Induction of mutations by tritiated water and 3H-thymidine in Drosophila melanogaster assayed by the somatic zeste-white eye mutation system

In order to study the mutagenic effect of exposure to tritium, Drosophila melanogaster larvae were treated with tritiated water (3H2O) or tritiated thymidine (3H-TdR) during development. Dose rates ranged from 0.0058 to 0.058 rad/h per nucleus for 3H-TdR and from 0.049 to 0.122 rad/h for 3H2O. Induction of mutations was measured by the appearance of somatic mutations in the eyes of an unstable strain of Drosophila melanogaster. Both substances caused a significant increase in mutation frequency. With the assumption that each mutation observed in this assay is caused by one DNA break, the effectiveness of tritium to create DNA breaks is estimated to be 0.20 breaks per decay for 3H-TdR and 0.27 breaks per decay for 3H2O.     

Genotoxicity testing with the somatic white-ivory system in the eye of Drosophila melanogaster

The white-ivory test in Drosophila melanogaster is designed to detect chemically induced reversions of the sex-linked, recessive unstable eye-color mutation white-ivory to the wild-type form. After exposure of larvae reversions are detectable as clones of red facets in the eye of newly enclosed adult flies. Tester strains containing a quadruplication of the white-ivory gene on the X-chromosome(s) were used. In a strain with males carrying 4 copies of the gene and females carrying 8 copies of the gene, spontaneous reversions occurred proportional to the gene copy number. In contrast to this, chemically induced reversions occurred only 1.36 times more frequently in females (carrying 8 copies of the gene) than in males (carrying 4 copies). Since chemicals inducing different lesions in DNA (bleomycin, cyclophosphamide, daunomycin, diethyl sulfate and 7,12-dimethylbenz[a]anthracene) did induce statistically significant frequencies of reversions the test appears to be capable of detecting a wide variety of genotoxic chemicals with different modes of action. The recombinogen strychnine did not induce reversions.     

Comparative induction of somatic eye-color mutations and sex-linked recessive lethals in Drosophila melanogaster by tryptophan pyrolysates

The mutagenicities of the products of pyrolysis of tryptophan, Trp-P-1 and Trp-P-2, on Drosophila melanogaster were examined by measuring the effects of these compounds in inducing recessive lethals and somatic eye-color mutations. Since negative results have already been obtained by the standard procedure in males, Trp-P-1 and Trp-P-2 (0.75 to 6 mg/ml) in sucrose solution were given to females for assay of recessive lethal mutations in X-chromosomes. These compounds caused a marginal increase above the control level in the mutation frequency. For the assay of effects on somatic eye-color mutations, Trp-P-1 (200 and 400 ppm) and Trp-P-2 (400 and 800 ppm) were fed to male larvae of a tester strain carrying a genetically unstable marker set of z and w+ on the X-chromosome. These compounds caused dose-dependent increases above the control level in somatic eye-color mutations in adults. It is concluded that, under the conditions used, the somatic eye-color mutation system was more sensitive than the recessive lethal system to the mutagenic effects of tryptophan pyrolysates.     

The disconnected visual system mutations in Drosophila melanogaster drastically disrupt circadian rhythms

Mutations at the disconnected (disco) locus in Drosophila melanogaster cause cultures of this insect to eclose in an essentially arrhythmic manner and also nearly eliminate free-running circadian rhythms of locomotor activity. Yet disco mutants are not totally light-insensitive: Whereas they performed very poorly in tests of certain behavioral responses to visual stimuli, they were able to exhibit "forced" periodic locomotor activity under conditions of light-dark cycling. We discuss these results in the context of (1) the dispensability of this insect's external photoreceptors for entrainment of its circadian pacemaker, and (2) possible disco-induced abnormalities in the connections of extraocular photoreceptors to their targets in the central nervous system and/or abnormalities in the targets themselves--which presumably include elements of the fly's circadian clock.     

Genetic instability in Drosophila melanogaster. Evidence for insertion mutations

Summary An X chromosome in Drosophila melanogaster is described which is mutationally unstable. Mutational events were identified through phenotypic changes associated with a tandem duplication of the X chromosome in which the white locus is present in duplicate. The left segment of the tandem duplication was marked with the mutant w ^sp, the right segment with mutant w ^17G. Some of the phenotypic changes were identified as deletions involving the w ^17G marked segment of the duplication. Other phenotypic changes involved the left segment in which phenotypically w ^sp mutated to w. Experimental evidence is presented which attributes these latter mutations to insertions of foreign DNA into the w locus equivalent to the insertion mutations of E. coli.     

Assessing sexual conflict in the Drosophila melanogaster laboratory model system

We describe a graphical model of interlocus coevolution used to distinguish between the interlocus sexual conflict that leads to sexually antagonistic coevolution, and the intrinsic conflict over mating rate that is an integral part of traditional models of sexual selection. We next distinguish the 'laboratory island' approach from the study of both inbred lines and laboratory populations that are newly derived from nature, discuss why we consider it to be one of the most fitting forms of laboratory analysis to study interlocus sexual conflict, and then describe four experiments using this approach with Drosophila melanogaster. The first experiment evaluates the efficacy of the laboratory model system to study interlocus sexual conflict by comparing remating rates of females when they are, or are not, provided with a spatial refuge from persistent male courtship. The second experiment tests for a lag-load in males that is due to adaptations that have accumulated in females, which diminish male-induced harm while simultaneously interfering with a male's ability to compete in the context of sexual selection. The third and fourth experiments test for a lag-load in females owing to direct costs from their interactions with males, and for the capacity for indirect benefits to compensate for these direct costs.     

The nature of reverse mutations in Drosophila melanogaster

A selection system for the screening of reversions has been constructed and used to test reversions of lethals located in the proximal region of the X chromosome of Drosophila and of Kpn mutations.Spontaneous and induced reversions have been screened, X-rays and ethyl methanesulphonate (EMS) being the mutagens used in the induction experiments.No genuine back-mutation was found in 6·10⁵ gametes scored. Sterile reversions of all four lethals tested were obtained. Their frequency suggested that at least in three of the lethals the sterile reversions represented “escapers” of the lethal effect rather than true revertants.Three fertile reversions of l^x4 were found and analyzed. All three were autosomal suppressors, located on the second chromosome, allelic to each other, dominant in males and recessive in females.One fertile reversion of l^3DES was found to be an X-linked suppressor. It is suggested that this suppressor is a Y-suppressed lethal, showing a V-type position effect, resulting from an aberration included in the proximal heterochromatin of the X chromosome.Reversions of Kpn were obtained at a similar rate to that found in previous reports²².The absence of true back-mutants in our experiments, in contrast to findings in previous reports, is discussed. From the existing literature on spontaneous and induced back-mutations in Drosophila melanogaster it appears that for several mutations the rates of forward and back-mutation are of the same order of magnitude. It is suggested that reported cases of back-mutations represent mainly inter- and intrachromosomal recombination in duplicated regions rather than mutational events and that the frequency of true back-mutation in Drosophila is usually of an order of magnitude, similar to that known for microorganisms and fungi.     

Characterisation of male meiotic-sterile mutations in Drosophila melanogaster

Male meiotic sterile mutations were selected among X-linked male—steriles by detection of micronuclei in early spermatids. Despite severe defects in the 1st or 2nd meiotic spindles in all mutants, no effect on mitosis was observed. Various features of spindle structure, chromosome segregation, and centriole movements were compared in seven meiotic steriles and in XO males. Chromosome behaviour and centriole movement were always affected concomitantly, and were both shown to be genetically independent of centre formation in the meiotic spindles. Precocious and delayed centromere separation was observed in the various mutants in both divisions, and similarly attributed to basic spindle lesions rather than chromosome defects. Attachment of the centriole body to the membrane of the spermatid nucleus was normal only in mutants where second division nuclei were formed. The role of the centriole body was shown to be independent of membrane attachment.—The phenomena observed in this study were discussed mainly with regard to genetic interdependence of morphogenetic processes during male meiosis. A common base for the pleiotropic defects of meiotic steriles and XO males is suggested, and the genetic control of meiosis is re-evaluated in the light of comparison with fertile meiotic mutants.     

Dominance of mutations affecting viability in Drosophila melanogaster

There have been several attempts to estimate the average dominance (ratio of heterozygous to homozygous effects) of spontaneous deleterious mutations in Drosophila melanogaster, but these have given inconsistent results. We investigated whether transposable element (TE) insertions have higher average dominance for egg-to-adult viability than do point mutations, a possibility suggested by the types of fitness-depressing effects that TEs are believed to have. If so, then variation in dominance estimates among strains and crosses would be expected as a consequence of variation in TE activity. As a first test, we estimated the average dominance of all mutations and of copia insertions in a set of lines that had accumulated spontaneous mutations for 33 generations. A traditional regression method gave a dominance estimate for all mutations of 0.17, whereas average dominance of copia insertions was 0.51; the difference between these two estimates approached significance (P = 0.08). As a second test, we reanalyzed Ohnishi 1974 data on dominance of spontaneous and EMS-induced mutations. Because a considerable fraction of spontaneous mutations are caused by TE insertions, whereas EMS induces mainly point mutations, we predicted that average dominance would decline with increasing EMS concentration. This pattern was observed, but again fell short of formal significance (P = 0.07). Taken together, however, the two results give modest support for the hypothesis that TE insertions have greater average dominance in their viability effects than do point mutations, possibly as a result of deleterious effects of expression of TE-encoded genes.     

A genetic model for human polyglutamine-repeat disease in Drosophila melanogaster.

To apply genetics to the problem of human polyglutamine-repeat disease, we recreated polyglutamine-repeat disease in Drosophila melanogaster. To do this, we expressed forms of the human gene encoding spinocerebellar ataxia type 3, also called Machado-Joseph disease (SCA-3/MJD). This gene is responsible for the most common form of human ataxia worldwide. Expression of a normal form of the MJD protein with 27 polyglutamines (MJDtr-Q27) had no phenotype. However, expression of a form of the protein with an expanded run of 78 glutamines (MJDtr-Q78) caused late onset progressive degeneration. In addition, the MJDtr-Q78 formed abnormal protein aggregates, or nuclear inclusions (NIs), whereas the control protein was cytoplasmic. These data indicate that the mechanisms of human polyglutamine-repeat disease are conserved to Drosophila. We are currently using this model to address potential mechanisms by which the mutant disease protein causes neural degeneration, as well as to define genes that can prevent polyglutamine-induced degeneration. By applying the power of Drosophila genetics to the problem of human polyglutamine-induced neural degeneration, we hope to identify ways to prevent and treat these diseases in humans.     

Drosophila melanogaster model for Mycobacterium abscessus infection

Mycobacterium abscessus is a human pathogen that is responsible for a broad spectrum of tissue infections and disseminated infections in immunodeficient patients. This pathogen is one of the most resistant organisms to chemotherapeutic agents. Therefore, we tested the hypothesis that the fruit fly, Drosophila melanogaster, is a genetically tractable model host for M. abscessus. In this context, we infected D. melanogaster with M. abscessus. This M. abscessus infection results in dissemination in the fly body, followed by death, which is accompanied by severe indirect flight muscle and brain damage. Our data show that M. abscessus can grow and replicate in D. melanogaster w¹¹¹⁸ and that it elicited a humoral immune response, especially of the Toll antimicrobial peptide pathway. To the best of our knowledge, this is the first report that mycobacteria induce the production of antimicrobial peptides in D. melanogaster.     

Interactions between germ cells and somatic cells in Drosophila melanogaster

Interactions between germ cells and somatic cells are important at several stages of Drosophila development. The types of interactions that will be discussed include: (1) molecules physically transferred from one cell to another; (2) long range interactions by hormones; and (3) local interactions between germ cells and somatic cells when they are in close proximity. These interactions have been mostly characterized during oogenesis.