Structural organization of transposable element mdg4 from Drosophila melanogaster and a nucleotide sequence of its long terminal repeats

A mobile dispersed genetic element, mdg4 , approximately 7.5 kilobases (kb) long has been cloned from D. melanogaster genome. Chromosomal bands have only few sites of mdg4 , but it always hybridizes to the chromocenter. The location of mdg4 varies among D. melanogaster strains. Blot hybridization shows that, in contrast to other mdg elements, mdg4 sequences are rather heterogeneous. Only few copies are full-length. A strong amplification of mdg4 has occurred during the in vitro cultivation of cells involving only one mdg4 variant. Long terminal repeats (LTRs) and flanking sequences have been sequenced in two cloned copies of transposable element mdg4 . In both cloned copies of mdg4 , LTRs have an identical nucleotide sequence 479 bp long. The mdg4 is flanked by four-base-pair direct repeats, short mismatched palindromes being present at the ends of each LTR. The termini of the mdg4 body contain an oligopurine stretch and a region partially complementary to D. melanogaster tRNA-Lys. Thus, structural organization of mdg4 LTRs is similar to that of several other mdg elements and retroviral proviruses.     

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.     

A novel transposition system in Drosophila melanogaster depending on the Stalker mobile genetic element.

Crosses between the Drosophila melanogaster y2sc1waG strain or some of its derivatives and the FM4 strain yielded insertional mutagenesis with a frequency of 10(-3)-10(-4). The system differs in several respects from the known cases of hybrid dysgenesis: (i) it does not depend on the direction of a cross; (ii) destabilization continues for a long time after initial crosses; (iii) mutations may occur at different stages of development. The mutation in the yellow locus has been cloned and found to depend on insertion into the coding region of the gene of a novel mobile genetic element designated as Stalker. The sequencing of Stalker termini reveals 405 bp direct repeats (LTRs) and a target 3 bp duplication, as well as some other sequences typical of retrovirus-like retrotransposons. The number of Stalker copies per genome and chromosomal localization vary among D. melanogaster strains. Before crosses, the location of Stalker on chromosomes is fairly stable in a particular strain but thereafter numerous changes in Stalker distribution take place. Most novel substrains are internally heterogenous which is indicative of the continuing Stalker transposition. Other mobile elements tested do not move. Possibly, only Stalker is mobilized in the system. Many known and novel mutations have been obtained. Comparison of their genetic localization with Stalker distribution suggests that the majority of them have been induced by the Stalker insertion.     

The transposable element Mdg3 in Drosophila melanogaster is flanked with the perfect direct and mismatched inverted repeats.

MDg3 is a family of mobile dispersed genetic elements represented by 15 copies in the haploid genome of D. melanogaster and flanked, like other similar elements, by the regions of homology. In the present work, these regions of mdg3 have been sequenced. The existence of perfect direct repeats 268 base pairs long has been demonstrated. Inverted repeats are located on the gene distal side of them. It is possible to construct a perfect 8 b.p. palindrome or a slightly mismatched 18 b.p. palindrome. The inverted repeats are flanked by two short 5 b.p. direct repeats.     

Mobile dispersed genetic elements in eukaryotes and their possible relationship to carcinogenesis

During last three years, the mobile dispersed genetic elements (mdg) were isolated from the genome of Drosophila melanogaster, yeasts and mammals. According to a number of their properties, mdg elements are quite similar to endogenous pro-retroviruses. It is known that in many cases oncogeneity of retroviruses depends on the incorporation of the certain host genes (potential oncogenes) into the viral genome. We suggest that in some cases mdg elements could entrap the potential oncogenes in the course of transposition. As a result, oncogenes become uncontrollable by host regulatory systems and may induce cell transformation. Another possible mechanism underlying switch off of the gene responsible for differentiation control may be mdg transposition to a region in close vicinity of the gene. As transposition of mdg elements seems to occur rather often, they may be regarded as one of the most important factors of genome rearrangements leading to cell transformation.     

MDG1het and aurora--non-mobile retrotransposons of Drosophila melanogaster]

Non-mobile retrotransposons mdg1het and aurora localized in Drosophila melanogaster heterochromatin were studied. A novel retrotransposon aurora comprising 324 bp LTRs was revealed as a 5 kb insertion causing 5 bp duplication of integration site in the heterochromatic Stellate gene. All the aurora copies are immobilized in D. melanogaster heterochromatin and adjoining chromosome regions 40, 41C and 80BC. Mobile aurora copies were revealed in D. simulans euchromatin by in situ hybridization technique. A comparison of 2.5 kb sequence of immobile mdg1het (including a half of ORF2 and 3'-LTR) with the correspondent sequence of transposable mdg1 copy [9] allowed to conclude that evolution of mdg1 subfamilies occurred under the selective pressure for the ability to transpose. The time period passed since the aurora and mdg1 copies integrated in heterochromatin was roughly estimated via divergence extent between the left and right LTR; for aurora copy it is 0-0.15 Myr, and for mdg1het copies it is 0-0.7 Myr.     

The nature of unstable insertion mutations and reversions in the locus cut of Drosophila melanogaster: molecular mechanism of transposition memory

The segment of the locus cut containing the mobile genetic element mdg4 (gypsy) insertions which induce unstable ct^MR2 and ct^MRpN10 mutations has been cloned. Both mutations depend on the insertion of mdg4 into the same sequence, which coincides with that in ct⁶ allele. The ct^MRpN10 mutation differs from ct^MR2 by additional insertion of a novel mobile element jockey into mdg4. Jockey is 2.8 kb long, represented by ˜2–100 copies per genome, very homogeneous and lacks long terminal repeats (LTRs). The excision of mdg4 takes place in stable ct⁺ reversions. On the other hand, a complete single LTR is retained in the case of unstable ct reversions characterized by a high level of reverse directed transpositions of mdg4 into the locus cut. The LTR serves as a guide for reinsertion of mdg4 itself or mdg4 with jockey into the same site of the genome. A possible mechanism of transposition memory (homologous recombination with extrachromosomal circular DNA) is discussed.