Nucleotide sequences required for Tn3 transposition immunity

The Tn3-family of Replicative Transposons

Transposons of the Tn3 family form a widespread and remarkably homogeneous group of bacterial transposable elements in terms of transposition functions and an extremely versatile system for mediating gene reassortment and genomic plasticity owing to their modular organization. They have made major contributions to antimicrobial drug resistance dissemination or to endowing environmental bacteria with novel catabolic capacities. Here, we discuss the dynamic aspects inherent to the diversity and mosaic structure of Tn3-family transposons and their derivatives. We also provide an overview of current knowledge of the replicative transposition mechanism of the family, emphasizing most recent work aimed at understanding this mechanism at the biochemical level. Previous and recent data are put in perspective with those obtained for other transposable elements to build up a tentative model linking the activities of the Tn3-family transposase protein with the cellular process of DNA replication, suggesting new lines for further investigation. Finally, we summarize our current view of the DNA site-specific recombination mechanisms responsible for converting replicative transposition intermediates into final products, comparing paradigm systems using a serine recombinase with more recently characterized systems that use a tyrosine recombinase.

Phage Mu transposition immunity reflects supercoil domain structure of the chromosome

Transposition immunity is the negative influence that the presence of one transposon sequence has on the probability of a second identical element inserting in the same site or in sites nearby. A transposition-defective Mu derivative (MudJr1) produced transposition immunity in both directions from one insertion point in the Salmonella typhimurium chromosome. To control for the sequence preference of Mu transposition proteins, Tn10 elements were introduced as targets at various distances from an immunity-conferring MudJr1 element. Mu transposition into a Tn10 target was not detectable when the distance of separation from MudJr1 was 5 kb, and transposition was unencumbered when the separation was 25 kb. Between 5 kb and 25 kb, immunity decayed gradually with distance. Immunity decayed more sharply in a gyrase mutant than in a wild-type strain. We propose that Mu transposition immunity senses the domain structure of bacterial chromosomes.

UV photoaffinity labeling of Tn3 transposase--DNA complexes: identification of DNA binding domains

The prokaryotic transposon Tn3 requires the transposase protein, as well as the cis-acting terminal inverted repeats (IRs), for transposition. The first step in the transposition process requires transposase binding to the IRs, as well as target site selection for element insertion. The primary aim of this study is to define the relationship between the structure of Tn3 transposase and its DNA binding functions. We have defined, by UV cross-linking, two broad regions of transposase that interact with DNA: a 70-kDa N-terminal domain and a 30-kDa C-terminal domain. The 70-kDa N-terminal domain encompasses the IR sequence specific binding domain, as well as a nonspecific DNA binding domain that has been previously described. We have also defined, by UV cross-linking, a region in the nonspecific DNA binding domain centered at amino acids 376 and 381 that is in contact with DNA. We have used site-directed mutagenesis of amino acids 376 and 381 to help delineate the function of this region of the transposase protein. Mutations in this region reduce transposition frequency to 30-40% of the wild type. These mutations reduce nonspecific DNA binding three- to four-fold but do not appear to affect specific binding to the IR. Transposition immunity is unaffected by mutations in the nonspecific DNA binding domain. This suggests that this region may be involved in target site selection.

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.

Conversion of pBR322-based plasmids into broad-host-range vectors by using the Tn3 transposition mechanism

We constructed a series of transposon vectors which allow efficient in vitro gene manipulation and subsequent introduction of cloned DNA into a variety of gram-negative bacteria. Transfer of the cloned fragment from these multicopy plasmids into self-transmissible broad-host-range vectors is achieved in vivo, using the Tn3 transposition mechanism. Transposition into a variety of broad-host-range plasmids proceeds efficiently, and the resulting recombinant plasmids can be readily transferred and maintained in a variety of gram-negative bacteria. The utility of the transposable vectors was demonstrated by the introduction and expression of the lacIPOZY sequences of Escherichia coli into Pseudomonas putida strains, allowing them to utilize lactose as a sole source of carbon and energy.

Conduction of pEC22, a plasmid coding for MR.EcoT22I, mediated by a resident Tn3-like transposon, Tn5396

pEC22 is a small plasmid that encodes the restriction-modification system MR.EcoT22I. Restriction and functional analysis of the plasmid identified the positions of genes encoding that system. The plasmid is able to be conducted by conjugal plasmids, a process mediated by a transposon contained within pEC22. This cryptic transposon, called Tn5396, was isolated from pEC22 and partially sequenced. The sequence of Tn5396 is for the most part typical of transposons of the Tn3 family and is most similar to that of Tn1000. The transposon differs from closely related transposons in that it lacks well-conserved sequences in the inverted-repeat region and has an unusually long terminal inverted repeat. Consideration of regions of internal sequence similarity in this and other transposons in the Tn3 family supports a theory of the mechanism by which the ends of Tn3-like transposons may maintain substantial identity between their inverted repeats over the course of evolutionary time.

Mutations in the inverted repeats of Tn3 affect binding of transposase and transposition immunity

In order to better understand the interaction between the inverted repeats (IRs) of the transposon Tn3 and Tn3 transposase, we have looked at the effects of mutations within the IRs on binding of transposase and transposition immunity. Binding of transposase to mutated IRs was measured using a site-specific nitrocellulose filter binding assay and by DNase I protection studies. Transposition immunity was measured in vivo using a transposition mating-out assay. The most important determinants for binding of transposase are present within the inside 21 base-pairs of the IR and several single base-pair mutations significantly reduce binding. Base-pair mutations which do not effect binding have strong negative effects on transposition immunity indicating that simple binding of transposase to the IR is not sufficient for the establishment of transposition immunity.

The Tn21 subgroup of bacterial transposable elements

The Tn3 family of transposable elements is probably the most successful group of mobile DNA elements in bacteria: there are many different but related members and they are widely distributed in gram-negative and gram-positive bacteria. The Tn21 subgroup of the Tn3 family contains closely related elements that provide most of the currently known variation in Tn3-like elements in gram-negative bacteria and that are largely responsible for the problem of multiple resistance to antibiotics in these organisms. This paper reviews the structure, the mechanism of transposition, the mode of acquisition of accessory genes, and the evolution of these elements.

Uncoupling of transpositional immunity from gamma delta transposition by a mutation at the end of gamma delta

The transposon gamma delta, in common with other members of the Tn3 family, confers transpositional immunity, a phenomenon by which plasmids containing a single transposon end show reduced activity as targets for further insertion by the same element. We found that a copy of a mutant delta end, in which the two terminal base pairs (5' GG) were substituted with cytosines, conferred the same degree of immunity as the unaltered delta end. However, a transposon analog with the mutant delta end as its termini could not transpose. These results suggest that the binding of transposase to a site on a target replicon is sufficient to confer immunity and that immunity does not involve subsequent DNA transactions at the bound target site, analogous to the catalytic processes that occur at the transposon ends during transposition.

Mutational analysis of the inverted repeats of Tn3

The transposase protein and the terminal inverted repeat sequences of the prokaryotic transposon Tn3 are essential for transposition. In order to determine the sequences within the inverted repeat necessary for transposition and interaction with transposase, we have constructed a series of mini-Tn3s in which specific mutations have been introduced into the inverted repeats. The effects of these mutations on transposition have been assayed in vivo using a mating-out transposition assay. Several single base-pair mutations within the transposase binding site reduce transposition frequency. Mutations that affect transposition show a greater effect when present in both inverted repeats than when present in only one inverted repeat.

Tn3 transposition immunity is conferred by the transposase-binding domain in the terminal inverted-repeat sequence of Tn3

A series of mutant terminal inverted repeats (IRs), having 2 bp substitutions at various sites within the 38-bp IR sequence of the ampicillin-resistance transposon Tn3, were tested for transposition immunity to Tn3. Mutations within region 1-10 in the IR did not affect transposition immunity, while mutations within region 13-38 inactivated the immunity function. These two regions corresponded to domain A which was not bound specifically by Tn3 transposase and to domain B which was bound by the transposase, respectively. This indicates that specific binding of transposase to domain B within the IR sequence is responsible for transposition immunity.