<Emphasis Type="Italic">Mariner</Emphasis>-like elements in <Emphasis Type="Italic">Rhynchosciara americana</Emphasis> (Sciaridae) genome: molecular and cytological aspects

Two mariner-like elements, Ramar1 and Ramar2, are described in the genome of Rhynchosciara americana, whose nucleotide consensus sequences were derived from multiple defective copies containing deletions, frame shifts and stop codons. Ramar1 contains several conserved amino acid blocks which were identified, including a specific D,D(34)D signature motif. Ramar2 is a defective mariner-like element, which contains a deletion overlapping in most of the internal region of the transposase ORF while its extremities remain intact. Predicted transposase sequences demonstrated that Ramar1 and Ramar2 phylogenetically present high identity to mariner-like elements of mauritiana subfamily. Southern blot analysis indicated that Ramar1 is widely represented in the genome of Rhynchosciara americana. In situ hybridizations showed Ramar1 localized in several chromosome regions, mainly in pericentromeric heterochromatin and their boundaries, while Ramar2 appeared as a single band in chromosome A.     

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.     

Identification of two mariner-like elements in the genome of the mosquito Ochlerotatus atropalpus

Two distinct mariner-like elements, Atmar-1 and Atmar-2, were isolated from the genome of the mosquito Ochlerotatus atropalpus. Full-sized Atmar-1 elements, obtained by screening a genomic library, have a 1293-bp consensus sequence with 27-bp inverted terminal repeats and a 1047-bp open reading frame (ORF) encoding the transposase. The Atmar-2 elements were amplified by polymerase chain reaction from genomic DNA and contain the central part of the transposase ORF. Individual clones of both mariner elements contain deletions, frameshifts, and stop codons. The Atmar-1 elements are present in 370-1200 copies, while the Atmar-2 elements are present in approximately 100-300 copies per haploid genome. One of the Atmar-1 elements, Atmar-1.33, could be mobilized, suggesting the presence of functional Atmar-1 elements elsewhere in the genome. Phylogenetic analysis demonstrated that Atmar-1 elements belong to the irritans subfamily and Atmar-2 elements to the cecropia subfamily of mariner elements.     

Molecular characterization of Vulmar1, a complete mariner transposon of sugar beet and diversity of mariner- and En/Spm-like sequences in the genus Beta.

Transposons of the Tc1-mariner superfamily are widespread in eukaryotic genomes. We have isolated the mariner element Vulmar1 from Beta vulgaris L., which is 3909 bp long and bordered by perfect terminal inverted repeats of 32 bp with homology to terminal inverted repeats of transposons from soybean and rice. According to a characteristic amino acid signature, Vulmar1 can be assigned to the DD39D group of mariner transposons. Vulmar1 is flanked by a 5'-TA-3' target site duplication that is typical for mariner transposons. Southern hybridization revealed that mariner-like copies are highly abundant in Beta species, and sequence analysis of 10 transposase fragments from representative species of the four Beta sections revealed an identity between 34% and 100% after conceptual translation. By fluorescent in situ hybridization, Vulmar1 was detected in distal euchromatin as well as in some intercalary and pericentromeric regions of all B. vulgaris chromosomes. In addition, using PCR, we were able to amplify fragments of the transposase gene of En/Spm-like transposons in the genus Beta. En/Spm-like transposase sequences are highly amplified in four Beta sections and showed a considerable degree of conservation (88.5-100%) at the protein level, while the homology to corresponding regions of En/Spm transposons of other plant species ranges from 49.5% to 62.5%. By fluorescent in situ hybridization, En/Spm-like transposon signals of strong intensity were detected on all chromosomes of B. vulgaris.     

Phylogenetic analysis of the functional domains of mariner-like element (MLE) transposases

We have analyzed the sequences of mariner-like element (MLE) transposases, in order to obtain a clearer picture of their phylogenetic relationships. In particular, we have considered their two known structural domains, as well as the nucleic acid sequences of the MLE inverted terminal repeats (ITR). The most consistent tree was obtained using sequences of the catalytic domain of the transposase. The trees obtained with the amino acid sequences of the ITR-binding domain and the ITR sequences themselves were similar to that obtained with the catalytic domain. However, a major difference indicated that the cecropia sub-family is divided into two sub-groups. These new trees were used to examine the evolutionary divergence of mariner-like transposable elements, with particular reference to the possibility that recombination events or gene conversions created mosaic elements during the evolution of transposons.     

Reduced Germline Mobility of a Mariner Vector Containing Exogenous DNA: Effect of Size or Site?

Germline mobilization of the transposable element mariner is severely inhibited by the insertion of a 4.5- to 11.9-kb fragment of exogenous DNA into a unique SacI site approximately in the middle of the 1286-bp element. In the presence of transposase driven by the germline-specific hsp26-sgs3 promoter, mobilization of the MlwB construct (containing a 11.9-kb insertion) is detected at low frequency. Analysis of a mobilized MlwB element indicated that mobilization is mediated by the mariner transposase. However, transposed MlwB elements are also defective in germline mobilization. Rare, transposase-induced germ-line excision events were also recovered for such vectors. The estimated rate of excision is <0.1% per chromosome per generation. Excision appears to be accompanied by gap repair if a suitable template is available. The data imply that the reduced mobility of mariner vectors with exogenous DNA in the SacI site results from disruption of sequences necessary for efficient mobilization. The relative stability may be a valuable property in the uses of mariner-like elements in genetic engineering of insects of economic importance.     

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.     

High copy number of highly similar mariner-like transposons in planarian (Platyhelminthe): evidence for a trans-phyla horizontal transfer

Several DNA sequences similar to the mariner element were isolated and characterized in the platyhelminthe Dugesia (Girardia) tigrina. They were 1,288 bp long, flanked by two 32 bp-inverted repeats, and contained a single 339 amino acid open-reading frame (ORF) encoding the transposase. The number of copies of this element is approximately 8,000 per haploid genome, constituting a member of the middle- repetitive DNA of Dugesia tigrina. Sequence analysis of several elements showed a high percentage of conservation between the different copies. Most of them presented an intact ORF and the standard signals of actively expressed genes, which suggests that some of them are or have recently been functional transposons. The high degree of similarity shared with other mariner elements from some arthropods, together with the fact that this element is undetectable in other planarian species, strongly suggests a case of horizontal transfer between these two distant phyla.      

A New Basal Subfamily of mariner Elements in Ceratitis rosa and Other Tephritid Flies

Several copies of highly related transposable elements, Crmar2, Almar1, and Asmar1, are described from the genomes of Ceratitis rosa, Anastrepha ludens, and A. suspensa, respectively. One copy from C. rosa, Crmar2.5, contains a full-length, uninterrupted ORF. All the other copies, from the three species contain a long deletion within the putative ORF. The consensus Crmar2 element has features typical of the mariner/Tc1 superfamily of transposable elements. In particular, the Crmar2 consensus encodes a D,D41D motif, a variant of the D,D34D catalytic domain of mariner elements. Phylogenetic analysis of the relationships of these three elements and other members of the mariner/Tc1 superfamily, based on their encoded amino acid sequences, suggests that they form a new basal subfamily of mariner elements, the rosa subfamily. BLAST analyses identified sequences from other diptera, including Drosophila melanogaster, which appear to be members of the rosa subfamily of mariner elements. Analyses of their molecular evolution suggests that Crmar2 entered the genome of C. rosa in the recent past, a consequence of horizontal transfer.     

Cloning and characterization of mariner-like elements in the soybean aphid, Aphis glycines Matsumura

Soybean aphid, Aphis glycines Matsumura (Hemiptera: Aphididae), is currently the most important insect pest of soybean (Glycine max (L.) Merr.) in the United States and causes significant economic damage worldwide, but little is known about the aphid at the molecular level. Mariner-like transposable elements (MLEs) are ubiquitous within the genomes of arthropods and various other invertebrates. In this study, we report the cloning of MLEs from the soybean aphid genome using degenerate PCR primers designed to amplify conserved regions of mariner transposases. Two of the ten sequenced clones (designated as Agmar1 and Agmar2) contained partial but continuous open reading frames, which shared high levels of homology at the protein level with other mariner transposases from insects and other taxa. Phylogenetic analysis revealed Agmar1 to group within the irritans subfamily of MLEs and Agmar2 within the mellifera subfamily. Southern blot analysis and quantitative PCR analysis indicated a low copy number for Agmar1-like elements within the soybean aphid genome. These results suggest the presence of at least two different putative mariner-like transposases encoded by the soybean aphid genome. Both Agmar1 and Agmar2 could play influential roles in the architecture of the soybean aphid genome. Transposable elements are also thought to potentially mediate resistance in insects through changes in gene amplification and mutations in coding sequences. Finally, Agmar1 and Agmar2 may represent useful genetic tools and provide insights on A. glycines adaptation.     

Molecular characterization of mariner‐like elements in emerald ash borer,Agrilus planipennis (Coleoptera,Polyphaga)

Emerald ash borer (EAB, Agrilus planipennis), an exotic invasive pest, has killed millions of ash trees (Fraxinus spp.) in North America and continues to threaten the very survival of the entire Fraxinus genus. Despite its high‐impact status, to date very little knowledge exists for this devastating insect pest at the molecular level. Mariner‐like elements (MLEs) are transposable elements, which are ubiquitous in occurrence in insects and other invertebrates. Because of their low specificity and broad host range, they can be used for epitope‐tagging, gene mapping, and in vitro mutagenesis. The majority of the known MLEs are inactive due to in‐frame shifts and stop codons within the open reading frame (ORF). We report on the cloning and characterization of two MLEs in A. planipennis genome (Apmar1 and Apmar2). Southern analysis indicated a very high copy number for Apmar1 and a moderate copy number for Apmar2. Phylogenetic analysis revealed that both elements belong to the irritans subfamily. Based on the high copy number for Apmar1, the full‐length sequence was obtained using degenerate primers designed to the inverted terminal repeat (ITR) sequences of irritans MLEs. The recovered nucleotide sequence for Apmar1 consisted of 1,292 bases with perfect ITRs, and an ORF of 1,050 bases encoding a putative transposase of 349 amino acids. The deduced amino acid sequence of Apmar1 contained the conserved regions of mariner transposases including WVPHEL and YSPDLAP, and the D,D(34)D motif. Both Apmar1 and Apmar2 could represent useful genetic tools and provide insights on EAB adaptation. © 2010 Wiley Periodicals, Inc.     

maT--a clade of transposons intermediate between mariner and Tc1

A group of transposons, named maT, with characteristics intermediate between mariner and Tc1 transposons, is described. Two defective genomic copies of MdmaT from the housefly Musca domestica, with 85% identity, were found flanking and imbedded in the MdalphaE7 esterase gene involved in organophosphate insecticide resistance. Two cDNA clones, with 99% identity to each other and 72%-89% identity to the genomic copies were also obtained, but both represented truncated versions of the putative open reading frame. A third incomplete genomic copy of MdmaT was also identified upstream of the putative M. domestica period gene. The MdmaT sequences showed high identity to the transposable element Bmmar1 from the silkworm moth, Bombyx mori, and to previously unidentified sequences in the genome of Caenorhabditis elegans. A total of 16 copies of full-length maT sequences were identified in the C. elegans genome, representing three variants of the transposon, with 34%-100% identity amongst them. Twelve of the copies, named CemaT1, were virtually identical, with eight of them encoding a putative full length, intact transposase. Secondary structure predictions and phylogenetic analyses confirm that maT elements belong to the mariner-Tc1 superfamily of transposons, but their intermediate sequence and predicted structural characteristics suggest that they belong to a unique clade, distinct from either mariner-like or Tc1-like elements.     

A highly repetitive, mariner-like element in the genome of Hyalophora cecropia.

A highly repetitive DNA element, homologous to the mariner transposon of Drosophila mauritiana was found in the intron of the gene for cecropin A, an antibacterial peptide from the Cecropia moth. The mariner-like elements (MLE) represent a homogeneous population with a copy number of about 1000/genome. Sequencing analysis showed it to be 1255 base pairs long, including 38-base pair terminal inverted repeats. The MLE contains a defective reading frame. Nevertheless, the putative product is clearly homologous to the predicted translation product encoded by mariner. In consonance is also the fact that the inverted repeats are highly conserved between the two elements and that the overall DNA homology is 48%. Since the mariner element is present in several Drosophila species closely related to Drosophila melanogaster and since MLE is present in the lepidopteran Cecropia, a route of horizontal transfer is indicated rather than vertical transmission from a common ancestor. This suggests the possible use of mariner for the construction of an interspecies vector.     

Mariner Mos1 transposase dimerizes prior to ITR binding

The mariner Mos1 synaptic complex consists of a tetramer of transposase molecules that bring together the two ends of the element. Such an assembly requires at least two kinds of protein-protein interfaces. The first is involved in "cis" dimerization, and consists of transposase molecules bound side-by-side on a single DNA molecule. The second, which is involved in "trans" dimerization, consists of transposase molecules bound to two different DNA molecules. Here, we used biochemical and genetic methods to enhance the definition of the regions involved in cis and trans-dimerization in the mariner Mos1 transposase. The cis and trans-dimerization interfaces were both found within the first 143 amino acid residues of the protein. The cis-dimerization activity was mainly contained in amino acids 1-20. The region spanning from amino acid residues 116-143, and containing the WVPHEL motif, was involved in the cis- to trans-shift as well as in trans-dimerization stabilization. Although the transposase exists mainly as a monomer in solution, we provide evidence that the transposase cis-dimer is the active species in inverted terminal repeat (ITR) binding. We also observed that the catalytic domain of the mariner Mos1 transposase modulates efficient transposase-transposase interactions in the absence of the transposon ends.     

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.     

Loss of transposase-DNA interaction may underlie the divergence of mariner family transposable elements and the ability of more than one mariner to occupy the same genome

Mariners are a large family of eukaryotic DNA-mediated transposable elements that move via a cut-and-paste mechanism. Several features of the evolutionary history of mariners are unusual. First, they appear to undergo horizontal transfer commonly between species on an evolutionary timescale. They can do this because they are able to transpose using only their own self-encoded transposase and not host-specific factors. One consequence of this phenomenon is that more than one kind of mariner can be present in the same genome. We hypothesized that two mariners occupying the same genome would not interact. We tested the limits of mariner interactions using an in vitro transposition system, purified mariner transposases, and DNAse I footprinting. Only mariner elements that were very closely related to each other (ca. 84% identity) cross-mobilized, and then inefficiently. Because of the dramatic suppression of transposition between closely related elements, we propose that to isolate elements functionally, only minor changes might be necessary between elements, in both inverted terminal repeat and amino acid sequence. We further propose a mechanism to explain mariner diversification based on this phenomenon.     

A comparative phylogenetic analysis of full-length<Emphasis Type="Italic">mariner</Emphasis> elements isolated from the Indian tasar silkmoth,<Emphasis Type="Italic">Antheraea mylitta</Emphasis> (Lepidoptera: saturniidae)

Mariner like elements (MLEs) are widely distributed type II transposons with an open reading frame (ORF) for transposase. We studied comparative phylogenetic evolution and inverted terminal repeat (ITR) conservation of MLEs from Indian saturniid silkmoth,Antheraea mylitta with other full length MLEs submitted in the database. Full length elements fromA. mylitta were inactive with multiple mutations. Many conserved amino acid blocks were identified after aligning transposase sequences. Mariner signature sequence, DD(34)D was almost invariable although a few new class of elements had different signatures.A. mylitta MLEs(Anmmar) get phylogenetically classified under cecropia subfamily and cluster closely with the elements from other Bombycoidea superfamily members implying vertical transmission from a common ancestor. ITR analysis showed a conserved sequence of AGGT(2-8N)ATAAGT for forward repeat and AGGT(2-8N)ATGAAAT for reverse repeat. These results and additional work may help us to understand the dynamics of MLE distribution inA. mylitta and construction of appropriate vectors for mariner mediated transgenics.     

Mariner-like sequences are present in the genome of the fruitfly,Drosophila melanogaster

No mariner-like elements (MLEs) have been described until now in the genome of Drosophila melanogaster despite many experiments using molecular methods. However, analyses of sequence data from the Berkeley Drosophila Genome Project show that there are DNA sequences corresponding to pieces of MLE in the genome of D. melanogaster. The sequences of these elements have diverged considerably (about 40%) from any other sequences observed elsewhere. Moreover, the putative amino acid sequences encoded by the best conserved regions reveal that these sequences are clearly homologous to MLEs transposase.     

Molecular and Functional Analysis of the Mariner Mutator Element Mos1 in Drosophila

The white-peach allele in Drosophila results from insertion of the transposable element mariner. The particular copy that is inserted in white-peach is an inactive copy referred to as the peach element. The peach element is excised at a high rate in the presence of active copies of mariner located elsewhere in the genome, and the excision of peach in somatic cells is recognized phenotypically by the occurrence of eye-color mosaicism in white-peach flies. Active mariner elements identified by their ability to induce high levels of white-peach mosaicism are denoted Mos (Mosaic) factors. We have sequenced and functionally analyzed the factor Mos1 originally identified in Drosophila mauritiana. The Mos1 element is 1286 base pairs in length, the same length as the peach element. It differs from the peach element in 11 nucleotide positions distributed throughout its length, including four amino acid replacements in the long open reading frame. Analysis of chimeric constructs between Mos1 and peach implies that functionally important differences occur in both the 5' and 3' halves of Mos1. A mariner element identical in sequence to Mos1 yields lower levels of mosaicism in transformants, implying that adjacent flanking sequences have important effects on Mos1 activity. Another mariner element, designated Ma351, isolated from a nonmosaic strain of D. mauritiana, differs from Mos1 in just three nucleotide positions. When introduced into the germline, Ma351 yields various levels of white-peach mosaicism depending on insertion site. These results imply that the activity of mariner elements is determined jointly by their own nucleotide sequences, by the effects of adjacent flanking sequences, and by longer-range position effects.     

A potentially functional mariner transposable element in the protist Trichomonas vaginalis

Mariner transposable elements encoding a D,D34D motif-bearing transposase are characterized by their pervasiveness among, and exclusivity to, animal phyla. To date, several hundred sequences have been obtained from taxa ranging from cnidarians to humans, only two of which are known to be functional. Related transposons have been identified in plants and fungi, but their absence among protists is noticeable. Here, we identify and characterize Tvmar1, the first representative of the mariner family to be found in a species of protist, the human parasite Trichomonas vaginalis. This is the first D,D34D element to be found outside the animal kingdom, and its inclusion in the mariner family is supported by both structural and phylogenetic analyses. Remarkably, Tvmar1 has all the hallmarks of a functional element and has recently expanded to several hundred copies in the genome of T. vaginalis. Our results show that a new potentially active mariner has been found that belongs to a distinct mariner lineage and has successfully invaded a nonanimal, single-celled organism. The considerable genetic distance between Tvmar1 and other mariners may have valuable implications for the design of new, high-efficiency vectors to be used in transfection studies in protists.