Circadian rhythms in Drosophila melanogaster: analysis of period as a function of gene dosage at the per (period) locus

Mutations at the per (period) locus of Drosophila melanogaster affect the period of its circadian rhythms. An analysis of published data on strains having duplications and deletions of the per locus indicates that the period is a logarithmic function of the level of the per gene product. The analysis also indicates that period is relatively insensitive to the level of that gene product; a presumed 300% increase in the gene product level produces only a 4.6% decrease in the period. The period of a strain transformed with per+ DNA conforms to the same logarithmic relationship if the level of mRNA in the transformant, which is one-tenth that in the wild type, is considered equivalent to a gene dosage one-tenth the wild type dose of 2, or 0.2. The periods of strains having various doses of mutant per alleles which shorten (pers) or lengthen (per1) the period can be fitted to the same logarithmic function. The analysis may provide an explanation for the partial dominance of pers over per+ and the dominance of per+ over per1, since it suggests that the per1 gene product is nearly inactive while the pers gene product is more than 34 times as active as the wild type product. Analysis of periods of strains heterozygous at the per locus suggests that the per gene product may be a multimeric protein. Three possible roles for the per gene product in circadian rhythmicity are discussed, including a role in synchronizing rhythm-producing cells.     

Molecular organization of the cut locus of Drosophila melanogaster

Mutations of the cut locus (ct) of Drosophila can be divided into four groups based on their phenotypes and complementation patterns. Each group alters the phenotype of a different set of tissues. Two hundred kilobases of ct DNA, located in 7B1-2, have been cloned by chromosomal walking, and the cloned sequences have been used to analyze more than 40 mutants. Based on the location of transposable element mutations and the extent of deficiencies and an inversion, four cut locus regions can be defined. Mutations in each region affect the phenotype of a different set of tissues. The most centromere proximal region contains mutations that are null for cut locus function. Within individual regions, a higher level of organization can be detected.     

Molecular analysis of chemically-induced mutations at the RpII215 locus of Drosophila melanogaster

A substantial fraction, perhaps 50% or more, of spontaneous mutations in Drosophila melanogaster have been shown by molecular analyses to be associated with the presence of a transposable element (TE) inserted into the affected gene. We are interested in the molecular structure of induced mutations in Drosophila, in particular whether TEs are also responsible for a significant proportion of chemically-induced mutations. We report here the molecular analysis of 58 mutations at the RpII215 locus induced with EMS or ENU. While we find evidence for moderately sized deletions at this locus (in 3/58, or 5% of the examined mutants), we failed to detect any mutations which were associated with an insertion event. It may be the case that induced mutations are qualitatively different from spontaneous mutations.     

Molecular analysis of large transposable elements carrying the white locus of Drosophila melanogaster

A large transposable element (TE) comprising the white-apricot and roughest genes has been found to transpose to well over a hundred sites scattered over the Drosophila genome. We report the cloning of the essential parts of several TEs. TE98 and TE28 sequences were cloned by `walking' along the chromosome from the previously cloned heatshock genes. The ends of the TEs are characterized by dispersed repetitive elements belonging to the foldback (FB) family. FB elements are also associated with two independently isolated transposable elements originating from the white locus, Tp w^c-1 and Tp w^+IV. The strong correlation between FB elements and large composite transposons suggests that a pair of these elements can mobilize large intermediary DNA segments. One particular FB family member, FB-NOF, is associated with TE28, the white-crimson (w^c) mutant, the w^c-derived Tp w^c-1 and probably also with Tp w^+IV. A unique sequence located close to the white end of TE28 was used to clone the borders of TE77 and the surrounding sequences in the bithorax region, indicating that the TE can be used as a probe for gene isolation. Some evolutionary implications of the large composite transposons are discussed.     

Structural and functional analysis of the scute locus in Drosophila melanogaster

Summary The functional expression of 12 scute alleles in homozygotes and compounds of Drosophila melanogaster at 14°, 22°, 30°C is analysed. Based on the data obtained, linear maps for bristles and mutations are built. The basic features of the maps, clustering and polarity, are invariable with respect to temperature, scute gene dosage and cross direction. In addition local dominance of the norm over bristle reduction was produced by the scute mutation; different types of complementation reactions were established for each bristle. The gene scute is treated as an operon-like system, composed of 3–4 cistrons with each controlling the formation of bristles on a particular region of the fly's body. This model argues well with the structure of maps constructed and implies a post-translational level of initial events of bristle-formation process.This paper is based on the report presented at XIV International Congress of Genetics (Moscow, August 1978)     

Molecular cloning and biological activity of ecdysis-triggering hormones in Drosophila melanogaster

Ecdysis-triggering hormones (ETH) initiate a defined behavioral sequence leading to shedding of the insect cuticle. We have identified eth, a gene encoding peptides with ETH-like structure and biological activity in Drosophila melanogaster. The open reading frame contains three putative peptides based on canonical endopeptidase cleavage and amidation sites. Two of the predicted peptides (DrmETH1 and DrmETH2) prepared by chemical synthesis induce premature eclosion upon injection into pharate adults. The promoter region of the gene contains a direct repeat ecdysteroid response element. Identification of eth in Drosophila provides opportunities for genetic manipulation of endocrine and behavioral events underlying a stereotypic behavior.     

Molecular genetic study of the cut locus of Drosophila melanogaster. V. The suffix sequence found in the locus is involved in the 3'-end maturation of different Drosophila mRNAs

The nucleotide sequences of 8 genomic and 2 mRNA copies of the suffix were studied. It was found that this short repeat (265 bp) forms the last exon (73 bp) in different developmentally regulated Drosophila genes. The functioning genes contain short insertions carrying polyadenylation signals and polyadenylation sites at the same position of the suffix. It was shown that the suffix sequence is directly involved in the formation of the last splicing site and 3'-end maturation of mRNA.     

Molecular cloning of the white locus region of Drosophila melanogaster using a large transposable element

We report the molecular cloning of a chromosome segment including the white locus of Drosophila melanogaster. This region was isolated using a deficiency extending from the previously cloned heat-shock puff sequences at 87A7 to a large transposable element containing the loci white and roughest.FB-NOF, a 7.5 kb element with partial homology to a family of inverted repeat sequences (Potter et al., 1980), is found very near the deficiency breakpoint, and is followed by DNA originating from the white locus region. Sequences totalling ˜60 kb surrounding this initial entry point were obtained by the cloning of successively overlapping fragments from a wild-type strain. Several rearrangement breakpoints have been mapped relative to the cloned DNA; these define the limits of the white locus and further differentiate the “white proximal region”, thought to function in gene regulation, from the remainder of the locus. Insertion of the dispersed repetitive element copia into the white locus is observed in strains carrying the white-apricot allele. Analysis of several white-apricot revertants suggests that copia insertion is responsible for the apricot eye color phenotype.     

Sleep and biological rhythms of Drosophila

Sleep and Biological Rhythms -