

The rate of breakage of duplex DNA molecules by laminar flow through a capillary has been studied. For λb2b5c DNA (molecular wt., M = 25 × 10⁶) the point at which breakage occurs is normally distributed around the center of the molecule with a standard deviation of 12.5% of the molecular length. At constant shear stress or shear rate, the breakage rate is independent of ionic strength. Thus, shear induced local denaturation is not a rate limiting, preliminary step in breakage. In experiments at constant temperature with varying solvent viscosity (controlled by added sucrose) the breakage rate is a function of shear rate, not of shear stress. The rate of opening of hydrogenbonded circles into linear molecules by hydrodynamic shear is also shown to be a function of shear rate and not of shear stress. The breakage rate at constant shear rate is not greatly dependent on temperature. The shear rate required to achieve breakage is inversely proportional to M^1,2. The breakage rate constant, k varies as a very high power of the shear rate; at 25°C, d In k/d In Gm ～ 15; at 10°C, d In k/d In Gm ～ 26, where Gm is the maximum shear rate at the capillary wall. The unexpected result that breakage rate is mainly dependent on shear rate, not shear stress, supports a model in which the DNA molecule is distorted with a driving force which depends on the hydrodynamic shear stress, ηG, but the rate limiting step is segment diffusion into a highly extended configuration. The characteristic time to achieve this configuration is proportional to solvent viscosity, η, hence the breakage rate is dependent on ηG/η or G, the shear rate.     

DNA polymerase β-dependent cell survival independent of XRCC1 expression

Base excision repair (BER) is a primary mechanism for repair of base lesions in DNA such as those formed by exposure to the DNA methylating agent methyl methanesulfonate (MMS). Both DNA polymerase β (pol β)- and XRCC1-deficient mouse fibroblasts are hypersensitive to MMS. This is linked to a repair deficiency as measured by accumulation of strand breaks and poly(ADP-ribose) (PAR). The interaction between pol β and XRCC1 is important for recruitment of pol β to sites of DNA damage. Endogenous DNA damage can substitute for MMS-induced damage such that BER deficiency as a result of either pol β- or XRCC1-deletion is associated with sensitivity to PARP inhibitors. Pol β shRNA was used to knock down pol β in Xrcc1^+/+ and Xrcc1^−/− mouse fibroblasts. We determined whether pol β-mediated cellular resistance to MMS and PARP inhibitors resulted entirely from coordination with XRCC1 within the same BER sub-pathway. We find evidence for pol β-dependent cell survival independent of XRCC1 expression for both types of agents. The results suggest a role for pol β-dependent, XRCC1-independent repair. PAR immunofluorescence data are consistent with the hypothesis of a decrease in repair in both pol β knock down cell variants.     

In vitro analysis of a type I DNA topoisomerase activity from cultured tobacco cells

The role of DNA topoisomerases in plant cell metabolism is currently under investigation in our laboratory. Using a purified type I topoisomerase from cultured tobacco, we have carried out a biochemical characterization of enzymatic behavior. The enzyme relaxes negatively supercoiled DNA in the presence of MgCl₂, and to a lesser extent in the presence of KCl. Phosphorylation of the topoisomerase does not influence its activity and it is not stimulated by the presence of histones H1 or H5. The enzyme may act in either a processive or distributive manner depending on reaction conditions. The anti-tumor drug, camptothecin, induces significant breakage by the enzyme on purified DNA molecules unless destabilized by the addition of KCl. The tobacco topoisomerase I can catalyze the formation of stable nucleosomes on circular DNA templates, suggesting a role for the enzyme in chromatin assembly.     

Detection of antigenically active mutant HGPRT after mutagenesis with Simian virus 40.

BCNU and 10 related chloroethylnitrosoureas were tested for their ability to induce sex-linked recessive lethals in Drosophila spermatozoa. All chloroethyl-nitrosoureas tested were potent mutagens.Among the substances with one chloroethylnitrosourea group, chlorozotocin, BCNU and methanesulfonyloxyethyl chloroethylnitrosourea exhibited the strongest mutagenic effects. Two hydroxyalkyl chloroethylnitrosoureas behaved as potent mutagens too, although the mutation frequencies obtained were one order of magnitude lower relative to the other substances.Among the compounds with two chloroethylnitrosourea groups, bisCNU-ethane and bisCNU-diphenylmethane were most active. When the interconnecting polymethylene chain was elongated from 2 methylene groups (bisCNU-ethane) to 6 methylene groups (bisCNU-hexane), the mutagenic activity decreased by a factor of 2. The mutagenic activity of polymethylene bischloroethylnitrosoureas with connecting chains of intermediate length was not different from bisCNU-hexane.Differences in mutagenic activity were supposed to reflect different concentrations reaching the target cells, possibly in part as a result of differences in transportability of the substances.     

Characterization of the plant homolog of Nijmegen breakage syndrome 1: Involvement in DNA repair and recombination

The Nbs1 gene is known to code for a protein involved in the hereditary cancer-prone disease, Nijmegen breakage syndrome. This gene is conserved in animals and fungi, but no plant homolog is known. The work reported here describes a homolog of Nbs1 isolated from higher plants. The Nbs1 proteins from both Arabidopsis thaliana and Oryza sativa are smaller in size than animal or yeast Nbs1, but both contain the conserved Nbs1 domains such as the FHA/BRCT domain, the Mre11-binding domain, and the Atm-interacting domain in orientations similar to what is seen in animal Nbs1. The OsNbs1 protein interacted not only with plant Mre11, but also with animal Mre11. In plants, OsNbs1 mRNA expression was found to be higher in the shoot apex and young flower, and AtNbs1 expression increased when plants were exposed to 100 Gy of X-rays. These results suggest that plant Nbs1 could participate in a Rad50/Mre11/Nbs1 complex, and could be essential for the regulation of DNA recombination and DNA damage responses.     

Roles of ChlR1 DNA helicase in replication recovery from DNA damage

The ChlR1 DNA helicase is mutated in Warsaw breakage syndrome characterized by developmental anomalies, chromosomal breakage, and sister chromatid cohesion defects. However, the mechanism by which ChlR1 preserves genomic integrity is largely unknown. Here, we describe the roles of ChlR1 in DNA replication recovery. We show that ChlR1 depletion renders human cells highly sensitive to cisplatin; an interstrand-crosslinking agent that causes stalled replication forks. ChlR1 depletion also causes accumulation of DNA damage in response to cisplatin, leading to a significant delay in resolution of DNA damage. We also report that ChlR1-depleted cells display defects in the repair of double-strand breaks induced by the I-PpoI endonuclease and bleomycin. Furthermore, we demonstrate that ChlR1-depeleted cells show significant delays in replication recovery after cisplatin treatment. Taken together, our results indicate that ChlR1 plays an important role in efficient DNA repair during DNA replication, which may facilitate efficient establishment of sister chromatid cohesion.     

聚腺苷二磷酸核糖基聚合酶──在DNA损伤修复及程序性死亡中的作用

聚腺苷二磷酸核糖基聚合酶(poly (ADP-ribose) polyerase, PARP)是存在于多数真核细胞中的一个蛋白质翻译后修饰酶,它可催化组蛋白H₁等重要核蛋白及它自身的聚腺苷二磷酸核糖基化作用.细胞受到外界损伤因子作用时, DNA发生链断裂,PARP结合到DNA断裂口,其催化活性被激活,修饰受体蛋白,进而引发一系列级联反应.这种性质使PARP有可能作为细胞内的分子感受器和传感器,启动细胞内对损伤作出反应的信号传导机制,从而根据细胞受损程度决定细胞的命运：修复或是死亡．     

Random-breakage mapping, a rapid method for physically locating an internal sequence with respect to the ends of a DNA molecule.

We describe a method for determining the position of a cloned internal sequence with respect to the ends of a DNA molecule. The molecules are randomly broken at low frequency and the fragments are subjected to electrophoresis. Southern hybridization using the cloned DNA as a probe identifies only those fragments containing the sequence. The size distribution of these fragments is such that two threshold changes in intensity of signal are seen in the smear pattern below the unbroken molecules. The positions of the changes represent the distances from the sequence to each molecular end. The intensity changes arise because the natural ends of the molecules influence the fragment distribution obtained. From once-broken molecules, no fragments can arise that contain a given sequence and are shorter than the distance between that sequence and the nearest molecular end. We tested the method by using x-rays to induce breakage in yeast DNA. Genes of independently known position were mapped within whole chromosomes or Not I restriction fragments using Southern blots from gels of irradiated molecules. We present equations to predict fragment distribution as a function of break-frequency and position of the probed sequence.     

Isolation and characterization of temperature-sensitive mutants in a Chinese hamster cell line

A replica plating method was used for the isolation of temperature-sensitive (ts) mutants after treatment of Chinese hamster cells with ethyl methanesulfonate (EMS). No significant increase in ts mutants was found after this treatment. The limitations and advantages of the replicating procedure to detect such differences, as well as an alternative method, are discussed.Mutants isolated were classified into two general groups—density-dependent and clear-cut—as measured by survival at low and high cell densities at the restrictive temperature. The density-dependent mutants may be truly “leaky”, losing a metabolite to the medium at an excessive rate at the restrictive temperature. On the other hand, the one clear-cut mutant analyzed extensively dies at a rate determined by its ability to utilize one or more components from the medium. It shows an inverse density relationship in rate of death, as inferred from rates of macromolecular synthesis, as opposed to its growth rate at the permissive temperature.     

Generation of DNA double-strand breaks and inhibition of somatic embryogenesis by tungsten microparticles in wheat

Particles of metallic tungsten, known also as tungsten microprojectiles, are routinely used to deliver foreign DNA into target cells and tissues. Some side effects of biolistic transformation have been observed but never studied in detail. Here we present evidence that intact tungsten particles can promote a breakage of phosphodiester bonds in native DNA, at a limited number of sites. A single, double-strand break appeared within almost each of the circular pUC119 molecules after a short incubation of plasmid DNA with a suspension of tungsten particles. No further DNA cutting could be induced even if the reaction rate was accelerated by increasing the concentration of tungsten in the incubation mixture. Indirect evidence indicates that similar lesions may be generated in cellular DNA of bombarded tissues. These lesions are rapidly repaired, as evidenced by increasing incorporation of labelled DNA precursors in bombarded wheat embryos. The rate of repair is, however, not high enough to restore all the genome functions. Neither germination of mature embryos nor initiation of callus tissues from immature embryos was inhibited by biolistic bombardment. Nevertheless, the frequency of formation of somatic embryos in calli derived from bombarded embryos was markedly lower than in calli derived from control embryos. Both immediate (generation of a limited number of double-strand breaks) and remote (selective inhibition of somatic embryogenesis) side effects of the biolistic process strongly suggest that biological activity of tungsten deserves special attention. This revised version was published online in June 2006 with corrections to the Cover Date.     

Mutagen sensitivity of Drosophila melanogaster. I. Isolation and preliminary characterization of a methyl methanesulphonate-sensitive strain

Sensitivity to the monofunctional alkylating agent methyl methanesulfonate (MMS) has been tested as a selection technique to isolate mutant strains which can provide insights into the genetic control of DNA replication, DNA repair and recombination in the complex eucaryote, Drosophila melanogaster. The successful isolation of an X-linked MMS-sensitive strain, mut^s, has suggested that mutagen sensitivity is a feasible methodology for the selection of mutant strains of Drosophila which will be useful in the genetic and biochemical analysis of these cellular functions. Preliminary characterization of this mutant strain indicates that: (A) it is extremely sensitive to killing by MMS; (B) it is more mutable by MMS than the parent wildtype strain; and (C) it appears to possess mutator gene activity.