The steps of reverse transcription of Drosophila mobile dispersed genetic elements and U3-R-U5 structure of their LTRs

Alteration of hsp82 gene expression by the gypsy transposon and suppressor genes in Drosophila melanogaster

Several mutations in Drosophila result from insertion of the gypsy retrotransposon. Gypsy insertion mutagenesis and its modulation by allele-specific modifier genes were investigated by inserting gypsy or fragments of it into the intron of the Drosophila hsp82 heat shock gene. With gypsy in the parallel orientation, nearly all transcripts in transfected cells and transformed pupae were truncated in the 5' long terminal repeat (LTR). Truncation also occurred in or near the 3' LTR. The 5' LTR polyadenylation signal was strongly potentiated by a downstream 326-bp internal gypsy segment in either orientation. Anti-parallel gypsy reduced the amount of normal transcript to a much smaller extent, and a low level of truncation occurred within gypsy. No evidence was found for effects of the gypsy insertions on the hsp82 promoter. Mutations in the allelespecific modifier genes su(f) and su(w alpha) had effects on the amounts of readthrough transcripts consistent with their genetic behavior, whereas the effects of mutations in su(Hw) were only partly in accord with genetic expectations.

Retrotransposon transposition intermediates are encapsidated into virus-like particles

Virus-like particles (VLPs) possessing reverse transcriptase activity are persistently present in Drosophila melanogaster cultured cells and are formed in yeast induced for transposition. Different retrotransposon transposition intermediates consistent with those expected from the model of reverse transcription pathway of retrotransposon transposition have been detected during the analysis of nucleic acids isolated from VLPs. These data indicate that the act of reverse transcription takes place in VLPs which may be considered as functional intermediates of transposition.

Micropia: a retrotransposon of Drosophila combining structural features of DNA viruses, retroviruses and non-viral transposable elements

The retrotransposon micropia was first described from Y-chromosomal fertility genes of Drosophila hydei. Screening a Drosophila melanogaster genomic library yielded several clones representing micropia elements in D. melanogaster. The DNA sequences of two elements from D. hydei (micropia-DhMiF2 and micropia-DhMiF8) and two elements from D. melanogaster (micropia-Dm2 and micropia-Dm11) permitted a detailed analysis of the spatial organization of micropia constituents. Micropia represents the typical gene organization represented by "core"-protein domains followed by a protease, reverse transcriptase, RNase and integrase domain. New features of the micropia family compared with other retrotransposons are: (1) a region of similarity to class I major histocompatibility complex antigens of mammals; (2) only one main open reading frame of about 4000 bases length; (3) a non-protein-coding region of about 500 base-pairs length between the 3' end of the open reading frame and the 5' start of the 3' long terminal repeat. This region includes 32 base-pair tandem repeats; (4) within the long terminal repeats, 82 base-pair tandem repeats with four potential ecdysteroid receptor binding sites. Because micropia combines many evolutionary features of different viruses, non-viral transposable elements, chromosomal genes and repetitive sequence organizations, this retrotransposon may be seen as a "minigenome" reflecting evolutionary principles of the construction of genomic components.

The Drosophila mobile element jockey belongs to LINEs and contains coding sequences homologous to some retroviral proteins

A detailed investigation of the Drosophila melanogaster mobile dispersed repetitive element jockey was performed. This is similar in its structural organization and coding potential to the long interspersed elements (LINEs) of various organisms. A complete copy of jockey (approx. 5 kb) is terminated with an oligodeoxynucleotide (dA) sequence preceded by two long open reading frames (ORFs) overlapping with a frameshift-1. Judging by the sequence homologies, ORF1 codes for a nucleic-acid-binding protein, and ORF2 for a reverse transcriptase which is most similar in its sequence to putative reverse transcriptase of other LINEs. As demonstrated by sequencing two deleted jockey copies, they contain only a small part of ORF2; however, other regions, including the terminal sequences, are highly conservative. The existence of a large number of jockey copies with a deletion in the second frame may indicate that they can use reverse transcriptase in trans.

Functional expression of a sequence-specific endonuclease encoded by the retrotransposon R2Bm

A fraction of the 28S ribosomal genes in certain insect species is interrupted by the insertion elements R1 and R2. These two elements from the silkworm Bombyx mori (R1Bm and R2Bm) are retrotransposons capable of transposing in a highly sequence-specific manner. We report here the functional expression in E. coli of the entire single open reading frame of R2Bm and show that it encodes a double-stranded endo-nuclease (integrase) that can specifically cleave the 28S gene at the R2 insertion site. The resulting cleavage is a 4 bp staggered 5' overhang. Deletion analysis of the 28S gene revealed that the DNA sequence required for specific cleavage is asymmetric with respect to the actual insertion (cleavage) site, with fewer than 10 bp required at one side and at least 24 bp at the other side of the site. A model is proposed based on these and previous data to account for the sequence-specific integration of the R2 retrotransposon.

jockey, a mobile Drosophila element similar to mammalian LINEs, is transcribed from the internal promoter by RNA polymerase II

The mobile element jockey is similar in structural organization and coding potential to the LINEs of various organisms. As demonstrated here, two polyadenylated jockey transcripts detected at different stages of Drosophila ontogenesis and in cell cultures have the same length as genomic copies of jockey and correspond to the strand containing ORFs. alpha-amanitin experiments indicate that jockey is transcribed by RNA polymerase II. Analysis of both expression of CAT constructions and initiation of transcription in jockey genomic and transfected copies has shown that jockey transcription is controlled by an internal promoter. Inward location of the promoter allows it to be preserved in the course of replication via reverse transcription and accounts for the distribution of jockey and probably other LINEs throughout the genome. This is the first case of an internal promoter described for RNA polymerase II. The comparison of sequences at the beginning of LINE elements in Drosophila allows one to detect possible core sequences.

Retroviruses

First brought to scientific attention as infectious cancer-causing agents nearly 80 years ago, retroviruses are popular in contemporary biology for many reasons. (i) The virus life cycle includes several events--in particular, reverse transcription of the viral RNA genome into DNA, orderly integration of viral DNA into host chromosomes, and utilization of host mechanisms for gene expression in response to viral signals--which are broadly informative about eukaryotic cells and viruses. (ii) Retroviral oncogenesis usually depends on transduction or insertional activation of cellular genes, and isolation of those genes has provided the scientific community with many of the molecular components now implicated in the control of normal growth and in human cancer. (iii) Retroviruses include many important veterinary pathogens and two recently discovered human pathogens, the causative agents of the acquired immunodeficiency syndrome (AIDS) and adult T cell leukemia/lymphoma. (iv) Retroviruses are genetic vectors in nature and can be modified to serve as genetic vectors for both experimental and therapeutic purposes. (v) Insertion of retroviral DNA into host chromosomes can be used to mark cell lineages and to make developmental mutants. Progress in these and other areas of retrovirus-related biology has been enormous during the past two decades, but many practical and theoretical problems remain to be solved.

An indicator gene to demonstrate intracellular transposition of defective retroviruses

An indicator gene for detection and quantitation of RNA-mediated transposition was constructed (neoRT). It was inserted into a Moloney murine leukemia provirus (Mo-MLV) deleted for the envelope gene to test for intracellular transposition of defective retroviruses [Mo-MLV(neo)RT]. NeoRT contains the selectable neo gene (which confers resistance to the drug G418), inactivated by a polyadenylylation sequence inserted between the neo promotor and coding sequence. The polyadenylylation sequence is flanked (on the antisense strand of the DNA) by a donor and an acceptor splice site so as to be removed upon passage of the provirus through an RNA intermediate. 3T3 cells transfected with the defective Mo-MLV(neo)RT provirus are sensitive to G418. After trans-complementation with Mo-MLV, viral transcripts confer resistance to G418 upon infection of test cells. In the resistant cells, the polyadenylylation sequence has been removed, as a result in most cases of precise splicing of the intronic domain. Retrotransposition of the defective Mo-MLV(neo)RT provirus was demonstrated by submitting transfected G418-sensitive clones to selection. Between 1 and 10 G418-resistant clones were obtained per 10(7) cells. Several possess additional copies, with evidence for precise removal of the intronic domain. By using target test cells in coculture experiments, extracellular intermediates of retrotransposition could not be detected.

Human transposon-like elements insert at a preferred target site: evidence for a retrovirally mediated process

Members of the human transposon-like family of repetitive sequences (called THE 1 repeats) like many other repetitive DNA sequences are flanked by short direct repeats. Comparison of the base sequences of twelve examples of these flanking direct repeats indicates that THE 1 repeats insert into a preferred genomic target site. In one case, we have identified the sequence of an empty site into which a THE 1 element inserted. The sequence of this empty site and sequences of truncated THE 1 LTRs are consistent with a retroviral mechanism for the insertion of THE 1 elements. Truncated transposon structures illustrate for the first time that intermediate structures of retrotransposition may also be integrated into the genome.

Genome reshuffling of the copia element in an inbred line of Drosophila melanogaster

Mobile genetic elements are found in the genomes of many organisms, and because of their effects on genes and their ability to induce chromosomal rearrangements they are an important source of genetic variability. Transposition rates are usually found to be low, estimated at around 10(-3) per generation. Higher rates of transposition are observed, however, in crosses between certain strains of Drosophila melanogaster ('hybrid dysgenesis'), which can lead to a dramatic rearrangement of many mobile elements ('transposition bursts'). We have studied the chromosomal distribution of mdg-1 and copia mobile elements in 17 highly inbred lines of D. melanogaster, after 69 generations of sib-mating. Most lines show no changes, but one showed a complete reshuffling of the copia element. We conclude that the transpositions of the copia element in this line occurred rapidly in a few generations. This phenomenon, distinct from 'transposition bursts' in that only copia elements are involved, may account for the instability sometimes observed in inbred lines and may be important in creating genetic variability in highly homozygous populations.

Transcription of a human transposon-like sequence is usually directed by other promoters

The transcriptional activity of a human transposon-like family of repeats, called the THE-1 family, has been studied in cell culture and in human tissue. Both strands of THE-1 are present in several discrete length poly A plus RNAs. Primer extension studies and the structures of cDNA clones show that these THE-1 transcripts are usually the product of other transcription units. The THE-1 LTR provides the polyadenylation processing site for two transcripts, which result from upstream non THE-1 promoters. Yet another transcript, containing an internal THE-1 element in the probable sense orientation, is greatly enriched in a polysomal size fraction.

Trypanosoma brucei repeated element with unusual structural and transcriptional properties

The genome of Trypanosoma brucei contains up to 400 copies of a conserved sequence (TRS, trypanosome repeated sequence). The majority of TRS copies (TRS1) are 5.2 X 10(3) base-pairs (kb) and are flanked by different separate halves of the previously described transposable element RIME (ribosomal mobile element), although a variant copy (TRS2) contains only the central 1.45 kb portion and lacks RIME. TRS1 elements can probably undergo transposition, since they are dispersed in all chromosome size classes and are bordered by direct repeats of about four base-pairs. Some TRS1 elements may contain an open reading frame over almost their entire length (1651 codons), encoding a protein showing homology with reverse transcriptase. TRS probes detect poly(A)+ transcripts of 5 to 9 kb, generated by a polymerase moderately sensitive to alpha-amanitin. Transcription is developmentally regulated. Both TRS and RIME sense transcripts are preferentially synthesized compared to anti-sense transcripts, and are much more abundant in bloodstream forms than in cultured procyclics.

Structural variations in the Drosophila retrotransposon, 17.6

More than 21 members of 17.6, a Drosophila retrotransposon, were isolated and their possible structural changes were examined by restriction mapping, blot hybridization, heteroduplex analysis and nucleotide sequence determination of long terminal repeats (LTRs). At least 7 members were found to suffer with terminal or internal long deletions. No pair of LTRs having an identical nucleotide sequence was found either within an element or between elements. Although an initiation site for the presumable genome-sized transcript of 17.6, a potential substrate for reverse transcription on translocation, was identified within the left-hand LTR, our results as a whole support the notion that the majority of 17.6s have continued to reside for a long period of time at their present chromosomal loci and hence the rate of translocation of 17.6 is very low.

The termini of extrachromosomal linear copia elements

Extrachromosomal linear copia elements were isolated and cloned from cultured Drosophila melanogaster cells. Four full length copia recombinants were characterised. Each contains a full sized copy of copia bounded by its direct repeats. The sequences of the ends of the copia inserts were determined. All of the termini are identical to those of genomic copias except for a single base deletion from one end of one clone. These results suggest that the priming for initiation of copia reverse transcription differs from normal retroviral models. Southern blot analysis of uncloned full length copia circles shows that approximately 50% correspond to the predicted circularisation product of such linears. We propose that this class of circles and the linear DNAs described here are precursors to integrated genomic copia elements.