Nucleotide sequence of the insertion sequence found in the T-DNA region of mutant Ti plasmid pTiA66 and distribution of its homologues in octopine Ti plasmid.

Machida, Yasunori; Sakurai, Michiharu; Kiyokawa, Shigeto; Ubasawa, Aiko; Suzuki, Yasuhiro; Ikeda, Joh‐E

doi:10.1073/pnas.81.23.7495

Cited by 55 publications

(25 citation statements)

References 34 publications

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“…(for a review, see reference 16). Unlike IS679, many have more than three ORFs; for example, the early isolates IS66 (15) and IS866 (2) have, respectively, four and five ORFs. No study so far, however, has addressed the transposition capability and requirement of ORFs in IS66 family elements.…”

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confidence: 99%

Structural and Functional Characterization of IS 679 and IS 66 -Family Elements

et al. 2001

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A new insertion sequence (IS) element, IS679 (2,704 bp in length), has been identified in plasmid pB171 of enteropathogenic Escherichia coli B171. IS679 has imperfect 25-bp terminal inverted repeats (IRs) and three open reading frames (ORFs) (here called tnpA, tnpB, and tnpC). A plasmid carrying a composite transposon (Tn679) with the kanamycin resistance gene flanked by an intact IS679 sequence and an IS679 fragment with only IRR (IR on the right) was constructed to clarify the transposition activity of IS679. A transposition assay done with a mating system showed that Tn679 could transpose at a high frequency to the F plasmid derivative used as the target. On transposition, Tn679 duplicated an 8-bp sequence at the target site. Tn679 derivatives with a deletion in each ORF of IS679 did not transpose, finding indicative that all three IS679 ORFs are essential for transposition. The tnpA and tnpC products appear to have the amino acid sequence motif characteristic of most transposases. A homology search of the databases found that a total of 25 elements homologous to IS679 are present in Agrobacterium, Escherichia, Rhizobium, Pseudomonas, and Vibrio spp., providing evidence that the elements are widespread in gram-negative bacteria. We found that these elements belong to the IS66 family, as do other elements, including nine not previously reported. Almost all of the elements have IRs similar to those in IS679 and, like IS679, most appear to have duplicated an 8-bp sequence at the target site on transposition. These elements have three ORFs corresponding to those in IS679, but many have a mutation(s) in an ORF(s). In almost all of the elements, tnpB is located in the ؊1 frame relative to tnpA, such that the initiation codon of tnpB overlaps the TGA termination codon of tnpA. In contrast, tnpC, separated from tnpB by a space of ca. 20 bp, is located in any one of three frames relative to tnpB. No common structural features were found around the intergenic regions, indicating that the three ORFs are expressed by translational coupling but not by translational frameshifting.Insertion sequences (ISs) comprise a large group of bacterial transposable DNA elements. These elements vary in size from 0.7 to 3.5 kb and have imperfect terminal inverted repeat sequences (IRs) of 10 to 40 bp in length (for recent reviews, see references 16 and 20). IS elements generally encode transposase, which is required for transposition, and duplicate a sequence of several base pairs at the target site on transposition. Based on the homology of their transposase genes, IS elements are classified into a number of families (see references 16 and 20). Most IS elements have an open reading frame (ORF) which is thought to encode transposase. Some elements, such as IS1 and IS3, have two ORFs, from which the transposase is produced by translational frameshifting (9,28,29,30). Unless frameshifting occurs, a protein(s) is produced that acts as a transposition inhibitor (31).IS679, which is present in two copies in plasmid pB171 of enteropathogenic ...

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Structural and Functional Characterization of IS 679 and IS 66 -Family Elements

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“…As far as gram-negative bacteria are concerned, most IS elements have been isolated from enteric bacteria (mainly E. coli; for reviews and lists of isolated elements, see references 14 and 20). However, there have been a substantial number of reports on IS elements identified in other gram-negative bacterial species, such as Agrobacterium tumefaciens (3,15,24,42), Xanthomonas campestris (22, 23), and various Rhizobium (9,28,32) and Pseudomonas (6,13,35,41,45) strains.In general, these elements have been found more or less by chance because of the capacity to inactivate or activate particular genes. However, there have been successful attempts to screen for transposable elements by means of direct selection procedures (8,15,30,35).…”

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Isolation and characterization of insertion sequence elements from gram-negative bacteria by using new broad-host-range, positive selection vectors

et al. 1991

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On the basis of an RSF1010-derived broad-host-range vector, three different systems which enable positive detection and isolation of insertion sequence (IS) elements from gram-negative bacteria were constructed. Vectors pSUP104-pheS, pSUP104-rpsL, and pSUP104-sac were used successfully in a number of Rhizobium strains and in Xanthomonas campestris. More than 20 different IS elements were isolated and characterized. The 16 IS elements from Rhizobium meliloti were further used to characterize various R. meliloti strains by hybridization. The resulting hybridization patterns were different for every strain and gave a dear and definite IS fingerprint of each strain. These IS fingerprints can be used to identify and characterize R. meliot strains rapidly and unequivocally, as they proved to be relatively stable. Some of the IS elements were found to be identical when the IS fingerprints from a given strain were compared. This method of IS fingerprinting can also establish whether IS elements are the same, related, or different.Insertion sequence (IS) elements are defined as relatively small mobile genetic entities which, unlike drug resistance transposons, do not contain selectable genes (5). This definition makes it clear that direct selection for the presence of an IS element is usually not possible. IS elements in procaryotes were first identified as causative agents of spontaneous mutations in Escherichia coli (21, 36). Since then, various classes of transposable elements have been found to be natural constituents of many bacterial chromosomes, plasmids, and bacteriophages. As far as gram-negative bacteria are concerned, most IS elements have been isolated from enteric bacteria (mainly E. coli; for reviews and lists of isolated elements, see references 14 and 20). However, there have been a substantial number of reports on IS elements identified in other gram-negative bacterial species, such as Agrobacterium tumefaciens (3,15,24,42), Xanthomonas campestris (22, 23), and various Rhizobium (9,28,32) and Pseudomonas (6,13,35,41,45) strains.In general, these elements have been found more or less by chance because of the capacity to inactivate or activate particular genes. However, there have been successful attempts to screen for transposable elements by means of direct selection procedures (8,15,30,35).In this report, we present the construction and use of three broad-host-range vectors designed to enable systematic searches for the presence of transposable elements in gramnegative bacteria. Advantage was taken of two direct selection systems initially constructed to simplify cloning experiments with E. coli (7, 17), as well as a system described by Gay and coworkers (15). The common principle of these systems is based upon insertional inactivation of a vectorborne dominant sensitivity marker. With pSUP104-pheS and pSUP104-rpsL, this leads to drug resistance. Inactivation of pSUP104-sac allows its host to grow on medium containing 5% sucrose. Both of these events are positively selectable phenotypes in the hosts. (A...

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“…However, no known sequence was found related to ORF4. IS272 is readily distinguishable from IS426 and IS427 isolated from the Agrobacteritrm nopaline-type strain "37 (Vanderleyden et al, 1986;De Meirsman e t al., 1989, 1990, from IS7 737 isolated from the nopaline-type strain PO22 (Wabiko, 1992), from IS866 and IS867 isolated from the octopine/vitopine-type strain Tm4 (Bonnard e t al., 1989;Paulus et al, 1989bPaulus et al, , 1991a and from IS66 isolated from the octopine-type strain A66 (Machida et al, 1984). However, we found similarity between terminal inverted repeats of IS272, IS66, IS866 and IS7737 from Agrobacteritrm, ISRl7 from R. legzlminosarzim and ISRm2 from R. meliloti, but limited to a six nucleotide consensus sequence (Fig.…”

Section: Occurrence Of Is292 In Various Agrobacterium Strainsmentioning

confidence: 70%

IS292: a novel insertion element from Agrobacterium

Ponsonnet¹,

Normand²,

Pilate³

et al. 1995

Microbiology

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A new insertion sequence, 15292, located in the 6b gene of a nopaline-type Agrobacterium strain (X88-292) isolated from poplar was identified and sequenced. IS292 is 2494 bp long, has 21 bp inverted terminal repeats with two mismatches, and generates 10 bp direct repeats upon integration. No sequence similarity was found between IS292 and other insertion elements associated with Agrobacterium, but it shows strong similarity with lSRI7 from Rhizobium leguminosamm bv. viciae. The occurrence of IS292-like sequences in various Agrobacterium isolates, especially different Agrobacterium strains isolated from the same biotope, was demonstrated by DNA hybridization.

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Nucleotide sequence of the insertion sequence found in the T-DNA region of mutant Ti plasmid pTiA66 and distribution of its homologues in octopine Ti plasmid.

Cited by 55 publications

References 34 publications

Structural and Functional Characterization of IS 679 and IS 66 -Family Elements

Structural and Functional Characterization of IS 679 and IS 66 -Family Elements

Isolation and characterization of insertion sequence elements from gram-negative bacteria by using new broad-host-range, positive selection vectors

IS292: a novel insertion element from Agrobacterium

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