Evidence for horizontal transfer of the LTR retrotransposon mdg3, which lacks an env gene

Horizontal (interspecific) transfer is regarded as a possible strategy for the propagation of transposable elements through evolutionary time. To date, however, conclusive evidence that transposable elements are capable of horizontal transfer from one species to another has been limited to class II or DNA-type elements. We tested the possibility of such transfer for several Drosophila melanogaster LTR retrotransposons of the gypsy group in an experiment in which D. melanogaster and D. virilis somatic cell lines were used as donor and recipient cells, respectively. This approach was chosen in light of the high levels of LTR retrotransposon amplification and expression observed in cultured D. melanogaster cells. In the course of the experiment, parallel analysis for mdg1, mdg3, 17.6, 297, 412 and B104/roo retrotransposons was performed to detect their presence in the genome of recipient cells. Only the mdg3 retrotransposon, which lacks an env gene, was found to be transmitted into recipient cells. This model, based on the use of cultured cells, is a promising system for further investigating the mechanisms of LTR retrotransposon transfer.     

Retrotransposon mdg3 Is Transferred between Somatic Cells of Unrelated Species in Mixed Culture

Since retrovirus-like particles of gypsy (mdg4) are capable of interspecific transfer, other Drosophila melanogaster gypsy-related retrotransposons were tested for this property. As a donor and a recipient, D. melanogaster and D. virilis cultured cells were used. Recipient cell DNA was analyzed with probes directed to mdg1, mdg3, 17.6, 297, 412, or B104/roo. Transfer was demonstrated for mdg3, which lacks env. The possible mechanism of transfer is discussed.     

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.     

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.     

Mobilization of retrotransposon copia in the Drosophila melanogaster genome]

Considerable heterogeneity of retrotransposon copia sites of location on polytene chromosomes was revealed in one of the substocks of the inbred Drosophila melanogaster stock. Heterogeneity of copia sites of location was found in no other substocks analyzed. The heterogeneity was shown to be caused by copia insertions in new sites. The frequency of insertions is about 12% per haploid genome per generation. The retrotransposon excisions and somatic transpositions were not observed. The location of retrotransposons mdg1, mdg2, mdg3, mdg4, 297 and H.M.S. Beagle appeared to be stable in all the stocks analyzed. Thus, a model system allowing to study mechanisms of retrotransposon copia transpositions in D. melanogaster tissues as well as phenotypic effects of copia mobilization is described.     

The endogenous Drosophila melanogaster retrovirus gypsy can propagate in Drosophila hydei cells

The endogenous Drosophila melanogaster retrovirus gypsy (mdg4) forms virus-like particles (VLPs) which are found as extracellular particles in the medium used to culture D. melanogaster cells. The D. hydei somatic cell line DH14, which does not harbour gypsy sequences, was exposed to D. melanogaster VLPs. Subsequent PCR and Southern analysis revealed that gypsy elements had penetrated into the D. hydei cells, suggesting interspecific transmission of the retrovirus. A D. hydei cell line containing gypsy sequences was established and grown in a mixed culture together with the G418-resistant D. hydei cell line DH33, and gypsy was shown to be transmitted from cell to cell. The proportion of cells carrying gypsy increased with time. The rate of gypsy invasion of the lines DH14 and DH33 was 10(-3) and 10(-2) per cell per generation, respectively. The results demonstrate the possibility of interspecific horizontal transfer of gypsy in the form of its VLPs.     

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.     

Genetic instability and transposition of mobile element mdg4 in a mutator strain of Drosophila melanogaster

Laboratory mutator strain of Drosophila melanogaster is characterized by increased (up to 10(-3)-10(-4) frequency of spontaneous mutability. Mutations appear in premeiotic stages of gametes development. The majority of mutations were unstable (high frequencies of reversions, appearance of new mutations at the same and other loci, replicating instability). Localization of mobile elements mdg1, mdg2, mdg3, mdg4, copia and P element in X chromosomes of mutator individuals and its mutations y, ct, sbt was studied by hybridization in situ. In all strains P element was absent. The distribution of mdg1, mdg2, mdg3 and copia was identical in mutator strains and its derivatives, but distribution of mdg4 was different. The essential heterogeneity in localization of mdg4 and increased (up to 30-40) copy number in the mutator strain individuals was observed. The ability of single element mdg4 to autonomous transpositions was thus shown.     

Structural heterogeneity and genomic distribution of Drosophila melanogaster LTR-retrotransposons

Structural heterogeneity of five long terminal repeat (LTR) retrotransposon families (297, mdg 1, 412, copia, and 1731) was investigated in Drosophila melanogaster. The genomic distribution of canonical and rearranged elements was studied by comparing hybridization patterns of Southern blots on salivary glands from adult females and males with in situ hybridization on polytene chromosomes. The proportion and genomic distribution of noncanonical copies is distinctive to each family and presents constant features in the four different D. melanogaster strains studied. Most elements of families 297 and mdg 1 were noncanonical and presented large interstock and intrastock polymorphism. Noncanonical elements of these two families were mostly located in euchromatin, although not restricted to it. The elements of families 412 and copia were better conserved. The proportion of noncanonical elements was lower. The 1731 family is mainly composed of noncanonical, beta-heterochromatic elements that are highly conserved among stocks. The relation of structural polymorphism to phylogeny, transpositional activity and the role of natural selection in the maintenance of transposable elements are discussed.     

Extrachromosomal DNA forms of copia-like transposable elements, F elements and middle repetitive DNA sequences in Drosophila melanogaster. Variation in cultured cells and embryos

Drosophila melanogaster embryos and cells in culture were screened for the presence of unintegrated covalently closed circular DNA forms that hybridize to copia-like transposable elements, the F element and uncharacterized dispersed middle repetitive DNA elements. Our results indicate that the majority of copia-like elements (including copia, 297, 412, mdg1, mdg3 and gypsy), the F elements, and 9 of 12 middle repetitive DNA elements are present as free DNA forms in cultured cells and embryos. An 18 base-pair inverted repeat has been reported to flank the long direct repeat of mdg3, implying that mdg3 is not an orthodox copia-like element; however, we have sequenced two independently isolated mdg3 clones and shown that the inverted repeat is not part of the element. The relative abundance with which free DNA forms are found varies between the cultured cells used, and between cultured cells and embryos. This variation, which can be up to 20-fold for some elements, does not correlate well with either the amount of element-specific poly(A)+ RNA present per cell or the number of element-specific sequences integrated in the genome.     

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.     

The ubiquitin ligase dTopors directs the nuclear organization of a chromatin insulator

Chromatin insulators are gene regulatory elements implicated in the establishment of independent chromatin domains. The gypsy insulator of D. melanogaster confers its activity through a protein complex that consists of three known components, Su(Hw), Mod(mdg4)2.2, and CP190. We have identified a factor, Drosophila Topoisomerase I-interacting RS protein (dTopors) that interacts with the insulator protein complex and is required for gypsy insulator function. In the absence of Mod(mdg4)2.2, nuclear clustering of insulator complexes is disrupted and insulator activity is compromised. Overexpression of dTopors in the mod(mdg4)2.2 null mutant rescues insulator activity and restores the formation of nuclear insulator bodies. dTopors associates with the nuclear lamina, and mutations in lamin disrupt dTopors localization as well as nuclear organization and activity of the gypsy insulator. Thus, dTopors appears to be involved in the establishment of chromatin organization through its ability to mediate the association of insulator complexes with a fixed nuclear substrate.