Comparison of dose-response relationships for ethyl methanesulfonate and 1-ethyl-1-nitrosourea in Drosophila melanogaster spermatozoa

The relative importance of different sites of alkylation on DNA was determined by comparing two ethylating agents. 1-Ethyl-1-nitrosourea (ENU) ethylates DNA with a higher proportion of total adducts on ring oxygens than ethyl methanesulfonate, which ethylates with a higher proportion of total adducts on the N-7 of guanine. Research with somatic cells in culture and prokaryotes strongly suggests that O6-guanine (O6-G) is the principal genotoxic site. To determine the importance in germ-line mutagenesis of the O6-G site relative to the N-7 of guanine, dose-response curves were constructed for both ENU and EMS, where dose was measured as total adducts per deoxynucleotide (APdN) and response as sex-linked recessive lethals (SLRL) induced in Drosophila melanogaster spermatozoa. For both mutagens the dose response curve was linear and extrapolated to the origin. The dose-response curve for ENU was fit to an equation m = 6.2D, and the dose response curve for EMS, from this and previous experiments, was m = 3.2D where m = %SLRL and D = APdN X 10(-3). Therefore, ENU is 1.9 times more efficient per adduct in inducing SLRL mutations than EMS. In vitro studies showed that ENU induced 9.5% of its total adducts on O6-G while EMS induced 2.0% of its adducts on O6-G. If O6-G was the sole genotoxic site, then ENU should be 4.8 times more efficient per adduct than EMS. In contrast, if N-7 G was the sole genotoxic site, ENU would be only 0.19 as effective as EMS. It was concluded that while O6-G was the principal genotoxic site, N-7 G made a significant contribution to germ-line mutagenesis.     

Induction of specific-locus mutations in female mice by 1-ethyl-1-nitrosourea and procarbazine

Using the specific-locus method, the ability of 1-ethyl-1-nitrosourea (ENU) and procarbazine hydrochloride (procarbazine) to induce gene mutations in mouse oocytes was tested and confirmed. The sensitive stage for the induction of mutations in oocytes with 160 mg/kg of ENU is 2-4 weeks post treatment. The induced mutation frequency in this mating interval was 5.1 X 10(-7) mutations/locus/gamete/mg/kg. The induction of mutations by procarbazine occurred 8-33 weeks after treatment. The induced mutation frequency in this mating interval for the 400 mg/kg group was 0.4 X 10(-7) mutations/locus/gamete/mg/kg. One third of the induced mutations was lethal in homozygous condition in both experiments. ENU and procarbazine have a lower mutational response in oocytes than in stem-cell spermatogonia.     

Relation between the changes in the structure and synthesis of DNA in the cells of mouse leukemia L1210 induced by 1-methyl-1-nitrosourea and 1,3-bis(2-chloroethyl)-1-nitrosourea

The damage of DNA structure and synthesis in murine leukemia L1210 cells upon single administration in therapeutic doses of antitumour agents of N-nitrosourea type, such as 1-methyl-1-nitrosourea (MNU) and 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) was studied. MNU and BCNU were characterized by stronger inhibitory effects on de novo DNA synthesis compared to additional pathway of DNA synthesis in leukemia L1210 cells in vivo. Centrifugation in alkaline sucrose density gradients of L1210 cell lysates has revealed persistent single-strand breaks and alkaline-labile sites in newly replicated DNA. Parental DNA structure was more stable to damaging drug effects than that of newly replicated DNA. The results are consistent with our previous data on the differences in the mechanisms of MNU and BCNU action and the absence of complete cross resistance between the drugs.     

Cytology of aberrations induced by X-rays in oocytes of Drosophila melanogaster.

200 first-division configurations were analyzed for cytological aberrations induced by X-rays in late meiotic prophase in oocytes of Drosophila melanogaster. For the 3000 and 6000 r doses, 38 and 66%, respectively, were classified as abnormal. The aberrant divisions included displacement of the chromosomes suggesting their non-disjunction, loss of a whole chromosome, fragments and heterologous exchanges and unidentifiable aberrations. Non-disjunctional chromosomes were free of heterologous exchanges. The concept that a majority of X-ray-induced dominant lethals is due to chromosomal breakage is supported by the findings of the present study.     

Specificity of mutational DNA sequence changes induced by X-rays in the cloned Escherichia coli crp gene.

Plasmid DNA carrying the adenosine 3',5'-cyclic monophosphate receptor protein (crp) gene of Escherichia coli was irradiated, in solution, with X-rays, and the mutations produced in the crp gene were assayed by transforming the recipient E. coli cells. Ninety-six mutant clones were isolated, and mutational changes were determined by DNA sequencing. Of the 92 mutations thus detected, 74 represented base substitution mutations and the remaining 18 were frameshifts. The base substitutions included 56 G:C to A:T transitions, 10 G:C to T:A transversions and 7 G:C to C:G transversions. An A:T to G:C transition was found only once, and neither an A:T to T:A nor an A:T to C:G transversion was detected. The frameshift mutations consisted of 11 one-base deletions and 7 one-base insertions. Accordingly, G:C to A:T transition was the predominant type of mutation, which constituted 76% (56/74) of the total base substitutions and 60% (56/92) of all detected mutations. Furthermore, of the 56 transitions, about three-quarters (41 clones) clustered at an identical site, a cytosine residue at the 706 position, demonstrating that this site is a distinct hot spot for X-ray mutagenesis. These results raise the possibility that radiation-induced mutations may not necessarily occur randomly, at least in certain cases.     

Mutations induced by X-rays and some chemical reagents changing Drosophila melanogaster life span

It has been shown that most of Drosophila melanogaster mutant lines obtained as a result of X-rays irradiation (XI) as well as of the combined action of XI and some chemical agents are characterized by decreased indexes of average (7-40 %) and maximal (1-35 %) life span. Insertion-excision processes at the instable genes white and cut are among the reasons of decreased vitality and shortened life span in induced mutants. Collection of neurodegenerative mutants has been obtained under the influence of ENU. Fast dying of flies and decreased vitality correlated with time point of neurodegenerations in brain structure.     

Effect of ethanol pretreatment on genetic damage induced by X-rays in Drosophila melanogaster sperm

Drosophila melanogaster males were treated with 96% ethanol for 45 min by means of soaked tissue paper placed at the bottom of regular culture vials before being exposed to 2 krad of X-rays. The use of ethanol was dictated by its high efficiency to scavenge hydroxyl radicals that play a substantial role in the indirect effect of ionizing radiation. The data obtained show that the frequency of sex-linked recessive lethals, reciprocal translocations and chromosome losses induced in postmeiotic cells were not reduced by ethanol pretreatment. Rather, in the combined treatments a significant increase in II-III translocations was observed in sperm. This effect declined in late and mid spermatids. Treatment with ethanol alone did not modify the frequencies of the genetic endpoints tested. It is tentatively suggested that: (i) ethanol or ethanol radicals impair the restitution of broken chromosome ends, thereby increasing the chances for rearrangement formation in the egg, or (ii) ethanol given prior to irradiation acts as a weak dose-modifying factor. If so, a slight increase in the effective dose could have resulted in a detectably higher frequency of translocations whose induction, unlike the other genetic damages investigated that increase linearly with dose, follows the slope of a 2-hit kinetic curve.     

Genetic damage induced by X-rays or neutrons in spermatozoa of Drosophila melanogaster; differential processing in the oocytes of females carrying the DNA-repair-deficient mutants mei-9a and mus-101d1

Radiation-induced premutational lesions on the chromosomes of irradiated mature spertozoa of Drosphila are processed when the sperm nucleus the egg cytoplasm at fertilization. This processing depends on enzymatic repair systems, which are built up in ocytes under the control of the maternal genotype. The present study is concerned with 2 repair-deficient mutants, mei-9^a and mus-101^D1. Irradiated Basc males were crossed to homozygous mei-9^a or mus-101^D1 females, or to repair-proficient control females. The frequencies of recovered sex-link recessive lethal mutations and of II–III translocations were used to assess the effects of impaired maternal repair. Neutrons, as a densely ionizing radiation, and X-rays as a sparsely ionizing one, were used to induce the premutational lesions.The question being asked was whether different radiation qualities cause specific types of lesion that are processed differentially under conditions of impaired maternal repair. The results indicate that this may be so. In comparison with the control, with repair-proficient females, all major effects caused by impaired maternal repair led to frequency reductions in the recovery of lethals and translocations. These reductions in yield were pronounced in all neutron experiments, whereby mus-101^D1 had a stronger effect than mei-9^a. Two possible explanations are considered. The first is based on the idea that specific lesions are processed in a specific way, resulting in a specific mutational end-product, which may not be recovered when repair is impaired. The second is based on the notion that energy deposition in cells exposed to neutrons is not uniform, which leads to clustered damage. Impaired repair may select againts multiply damaged cells much more powerfully than normal repair. Consequently, the surviving fraction of cells is likely to have received less than the average dose. With X-rays, no or only spurious effects of the repair-defective mutants were detected, except in the following case: recovery of translocations (but not of lethals) was strongly reduced when irradiated males were crossed to mus-101^D1 females. It is assumed that mus-101^D1 is defective in repair of DNA double-strand damage, and that the formation of translocations may depend particularly on this repair function.     

Transposition and reversion of mutations induced in Drosophila by viral DNA

Injection of solutions of highly polymerized DNA isolated from nuclear polyhedrosis virus of Galleria mellonella into adult males induced with a considerable frequency visible mutations, two of which were studied in detail. They were detected in about 30 000 flies in the progeny of treated males. Much less than Notched-wings much greater than (Ndw, chromosome 3, location 87.9, dominant) independently arose 12 times, much less than thickened-veins much greater than (thi, chromosome 2, location 71.4, recessive) independently arose 7 times. No mutations were detected in the control of the same size. It was found that both Ndw and thi mutations gave frequent transpositions and reversions in mature, immature germ cells and in somatic cells, in latter cases leading to mosaicism. These results demonstrate for the first time that mutations induced by exogenous DNA are capable of transposition and reversion.     

Induction of DNA double strand breaks by arsenite: comparative studies with DNA breaks induced by X-rays

Chinese hamster ovary (CHO-K1) cell line and two of its DNA double strand break (DSB) repair deficient mutant cell lines, xrs-5 (Ku80 mutant) and irs-20 (DNA-PKcs mutant), were treated with various concentrations of sodium arsenite for 2.5h, and the colony forming abilities were studied. The wild type cells showed the highest cell survival, while xrs-5 cells showed the lowest survival, and irs-20 cells had an intermediate survival. These results are very similar to the cell survival curves induced by X-rays in these three cell lines. Our data also show the dose dependent induction of DNA-DSBs in these cell lines exposed to arsenite. However, in order to obtain a similar cell survival in wild type cells, twice as many DNA-DSBs are necessary with arsenite exposure when compared with X-rays, suggesting that the types of DNA lesions leading to DSB induced by arsenite are different from those by X-rays. Based on these data, further mechanistic investigations including the involvement of DNA-DSB repair proteins are warranted in the recovery process from arsenic (As) exposure.     

Cell-stage-specific enhancement by caffeine of the frequency of chromatid aberrations induced by X-rays in neural ganglia of Drosophila melanogaster

Caffeine (10(-2) M) induced a high level of chromatid aberrations in neural ganglia of third-instar larvae of Drosophila melanogaster only when it was added to cells in late G2 and mitotic prophase. No aberrations were observed after treatment in late S--middle G2 or C-mitosis. We observed that, in these stages, caffeine strongly increased X-ray-induced damage (500 R). This potentiation was quantitatively similar. But it involved all types of aberration after treatment in C-mitosis, and essentially isochromatid deletions and chromatid exchanges after treatment in S--G2. Some hypotheses are put forth to explain the possible mechanism of action of caffeine in the potentiation of X-ray-induced damage.     

Mitochondrial DNA content of mature spermatozoa and oocytes in the genetic model Drosophila

Although crucial to the success of fertilization and embryogenesis, little is known about the mitochondrial DNA (mtDNA) content of mature spermatozoa and oocytes across taxa and across different fertilization systems. Oocytes are assumed to hold a large population of mtDNAs that populate emerging cells during early embryogenesis, whereas spermatozoa harbor only a limited pool of mtDNAs that is believed to sustain functionality but fails to contribute paternal mtDNA to the zygote. Recent work suggests that mature sperm of the genetic model Drosophila melanogaster lack mtDNA, questioning the significance of zygotic mechanisms for the selective elimination of paternal mtDNA and their necessity for fertilization success. This finding further contradicts previous observations of the inheritance of paternal mtDNA in drosophilids. Using quantitative polymerase chain reaction, we estimate the mtDNA content of several laboratory strains of D. melanogaster and D. simulans to shed light on this discrepancy and to describe the mitochondrial/mtDNA load of gametes within this system. These measurements led to an average estimate of 22.91±4.61 mtDNA molecules/copies per spermatozoon across both species and to 1.07E+07±2.71E+06 molecules/copies per oocyte for D. simulans. As a consequence, the ratio of paternal and maternal mtDNA in the zygote was estimated at 1:4.65E+05.