Transposable elements and DNA transposition in eukaryotes

Retrotransposable Elements: DNA Fingerprinting and the Assessment of Genetic Diversity

Retrotransposable elements (RTEs) are highly common mobile genetic elements that are composed of several classes and make up the majority of eukaryotic genomes. The "copy-out and paste-in" life cycle of replicative transposition in these dispersive and ubiquitous RTEs leads to new genome insertions without excision of the original element. RTEs are important drivers of species diversity; they exhibit great variety in structure, size, and mechanisms of transposition, making them important putative components in genome evolution. Accordingly, various applications have been developed to explore the polymorphisms in RTE insertion patterns. These applications include conventional or anchored polymerase chain reaction (PCR) and quantitative or digital PCR with primers designed for the 5' or 3' junction. Marker systems exploiting these PCR methods can be easily developed and are inexpensively used in the absence of extensive genome sequence data. The main inter-repeat amplification polymorphism techniques include inter-retrotransposon amplified polymorphism (IRAP), retrotransposon microsatellite amplified polymorphism (REMAP), and Inter-Primer Binding Site (iPBS) for PCR amplification with a single or two primers.

The somatic piRNA pathway controls germline transposition over generations

Transposable elements (TEs) are parasitic DNA sequences that threaten genome integrity by replicative transposition in host gonads. The Piwi-interacting RNAs (piRNAs) pathway is assumed to maintain Drosophila genome homeostasis by downregulating transcriptional and post-transcriptional TE expression in the ovary. However, the bursts of transposition that are expected to follow transposome derepression after piRNA pathway impairment have not yet been reported. Here, we show, at a genome-wide level, that piRNA loss in the ovarian somatic cells boosts several families of the endogenous retroviral subclass of TEs, at various steps of their replication cycle, from somatic transcription to germinal genome invasion. For some of these TEs, the derepression caused by the loss of piRNAs is backed up by another small RNA pathway (siRNAs) operating in somatic tissues at the post transcriptional level. Derepressed transposition during 70 successive generations of piRNA loss exponentially increases the genomic copy number by up to 10-fold.

Use of retrotransposon-derived genetic markers to analyse genomic variability in plants

Transposable elements (TEs) are common mobile genetic elements comprising several classes and making up the majority of eukaryotic genomes. The movement and accumulation of TEs has been a major force shaping the genes and genomes of most organisms. Most eukaryotic genomes are dominated by retrotransposons and minimal DNA transposon accumulation. The 'copy and paste' lifecycle of replicative transposition produces new genome insertions without excising the original element. Horizontal TE transfer among lineages is rare. TEs represent a reservoir of potential genomic instability and RNA-level toxicity. Many TEs appear static and nonfunctional, but some are capable of replicating and mobilising to new positions, and somatic transposition events have been observed. The overall structure of retrotransposons and the domains responsible for the phases of their replication are highly conserved in all eukaryotes. TEs are important drivers of species diversity and exhibit great variety in their structure, size and transposition mechanisms, making them important putative actors in evolution. Because TEs are abundant in plant genomes, various applications have been developed to exploit polymorphisms in TE insertion patterns, including conventional or anchored PCR, and quantitative or digital PCR with primers for the 5' or 3' junction. Alternatively, the retrotransposon junction can be mapped using high-throughput next-generation sequencing and bioinformatics. With these applications, TE insertions can be rapidly, easily and accurately identified, or new TE insertions can be found. This review provides an overview of the TE-based applications developed for plant species and assesses the contributions of TEs to the analysis of plants' genetic diversity.

PLE-wu, a new member of piggyBac transposon family from insect, is active in mammalian cells

piggyBac, a highly active transposon in insect and mammalian cells, is a very useful tool in genome manipulation. A new piggyBac-like element (PLE), named PLE-wu, was identified from a mutant baculovirus cultured in sf9 insect cells. This new transposon is 2931 bp in length and encodes two active forms of transposase, a 708-amino acid-long transposase and a short 576-residue-long transposase translated from a downstream in-frame initiation codon. PLE-wu has asymmetric terminal structures, containing 6-bp inverted terminal repeats, 32-bp imperfect inverted and direct sub-terminal repeats. Similar to piggyBac, PLE-wu exhibits traceless excision activity in both insect and mammalian cells, restoring the original TTAA target sequence upon excision. It also retains the insertion activity in mammalian cells with a plasmid to chromosome transposition rate about 10-fold higher than random integration. Plasmid rescue assays revealed that the TTAA target sequence was duplicated at the junctions of the insertion site. Deletion of the terminal sequences including the sub-terminal repeats decreased the transposition activity of the 708-residue-long transposase, while the transposition activity of the short form of transposase was not affected. With its low sequence similarity to piggyBac, PLE-wu will contribute to the understanding the mechanism of PLE transposition, as well as design of new transposon systems with higher activity.

Individual analysis of transposon polymorphisms by AFLP

The DNA polymorphisms caused by insertion and excision of transposable elements (TEs) are applicable in studying genome dynamics, genetic diversity, and molecular evolution, generating genome-wide molecular maps and investigating functional attributes of transposons in epigenetics and diseases. Identification of individual mutations caused by TEs using the principles of amplified fragment length polymorphism assay is a reliable and cost-effective approach. The method relies upon selective polymerase chain reaction (PCR) of flanking regions of TE insertion sites in the genome. A detailed procedure is described in this chapter that outlines each step starting from the preparation of PCR template to identification and isolation of the polymorphic bands. The approach outlined in this protocol can be adopted to identify individual polymorphisms caused by any transposon in any organism.

Phylogenetic and functional characterization of the hAT transposon superfamily

Transposons are found in virtually all organisms and play fundamental roles in genome evolution. They can also acquire new functions in the host organism and some have been developed as incisive genetic tools for transformation and mutagenesis. The hAT transposon superfamily contains members from the plant and animal kingdoms, some of which are active when introduced into new host organisms. We have identified two new active hAT transposons, AeBuster1, from the mosquito Aedes aegypti and TcBuster from the red flour beetle Tribolium castaneum. Activity of both transposons is illustrated by excision and transposition assays performed in Drosophila melanogaster and Ae. aegypti and by in vitro strand transfer assays. These two active insect transposons are more closely related to the Buster sequences identified in humans than they are to the previously identified active hAT transposons, Ac, Tam3, Tol2, hobo, and Hermes. We therefore reexamined the structural and functional relationships of hAT and hAT-like transposase sequences extracted from genome databases and found that the hAT superfamily is divided into at least two families. This division is supported by a difference in target-site selections generated by active transposons of each family. We name these families the Ac and Buster families after the first identified transposon or transposon-like sequence in each. We find that the recently discovered SPIN transposons of mammals are located within the family of Buster elements.

Transgenesis in Xenopus using the Sleeping Beauty transposon system

Transposon-based integration systems have been widely used for genetic manipulation of invertebrate and plant model systems. In the past decade, these powerful tools have begun to be used in vertebrates for transgenesis, insertional mutagenesis, and gene therapy applications. Sleeping Beauty (SB) is a member of Tc1/mariner class of transposases and is derived from an inactive form of the gene isolated from Atlantic salmon. SB has been used extensively in human cell lines and in whole animal vertebrate model systems such as the mouse, rat, and zebrafish. In this study, we describe the use of SB in the diploid frog Xenopus tropicalis to generate stable transgenic lines. SB transposon transgenes integrate into the X. tropicalis genome by a noncanonical process and are passed through the germline. We compare the activity of SB in this model organism with that of Tol2, a hAT (hobo, Ac1, TAM)-like transposon system.

The stochastic model of non-equilibrium mutagen-induced alterations of DNA: implication to genetic instability in cancer

Genetic alterations such as point mutations, chromosomal rearrangements, modification of DNA methylation and chromosome aberrations accumulate during the lifetime of an organism. They can be caused by intrinsic errors in the DNA replication and repair as well as by external factors such as exposure to mutagenic substances or radiation. The main purpose of the present work is to begin an exploration of the stochastic nature of non-equilibrium DNA alteration caused by events such as tautomeric shifts. This is done by modeling the genetic DNA code chain as a sequence of DNA-bit values ('1' for normal bases and '-1' for abnormal bases). We observe the number of DNA-bit changes resulting from the random point mutation process which, in the model, is being induced by a stochastic Brownian mutagen (BM) as it diffuses through the DNA-bit systems. Using both an analytical and Monte Carlo (MC) simulation techniques, we observe the local and global number of DNA-bit changes. It is found that in 1D, the local DNA-bit density behaves like 1/t, the global total number of the switched (abnormal) DNA-bit increases as t. The probability distribution P(b, 0, t) of b(0, t) is log-normal. It is also found that when the number of mutagens is increased, the number of the total abnormal DNA-bits does not grow linearly with the number of mutagens. All analytic results are in good agreement with the simulation results.

A hAT superfamily transposase recruited by the cereal grass genome

Transposable elements are ubiquitous genomic parasites with an ancient history of coexistence with their hosts. A few cases have emerged recently where these genetic elements have been recruited for normal function in the host organism. We have identified an expressed hobo/Ac/Tam (hAT) family transposase-like gene in cereal grasses which appears to represent such a case. This gene, which we have called gary, is found in one or two copies in barley, two diverged copies in rice and two very similar copies in hexaploid wheat. No gary homologues are found in Arabidopsis. In all three cereal species, an apparently complete 2.5 kb transposase-like open reading frame is present and nucleotide substitution data show evidence for positive selection, yet the predicted gary protein is probably not an active transposase, as judged by the absence of key amino acids required for transposase function. Gary is expressed in wheat and barley spikes and gary cDNA sequences are also found in rice, oat, rye, maize, sorghum and sugarcane. The short inverted terminal repeats, flanked by an eight-nucleotide host sequence duplication, which are characteristic of a hAT transposon are absent. Genetic mapping in barley shows that gary is located on the distal end of the long arm of chromosome 2H. Wheat homologues of gary map to the same approximate location on the wheat group 2 chromosomes by physical bin-mapping and the more closely related of the two rice garys maps to the syntenic location near the bottom of rice chromosome 4. These data suggest that gary has resided in a single genomic location for at least 60 Myr and has lost the ability to transpose, yet expresses a transposase-related protein that is being conserved under host selection. We propose that the gary transposase-like gene has been recruited by the cereal grasses for an unknown function.

Mobile genetic elements and sexual reproduction

Transposable elements (TE) are prominent components of most eukaryotic genomes. In addition to their possible participation in the origin of sexual reproduction in eukaryotes, they may be also involved in its maintenance as important contributors to the deleterious mutation load. Comparative analyses of transposon content in the genomes of sexually reproducing and anciently asexual species may help to understand the contribution of different TE classes to the deleterious load. The apparent absence of deleterious retrotransposons from the genomes of ancient asexuals is in agreement with the hypothesis that they may play a special role in the maintenance of sexual reproduction and in early extinction for which most species are destined upon the abandonment of sex.

The hAT -like DNA transposon DodoPi resides in a cluster of retro- and DNA transposons in the stramenopile Phytophthora infestans

A family of transposable elements belonging to the hAT group of DNA transposons is described from an oomycete, the plant pathogen Phytophthora infestans. The family, named DodoPi, was identified by studying a hotspot for retro- and DNA transposon insertions adjacent to the mating type locus. The DodoPi family comprises a small number of full-length copies, each of which is 2.7 kb long and predicted to encode a transposase-like protein consisting of 617 amino acids, and several truncated copies. Both types contain 12-bp terminal inverted repeats and are flanked by 8-bp target site duplications. Despite the detection of a DodoPi transcript and of many polymorphisms between isolates, conclusive evidence of recent transposition was not obtained. A phylogenetic analysis indicated that DodoPi was novel, with only modest similarity to some elements from plants and fungi. Relatives were detected in only some members of the genus. This is the first DNA transposon identified in the stramenopile group of eukaryotes.

Polymorphisms flanking the mariner integration sites in the rice gall midge (Orseolia oryzae Wood-Mason) genome are biotype-specific

In an effort to study genome diversity within and between the Indian biotypes of the Asian rice gall midge, Orseolia oryzae, a major insect pest of rice, we made use of mariner transposable element integration site polymorphisms. Using degenerate primers, the design of which is based on mariner sequences, we amplified a ca. 450 bp mariner sequence from the rice gall midge. The mariner sequence showed homology with that of a mariner element isolated from the Hessian fly, Mayetiola destructor, a major dipteran pest of wheat. Southern hybridization, using this mariner fragment as a probe, revealed that the mariner elements are moderately to highly repetitive in the rice gall midge genome. Based on the sequence information of this 450-bp PCR-amplified fragment, outward-directed primers were designed and used in an inverse PCR (iPCR) to amplify the DNA flanking the conserved regions. To study the regions flanking the mariner integration sites, we employed a novel PCR-based approach: a combination of sequence specific amplification polymorphism (SSAP) and amplified fragment length polymorphism (AFLP). The outward-directed mariner-specific primer was used in combination with adapter-specific primers with 1-3 selective nucleotides at their 3' ends. The amplification products were resolved on an agarose gel, Southern-transferred onto nylon membranes, and probed with the iPCR fragment. Results revealed biotype-specific polymorphisms in the regions flanking the mariner integration sites, suggesting that mariner elements in the rice gall midge may be fixed in a biotype-specific manner. The implications of these results are discussed in the context of biotype differentiation.

Structure and evolution of the hAT transposon superfamily

The maize transposon Activator (Ac) was the first mobile DNA element to be discovered. Since then, other elements were found that share similarity to Ac, suggesting that it belongs to a transposon superfamily named hAT after hobo from Drosophila, Ac from maize, and Tam3 from snapdragon. We addressed the structure and evolution of hAT elements by developing new tools for transposon mining and searching the public sequence databases for the hallmarks of hAT elements, namely the transposase and short terminal inverted repeats (TIRs) flanked by 8-bp host duplications. We found 147 hAT-related sequences in plants, animals, and fungi. Six conserved blocks could be identified in the transposase of most hAT elements. A total of 41 hAT sequences were flanked by TIRs and 8-bp host duplications and, out of these, 34 sequences had TIRs similar to the consensus determined in this work, suggesting that they are active or recently active transposons. Phylogenetic analysis and clustering of hAT sequences suggest that the hAT superfamily is very ancient, probably predating the plant-fungi-animal separation, and that, unlike previously proposed, there is no evidence that horizontal gene transfer was involved in the evolution of hAT elements.

Reverse transcriptase can stabilize or destabilize the genome

Telomeres, the eukaryotic chromosome termini, are deoxyribonucleoprotein structures that distinguish natural chromosome ends from broken DNA. In most organisms, telomeres are extended by a reverse transcriptase (RT) with an integrated RNA template, telomerase; in Drosophila melanogaster, however, telomere-specific retrotransposons, HeT-A and TART, transpose specifically to chromosome ends. Whether telomeres are extended by a telomerase or by retrotransposons, an RT is a key component. RT has been studied extensively, both for its important role in converting RNA genomes to DNA, which has great evolutionary impact, and as a therapeutic target in human retroviral diseases. Here we discuss a few important aspects of RT usage during retrotransposition and telomere elongation.Key words: telomeres, telomerase, retrotransposons, reverse transcriptase.

Oncoviral DNAs induce transposition of endogenous mobile elements in the genome of Drosophila melanogaster

Previously, we have shown that particles of Rous sarcoma virus or cloned fragments of RSV cDNA as well as DNA of oncogenic simian adenovirus Sa7, injected into the polar plasm of early Drosophila melanogaster embryos, were able to induce, with high frequency, unstable visible mutations in different groups of genetic loci. The genetic instability of the recovered mutations, i.e., their ability to revert to normal state or to generate new mutant alleles at the affected locus, was manifest in mutant lines through several generations. The molecular analysis undertaken in this study of the yellow-scute loci region which is highly sensitive to the microinjected Sa7 DNA, and of the white locus, that frequently mutates under the influence of RSV cDNA, clearly shows that the induced mutations and reversions are accompanied by insertion/excision of endogenous mobile elements. This conclusion is confirmed by in situ hybridization experiments which demonstrate that the adenovirus DNA is able to change, though with different efficiency, the chromosomal localization of certain Drosophila retrotransposons. These results partially elucidate the molecular mechanism of the genetic instability in D. melanogaster induced by microinjection of oncoviruses into early embryos, implying that is results from mobilization of endogenous transposons which play the role of insertional elements directly causing unstable mutations.

Homologous sequences in the Campoletis sonorensis polydnavirus genome are implicated in replication and nesting of the W segment family

Polydnaviruses (PDVs) are double-stranded DNA viruses with segmented genomes that replicate only in the oviducts of some species of parasitic wasps and are required for the successful parasitization of lepidopteran insects. PDV DNA segments are integrated in the genomes of their associated wasp hosts, and some are nested; i.e., smaller segments are produced from and largely colinear with larger segments. To determine the internal structure of nested viral segments, the first complete nucleotide sequence of a PDV genome segment and its integration locus was determined. By restriction mapping, Southern blot, and sequence analyses, we demonstrated that the Campoletis sonorensis PDV segment W is integrated into wasp genomic DNA. DNA sequence analysis revealed that proviral segment W terminates in two 1,185-bp direct long terminal repeats (LTRs) in the wasp chromosome, while only one LTR copy is present in the extrachromosomal (viral) W. The results suggest that terminal direct repeats are a general feature of PDV DNA segment integration but that the homology and size of the repeats can vary extensively. Segment W contains 12 imperfect direct repeats of six different types between 89 bp and 1.9 kbp with 65 to 90% homology. The orientation and structure of the repeats suggest that W itself may have arisen through sequence duplication and subsequent divergence. Mapping, hybridization, and sequence analyses of cloned R and M demonstrated that these segments are nested within segment W and that internal imperfect direct repeats of one type are implicated in the homologous intramolecular recombination events that generate segments R and M. Interestingly, segment nesting differentially increases the copy number of genes encoded by segment W, suggesting that the unusual genomic organization of PDVs may be directly linked to the unique functions of this virus in its obligate mutualistic association with parasitic wasps.

Excision of the piggyBac transposable element in vitro is a precise event that is enhanced by the expression of its encoded transposase

The piggyBac Lepidopteran transposable element moves from the cellular genome into infecting baculovirus genomes during passage of the virus in cultured TN-368 cells. We have constructed genetically tagged piggyBac elements that permit analysis of excision when transiently introduced on plasmids into the piggyBac-deficient Spodoptera frugiperda IPLB-SF21AE cell line. Precise excision of the element from these plasmids occurs at a higher frequency in the presence of a helper plasmid that presumably supplies the piggyBac transposase. The results suggest that the piggyBac transposon encodes a protein that functions to facilitate not only insertion, but precise excision as well. This is the first demonstration of piggyBac mobility from plasmid sources in uninfected Lepidopteran cells.

Germ line and embryonic expression of Fex, a member of the Drosophila F-element retrotransposon family, is mediated by an internal cis-regulatory control region

The F elements of Drosophila melanogaster belong to the superfamily of long interspersed nucleotide element retrotransposons. To date, F-element transcription has not been detected in flies. Here we describe the isolation of a member of the F-element family, termed Fex, which is transcribed in specific cells of the female and male germ lines and in various tissues during embryogenesis of D. melanogaster. Sequence analysis revealed that this element contains two complete open reading frames coding for a putative nucleic acid-binding protein and a putative reverse transcriptase. Functional analysis of the 5' region, using germ line transformation of Fex-lacZ reporter gene constructs, demonstrates that major aspects of tissue-specific Fex expression are controlled by internal cis-acting elements that lie in the putative coding region of open reading frame 1. These sequences mediate dynamic gene expression in eight expression domains during embryonic and germ line development. The capacity of the cis-regulatory region of the Fex element to mediate such complex expression patterns is unique among members of the long interspersed nucleotide element superfamily of retrotransposons and is reminiscent of regulatory regions of developmental control genes.

Precise excision of TTAA-specific lepidopteran transposons piggyBac (IFP2) and tagalong (TFP3) from the baculovirus genome in cell lines from two species of Lepidoptera

Transposon mutagenesis of baculoviruses provides an ideal experimental system for analysis of the movement of a unique family of mobile element identified from lepidopteran genomes. Members of this family of short-inverted-repeat elements are characterized by their extreme specificity for TTAA target sites. This report describes the analysis of excision events for two representatives of this family, tagalong (formerly TFP3) and piggyBac (formerly IFP2). These elements were tagged with a polyhedrin/lacZ reporter gene and inserted back into the virus genome either by homologous recombination or by transposition. Revertants were selected based on a white plaque phenotype. Both elements excise in a precise fashion from their positions in the baculovirus genome in either TN-368 cells or IPLB-SF21 AE cells. The precise excision of these elements in infected IPLB-SF21 AE cells occurs in the absence of either tagalong or piggyBac element encoded functions. The common characteristics of both insertion and excision for these elements provides further validation for their inclusion in a single family of unique transposons.

PCR analysis of insertion site specificity, transcription, and structural uniformity of the Lepidopteran transposable element IFP2 in the TN-368 cell genome

The IFP2 element is a unique Lepidopteran transposon that has been associated with spontaneous Baculovirus mutants isolated following passage of the virus in the TN-368 cell line. Independent genomic representatives of IFP2 from TN-368 cells show little sequence divergence, suggesting that IFP2 was recently introduced into this genome and is highly stable. IFP2 is inserted within AT-rich regions of the TN-368 genome and targets TTAA sites. The specificity for TTAA target sites during transposition is not limited to the movement of IFP2 during an active Baculovirus infection, but is a property of its movement in uninfected cells as well. The exact origin of IFP2 remains obscure since it is found in two independently established Trichoplusia ni cell lines but not in three others, and we have not yet identified any IFP2 sequences in either field collected larvae or laboratory colonies.

Complete sequence of a mariner transposable element from the predatory mite Metaseiulus occidentalis isolated by an inverse PCR approach

Degenerate primers designed and synthesized based on two conserved regions of the mariner transposase open reading frame were used to amplify a 454 bp DNA fragment from M. occidentalis. Two inverse primers were then synthesized and used to amplify flanking genomic DNA fragments from M. occidentalis by a ligation-mediated inverse PCR. The complete mariner element (Moc1) was 1284 bp long, including the imperfect 28 bp inverted terminal repeat sequences, and shared 59% similarity to an active 1286 bp long D. mauritiana mariner element (Mos1). Insertions, deletions and substitutions were observed in the Moc1 sequence at several positions. No intact open reading frame was detected and the Moc1 element is considered inactive. Stringent Southern blot hybridizations revealed at least twelve copies of mariner sequences similar to Moc1 in the colonies tested.

Localized expression of a novel micropia-like element in the blastoderm of Drosophila melanogaster is dependent on the anterior morphogen bicoid

We have identified a novel transposon-like element of Drosophila melanogaster that is present in approximately 20 copies in the genome. It codes for a polyprotein containing the diagnostic sequence motifs for a nucleic acid binding CCHC protein, a proteinase, a reverse transcriptase and an integrase as typically found in retroviruses. Owing to its early expression in the blastoderm embryo, and its close relationship to micropia, a previously identified Drosophila retrotransposon, we termed the novel element "blastopia". The spatially restricted expression of blastopia transcripts in head anlagen of the blastoderm embryo is under the direct or indirect control of the Drosophila morphogen bicoid, which is normally required to establish the anterior pattern elements in the embryo. Our results suggest that a blastopia element acts as an "enhancer trap", and thereby participates in the control of an as yet unidentified gene normally expressed in the head anlagen of the embryo.

The Drosophila copia retrotransposon contains binding sites for transcriptional regulation by homeoproteins

We have identified in the 5' untranslated region of the Drosophila copia retrotransposon, 3' to the left LTR, a sequence for transcriptional regulation by homeoproteins. Co-transfection assays using expression vectors for homeoproteins and reporter vectors containing the lacZ gene under the control of either the entire copia LTR with 5' untranslated sequence, or a minimal heterologous promoter flanked with a 130 bp fragment containing the copia untranslated region, disclosed both positive and negative modulations of promoter activity in Drosophila cells in culture: a 5-10 fold decrease with engrailed, even-skipped and zerknüllt in DH33 cells, and a 10-30 fold increase with fushi tarazu and zerknüllt in Schneider II cells. In all cases, the regulatory effects were abolished with reporter plasmids deleted for a 58 bp fragment encompassing the putative homeoprotein binding sites. Mobility shift assays with a purified homeodomain-containing peptide demonstrated direct interaction with the 58 bp fragment, with an affinity in the 1-10 nM range as reported with the same peptide for other well characterized homeodomain binding regulatory sites. Foot-printing experiments with the extended LTR demonstrated protection of 'consensus' sequences, located within the 58 bp fragment. These homeodomain binding sites could be involved in the developmental regulation of the copia retrotransposon.

Presence of a member of the Tc1-like transposon family from nematodes and Drosophila within the vasotocin gene of a primitive vertebrate, the Pacific hagfish Eptatretus stouti

Molecular cloning of the vasotocin gene of a cyclostome, the Pacific hagfish Eptatretus stouti, reveals, in contrast to other known members of the vertebrate vasopressin/oxytocin hormone gene family, an unusual exon-intron organization. Although the location of three exons and two introns is conserved, an additional intron is present 5' of the coding region of the hagfish gene. The third intron, which is greater than 14 kilobase pairs in size, contains on the opposite DNA strand to that encoding vasotocin an open reading frame exhibiting striking similarity to the putative transposase of Tc1-like nonretroviral mobile genetic DNA elements, so far reported only from nematodes and Drosophila. The hagfish element, called Tes1, is flanked by inverted terminal repeats representing an example of the existence of a typical inverted terminal-repeat transposon within vertebrates. The presence of Tc1-like elements in nematodes, Drosophila, and cyclostomes indicates that these genetic elements have a much broader phylogenetic distribution than hitherto expected.

Control of transcription of Drosophila retrotransposons

Studies of transcriptional control sequences responsible for regulated and basal-level RNA synthesis from promoters of Drosophila melanogaster retrotransposons reveal novel aspects of gene regulation and lead to identification of trans-acting factors that can be involved in RNA polymerase II transcription not only of retrotransposons, but of many other cellular genes. Comparisons between promoters of retrotransposons and some other Drosophila genes demonstrate that there is a greater variety in basal promoter structure than previously thought and that many promoters may contain essential sequences downstream from the RNA start site.

Retrotransposon Gypsy and genetic instability in Drosophila (review)

The laboratory mutator strain (MS) has properties which can be characterized as genetic instability. It exhibits the high level of gypsy autonomous transposition in somatic and germ cells. This paper summarizes all the data concerning this system and gypsy itself that has been obtained in our works during the last years.