Searching for sleep mutants of Drosophila melanogaster

The functions of sleep are still unknown, but are probably related to cellular and molecular aspects of neural function. To better understand the benefits that sleep may bring at the cellular level, recent studies have employed Drosophila melanogaster as a model system and shown that fruit flies share the fundamental features of mammalian sleep. As in mammals, sleep in Drosophila is characterized by increased arousal threshold and by changes in brain electrical activity. Fly sleep is homeostatically regulated independent of the circadian clock, is modulated by stimulants and hypnotics, and is affected by age. Also, fly sleep is associated with changes in brain gene expression similar to those observed in mammals. While Drosophila neurobiology is sufficiently complex to permit meaningful generalizations to mammals and humans, Drosophila genetics is simple enough to allow a rapid mutagenesis screening. An ongoing mutagenesis study has screened approximately 5000 mutant Drosophila lines and found that sleep amount, sleep pattern, and the homeostatic regulation of sleep are highly conserved phenotypes in flies. So far, this study has identified 10 short sleeper lines and 4 lines that show no sleep rebound after sleep deprivation. Ultimately, the characterization of these lines should help identifying crucial cellular pathways involved in the regulatory mechanisms of sleep and its functional consequences.     

Developmental defects of female-sterile mutants of Drosophila melanogaster

Gans et al. (1975) isolated female-sterile mutants, viable and normal in the homozygous state, producing apparently normal eggs which were unable to develop or developed into defective embryos or adults, even when fertilized with wild-type sperm. Developmental abnormalities of these mutants were surveyed by observing living and fixed material. The following types of mutants were distinguished according to the predominant developmental defect: (i) Eggs not developing at all, mostly remaining unfertilized. (ii) Eggs stopping development after a few cleavages, some with polyploid nuclei. (iii) Eggs stopping development at various embryonic stages, with haploid nuclei. (iv) Eggs with abnormal blastoderm, not developing further or giving abnormal embryos. (v) Eggs with abnormal gastrula, in one case with excessive invaginations, in another case with germ band failing to elongate. (vi) Eggs with embryos dying at different stages, without easily visible effects. Several of the mutants were temperature sensitive. In all the mutants there were eggs that died without developing. Most of the developmental defects appear to be due to general metabolic disturbances of the egg, not directly related to morphogenesis. There were no mutants affecting determination of a particular adult organ. The closest to a morphological type of mutation were those with abnormal blastoderm having successive bands of nuclei of different sizes. Those mutants were thermosensitive; at permissive termperatures they developed into agametic adults or adults with various defects of abdomens, wings or eyes. The nature of maternal genetic control of early morphogensis was discussed.     

Postreplication repair defects in mutants of Drosophila melanogaster

Summary Mutants of Drosophila melanogaster which are defective in DNA synthesis have been identified among mutagen-sensitive stocks through analysis of both organ and cell cultures. A new procedure employing larval brain ganglia allows poorly fertile or sterile mutants to be analyzed for the first time. Parallel studies were performed in both tissues to establish the sensitivity of the new assay relative to that of the proven cell-culture assay. Damage was induced in the DNA of cultured cells with UV irradiation and in that of ganglial cells with the carcinogen N-acetoxy-2-acetylaminofluorene. Cultures were then pulse-labeled with ³H-thymidine, incubated in the absence of thymidine, and the newly synthesized DNA was analyzed by alkaline sucrose gradient centrifugation. The molecular weight of labeled DNA from mutant cells was compared with that from control cells to assess the effect of the mutant on DNA synthesis. Among 16 mutant stocks that were scanned in either or both tissues, seven show reductions in DNA synthesis using an undamaged template. Mutants at five different genetic loci [mus(2)205, mus(3)304, mus(3)308, mus(3)310 and mus(3)311] possess a reduced capacity to synthesize DNA on a UV-damaged template in primary cell cultures. Four of these five defects can also be detected in carcinogen-treated organ cultures. Two additional defects in postreplication repair were observed with the brainganglia assay in strains that cannot be assayed in cell culture [mus(1)108, mus(2)206].Abbreviations MMS methyl methanesulfonate - HN2 nitrogen mustard - AAF 2-acetylaminofluorene - AAAF N-acetoxy-2-acetylaminofluorene - DMSO dimethyl sulfoxide     

Nutritional Value-Dependent and Nutritional Value-Independent Effects on Drosophila melanogaster Larval Behavior

Gustatory stimuli allow an organism not only to orient in its environment toward energy-rich food sources to maintain nutrition but also to avoid unpleasant or even poisonous substrates. For both mammals and insects, sugars-perceived as "sweet"-potentially predict nutritional benefit. Interestingly, even Drosophila adult flies are attracted to most high-potency sweeteners preferred by humans. However, the gustatory information of a sugar may be misleading as some sugars, although perceived as "sweet," cannot be metabolized. Accordingly, in adult Drosophila, a postingestive system that additionally evaluates the nutritional benefit of an ingested sugar has been shown to exist. By using a set of seven different sugars, which either offer (fructose, sucrose, glucose, maltodextrin, and sorbitol) or lack (xylose and arabinose) nutritional benefit, we show that Drosophila, at the larval stage, can perceive and evaluate sugars based on both nutrition-dependent and -independent qualities. In detail, we find that larval survival and feeding mainly depend on the nutritional value of a particular sugar. In contrast, larval choice behavior and learning are regulated in a more complex way by nutrition value-dependent and nutrition value-independent information. The simplicity of the larval neuronal circuits and their accessibility to genetic manipulation may ultimately allow one to identify the neuronal and molecular basis of the larval sugar perception systems described here behaviorally.     

Coagulation and survival in Drosophila melanogaster fondue mutants

Drosophila larval coagulation factors have been identified in vitro. Better understanding of insect hemolymph coagulation calls for experiments in vivo. We have characterized a fondue (fon) mutation and null alleles isolated by imprecise excision of a transposable element. Loss of fon was pupal lethal, but adults could be recovered by expressing the UAS::fonGFP construct of Lindgren et al. (2008). Despite their lethality, fon mutations did not affect larval survival after wounding either when tested alone or in combination with a mutation in the hemolectin clotting factor gene. This reinforces the idea of redundant hemostatic mechanisms in Drosophila larvae, and independent pleiotropic functions of the fondue protein in coagulation and a vital process in metamorphosis.     

Pyrimidine biosynthesis in the dumpy mutants of Drosophila melanogaster

Summary The status of de novo pyrimidine synthesis in the dp mutant of Drosophila melanogaster was examined by measuring the activity of the rate-limiting orotate phosphribosyl transferase (OPRT) enzyme. Activity is significantly elevated in late third instar larvae of 5 different dp mutant strains. A more detailed analysis of a dp ^ovc allele has shown that this elevation arises at about mid-larval life and persists until pupation.A low nucleotide diet causes a depression in OPRT activity in dp ^ovc larvae which can be reversed by dietary supplementation of uracil. However, neither the low nucleotide diet nor uracil supplementation results in a change in the expressivity of the dp mutant phenotypes.Changes in expressivity are produced by 6-azauracil and by elevated temperature although, in those cases, the effect on OPRT activity is minimal.The significance of the observations is discussed in relation to the role of pyrimidine biosynthesis in dp expressivity and chitin synthesis.     

Autonomous cellular differentiation of homoeotic bithorax mutants of Drosophila melanogaster

Various mixtures of imaginal disc cells from wild-type and from homoeotic bithorax mutants have been studied in an in vivo Drosophila cell culture system. These mutants effect specific types of segmental transformations, e.g., bithorax-3 (bx³) transforms the anterior region of the metathorax (MT) into a region resembling the anterior mesothorax (MS), while postbithorax (pbx) transforms the posterior MT into a posterior MS-like region. In cell mixtures, wild-type haltere-disc cells segregate from wild-type wing-disc cells. On the other hand, bx³ and pbx haltere-disc cells integrate with wild-type cells derived from anterior and posterior regions, respectively, of wing discs. The behavior of these and other tested mutants of the bithorax series indicates in all cases studied that (1) the effects of the mutants are cell-autonomous, and (2) cellular affinities are determined by the genetic constitution rather than the segmental origin of the cells.     

Restoration of wing margins in Lyra mutants of Drosophila melanogaster

Lyra is a dominant, homozygous lethal mutation of Drosophila melanogaster; in heterozygotes the wings lack portions of the anterior and posterior margins including the characteristic bristles. We have found that, in addition to the loss of bristle forming cells, there is a decrease in the number of wing surface cells that varies between 10 and 20%. However, we observed no histological evidence of excessive cell death in either the larval discs or the pupal wing precursors in Lyra flies. Restoration of all or part of the normal wing margins occurs in some, but not all, cases of morphogenetic mosaics, in which there were patches of wild-type cells in Lyra wing margins due to irradiation-induced mitotic recombination. Analysis of these restorations, using margin bristles as indicators, shows that the Lyra wild-type gene is not involved in bristle formation per se and further that its expression is not cell autonomous. Instead the effect of the Lyra mutation appears to be associated with development of a margin forming subpopulation of cells and to influence the characteristic pattern of cells and bristles in the wing margin via an inductive interaction. The dorsal-ventral boundary can be demonstrated in the de facto wing margins of Lyra mutants suggesting that its origin is independent of any function Lyra might have in normal wing margin morphogenesis. In wing margin restorations the dorsal-ventral boundary is clearly delimited by trichomes and somewhat less rigorously shown by the margin bristles. Further, in these restorations ventral clones induce dorsal bristles, as well as ventral ones, and vice versa, indicating that the influence of Lyra is not restricted by the dorsal-ventral boundary.     

Specifics of anaphase chromatid disjunction in Drosophila melanogaster mitotic mutants

Anaphase chromatid behavior defects (CBDs) were quantitatively and qualitatively studied in nerve ganglion cells of third-instar larvae of several control wild-type Drosophila melanogaster strains and four strains with mutations of the aar(v158), ff3, mast(v40), and CycB(2g) cell-cycle genes. A linear specificity was observed for the CBD frequency, type, determination, and correction probability. The probability of anaphase CBD correction was close to unity in the control strains and lower in the mutant strains. The lower correction probability in the mutant strains was explained in the context of two findings, that the mutations induced the CBDs that were atypical of the wild-type strains and were potentially uncorrectable in anaphase and that the mutations negatively affected the relative anaphase time in mitosis.