Intermolecular Transposition of Is10 Causes Coupled Homologous Recombination at the Transposition Site

Interplasmid and chromosome to plasmid transposition of IS10 were studied by assaying inactivation of the phage 434 cI gene, carried on a low copy number plasmid. This was detected by the activity of the tet gene expressed from the phage 434 P(R) promoter. Each interplasmid transposition resulted in the fusion of the donor and acceptor plasmids into cointegrate structure, with a 9-bp duplication of the target DNA at the insertion site. Cointegrate formation was abolished in δrecA strains, although simple insertions of IS10 were observed. This suggests a two-stage mechanism involving IS10 conservative transposition, followed by homologous recombination between the donor and the acceptor. Two plasmids carrying inactive IS10 sequences were fused to cointegrates at a 100-fold lower frequency, suggesting that homologous recombination is coupled to and stimulated by the transposition event. Each IS10 transposition from the chromosome to the acceptor plasmid involved replicon fusion, providing a mechanism for IS10-mediated integration of extrachromosomal elements into the chromosome. This was accompanied by the formation of an additional copy of IS10 in the chromosome. Thus, like replicative transposition, conservative transposition of IS10 is accompanied by cointegrate formation and results in duplication of the IS10.     

Transposition of IS50L activates downstream genes.

A transposition system constructed to detect the transposition of Tn5 to a site upstream of the lacZ gene has revealed that transposition of IS50L can activate downstream genes. Expression is apparently mediated by the NPTII promoter. Transposase produced either by IS50R or by the suppressed IS50L catalyzed transposition of IS50L.     

Transposon Tn10: genetic organization, regulation, and insertion specificity

Transposon Tn10 is a composite element in which two individual insertion sequence (IS)-like sequences cooperate to mediate transposition of the intervening material. The two flanking IS10 elements are not identical; IS10-right is responsible for functions required to promote transposition, and IS10-left is defective in transposition functions. We suggest that the two IS10 elements were originally identical in sequence and have subsequently diverged. IS10-right is compactly organized with structural gene(s), promoters, and sites important for transposition and (presumably) its regulation all closely linked and, in some cases, overlapping. IS10 has a single major coding region that almost certainly encodes an essential transposition function. A pair of opposing promoters flank the start of this coding region. One of these promoters is responsible for expression in vivo of transposon-encoded transposition functions. We propose that the second promoter is involved in modulation of Tn10 transposition. Genetic analysis suggests that transposon-encoded function(s) may be preferentially cis-acting. Insertion of Tn10 into particular preferred target sites is due primarily to the occurrence of a particular six-base pair target DNA sequence. The properties of this sequence suggest that symmetrically disposed subunits of a single protein may be responsible for both recognition and cleavage of target DNA during insertion.     

IS10 transposition is regulated by DNA adenine methylation

We show that dam- mutants are a major class of E. coli mutants with increased IS10 activity. IS10 has two dam methylation sites, one within the transposase promoter and one within the inner terminus where transposase presumably binds. Absence of methylation results in increased activity of both promoter and terminus, and completely accounts for increased transposition in dam- strains. Transposition of Tn903 and Tn5 are also increased in dam- strains, probably for analogous reasons. Transposition is also increased when IS10 is hemimethylated. One hemimethylated species is much more active than the other and is estimated to be at least 1000 times more active than a fully methylated element. Evidence is presented that the promoter and inner terminus of IS10 are coordinately activated in a dam-dependent fashion, presumably because they are hemimethylated at the same time. Thus, in dam+ strains, IS10 will transpose preferentially when DNA is hemimethylated. We suggest specifically that IS10 transposition may preferentially occur immediately after passage of a chromosomal replication fork.     

LexA protein of Escherichia coli represses expression of the Tn5 transposase gene.

The LexA protein of Escherichia coli represses expression of a variety of genes that, by definition, constitute the SOS regulon. Genetic evidence suggests that Tn5 transposition is also regulated by the product of the lexA gene (C.-T. Kuan, S.-K. Liu, and I. Tessman, Genetics 128:45-57, 1991). We now show that the LexA protein represses expression of the tnp gene, located in the IS50R component of Tn5, which encodes a transposase, and that LexA does not repress expression of the IS50R inh gene, which encodes an inhibitor of transposition. Elimination of LexA resulted in increased expression of the tnp gene by a factor of 2.7 +/- 0.4, as indicated by the activity of a lacZ gene fused to the tnp gene. LexA protein retarded the electrophoretic movement of a 101-bp segment of IS50R DNA that contained a putative LexA protein-binding site in the tnp promoter; the interaction between the LexA repressor and the promoter region of the tnp gene appears to be relatively weak. These features show that the IS50R tnp gene is a member of the SOS regulon.     

Evolutionary changes in the structural and regulatory regions of aminoglycoside-3'-phosphotransferase type I gene of E. coli

To investigate the evolutionary relationships between the aph(3') genes from different plasmids, the nucleotide sequence of the aph(3') gene from the E. coli R plasmid was determined and compared with the known aph(3') genes of Tn903 and Tn4352. Three point mutations in the structural part of the cloned aph(3') gene caused amino acid changes in the enzyme molecule at positions 19, 27 and 48 beginning from the start codon. The structural part of the gene was followed by two stop codons and a long DNA region containing no nucleotide sequences homologous to the sequences of Tn903 or Tn4352. Both the cloned aph(3') gene and Tn4352 were limited on the left by the spacer sequence and the insertion sequence IS176. Twenty one base pairs deletion abolished the -35 sequence of the promoter suggested for the aph(3') gene of Tn4352 and resulted in formation of a fusion promoter utilizing the -35 box of IS176 and the -10 box of the aph(3') gene. The distance between the -35 and -10 sequences changed from 18 to 17 bp. Changes in the cloned aph(3') gene and the flanking DNA regions resulted in formation of a new promoter and loss of the right IS176 element.     

Multiple copies of IS10 in the Enterobacter cloacae MD36 chromosome.

Repetitive sequences were isolated and characterized as double-stranded DNA fragments by treatment with S1 nuclease after denaturation and renaturation of the total DNA of Enterobacter cloacae MD36. One repetitive sequence was identical to the nucleotide sequence of IS10-right (IS10R), which is the active element in the plasmid-associated transposon Tn10. Unexpectedly, 15 copies of IS10R were found in the chromosomal DNA of E. cloacae MD36. One copy of the central region of Tn10 was found in the total DNA of E. cloacae MD36. IS10Rs in restriction fragments isolated from the E. cloacae MD36 total DNA showed 9-bp duplications adjacent to the terminal sequences that are characteristic of Tn10 transposition. This result suggests that many copies of IS10R in E. cloacae MD36 are due to transposition of IS10R alone, not due to transposition of Tn10 or to DNA rearrangement. I also found nine copies of IS10 in Shigella sonnei HH109, two and four copies in two different natural isolates of Escherichia coli, and two copies in E. coli K-12 strain JM109 from the 60 bacterial strains that were examined. All dam sites in the IS10s in E. cloacae MD36 and S. sonnei HH109 were methylated. Tn10 and IS10 transpose by a mechanism in which the element is excised from the donor site and inserted into the new target site without significant replication of the transposing segment; thus, the copy numbers of the elements in the cell are thought to be unchanged in most circumstances. Accumulation of IS10 copies in E. cloacae MD36 has interesting evolutionary implications.     

Transposition of IS10R in Lactococcus lactis

Aims:  To characterize the transposition mechanism of the IS-element IS 10 R and study how this element is involved in gene disruption in Lactococcus lactis .
Methods and Results:  The gene flciA confers immunity against lactococcin A in lactococci. However, the immunity function was lost when flciA was co-expressed with the regulator gene nisR on a plasmid in L. lactis NZ9000. By PCR and DNA sequencing, it was revealed that flciA in immune-negative transformants was disrupted by the IS-element IS 10 R. Such gene disruption did not occur when flciA was expressed alone nor when the plasmid-located nisR was mutated, suggesting that nisR is directly involved in the transposition. The sequence 5'-CACTTAACC-3', which was found in flciA and at both ends of the inserted IS 10 R, was identified as target site by site-directed mutagenesis.
Conclusions:  IS 10 R transposes in L. lactis NZ9000 in a nisR -dependent fashion and employs the sequence 5'-CACTTAACC-3' as integration site.
Significance and Impact of the Study:  To our knowledge, this is the first time IS 10 R and aspects of its transposition are described in the industrial important bacterium L. lactis . The highly controllable insertion of IS 10 R into a target site might present a great potential as a gene disruption system.     

Identification of an ancillary protein, YabF, required for activity of the KefC glutathione-gated potassium efflux system in Escherichia coli

A new subunit, YabF, for the KefC K(+) efflux system in Escherichia coli has been identified. The subunit is required for maximum activity of KefC. Deletion of yabF reduces KefC activity 10-fold, and supply of YabF in trans restores activity. IS2 and IS10R insertions in yabF can be isolated as suppressors of KefC activity consequent upon the V427A and D264A KefC mutations.     

Effective selection and analysis of IS1 element transposition using the oLpLN region of phage lambda

The plasmid pNT6 permits selection of IS1-element insertions into the plasmid occurring with the frequency about 10%. The bacteriophage promoter pL cloned in pNT6 is a hot-spot region for IS1-element insertion. The frequency of IS1 transposition into pL depends on genotype. The plasmid pNT6 may be considered to be a useful target DNA for screening and analysis of IS1-element transposition.     

Insertion element IS1 can generate a 10-base pair target duplication

Transposable element IS1 is known to generate mainly 9-bp and occasionally 8-bp target duplications upon transposition. We have isolated a plasmid pBR322 derivative having IS1 inserted into a site between the promoter and the structural gene for tetracycline resistance. DNA sequence analysis revealed that integration of this IS1 resulted in a 10-bp target duplication.