The Tc2 transposon of Caenorhabditis elegans has the structure of a self-regulated element

Genome-wide characterization of Mariner-like transposons and their derived MITEs in the Whitefly Bemisia tabaci (Hemiptera: Aleyrodidae)

The whitefly, Bemisia tabaci is a hemipteran pest of vegetable crops vectoring a broad category of viruses. Currently, this insect pest showed a high adaptability and resistance to almost all the chemical compounds commonly used for its control. In many cases, transposable elements (TEs) contributed to the evolution of host genomic plasticity. This study focuses on the annotation of Mariner-like elements (MLEs) and their derived Miniature Inverted repeat Transposable Elements (MITEs) in the genome of B. tabaci. Two full-length MLEs belonging to mauritiana and irritans subfamilies were detected and named Btmar1.1 and Btmar2.1, respectively. Additionally, 548 defective MLE sequences clustering mainly into 19 different Mariner lineages of mauritiana and irritans subfamilies were identified. Each subfamily showed a significant variation in MLE copy number and size. Furthermore, 71 MITEs were identified as MLEs derivatives that could be mobilized via the potentially active transposases encoded by Btmar 1.1 and Btmar2.1. The vast majority of sequences detected in the whitefly genome present unusual terminal inverted repeats (TIRs) of up to 400 bp in length. However, some exceptions are sequences without TIRs. This feature of the MLEs and their derived MITEs in B. tabaci genome that distinguishes them from all the other MLEs so far described in insects, which have TIRs size ranging from 20 to 40 bp. Overall, our study provides an overview of MLEs, especially those with large TIRs, and their related MITEs, as well as diversity of their families, which will provide a better understanding of the evolution and adaptation of the whitefly genome.

Multiple waves of recent DNA transposon activity in the bat, Myotis lucifugus

DNA transposons, or class 2 transposable elements, have successfully propagated in a wide variety of genomes. However, it is widely believed that DNA transposon activity has ceased in mammalian genomes for at least the last 40 million years. We recently reported evidence for the relatively recent activity of hAT and Helitron elements, two distinct groups of DNA transposons, in the lineage of the vespertilionid bat Myotis lucifugus. Here, we describe seven additional families that have also been recently active in the bat lineage. Early vespertilionid genome evolution was dominated by the activity of Helitrons, mariner-like and Tc2-like elements. This was followed by the colonization of Tc1-like elements, and by a more recent explosion of hAT-like elements. Finally, and most recently, piggyBac-like elements have amplified within the Myotis genome and our results indicate that one of these families is probably still expanding in natural populations. Together, these data suggest that there has been tremendous recent activity of various DNA transposons in the bat lineage that far exceeds those previously reported for any mammalian lineage. The diverse and recent populations of DNA transposons in genus Myotis will provide an unprecedented opportunity to study the impact of this class of elements on mammalian genome evolution and to better understand what makes some species more susceptible to invasion by genomic parasites than others.

Characterization of multiple lineages of Tc1-like elements within the genome of the amphibian Xenopus tropicalis

We have used genomic sequencing data extracted from the first assembly of the Xenopus tropicalis genome combined with a degenerated PCR approach to identify multiple lineages of Tc1 related transposable elements. Full-length elements were isolated in each lineage and were characterized. Most of them exhibit the typical characteristics of Tc1-like elements (TLEs). An open reading frame (ORF) encoding a 340-350 aa transposase containing a [D, D(34)E] signature was found as well as conserved inverted terminal repeats (ITRs) at each extremities. These ITRs could vary in length, depending on the TLE lineage. These new TLEs were named Eagle, Froggy, Jumpy, Maya, Xeminos, XtTXr and XtTXz. Phylogenetic analyses indicate that their closest relatives are present in the genomes of actinopterygian and amphibian. Interestingly, Maya and Xeminos share remarkable characteristics. Maya contains a [D,D(36)E] motif but is not related to any described TLE so far. Xeminos is the first vertebrate TLE strongly related to an invertebrate lineage. Finally, we have identified for most of these TLEs, copies containing an intact transposase ORF suggesting that these elements may still be active.

Shared transcriptional signature in Caenorhabditis elegans Dauer larvae and long-lived daf-2 mutants implicates detoxification system in longevity assurance

In the nematode Caenorhabditis elegans, formation of the long-lived dauer larva and adult aging are both controlled by insulin/insulin-like growth factor-1 signaling. Potentially, increased adult life span in daf-2 insulin/insulin-like growth factor-1 receptor mutants results from mis-expression in the adult of a dauer larva longevity program. By using oligonucleotide microarray analysis, we identified a dauer transcriptional signature in daf-2 mutant adults. By means of a nonbiased statistical approach, we identified gene classes whose expression is altered similarly in dauers and daf-2 mutants, which represent potential determinants of life span. These include known determinants of longevity; the small heat shock protein/alpha-crystallins are up-regulated in both milieus. The cytochrome P450, short-chain dehydrogenase/reductase, UDP-glucuronosyltransferase, and glutathione S-transferase (in daf-2 mutants) gene classes were also up-regulated. These four gene classes act together in metabolism and excretion of toxic endobiotic and xenobiotic metabolites. This suggests that diverse toxic lipophilic and electrophilic metabolites, disposed of by phase 1 and phase 2 drug metabolism, may be the major determinants of the molecular damage that causes aging. In addition, we observed down-regulation of genes linked to nutrient uptake, including nhx-2 and pep-2. These work together in the uptake of dipeptides in the intestine, implying dietary restriction in daf-2 mutants. Some gene groups up-regulated in dauers and/or daf-2 were enriched for certain promoter elements as follows: the daf-16-binding element, the heat shock-response element, the heat shock-associated sequence, or the hif-1-response element. By contrast, the daf-16-associated element was enriched in genes down-regulated in dauers and daf-2 mutants. Thus, particular promoter elements appear longevity-associated or aging associated.

Continuous exchange of sequence information between dispersed Tc1 transposons in the Caenorhabditis elegans genome

In a genome-wide analysis of the active transposons in Caenorhabditis elegans we determined the localization and sequence of all copies of each of the six active transposon families. Most copies of the most active transposons, Tc1 and Tc3, are intact but individually have a unique sequence, because of unique patterns of single-nucleotide polymorphisms. The sequence of each of the 32 Tc1 elements is invariant in the C. elegans strain N2, which has no germline transposition. However, at the same 32 Tc1 loci in strains with germline transposition, Tc1 elements can acquire the sequence of Tc1 elements elsewhere in the N2 genome or a chimeric sequence derived from two dispersed Tc1 elements. We hypothesize that during double-strand-break repair after Tc1 excision, the template for repair can switch from the Tc1 element on the sister chromatid or homologous chromosome to a Tc1 copy elsewhere in the genome. Thus, the population of active transposable elements in C. elegans is highly dynamic because of a continuous exchange of sequence information between individual copies, potentially allowing a higher evolution rate than that found in endogenous genes.

Characterization of Mcmar1, a mariner-like element with large inverted terminal repeats (ITRs) from the phytoparasitic nematode Meloidogyne chitwoodi

Two copies of a new mariner-like element (MLE) presenting unusual inverted terminal repeats (ITRs), Mcmar1-1 and Mcmar1-2, were cloned and sequenced in the genome of the phytoparasitic nematode Meloidogyne chitwoodi. Although the sequence features of these Mcmar1 transposons are commonplace and link them to the mariner family, at their extremities they have large 355-pb long inverted terminal repeats that are perfectly conserved. This characteristic distinguishes them from all the other MLEs so far described that have imperfectly conserved ITRs of about 26-30 bp. In consequence, the sequenced full-length Mcmar1-1 element is 2000 bp long, and comprises an uninterrupted open reading frame (ORF) that encodes a putatively active transposase with 340 amino acid residues. The Mcmar1-2 element is a deleted form of Mcmar1-1 that contains a deletion overlapping most of the internal region of the 5'ITR and the 5' region of the transposase ORF. The presence of large ITRs in different transposons related to the Tc1-mariner super-family is discussed.

Transposons but not retrotransposons are located preferentially in regions of high recombination rate in Caenorhabditis elegans

We analyzed the distribution of transposable elements (TEs: transposons, LTR retrotransposons, and non-LTR retrotransposons) in the chromosomes of the nematode Caenorhabditis elegans. The density of transposons (DNA-based elements) along the chromosomes was found to be positively correlated with recombination rate, but this relationship was not observed for LTR or non-LTR retrotransposons (RNA-based elements). Gene (coding region) density is higher in regions of low recombination rate. However, the lower TE density in these regions is not due to the counterselection of TE insertions within exons since the same positive correlation between TE density and recombination rate was found in noncoding regions (both in introns and intergenic DNA). These data are not compatible with a global model of selection acting against TE insertions, for which an accumulation of elements in regions of reduced recombination is expected. We also found no evidence for a stronger selection against TE insertions on the X chromosome compared to the autosomes. The difference in distribution of the DNA and RNA-based elements along the chromosomes in relation to recombination rate can be explained by differences in the transposition processes.

Molecular and evolutionary analysis of two divergent subfamilies of a novel miniature inverted repeat transposable element in the yellow fever mosquito, Aedes aegypti

A novel family of miniature inverted repeat transposable elements (MITEs) named Pony was discovered in the yellow fever mosquito, Aedes aegypti. It has all the characteristics of MITEs, including terminal inverted repeats, no coding potential, A+T richness, small size, and the potential to form stable secondary structures. Past mobility of PONY: was indicated by the identification of two Pony insertions which resulted in the duplication of the TA dinucleotide targets. Two highly divergent subfamilies, A and B, were identified in A. aegypti based on sequence comparison and phylogenetic analysis of 38 elements. These subfamilies showed less than 62% sequence similarity. However, within each subfamily, most elements were highly conserved, and multiple subgroups could be identified, indicating recent amplifications from different source genes. Different scenarios are presented to explain the evolutionary history of these subfamilies. Both subfamilies share conserved terminal inverted repeats similar to those of the Tc2 DNA transposons in Caenorhabditis elegans, indicating that Pony may have been borrowing the transposition machinery from a Tc2-like transposon in mosquitoes. In addition to the terminal inverted repeats, full-length and partial subterminal repeats of a sequence motif TTGATTCAWATTCCGRACA represent the majority of the conservation between the two subfamilies, indicating that they may be important structural and/or functional components of the Pony elements. In contrast to known autonomous DNA transposons, both subfamilies of PONY: are highly reiterated in the A. aegypti genome (8,400 and 9, 900 copies, respectively). Together, they constitute approximately 1. 1% of the entire genome. Pony elements were frequently found near other transposable elements or in the noncoding regions of genes. The relative abundance of MITEs varies in eukaryotic genomes, which may have in part contributed to the different organizations of the genomes and reflect different types of interactions between the hosts and these widespread transposable elements.

Evidence that a family of miniature inverted-repeat transposable elements (MITEs) from the Arabidopsis thaliana genome has arisen from a pogo-like DNA transposon

Sequence similarities exist between terminal inverted repeats (TIRs) of some miniature inverted-repeat transposable element (MITE) families isolated from a wide range of organisms, including plants, insects, and humans, and TIRs of DNA transposons from the pogo family. We present here evidence that one of these MITE families, previously described for Arabidopsis thaliana, is derived from a larger element encoding a putative transposase. We have named this novel class II transposon Lemi1. We show that its putative product is related to transposases of the Tc1/mariner superfamily, being closer to the pogo family. A similar truncated element was found in a tomato DNA sequence, indicating an ancient origin and/or horizontal transfer for this family of elements. These results are reminiscent of those recently reported for the human genome, where other members of the pogo family, named Tiggers, are believed to be responsible for the generation of abundant MITE-like elements in an early primate ancestor. These results further suggest that some MITE families, which are highly reiterated in plant, insect, and human genomes, could have arisen from a similar mechanism, implicating pogo-like elements.

Pogo transposase contains a putative helix-turn-helix DNA binding domain that recognises a 12 bp sequence within the terminal inverted repeats

Pogo is a transposable element with short terminal inverted repeats. It contains two open reading frames that are joined by splicing and code for the putative pogo transposase, the sequence of which indicates that it is related to the transposases of members of the Tc1/mariner family as well as proteins that have no known transposase activity including the centromere binding protein CENP-B. We have shown that the N-terminal region of pogo transposase binds in a sequence-specific manner to the ends of pogo and have identified residues essential for this. The results are consistent with a prediction that DNA binding is due to a helix-turn-helix motif within this region. The transposase recognises a 12 bp sequence, two copies of which are present at each end of pogo DNA. The outer two copies occur as inverted repeats 14 nucleotides from each end of the element, and contain a single base mismatch and indicate the inverted repeats of pogo are 26 nucleotides long. The inner copies occur as direct repeats, also with a single mismatch.

Characterization of the Sol3 family of nonautonomous transposable elements in tomato and potato

Sol3 transposons are mobile elements defined by long terminal inverted repeats which are found in tomato and potato. Members of the Sol3 family have been isolated from a variety of solanaceous species including Solanum tuberosum (potato), S. demissum, S. chacoense, Lycopersicon esculentum (tomato), and L. hirsutum. While highly conserved elements are found within different species, Sol3 terminal inverted repeats can also flank unrelated sequences. Southern blot analysis indicates that Sol3 elements are less prevalent in the potato (approximately 50 copies) than in the tomato (>100 copies) genome. No Sol3-hybridizing sequences were observed in tobacco. While a number of Sol3 elements ranging in size from 500 bp to 2 kbp were sequenced, no transposase coding domains could be identified within the internal regions of the elements. The data suggest that the Sol3 represent a heterogeneous family of nonautonomous transposable elements associated with an as-yet-unidentified autonomous transposon.

Members of the pogo superfamily of DNA-mediated transposons in the human genome

A new superfamily of transposons from fungi, nematodes, and flies related to the pogo element of Drosophila melanogaster was recognized that represents a branch of the extended superfamily of transposase and integrase proteins sharing a common D.D35E catalytic domain. Searches of human sequences in the public databases for similarity to this domain revealed at least two members of this new superfamily, with many highly mutated copies, in the human genome. A full-length consensus was constructed for one of them, which includes the MER37 medium reiteration frequency sequence recognized previously, from 343 human sequence accessions (261 of which are unique). Most of these were Expressed Sequence Tags, some were Sequence-Tagged Sites, and a few are from long genomic sequences. The 2417 bp consensus has the hallmarks of a pogo superfamily transposon, including 12 bp inverted terminal repeats, and encodes two long open reading frames. The first ORF encodes a polypeptide with 42% amino acid sequence identity to pogo in the D.D35E region. The second element shows 49% amino acid sequence identity with the first, and 40% with pogo in this region. These elements coincide with those described recently as Tigger1 and Tigger2, respectively. These transposons appear to have been active 80-90 Myr ago in the genome of an early primate or primate ancestor.

Identification of putative nonautonomous transposable elements associated with several transposon families in Caenorhabditis elegans

Putative nonautonomous transposable elements related to the autonomous transposons Tc1, Tc2, Tc5, and mariner were identified in the C. elegans database by computational analysis. These elements are found throughout the C. elegans genome and are defined by terminal inverted repeats with regions of sequence similarity, or identity, to the autonomous transposons. Similarity between loci containing related nonautonomous elements ends at, or near, the boundaries of the terminal inverted repeats. In most cases the terminal inverted repeats of the putative nonautonomous transposable elements are flanked by potential target-site duplications consistent with the associated autonomous elements. The nonautonomous elements identified vary considerably in size (from 100 bp to 1.5 kb in length) and copy number in the available database and are localized to introns and flanking regions of a wide variety of C. elegans genes.

Tiggers and DNA transposon fossils in the human genome

We report several classes of human interspersed repeats that resemble fossils of DNA transposons, elements that move by excision and reintegration in the genome, whereas previously characterized mammalian repeats all appear to have accumulated by retrotransposition, which involves an RNA intermediate. The human genome contains at least 14 families and > 100,000 degenerate copies of short (180-1200 bp) elements that have 14- to 25-bp terminal inverted repeats and are flanked by either 8 bp or TA target site duplications. We describe two ancient 2.5-kb elements with coding capacity, Tigger1 and -2, that closely resemble pogo, a DNA transposon in Drosophila, and probably were responsible for the distribution of some of the short elements. The deduced pogo and Tigger proteins are related to products of five DNA transposons found in fungi and nematodes, and more distantly, to the Tc1 and mariner transposases. They also are very similar to the major mammalian centromere protein CENP-B, suggesting that this may have a transposase origin. We further identified relatively low-copy-number mariner elements in both human and sheep DNA. These belong to two subfamilies previously identified in insect genomes, suggesting lateral transfer between diverse species.

Identification and characterization of putative transposable DNA elements in solanaceous plants and Caenorhabditis elegans

Several families of putative transposable elements (TrEs) in both solanaceous plants and Caenorhabditis elegans have been identified by screening the DNA data base for inverted repeated domains present in multiple copies in the genome. The elements are localized within intron and flanking regions of many genes. These elements consist of two inverted repeats flanking sequences ranging from 5 bp to > 500 bp. Identification of multiple elements in which sequence conservation includes both the flanking and internal regions implies that these TrEs are capable of duplicative transposition. Two of the elements were identified in promoter regions of the tomato (Lycoperiscon esculentum) polygalacturonase and potato (Solanum tuberosum) Win1 genes. The element in the polygalacturonase promoter spans a known regulatory region. In both cases, ancestral DNA sequences, which represent potential recombination target sequences prior to insertion of the elements, have been cloned from related species. The sequences of the inverted repeated domains in plants and C. elegans show a high degree of phylogenetic conservation. While frequency of the different elements is variable, some are present in very high copy number. A member of a single C. elegans TrE family is observed approximately once every 20 kb in the genome. The abundance of the described TrEs suggests utility in the genomic analysis of these and related organisms.

Mutations in gld-1, a female germ cell-specific tumor suppressor gene in Caenorhabditis elegans, affect a conserved domain also found in Src-associated protein Sam68

The gld-1 gene of Caenorhabditis elegans is a germ-line-specific tumor suppressor gene that is essential for oogenesis. We have cloned the gld-1 gene and find that it encodes two proteins that differ by 3 amino acids. The predicted proteins contain a approximately 170-amino-acid region that we term the GSG domain (GRP33/Sam68/GLD-1), on the basis of significant similarity between GLD-1, GRP33 from shrimp, and the Src-associated protein Sam68 from mouse (also described as GAPap62 from humans). A conserved structural motif called the KH domain is found within the larger GSG domain, suggesting a biochemical function for GLD-1 protein in binding RNA. The importance of the GSG domain to the function of gld-1 in vivo is revealed by mutations that affect 5 different conserved GSG domain residues. These include missense mutations in an absolutely conserved residue of the KH domain that eliminate the tumor suppressor function of gld-1.

A variant Tc4 transposable element in the nematode C. elegans could encode a novel protein

A variant C. elegans Tc4 transposable element, Tc4-rh1030, has been sequenced and is 3483 bp long. The Tc4 element that had been analyzed previously is 1605 bp long, consists of two 774-bp nearly perfect inverted terminal repeats connected by a 57-bp loop, and lacks significant open reading frames. In Tc4-rh1030, by comparison, a 2343-bp novel sequence is present in place of a 477-bp segment in one of the inverted repeats. The novel sequence of Tc4-rh1030 is present about five times per haploid genome and is invariably associated with Tc4 elements; we have used the designation Tc4v to denote this variant subfamily of Tc4 elements. Sequence analysis of three cDNA clones suggests that a Tc4v element contains at least five exons that could encode a novel basic protein of 537 amino acid residues. On northern blots, a 1.6-kb Tc4v-specific transcript was detected in the mutator strain TR679 but not in the wild-type strain N2; Tc4 elements are known to transpose in TR679 but appear to be quiescent in N2. We have analyzed transcripts produced by an unc-33 gene that has the Tc4-rh1030 insertional mutation in its transcribed region; all or almost all of the Tc4v sequence is frequently spliced out of the mutant unc-33 transcripts, sometimes by means of non-consensus splice acceptor sites.