Effects of inhibitors and activators on the activity of two diaphorases from Drosophila virilis

The effect of some inhibitors and activators of mammalian DT-diaphorase on diaphorase-1 (DIA-1) and diaphorase-2′ (DIA-2′) purified from Drosophila virilis was studied. The inhibitors and activators changed the activity of these diaphorases in a different way, revealing a similarity between mammalian DT-diaphorase and D. virilis DIA-1 on the one hand and on the other between the D. virilis DIA-1 and the diaphorase purified from Bombyx mori eggs. These effects also confirm the independent genetic control of DIA-1 and DIA-2′ in D. virilis and make possible the differentiation of these diaphorase activities in crude enzyme extracts.     

Drosophila virilis histone gene clusters lacking H1 coding segments

Summary Approximately 30–40% ofDrosophila virilis DNA complementary to clonedDrosophila histone genes is reduced to 3.4-kilobase-pair (kbp) segments by Bgl I or Bgl II digestion. The core histone genes of a 3.4-kbp Bgl II segment cloned in the plasmid pDv3/3.4 have the same order as theD. melanogaster core histone genes in the plasmid cDm500: . Nonetheless, pDv3/3.4 and cDm500 have different histone gene configurations: In pDv3/3.4, the region between the H2B and H3 genes contains 0.35 kbp and cannot encode histone H1; in cDm500, the region contains 2.0 kbp and encodes histone H1. The lack of an H1 gene between the H2B and H3 genes in 30–40% ofD. virilis histone gene clusters suggests that changes in histone gene arrays have occurred during the evolution ofDrosophila. The ancestors of modernDrosophila may have possessed multiple varieties of histone gene clusters, which were subsequently lost differentially in thevirilis andmelanogaster lineages. Alternatively, they may have possessed a single variety, which was rearranged during evolution. The H1 genes ofD. virilis andD. melanogaster did not cross-hybridize in vitro under conditions that maintain stable duplexes between DNAs that are 75% homologous. Consequently,D. virilis H1 genes could not be visualized by hybridization to an H1-specific probe and thus remain unidentified. Our observations suggest that the coding segments in the H1 genes ofD. virilis andD. melanogaster are >25% divergent. Our estimate of sequence divergence in the H1 genes ofD. virilis andD. melanogaster seems high until one considers that the coding sequences of cloned H1 genes from the closely related speciesD. melanogaster andD. simulans are 5% divergent.     

Histone content in relation to amount of heterochromatin and developmental stage in three species of Drosophila

Relative amounts of various histone fractions in Drosophila chromatin were estimated densitometrically on electrophoretic gel separations. Several consistent and highly significant differences were obtained between larval and adult chromatin. The arginine-rich histones showed the most conspicuous changes: higher amounts of H4 in larvae, higher H3 in adults. The level of modification of these histones was clearly higher in larval than in adult chromatin. The modification of the two slower subfractions of H4 involved, in all probability, phosphorylation as well as acetylation. In all types of Drosophila chromatin studied 50% or more of the H2a molecules were phosphorylated—a remarkably high proportion. The species differences observed in relative amounts of histone were consistent in both stages of development. D. melanogaster differed from D. hydei and D. virilis in all histones except H2b, while the latter two species were generally similar. The interspecific variation in histone pattern was generally not correlated to differences in content of heterochromatin. The level of modification of H3 was, however, presumably an exception, as it was significantly lower for both larvae and adults in D. virilis than in the other two species. These differ from D. virilis in containing appreciably lower proportions of heterochromatic chromosome segments.     

THE GENETIC BASIS OF EVOLUTION OF THE MALE COURTSHIP SOUNDS IN THE DROSOPHILA VIRILIS GROUP

When courting, males of the Drosophila virilis group vibrate their wings and emit species-specific courtship sounds consisting of trains of polycyclic sound pulses. To analyze the genetic basis of evolutionary changes in the sounds we made an F₁ diallel set of reciprocal crosses between the members of the virilis phylad of the group (two stocks of D. virilis and one of D. americana americana, D. a. texana, D. novamexicana, and D. lummei). We also crossed the D. virilis stocks with the members of the montana phylad of the same group (D. kanekoi, D. littoralis, D. borealis, D. flavomontana, D. lacicola, and D. montana) and made a backcross (D. virilis x D. littoralis) x D. virilis using a D. virilis marker stock (b; sv t tb gp; cd; pe). The sounds of the hybrids were analyzed using the following parameters: the length of a pulse train (PTL), the number of pulses in a train (PN), the interpulse interval (IPI), the length of a pulse (PL), the number of cycles in a pulse (CN), and the length of a cycle (CL). In the virilis phylad, the differences between species appeared to be determined mainly by autosomal genes in each sound trait. The heritabilities (narrow-/broad-sense) obtained from the diallel tables were the following: PTL 0.662/0.817, PN 0.651/0.841, IPI 0.193/0.546, PL 0.408/0.552, CN 0.425/0.719, and CL 0.361/0.764. The direction of dominance is for longer PTL, higher PN and CN, and shorter IPI and CL. PL shows ambidirectional dominance. In the sounds of the virilis phylad species, PTL and PL seem to be phenotypically the most important parameters, since their components (PN and IPI for PTL, CN and CL for PL) are negatively correlated. In crosses between D. virilis and D. littoralis or D. flavomontana reciprocal hybrids differed from each other in PTL, IPI, PL, and CN indicating X-chromosomal or cytoplasmic inheritance. In the backcrosses between D. virilis and D. littoralis the role of the X chromosome was ascertained to be decisive. We conclude that an X-chromosomal major change allowing variation in IPI has occurred during the separation of the two D. virilis group phylads, the long IPI allowing variation also in PL (and CN). The evolution of the sounds in the virilis phylad has probably gone towards longer and denser pulse trains, while in the montana phylad the sounds have evolved in different directions.     

Functional conservation of a glucose-repressible amylase gene promoter from Drosophila virilis in Drosophila melanogaster

Summary Previous studies have demonstrated that the expression of the -amylase gene is repressed by dietary glucose in Drosophila melanogaster. Here, we show that the -amylase gene of a distantly related species, D. virilis, is also subject to glucose repression. Moreover, the cloned amylase gene of D. virilis is shown to be glucose repressible when it is transiently expressed in D. melanogaster larvae. This cross-species, functional conservation is mediated by a 330-bp promoter region of the D. virilis amylase gene. These results indicate that the promoter elements required for glucose repression are conserved between distantly related Drosophila species. A sequence comparison between the amylase genes of D. virilis and D. melanogaster shows that the promoter sequences diverge to a much greater degree than the coding sequences. The amylase promoters of the two species do, however, share small clusters of sequence similarity, suggesting that these conserved cis-acting elements are sufficient to control the glucose-regulated expression of the amylase gene in the genus Drosophila.Offprint requests to: D.A. Hickey     

Localization of <Emphasis Type="Italic">Dras1</Emphasis> gene in polytene chromosomes of sibling species of <Emphasis Type="Italic">Drosophila virilis</Emphasis> group

The Dras1 gene was mapped by in situ hybridization to polytene chromosomes of several sibling species of the Drosophila virilis group and their hybrids. A 1037-bp fragment of Dras1 gene from the D. virilis genome was used as the probe. The gene sequence was localized in the region of a 25 A-B disk in chromosome 2 (in accordance with the D. virilis polytene chromosome map (Gubenko and Evgen’ev, 1984).     

Genetic regulation of chromosome behaviour in interspecific hybrids of Drosophila

Summary When crossing Drosophila virilis females with D. littoralis males, the elimination of D. littoralis sixth chromosome (microchromosomes) was often observed. The absence of the sixth chromosome of D. littoralis was revealed when studying F₁ hybrids, because of the mosaic expression of the recessive gene gl, located in the sixth chromosome of D. virilis. In the reciprocal cross the elimination of the sixth chromosome of D. littoralis did not take place (Sokolov 1959).Genetic analysis enabled the authors to conclude that the observed maternal effect on mitosis is controlled by recessive genes located on the second and fourth chromosome of D. virilis. The genes located on the second chromosome, differ from those on the fourth chromosome both in temperature sensitivity and in the time and/ or the mechanism controlling the mitotic behaviour of the chromosomes.By means of back-crosses a new stock was established where all chromosomes except the sixth belonged to D. virilis. The sixth pair (microchromosomes) in this line was represented by one D. virilis and one D. littoralis chromosome. It was shown that the sixth chromosome of D. littoralis might be eliminated or undergo non-disjunction in D. virilis germline but the frequency of such atypical behaviour was very low (about 2 %). Low temperature treatment was not effective for increasing the frequency of either elimination or non-disjunction of the D. littoralis sixth chromosome in D. virilis germ-line.     

Genetics of esterases in Drosophila of the virilis group. I. Characteristics of esterase patterns in D. virilis,D. texana,D. littoralis,and their hybrids

Starch and polyacrylamide gel electrophoreses have detected six esterase fractions in Drosophila of the virilis group. These esterases have been characterized in detail using a series of substrates and inhibitors and also thermal treatment. Differences in esterase patterns have been found between D. virilis, D. texana, and D. litoralis as well as between D. virilis stocks. An interstock polymorphism for different esterase patterns has been established with respect to the electrophoretic mobilities of a number of esterase fractions. In rare instances, it has been observed within some D. virilis stocks, too. There is specificity in organ distribution of esterase fractions in Drosophila. Monogenic control of the electrophoretic mobilities of esterase-2 and esterase-4 has been demonstrated in D. virilis, and a dimer structure has been found in esterase-2. Genes controlling esterase-2 and esterase-4 are located on the second chromosome (209.3 for esterase-2 and 192.0 for esterase-4). In interstock and interspecific hybrids, esterases usually manifest codominance. In interstock hybrids, esterase-2 forms a hybrid band not observed in interspecific hybrids. In third instar larvae of interspecific hybrids, differential expression of certain esterase isozymes has been noted. These observations are in agreement with data from histochemical studies of organs of different hybrids.     

Mechanisms of programmed cell death during oogenesis in <Emphasis Type="Italic">Drosophila virilis</Emphasis>

We describe the features of programmed cell death occurring in the egg chambers of Drosophila virilis during mid-oogenesis and late oogenesis. During mid-oogenesis, the spontaneously degenerating egg chambers exhibit typical characteristics of apoptotic cell death. As revealed by propidium iodide, rhodamine-conjugated phalloidin staining, and the TUNEL assay, respectively, the nurse cells contain condensed chromatin, altered actin cytoskeleton, and fragmented DNA. In vitro caspase activity assays and immunostaining procedures demonstrate that the atretic egg chambers possess high levels of caspase activity. Features of autophagic cell death are also observed during D. virilis mid-oogenesis, as shown by monodansylcadaverine staining, together with an ultrastructural examination by transmission electron microscopy. During the late stages of oogenesis in D. virilis, once again, the two mechanisms, viz., nurse cell cluster apoptosis and autophagy, operate together, manifesting features of cell death similar to those detailed above. Moreover, an altered form of cytochrome c seems to be released from the mitochondria in the nurse cells proximal to the oocyte. We propose that apoptosis and autophagy function synergistically during oogenesis in D. virilis in order to achieve a more efficient elimination of the degenerated nurse cells and abnormal egg chambers. The present study was co-financed within Op. Education by the European Social Fund and by National Resources via a grant (HRAKLEITOS 70/3/7164) to Professor L.H. Margaritis.     

Analysis of DNAs from two species of the virilis group of Drosophila and implications for satellite DNA evolution

The DNAs from two virilis group species of Drosophila, D. lummei and D. kanekoi, have been analyzed. D. lummei DNA has a major satellite which, on the basis of CsCl equilibrium centrifugation, thermal denaturation, renaturation and in situ hybridization is identical to D. virilis satellite I. D. kanekoi DNA has a major satellite at the same buoyant density in neutral CsCl gradients as satellite III of D. virilis. However, on the basis of alkaline CsCl gradients, the satellite contains a major and a minor component, neither one of which is identical to D. virilis satellite III. By in situ hybridization experiments, sequences complementary to the major component of the D. kanekoi satellite are detected in only some species and in a way not consistent with the phylogeny of the group. However, by filter hybridization experiments using nick-translated D. kanekoi satellite as well as D. lummei satellite I and D. virilis satellite III DNAs as probes, homologous sequences are detected in the DNAs of all virilis group species. Surprisingly, sequences homologous to these satellite DNAs are detected in DNAs from non-virilis group Drosophila species as well as from yeast, sea urchin, Xenopus and mouse.     

Genetics of esterases in Drosophila. VII. Genetic control of the activity level of juvenile hormone (JH)-esterase and heat resistance in D. virilis at high temperatures

The heat-resistant subline 147S was obtained in Drosophila virilis by selecting for viability individuals of heat-sensitive stock 147. It was shown that in the heat-treated 147S pupae the activity of juvenile hormone (JH)-esterase is decreased and, consequently, the titer of juvenile hormone is increased compared with those in the control pupae. These changes are consistent with those observed earlier for resistant stock 101. Heat-resistant stocks 101 and 147S were crossed with heat-sensitive stock 147, whose heat-treated larvae show earlier activation and higher activity of JH-esterase than control larvae. The viability and electrophoretic esterase patterns were analyzed in the F₁ and F₂ hybrids at different temperatures. It was found that the F₁ hybrid is resistant to the effect of high temperature and its activity level of JH-esterase is lower compared with controls. In the F₂ hybrid, there was a 3:1 segregation of viability and a 1:2:1 segregation of the activity level of JH-esterase at high temperatures. It is concluded that the activity level of JH-esterase and heat resistance in D. virilis are monogenically controlled at high temperatures.     

Evolutionary divergence of the cytochrome b5 gene of Drosophila

Cytochrome proteins perform a broad spectrum of biological functions ranging from oxidative metabolism to electron transport and are thus essential to all organisms. The b-type cytochrome proteins bind heme noncovalently, are expressed in many different forms and are localized to various cellular compartments. We report the characterization of the cytochrome b₅ (Cyt-b) gene of Drosophila virilis and compare its structure to the Cyt-b gene of Drosophila melanogaster. As in D. melanogaster, the D. virilis gene is nuclear encoded and single copy. Although the intron/exon structures of these homologues differ, the Cyt-b proteins of D. melanogaster and D. virilis are approximately 75% identical and share the same size coding regions (1,242 nucleotides) and protein products (414 amino acids). The Drosophila Cyt-b proteins show sequence similarity to other b-type cytochromes, especially in the N-terminal heme-binding domain, and may be targeted to the mitochondrial membrane. The greatest levels of similarity are observed in areas of potential importance for protein structure and function. The exon sequences of the D. virilis Cyt-b gene differ by a total of 292 base changes. However, 62% of these changes are silent. The high degree of conservation between species separated by 60 million years of evolution in both the DNA and amino acid sequences suggests this nuclear cytochrome b₅ locus encodes an essential product of the Drosophila system.Correspondence to: C.E. Rozek     

Ecdysone-induced changes in glycoprotein synthesis and puff activities in Drosophila virilis salivary glands

During five hours after the injection of -ecdysone into the hemolymph of D. virilis late third instar larvae the formation of larval glycoproteins in the salivary glands is terminated and the synthesis of a different set of glycoproteins which is characteristic for the prepupal gland is initiated. The data presented suggest that products from early puffs inhibit the formation of larval glycoproteins while the induction of late puffs may be responsible for the appearance of prepupal glycoproteins.     

Purification and characterization of diaphorases from someDrosophila species

Diaphorase-1 and diaphorase-2 were isolated from twoDrosophila species,D. virilis andD. melanogaster, and purified by gel filtration, affinity chromatography, immunoaffinity chromatography, and ion-exchange chromatography. The molecular weights of both enzymes were the same in each species. The molecular weight of diaphorase-1 was the same under both denaturating and nondenaturating conditions, close to 60,000, indicating a monomeric structure. Sodium dodecyl sulfate (SDS) electrophoresis of the purified diaphorase-2 revealed the presence of a single protein band of 55,000 Da, while the molecular weight of the native enzyme was found to be 67,000. The two diaphorases were further characterized by their pH optima, isoelectric points, and kinetic parameters, and antibodies were raised in rabbits against the purified enzymes fromD. virilis. The antibodies showed no cross-reactions but recognized the corresponding diaphorases inD. melanogaster andD. novamexicana as well asD. virilis. The data obtained confirmed the hypothesis of an independent genetic control of diaphorase-1 and diaphorase-2 inDrosophila.     

The Importance of Acoustic Signals in Multimodal Courtship Behavior in Drosophila virilis,D. lummei and D. littoralis

The courtship rituals of Drosophila include an exchange of several signals with different modalities, chemical, visual, acoustic and tactile stimuli, between sexes. Using a video recording method, we studied the role of acoustic communication in courtship behavior in three species of the Drosophila virilis group, D. virilis, D. lummei and two populations of D. littoralis. Five series of experiments were performed: tests with intact flies (control), tests with mute flies (wingless males or females), and tests with deaf flies (aristaless males or females). We distinguished the two situations: either a female did not hear a male or vice versa, males did not hear females. When females did not hear males, the reduction in the copulation number was found in D. virilis and both populations of D. littoralis, but not in D. lummei. When males did not hear females, the reduction in the copulation number was only found in D. littoralis. The ablation of the male aristae in D. virilis and D. lummei even increased the mating success as compared to the control, which may be explained by the ‘sensory overload’ hypothesis. The changes in courtship temporal structure usually included the delayed onset of the main courtship elements (tapping, licking, and singing), and the variation in their duration and the total time of courtship. These effects were, however, more substantial in D. virilis and both populations of D. littoralis than in D. lummei. Thus, the effect of blocking the acoustic channel was different in the three species regardless of their phylogenetic relationship, and the role of acoustic communication in courtship behavior seemed to increase in the order D. lummei – D. virilis – D. littoralis.

     

Genetics of esterases in Drosophila. V. Characteristics of the “pupal” esterase in D. virilis

From analysis of the properties of the pupal esterase (p-esterase) in Drosophila virilis, it is concluded that it is heat stable, its electrophoretic detection depends on culture density, its expression is stage specific, and it is not a variant of esterase 2. It was also demonstrated that p-esterase, like esterase 6, is activated by injections of the juvenile hormone into larvae. Heat treatment of heat-resistant D. virilis stocks led to decreased activities of the juvenile hormone dependent esterases but did not affect those of the heat-sensitive stocks. It is suggested that heat resistance in D. virilis is related to some functional features of the system of modifier genes controlling the phenotypic expression of esterases.     

Isolation and characterization of microsatellites in Drosophila virilis and their cross species amplification in members of the D. virilis group

We report the isolation and cross species amplification of 42 Drosophila virilis microsatellite loci. Nine loci were isolated from mapped P1 bacteriophage clones and 33 were obtained from genomic DNA or GenBank searches. Cross species amplification was tested for all members of the D. virilis group. The amplification success was high (varying from 45% to 100%) and most of the loci were polymorphic. This set of loci can be applied for several genetic studies such as mapping behavioural quantitative trait loci (QTL) and for studying population structure in a phylogeographical framework in D. virilis group species.     

Strategic differences in thermal adaptation between two Drosophila species,D. virilis and D. immigrans

Summary Preadult viability and developmental time at four different temperatures, heat and cold resistances of adult flies, effects of acclimatization on heat resistance, and preferred temperature of adult flies were compared between two species of Drosophila, D. virilis and D. immigrans. Four Japanese local populations were surveyed for each species. As compared with immigrans, virilis was higher in its ability to tolerate both heat and cold stresses and was viable over a broader temperature range. On the other hand, immigrans revealed a superior ability to acclimatize and a rigid preference for gradually changing thermal environment. Differences between geographical populations are remarkable for heat tolerance in virilis and cold tolerance in immigrans. In conclusion, thermal adaptation of virilis seems to be based on the high tolerance to extreme temperatures and that of immigrans mainly on the behavioural preference for viable temperatures.     

Comparative polytene chromosome maps of <Emphasis Type="Italic">D. montana</Emphasis> and <Emphasis Type="Italic">D. virilis</Emphasis>

Chromosomal inversion polymorphism was characterized in Finnish Drosophila montana populations. A total of 14 polymorphic inversions were observed in Finnish D. montana of which nine had not been described before. The number of polymorphic inversions in each chromosome was not significantly different from that expected, assuming equal chance of occurrence in the euchromatic genome. There was, however, no correlation between the number of polymorphic inversions and that of fixed inversions in each chromosome. Therefore, a simple neutral model does not explain the evolutionary dynamics of inversions. Furthermore, in contrast to results obtained by others, no significant correlation was found between the two transposable elements (TEs) Penelope and Ulysses and inversion breakpoints in D. montana. This result suggests that these TEs were not involved in the creation of the polymorphic inversions seen in D. montana. A comparative analysis of D. montana and Drosophila virilis polytene chromosomes 4 and 5 was performed with D. virilis bacteriophage P1 clones, thus completing the comparative studies of the two species.