Transpositions of mobile dispersed genes in Drosophila melanogaster and fitness of stocks

Summary In situ hybridization with polytene chromosomes was used to demonstrate the transposition of mobile dispersed genes (mdg)-1 and 3 following the selection of flies from low reproductive activity and vability (LA stock) for high reproductive activity, viability and fitness (LA⁺ and HA stocks).The inbred LA stock is continuously selected for low reproductive activity and viability and maintains at least for twentyfive generations a characteristic pattern of mdg-1 distribution in 14–15 sites. Inbred LA⁺ and HA stocks exhibit a changed pattern of mdg-1 locations and the number of sites reaches 21–25. Parallel and independent selection for higher viability may lead to similar characteristic changes in the localization of mdg-1.In several independent experiments we observed, within one generation, a spontaneous and saltatory growth of viability and fitness in the mass-bred LA stock. In these cases new mdg-1 and mdg-3 sites reproducibly appeared to within several bands, some of them characteristic of LA⁺ and HA stocks.We discuss the possible role of mdg in determining the quantitative characters of individuals and their fitness.     

Clusters containing different mobile dispersed genes in the genome of Drosophila melanogaster.

Ten clones containing the actively transcribed mobile dispersed gene Dm255 and its flanking sequences were selected from the HindIII bank of the Drosophila melanogaster genome. The Dm225 sequences present in these clones were identical while the flanking sequences were different in all of the clones analysed. Four of them contained, in addition to Dm225, other DNA sequences binding high amounts of cytoplasmic poly(A) + RNA. The properties of these new genes are similar to those of Dm255: they are also actively transcribed, multiple in copies, scattered throughout the genome, and located at varying genome sites which also were scattered throughout the whole genome of D. melanogaster. Thus, different mobile dispersed genes often appear as closely apposing units forming gene clusters in the genome.     

Distribution of mobile dispersed genes (mdg-1 and mdg-3) in the chromosomes of Drosophila melanogaster

The localization of mobile dispersed genes (mdg-1 and mdg-3) was studied by in situ hybridization with the polytene chromosomes of 20 laboratory stocks of Drosophila melanogaster. The average number of sites was 20 for mdg-1 and 12 for mdg-3, but the actual number varied from stock to stock (14–27 for mdg-1 and 5–18 for mdg-3). A total of 182 possible sites have been detected for mdg-1 and 123 sites for mdg-3. In spite of the individual and interstock variation, the distribution over chromosomes was found to be nonrandom for mdg-3 and especially for mdg-1. Frequently occurring sites of mdg-1 hybridization were revealed, most of which coincided with regions of intercalary heterochromatin, especially in chromosome 2.     

Mobile dispersed genetic element MDG1 of Drosophila melanogaster: structural organization.

The whole-length mobile dispersed genetic element mdg1 has been cloned from D. melanogaster genome. It contains DNA fragments described earlier as Dm225 and Dm234, Mdg1 is 7.2 kb long and framed with two direct repeats of 300-400 base pairs each. Mdg1 family is represented by about 25 copies in the genome of flies and by 200 copies in the genome of cultured cell line 67J25D. Virtually all the copies in the genome of D. melanogaster have the same restriction map. Oligo(dA)-oligo(dT) regions were found within mdg1.     

Transposition bursts in analysis of repeated mutations in unstable strains of Drosophila melanogaster

The phenomenon of transposition memory was earlier demonstrated for the cut locus and mdg4. This work has been aimed at finding out, in what way the transposition memory can be realized. An unstable stock cmMR17ctMRpN17 was analysed which had high frequency of double cm+ct+ reversions and cmMRctMRpN repeated mutations. A series of five such transpositions could be followed. The ctMRpN17 mutation is a result of insertion at the cut locus mdg4 with the jockey element inserted within it. As seen from in situ hybridization analysis, transitions to the normal phenotype correlate, as a rule, with the excision of mdg4 and the jockey from the cut locus. Analysis of distribution of mdg1, mdg2, mdg3 and jockey on the X-chromosome of unstable revertants and repeated mutants indicated that not only transpositions of mdg4 and jockey, but also those of all mobile elements tested occur. So, we propose that the transposition memory in our genetic system is manifested in the process of transposition bursts.     

Deleterious mutations in various Drosophila melanogaster strains carrying meiotic mutation c(3)G

In the absence of meiotic recombination, deleterious mutations, decreasing the viability, are accumulated and fixed in small Drosophila populations. Study of the viability of hybrid progenies of three laboratory Drosophila melanogaster strains carrying meiotic mutation c(3)G17 has suggested that the deleterious mutations are negatively synergistic in their interaction. The deleterious mutations localized to the pericentromeric region of chromosome 3 are threefold more efficient as compared with the mutations located in distal regions. Substitution of a new chromosome for the balancer chromosome in a strain with meiotic mutation c(3)G17 partially restores (by approximately 20%) the viability of homozygotes c(3)G17/c(3)G17 over the first 20-30 generations. Further cultivation for 30 generations with the same balancer again decreases the viability to the initial level. An epigenetic nature of deleterious mutations is discussed.     

Mobile dispersed genetic element MDG1 of Drosophila melanogaster: nucleotide sequence of long terminal repeats.

Long terminal repeats (LTRs) of two members of mdg1 family were sequenced. In the both cases, they are represented by perfect direct repeats 442 and 444 bp in length. Sixteen nucleotides in the LTRs of two different mdg1 elements are different. Each LTR contains slightly mismatched 16-nucleotide inverted repeats located at the ends of the LTR. Six base pairs closest to the termini of LTR form perfect inverted repeats. On the gene-distal sides of LTRs, short 4-nucleotide direct repeats are located, probably representing the duplication of a target DNA sequence arising from insertion of mdg. They are different in the two cases analyzed. Just as the other analyzed eukaryotic transposable elements, mdg1 starts with TGT and ends with ACA. Within the both strands of LTR, the sequences similar to Hogness box (a putative signal for RNA initiation, or a selector) and AATAAA blocks (putative polyadenylation signals) are present. The LTR of mdg1 contains many short direct and inverted repetitive sequences. These include a 10-nucleotide sequence forming a perfect direct repeat with the first ten nucleotides of the LTR. A region of LTR about 70 bp long is represented by simple repetitive sequences (TAT).     

Variation among the dispersed (GATA)n sequences in Drosophila melanogaster

Five nonallelic copies of the dispersed (GATA)n repeated sequence of Drosophila melanogaster (referred to as GATA elements) have been sequenced and analysed. The GATA elements range in size from 111 to 444 bp, consisting predominantly of tandemly repeated GATAs, interspersed with variants of the subunit. The types and distributions of these variants are consistent with the hypothesis that they have arisen by a random accumulation of point mutations (substitutions, deletions, and insertions) in pure (GATA)n sequences. Duplications or deletions of the GATA subunit, and of GATA variants, have also probably occurred, as a result of either unequal crossing-over or slipped-strand mispairing. Evidence for duplication (deletion) has been obtained from a comparison of two allelic GATA elements isolated from different populations. GATA elements, in common with other dispersed, simple repeats, are probably highly variable in length.     

A comparative study of the location of mobile dispersed genes in salivary gland and midgut polytene chromosomes of Drosophila melanogaster

The location of DNA fragments representing mobile dispersed genes (MDG) in salivary gland and midgut polytene chromosomes was compared by means of in situ hybridization. In the Drosophila stock under study the average number of hybridization sites in the polytene chromosomes of one nucleus was 20 for MDG-1 and 10 for MDG-3. The total numbers of hybridization sites and their relative positions proved to be same in the polytene chromosomes of the two tissues. These results support the idea of a stable location of the mobile dispersed genes in the course of ontogenesis.     

Successive transposition explosions in Drosophila melanogaster and reverse transpositions of mobile dispersed genetic elements

Transposition outbursts occur in the destabilized Drosophila melanogaster strain ct^MR2 carrying a mutation in the locus cut induced by an insertion of mdg4. While the distribution of mobile genetic elements remained unchanged in the great majority of germ cells, in a few cells numerous transpositions had occurred involving mdg (copia-like), fold-back and P-elements. We used in situ hybridization to analyze the distribution of five families of mdg elements in the X-chromosome during several consequent mutational changes in D. melanogaster. Each of them was accompanied by many changes in mdg localization, all of which occurred in one and the same cell. Thus, we could observe the series consisting of up to five successive transposition explosions leading to an almost complete change in the distribution of the mdg elements tested. We also found that in the course of successive transposition explosions, mdg elements often inserted into those sub-sections of the X-chromosome where they had previously been located. This phenomenon, designated as reverse directed transposition, was studied in more detail on insertion into the locus yellow. The rate of reverse transposition of the same mdg element to the corresponding locus was 10–100 times as high as that of primary insertion. In some cases, `the transposon shuttle' into and out of the locus was observed. The existence of `transposition memory' partially explains the specificity of mdg localization in closely related strains as well as the co-ordinated behaviour of different mdg elements in independent transposition explosions. The evolutionary significance of transposition explosions and directed reverse transposition (transposon shuttle) is discussed.     

Mobile Genetic Element gypsy(MDG4) in Drosophila melanogasterStrains: Structural Characteristics and Regulation of Transposition

Distribution of two structural functional variants of the gypsy(MDG4) mobile genetic element was examined in 44 strains of Drosophila melenogaster. The results obtained suggest that less transpositionally active gypsyvariant is more ancient component of the Drosophilagenome. Using Southern blotting, five strains characterized by increased copy number of gypsywith significant prevalence of the active variant over the less active one were selected for further analysis. Genetic analysis of these strains led to the suggestion that some of them carry factors that mobilize gypsyindependently from the cellular flamencogene known to be responsible for transposition of this element. Other strains probably contained a suppressor of the flam ^–mutant allele causing active transpositions of the gypsy. Thus, the material for studying poorly examined relationships between the retrovirus and the host cell genome was obtained.     

Transposition of the bobbed locus in Drosophila melanogaster

Due to the complete absence of ribosomal DNA (genetic symbol bb-), the Xbb- chromosome of Drosophila is lethal both in homozygous conditions and in compound with the Xbb- chromosome. However, in the cross between the C(1)RM/Ybb- females and the Xbb-/BSYbb+ males, characterized by the development of lethal Xbb-/Ybb- zygotes, two fertile males were detected. These males possessed all the markers of the Xbb- chromosome but lacked the Y chromosome BS marker. Genetic analysis of their progeny showed that genes responsible for restoration of viability and fertility of these exceptional males were associated with the X chromosome. The crossover tests showed that in one case these genes were tightly linked to the w locus (the bbAM1 allele), and in the second case they were located 12.6 map units to the right of the Tu locus (the bbAM7 allele). It has also been shown that the bb locus was transposed to the X chromosome within the short arm of Y chromosome. Transposition of the BSYbb+ chromosome-specific rDNA sequences to the X chromosome was confirmed by means of Southern blotting. These data indicate that replacement of the bb locus is realized by transposition rather than recombination.