Primary structure and functional organization of Drosophila 1731 retrotransposon

Amplification of the 1731 LTR retrotransposon in Drosophila melanogaster cultured cells: Origin of neocopies and impact on the genome

Transposable elements (TEs), represent a large fraction of the eukaryotic genome. In Drosophila melanogaster, about 20% of the genome corresponds to such middle repetitive DNA dispersed sequences. A fraction of TEs is composed of elements showing a retrovirus-like structure, the LTR-retrotransposons, the first TEs to be described in the Drosophila genome. Interestingly, in D. melanogaster embryonic immortal cell culture genomes the copy number of these LTR-retrotransposons was revealed to be higher than the copy number in the Drosophila genome, presumably as the result of transposition of some copies to new genomic locations [Potter, S.S., Brorein Jr., W.J., Dunsmuir, P., Rubin, G.M., 1979. Transposition of elements of the 412, copia and 297 dispersed repeated gene families in Drosophila. Cell 17, 415-427; Junakovic, N., Di Franco, C., Best-Belpomme, M., Echalier, G., 1988. On the transposition of copia-like nomadic elements in cultured Drosophila cells. Chromosoma 97, 212-218]. This suggests that so many transpositions modified the genome organisation and consequently the expression of targeted genes. To understand what has directed the transposition of TEs in Drosophila cell culture genomes, a search to identify the newly transposed copies was undertaken using 1731, a LTR-retrotransposon. A comparison between 1731 full-length elements found in the fly sequenced genome (y(1); cn(1)bw(1), sp(1) stock) and 1731 full-length elements amplified by PCR in the two cell line was done. The resulting data provide evidence that all 1731 neocopies were derived from a single copy slightly active in the Drosophila genome and subsequently strongly activated in cultured cells; and that this active copy is related to a newly evolved genomic variant (Kalmykova, A.I., et al., 2004. Selective expansion of the newly evolved genomic variants of retrotransposon 1731 in the Drosophila genomes. Mol. Biol. Evol. 21, 2281-2289). Moreover, neocopies are shown to be inserted in different sets of genes in the two cell lines suggesting they might be involved in the biological and physiological differences observed between Kc and S2 cell lines.

Virus-like particle formation in Drosophila melanogaster germ cells suggests a complex translational regulation of the retrotransposon cycle and new mechanisms inhibiting transposition

Transposition of 1731, a Drosophila melanogaster LTR retrotransposon, was investigated in reproductive organs by RNA, protein and VLP distribution during its life cycle. We detected 1731 transcription in oogonia but not in spermatogonia; in all cells during oogenesis but only in primary spermatocytes; and in ovarian cytoplasm but both in nuclei and cytoplasm of primary spermatocytes. By confocal scanning, we showed that whereas Gag protein appeared in all cytoplasms during oogenesis, in testes Gag detection began in late premeiotic primary spermatocytes and increased in elongating spermatids suggesting distinct mechanisms of 1731 transcription and translation regulation. By electron microscopy, we did not detect 1731 VLPs in ovaries, suggesting a complex post-translational control blocking VLP assembly and transposition. Interestingly, in testes we discovered VLP aggregates in cystic cytoplasm of maturing partially individualized spermatids. In testes, we observed two delays in 1731 product expressions, suggesting a complex temporal control mechanism. Transcriptional/translational delay may be determined by accumulation of 1731 RNAs in primary spermatocyte nuclei. Translational/VLP assembly delay may be determined by post-transductional mechanisms controlling +1 frameshift and Pol-protein degradation. Our results indicated two differential mechanisms inhibiting 1731 transposition in Drosophila melanogaster ovaries and testes. In addition, we proposed a new mechanism for transposition control at the cell cycle level.

SplitTester: software to identify domains responsible for functional divergence in protein family

BACKGROUND

Many protein families have undergone functional divergence after gene duplications such that current subgroups of the family carry out overlapping but distinct biological roles. For the protein families with known functional subtypes (a functional split), we developed the software, SplitTester, to identify potential regions that are responsible for the observed distinct functional subtypes within the same protein family.

RESULTS

Our software, SplitTester, takes a multiple protein sequences alignment as input, generated from protein members of two subgroups with known functional divergence. SplitTester was designed to construct the neighbor joining tree (a split cluster) from variable-sized sliding windows across the alignment in a process called split-clustering. SplitTester identifies the regions, whose split cluster is consistent with the functional split, but may be inconsistent with the phylogeny of the protein family. We hypothesize that at least some number of these identified regions, which are not following a random mutation process, are responsible for the observed functional split. To test our method, we used reverse transcriptase from a group of Pseudoviridae retrotransposons: to identify residues specific for diverged primer recognition. Candidate regions were then mapped onto the three dimensional structures of reverse transcriptase. The locations of these amino acids within the enzyme are consistent with their biological roles.

CONCLUSION

SplitTester aims to identify specific domain sequences responsible for functional divergence of subgroups within a protein family. From the analysis of retroelements reverse transcriptase family, we successfully identified the regions splitting this family according to the primer specificity, implying their functions in the specific primer selection.

Translational recoding signals between gag and pol in diverse LTR retrotransposons

Because of their compact genomes, retroelements (including retrotransposons and retroviruses) employ a variety of translational recoding mechanisms to express Gag and Pol. To assess the diversity of recoding strategies, we surveyed gag/pol gene organization among retroelements from diverse host species, including elements exhaustively recovered from the genome sequences of Caenorhabditis elegans, Drosophila melanogaster, Schizosaccharomyces pombe, Candida albicans, and Arabidopsis thaliana. In contrast to the retroviruses, which typically encode pol in the -1 frame relative to gag, nearly half of the retroelements surveyed encode a single gag-pol open reading frame. This was particularly true for the Ty1/copia group retroelements. Most animal Ty3/gypsy retroelements, on the other hand, encode gag and pol in separate reading frames, and likely express Pol through +1 or -1 frameshifting. Conserved sequences conforming to slippery sites that specify viral ribosomal frameshifting were identified among retroelements with pol in the -1 frame. None of the plant retroelements encoded pol in the -1 frame relative to gag; however, two closely related plant Ty3/gypsy elements encode pol in the +1 frame. Interestingly, a group of plant Ty1/copia retroelements encode pol either in a +1 frame relative to gag or in two nonoverlapping reading frames. These retroelements have a conserved stem-loop at the end of gag, and likely express pol either by a novel means of internal ribosomal entry or by a bypass mechanism.

Structure and evolution of mtanga, a retrotransposon actively expressed on the Y chromosome of the African malaria vector Anopheles gambiae

Here we report the discovery of a novel family of long terminal repeat (LTR)-retrotransposons designated mtanga-Y, specific to the Y chromosome of the African malaria vector, Anopheles gambiae. mtanga-Y elements represent the first Y-linked sequences and the first members of the Ty1-copia superfamily of retrotransposons described from this mosquito. Analysis of a full-length 4,284-bp element revealed the presence of two intact overlapping open reading frames bounded by LTRs of 119 bp. Evidence suggests that the elements are capable of retrotransposition, as transcripts and potential replication intermediates (one-LTR circles) were detected. However, the approximately 12 copies of mtanga-Y appear to be clustered rather than dispersed on the Y chromosome. Absent from the Y chromosome of four sibling species (A. arabiensis, A. quadriannulatus, A. melas, and A. merus), similar, but often defective, mtanga elements are present elsewhere in these genomes, as well as in A. gambiae. These data are consistent with a relatively recent invasion of the A. gambiae Y chromosome by an intact element. The presence of functional mtanga-Y elements suggests that the Y chromosome may be a source, not just a sink, for retrotransposons.

Tirant is a new member of the gypsy family of retrotransposons in Drosophila melanogaster

In this paper, we propose a consensus sequence for a putative complete Tirant retrotransposon. Several defective copies, as well as relevant sequences available in databases have been analyzed. The putative complete Tirant element is 8533 bp long, and presents all the structural features of a retrovirus-like transposable element of the gypsy family. It contains three ORFs (open reading frames) that encode putative products resembling the retroviral Gag, Pol, and Env proteins. Southern blot analyses show that complete and defective Tirant elements are widespread in Drosophila melanogaster. The different hybridization patterns observed in several natural populations of this species suggest that Tirant is an active element.

The yeast retrotransposon Ty5 uses the anticodon stem-loop of the initiator methionine tRNA as a primer for reverse transcription

Retrotransposons and retroviruses replicate by reverse transcription of an mRNA intermediate. Most retroelements initiate reverse transcription from a host-encoded tRNA primer. DNA synthesis typically extends from the 3'-OH of the acceptor stem, which is complementary to sequences on the retroelement mRNA (the primer binding site, PBS). However, for some retrotransposons, including the yeast Ty5 elements, sequences in the anticodon stem-loop of the initiator methionine tRNA (IMT) are complementary to the PBS. We took advantage of the genetic tractability of the yeast system to investigate the mechanism of Ty5 priming. We found that transposition frequencies decreased at least 800-fold for mutations in the Ty5 PBS that disrupt complementarity with the IMT. Similarly, transposition was reduced at least 200-fold for IMT mutations in the anticodon stem-loop. Base pairing between the Ty5 PBS and IMT is essential for transposition, as compensatory changes that restored base pairing between the two mutant RNAs restored transposition significantly. An analysis of 12 imt mutants with base changes outside of the region of complementarity failed to identify other tRNA residues important for transposition. In addition, assays carried out with heterologous IMTs from Schizosaccharomyces pombe and Arabidopsis thaliana indicated that residues outside of the anticodon stem-loop have at most a fivefold effect on transposition. Our genetic system should make it possible to further define the components required for priming and to understand the mechanism by which Ty5's novel primer is generated.

Molecular structure of the copia-like retrotransposable element Yokozuna on the W chromosome of the silkworm, Bombyx mori

We discovered a novel retrotransposable element, designated Yokozuna, on the W chromosome of Bombyx mori. The size of this element is 4738 bp, including a 208-bp long terminal repeat (LTR) on one side and a 183-bp LTR on the other. This retrotransposable element is flanked by a 5-bp target site duplication, TAATT. Yokozuna contains a single long open reading frame (ORF) and the whole deduced amino acid sequence of ORF reveals strong homology with copia of Drosophila. Moreover, an alignment analysis of the reverse transcriptase (RT) sequences suggested that the Yokozuna element is the first Bombyx retrotransposable element belonging to the Ty1-copia group. The number of Yokozuna per haploid genome is approximately four copies. Although Yokozuna was discovered on the W chromosome, it is not specific for the W chromosome.

SIRE-1, a copia/Ty1-like retroelement from soybean, encodes a retroviral envelope-like protein

The soybean genome hosts a family of several hundred, relatively homogeneous copies of a large, copia/Ty1-like retroelement designated SIRE-1. A copy of this element has been recovered from a Glycine max genomic library. DNA sequence analysis of two SIRE-1 subclones revealed that SIRE-1 contains a long, uninterrupted, ORF between the 3' end of the pol ORF and the 3' long terminal repeat (LTR), a region that harbors the env gene in retroviral genomes. Conceptual translation of this second ORF produces a 70-kDa protein. Computer analyses of the amino acid sequence predicted patterns of transmembrane domains, alpha-helices, and coiled coils strikingly similar to those found in mammalian retroviral envelope proteins. In addition, a 65-residue, proline-rich domain is characterized by a strong amino acid compositional bias virtually identical to that of the 60-amino acid, proline-rich neutralization domain of the feline leukemia virus surface protein. The assignment of SIRE-1 to the copia/Ty1 family was confirmed by comparison of the conceptual translation of its reverse transcriptase-like domain with those of other retroelements. This finding suggests the presence of a proretrovirus in a plant genome and is the strongest evidence to date for the existence of a retrovirus-like genome closely related to copia/Ty1 retrotransposons.

pCal, a highly unusual Ty1/copia retrotransposon from the pathogenic yeast Candida albicans

Retrotransposons are mobile genetic elements. They can transpose via the reverse transcription of mRNA into double-stranded DNA (dsDNA) followed by the insertion of this dsDNA into new sites within the host genome. The unintegrated, linear, dsDNA form of retrotransposons is usually very rare. We report here the isolation of a retrotransposon from Candida albicans which is unusual in this respect. This element, which we have named pCal, was first identified as a distinct band when uncut C. albicans DNA was examined on an agarose gel. Sequence analysis of the cloned element revealed that it is a retrotransposon belonging to the Ty1/copia group. It is estimated that pCal produces 50 to 100 free, linear, dsDNA copies of itself per cell. This is a much higher level of expression than even that of the system in which Ty1 is expressed behind the highly active GAL1 promoter on a high-copy-number plasmid (about 10 copies per cell). Another unusual feature of pCal is that its Pol enzymes are likely to be expressed via the pseudoknot-assisted suppression of an upstream, in-phase stop codon, as has been shown for Moloney murine leukemia virus.

Developmental expression analysis of the 1731 retrotransposon reveals an enhancement of Gag-Pol frameshifting in males of Drosophila melanogaster

Extensive analyses of Drosophila melanogaster retrotransposon transcriptions in cultured cells or during development have been reported, but little is known about their translation during the development of the fly. Analysis of the translational products of the 1731 Drosophila melanogaster retrotransposon in Kc Drosophila cultured cells has been reported, showing the existence of primary products (Gag and Pol) and of processed polypeptides of various sizes. Study of 1731 retrotransposon expression at both levels of transcription and translation during the development of Drosophila melanogaster, is presented. 1731 transcripts were detected by in situ hybridization and 1731 proteins were detected by immunostaining and immunoblotting in embryos and in adult gonads. 1731 transcripts and proteins were detected in the mesoderm and central nervous system during embryonic development, in nurse cells and follicle cells in adult ovaries and in primary spermatocytes in adult testes. Moreover, Western blot analysis of the 1731 proteins with anti-Gag or anti-Pol antibodies in gonads revealed that the 1731 mRNA could be translated differentially according to the expressing tissue: essentially, ovarian translation and/or processing of 1731 products is different from that operating in testes, where the Gag-Pol fusion polyprotein is the most prominent product. Our results indicate that expression of the 1731 mobile element is regulated not only at the transcriptional level but also at the translational level, and that this regulation is different in the two sexes.

Roles of the influenza virus polymerase and nucleoprotein in forming a functional RNP structure

Influenza virus transcription and replication is performed by ribonucleoprotein particles (RNPs). They consist of an RNA molecule covered with many copies of nucleoprotein (NP) and carry a trimeric RNA polymerase complex. RNA modification analysis and electron microscopy performed on native RNPs suggest that the polymerase forms a complex with both conserved viral RNA (vRNA) ends, whereas NP binding exposes the RNA bases to the solvent. After chemical removal of the polymerase, the bases at the vRNA extremities become reactive to modification and the vRNPs behave as structures with free ends, as judged from the observation of salt-induced conformational changes by electron microscopy. The vRNA appears to be completely single-stranded in polymerase-free RNPs despite a partial, inverted complementarity of the vRNA ends. The absence of a stable double-stranded panhandle structure in polymerase-free RNPs has important implications for the mechanism of viral transcription and the switch from transcription to replication.

Cloning and characterization of a highly repeated DNA sequence in Hordeum vulgare L

A novel repetitive DNA sequence, R10hvcop, has been identified in the barley (Hordeum vulgare L.) genome. This 830 base pair (bp) DNA sequence has a 606-bp open reading frame and is present as approximately 1.96 x 10(5) copies per haploid barley genome. Southern blot analysis revealed that repetitive DNA elements containing R10hvcop and related sequences were dispersed within the barley chromosomes. Sequences similar to R10hvcop were also found in wheat (Triticum aestivum L.), rye (Secale cereale L.), and oat (Avena sativa L.) with copy numbers of 8 x 10(4), 1.39 x 10(5), and 7.9 x 10(4) per haploid genome, respectively. Sequences similar to R10hvcop were also present in the corn (Zea mays L. ssp. mays) genome, but they were not highly repeated. Barley, wheat, rye, oat, and corn showed species-specific restriction fragment length polymorphisms of R10hvcop and related sequences. Computer-based similarity searches revealed that R10hvcop is closely related to reverse transcriptase genes in retrotransposon-like elements of several plant species and of Drosophila. The highly repetitive nature, interspersed distribution, and high degree of similarity to reverse transcriptase genes suggests that R10hvcop contains the sequence of a diverged reverse transcriptase gene.

UVB irradiation upregulation of the Drosophila 1731 retrotransposon LTR requires the same short sequence of U3 region in a human epithelial cell line as in Drosophila cells

Phylogenetic analysis of the retrotransposon and retrovirus suggests an evolutionary relationship between them and indicates that transactivation of the long terminal repeat (LTR)-containing retroelements could be ubiquitous. Using constructs expressing a reporter gene under the control of the entire or deleted LTR of 1731, which is a retrotransposable element of Drosophila melanogaster, we were able to show that the UVB-irradiation activation of the 1731-LTR requires the same short sequence of U3 region in a human epithelial cell line as in Schneider's Drosophila cell line (S2). This sequence is similar to the binding sequence of the members of the nuclear factor-kappa B (NF-kappa B)/rel family. In addition, human colonic carcinoma cells (HT29), in response to UVB-irradiation, produce some extracellular factor(s) that activates the 1731-LTR in nonirradiated cells.

Native DNA repeats and methylation in Ascobolus

We identified two classes of native dispersed DNA repeats in the Ascobolus genome. The first class consisted of several kilobase long, methylated repeats. These repeats, named Mars (methylated Ascobolus repeated sequences), fell in one family of LINE-like elements and in three families of LTR-containing retrotransposable elements. The methylation features of Mars elements were those expected if they were natural targets for the MIP (methylation induced premeiotically) previously discovered in Ascobolus. The second class consisted of short repeats, approximately 100 bp long, corresponding to 5S rRNA and tRNA genes. As expected from their size, which was too small to allow MIP to occur, they were unmethylated, as were 26 kb of unique sequences tested. These observations are consistent with the hypothesis that MIP is targeted at natural DNA repeats and constitutes a defensive process against the detrimental consequences of the spreading of mobile elements throughout the genome. The 9 kb tandem repeats harbouring the 28S, 18S and 5.8S rRNA genes displayed methylation features suggesting that rDNA methylation proceeds through a process other than MIP.

Characterization and cloning of p11, a transrepressor of Drosophila melanogaster retrotransposon 1731

The NssBF element has been characterized as a 26 nt sequence in the long terminal repeat of Drosophila melanogaster retrotransposon 1731. This sequence has been shown to be implicated in transcriptional repression of the 1731 promoter. We here report the cloning of a cDNA encoding a nuclear DNA binding protein named p11 that binds specifically to the NssBF element. P11 is a 98 amino acid polypeptide. It exhibits similarities with the mouse p9 single-stranded DNA binding protein, raising the possibility of a very general family of protein factors. Co-transfection experiments in human U937 cells showed repression of the 1731 promoter by overexpression of p11.

The Gag polypeptides of the Drosophila 1731 retrotransposon are associated to virus-like particles and to nuclei

1731 is a Drosophila melanogaster retrotransposon whose nucleotide sequence shows a proviral architecture with two long terminal repeats (LTRs) framing two internal Open Reading Frames (ORFs). The pol ORF2 of this mobile genetic element was demonstrated to code for an active Reverse Transcriptase (RT) and the ORF1 is expected to code for the structural Gag proteins of the virus-like particles (VLP). Using specific anti-Gag antibodies, we have characterized the 1731 Gag polypeptides expressed either in vitro or in Kc Drosophila melanogaster cultured cells. Together with the 1731 RT, the largest, likely post-translationaly-modified Gag polypeptides are gathered into cytoplasmic virus-like particles. Moreover and consistent with the nuclear localization signal present in the Gag sequence, we observed that a short 1731 Gag polypeptide is associated to the cell nuclei.

Genetic recombination and DNA transpositions induced by pteridines and extracts of pteridine-treated diapausing chrysalids and mutants injected in Drosophila melanogaster

This paper presents the results of two different treatments using pteridines in Drosophila melanogaster larvae: injection of pteridines alone; and injection of extracts from diapaused Pieris brassicae chrysalids treated with pteridines. Genetic analysis reveals first the induction of lethal or visible recessive mutations that give rise mostly to developmental mutants with variable phenotypes, and second the induction of genetic recombinations. Both treatments disturb genetic recombination in F1 female female issued from the treated larvae. This disturbance is evidenced by the increase in the rate of recombination particularly in the centromere region, and induces in F1 female female and male male clusters of mitotic recombinations of premeiotic origin. These two observations present an analogy with hybrid dysgenesis in the P-M system. This suggests that the treatments either promote the mobility of transposons in female and male larvae and their progeny, or affect the system controlling transposon mobility and integration at specific chromosomal sites. We used in situ hybridization to test our hypotheses, using P, I and copia-like probes. P yields a positive response both at the level of gonadal sterility (gonadal dysgenesis test) and in situ hybridization: after treatment, Oregon K and the wing-altered mutant bspw exhibit a normal number of P elements whereas the maternal strain Oregon K is totally devoid of P. This mutant bspw carries the neutral strain Q (a variant of P), which cannot produce P-M dysgenesis. The implication of these findings for understanding the mode of action of pteridines is twofold: (1) pteridines may be mutagenic agents which perturb meiotic and mitotic recombination; and (2) pteridines disturb the system regulating the mobility and insertion of P elements.

Structural features of mag, a gypsy-like retrotransposon of Bombyx mori, with unusual short terminal repeats

Mag is a retrotransposon found as an insert in the Sericin 2 gene. It is present in a few copies--4 to 15--dispersed in the genome of different strains of Bombyx mori as well as in Bombyx mandarina. Flanked by a 5 bp target sequence with no sequence specificity, it is bordered by direct repeats of 77 nucleotides. Despite their unusual short size, these terminal repeats and their immediately adjacent sequences present all the signals necessary for transcription into genomic RNA and for reverse transcription. Mag contains two overlapping open reading frames which are organized as the gag and pol genes of retroviruses and encode putative nucleic acid binding peptide, protease, reverse transcriptase, RNase H and endonuclease in this order. Sequence comparison of these proteins places mag within the gypsy group of LTR retrotransposons next to the echinoderm element SURL.

The microinjected Drosophila melanogaster 1731 retrotransposon is activated after the midblastula stage of the amphibian Pleurodeles waltl development

The entire 1731 retrotransposon of Drosophila melanogaster, tagged with the E. coli lac Z gene inserted in its gag sequence, was injected into oocytes and fertilized eggs of the urodele amphibian Pleurodeles waltl. Expression of the reporter gene indicated that the 1731 promoter (its 5'LTR) is active in the embryos and not in the oocytes. It appeared that this element is regulated as amphibian genes are at the beginning of the development, i.e. that expression was detected after the mid blastula stage and maintained up to four or five days after injection. Another construction associating the modified 1731 promoter with the CAT gene is also expressed in Pleurodeles embryos during the same period of development. This indicated that the 1731 promoter issued from a Drosophila species is activated as promoting sequences of amphibian zygotic genes are, suggesting that in the case of horizontal transfer, 1731 can be expressed into vertebrate organisms.

Translation and fates of the gag protein of 1731, a Drosophila melanogaster retrotransposon

An entire copy of 1731, a Drosophila melanogaster retrotransposon, was tagged by fusing in frame its putative gag gene with the reporter LacZ sequence. The high transfection efficiency of Drosophila virilis cells added to the absence of 1731 in their genome allowed, by combining histochemical staining and immunological detections, the demonstration of the translation of the 1731 gag gene. The gag protein is gathered in virus-like particles. Its occurrence in nuclei is consistent with a nuclear localization signal. The expression of the sense construction was inhibited by cotransfections with its antisense homologue.

Promoter activity of the 1731 Drosophila retrotransposon in a human monocytic cell line

The resemblance between retrotransposons and retroviruses suggests an evolutionary relationship and indicates that they may share common transcription factors. We have analyzed the behaviour of the Drosophila 1731 retrotransposon promoter in the human monocytic U937 cell line. We show that the long terminal repeat (LTR) of 1731 promotes CAT (chloramphenicol acetyl transferase) activity in these cells, in which it is enhanced by phorbol esters. Using gel mobility assays, we detected a human nuclear protein that binds in the U3 region of the LTR in a sequence-specific manner. Its precise target was determined by a DNase I footprinting experiment.

Pao, a highly divergent retrotransposable element from Bombyx mori containing long terminal repeats with tandem copies of the putative R region

Analysis of aberrant ribosomal DNA (rDNA) repeats of Bombyx mori resulted in the discovery of a 4.8 kilobase retrotransposable element, Pao. Approximately 40 copies of Pao are present in the genome with most located outside the rDNA units. The complete sequence of one Pao element and partial sequence of four other copies indicated that Pao encodes an 1158 amino acid open-reading frame (ORF). Located within this ORF are domains with sequence similarity to retroviral gag genes, aspartic protease and reverse transcriptase. RNase H and integrase domains were not identified suggesting that the cloned copies were not full-length elements. Pao elements contain long terminal repeats (LTRs) with a central region composed of variable numbers of 46 bp tandem repeats. The variable region appears to correspond to the R region of retroviral LTRs, the region responsible for strand transfer during reverse transcription. Based on a sequence analysis of its reverse transcriptase domain, Pao is most similar to TAS of Ascaris lumbricoides. Pao and TAS represent a subgroup of LTR retrotransposons distinct from the Copia-Ty1 and Gypsy-Ty3 subgroups.

Copia-like retrotransposable element evolution in diploid and polyploid cotton (Gossypium L.)

Copia-like retrotransposable elements were identified in allotetraploid cotton, Gossypium hirsutum, and two species representing its diploid progenitors, G. herbaceum and G. raimondii. These elements are present in high copy number in all three species. Because the two diploid genomic groups have been isolated on opposite sides of the world for 6-11 million years, horizontal transfer of elements between these species is highly unlikely. Elements were intensively sampled to generate a model of copia-like retrotransposable element evolution in systems where vertical transmission is the sole probable means of descent. Copia-like retrotransposon diversity is equally great in all three Gossypium species. Despite this high heterogeneity, analysis of 89 partial reverse transcriptase sequences resulted in the recognition of nine sharply differentiated retrotransposon lineages, each containing elements that share high sequence similarity. No evidence of horizontal transfer from other taxa was obtained. Phylogenetic analyses demonstrate that element topologies are incongruent with Gossypium phylogeny. Consideration of processes that obscure phylogenetic reconstruction of multigene families (including sampling error, variable degrees of orthology and paralogy, differential lineage age and lineage loss and/or proliferation) demonstrates that incongruence between organismal and retrotransposon trees is expected under conditions in which vertical processes are the sole means of transmission. Identification of closely related elements between species allowed rates of copia-like retrotransposon sequence evolution to be estimated as approximately 10(-9) nucleotide substitutions/site/year. These rates are consistent with the interpretation that these retrotransposons have been evolving under functional constraints for most of the time frame bracketed by the species studied. Extrapolation of these results to previous studies that sampled from more highly divergent taxa indicates that horizontal transfer need not be invoked to explain observed phylogenetic patterns.

Reverse transcriptase families and a copia-like retrotransposon, Osser, in the green alga Volvox carteri

By using the polymerase chain reaction (PCR) we have isolated and sequenced two distinct families of reverse transcriptase (RT) sequences from the genome of the colonial alga, Volvox carteri. Probing a genomic library with these RT clones revealed copia-like retrotransposons. One of these elements, named Osser, is 4,875 bp long, bordered by 197-bp identical long terminal repeats (LTRs), and shows the typical organization of retrotransposons belonging to the copia-Tyl group. This is the first complete copia-like retrotransposon sequence described in a green alga.

A redefinition of the Asp-Asp domain of reverse transcriptases

The rules defining the Asp-Asp domain of RNA-dependent polymerases deduced by Argos (1988) were tested in a set of 53 putative reverse transcriptases (RTs) sequences. Since it was found that some of these rules are not followed by RTs coded by bacteria, group II introns, and non-LTR retrotransposons, we present here a more strict definition of the Asp-Asp domain.

Molecular analysis of the yeast Ty4 element: homology with Ty1, copia, and plant retrotransposons

The element; Ty4 is a retrotransposon present in low copy number in the genome of Saccharomyces cerevisiae [Stucka et al., Nucleic Acids Res. 17 (1989) 4993-5001]. We have determined the complete nucleotide sequence of one such element from a particular strain and compared it to the other two elements occurring in this strain. The genomic organization of Ty4 is homologous to that found in other retrotransposons of the Ty1-copia group. The internal part of the element contains two large open reading frames (TY4A and TY4B) overlapping by 226 bp in a + 1 mode. TY4A reveals characteristics of the gag portion of retrotransposons and retroviruses, while TY4B consists of a protease, an integrase, a reverse transcriptase, and an RNase H domain (in that order). Our analyses suggest that only one of these copies might be transpositionally active. Sequence comparisons at the amino acid level show that the domains in Ty4 diverge considerably from those of other retrotransposons. The greatest similarity is seen between the reverse transcriptases (50%), the proteases (40%), and the integrases (30%) of Ty4, Ty1/2 and copia, respectively, whereas the degree of similarity for all other entities of these elements is much lower. Considering evolutionary aspects of the retrotransposons, we have to conclude that Ty4 has diverged at an early stage from the progenitors of other known retroelements and represents a novel and independent subgroup of the Ty1-copia class of retrotransposons.

Characterization of the reverse transcriptase of 1731, a Drosophila melanogaster retrotransposon

The nucleotide sequence of 1731, a retrotransposon cloned from the genome of Drosophila melanogaster, reveals a structural similarity with the proviral form of the retroviruses including a pol-like gene containing a putative reverse-transcriptase(RT)-coding sequence. Diverse parts of that sequence were subcloned and expressed in Escherichia coli. It has been demonstrated that the expression of the RT-like sequence, when translated, gives rise to peptides displaying enzyme activity characteristic of a true RT enzyme. In addition, rabbit antisera directed against such recombinant proteins allowed us to detect an immunoreactive protein of around 110 kDa, which was only present in D. melanogaster cell lines, but not in cells derived from Drosophila virilis or Drosophila hydei, whose genomes do not bear the 1731 element. This protein is expected to correspond to a non-processed pol-gene translated product and cosediments with virus-like particles exhibiting RT activity.

copia-like retrotransposons are ubiquitous among plants

Transposable genetic elements are assumed to be a feature of all eukaryotic genomes. Their identification, however, has largely been haphazard, limited principally to organisms subjected to molecular or genetic scrutiny. We assessed the phylogenetic distribution of copia-like retrotransposons, a class of transposable element that proliferates by reverse transcription, using a polymerase chain reaction assay designed to detect copia-like element reverse transcriptase sequences. copia-like retrotransposons were identified in 64 plant species as well as the photosynthetic protist Volvox carteri. The plant species included representatives from 9 of 10 plant divisions, including bryophytes, lycopods, ferns, gymnosperms, and angiosperms. DNA sequence analysis of 29 cloned PCR products and of a maize retrotransposon cDNA confirmed the identity of these sequences as copia-like reverse transcriptase sequences, thereby demonstrating that this class of retrotransposons is a ubiquitous component of plant genomes.

A nuclear single-stranded-DNA binding factor interacts with the long terminal repeats of the 1731 Drosophila retrotransposon

Using gel mobility assays, we have detected two proteins that bind in the U3 region of the 1731 retrotransposon long terminal repeats (between positions -110 and -73) in nuclear extracts from Drosophila melanogaster cultured cells. The first one binds double-stranded DNA, whereas the other binds the mRNA-like strand in a sequence-specific manner. We report here the characterization of the latter protein, named NssBF for nuclear single-stranded-DNA binding factor. Gel filtration shows an apparent molecular mass of 95 kDa for NssBF. The points of contact between NssBF and its single-stranded DNA target were determined. This protein binds neither the complementary strand nor the corresponding RNA sequence. A possible role of NssBF in transcription is discussed.

Ty1-copia group retrotransposons and the evolution of retroelements in the eukaryotes

Ty1-copia group retrotransposons are among the best studied transposable elements in the eukaryotes. This review discusses the extent of these transposons in the eukaryote kingdoms and compares models for the evolution of these genetic elements in the light of recent phylogenetic data. These data show that the Ty1-copia group is widespread among invertebrate eukaryotes, especially in the higher plant kingdom, where these genetic elements are unusually common and heterogeneous in their sequence. The phylogenetic data also suggest that the present day spectrum of Ty1-copia group retrotransposons has been influenced both by divergence during vertical transmission down evolving lineages and by horizontal transmission between distantly related species. Lastly, the factors affecting Ty1-copia group retrotransposon copy number and sequence heterogeneity in eukaryotic genomes and the effects of transpositional quiescence and defective retrotransposons upon evolution of Ty1-copia group retrotransposons are discussed.

A new member of a family of site-specific retrotransposons is present in the spliced leader RNA genes of Trypanosoma cruzi

A new member of a family of site-specific retrotransposons is described in the New World trypanosome Trypanosoma cruzi. This element, CZAR (cruzi-associated retrotransposon), resembles two previously described retrotransposons found in the African trypanosome T. brucei gambiense and the mosquito trypanosomatid Crithidia fasciculata in specifically inserting between nucleotides 11 and 12 of the highly conserved 39-mer of the spliced leader RNA (SL-RNA) gene. CZAR is similar in overall organization to the other two SL-RNA-associated elements. It possesses two potential long open reading frames which resemble the gag and pol genes of retroviruses. In the pol open reading frame, all three elements contain similarly arranged endonuclease domains and share extensive amino acid homology in the reverse transcriptase region. All are associated with the SL-RNA gene locus and are present in low copy numbers. They do not appear to have 5' truncated versions. All three retrotransposons are otherwise quite distinct from one another, with no significant overall amino acid homology. The presence of such retroelements inserted into the identical site within SL-RNA gene sequences in at least three evolutionarily distant trypanosomatid species argues for a functional role. Because these elements appear to have a precise target site requirement for integration, we refer to them as SL siteposons.

A new member of a family of site-specific retrotransposons is present in the spliced leader RNA genes of Trypanosoma cruzi

A new member of a family of site-specific retrotransposons is described in the New World trypanosome Trypanosoma cruzi. This element, CZAR (cruzi-associated retrotransposon), resembles two previously described retrotransposons found in the African trypanosome T. brucei gambiense and the mosquito trypanosomatid Crithidia fasciculata in specifically inserting between nucleotides 11 and 12 of the highly conserved 39-mer of the spliced leader RNA (SL-RNA) gene. CZAR is similar in overall organization to the other two SL-RNA-associated elements. It possesses two potential long open reading frames which resemble the gag and pol genes of retroviruses. In the pol open reading frame, all three elements contain similarly arranged endonuclease domains and share extensive amino acid homology in the reverse transcriptase region. All are associated with the SL-RNA gene locus and are present in low copy numbers. They do not appear to have 5' truncated versions. All three retrotransposons are otherwise quite distinct from one another, with no significant overall amino acid homology. The presence of such retroelements inserted into the identical site within SL-RNA gene sequences in at least three evolutionarily distant trypanosomatid species argues for a functional role. Because these elements appear to have a precise target site requirement for integration, we refer to them as SL siteposons.

A short 5' region of the long terminal repeat is required for regulation by hormone and heat shock of Drosophila retrotransposon 1731

1731, a Drosophila retrotransposon was first described as having a transcription activity which was negatively regulated by 20-hydroxyecdysone (20-OH), the steroid molting hormone of insects. Using constructions expressing the bacterial chloramphenicol-acetyltransferase (CAT) gene under the control of the entire or deleted Long Terminal Repeats (LTRs) of 1731, we were able to show that a short (28 bp) sequence located in the U3 region of these LTRs was required for 1) the increase in promoter strength, 2) negative regulation by 20-OH and, 3) positive regulation by heat shock.

A superfamily of Arabidopsis thaliana retrotransposons

We describe a superfamily of Arabidopsis thaliana retrotransposable elements that consists of at least ten related families designated Ta1-Ta10. The Ta1 family has been described previously. Two genomic clones representing the Ta2 and Ta3 elements were isolated from an A. thaliana (race Landsberg erecta) lambda library using sequences derived from the reverse transcriptase region of Ta1 as hybridization probes. Nucleotide sequence analysis showed that the Ta1, Ta2 and Ta3 families share greater than 75% amino acid identity in pairwise comparisons of their reverse transcriptase and RNase H genes. In addition to Ta1, Ta2 and Ta3, we identified seven other related retrotransposon families in Landsberg erecta, Ta4-Ta10, using degenerate primers and the polymerase chain reaction to amplify a highly conserved region of retrotransposon-encoded reverse transcriptase. One to two copies of elements Ta2-Ta10 are present in the genomes of the A. thaliana races Landsberg erecta and Columbia indicating that the superfamily comprises at least 0.1% of the A. thaliana genome. The nucleotide sequences of the reverse transcriptase regions of the ten element families place them in the category of copia-like retrotransposons and phylogenetic analysis of the amino acid sequences suggests that horizontal transfer may have played a role in their evolution.

A transposon with an unusual LTR arrangement from Chlamydomonas reinhardtii contains an internal tandem array of 76 bp repeats

TOC1, a transposable element from Chlamydomonas reinhardtii, is 5662 bases long. The 217 and 237 base long terminal repeat sequences of TOC1 are unusually arranged around the 4600 and 123 base unique regions: [217]-4600-[237] [217]-123-[237]. Although TOC1 contains long terminal repeats and most TOC1 elements are complete, features shared with virus-like retroposons, its unique 4600 base region is more similar to the structure of the L1 family of non-virus retroposons: first, 11 3/4 tandemly repeated copies of a 76 base repeat are found 813 bases from the left end of TOC1, and second using the universal genetic code large open reading frames were not found in TOC1. The relationship between TOC1, virus-like retroposons and the L1 family of non-virus retroposons is unclear and may be very distant since only poor similarity was found between the TOC1 encoded ORFs and retrovirus polypeptides. The length of the tandem array of 76 base repeat sequences was conserved in most TOC1 elements and solo 76 base repeat sequences were not found outside TOC1 elements in the C. reinhardtii genome. Nucleotide substitutions allow all copies of the 76 base repeat to be distinguished from one another.

Retrotransposon-like nature of Tp1 elements: implications for the organisation of highly repetitive, hypermethylated DNA in the genome of Physarum polycephalum

The repetitive fraction of the genome of the eukaryotic slime mould Physarum polycephalum is dominated by the Tp1 family of highly repetitive retrotransposon-like sequences. Tp1 elements consist of two terminal direct repeats of 277bp which flank an internal domain of 8.3kb. They are the major sequence component in the hypermethylated (M+) fraction of the genome where they have been found exclusively in scrambled clusters of up to 50kb long. Scrambling is thought to have arisen by insertion of Tp1 into further copies of the same sequence. In the present study, sequence analysis of cloned Tp1 elements has revealed striking homologies of the predicted amino acid sequence to several highly conserved domains characteristic of retrotransposons. The relative order of the predicted coding regions indicates that Tp1 elements are more closely related to copia and Ty than to retroviruses. Self-integration and methylation of Tp1 elements may function to limit transposition frequency. Such mechanisms provide a possible explanation for the origin and organisation of M + DNA in the Physarum genome.

Type I (R1) and type II (R2) ribosomal DNA insertions of Drosophila melanogaster are retrotransposable elements closely related to those of Bombyx mori

Approximately 50% of the ribosomal DNA (rDNA) units of Drosophila melanogaster are inactivated by two different 28 S RNA ribosomal gene insertions (type I and type II). We present here the nucleotide sequence of complete type I and type II elements. Conceptual translation of these sequences revealed open reading frames (ORFs) encoding amino acid residues conserved in all retrotransposable elements. Full-length type I elements are 5.35 x 10(3) base-pairs in length and contain two overlapping ORFs. The smaller ORF (471 amino acid residues) has similarity to gag genes, while the larger ORF (1021 residues) has similarity to pol genes. Full-length type II elements are 3.6 x 10(3) base-pairs and contain one large ORF (1056 residues) that appears to represent a gag-pol fusion. Type I and type II elements are similar in structure, in the proteins they encode, and in insertion specificity to the R1Bm and R2Bm retrotransposable elements of Bombyx mori. We suggest that the D. melanogaster elements be called R1Dm and R2Dm, to reflect their structure as retrotransposons. Comparison of the R1 and R2 elements from these two widely different species revealed regions of the ORF that are likely to play an important role in the propagation of the elements. Four distinct regions of sequence conservation separated by regions of little or no sequence similarity were detected for both the R1 and R2 elements: (1) cysteine motifs of the gag gene, with three such motifs for R1 and one motif for R2; (2) a reverse transcriptase domain; (3) an integrase domain located carboxyl terminal to the reverse transcriptase region; and (4) a small region amino terminal to the reverse transcriptase domain, whose function is not known. The level of identity of the amino acid residues for these segments is 28 to 34% between the R1 elements, and 34 to 39% for the R2 elements. Finally, it may be predicted that the mechanism of unequal crossover might eventually eliminate R1 and R2 from the rDNA locus. The long history of selection at the protein level exhibited by these elements indicates that it is their active transposition that maintains them in the locus. The high level of sequence homogeneity between copies of each element within the same species is consistent with the high turnover rate expected to result from these processes.

Identification of four conserved motifs among the RNA-dependent polymerase encoding elements

Four consensus sequences are conserved with the same linear arrangement in RNA-dependent DNA polymerases encoded by retroid elements and in RNA-dependent RNA polymerases encoded by plus-, minus- and double-strand RNA viruses. One of these motifs corresponds to the YGDD span previously described by Kamer and Argos (1984). These consensus sequences altogether lead to 4 strictly and 18 conservatively maintained amino acids embedded in a large domain of 120 to 210 amino acids. As judged from secondary structure predictions, each of the 4 motifs, which may cooperate to form a well-ordered domain, places one invariant amino acid in or proximal to turn structures that may be crucial for their correct positioning in a catalytic process. We suggest that this domain may constitute a prerequisite 'polymerase module' implicated in template seating and polymerase activity. At the evolutionary level, the sequence similarities, gap distribution and distances between each motif strongly suggest that the ancestral polymerase module was encoded by an individual genetic element which was most closely related to the plus-strand RNA viruses and the non-viral retroposons. This polymerase module gene may have subsequently propagated in the viral kingdom by distinct gene set recombination events leading to the wide viral variety observed today.

Functional analysis of the long terminal repeats of Drosophila 1731 retrotransposon: promoter function and steroid regulation

1731 is a Drosophila retrotransposon whose transcripts decrease in Drosophila cells after treatment by the steroid hormone 20-hydroxyecdysone (20-OH). Several constructions have been made where the bacterial chloramphenicol acetyltransferase (CAT) gene is put under the control of either the 5' or the 3' long terminal repeats (LTRs) of 1731. CAT activity assays in transfected Drosophila cells show that either the 5' or the 3'LTR constitutes a unidirectional promoter. Analysis of partially deleted LTR suggests the presence of so-called silencer and activator regions in these LTRs. Moreover, the first 260 bp of the LTR are sufficient to provoke 20-OH inhibition whereas the first 58 bp are necessary for hormonal responsiveness. These 58 bp contain sequences showing similarities with the targets of trans-acting factors such as Octal-c and NFkB.

Evidence that mutation patterns vary among Drosophila transposable elements

In Drosophila melanogaster, codon usage in the open reading frames (ORFs) of transposable elements (TEs) differs greatly from that in other ORFs. In addition, while the ORFs from a single element are similar, there is considerable variation among elements. In the TE ORFs there are no indications of selection for the codons prevalent in the other D. melanogaster genes, but rather codon usage can be succinctly summarized in terms of the base composition at silent sites. We suggest that the particular silent site base composition of each TE is determined by an individual pattern of mutation. In many of the TEs there is an ORF encoding a protein with homology to reverse transcriptase; the amino acid sequences of these are quite divergent, and so it is possible that each of these incorporates certain mismatched bases at different frequencies during replication.

The transcriptional control regions of the copia retrotransposon

We have analysed the sequence elements that control expression of the copia retrotransposon. Expression of copia fusion constructs containing DNA sequence deletions and rearrangements was assayed by transient expression analysis. Progressive deletion and linker substitution identifies two regions on either side of the major transcriptional start sites in the copia long terminal repeat These regions are both required for high level expression in a cultured Drosophila melanogaster cell line but only the upstream region is required for copia expression in a Drosophila hydei cell line. A third control region lies downstream of the long terminal repeat in a region previously believed to contain no cis-acting regulatory sequences. We show by displacement and inversion of this region that it contains a transcriptional enhancer.

On the transposition of copia-like nomadic elements in cultured Drosophila cells

We studied the stability of the genomic distribution of six retrotransposon families in long-term and short-term cultures of Drosophila cells. In a subclone derived from Kc cells, no significant rearrangements were detected over an 8 year period. On the contrary, extensive reshuffling and amplification of transposon families were observed in recently established cell lines. These results show that in cultured Drosophila cells transposition appears to be restricted to the transition from the embryo to continuous cell lines.