Sequence identity between an inverted repeat family of transposable elements in Drosophila and Caenorhabditis

Identification of kit-ligand a as the Gene Responsible for the Medaka Pigment Cell Mutant few melanophore

The body coloration of animals is due to pigment cells derived from neural crest cells, which are multipotent and differentiate into diverse cell types. Medaka (Oryzias latipes) possesses four distinct types of pigment cells known as melanophores, xanthophores, iridophores, and leucophores. The few melanophore (fm) mutant of medaka is characterized by reduced numbers of melanophores and leucophores. We here identify kit-ligand a (kitlga) as the gene whose mutation gives rise to the fm phenotype. This identification was confirmed by generation of kitlga knockout medaka and the findings that these fish also manifest reduced numbers of melanophores and leucophores and fail to rescue the fm mutant phenotype. We also found that expression of sox5, pax7a, pax3a, and mitfa genes is down-regulated in both fm and kitlga knockout medaka, implicating c-Kit signaling in regulation of the expression of these genes as well as the encoded transcription factors in pigment cell specification. Our results may provide insight into the pathogenesis of c-Kit-related pigmentation disorders such as piebaldism in humans, and our kitlga knockout medaka may prove useful as a tool for drug screening.

Complete gene sequence of spider attachment silk protein (PySp1) reveals novel linker regions and extreme repeat homogenization

Spiders use a myriad of silk types for daily survival, and each silk type has a unique suite of task-specific mechanical properties. Of all spider silk types, pyriform silk is distinct because it is a combination of a dry protein fiber and wet glue. Pyriform silk fibers are coated with wet cement and extruded into "attachment discs" that adhere silks to each other and to substrates. The mechanical properties of spider silk types are linked to the primary and higher-level structures of spider silk proteins (spidroins). Spidroins are often enormous molecules (>250 kDa) and have a lengthy repetitive region that is flanked by relatively short (∼100 amino acids), non-repetitive amino- and carboxyl-terminal regions. The amino acid sequence motifs in the repetitive region vary greatly between spidroin type, while motif length and number underlie the remarkable mechanical properties of spider silk fibers. Existing knowledge of pyriform spidroins is fragmented, making it difficult to define links between the structure and function of pyriform spidroins. Here, we present the full-length sequence of the gene encoding pyriform spidroin 1 (PySp1) from the silver garden spider Argiope argentata. The predicted protein is similar to previously reported PySp1 sequences but the A. argentata PySp1 has a uniquely long and repetitive "linker", which bridges the amino-terminal and repetitive regions. Predictions of the hydrophobicity and secondary structure of A. argentata PySp1 identify regions important to protein self-assembly. Analysis of the full complement of A. argentata PySp1 repeats reveals extreme intragenic homogenization, and comparison of A. argentata PySp1 repeats with other PySp1 sequences identifies variability in two sub-repetitive expansion regions. Overall, the full-length A. argentata PySp1 sequence provides new evidence for understanding how pyriform spidroins contribute to the properties of pyriform silk fibers.

The Caenorhabditis briggsae genome contains active CbmaT1 and Tcb1 transposons

The maT clade of transposons is a group of transposable elements intermediate in sequence and predicted protein structure to mariner and Tc transposons, with a distribution thus far limited to a few invertebrate species. We present evidence, based on searches of publicly available databases, that the nematode Caenorhabditis briggsae has several maT-like transposons, which we have designated as CbmaT elements, dispersed throughout its genome. We also describe two additional transposon sequences that probably share their evolutionary history with the CbmaT transposons. One resembles a fold back variant of a CbmaT element, with long (380-bp) inverted terminal repeats (ITRs) that show a high degree (71%) of identity to CbmaT1. The other, which shares only the 26-bp ITR sequences with one of the CbmaT variants, is present in eight nearly identical copies, but does not have a transposase gene and may therefore be cross mobilised by a CbmaT transposase. Using PCR-based mobility assays, we show that CbmaT1 transposons are capable of excising from the C. briggsae genome. CbmaT1 excised approximately 500 times less frequently than Tcb1 in the reference strain AF16, but both CbmaT1 and Tcb1 excised at extremely high frequencies in the HK105 strain. The HK105 strain also exhibited a high frequency of spontaneous induction of unc-22 mutants, suggesting that it may be a mutator strain of C. briggsae.

Phylogenetic analysis reveals stowaway-like elements may represent a fourth family of the IS630-Tc1-mariner superfamily

The genomes of plants, like virtually all other eukaryotic organisms, harbor a diverse array of mobile elements, or transposons. In terms of numbers, the predominant type of transposons in many plants is the miniature inverted-repeat transposable element (MITE). There are three archetypal MITEs, known as Tourist, Stowaway, and Emigrant, each of which can be defined by a specific terminal inverted-repeat (TIR) sequence signature. Although their presence was known for over a decade, only recently have open reading frames (ORFs) been identified that correspond to putative transposases for each of the archetypes. We have identified two Stowaway elements that encode a putative transposase and are similar to members of the previously characterized IS630-Tc1-mariner superfamily. In this report, we provide a high-resolution phylogenetic analysis of the evolutionary relationship between Stowaway, Emigrant, and members of the IS630-Tc1-mariner superfamily. We show that although Emigrant is closely related to the pogo-like family of elements, Stowaway may represent a novel family. Integration of our results with previously published data leads to the conclusion that the three main types of MITEs have different evolutionary histories despite similarity in structure.

Patterns of genetic variation at a chromosome 4 locus of Drosophila melanogaster and D. simulans

DNA sequence surveys of Drosophila melanogaster populations show a strong positive correlation between the recombination rate experienced by a locus and its level of nucleotide polymorphism. In particular, surveys of the fourth chromosome gene ci(D) show greatly reduced levels of nucleotide variation; this observation was originally interpreted in terms of selective sweeps occurring on the nonrecombining fourth chromosome. Subsequent theoretical work has, however, uncovered several other selective processes that can reduce variation. In this study, we revisit the Drosophila fourth chromosome, investigating variation in 5-6 kb of the gene ankyrin in D. melanogaster and D. simulans. Silent nucleotide site diversity is approximately 5 x 10(-4) for both species, consistent with the previous observations of low variation at ci(D). Given the observed frequency spectra at ankyrin, coalescent simulations indicate that reduced diversity in the region is unlikely to be due to a selective sweep alone. We find evidence for recombinational exchange at this locus, and both species appear to be fixed for an insertion of the transposable element HB in an intron of ankyrin.

Transposable elements and gene transformation in non-drosophilid insects

This review summarizes recent data on the development of non-drosophilid insect transformation systems. The discussion focuses on one particular approach to developing transformation systems that relies on the use of short inverted repeat-type transposable elements analogous to that employed for Drosophila melanogaster transformation. Representatives from four families of short inverted repeat-type transposable elements have been shown to either act as non-drosophilid gene vectors or to have the ability to transpose accurately when introduced into non-host insect cells. Minos, a member of the Tcl family of elements isolated originally from D. hydei has been successfully used as a germline transformation vector in the Medfly, Ceratitis capitata. Hermes, a member of the hAT family of elements isolated originally from Musca domestica has been successfully used as a gene transformation vector in D. melanogaster and has a host range that appears to include culicids. hobo, another member of the hAT family of elements isolated from D. melanogaster also has a broad host range that includes tephritid fruitflies. mariner(Mos), a member of the mariner family of elements isolated from D. mauritiana can transpose in calliphorids. Finally, piggyBac/IFP2, a member of the TTAA-specific family of elements isolated from Trichoplusia ni can transpose when introduced into Spodoptera frugiperda cells. Although routine transformation of insects other than D. melanogaster is not possible it is clear that the raw materials for the development of efficient transformation systems are now available.

Characterization of Gandalf, a new inverted-repeat transposable element of Drosophila koepferae

The cloning and characterization of Gandalf, a new DNA-transposing mobile element obtained from the Drosophila koepferae (repleta group) genome is described. A fragment of Gandalf was found in a middle repetitive clone that shows variable chromosomal localization. Restriction, Southern blot, PCR and sequencing analyses have shown that most Gandalf copies are about 1 kb long, are flanked by 12 bp inverted terminal repeats and contain subterminal repetitive regions on both sides of the element. As with other elements of the DNA-transposing type (known as the 'Ac family'), the Gandalf element generates 8 bp direct duplications at the insertion point. Coding region analysis has shown that the longer open reading frame found in Gandalf copies could encode part of a protein. However, whether or not the 1 kb copies of the element are actually the active transposons remains to be elucidated. Gandalf shows a very low copy number in D. buzzatii, a sibling species of D. koepferae. An attempt to induce interspecific hybrid dysgenesis in hybrids of these two species has been unsuccessful.

Characterization of a Tc1-like transposable element in zebrafish (Danio rerio)

We have characterized Tdr1, a family of Tc1-like transposable elements found in the genome of zebrafish (Danio rerio). The copy number and distribution of the sequence in the zebrafish genome have been determined, and by these criteria Tdr1 can be classified as a moderately repetitive, interspersed element. Examination of the sequences and structures of several copies of Tdr1 revealed that a particular deletion derivative, 1250 bp long, of the transposon has been amplified to become the dominant form of Tdr1. The deletion in these elements encompasses sequences encoding the N-terminal portion of the putative Tdr1 transposase. Sequences corresponding to the deleted region were also detected, and thus allowed prediction of the nucleotide sequence of a hypothetical full-length element. Well conserved segments of Tc1-like transposons were found in the flanking regions of known fish genes, suggesting that these elements have a long evolutionary history in piscine genomes. Tdr1 elements have long, 208 bp inverted repeats, with a short DNA motif repeated four times at the termini of the inverted repeats. Although different from that of the prototype C. elegans transposon Tc1, this inverted repeat structure is shared by transposable elements from salmonid fish species and two Drosophila species. We propose that these transposons form a subgroup within the Tc1-like family. Comparison of Tc1-like transposons supports the hypothesis that the transposase genes and their flanking sequences have been shaped by independent evolutionary constraints. Although Tc1-like sequences are present in the genomes of several strains of zebrafish and in salmonid fishes, these sequences are not conserved in the genus Danio, thus raising the possibility that these elements can be exploited for gene tagging and genome mapping.

The transposable element impala, a fungal member of the Tc1-mariner superfamily

A new transposable element has been isolated from an unstable niaD mutant of the fungus Fusarium oxysporum. This element, called impala, is 1280 nucleotides long and has inverted repeats of 27 bp. Impala inserts into a TA site and leaves behind a "foot-print" when it excises. The inserted element, impala-160, is cis-active, but is probably trans-defective owing to several stop codons and frameshifts. Similarities exist between the inverted repeats of impala and those of transposons belonging to the widely dispersed mariner and Tc1 families. Moreover, translation of the open reading frame revealed three regions showing high similarities with Tc1 from Caenorhabditis elegans and with the mariner element of Drosophila mauritiana. The overall comparison shows that impala occupies an intermediate position between the mariner and Tc1-like elements, suggesting that all these elements belong to the same superfamily. The degree of relatedness observed between these elements, described in different kingdoms, raises the question of their origin and evolution.

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.

Pot2, an inverted repeat transposon from the rice blast fungus Magnaporthe grisea

We report the cloning and characterisation of Pot2, a putative transposable element from Magnaporthe grisea. The element is 1857 bp in size, has 43-bp perfect terminal inverted repeats (TIRs) and 16-bp direct repeats within the TIRs. A large open reading frame, potentially coding for a transposase-like protein, was identified. This putative protein coding region showed extensive identity to that of Fot1, a transposable element from another phytopathogenic fungus, Fusarium oxysporum. Pot2, like the transposable elements Tc1 and Mariner of Caenorhabditis elegans and Drosophila, respectively, duplicates the dinucleotide TA at the target insertion site. Sequence analysis of DNA flanking 12 Pot2 elements revealed similarity to the consensus insertion sequence of Tc1. Pot2 is present at a copy number of approximately 100 per haploid genome and represents one of the major repetitive DNAs shared by both rice and non-rice pathogens of M. grisea.

The Tc5 family of transposable elements in Caenorhabditis elegans

We have identified Tc5, a new family of transposable genetic elements in the nematode Caenorhabditis elegans. All wild-type varieties of C. elegans that we examined contain 4-6 copies of Tc5 per haploid genome, but we did not observe transposition or excision of Tc5 in these strains. Tc5 is active, however, in the mut-2 mutant strain TR679. Of 60 spontaneous unc-22 mutations isolated from strain TR679, three were caused by insertion of Tc5. All three Tc5-induced mutations are unstable; revertants results from precise or nearly precise excision of Tc5. Individual Tc5 elements are similar to each other in size and structure. The 3.2-kb element is bounded by inverted terminal repeats of nearly 500 bp. Eight of the ten terminal nucleotides of Tc5 are identical to the corresponding nucleotides of Tc4. Further, both elements recognize the same target site for insertion (CTNAG) and both cause duplication of the central TNA trinucleotide upon insertion. Other than these similarities to Tc4, Tc5 is unrelated to the three other transposon families (Tc1, Tc3 and Tc4) that transpose and excise at high frequency in mut-2 mutant strains. Mechanisms are discussed by which four apparently unrelated transposon families are all affected by the same mut-2 mutation.

Mobile Minos elements from Drosophila hydei encode a two-exon transposase with similarity to the paired DNA-binding domain

Elements related to the Tc1-like Minos mobile element have been cloned from Drosophila hydei and sequenced. Southern blot and sequence analyses show that (i) the elements are actively transposing in the Drosophila hydei germ line, (ii) they are characterized by a striking degree of sequence and size homogeneity, and (iii) like Tc1, they insert at a TA dinucleotide that is probably duplicated during the process. The nucleotide sequences of two elements, Minos-2 and Minos-3, differ at only one position from each other and contain two nonoverlapping open reading frames that are separated by a putative 60-nucleotide intron. The amino-terminal part of the Minos putative transposase shows sequence similarity to the paired DNA-binding domain. Forced transcription of a modified Minos element that was introduced into the Drosophila melanogaster germ line by P element-mediated transformation resulted in the production of accurately spliced polyadenylylated RNA molecules. It is proposed that Minos-2 and/or Minos-3 may encode an active transposase containing an amino-terminal DNA-binding domain that is distantly related to the paired DNA-binding domain.

Identification of a mariner-like repetitive sequence in C. elegans

A repetitive element in C.elegans has been found that bears high homology to the element mariner of Drosophila mauritiana (EMBL accession number X77804). This element is present in about 20 copies in the N2 strain of C.elegans, and appears in roughly equal copy numbers in the related strain BO and in the hybrid strains RW7097 and TR679. There is only one copy of this MLE in three related species of Caenorhabditis. A cDNA of this mariner-like element (MLE) codes for a protein with 58% homology to the Drosophila transposase. The mariner-like element is not mobile in N2. This class of elements has now been described in insects, planaria and nematodes (GenBank accession number M98552 and this report).

Target site choice of the related transposable elements Tc1 and Tc3 of Caenorhabditis elegans

We have investigated the target choice of the related transposable elements Tc1 and Tc3 of the nematode C. elegans. The exact locations of 204 independent Tc1 insertions and 166 Tc3 insertions in an 1 kbp region of the genome were determined. There was no phenotypic selection for the insertions. All insertions were into the sequence TA. Both elements have a strong preference for certain positions in the 1 kbp region. Hot sites for integration are not clustered or regularly spaced. The orientation of the integrated transposon has no effect on the distribution pattern. We tested several explanations for the target site preference. If simple structural features of the DNA (e.g. bends) would mark hot sites, we would expect the patterns of the two related transposons Tc1 and Tc3 to be similar; however we found them to be completely different. Furthermore we found that the sequence at the donor site has no effect on the choice of the new insertion site, because the insertion pattern of a transposon that jumps from a transgenic donor site is identical to the insertion pattern of transposons jumping from endogenous genomic donor sites. The most likely explanation for the target choice is therefore that the primary sequence of the target site is recognized by the transposase. However, alignment of the Tc1 and Tc3 integration sites does not reveal a strong consensus sequence for either transposon.

A proposed superfamily of transposase genes: transposon-like elements in ciliated protozoa and a common "D35E" motif

The transposon-like elements TBE1, Tec1, and Tec2 of hypotrichous ciliated protozoa appear to encode a protein that belongs to the IS630-Tc1 family of transposases. The Anabaena IS895 transposase also is placed in this family. We note that most family members transpose into the dinucleotide target, TA, and that members with eukaryotic hosts have a tendency for somatic excision that is carried to an extreme by the ciliate elements. Alignments including the additional members, and also mariner elements, show that transposases of this family share strongly conserved residues in a large C-terminal portion, including a fully conserved dipeptide, Asp-Glu (DE), and a block consisting of a fully conserved Asp and highly conserved Glu, separated by 34 or 35 residues (D35E). This D35E motif likely is homologous to the previously characterized D35E motif of the family of retroviral-retrotransposon integrases and IS3-like transposases. Because it is known that the IS3-retroposon D35E region is a critical portion of a domain capable of various in vitro transposition-related reactions, the results suggest that the two families share homologous catalytic transposase domains and that members of both families may share a common transposition mechanism.

Horizontal transmission versus ancient origin: mariner in the witness box

The transposable element mariner has been found in many species of Drosophilidae, several groups of Arthropods, and more recently in Platyhelminthes as well as in a phytopathogenic fungus. In the family Drosophilidae, the distribution of mariner among species shows many gaps, and its geographical distribution among endemic species is restricted to Asia and Africa. Among mariner elements in species within and outside the Drosophilidae, the similarities in nucleotide sequence and the amino acid sequence of the putative transposase reveal many phylogenetic inconsistencies compared with the conventional phylogeny of the host species. This paper discusses the contrasting hypotheses of horizontal transfer versus ancestral origin proposed to explain these results.

Evolution and consequences of transposable elements

Recent studies on transposable elements (TEs) have shed light on the mechanisms that have shaped their evolution. In addition to accumulating nucleotide substitutions over evolutionary time, TEs appear to be especially prone to genetic rearrangements and vertical transmissions across even distantly related species. As a consequence of replicating in host genomes, TEs have a significant mutational effect on their hosts. Although most TE-insertion mutations seem to exert a negative effect on host fitness, a growing body of evidence indicates that some TE-mediated genetic changes have become established features of host species genomes indicating that TEs can contribute significantly to organismic evolution.

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.

Evidence suggesting an evolutionary relationship between transposable elements and immune system recombination sequences

Sequence similarity between the termini of invertebrate Tcl-like transposable sequences and the signal sequences of the vertebrate immunoglobulin somatic recombination pathway is described. These similarities suggest that the Tcl transposition pathway may share common sequence-specific binding factors with the immunoglobulin somatic recombination pathway.

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

We have analyzed the sequence of the Tc2 transposon of the nematode Caenorhabditis elegans. The Tc2 element is 2,074 bp in length and has perfect inverted terminal repeats of 24 bp. The structure of this element suggests that it may have the capacity to code for a transposase protein and/or for regulatory functions. Three large reading frames on one strand exhibit nonrandom codon usage and may represent exons. The first open coding region is preceded by a potential CAAT box, TATA box, and consensus heat shock sequence. In addition to its inverted terminal repeats, Tc2 has an unusual structural feature: subterminal degenerate direct repeats that are arranged in an irregular overlapping pattern. We have also examined the insertion sites of two Tc2 elements previously identified as the cause of restriction fragment length polymorphisms. Both insertions generated a target site duplication of 2 bp. One element had inserted inside the inverted terminal repeat of another transposon, splitting it into two unequal parts.

Fot1, a new family of fungal transposable elements

We report here the discovery of a family of transposable elements, which we refer to as Fot1 elements, in the fungal plant pathogen Fusarium oxysporum. The first element was identified as an insertion in the gene encoding nitrate reductase. It is 1928 bp long, has 44 bp inverted terminal repeats, contains a large open reading frame and is flanked by a 2 bp (TA) target site duplication. This element shares significant structural similarities with a class of transposons that includes Tc1 from Caenorhabditis elegans and therefore represents a new class of transposable elements in fungi.

Horizontal transfer of P elements and other short inverted repeat transposons

Evidence for horizontal transfer of the P family of transposable elements in the genus Drosophila is reviewed and evaluated, along with observations consistent with the recent invasion of Drosophila melanogaster by these elements. Some other examples of horizontal transfer involving other groups of transposable elements having short inverted terminal repeats are also briefly described. The sequential mechanistic steps likely to be involved in a horizontal transfer event are explored, including the requirement for suitable interspecific vectors or carriers. Finally, the frequency and significance of horizontal transfer of transposable elements are briefly discussed within an evolutionary framework.

Evolution of the transposable element Uhu in five species of Hawaiian Drosophila

The complete DNA sequence of three independent isolates of Uhu, a member of the Tc1-like class of transposable elements from D. heteroneura (Uhu-1, Uhu-3, and Uhu-4), has been determined. These isolates have between 95 and 96.4% nucleotide sequence identity indicating that Uhu is well conserved within this species. A comparison of the DNA sequences of Uhu and the D. melanogaster Hb1 transposable element shows that the nucleotide substitution rate for Uhu is comparable to the synonymous rate for the Adh gene in these species. Uhu has been identified in four other species of endemic Hawaiian Drosophila, D. silvestris, D. differens, D. planitibia and D. picticornis, and nine Uhu elements were isolated from genomic libraries of these four species. A 444 base pair region from within the coding region of the Uhu element, with well conserved ends, was amplified by the polymerase chain reaction and used for sequence comparison of elements from different species. The analysis of the sequence similarities between the elements within and between the species shows a grouping of the two pairs of most closely related species (D. heteroneura and D. silvestris, and D. differens and D. planitibia), but shows a much larger variation within the most recently diverged species (D. heteroneura and D. silvestris) than expected. There are extensive nucleotide substitutions and deletions in the Uhu elements from D. picticornis showing that they are degenerating and being lost in this species. These observations indicate that the Uhu element has been transmitted vertically and that transposition may have been activated at the time of formation of each species as it colonized the newly formed islands of the Hawaiian archipelago.

Minos, a new transposable element from Drosophila hydei, is a member of the Tc1-like family of transposons

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Sequences homologous to Tc(s) transposable elements of Caenorhabditis elegans are widely distributed in the phylum nematoda

To have a better understanding of the evolutionary history of mobile elements within the nematodes, we examined the distribution and the conservation of homologues to transposable elements from Caenorhabditis elegans (Tc1, Tc2, Tc3, Tc4, Tc5, and FB1) in 19 nematode species belonging to the class Secernentea. Our results show that Tc1 elements display a distribution restricted to the family Rhabditidae with poor conservation. The Tc2 and FB1 homologous elements have the same patchy distribution within the Rhabditidae. They were only found in Caenorhabditis and in Teratorhabditis. The Tc3 element is widely distributed among nematode species. Tc3 homologous elements are present in the majority of the Rhabditidae but also in two genera within the family Panagrolaimidae, and in Bursaphelenchus, which belongs to the order Aphelenchida. Tc4 and Tc5 homologues show the most limited distribution of all tested elements, being strictly limited to C. elegans. These data indicate that in some cases, the distribution of transposable elements in the nematode cannot be explained by strict vertical transmission. The distribution of Tc3, Tc4, and Tc5 suggests that horizontal transmission may have occurred between reproductively isolated species during their evolutionary history.

A transposon-related palindromic repetitive sequence from C. elegans

A family of transposon-like sequences in the C. elegans genome is described. This family, termed the Tc6 family, consists mostly of conserved, 1.6 kb elements. Four Tc6 elements or partial elements have been cloned and the DNA sequences of three were determined. One appears to be a complete element of 1603 nucleotides, consisting of a palindrome of 765 nucleotides, with a central, non-palindromic region of 73 nucleotides. Another has an identical structure except for an internal deletion. A third is a partial element terminating at a probable internal restriction site used for cloning. A fourth clone contained portions of the Tc6 sequence juxtaposed to non-Tc6 sequences. All C. elegans strains examined contain 20-30 Tc6 elements. The ends of Tc6 elements are conserved and have sequence similarity to the ends of C. elegans transposons Tc1 and Tc3. The ends of Tc6 elements also have sequence similarity to the heptamer portion of the immunoglobulin and T-cell receptor recombination signal sequence, raising the possibility of wide phylogenetic conservation of the recombination mechanism. Tc6 elements also share sequence motifs with plant-pathogenic viroid RNA's, possibly indicative of a Tc6 RNA replicative phase.

Characterization of the FB-NOF transposable element of Drosophila melanogaster

FB-NOF is a composite transposable element of Drosophila melanogaster. It is composed of foldback sequences, of variable length, which flank a 4-kb NOF sequence with 308-bp inverted repeat termini. The NOF sequence could potentially code for a 120-kD polypeptide. The FB-NOF element is responsible for unstable mutations of the white gene (wc and wDZL) and is associated with the large TEs of G. Ising. Although most strains of D. melanogaster have 20-30 sites of FB insertion, FB-NOF elements are usually rare, many strains lack this composite element or have only one copy of it. A few strains, including wDZL and Basc have many (8-21) copies of FB-NOF, and these show a tendency to insert at "hot-spots." These strains also have an increased number of FB elements. The DNA sequence of the NOF region associated with TE146(Z) has been determined.

The transposable element Uhu from Hawaiian Drosophila--member of the widely dispersed class of Tc1-like transposons

We report the complete nucleotide sequence of the transposable element Uhu from the vicinity of the alcohol dehydrogenase (Adh) gene of Drosophila heteroneura (an endemic Hawaiian Drosophila). The complete element is about 1650 base-pairs (bp) long, has 46-50 base-pair inverse imperfect repeats at it's ends, and contains a large open reading frame potentially encoding a 192 amino acid protein. We demonstrate that Uhu belongs to a class of transposable elements which includes Tc1 from Caenorhabditis elegans, Barney from Caenorhabditis briggsae, and HB1 from Drosophila melanogaster. All of these elements share significant sequence similarity, are approximately 1600 base pairs long, have short inverse terminal repeats (ITRs), contain open reading frames (ORFs) with significant sequence identity, and appear to insert specifically at TA sequences generating target site duplications.

Isolation and sequence analysis of Caenorhabditis briggsae repetitive elements related to the Caenorhabditis elegans transposon Tc1

We have identified two repetitive element families in the genome of the nematode Caenorhabditis briggsae with extensive sequence identity to the Caenorhabditis elegans transposable element Tc1. Five members each of the TCb1 (previously known as Barney) and TCb2 families were isolated by hybridization to a Tc1 probe. Tc1-hybridizing repetitive elements were grouped into either the TCb1 or TCb2 family based on cross-hybridization intensities among the C. briggsae elements. The genomic copy number of the TCb1 family is 15 and the TCb2 family copy number is 33 in the C. briggsae strain G16. The two transposable element families show numerous genomic hybridization pattern differences between two C. briggsae strains, suggestive of transpositional activity. Two members of the TCb1 family, TCb1#5 and TCb1#10, were sequenced. Each of these two elements had suffered an independent single large deletion. TCb1#5 had a 627-bp internal deletion and TCb1#10 had lost 316 bp of one end. The two sequenced TCb1 elements were highly conserved over the sequences they shared. A 1616-bp composite TCb1 element was constructed from TCb1#5 and TCb1#10. The composite TCb1 element has 80-bp terminal inverted repeats with three nucleotide mismatches and two open reading frames (ORFs) on opposite strands. TCb1 and the 1610-bp Tc1 share 58% overall nucleotide sequence identity, and the greatest similarity occurs in their ORF1 and inverted repeat termini.

TcA, the putative transposase of the C. elegans Tc1 transposon, has an N-terminal DNA binding domain

Tc1 is a transposon present in several copies in the genome of all natural isolates of the nematode C.elegans; it is actively transposing in many strains. In those strains Tc1 insertion is the main cause of spontaneous mutations. The transposon contains one large ORF that we call TcA; we assume that the TcA protein is the transposase of Tc1. We expressed TcA in E.coli, purified the protein and showed that it has a strong affinity for DNA (both single stranded and double stranded). A fusion protein of beta-galactosidase and TcA also exhibits DNA binding; deletion derivatives of this fusion protein were tested for DNA binding. A deletion of 39 amino acids at the N-terminal region of TcA abolishes the DNA binding, whereas a deletion of 108 C-terminal amino acids does not affect DNA binding. This shows that the DNA binding domain of TcA is near the N-terminal region. The DNA binding capacity of TcA supports the assumption that TcA is a transposase of Tc1.

Structural analysis of Tc1 elements in Caenorhabditis elegans var. Bristol (strain N2)

The transposable element Tc1 in the genome of Caenorhabditis elegans var. Bristol strain N2 is very stable. In order to investigate possible causes of Tc1 immobility in this strain 17 individual isolates have been cloned and characterized with regard to their structure and genomic environment. Ten of 16 elements examined had identical restriction maps, and at least 1 of these (#7) showed a high level of somatic excision. Two of the elements had altered restriction sites, 2 had different internal deletions of about 700 bp, 1 had an 89-bp terminal deletion, and 1 a 54-bp insertion. When DNA sequences flanking the N2 Tc1 elements were used as probes in genomic hybridizations, it was found that most N2 elements are located in regions of repetitive DNA. Furthermore when hybridizations to DNA from N2 and var. Bergerac strain B0 were performed, a major band of the same size was observed in both strains. Two flanking sequences identified strain polymorphic sites hP2(IV) and hP3(IV). In at least one of these cases, a rearranged Tc1 was present in the B0 strain at the same location. The fact that all or most of the Tc1 elements are in the same location in N2 and B0 adds support to the hypothesis that the high copy number B0 strain arose from amplification of Tc1 copies in a N2-like strain. The N2 Tc1 elements are highly conserved; however, intact elements had fewer nucleotide changes than the rearranged elements. These results may indicate that the intact Tc1 elements in N2 are functionally active and subject to selective pressure.