Switching from cut-and-paste to replicative Tn7 transposition.

The bacterial transposon Tn7 usually moves through a cut-and-paste mechanism whereby the transposon is excised from a donor site and joined to a target site to form a simple insertion. The transposon was converted to a replicative element that generated plasmid fusions in vitro and cointegrate products in vivo. This switch was a consequence of the separation of 5'- and 3'-end processing reactions of Tn7 transposition as demonstrated by the consequences of a single amino acid alteration in an element-encoded protein essential for normal cut-and-paste transposition. The mutation specifically blocked cleavage of the 5' strand at each transposon end without disturbing the breakage and joining on the 3' strand, producing a fusion (the Shapiro Intermediate) that resulted in replicative transposition. The ability of Tn7 recombination products to serve as substrates for both the limited gap repair required to complete cut-and-paste transposition and the extensive DNA replication involved in cointegrate formation suggests a remarkable plasticity in Tn7's recruitment of host repair and replication functions.

A functional analysis of the inverted repeat of the gamma delta transposable element.

We have constructed a library of point mutants of the 35 base-pair terminal inverted repeat (IR) of the bacterial transposon gamma delta, a member of the Tn3 family of transposable elements. The effect of the mutant ends, both on the immunity conferred on an IR-containing target plasmid and on the transposition of model transposons, was determined. The region important for immunity was shown to be a 30 base-pair stretch of DNA, running from G8 and A9 to G38; mutations in the outermost seven or eight base-pairs did not significantly affect immunity. Positions at which mutations disrupted immunity chiefly coincided with positions previously determined to constitute three segments of the IR with which gamma delta tranposase protein interacts via major groove contacts. We conclude that sequence-specific binding contacts between gamma delta transposase and its cognate IR are limited to a specific subset of positions (those sensitive to mutation in the immunity assay) within this 30 base-pair region. We found that the innermost of the three major groove contact regions was the most susceptible to mutation, while the outermost was the least. Indications of minor groove contacts were also found. Very few point mutations within the 30 base-pair sequence-specific binding region had much effect on transposition when the mutant ends were in the "wild-type" context with the adjacent integration host factor (IHF) binding site. However, deletion of the IHF site, in some cases, revealed a transposition defect, suggesting that for transposition (but not immunity), IHF-transposase cooperation can largely overcome the effects of reduced transposase binding. Although the outer seven base-pairs were not important for immunity, mutations in the outer three or four eliminated or reduced transposition activity, suggesting that these positions are involved in a step in transposition that follows transposase binding.

The Tn7 transposase is a heteromeric complex in which DNA breakage and joining activities are distributed between different gene products.

The bacterial transposon Tn7 translocates by a cut and paste mechanism: excision from the donor site results from double-strand breaks at each end of Tn7 and target insertion results from joining of the exposed 3' Tn7 tips to the target DNA. Through site-directed mutagenesis of the Tn7-encoded transposition proteins TnsA and TnsB, we demonstrate that the Tn7 transposase is a heteromeric complex of these proteins, each protein executing different DNA processing reactions. TnsA mediates DNA cleavage reactions at the 5' ends of Tn7, and TnsB mediates DNA breakage and joining reactions at the 3' ends of Tn7. Thus the double-strand breaks that underlie Tn7 excision result from a collaboration between two active sites, one in TnsA and one in TnsB; the same (or a closely related) active site in TnsB also mediates the subsequent joining of the 3' ends to the target. Both TnsA and TnsB appear to be members of the retroviral integrase superfamily: mutation of their putative DD(35)E motifs blocks catalytic activity. Recombinases of this class require a divalent metal cofactor that is thought to interact with these acidic residues. Through analysis of the metal ion specificity of a TnsA mutant containing a sulfur (cysteine) substitution, we provide evidence that a divalent metal actually interacts with these acidic amino acids.

Unexpected structural diversity in DNA recombination: the restriction endonuclease connection.

Transposition requires a coordinated series of DNA breakage and joining reactions. The Tn7 transposase contains two proteins: TnsA, which carries out DNA breakage at the 5' ends of the transposon, and TnsB, which carries out breakage and joining at the 3' ends of the transposon. TnsB is a member of the retroviral integrase superfamily whose hallmark is a conserved DDE motif. We report here the structure of TnsA at 2.4 A resolution. Surprisingly, the TnsA fold is that of a type II restriction endonuclease. Thus, Tn7 transposition involves a collaboration between polypeptides, one containing a DDE motif and one that does not. This result indicates that the range of biological processes that utilize restriction enzyme-like folds also includes DNA transposition.