Unexpected stability of mariner transgenes in Drosophila

A number of mariner transformation vectors based on the mauritiana subfamily of transposable elements were introduced into the genome of Drosophila melanogaster and examined for their ability to be mobilized by the mariner transposase. Simple insertion vectors were constructed from single mariner elements into which exogenous DNA ranging in size from 1.3 to 4.5 kb had been inserted; composite vectors were constructed with partial or complete duplications of mariner flanking the exogenous DNA. All of the simple insertion vectors showed levels of somatic and germline excision that were at least 100-fold lower than the baseline level of uninterrupted mariner elements. Although composite vectors with inverted duplications were unable to be mobilized at detectable frequencies, vectors with large direct duplications of mariner could be mobilized. A vector consisting of two virtually complete elements flanking exogenous DNA yielded a frequency of somatic eye-color mosaicism of approximately 10% and a frequency of germline excision of 0.04%. These values are far smaller than those observed for uninterrupted elements. The results imply that efficient mobilization of mariner in vivo requires the presence and proper spacing of sequences internal to the element as well as the inverted repeats.     

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.     

Distribution and conservation of the foldback transposable element inDrosophila

Summary Foldback elements are a family of transposable elements described inDrosophila melanogaster. The members of this dispersed repetitive family have terminal inverted repeats that sometimes flank a central region. The inverted repeats of all the family members are homologous.The study of the distribution and conservation of the foldback elements in differentDrosophila species shows that this distribution is different from that of the hybrid dysgenesis systems (PM and IR). Sequences homologous to foldback elements were observed by Southern blots and in situ hybridization in all species of themelanogaster subgroup and in some species of themontium andtakahashii subgroups. The element was probably already present before the radiation of these subgroups. No evidence of horizontal transmission of the foldback element could be observed.     

Complete foldback transposable elements encode a novel protein found in Drosophila melanogaster.

An apparently complete foldback (FB) transposable element homologous to FB white-crimson (FBwc) was analyzed. A complete FB element could encode one or more proteins required for regulation of FB transposition. The central DNA region (the loop) and the junctions between the loop and the inverted terminal repeats were sequenced. Three open reading frames (ORFs) are present in the loop, and a novel 308 bp inverted repeat is present at the junctions. No significant homologies were found when the DNA sequences of the loop region and the novel inverted repeat were screened against the Gene data bank. Antibodies were prepared in guinea-pigs against a peptide present near the amino terminus of ORF1, the longest ORF. A 71,000 dalton protein was isolated from an extract of Drosophila melanogaster early-stage embryos on an anti-ORF1 peptide-affinity column. Immunohistochemical studies of adult flies demonstrate localization of this protein in egg chambers.     

Efficient mobilization of mariner in vivo requires multiple internal sequences

Aberrant products of mariner excision that have an impaired ability to be mobilized often include internal deletions that do not encroach on either of the inverted repeats. Analysis of 13 such deletions, as well as 7 additional internal deletions obtained by various methods, has revealed at least three internal regions whose integrity is necessary for efficient mariner mobilization. Within the 1286-bp element, the essential regions are contained in the intervals bounded by coordinates 229-586, 735-765, and 939-1066, numbering in base pairs from the extreme 5' end of the element. These regions may contain sequences that are necessary for transposase binding or that are needed to maintain proper spacing between binding sites. The isolation of excision-defective elements with point mutations at nucleotide positions 993 and 161/179 supports the hypothesis of sequence requirements, but the reduced mobility of transformation vectors with insertions into the SacI site at position 790 supports the hypothesis of spacing requirements. The finding of multiple internal regions that are essential for efficient mariner mobilization in vivo contrasts with reports that mini-elements with as little as 43 bp of DNA between the inverted repeats can transpose efficiently in vitro.     

Two distinct P element subfamilies in the genome of Drosophila bifasciata

The genome of Drosophila bifasciata harbours two distinct subfamilies of P-homologous sequences, designated M-type and O-type elements based on similarities to P element sequences from other species. Both subfamilies have some general features in common: they are of similar length (M-type: 2935 bp, O-type: 2986 bp), are flanked by direct repeats of 8 by (the presumptive target sequence), contain terminal inverted repeats, and have a coding region consisting of four exons. The splice sites are at homologous positions and the exons have the coding capacity for proteins of 753 amino acids (M-type) and 757 amino acids (O-type). It seems likely that both types of element represent functional transposons. The nucleotide divergence of the two P element subfamilies is high (31%). The main structural difference is observed in the terminal inverted repeats. Whereas the termini of M-type elements consist of 31 by inverted repeats, the inverted repeats of the O-type elements are interrupted by non-complementary stretches of DNA, 12 by at the 5′ end and 14 by at the 3′ end. This peculiarity is shared by all members of the O-type subfamily. Comparison with other P element sequences indicates incongruities between the phylogenies of the species and the P transposons. M-type and O-type elements apparently have no common origin in the D. bifasciata lineage. The M-type sequence seems to be most closely related to the P element from Scaptomyza pallida and thus could be considered as a more recent invader of the D. bifasciata gene pool. The origin of the O-type elements cannot be unequivocally deduced from the present data. The sequence comparison also provides new insights into conserved domains with possible implications for the function of P transposons.     

The 1723 element: a long, homogeneous, highly repeated DNA unit interspersed in the genome of Xenopus laevis

We describe a highly repeated DNA element in the Xenopus laevis genome. This sequence, named the 1723 element, was first identified among sequences that are transcribed during embryonic development. The element is present in about 8500 copies per haploid genome, which together accounts for about 2.4% of the genome. Most copies of the element have highly conserved restriction maps, and are interspersed in the genome. The copies range in size from 6000 to 10,000 base-pairs due to an expandable region that contains variable numbers of a tandemly repeating 183 to 204 base-pair unit. The element is framed by an imperfect 18 base-pair inverted sequence, and inverted repeats of 180 to 185 base-pairs are nearby. Sequence analysis of DNA adjacent to three cloned elements shows that the elements are flanked by 8 base-pair direct repeats. These and other properties of 1723 suggest that it may be transposable.     

Self-inflicted wounds, template-directed gap repair and a recombination hotspot. Effects of the mariner transposase

Aberrant repair products of mariner transposition occur at a frequency of approximately 1/500 per target element per generation. Among 100 such mutations in the nonautonomous element peach, most had aberrations in the 5' end of peach (40 alleles), in the 3' end of peach (11 alleles), or a deletion of peach with or without deletion of flanking genomic DNA (29 alleles). Most mariner mutations can be explained by exonuclease "nibble" and host-mediated repair of the double-stranded gap created by the transposase, in contrast to analogous mutations in the P element. In mariner, mutations in the 5' inverted repeat are smaller and more frequent than those in the 3' inverted repeat, but secondary mutations in target elements with a 5' lesion usually had 3' lesions resembling those normally found at the 5' end. We suggest that the mariner transposase distinguishes between the 5' and 3' ends of the element, and that the 5' end is relatively more protected after strand scission. We also find: (1) that homolog-dependent gap repair is a frequent accompaniment to mariner excision, estimated as 30% of all excision events; and (2) that mariner is a hotspot of recombination in Drosophila females, but only in the presence of functional transposase.     

The role of vertical and horizontal transfer in the evolution of Paris-like elements in drosophilid species

The transposable element (TE) Paris was described in a Drosophila virilis strain (virilis species group) as causing a hybrid dysgenesis with other mobile genetic elements. Since then, the element Paris has only been found in D. buzzatii, a species from the repleta group. In this study, we performed a search for Paris-like elements in 56 species of drosophilids to improve the knowledge about the distribution and evolution of this element. Paris-like elements were found in 30 species from the Drosophila genus, 15 species from the Drosophila subgenus and 15 species from the Sophophora subgenus. Analysis of the complete sequences obtained from the complete available Drosophila genomes has shown that there are putative active elements in five species (D. elegans, D. kikkawai, D. ananassae, D. pseudoobscura and D. mojavensis). The Paris-like elements showed an approximately 242-bp-long terminal inverted repeats in the 5' and 3' boundaries (called LIR: long inverted repeat), with two 28-bp-long direct repeats in each LIR. All potentially active elements presented degeneration in the internal region of terminal inverted repeat. Despite the degeneration of the LIR, the distance of 185?bp between the direct repeats was always maintained. This conservation suggests that the spacing between direct repeats is important for transposase binding. The distribution analysis showed that these elements are widely distributed in other Drosophila groups beyond the virilis and repleta groups. The evolutionary analysis of Paris-like elements suggests that they were present as two subfamilies with the common ancestor of the Drosophila genus. Since then, these TEs have been primarily maintained by vertical transmission with some events of stochastic loss and horizontal transfer.     

Identification of Nucleotide Substitutions Necessary for Trans-Activation of Mariner Transposable Elements in Drosophila: Analysis of Naturally Occurring Elements

Six copies of the mariner element from the genomes of Drosophila mauritiana and Drosophila simulans were chosen at random for DNA sequencing and functional analysis and compared with the highly active element Mos1 and the inactive element peach. All elements were 1286 base pairs in length, but among them there were 18 nucleotide differences. As assayed in Drosophila melanogaster, three of the elements were apparently nonfunctional, two were marginally functional, and one had moderate activity that could be greatly increased depending on the position of the element in the genome. Both molecular (site-directed mutagenesis) and evolutionary (cladistic analysis) techniques were used to analyze the functional effects of nucleotide substitutions. The nucleotide sequence of the element is the primary determinant of function, though the activity level of elements is profoundly influenced by position effects. Cladistic analysis of the sequences has identified a T----A transversion at position 1203 (resulting in a Phe----Leu amino acid replacement in the putative transposase) as being primarily responsible for the low activity of the barely functional elements. Use of the sequences from the more distantly related species, Drosophila yakuba and Drosophila teissieri, as outside reference species, indicates that functional mariner elements are ancestral and argues against their origination by a novel mutation or by recombination among nonfunctional 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.     

DNA binding activities of the Caenorhabditis elegans Tc3 transposase.

Tc3 is a member of the Tc1/mariner family of transposable elements. All these elements have terminal inverted repeats, encode related transposases and insert exclusively into TA dinucleotides. We have studied the DNA binding properties of Tc3 transposase and found that an N-terminal domain of 65 amino acids binds specifically to two regions within the 462 bp Tc3 inverted repeat; one region is located at the end of the inverted repeat, the other is located approximately 180 bp from the end. Methylation interference experiments indicate that this N-terminal DNA binding domain of the Tc3 transposase interacts with nucleotides on one face of the DNA helix over adjacent major and minor grooves.     

Sequence Analysis of Active Mariner Elements in Natural Populations of Drosophila Simulans

Active and inactive mariner elements from natural and laboratory populations of Drosophila simulans were isolated and sequenced in order to assess their nucleotide variability and to compare them with previously isolated mariner elements from the sibling species Drosophila mauritiana and Drosophila sechellia. The active elements of D. simulans are very similar among themselves (average 99.7% nucleotide identity), suggesting that the level of mariner expression in different natural populations is largely determined by position effects, dosage effects and perhaps other factors. Furthermore, the D. simulans elements exhibit nucleotide identities of 98% or greater when compared with mariner elements from the sibling species. Parsimony analysis of mariner elements places active elements from the three species into separate groups and suggests that D. simulans is the species from which mariner elements in D. mauritiana and D. sechellia are most likely derived. This result strongly suggests that the ancestral form of mariner among these species was an active element. The two inactive mariner elements sequenced from D. simulans are very similar to the inactive peach element from D. mauritiana. The similarity may result from introgression between D. simulans and D. mauritiana or from selective constraints imposed by regulatory effects of inactive elements.     

Molecular characterization of a mariner-like element in the Atta sexdens rubropilosa genome

Mobile elements are widely present in eukaryotic genomes. They are repeated DNA segments that are able to move from one locus to another within the genome. They are divided into two main categories, depending on their mechanism of transposition, involving RNA (class I) or DNA (class II) molecules. The mariner-like elements are class II transposons. They encode their own transposase, which is necessary and sufficient for transposition in the absence of host factors. They are flanked by a short inverted terminal repeat and a TA dinucleotide target site, which is duplicated upon insertion. The transposase consists of two domains, an N-terminal inverted terminal repeat binding domain and a C-terminal catalytic domain. We identified a transposable element with molecular characteristics of a mariner-like element in Atta sexdens rubropilosa genome. Identification started from a PCR with degenerate primers and queen genomic DNA templates, with which it was possible to amplify a fragment with mariner transposable-element homology. Phylogenetic analysis demonstrated that this element belongs to the mauritiana subfamily of mariner-like elements and it was named Asmar1. We found that Asmar1 is homologous to a transposon described from another ant, Messor bouvieri. The predicted transposase sequence demonstrated that Asmar1 has a truncated transposase ORF. This study is part of a molecular characterization of mobile elements in the Atta spp genome. Our finding of mariner-like elements in all castes of this ant could be useful to help understand the dynamics of mariner-like element distribution in the Hymenoptera.     

Characterization of Soymar1, a mariner element in soybean.

Mariner elements, a family of DNA-mediated transposable elements with short, inverted terminal repeats, have been reported in a wide variety of arthropods, as well as planarians, nematodes, and humans. No such element has been reported in a plant. Here we report a mariner element in the plant soybean (Glycine max (L.) Merr.). Although this sequence belongs to the mariner family, it is clearly distinct from previously reported mariner-like elements, as well as from the Tc1 transposon family. Novel aspects of its sequence could be useful as a starting point to identify mariner-like elements in new organisms, and it may prove useful in creating a transformation vector for plants.     

Tc1 transposase of Caenorhabditis elegans is an endonuclease with a bipartite DNA binding domain.

The Tc1 transposon of Caenorhabditis elegans is a member of the Tc1/mariner family of mobile elements. These elements have inverted terminal repeats that flank a single transposase gene. Here we show that Tc1 transposase, Tc1A, has a bipartite DNA binding domain related to the paired domain of mammalian and Drosophila genes. Both the DNA binding domain of Tc1A and the DNA binding site in the inverted repeat of Tc1 can be divided into two subdomains. Methylation interference studies demonstrate adjacent minor and major groove contacts at the inner part of the binding site by the N-terminal 68 amino acids of the DNA binding domain. In addition, Tc1A amino acids 69-142 are essential for major groove contacts at the outer part of the binding site. Recombinant Tc1A is found to be able to introduce a single strand nick at the 5' end of the transposon in vitro. Furthermore, Tc1A can mediate a phosphoryl transfer reaction. A mutation in a DDE motif abolishes both endonucleolytic and phosphoryl transfer activities, suggesting that Tc1A carries a catalytic core common to retroviral integrases and IS transposases.