Genotoxicity of 5-azacytidine in somatic cells of Drosophila

The newly developed somatic mutation and recombination test, utilizing the wing-hair mutations mwh and flr3, was used to evaluate the genotoxicity of the base analog 5-azacytidine in larvae of Drosophila melanogaster. Third instar larvae were fed media wetted with various concentrations of the compound, and wings of surviving adults were removed and scored for the presence of clones of cells possessing malformed hairs. Wings of exposed flies trans-dihybrid for mwh and flr3 had significantly increased frequencies of twin spots, small single spots and large single spots. Significant linear regression of twin-spot frequencies upon concentration was also obtained. Induction of twin spots by 5-azacytidine unambiguously demonstrates its recombinogenic activity in somatic cells of Drosophila. Significantly increased frequencies of large single spots on wings of inversion-heterozygous flies were also observed and suggest that 5-azacytidine may also be inducing somatic gene mutations (or deletions).     

Modifications of the effect of bleomycin in the somatic mutation and recombination test in Drosophila melanogaster

Exposure to oxygen has been implicated as an important mechanism of mutations, cancer and aging. Most data supporting this notion have been obtained in vitro, but the elaborate defense systems against oxygen stress in aerobic organisms make it difficult to extrapolate in vitro data to in vivo conditions. In the present investigation the somatic mutation and recombination test (SMART) in Drosophila with the wing spot system (Graf et al., 1984) has been used as an in vivo system to study the effect of oxygen radicals generated by bleomycin (BLM). BLM causes a dose-related increase of wing spots and this effect drastically increases by increasing oxygen in the atmosphere to 70%. Data from treatment of larvae of different ages, as well as post-treatment with oxygen, indicate that BLM can persist, presumably intercalated in DNA, and subsequently be activated by oxygen to generate free radicals. By the use of inversion heterozygosity, which eliminates somatic recombination, it was shown that the majority of wing spots induced by BLM emanate from somatic recombination. A small number of flies deviated from the rest by an abnormally high frequency of BLM-induced wing spots. Preliminary results from a selection of such flies indicate that this extreme response to BLM is genetically determined. Treatment with BLM was also combined with agents known to interfere with the defense mechanisms against radicals or function as radical scavengers. Only ascorbic acid cotreatment had a modifying effect on BLM mutagenicity. The other agents did not alter or at most had a marginal effect on BLM mutagenicity. These data indicate that the defense mechanisms do not constitute a limiting factor in this case. BLM intercalates between DNA bases, presumably giving little time and opportunity for modifying agents to react with radicals generated in direct contact with the gene targets. No effect of BLM was observed on male germ cells by measuring loss and non-disjunction of ring-X/Y, neither in air nor in a 70% oxygen atmosphere.     

Inhalation of methyl bromide gas induces mitotic recombination in somatic cells of Drosophila melanogaster

The fumigant methyl bromide was evaluated for genotoxicity in the somatic wing-spot assay of Drosophila melanogaster. Third instar larvae trans-dihybrid for mwh and flr3 were exposed to varying concentrations (0-16 mg/l) of the gas for 1 h. Following this exposure via inhalation, the larvae were placed into vials containing Instant Medium. 7 days after the exposure, the adult flies in the vials were collected, and their wings were scored under 400X magnification for the presence of clones of cells possessing malformed wing-hairs. Such clones appeared as mwh-flr3 twin spots and single spots of either mwh or flr3 phenotype. Exposure to methyl bromide was found to result in the positive induction of both twin spots and large (greater than 2 cells) single spots. For each endpoint, a significant exponential association was obtained between concentration and frequency of spots per wing. Methyl bromide was found to be a negative inducer of small (1-2 cells) single spots at all concentrations except 16 mg/l where a positive effect was observed. Because twin spots arise exclusively from mitotic recombination, methyl bromide was identified as having recombinogenic activity in the somatic tissue of Drosophila larvae.     

Genetic effects of cosmic radiation in Drosophila melanogaster]

To examine possible effects of space radiation on living organism, we have analyzedtwo types of mutations, sex-linked recessive lethal mutations and somatic mutations, in fruit fly of the species Drosophila melanogaster. Drosophila strains used were wild type strains and a radiation-sensitive strain mei-41. Two different developmental stages of samples were sent into space; young adult males to analyze sex-linked recessive lethal mutations and about 30hr-old larvae to detect somatic mutations in wing epidermal cells. For wild type and mei-41 strains each, about 200 adult male flies and about 6,000 larvae were loaded on space shuttle Endeavour. The male flies returned from space were mated to virgin female flies of a tester strain, and the presence of the lethal mutations was analyzed at F2 generation. The frequencies of sex-linked recessive lethal mutations in flight groups were 2 and 3 times higher for wild type Canton-S and mei-4 1, respectively, than those in ground control groups. Most larvae sent to space emerged as adult flies within about 10 days after the landing. The presence of wing-hair somatic mutations, which give morphological change in hairs growing on the surface of wing epidermal cells, was analyzed under microscope. In wild type strain Muller-5, the frequency of wing hair mutant spots in flight group was about 1.5-fold higher than that in ground control, and in Canton-S-derived wild type strain the frequencies were similar between the two groups. By contrast, for mei-41 strain the mutation frequency was lower in flight group than in control group. The observed higher frequency of lethal mutations in the flight group might be due to a possibility that radiation effects on reproductive cells could be greatly enhanced under micro gravity. However, if this would be the case, we do not have appropriate explanation for the apparent absence of such synergistic effects on somatic wing-hair mutation system.     

Genotoxicity evaluation of five tricyclic antidepressants in the wing somatic mutation and recombination test in Drosophila melanogaster

Five tricyclic antidepressants were tested for genotoxicity using the somatic mutation and recombination test (SMART) in wing cells of Drosophila melanogaster. Three-day-old larvae trans-heterozygous for 2 linked recessive wing hair mutants (multiple wing hairs and flare) were fed the test compounds in water mixed with a standard dry food for 48 h. Wings of the emerging adult flies were scored for the presence of spots of mutant cells which can be the consequence of either somatic mutation or mitotic recombination. Desipramine and imipramine were clearly genotoxic at concentrations above 1 mM whereas amitriptyline, nortriptyline and protriptyline were not genotoxic at concentrations up to 100 mM. This seems to implicate the nitrogen atom at position 5 in the 7-membered ring of the tricyclic molecule as being responsible for the genotoxic property of the compounds in Drosophila.     

Malsegregation of chromosomes is not a major source of somatic mosaicism in Drosophila melanogaster

Two genotypes were constructed to determine whether some of the mosaic spots, on which the SMART (somatic mutation and recombination test) procedures are based may arise through malsegregation of the chromosomes. Both arms of the metacentric third chromosomes were labelled with marker mutations, and in this way one- and two-arm events (the former representing rearrangements or point mutations, the latter representing malsegregation) could be recorded separately. Although several hundred clones were identified following exposure of larvae to X-rays, colchicine or vinchicine or vincristine (all known inducers of malsegregation), none arose as a consequence of two-arm events. This suggests that malsegregation of the chromosomes plays little, if any role in the formation of mosaic spots. Instead, the clones develop due to mitotic recombinations, deletions or point mutations.     

Genotoxicity of neutrons in Drosophila melanogaster. Somatic mutation and recombination induced by reactor neutrons

This paper describes the observation of a direct relationship between the absorbed doses of neutrons and the frequencies of somatic mutation and recombination using the wing somatic mutation and recombination test (SMART) of Drosophila melanogaster. This test was used for evaluating the biological effects induced by neutrons from the Triga Mark III reactor of Mexico. Two different reactor power levels were used, 300 and 1000 kW, and two absorbed doses were tested for each power level: 1.6 and 3.2 Gy for 300 kW and 0.84 and 1.7 Gy for 1000 kW. A linear relationship was observed between the absorbed dose and the somatic mutation and recombination frequencies. Furthermore, these frequencies were dependent on larval age: In 96-h-old larvae, the frequencies were increased considerably but the sizes of the spots were smaller than in 72-h-old larvae. The analysis of the balancer-heterozygous progeny showed a linear absorbed dose- response relationship, although the responses were clearly lower than found in the marker-trans-heterozygous flies. Approximately 65% of the genotoxicity observed is due to recombinational events. The results of the study indicate that thermal and fast neutrons are both mutagenic and recombinagenic in the D. melanogaster wing SMART, and that the frequencies are dependent on neutron dose, reactor power, and the age of the treated larvae.     

Somatic mutation in the wings of Drosophila melanogaster females dysgenic due to P elements when reared at 29 degrees C.

The possibility of somatic mobilisation of P elements in Drosophila melanogaster was investigated. Flies, trans-heterozygous for the genetic markers mwh and flr3, were obtained by crossing males containing transposition-competent P elements with females having M cytotype. The hybrid dysgenic flies were reared at 29 degrees C and their wings examined for mutant clones. The frequency of mutant spots found on the wings of the female flies was significantly higher than that of female control flies. We postulate that this increase in frequency may be due to P element mobilisation at high temperature in the wing cells of dysgenic hybrids. This is in direct contrast to the large body of research which indicates that P-transposition-mediated mutation is restricted to the germline.     

Involvement of eddy currents in the mutagenicity of ELF magnetic fields

Possible carcinogenic and/or mutagenic activity of extremely low frequency magnetic fields was examined using somatic mutation and recombination test system of Drosophila melanogaster. An X-linked semi-dominant DNA repair defective mutation mei-41(D5) was introduced into the conventional mwh/flr test system to enhance mutant spot frequency. Virgin females of w mei-41(D5)/FM6; flr/TM6 were crossed with w mei-41(D5)/Y; mwh jv; spa(pol) males. The F(1) third instar larvae were exposed to a 50Hz, 20mT sinusoidal AC magnetic field for 24h. After moulting from pupal cases, their wings were examined under a bright field microscope to detect hair spots with mwh or flr mutant morphology. The exposure caused a statistically significant enhancement in somatic recombination spot frequency. Mutant spots arising due to chromosomal non-disjunction or terminal deletion also increased but the frequency of spots resulting from point mutation was not altered. The enhancement in the recombination spot frequency was suppressed to the control level when a culture medium without electrolytes was used during exposure. When larvae were exposed to a magnetic field in an annular dish, flies from the outer ring showed more mutant spots compared to those from the inner ring. These results suggest that the detected mutagenic activity was that of the induced eddy current, rather than that of the magnetic field itself.     

High recombinagenic activities of three antiviral agents, adenine derivatives, in the Drosophila wing spot test

Three adenine derivatives (R,S)-9-(2,3-dihydroxypropyl)adenin (DHPA), D-eritadine (EA), and 9-(2-phosphonylmethoxyethyl)adenine (PMEA), prospective antiviral drugs, were subjected to genotoxicity analysis using the somatic mutation and recombinatino test in Drosophila melanogaster. All three compounds were found to be very potent inducers of mosaic spots on Drosophila wings in a dose-related fashion. Data obtained in inversion-free flies revealed that the compounds, in particualr DHPA and EA (nucleoside analogues), are highly effective in the induction of mitotic recombination. PMEA, a nucleotide, exhibited a rather different genotoxic profile from those of DHPA and EA, indicating a different mechanism of genetic action of this compound. Of somatic mutations, chromosome aberrations, rather than point mutations seem to play a major role in the genotoxicity of PMEA. In flies carrying an inversion chromosome, which eliminates most products of mitotic recombination, reduced spot frequencies were obtained, which, however, were still unexpectedly high for compounds with strong recombinagenic activities. Most probably, in additino to structural mutations of chromosomes, double mitotic crossing-over and non-reciprocal recombinatino events similar to unequal sister-strand recombination of gene conversion significantly contributed to spot induction in the inversion heterozygous flies. Concerning the mechanism of genotoxic action, we suggest that these adenine derivatives can be incorporated into DNa chains during replication. This would result, via breaks and DNa repair mechanisms, either in various recombination events or in chromosome aberrations.     

Frequency of x-ray induced mitotic recombination in genotypes with different X-Y-combination-chromosomes in Drosophila melanogaster

Summary In first and second instar larvae of Drosophila melanogaster mitotic recombination has been induced by X-rays. Resulting mosaic spots were analysed in the eyes of adult females. The five examined genotypes varied in the combination of different X-chromosomes and in the presence or absence of the duplication Dp(1;3)N ^264-58. X-chromosomes used have been elongated by proximally or distally linked arms of the Y-chromosome. The portion of Y-heterochromatin in the genome is negatively correlated with the frequency of twin mosaic spots (Fig. 1). The frequency of these spots is lower in flies bearing the duplication than in those without the duplication. With respect to the X-chromosome combinations, there are no marked differences in the frequencies of single mosaic spots (Fig. 2); with respect to the duplication they are absent. In the genotype Y ^S X/X.Y ^S prophases of neuroblast mitoses (Fig. 4) show normal pairing of homologous chromosome sections. Reasons for the different spot frequencies are discussed.

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Vorgelegt von E. Hadorn     

Active mariner transposable elements are widespread in natural populations of Drosophila simulans

The occurrence of active, or autonomous, mariner elements was investigated by crossing white-peach mutant Drosophila simulans females with wild-type males from various geographic origins. From a total of 194 experimental crosses only 17 failed to produce progeny with eye mosaicism (MOS, i.e. pigmented spots in otherwise white-peach eyes). Therefore, active mariner elements inducing somatic excision of the copy inserted at the white locus are abundant in all populations sampled. In the experimental crosses the frequency of mosaic offspring ranged from 0 to 100%, showing that the phenotypic expression is highly variable. The MOS phenotype, measured by the number of spots on the eyes, is quite variable within the progeny of single crosses. Although a difference was observed in the average MOS score (percentage of mosaic flies) between northern and southern populations of France, there was no indication of long range variation between geographic populations. Neither was there a systematic difference between recently collected populations and samples kept several years as isofemale lines.     

Reduction of spontaneous somatic mutation frequency by a low-dose X irradiation of Drosophila larvae and possible involvement of DNA single-strand damage repair

The third instar larvae of Drosophila were irradiated with X rays, and the somatic mutation frequency in their wings was measured after their eclosion. In the flies with normal DNA repair and apoptosis functions, 0.2 Gy irradiation at 0.05 Gy/min reduced the frequency of the so-called small spot (mutant cell clone with reduced reproductive activity) compared with that in the sham-irradiated flies. When apoptosis was suppressed using the baculovirus p35 gene, the small spot frequency increased four times in the sham-irradiated control group, but the reduction by the 0.2-Gy irradiation was still evident. In a non-homologous end joining-deficient mutant, the small spot frequency was also reduced by 0.2 Gy radiation. In a mutant deficient in single-strand break repair, no reduction in the small spot frequency by 0.2 Gy radiation was observed, and the small spot frequency increased with the radiation dose. Large spot (mutant cell clone with normal reproductive activity) frequency was not affected by suppression of apoptosis and increased monotonically with radiation dose in wild-type larvae and in mutants for single- or double-strand break repair. It is hypothesized that some of the small spots resulted from single-strand damage and, in wild-type larvae, 0.2 Gy radiation activated the normal single-strand break repair gene, which reduced the background somatic mutation frequency.     

Effect of organic tomato (Lycopersicon esculentum) extract on the genotoxicity of doxorubicin in the Drosophila wing spot test

The consumption of organic tomatoes (ORTs) reduces the risk of harmful effects to humans and the environment caused by exposure to toxic agrochemicals. In this study, we used the somatic mutation and recombination test (SMART) of wing spots in Drosophila melanogaster to evaluate the genotoxicity of ORT and the effect of cotreatment with ORT on the genotoxicity of Doxorubicin^® (DXR, a cancer chemotherapeutic agent) that is mediated by free radical formation. Standard (ST) cross larvae were treated chronically with solutions containing 25%, 50% or 100% of an aqueous extract of ORT, in the absence and presence of DXR (0.125 mg/mL), and the number of mutant spots on the wings of emergent flies was counted. ORT alone was not genotoxic but enhanced the toxicity of DXR when administered concomitantly with DXR. The ORT-enhanced frequency of spots induced by DXR may have resulted from the interaction of ORT with the enzymatic systems that catalyze the metabolic detoxification of this drug.     

Studies on mutagen-sensitive strains of Drosophila melanogaster. II. Detection of qualitative differences between genetic damage induced by X-irradiation of mature spermatozoa in oxygenated and anoxic atmospheres through the use of the repair-deficient mutant mei-9a

Muller-5 males were irradiated with X-rays in nitrogen, in air or in oxygen (followed by nitrogen or oxygen post-treatments in the nitrogen and oxygen series) and were mated to females of a repair-proficient strain (mei+) or to those of a strain known to be deficient in excision repair of UV damage (in somatic cells). The latter strain, designated as mei-9a, is also known to be sensitive, in the larval stages, to the killing effects of UV, X-rays and to a number of chemical mutagens. The frequencies of sex-linked recessive lethals and autosomal translocations induced in the spermatozoa of males were determined and compared. The frequencies of sex-linked recessive lethals in the mei-9 control groups were consistently higher than in the mei+ groups. Irradiation in air or in nitrogen led to significantly higher yields of recessive lethals when the irradiated males were mated to mei-9 females, whereas, after irradiation in oxygen, the yields were similar with both kinds of female. No significant differences in the frequencies of reciprocal translocations were observed between the mei+ and mei-9 groups after irradiation of the males in nitrogen, in air or in oxygen. Likewise, no differential effects of the contrasting post-treatments (nitrogen versus oxygen), either for recessive lethals or for translocations, could be discerned. These results are considered to support the notion that the kinds of genetic damage induced in mature spermatozoa in air or in nitrogen are qualitatively similar (at least with respect to the component(s) that lead to the production of recessive lethal mutations), but clearly different when induced in an oxygen atmosphere. The enhanced yields of recessive lethals with mei-9 females (after irradiation of the males either in air or in nitrogen) has been interpreted on the assumption that the mei-9 mutant is also deficient for the repair of X-ray-induced, recessive lethal-generating premutational lesions. Possible reasons for the lack of differences between the mei+ and mei-9 groups with respect to translocation yields and for the absence of measurable differences in response between the contrasting post-treatments (after irradiation of the males in nitrogen) are discussed.     

Role of propionic acid, yeasts and ethyl alcohol in regulating the activity of H-factor in Drosophila simulans]

Effects of yeast, propionic acid and ethanol on the activity of H-factor, which sharply increases the frequency of somatic recombination in X-chromosomes of dorsal prothoracal disc cells in Drosophila simulans are studied. The frequency of yellow and singed mosaic spots in heterozygous yw ++/++sn1vHD. melanogaster females, inherited H-factor from the father (the stock sn1v) is estimated. The results of the varience analysis have shown that yeast and propionic acid regulate the activity of H-factor in cells of dorsal prothoracal disc, the interaction of yeast and propionic acid being also observed. Yeasts (or some unknown product of their metabolism) are the activator of H-factor; thus, when larvae eat much yeast, the frequency of yellow and singed mosaic spots in humeral region becomes high. A decrease of mosaic spot frequency under the increase of propionic acid content in nutrition medium is a result of the inhibitory effect of propionic acid on the yeast growth, but not of the direct repression of H-factor activity. So, propionic acid may be considered as a regulator of the second order. Ethanol does not activate H-factor. Changes in the content of yeast and propionic acid in nutrition medium do not affect the frequency of yellow and singed mosaic spots in other regions of D. simulans body, except humeral.     

Genotoxicity testing of five herbicides in the Drosophila wing spot test

Four triazine herbicides: amitrole, metribuzin, prometryn and terbutryn, and the bipyridal compound diquat dibromide have been evaluated for genotoxicity in the wing somatic mutation and recombination test of Drosophila melanogaster, following standard procedures. Third-instar larvae trans-heterozygous for the third chromosome recessive markers multiple wing hairs (mwh) and flare-3 (flr(3)) were chronically fed with different concentrations of the test compounds. Feeding ended with pupation of the surviving larvae. Genetic changes induced in somatic cells of the wing's imaginal discs lead to the formation of mutant clones on the wing blade. Point mutation, chromosome breakage and mitotic recombination produce single spots; while twin spots are produced only by mitotic recombination. Exposure to 0.5 mM and 1 mM of amitrole clearly increased the frequency of small single, large single and total spots. Terbutryn, at the concentration of 5 mM, induced a slight increase in the frequency of small single and total spots, but this result could be false positive. The other three herbicides tested did not show any genotoxic effect. When heterozygous larvae for mwh and the multiple inverted TM3 balancer chromosomes were treated, significant increases in the frequency of mutant spots were only detected for amitrole. The observed spot frequencies were lower than those found in mwh/flr(3)50%) of the total spot induction was due to mitotic recombination.     

Genotoxicity of ziram established through wing, eye and female germ-line mosaic assays and the sex-linked recessive lethal test in Drosophila melanogaster

The genotoxicity of ziram (zinc-dimethyl dithiocarbamate, CAS No. 137-30-4), a carbamate fungicide, is studied in the wing, eye and female germ-line mosaic assays and the sex-linked recessive lethal test in Drosophila melanogaster. First-, second- and third-instar larvae, carrying suitable recessive genetic markers on their first and third chromosomes, were exposed to ziram. Wings and eyes of adults were screened for the induction of mosaic spots and the eggs laid by adult females for germ-line mosaicism. The Basc method was used to detect sex-linked recessive lethals. Ziram is genotoxic to the somatic and germ cells of Drosophila melanogaster.     

Mechanistic and methodological aspects of chemically-induced somatic mutation and recombination in Drosophila melanogaster

This study presents the analysis of chemically-induced somatic mutations and chromosomal damage in the eye imaginal discs of Drosophila larvae, assayed later as twin (TS) and single light (LS) mosaic spots in the adult eyes. Regarding the question as to what kind of DNA alterations contribute to somatic cell mutagenicity, the approach followed here has been to investigate the possible differences in response between male (hemizygous for an X) and female (homozygous) larvae, rod-X/rod-X versus ring-X/rod-X genotypes and inversion-heterozygotes versus genotypes not carrying an inversion. The systems chosen for this analysis were the white-coral/white (wco/w) and the white+/white (w+/w) eye mosaic system. The principle findings with 12 mutagens of different modes of action are as follows: (1) At least 98% of all TS and LS induced by cisplatin (DDP) in wco/w female larvae and about 95% of those by formaldehyde (FA) appear as the result of recombinogenic activity between the two homologous X-chromosomes. The corresponding estimates for MMS, EMS and ENU are 81%, 73% and 61%, respectively. (2) The long scS1L sc8R inversion, which also contains In(1)dl-49, suppresses induction of TS to 83-93%. There was also a sharp decline in the frequency of LS in inversion heterozygotes for DDP (91%), FA (86%), MMS (52%) and EMS (47%). (3) Ethylnitrosourea (ENU) was the mutagen for which introduction of the inverted chromosome reduced only slightly (23%) the frequency of LS, indicating that the majority of them were somatic mutations (and deletions) at the white locus. (4) In w/RX females heterozygous for a ring-X chromosome, the frequency of LS was only approximately one tenth of that of the control (w+/w) group, after exposure to MMS or DDP. The explanation is that exchange processes involving the ring frequently lead to genetic imbalance with subsequent cell killing.     

Genetic mosaic analysis of the equatorial-less mutation in Drosophila mezunogaster

eql (equatorial-less) is a recessive lethal mutation on the second chromosome of Drosophila melanogasfer. J. Campos-Ortega found that eql clones in somatic mosaic flies have reduced numbers of photoreceptor cells, and he suggested that only the R1, R6, and R7 photoreceptor cells were missing in this mutant. These photoreceptor cells help to define the inverted orientation of ommatidial facets along the equatorial midline of the fly eye, hence the mutation was named “equatorial-less”. We have conducted a detailed analysis of the eql mutation, by serial section reconstruction of eql clones marked with bw or w^? in somatic mosaic flies. We found that all photoreceptor cell types (Rl–R8) could be deleted by the eql mutation, and in rare cases the number of photoreceptor cells was increased. The apparent lack of photoreceptor cell type specificity was confirmed by our analysis of genetically mosaic facets, which indicated that no single photoreceptor cell, or subset of photoreceptor cells, was uniquely required to express eql Rather, eql appears to function in all photoreceptor cells, and possibly in all eye precursor cells. The distribution of photoreceptor cell numbers in w eql facets was consistent with the hypothesis that each photoreceptor cell was deleted independently of the others. The eql gene is located on the right arm of chromosome 2 at map location 2 ? 104.5 ± 0.7 and lies between the polytene chromosome bands 59D8 and 60A7. © 1995 Wiley-Liss, Inc.