Molecular phylogeny of the Drosophila tripunctata and closely related species groups (Diptera: Drosophilidae)

We suggest a new phylogenetic hypothesis for the tripunctata radiation based on sequences of mitochondrial genes. Phylogenetic trees were reconstructed by parsimony, maximum likelihood and Bayesian methods. We performed tests for hypotheses of monophyly for taxonomic groups and other specific hypotheses. Results reject the monophyly for the tripunctata group whereas monophyly is not rejected for the tripunctata radiation and other specific groups within the radiation. Although most of the basal nodes were unresolved we were able to identify four clusters within the tripunctata radiation. These results suggest the collection of additional data before a proper taxonomic revision could be proposed.     

Estimation of the molecular clock rate in lineages of the Drosophila virilis species group

The phylogeny of the Drosophila virilis species group was studied on the basis of five nuclear and mitochondrial genes: Adh, NonA, Fu, Ras1, and 16S-12S rRNA. Mathematical simulation was suggested in order to estimate the uneven accumulation of replacements in lineages of closely related species using an arbitrary number of sequences. This accounts for multiple, parallel, and reverse mutations. Periods of evolution with irregular rates in the virilis species group were reconstructed. A phylogenetic tree for the group was constructed on the basis of neutral variability.     

Genetic and molecular variation in the RpII215 region of Drosophila melanogaster

Summary The RpII215 region of the X chromosome of Drosophila melanogaster was investigated to identify genetic functions and correlate these with the known molecular organization of the region. Five genetic loci were identified in a subregion that is reported to transcribe nine or more messages. One locus is nod, which causes meiotic abnormalities, and three other loci are recessive lethal mutations whose developmental lesions are unknown. The fifth and most mutable of the loci is RpII215, which encodes the 215,000 dalton subunit of RNA polymerase II. Mutant effects of RpII215 alleles include: temperature-dependent (heat and cold) survival, altered sensitivity to -amanitin, male sterility, maternal effects and epistatic enhancement of mutant effects of other loci.     

Compartments in the wing of Drosophila: A study of the engrailed gene

It has recently been suggested that the wildtype alleles of homeotic genes are responsible for controlling the development of compartments. Because the mutation engrailed gives the posterior wing compartment anterior characteristics, it can be regarded as such a homeotic gene. Our experiments confirm the role of the engrailed gene in development of the posterior wing compartment, results which strongly support and extend the compartment hypothesis.Clonal analysis reveals that the state of the engrailed gene is immaterial to the entire anterior compartment, and crucial to the normal development of the posterior compartment, where it controls the pattern of veins and bristles. The presence of a straight and precisely positioned compartment border is dependent on the activity of the engrailed gene until late in development. We suggest that this is due to the gene's effects on cell affinities of the posterior compartment.The engrailed mutation increases the size and changes the shape of the posterior compartment. engrailed clones cause local wing enlargement only if they are dorsal and include the posterior margin of the wing. Wildtype cells outside the clone contribute to this change of shape. This result suggests that the postero-dorsal margin is primarily responsible for the control of shape, and that the ventral compartment is, to some extent, modeled on the dorsal.     

A method for the molecular characterization of bbl loci in Drosophila melanogaster

Summary In this work we have used a method that allows a rapid and precise quantification of rRNA genes. With the purpose of examining small numbers of rRNA genes, we used Drosophila melanogaster embryos which are inviable because their sex chromosomes carry extensive rDNA deletions. Two of the mutants, B ^s Ybb ¹ and Ybb ^l , appear to be completely devoid of rDNA. The third, Ybb ^-, contains no more than five genes.Work supported by C.N.R. contract No. 82-2100 and Progetto Finalizzato C.N.R. Ingegneria Genetica No. 83-01007-51     

Role of FOXO transcription factor in radiation adaptive response and hormesis in Drosophila melanogaster

Earlier, we put forward a hypothesis on the role of the FOXO-dependent mechanism of stressresponse gene activation in radiation adaptive response and hormesis at the level of an entire organism [1]. To confirm this assumption, we analyzed the influence of γ-irradiation on the duration of larval development and imago lifespan in Drosophila strains with different FOXO function activity. We revealed that hormesis and adaptive response, manifested in the increased duration of larval development and lifespan after low-dose irradiation, were absent in homozygous strains for the FOXO hypomorphic allele in contrast to wild-type Canton-S strain and FOXO heterozygotes.     

A further characterization of the cinnamon gene in Drosophila melanogaster

Summary Two mutants of Saccharomyces cerevisiae lacking pyruvate kinase (EC.2.7.1.40) are described. The mutations are recessive, segregate 2⁺:2^- in tetrads and do not complement each other. Single-step spontaneous revertants, isolated on glucose plates, get back pyruvate kinase activity. The enzymes from various revertants display a wide spectrum of specific activity, thermolability and altered affinity for ligands such as P-enol pyruvate, ADP and fructose 1,6-diphosphate. The mutants produce materials crossreacting to the rabbit antibody raised against purified pyruvate kinase from the wild type yeast. These mutations thus define the structural gene of pyruvate kinase.The mutations map on the leaft arm of chromosome I and form a single complementation group with five other pyruvate kinase mutations in the pyk1 gene that was earlier suggested to be a regulatory locus controlling the synthesis of this enzyme. A comparative study of these mutants has been made with the structural mutants described here.     

Genetic analysis of Drosophila vitellogenesis: A molecular weight variant of yolk polypeptide-2 in Drosophila simulans

Summary To assess the likelihood of finding genetic variants for the three major yolk polypeptides (YPs) within the species Drosophila melanogaster, YPs from the five species most closely related to D. melanogaster were investigated. The relative positions of the three YPs were characteristic for each species, and in all cases the mobilities of the YP in the ovary corresponded to that of the YP in the hemolymph of the same species.Different stocks of Drosophila simulans were found to have either of two forms of yolk polypeptide-2 (YP2). The YP2^S polypeptide migrated more slowly than YP2^F by an apparent molecular weight difference of about 700 daltons. The genetic factor responsible for this difference mapped to locus 35 on the X chromosome. The Yp2 allele present specified the mobility of the YP2 polypeptide in both the hemolymph and the ovary. YP1 and YP3 were the same in both Yp2 ^S and Yp2 ^F stocks indicating that they are not affected by the Yp2 gene. Densitometric scans of gels showed that there was more than twice as much YP2^F as YP2^S in the ovaries and hemolymph of homozygous animals. Yp2 ^S/Yp2 ^F heterozygotes contained both fast and slowly migrating YP2. The amount of each YP2 in Yp2 ^F/Yp2 ^S heterozygotes was about half that found in each homozygote. These dosage results suggest that this locus is the structural gene. Peptide mapping showed that the structural element contributing to retarded mobility of YP2^S is unlikely to reside at either end of the molecule. These experiments suggest a cytogenetic location in which to concentrate further investigations on the genetic regulation of YP2 synthesis.     

The sibling species Drosophila melanogaster and Drosophila simulans differ in the expression profile of glutathione S-transferases

Two major forms of glutathione S-transferase are known in Drosophila melanogaster: GST D and GST 2. In the present paper we report the existence of a third major form of glutathione S-transferase in Drosophila simulans. Induction with phenobarbital revealed a different regulation of GST between these species. Despite the fact that these two species are closely related, there was a difference in the expression profile of the enzyme implicated in the detoxification system, suggesting variations in capacity to suit their environment.     

Macroevolutionary relationships of species of Drosophila melanogaster group based on mtDNA sequences

The phylogenetic relationships among the Drosophila melanogaster group species were analyzed using approximately 1700 nucleotide-long sequences of the mitochondrial DNA. Phylogenetic analysis was performed using this region consisting of a part of the cytochrome b (cytb) coding gene, the entire coding sequences of tRNA-Leu, tRNA-Ser and the first subunit of NADH dehydrogenase (NADH1), and a part of the 16S-rRNA gene. The study of these sequences showed that this region of mtDNA is very invariable, as regards with the type of the genes that it contains, as well as the order that they are located on it. The resulting phylogenetic trees reveal a topology that separates the species into three main ancestral lines, leading to the following subgroups: (a) ananassae subgroup, (b) montium subgroup, and (c) melanogaster and Oriental subgroups. The inferred topology complements and generally agrees with previously proposed classifications based on morphological and molecular data.     

Autonomy of the wingless mutation in Drosophila melanogaster

Summary T(Y;2) translocations were used to cytologically localise the wingless locus of Drosophila melanogaster. We found that an existing T(Y;2), which is an insertion of a segment of 2L into the Y chromosome, has wg ⁺ within this insert. This Y chromosome was used to generate an attached XY chromosome containing wg ⁺. The mutation claret-nondisjunctional (ca ^nd) was used to induce the loss of this XY chromosome and thus generate gynandromorphs with wg ¹/wg ¹ male tissue and wg ⁺/wg ¹/wg ¹ female tissue. Analysis of these gynanders demonstrated that a genotypically wingless mutant hemithorax is usually also phenotypically mutant in these half body mosaics; thus wg ¹ is discautonomous. This observation is of interest as it is known that wg is not cell autonomous.