The distribution of the transposable elementBari-1 in theDrosophila melanogaster andDrosophila simulans genomes

The distribution of the transposable elementBari-1 inD. melanogaster andD. simulans was examined by Southern blot analysis and byin situ hybridization in a large number of strains of different geographical origins and established at different times.Bari-1 copies mostly homogeneous in size and physical map are detected in all strains tested. Both inD. melanogaster and inD. simulans a relatively high level of intraspecific insertion site polymorphism is detectable, suggesting that in both speciesBari-1 is or has been actively transposing. The main difference between the two sibling species is the presence of a large tadem array of the element in a well-defined heterochromatic location of theD. melanogaster genome, whereas such a cluster is absent inD. simulans. The presence ofBari-1 elements with apparently identical physical maps in allD. melanogaster andD. simulans strains examined suggests thatBari-1 is not a recent introduction in the genome of themelanogaster complex. Structural analysis reveals unusual features that distinguish it from other inverted repeat transposons, whereas many aspects are similar to the widely distributedTc1 element ofC. elegans.     

Interspecific competition betweenDrosophila melanogaster andDrosophila simulans

Summary The number of eggs laid in aDrosophila culture and the survival of these eggs may depend on the number of larvae that are still inhabiting or that have already used the culture medium.A known average number ofD. simulans st larvae (designated original inhabitants) were introduced into culture vials by allowing adults to lay for 24 h (low density) or 48 h (high density). On each day for 14 days, adults of three competitor strains (D. melanogaster Or-R-C, D. melanogaster yw andD. simulans st) were added to different samples of these vials and allowed to lay for 24 h. The numbers of effective eggs (eggs expected to be laid less those withheld, cannibalised or buried) produced by competitor strains were estimated from adult emergences. Survival of original inhabitant larvae to the adult stage also was measured.At the lower density of original inhabitants, the mean proportions of effective eggs (number of effective eggs/number of eggs expected in an uninhabited culture) were not significantly different for the three competitor strains. The mean proportions were lower at the higher density (significantly so for the twoD. melanogaster competitors), and at this density, the mean proportion forD. melanogaster yw was significantly less than that forD. simulans st. These results are consistent with a simple egg destruction hypothesis, but suggest thatyw females were retaining more eggs at the higher density.Original inhabitants showed higher survival when at the higher density. Each of the three competitors caused a significantly different reduction in original inhabitant survival, which was directly related to competitor larval activity. Increasing larval activity probably reduced survival of original inhabitants by increasing pupal mortality due to drowning in the medium.Day of introduction of competitors influenced survival of original inhabitants and also the proportion of effective eggs from each competitor. The proportion of effective eggs decreased to the day 5 introduction. From day 5 to day 8, the proportion increased because the original inhabitants were pupating. After day 8, effective egg proportions again decreased, possibly due to inhibition of egg-laying or reduced survival of immature stages.     

Genomic imprinting of chromatin inDrosophila melanogaster

During gametogenesis, chromosomes may become imprinted with information which facilitates proper expression of the DNA in offspring. We have used a position effect variegation mutant as a reporter system to investigate the possibility of imprinting inDrosophila melanogaster. Genetic crosses were performed in which the variegating gene and a strong modifier of variegation were present either within the same parental genome or in opposite parental genomes in all possible combinations. Our results indicate that the presence of the variegating chromosome and a modifier chromosome in the same parental genome can alter the amount of variegation formed in progeny. The genomic imprinting we observed is not determined by the parental origin of the variegating chromosome but is instead determined by the genetic background the variegating chromosome is subjected to during gametogenesis.     

DNA sequence comparison of micropia transposable elements fromDrosophila hydei andDrosophila melanogaster

Members of the retrotransposon family micropia were discovered as constituents of wild-typeY chromosomal fertility genes fromDrosophila hydei. Several members of the micropia family have subsequently been recovered fromDrosophila melanogaster and four micropia elements, micropia-DhMiF2, -DhMiF8, -Dm11 and-Dm2, two each fromD. hydei andD. melanogaster, have been totally sequenced (17 kb of micropia sequences and 6.8 kb from insertions)¹. Comparative analysis of micropia sequences revealed a complex pattern of divergence within a singleDrosophila genome. The divergence includes deletions, possibly by a slipped mispairing mechanism, insertions of a retroposon, and of another retrotransposon (copia) and positional nucleotide shuffling within the tandem repeats of the 3 non-protein-coding region of micropia elements. A 10 bp long sequence of each repeat unit of the 3 tandem repeats of micropia elements is highly conserved and is therefore a candidate of functional importance either in transposition events or in regulatory activity on flanking DNA sequences.Abbreviations LTR long terminal repeat - PBS primer binding site - PolII RNA polymerase II - bp base pairs - kb kilobases (pairs) - LINE long interspersed sequence - MHC major histocompatibility complex This paper is dedicated to the 90^th birthday of Prof. Dr. Bernhard Rensch.     

Rates of movement of transposable elements inDrosophila melanogaster

Mobilization rates of nine families of transposable elements (P, hobo, FB, gypsy, 412, copia, blood, 297, andjockey) were estimated by using 182 lines. Lines were started from a completely isogenic population ofDrosophila melanogaster, carrying the markersepia as an indicator of possible contamination, and have been accumulating spontaneous mutations independently for 80 generations of brother-sister (or two double-first-cousin) matings. Transposable element movements have been analyzed in complete genomes by the Southern technique. Mobilization was a rare event, with an average rate of 10^?5 per site per generation. The most active element wasFB. In contrast, the retroelementsgypsy andblood did not move at all. Most changes in restriction patterns were consistent with rearrangements rather than with true transposition. The euchromatic or heterochromatic location of elements was tested by comparing insertion patterns from adults and salivary glands. Certain putative rearrangements involved heterochromatic copies of the retroelements412, copia or297. Clustering of movement across families was observed, suggesting that movement of different families may be non-independent. An association between modified insertion patterns and mutant effects on quantitative traits shows that spontaneous transposition events cause continuous variation.     

The occurrence of the transposable elementpogo inDrosophila melanogaster

We examined the genomic occurrence of the transposable elementpogo in over 120 strains ofDrosophila melanogaster, from around the world and from different eras. All had multiple copies of a 2.1 kilobase (kb)pogo element, and multiple copies of several size classes between 1.0 and 1.8 kb. There were differences between strains in intensities or presences of deletion-derivative size classes, suggesting current or recent mobility in the species. We were unable to find anypogo-hybridization in eight other species in the genus, in three subgenera, or in the relatedScaptomyza pallida. Thepogo element may be a ‘middle-aged’ element in the genome ofD. melanogaster, having entered the species since its divergence from its sibling species, but long before theP andhobo elements.     

Maintenance of transposable element copy number in natural populations of Drosophila melanogaster and D. simulans

To investigate the main forces controlling the containment of transposable elements (TE) in natural populations, we analyzed the copia, mdg1, and 412 elements in various populations of Drosophila melanogaster and D. simulans. A lower proportion of insertion sites on the X chromosome in comparison with the autosomes suggests that selection against the detrimental effects of TE insertions is the major force containing TE copies in populations of Drosophila. This selection effect hypothesis is strengthened by the absence of the negative correlation between recombination rate and TE copy number along the chromosomes, which was expected under the alternative ectopic exchange model (selection against the deleterious rearrangements promoted by recombination between TE insertions). A cline in 412 copy number in relation to latitude was observed among the natural populations of D. simulans, with very high numbers existing in some local populations (around 60 copies in a sample from Canberra, Australia). An apparent absence of selection effects in this Canberra sample and a value of transposition rate equal to 1–2 × 10^-3 whatever the population and its copy number agree with the idea of recent but temporarily drastic TE movements in local populations. The high values of transposition rate in D. simulans clearly disfavor the hypothesis that the low amount of transposable elements in this species could result from a low transposition rate. This revised version was published online in August 2006 with corrections to the Cover Date.     

Worldwide distribution of transposable element copy number in natural populations of Drosophila simulans

Abstract.— Transposable elements (TEs), which promote various kinds of mutations, constitute a large fraction of the genome. How they invade natural populations and species is therefore of fundamental importance for understanding the dynamics of genetic diversity and genome composition. On the basis of 85 samples of natural populations of Drosophila simulans , we report the distributions of the genome insertion site numbers of nine TEs that were chosen because they have a low average number of sites. Most populations were found to have 0–3 insertion sites, but some of them had a significantly higher number of sites for a given TE. The populations located in regions outside Africa had the highest number of sites for all elements except HMS Beagle and Coral , suggesting a recent increase in the activity of some TEs associated with the colonization patterns of Drosophila simulans . The element Tirant had a very distinctive pattern of distribution: it was identified mainly in populations from East Africa and some islands in the Indian Ocean, and its insertion site number was low in all these populations. The data suggest that the genome of the entire species of Drosophila simulans may be being invaded by TEs from populations in which they are present in high copy number.     

Distribution and conservation of the foldback transposable element inDrosophila

Summary Foldback elements are a family of transposable elements described inDrosophila melanogaster. The members of this dispersed repetitive family have terminal inverted repeats that sometimes flank a central region. The inverted repeats of all the family members are homologous.The study of the distribution and conservation of the foldback elements in differentDrosophila species shows that this distribution is different from that of the hybrid dysgenesis systems (PM and IR). Sequences homologous to foldback elements were observed by Southern blots and in situ hybridization in all species of themelanogaster subgroup and in some species of themontium andtakahashii subgroups. The element was probably already present before the radiation of these subgroups. No evidence of horizontal transmission of the foldback element could be observed.     

hobo transposable elements in Drosophila melanogaster and D. simulans.

Genomic patterns of occurrence of the transposable element hobo are polymorphic in the sibling species Drosophila melanogaster and D. simulans. Most tested strains of both species have apparently complete (3.0 kb) and smaller hobo elements (H lines), but in both species some strains completely lack such canonical hobo elements (E lines). The occurrence of H and E lines in D. simulans as well as in D. melanogaster implies that an hypothesis of recent introduction in the latter species is inadequate to explain the phylogenetic occurrence of hobo. Particular internally deleted elements, the approximately 1.5 kb Th1 and Th2 elements, are abundant in many lines of D. melanogaster, and an analogous 1.1 kb internally deleted element, h del sim, is abundant in most lines of D. simulans. Besides the canonical hobo sequences, both species (and their sibling species D. sechellia and D. mauritiana) have many hobo-hybridizing sequences per genome that do not appear to be closely related to the canonical hobo sequence.     

Differing amounts of genetic polymorphism in testes and male accessory glands ofDrosophila melanogaster andDrosophila simulans

We surveyed genetic polymorphism by two-dimensional gel electrophoresis of male reproductive tract proteins in 20 isofemale lines each ofDrosophila melanogaster andDrosophila simulans. After classifying 244 such proteins ofDrosophila melanogaster and 271 ofDrosophila simulans by their distribution between testes and accessory glands within the reproductive tract, significant correlations were found between genetic polymorphism and tissue distribution. In both species, gland-specific proteins were significantly more polymorphic than testis-specific proteins, as well as those found in both testes and glands. Simultaneously, inDrosophila simulans, proteins found in roughly equivalent relative abundance in both testes and glands were significantly less variable than gland-specific and testis-specific proteins, as well as those with a quantitative difference in relative abundance between testes and glands. These correlations may reflect general differences in variability between extracellular and intracellular proteins and between proteins with broad as opposed to tissue-specific distributions.We thank the Natural Sciences and Engineering Research Council of Canada for financial support (Grant A0235 to R.S.S.).     

The genetics and evolution of the mariner transposable element in Drosophila simulans: worldwide distribution and experimental population dynamics

We have studied both the frequency and biogeographical distribution of the transposable DNA element mariner in natural populations of Drosophila simulans and the short-term evolutionary characteristics of mariner in experimental populations. The mariner element has been identified in natural populations of D. simulans from Africa, Europe, the Middle East, Japan, Australia, several Pacific islands, North America, and South America. Only four lines out of 296 were devoid of active mariner elements, as measured by the presence of functional mariner transposase. A slight correlation was found between the latitudinal coordinate of the collection sites and the level of mariner activity in the population; this correlation became highly significant in Australia where a cline in mariner activity was observed along the eastern coast of the continent. We also observed that wild-type laboratory strains kept for several years as small populations might lose mariner activity over time. Using experimental populations, we modeled what might happen when naturally occurring populations exhibiting high and low levels of mariner activity encounter one another. We found that active mariner elements either will tend to lose their activity over time and gradually become inactive or possibly will be lost from the population; in either case, this will lead to the pattern seen in this experiment of a significant loss of mariner activity over time. This revised version was published online in July 2006 with corrections to the Cover Date.     

Genomic distribution of copia-like transposable elements in somatic tissues and during development of Drosophila melanogaster

The genomic distribution of elements of the copia, 412, B 104, mdg 1, mdg 4 and 1731 transposon families was compared by the Southern technique in DNA preparations extracted from brains, salivary glands and adult flies of two related Drosophila lines. The copia, 412 and mdg 1 sequences were also probed in DNA from sperm, embryos, and 1st and 2nd instar larvae. The homogeneity of the patterns observed shows that somatic transposition is unlikely to occur frequently. A correlation between mobility and the euchromatic or heterochromatic location of transposable elements is discussed. In addition, an explanation of the variable band intensities of transposable elements in Southern autoradiographs is proposed.     

The mariner transposable element in natural populations of Drosophila simulans

In cosmopolitan species, geographical variations in copy number and/or level of transposition activity have been observed for several transposable elements (TEs). Environment, history and population structure can contribute to such variation in ways that are difficult to tease apart. For the mariner element, previous studies of the geographic variation of its somatic activity in natural populations of Drosophila simulans have shown contradictory results (latitudinal clines of divergent orientations or no apparent structure). To try and resolve these inconsistencies, we gathered all available data on the mariner somatic activity of worldwide natural populations. This includes previously published results by different groups and also new data. The correlations between the level of activity and several geoclimatic factors were tested. Although no general effect of temperature was found, a relationship with the invasion history was detected. It was also shown that recent invasive populations have a higher level of activity than the putative ancestral ones. Our results strongly suggest that variability of the mariner somatic activity among natural populations of D. simulans is mainly due to populational and historical factors probably related to the recent world colonization of this species. Indeed, this activity is correlated to the main route out of Africa (the Nile route) and the recent colonization of continents such as Australia and South America.     

P transposable element in Drosophila melanogaster: horizontal transfer]

The P transposable element family in Drosophila melanogaster is responsible for the syndrome of hybrid dysgenesis which includes chromosomal rearrangements, male recombination, high mutability and temperature sensitive agametic sterility (called gonadal dysgenesis sterility). P element activity is controlled by a complex regulation system, encoded by the elements themselves, which keeps their transposition rate low within the strain bearing P elements and limits copy number by genome. A second regulatory mechanism, which acts on the level of RNA processing, prevents P mobility to somatic cells. The oldest available strains, representing most major geographical regions of the world, exhibited no detectable hybridization to the P-element. In contrast, all recently collected natural populations that were tested carried P-element sequences. The available evidence is consistent with the hypothesis of a worldwide P-element invasion of D. melanogaster during the past 30 years. Timing and direction of the invasion are discussed. The lack of P-element in older strains of Drosophila melanogaster as well as in the species must closely related to Drosophila melanogaster, suggests that P entered the Drosophila melanogaster genome recently, probably by horizontal transfer from an other species. The analysis of P-element elsewhere in the genus Drosophila reveals that several more distantly related species carried transposable elements with sequences quite similar to P. The species with the best-matching P-element is D. willistoni. A P-element from this species was found to match all but one of the 2907 nucleotides of the Drosophila melanogaster P-element. The phylogenic distributions and the likely horizontal transfers of the two other Drosophila transposable elements are discussed.     

Germ line abnormalities InDrosophila simulans transfected with the transposable P element

A strain ofDrosophila simulans was studied 40 generations after the transposable P element had been introduced into the genome by means of transformation. The genome also contained arosy transposon consisting of the wildtype allele of therosy gene flanked by P element DNA. During the 40 generations of evolution the number of P elements had increased to the level of 8–15 and the number ofrosy transposons to the level of 4–12. Continued transpositional activity in the germ line of the strain was evidenced by deletions occurring in therosy transposon and, in two independent sublines, by the transposition of therosy transposon from the X chromosome to the autosomes. Although at 25°C gonadal development and fertility appeared normal in both sexes, at 29°C both sexes were sterile. The sterile females had morphologically normal ovaries, but the sterile males often had shrunken, dysmorphic testes containing few or no immature sperm bundles. However, the sterility found in the transfected strain may not result directly from transpositional activity of the P element. The characteristics of theD. simulans strain infected with the P element are discussed in the context of factors that influence hybrid dysgenesis inD. melanogaster.     

Ontogeny and tissue distribution of alcohol dehydrogenase inDrosophila melanogaster

Summary Alcohol dehydrogenase (ADH) activity inDrosophila larvae and adults is localized primarily in fat body, intestine, and Malpighian tubules. In adult males, it occurs furthermore in derivatives of the genital disk.When expressed as ADH activity/whole organism, increasing values are found throughout the larval stages. Around the time of puparium formation, the activity decreases, to increase again around hatching of the adult.As the genital disk undergoes metamorphosis, it synthesizes (or activates) ADH rather than acquiring the enzyme from elsewhere in the organism.

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Zusammenfassung Alkohol-Dehydrogenase(ADH)-Aktivität kommt inDrasophila-Larven und Imagines hauptsächlich im Fettkörper, Verdauungstrakt und Malpighischen Gefäßen vor. In männlichen Imagines findet man das Enzym zudem in Derivaten der Genital-Imaginalscheiben.Ausgedrückt alsADH- Aktivität/Organismus, steigen dieADH-Werte während der Larvenstadien stetig an. Um die Zeit der Pupariumbildung nehmen sie dann ab und um die Schlüpfzeit zur Imago wieder zu.Während der Metamorphose synthetisiert (oder aktiviert) die männliche Genitalscheibe ADH; das Enzym wird nicht aus der Umgebung angereichert.

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Research supported by NSF grant GB 7803 and NIH Training Grant HD-139.