Mutagenic effects of some water-soluble metal compounds in a somatic eye-color test system in Drosophila melanogaster

Nickel, cadmium, lead, arsenic, manganese and chromium salts as well as MeHgOH were screened for mutagenicity, using a sensitive somatic eye-color test system in Drosophila melanogaster. The test is based on the insertion of a mobile element which causes instability in the white locus that is somatically enhanced by mutagens. This white locus expression is combined with a mutation, zeste, in another gene, to produce a light yellow eye color. Larval feeding with mutagens causes somatic mutations in the eye imaginal disc cells that develop into easily detectable red spots in the yellow eyes of adult males. Survival tests showed large differences in the toxicity of different metals, but only hexavalent chromium increased the frequency of somatic mutations above the control level. When combined treatments were carried out with MMS and various metals, sodium arsenite caused a reduction of the MMS-induced mutation frequency while methylmercury increased the frequency of somatic spots.     

Somatic cell mutagenesis in Drosophila: recovery of genetic damage in relation to the types of DNA lesions induced in mutationally unstable and stable X-chromosomes

This paper reports the results of a study on the genotoxic activities of 12 mutagens and clastogens of widely differing mode of action in somatic cells in vivo, i.e., in the eye primordia of Drosophila larvae. After emergence, adult flies were monitored for aberrantly colored sectors in the compound eyes of the following genotypes: UZ males and females (zeste) carrying a genetically unstable transposable element, SZ males and females (zeste) carrying a partial duplication of the w+ locus plus a transposon insert, white-coral/white (wco/w) females, w+/w females and w+ males. The UZ and SZ marker sets make it possible to monitor shifts from zeste to red (scored as mosaic red spots, RS) and for loss of the white locus (light spots, LS). wco/w+ females were scored for mosaic twin spots (TS) and LS, w+ genotypes for just LS. The genotoxins analyzed were methyl methanesulfonate (MMS), dimethyl sulfate (DMS) and ethylnitrosourea (ENU) (alkylating), adriamycin (AM) and daunomycin (DM) (intercalating), Trenimon, Thio-TEPA and cisplatin (DDP) (cross-linking), bleomycin (strand-breaking), 7,12-dimethylbenz[a]anthracene (DMBA) and 9,10-dimethylanthracene (DA) (bulky monoadducts) and cytosine arabinofuranoside (inhibition of DNA synthesis). The relative mutabilities with frequencies of mosaic light spots (LS) in w+/w female as the standard (relative mutability = 1) vs. genotypes UZ (RS in male) vs. SZ (RS in male) vs. w+ (LS in male) were 1:0.6:0.2:0.3 for MMS, 1:0.09:0.05:0.7 for DDP, and 1:1.6:0.2:1.0 for ENU, ENU showed exceptional behavior in that it was the only compound for which mutational response, measured by the induction of red spots, was highest with the UZ marker set. Occurrence of large light spots (LS) in male but not in female genotypes was negatively correlated with efficiency of agents for chromosomal damage, suggesting that in the hemizygous condition, as in males, selection of damaged cells and mitotic delay may have played a significant role. In general, the results indicate that there is no association between the ability of an agent to act as a clastogen and the recovery of aberrant (red spots) sectors in either the UZ or the SZ strain, and of single light spots (LS) in w+, UZ and SZ males. The possibility is considered that the process causing the genetic instability in the UZ strain is under genetic control, and that strong point mutagens such as ENU through efficient gene mutation induction can interfere with it.     

Genetic instability in Drosophila melanogaster

Summary An unstable long tandem duplication which includes the white locus twice, marked with w ^sp in the left and w ^17G in the right locus, when kept in males has been found to produce red-eyed sons which have lost the long duplication and with it the w ^sp and w ^17G mutants. Such exceptions were produced also when w ^17G had been exchanged for w ^a.Stocks originating from these exceptions are unstable, producing: 1) zeste males, also unstable, 2) w ^- deletions, stable, 3) transpositions of the white locus to sites in other chromosomes.The instability is interpreted as the effect of an IS element, within or adjacent to the white locus, which is supposed to retain a duplication of the proximal zeste interacting part of this locus. According to the orientation of the IS element the duplicated part can be active or inactive, giving a zeste or red eye phenotype.The frequency of exceptional offspring after X-ray treatment of the red and zeste unstable stocks have been compared to stable stocks with corresponding genotypes.     

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.     

Effects of DNA-repair-deficient mutants on somatic and germ line mutagenesis in the UZ system in Drosophila melanogaster

To analyze the underlying mechanisms of the UZ system in Drosophila melanogaster, i.e., the unstable white locus with an IS element included originally described by Rasmuson and Green (1974), the repair deficient mutants mei-9b and mei-4lD5 and the meiotic mutant mei-2l8 were introduced into X-chromosomes containing the UZ system. These strains were submitted to larval feeding of MMS to analyze differences occurring in mutation rate and survival. The mei-9b and mei-4l strains were markedly sensitive to MMS treatment, while mei-2l8 did not affect survival. Only the mutant mei-4l, which is lacking in post-replication repair, affected the somatic mutation rate of the UZ system, decreasing it by 50%. The spontaneous germ line mutation rate of UZ, on the other hand, was increased by introducing mei-4l or mei-9b, possibly as a result of the high frequency of unrepaired spontaneous chromosome breaks that occur in these mutants.     

The unstable wDZL mutation of Drosophila is caused by a 13 kilobase insertion that is imprecisely excised in phenotypic revertants

We have analyzed the lesion in wDZL, a genetically unstable mutant allele of the eye color locus, white, of Drosophila melanogaster. We have cloned the DNA of the white locus region of flies carrying the wDZL allele and find a 13 kilobase insertion not present in the wild-type at the corresponding location. In 12 independent cases examined, reversion to a wild-type eye color phenotype correlates with the excision of a portion of this 13 kilobase insertion, indicating that the insertion is the cause of the mutation. The portion of the insertion that is excised in these eye color revertants is heterogeneous in size but appears to include the central 6 kilobases of the insertion in all cases. Many of these eye color revertants continue to undergo mutation at the white locus, indicating that the residual portion of the insertion in these revertants is sufficient to promote mutations.     

The product of the Drosophila zeste gene binds to specific DNA sequences in white and Ubx.

Three different segments of the zeste coding sequence were inserted in an expression vector and antibodies were raised against the resulting zeste-beta galactosidase hybrid proteins. The antibodies were used to analyse the zeste protein produced in bacteria from a different expression vector containing the entire zeste coding region. The major products made in bacteria as well as the products of in vitro translation of zeste RNA migrate anomalously upon SDS--acrylamide gel electrophoresis. Specific DNA fragments from the white and Ubx gene co-immunoprecipitate with zeste protein. At least two independent zeste binding sites are found in a 250-bp interval of the white regulatory region that contains also the sites of wsp mutations, which are known to be deficient in zeste interaction.     

Genetic activities of 4-chloromethylbiphenyl,the 4-hydroxy derivative and benzyl chloride in the soma and germ line of Drosophila melanogaster

The genetic activities of 4CMB, 4HMB and BC were assayed as regards the induction of somatic alterations in gene expression on an unstable w⁺ locus with an intragenic TE and all the simultaneously induced germinal mutations on the X-chromosome carrying this locus. The compounds were applied topically in solution at equimolar doses on late embryos and newly hatched larvae. The somatic events were scored as aberrantly pigmented eye sectors in the emerging adult males and the germinal mutations in their F₂ progeny, according to the Muller-5 technique.The somatic events were expressed as red or white mosaic eye sectors; the former could be an outcome of the repression or deletion of the zeste-regulatory proximal subunits of w⁺ locus, and the latter generally attributable to deletions (w⁻) within its structural part. All 3 compounds were effective in the induction of red sectors at the higher tested doses (0.5–2.0 mM) and the level of this activity was virtually the same for 4CMB and 4HMB, but was 2-fold higher for BC. In contrast, the frequencies of the simultaneously scored white sectors were not raised significantly above the controls with 4CMB, but showed decisive increases above this level with both 4HMB and BC.The germinal X-chromosome mutations (recessive lethals and visibles) were only induced at the highest tested dose (2.0 mM), and their frequencies were virtually the same for all 3 compounds reaching a common level of about 0.6%, which is some 3-fold the normal control level for the test system. Specific-locus mutability at the TE w⁺ was suggestively positive only with BC.     

Germ line and somatic instability of a white mutation in Drosophila mauritiana due to a transposable genetic element

A spontaneous white mutation recovered in Drosophila mauritiana is unstable and reverts to normal eye color at a frequency greater than 4 per 1,000 X-chromosomes. Germ line reversion occurs at a high rate in D. mauritiana males and in interspecific hybrid females, while the rate is depressed in D. mauritiana females. These events are not restricted to the germ line, as cases of variegated patterns of eye pigmentation, indicating somatic reversion, are recovered at a frequency comparable to that of the male germ line reversion rate. Germ line reversion events are genetically stable, while the somatic variegation patterns are not heritable. The patterns of eye pigment variegation produced suggests that reversion events are occurring throughout development. Whole genome DNA digests blotted and probed with the cloned D. melanogaster white gene indicate that this unstable white mutation in D. mauritiana is associated with an insertion of DNA that is lost upon reversion to wild type, indicating that this DNA insert is in fact a transposable element.     

Genetics of an Unstable White Mutant in Drosophila Simulans: Reversion, Suppression and Somatic Instability

A spontaneous white mutation, white-milky (wmky) of Drosophila simulans is moderately unstable and is associated with a 16-kb long DNA insertion into the white gene. wmky, which is an unstable mutation found in D. simulans, has been genetically analyzed. Among nine spontaneous, partial reversions toward wild type, five were white locus mutations. They are phenotypically different from each other and three show eye color sexual dimorphism indicating a failure of the dosage compensation mechanism. Two w locus mutations whose eye color appeared identical between males and females were also isolated. Of the other back-mutants, three were associated with a recessive suppressor of wmky and one was a semidominant suppressor. These suppressor loci are located on the third chromosome at map positions about 90 and 120, respectively. The suppressor mutations demonstrate specific effects on w locus mutations derived from wmky which lack in the gene dosage compensation. Somatic instability was detected at the frequency of 5.6 X 10(-4) in wmky flies heterozygous for the recessive suppressor and the frequency was increased 10-fold when the suppressor mutation was placed in a different genetic background.     

A dosage-sensitive modifier of retrotransposon-induced alleles of the Drosophila white locus.

The apricot allele of the white locus results from the insertion of the retrotransposon copia. Mutations in a newly discovered locus, the Darkener-of-apricot (Doa), suppress wa and some of its revertants. Of 44 other white alleles tested, only wsp55 is affected by Doa, although, in contrast, it is enhanced by Doa mutations. The Doa locus modulates wa and wsp55 expression as a function of its own dosage. Mutations in Doa are dominant suppressors or enhancers and are recessive lethals. Rare Doa mutant homozygotes escaping lethality demonstrate extreme phenotypic suppression of wa and enhancement of wsp55. RNA from wa is substantially wild-type in structure in escapers, although reduced in quantity.     

A Genetic Analysis of the Suppressor 2 of Zeste Complex of Drosophila Melanogaster

The zeste(1) (z(1)) mutation of Drosophila melanogaster produces a mutant yellow eye color instead of the wild-type red. Genetic and molecular data suggest that z(1) achieves this change by altering expression of the wild-type white gene in a manner that exhibits transvection effects. There exist suppressor and enhancer mutations that modify the z(1) eye color, and this paper summarizes our studies of those belonging to the Suppressor 2 of zeste complex [Su(z)2-C]. The Su(z)2-C consists of at least three subregions called Psc (Posterior sex combs), Su(z)2 and Su(z)2D (Distal). The products of these subregions are proposed to act at the level of chromatin. Complementation analyses predict that the products are functionally similar and interacting. The alleles of Psc define two overlapping phenotypic classes, the hopeful and hapless. The distinctions between these two classes and the intragenic complementation seen among some of the Psc alleles are consistent with a multidomain structure for the product of Psc. Psc is a member of the homeotic Polycomb group of genes. A general discussion of the Polycomb and trithorax group of genes, position-effect variegation, transvection, chromosome pairing and chromatin structure is presented.     

Homeosis and the interaction of zeste and white in Drosophila

Summary Transvection effects in Drosophila melanogaster suggest a form of gene modulation that is responsive to the proximity of homologous genes. These effects have been well characterized at bithorax and decapentaplegic, and in the interaction between the zeste and white genes. The mechanistic basis for transvection is not known. As part of a genetic analysis of transvection, a study is being made of a class of mutation defined as modifiers of the eye color resulting from the interaction of zeste and white. This report details the observations that several of these mutations also have homeotic effects.     

Aneuploidy in Drosophila, I. Genetic test systems in the female Drosophila melanogaster for the rapid detection of chemically induced chromosome gain and chromosome loss

An account is provided of two genetic schemes in the Drosophila melanogaster female designed as rapid detectors of chemically induced aneuploidy, including both chromosome gain and chromosome loss. One scheme is referred to as FIX, in which the female carried free (heterozygously) inverted X (chromosomes) and the other, ZESTE, where females do not carry inversions and the X-linked sexually dimorphic zeste mutation plays the key role in the detection of aneuploid offspring. The principle attribute of the FIX system is that all euploid offspring are wild-type for body and eye color whereas aneuploid females have a yellow body and aneuploid males white eyes; int he ZESTE system all euploid individuals are wild-type for eye color, aneuploid females possess zeste-colored eyes and aneuploid males white eyes. In addition induced polyploidies (2X:2A gametes) appear as yellow and zeste male intersexes in the FIX and ZESTE systems, respectively. In this way all aneuploids are recognized immediately. Consequently, detection of compounds with weak effects requiring large sample sizes may be made in a fraction of the time associated with more traditional schemes for aneuploidy detection in Drosophila.     

Identification of Mutations in Three Genes That Interact with Zeste in the Control of White Gene Expression in Drosophila Melanogaster

Three previously described genes, enhancer of yellow, 1, 2 and 3, are shown to cooperate with the zeste gene in the control of white gene expression. The mutations e(y)1(u1), e(y)3(u1), and to a lesser extent e(y)2(u1), enhance the effect of the zeste null allele z(v77h). Different combinations of e(y)1(u1), e(y)2(u1) and e(y)3(u1) mutations with several other z alleles also enhance the white mutant phenotype, but only to levels characteristic of white alleles containing a deletion of the upstream eye enhancer. Loss of zeste protein binding sites from the white locus does not eliminate the effect of e(y)1(u1) and e(y)3(u1) mutations, suggesting that the products of these genes interact with some other nucleotide sequences. Combinations of either e(y)1(u1) or e(y)2(u1) mutations with e(y)3(u1) are lethal. The products of these three genes may represent, together with zeste, a group of proteins involved in the organization of long-distance interactions between DNA sequences.