Independent regulation of mobile element copy number in Drosophila melanogaster inbred lines

Distribution of P and hobo mobile elements in environmentally manipulated long-term Drosophila melanogaster cage populations

The copy number and the chromosome positions of the P and hobo insertions were determined by means of in situ hybridization to polytene chromosomes, in five long-term Drosophila melanogaster cage populations kept for 18 years under different culture conditions (temperature and relative humidity). The analysis revealed that the copy number of both P and hobo elements were similar between the populations kept under the same culture conditions and significantly different among the populations maintained under different culture conditions. A tendency for similar distribution of these elements along the major chromosome arms was also observed in the populations of the same environmental manipulation. The distribution of the insertions along the chromosomes was not random for both the P and hobo elements; sites with high insertion frequencies were found (hot spots of occupation). Some of them were common in all cage populations while others were characteristic of the populations kept under the same conditions. Finally, fixed sites of occupation were also observed in all populations and refer mostly to hobo distribution. The data are discussed on the basis of the possible involvement of the P and hobo elements, in some way, to the adaptation process and speciation.

A three-season comparative analysis of the chromosomal distribution of P and hobo mobile elements in a natural population of Drosophila melanogaster

An analysis on the chromosomal distribution of P and hobo elements in a Greek natural population extending over three seasons showed that the P elements were more abundant in the population than hobos. The copy number distribution per chromosome arm was in general random. The X chromosome had more P copies and the 3R arm more hobos in all three collections. Significant seasonal differences were not observed for these two elements in relation to the total number of insertions per haploid genome. There were, however, certain seasonal differences. They involved the copy number variability, the intra-arm distribution, the distribution along the chromosomes, and the spread and occupancy frequencies. There were no significant differences between the copy numbers of the two elements carried by the standard and the corresponding inverted regions for a number of inversions found in the population. Finally, three out of the five cosmopolitan inversions were found to have hobo insertions at or very near the one of the two breakpoints. Three out of the total had P insertions at or very near the one of the two breakpoints in some squashes and two of the three endemic inversions had a hobo insertion at or very near the one breakpoint, while the third had a P insertion.

Population dynamics of the copia, mdg1, mdg3, gypsy, and P transposable elements in a natural population of Drosophila melanogaster

The insertion site polymorphism of the copia, mdg1, mdg3, gypsy, and P transposable elements was analysed by in situ hybridization to the polytene chromosomes in genomes of males from a natural population of Drosophila melanogaster. Parameters of various theoretical models of the population biology of transposable elements were estimated from our data, and different hypotheses explaining TE copy number containment were tested. The copia, mdg1 and gypsy elements show evidence for a deficiency of insertions on the X chromosomes, a result consistent with selection against the mutational effects of insertions. On the contrary, mdg3 and P copy numbers fit a neutral model with a balance between regulated transposition and excisions. There is no strong evidence of a systematic accumulation of elements in the distal and proximal regions of the chromosomes where crossing over and ectopic exchanges are reduced. For all chromosome arms but 3L, however, the TE site density increases from the proximal to the distal parts of the chromosomes (the centromeric regions were excluded in this analysis) with sometimes a sharp decrease in density at the extreme tip, following in part the exchange coefficient. The way the copy number of TEs is contained in genomes depends thus on the element considered, and on various forces acting simultaneously, indicating that models of TE dynamics should include details of each element.

Invasion of the hobo transposable element studied by in situ hybridization on polytene chromosomes of Drosophila melanogaster

The invasion kinetics of hobo transposable element in the Drosophila melanogaster genome was studied by in situ hybridization on the polytene chromosomes. Six independent lines of Drosophila melanogaster flies that had been previously transformed by microinjection of the pHFL1 plasmid containing a complete hobo element were followed over 50 generations. We observed that hobo elements were scattered on each of the chromosome arms, with more insertion sites on the 3R arm. The total number of insertion sites remains quite small, between four and six, at generation 52. On the 2R arm, a short inversion appeared once at generation 52. Most of the integration sites reported here were already described for several transposons but some of them appear to be hotspots for hobo elements.

I-R hybrid dysgenesis in Drosophila melanogaster. Use of in situ hybridization to show the association of I factor DNA with induced sex-linked recessive lethals

The purpose of this paper is the genetic visualization by in situ hybridization of 130 sex-linked recessive lethals plus a non-lethal induced by I-R dysgenesis. This collection of lethals involves inducer strains which differ in the position of the I elements on the X chromosomes. The I-R interaction was strong. Our previous results have shown that about 30% of the induced recessive lethals are associated with cytologically visible chromosomal rearrangements. (1) The rearrangements induced by I-R-type hybrid dysgenesis often exhibit homology with the I factor at the level of one or both junction points, depending on the types of chromosome rearrangements. These results suggest that the chromosome rearrangements arise directly from the transposition of I elements. However, the breakpoints of some types of cytologically non-visible deficiencies and of 2 small cytologically visible deficiencies do not present detectable homology with the I factor. (2) The majority of rearrangements do not involve the I elements already present on the paternal X chromosome. (3) The hybridization signal distributions on the X chromosome are not uniform. They present peaks of various heights which may correspond to specific anchoring areas of copies of I in the course of integration. (4) The data presented here agree with the literature with respect to the mean number of copies of I per X chromosome and to the excess of copies of I at locus 1A. Two rearrangement formation mechanisms are envisaged: crossing-over and 'target' exchanges.

Population genetics of transposable DNA elements. A Drosophila point of view

This paper is an attempt to bring together the various, dispersed data published in the literature on insertion polymorphism of transposable elements from various kinds of populations (natural populations, laboratory strains, isofemale and inbred lines). Although the results deal mainly with Drosophila, data on other organisms have been incorporated when necessary to illustrate the discussion. The data pertinent to the regions of insertion, the rates of transposition and excision, the copy number regulation, and the degree of heterozygosity were analysed in order to be confronted with the speculations made with various theoretical models of population biology of transposable elements. The parameters of these models are very sensitive to the values of the transposable element characteristics estimated on populations, and according to the difficulties of these estimations (population not at equilibrium, particular mutations used to estimate the transposition and excision rates, trouble with the in situ technique used to localize the insertions, undesired mobilization of TEs in crosses, spontaneous genome resetting, environmental effects, etc.) it cannot be decided accurately which model better accounts for the population dynamics of these TEs. Tendencies, however, emerge in Drosophila: the copia element shows evidence for deficiency of insertions on the X chromosomes, a result consistent with selection against mutational effects of copia insertions; the P element repartition does not significantly deviate from the neutral assumption, in spite of a systematic copy number of insertions higher on the X than on the autosomes. Data on other elements support either the neutral model of TE containment, neither of the two models, or both. Prudence in conclusion should then be de rigueur when dealing with such kind of data. Finally the potential roles of TEs in population adaptation and evolution are discussed.

The role of the transposable element hobo in the origin of endemic inversions in wild populations of Drosophila melanogaster

Evidence from in situ hybridizations of DNA from the transposable element hobo to polytene salivary gland chromosome squashes reveals that hobo occupies both cytological breakpoints of three of four endemic inversions sampled from natural populations of Drosophila melanogaster in the Hawaiian islands. The fourth endemic inversion has a single hobo insert at one breakpoint. Cosmopolitan inversions on the same chromosomes do not show this association. Frequencies of both endemic and cosmopolitan inversions in Hawaiian populations fall in ranges typical for natural populations of D. melanogaster sampled worldwide, suggesting that these results may be typical of other regions besides Hawaii. This appears to be the first direct demonstration that transposable elements are responsible for causing specific rearrangements found in nature; consequently, it is also the first direct demonstration that chromosome rearrangements can arise in nature in a manner predicted by results of hybrid dysgenic crosses in the laboratory. Possible population genetic and evolutionary consequences are discussed.

Localization of P elements, copy number regulation, and cytotype determination in Drosophila melanogaster

Seventeen highly-inbred lines of Drosophila melanogaster extracted from an M' strain (in the P/M system of hybrid dysgenesis) were studied for their cytotype and the number and chromosomal location of complete and defective P elements. While most lines were of M cytotype, three presented a P cytotype (the condition that represses P-element activity) and one was intermediate between M and P. All lines were found to possess KP elements and only eight to bear full-sized P elements. Only the lines with full-sized P elements showed detectable changes in their P-insertion pattern over generations; their rates of gain and of loss of P-element sites were equal to 0.12 and 0.09 per genome, per generation, respectively. There was no correlation between these two rates within lines, suggesting independent transpositions and excisions in the inbred genomes. The results of both Southern blot analysis and in situ hybridization of probes made from left and right sides of the P element strongly suggested the presence of a putative complete P element in region 1A of the X chromosome in the three lines with a P cytotype; the absence of P copy in this 1A region in lines with an M cytotype, favours the hypothesis that the P element inserted in 1A could play a major role in the P-cytotype determination. Insertion of a defective 2 kb P element was also observed in region 93F in 9 of the 13 M lines. The regulation of the P-element copy number in our lines appeared not to be associated with the ratio of full-length and defective P elements.

Copy number and distribution of P and I mobile elements in Drosophila melanogaster populations

The distribution of the number of copies of P and I transposable elements per genome was investigated by in situ hybridization for a large set of Drosophila melanogaster strains. These included the P, Q and M' types of the P-M system of hybrid dysgenesis. P element copy number varied widely (range 5-59). P and Q strains had around 40 copies whereas M' strains generally had lower numbers (between 5 and 35) with one extreme value (52). The copy number of I elements appeared to be precisely regulated, as no strains were found outside the 15 +/- 5 range. The number of copies of the two families were independent. An excess of P copies on the X chromosome compared with the autosomes was found for the P and Q strains, but not for M' strains. Among X-inserted P sites, a very high frequency of occupation was found at the tip of the X chromosome (cytological site 1A), especially for P and Q strains. The possible regulatory role in the P-M system of X-inserted P sites is discussed.

Interactions between transposable elements for insertion in the Drosophila melanogaster genome

Using in situ hybridization to polytene salivary gland chromosomes, we have registered the co-occurrences of insertions of the four mobile elements, copia, mdg-1, I and P in the whole genomes of 17 highly-inbred lines of Drosophila melanogaster (the insertions in the centromeric regions were excluded); these elements differ in structure, DNA sequence and profile of developmental transcription. The mdg-1 and P elements tend to avoid each other on the X chromosomes but not on the autosomes; copia and mdg-1, two copia-like elements, show an excess of co-occurrences on the 2L and 3R chromosome arms but not on the X chromosomes. The pairs mdg-1/I, I/copia, I/P and copia/P do not show any kind of interaction. Populational studies are thus necessary to obtain complete accurate information on interactions between transposable elements for their sites of insertion in a genome.

I elements of Drosophila melanogaster generate specific chromosomal rearrangements during transposition

We report a detailed molecular analysis of three chromosomal rearrangements, which have been produced during I-R hybrid dysgenesis in Drosophila melanogaster. They all disrupt the yellow gene. One of them is a deletion; the other two are inversions, which may be interpreted as the results of recombination events between I elements inserted at their break points. These events appear to occur at the time of transposition and involve integrating rather than resident I elements. They are produced by a mechanism very similar to homologous ectopic recombination.