The inverted repeats of IS<Emphasis Type="Italic">1384</Emphasis>, a newly described insertion sequence from<Emphasis Type="Italic"> Pseudomonas putida</Emphasis> strain H,represent the specific target for integration of IS<Emphasis Type="Italic">1383</Emphasis>

Analysis of a region on plasmid pPGH1 from Pseudomonas putida strain H that is flanked by two copies of IS1383 has revealed an additional element with the typical features of a bacterial insertion sequence. This new IS element, designated IS1384, contains a single ORF of 972 bp, and is flanked by 9-bp inverted repeats. Based on sequence homology and structural characteristics of the putative transposase it encodes, IS1384 belongs to the IS5 subgroup of the IS5 family. Two copies of IS1384 are present on plasmid pPGH1, whereas none could be detected on the chromosome of P. putida strain H. Sequence analysis revealed the presence of two truncated copies of IS1384 on the second plasmid in this strain, pPGH2. The inverted repeats of all IS1384 copies (including the truncated ones) are interrupted by the integration of an IS1383 element. All integrations were found to be site- and orientation-specific. PCR studies and sequence data indicate that IS1383 can form a circular intermediate on excision. In the circular form, the previously described 13-bp inverted repeats of IS1383 are separated by 10 bp that are identical to the 5-bp motif that flanks each side of the element when it is integrated in its target. We provide evidence that these additional nucleotides, although not of inverted symmetry, represent an essential part of the inverted repeats. Furthermore, the data indicate that IS1383 integrated into the inverted repeats of IS1384 by a site-specific recombination rather than a site-specific insertion event.     

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.     

A Coxiella burnetti repeated DNA element resembling a bacterial insertion sequence.

A DNA fragment located on the 3' side of the Coxiella burnetii htpAB operon was determined by Southern blotting to exist in approximately 19 copies in the Nine Mile I genome. The DNA sequences of this htpAB-associated repetitive element and two other independent copies were analyzed to determine the size and nature of the element. The three copies of the element were 1,450, 1,452, and 1,458 bp long, with less than 2% divergence among the three sequences. Several features characteristic of bacterial insertion sequences were discovered. These included a single significant open reading frame that would encode a 367-amino-acid polypeptide which was predicted to be highly basic, to have a DNA-binding helix-turn-helix motif, to have a leucine zipper motif, and to have homology to polypeptides found in several other bacterial insertion sequences. Identical 7-bp inverted repeats were found at the ends of all three copies of the element. However, duplications generated by many bacterial mobile elements in the recipient DNA during insertion events did not flank the inverted repeats of any of the three C. burnetii elements examined. A second pair of inverted repeats that flanked the open reading frame was also found in all three copies of the element. Most of the divergence among the three copies of the element occurred in the region between the two inverted repeat sequences in the 3' end of the element. Despite the sequence changes, all three copies of the element have retained significant dyad symmetry in this region.     

Assembly of the mariner Mos1 synaptic complex

The mobility of transposable elements via a cut-and-paste mechanism depends on the elaboration of a nucleoprotein complex known as the synaptic complex. We show here that the Mos1 synaptic complex consists of the two inverted terminal repeats of the element brought together by a transposase tetramer and is designated paired-end complex 2 (PEC2). The assembly of PEC2 requires the formation of a simpler complex, containing one terminal repeat and two transposase molecules and designated single-end complex 2 (SEC2). In light of the formation of SEC2 and PEC2, we demonstrate the presence of two binding sites for the transposase within a single terminal repeat. We have found that the sequence of the Mos1 inverted terminal repeats contains overlapping palindromic and mirror motifs, which could account for the binding of two transposase molecules "side by side" on the same inverted terminal repeat. We provide data indicating that the Mos1 transposase dimer is formed within a single terminal repeat through a cooperative pathway. Finally, the concept of a tetrameric synaptic complex may simply account for the inability of a single mariner transposase molecule to interact at the same time with two kinds of DNA: the inverted repeat and the target DNA.     

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.     

Maize Activator transposase has a bipartite DNA binding domain that recognizes subterminal sequences and the terminal inverted repeats

The mobility of maize transposable element Activator (Ac) is dependent on the 11-bp terminal inverted repeats (IRs) and approximately 250 subterminal nucleotides at each end. These sequences flank the coding region for the transposase (TPase) protein, which is required for the transposition reaction. Here we show that Ac TPase has a bipartite DNA binding domain, and recognizes the IRs and subterminal sequences in the Ac ends. TPase binds cooperatively to repetitive ACG and TCG sequences, of which 25 copies are found in the 5′ and 20 copies in the 3′ subterminal regions. TPase affinity is highest when these sites are flanked on the 3′ side by an additional G residue (A/TCGG), which is found at 75% of binding sites. Moreover, TPase binds specifically to the Ac IRs, albeit with much lower affinity. Two mutations within the IRs that immobilize Ac abolish TPase binding completely. The basic DNA binding domain of TPase is split into two subdomains. Binding to the subterminal motifs is accomplished by the C-terminal subdomain alone, whereas recognition of the IRs requires the N-terminal subdomain in addition. Furthermore, TPase is extremely flexible in DNA binding. Two direct or inverted binding sites are bound equally well, and sites that are five to twelve bases apart are similarly well bound. The consequences of these findings for the Ac transposition reaction are discussed.     

The Arabidopsis TAG1 transposase has an N-terminal zinc finger DNA binding domain that recognizes distinct subterminal motifs

The in vitro DNA binding activity of the Arabidopsis Tag1 transposase (TAG1) was characterized to determine the mechanism of DNA recognition. In addition to terminal inverted repeats, the Tag1 element contains four different subterminal repeats that flank a transcribed region encoding a 729-amino acid protein. A single site-specific DNA binding domain is located near the N terminus of TAG1, between residues 21 and 133. This domain binds specifically to the AAACCC and TGACCC subterminal repeats, found near the 5' and 3' ends of the element, respectively. The ACCC sequence within these repeats is critical for recognition because mutations at positions 3, 5, and 6 abolished binding, yet the first two bases also are important because substitutions at these positions decreased binding by up to 90%. Weak interaction also occurs with the terminal inverted repeats, but no binding was observed to the other two 3' subterminal repeat regions. Sequence analysis of the TAG1 DNA binding domain revealed a C(2)HC zinc finger motif. Tests for metal dependence showed that DNA binding activity was inhibited by divalent metal chelators and greatly enhanced by zinc. Furthermore, mutation of each cysteine residue predicted to be a metal ligand in the C(2)HC motif abolished DNA binding. Together, these data show that the DNA binding domain of TAG1 specifically binds to distinct subterminal repeats and contains a zinc finger.     

Maize Activator transposase has a bipartite DNA binding domain that recognizes subterminal sequences and the terminal inverted repeats

 The mobility of maize transposable element Activator (Ac) is dependent on the 11-bp terminal inverted repeats (IRs) and approximately 250 subterminal nucleotides at each end. These sequences flank the coding region for the transposase (TPase) protein, which is required for the transposition reaction. Here we show that Ac TPase has a bipartite DNA binding domain, and recognizes the IRs and subterminal sequences in the Ac ends. TPase binds cooperatively to repetitive ACG and TCG sequences, of which 25 copies are found in the 5′ and 20 copies in the 3′ subterminal regions. TPase affinity is highest when these sites are flanked on the 3′ side by an additional G residue (A/TCGG), which is found at 75% of binding sites. Moreover, TPase binds specifically to the Ac IRs, albeit with much lower affinity. Two mutations within the IRs that immobilize Ac abolish TPase binding completely. The basic DNA binding domain of TPase is split into two subdomains. Binding to the subterminal motifs is accomplished by the C-terminal subdomain alone, whereas recognition of the IRs requires the N-terminal subdomain in addition. Furthermore, TPase is extremely flexible in DNA binding. Two direct or inverted binding sites are bound equally well, and sites that are five to twelve bases apart are similarly well bound. The consequences of these findings for the Ac transposition reaction are discussed. Received: 3 June 1996 / Accepted: 29 July 1996     

Structure and evolution of a family of interspersed repetitive DNA sequences inCaenorhabditis elegans

Summary The structure of three members of a repetitive DNA family from the genome of the nematodeCaenorhabditis elegans has been studied. The three repetitive elements have a similar unitary structure consisting of two 451-bp sequences in inverted orientation separated by 491 bp, 1.5 kb, and 2.5 kb, respectively. The 491-bp sequence separating the inverted 451-bp sequences of the shortest element is found adjacent to one of the repeats in the other two elements as well. The combination of the three sequences we define as the basic repetitive unit. Comparison of the nucleotide sequences of the three elements has allowed the identification of the one most closely resembling the primordial repetitive element. Additionally, a process of co-evolution is evident that results in the introduction of identical sequence changes into both copies of the inverted sequence within a single unit. Possible mechanisms are discussed for the homogenization of these sequences. A direct test of one possible homogenization mechanism, namely homologous recombination between the inverted sequences accompanied by gene conversion, shows that recombination between the inverted repeats does not occur at high frequency.     

An insertion sequence unique to Frankia strain ArI5

At the genetic level, understanding of symbiotic nitrogen fixation by Frankia is limited to nif functions that are highly conserved among all organisms. The genetics and biochemistry of nodulation are largely unexplored because of a complete lack of genetic tools. In other bacteria, mobile genetic elements such as insertion sequences (IS) and transposons are commonly used to create mutations and insert new genetic material. We have characterized a 4 kbp segment of DNA from Frankia strain ArI5 that has the hallmarks of a mobile genetic element, inverted repeats flanking a gene encoding a transposase. There are at least six copies of this element in strain ArI5 but none in either strain CcI3 or CpI1. The inverted repeats are 17 nt long and separated by 2156 bp. Within that region are two, overlapping ORFs that each encode a transposase. RT-PCR analysis of RNA from Frankia ArI5 cells conclusively demonstrates the expression of one transposase gene and suggests that both may be transcribed. Numerous attempts to clone the intact IS in E. coli were unsuccessful suggesting that the element may be unstable in this context. A clone containing the complete IS was constructed in E. coli then modified by insertion of the kanamycin (KAN) resistance gene from Tn5. A fragment of DNA including the inverted repeats, transposase genes and KAN gene, was transferred to the suicide vector pJBSD1. The construct, pFRISK, was transformed into E. coli to search for transposition events.     

Binding of the Tn3 transposase to the inverted repeats of Tn3

The transposase protein and the inverted repeat sequences of Tn3 are both essential for Tn3 cointegrate formation and transposition. We have developed two assays to detect site-specific binding of transposase to the inverted repeats: (1) a nitrocellulose filter binding assay in which transposase preferentially retains DNA fragments containing inverted repeat sequences, and (2) a DNase 1 protection assay in which transposase prevents digestion of the inverted repeats by DNase 1. Both assays show that transposase binds directly to linear, duplex DNA containing the inverted repeats. The right inverted repeat of Tn3 binds slightly more strongly than the left one. Site-specific binding requires magnesium but does not require a high energy cofactor.     

MMTS, a new subfamily of Tc1-like transposons

A novel Tc1-like transposable element has been identified as a new DNA transposon in the mud loach, Misgurnus mizolepis. The M. mizolepis Tc1-like transposon (MMTS) is comprised of inverted terminal repeats and a single gene that codes Tc1-like transposase. The deduced amino acid sequence of the transposase-encoding region of MMTS transposon contains motifs including DDE motif, which was previously recognized in other Tc1-like transposons. However, putative MMTS transposase has only 34-37% identity with well-known Tc1, PPTN, and S elements at the amino acid level. In dot-hybridization analysis used to measure the copy numbers of the MMTS transposon in genomes of the mud loach, it was shown that the MMTS transposon is present at about 3.36 x 104 copies per 2 x 109 bp, and accounts for approximately 0.027% of the mud loach genome. Here, we also describe novel MMTS-like transposons from the genomes of carp-like fishes, flatfish species, and cichlid fishes, which bear conserved inverted repeats flanking an apparently intact transposase gene. Additionally, BLAST searches and phylogenetic analysis indicated that MMTS-like transposons evolved uniquely in fishes, and comprise a new subfamily of Tc1-like transposons, with only modest similarity to Drosophila melanogaster (foldback element FB4, HB2, HB1), Xenopus laevis, Xenopus tropicalis, and Anopheles gambiae (Frisky).     

The terminal inverted repeats of IS911: requirements for synaptic complex assembly and activity

The bacterial insertion sequence IS911 transposes via a covalently closed circular intermediate. Circle formation involves transposase-mediated pairing of both insertion sequence ends. While full-length transposase, OrfAB, binds poorly in vitro to IS911 DNA fragments carrying a copy of the IS911 end, truncated protein derivatives carrying the first 135 (OrfAB[1-135]) or 149 (OrfAB[1-149]) amino acid residues bind efficiently. They generate a paired-end complex containing two such fragments which resembles that expected for the first synaptic complex. Shorter protein derivatives lacking a region involved in multimerisation do not form these complexes but modify the binding of OrfAB[1-135] and OrfAB[1-149]. DNaseI footprinting demonstrated that OrfAB[1-149] protects a sub-terminal (internal) region of the inverted repeats which includes two blocks of sequence (beta and gamma) conserved between the left (IRL) and right (IRR) ends. DNA binding assays in vitro and measurement of recombination activity in vivo of sequential deletion derivatives of the two inverted repeats suggested a model in which the N-terminal region of OrfAB binds the conserved boxes beta and gamma in a sequence-specific manner and anchors the two insertion sequence ends into a paired-end complex. The external region of the inverted repeat is proposed to contact the C-terminal transposase domain carrying the catalytic site.     

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.     

The primary structure and characteristics of the ISAfe600, an insertion sequence from Acidithiobacillus ferrooxidans strains

A new IS-like element (604 bp) was revealed in the genome of several Acidithiobacillus ferrooxidans strains isolated from diverse biotopes. It includes 26-bp imperfectly matched terminal inverted repeats (TIRs), similar in structure to the TIRs of ISAfel insertion element. The 60-bp DNA fragment adjacent to the right TIR (TIRR) exhibits pronounced homology with the similarly located DNA fragments in ISAfel and IST445, as well as with the internal fragment of ISAfel encoding the transposase gene (nucleotides from 254 to 311 bp). The central section of ISAfe600 is unique and exhibits no homology with any prokaryotic DNA. A duplication of 8 bp of the target DNA was found in the ISAfe600 insertion site. One to four copies of ISAfe600 were revealed by Southern hybridization in the genome of A. ferrooxidans strains studied. The number of ISAfe600 copies varies depending on the growth conditions (energy substrate). Since the open reading frames big enough to encode transposase are not presert in the structure of ISAfe600, it may be a deficient IS element; its translocation is possibly achieved under control of the ISAfel transposase.     

Developmentally coordinated en masse excision of a highly repetitive element in E. crassus

The E. crassus Tec1 element is present in greater than 10(4) copies in the micronuclear genome but is absent from the macronuclear genome. During formation of a macronucleus from a micronucleus, a majority of the Tec1 elements appear as extrachromosomal circles. The circular and integrated forms of Tec1 have been characterized by restriction mapping to produce consensus maps and by sequence analysis of the element's termini. The circular forms are resistant to BAL31 and have the restriction map expected if the element excises at the end of its inverted repeats. DNA sequence analysis of a circular form confirms that the inverted repeats are in a head-to-head configuration. Excision of Tec1 occurs very early during macronuclear development as the DNA begins to replicate to form polytene chromosomes.     

Plasmid fusions mediated by one end of TnA

We have observed plasmid fusions in a recA background mediated by a single end of TnA. These occur when transposase is provided either in cis or in trans. Insertions of the plasmid carrying the TnA inverted repeat sequence occur at many sites in the target plasmid. The point of fusion on the plasmid carrying TnA sequences always appears to be located in the region which carries the TnA inverted repeat sequence. In contrast to the transposition of an intact TnA element, plasmid fusions mediated by one end of TnA are very rare events. The implications of our results for models of transposition are discussed.     

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.