Åsa Rasmuson

Genetic instability in Drosophila melanogaster

SummaryAn unstable long tandem duplication which includes the white locus twice, marked with wsp in the left and w17G 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 wsp and w17G mutants. Such exceptions were produced also when w17G had been exchanged for wa.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.

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.

The use of a mutationally unstable X-chromosome in Drosophila melanogaster for mutagenicity testing.

Somatic eye-colour mutations in an unstable genetic system, caused by a transposable element in the white locus of the X-chromosome in Drosophila melanogaster, is suggested as an assay system for mutagenicity testing. The system is evaluated by comparison with a corresponding system in a stable X-chromosome. Its sensitivity is confirmed with X-ray and EMS treatment, and it is found to be confined to the specific segment of the X-chromosome where the transposable element is localized.

A negative test for mutagenic action of microwave radiation in Drosophila melanogaster.

Microwave radiation (2450 MHz CW) was tested for mutagenicity in Drosophila melanogaster. Embryos in water were exposed to the electromagnetic field with a mean specific absorption rate of 100 W/kg. A sensitive somatic test system was used, in which mutagenicity was measured as the frequency of somatic mutations for eye pigmentation. With the test system used, microwaves did not show any mutagenic activity.

Comparative studies of the induction of somatic eye-color mutations in an unstable strain of Drosophila melanogaster by MMS and X-rays at different developmental stages.

An unstable white locus in Drosophila melanogaster originally described by Rasmuson and Green (1974) and further by Rasmuson et al. (1978, 1980) contains an IS element. This constellation interacts with the zeste mutation and forms a mutationally unstable system that is sensitive to a variety of mutagens. Mutational shifts between zeste and wild-type eye color as well as deletions and transpositions of the white locus are frequently occurring in the unstable X-chromosome in germ line and in somatic tissue. Germinal mutations from zeste to wild-type eye color are associated with an insertion of a piece of DNA, proximal to the wsp site, and the shifts from red to zeste are caused by an excision of the same piece (Rasmuson, in preparation). Mutations to pigmentless phenotype are interpreted as deletions of the white locus, while they always are irreversible and show non-complementation with wsp. The somatic system can be used as a screening test for potential mutagens, described by Rasmuson et al. (1984). This survey is an attempt to correlate the size of the mutated area of the eyes with the age of the larvae at mutagen treatment. X-Rays and MMS were used to give an indication of the mechanism of the instability, according to the different kinds of DNA damage induced. The results show that the mean size of red spots decreased with increasing age of larvae at treatment, while the mutation frequencies were increased because of the multiplication of the cells in the eye anlage susceptible to the mutagens. This is contradictory to the hypothesis maintained by Fahmy and Fahmy (1980) that the somatic shifts are not mutagenic but epigenetic events, due to altered regulation of the gene expression. Red spots induced with MMS are smaller in size than X-ray-induced red spots, indicating a delay in the establishment of mutations from chemically-induced lesions compared to irradiation damage. White spots on the other hand were equally large in size, irrespective of inducing agent and about twice the size of the chemically-induced red spots, implying a faster and more direct action for fixation of deletions than for the production of MMS induced shifts in eye color from zeste to red.

Uptake and incorporation in pteridines of externally supplied GTP in normal and pigment-deficient eyes ofDrosophila melanogaster

Some aspects of the synthesis of drosopterins in the eyes ofDrosophila melanogaster have been studied in flies with different levels ofwhite gene expression. The activity of GTP cyclohydrolase was found to differ between wild-type and yellow-eyed mutantsin vivo but notin vitro. To elucidate the uptake of substrate, we measured the removal of labeled GTP from the incubation medium by excised pupal eyes and followed the subsequent fate of this label. It was found that GTP was dephosphorylated to guanosine extracellularly before label was taken up by the eye tissue. The uptake was much lower in yellow and white eyes than in wild-type eyes, and in the latter, a considerable part of the label was present in pteridine compounds. The strain differences in the uptake of label seem to be due to different rates of intracellular utilization of guanine derivatives in pteridine synthesis. We suggest that this is caused by a hampered transport of precursor (possibly GTP) in white andzeste eyes through the membrane of red pigment granules.

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