Substrate recognition and induced DNA deformation by transposase at the target-capture stage of Tn10 transposition

Abstract

The bacterial transposon Tn 10 inserts preferentially into sites that conform to a 9 bp consensus sequence: 5′ NGCTNAGCN 3′. However, this sequence is not on its own sufficient to confer target specificity as the base-pairs flanking this sequence also contribute significantly to target-site selection. We have performed a series of “contact-probing experiments” to define directly the protein-DNA interactions that govern target-site selection in the Tn 10 system. The HisG1 hotspot for Tn 10 insertion was the main focus here. We infer that there is a rather broad zone (∼24 bp) of contact between transposase and target DNA in the target-capture complex. This includes base-specific contacts at all of the purine residues in the consensus positions of the target core and primarily backbone contacts out to 7–8 bp in the two flanking regions immediately adjacent to the core. Also, highly localized sites of chemical hypersensitivity are identified that reveal symmetrically disposed deformations in DNA structure in the target-capture complex. Furthermore, the level of strand transfer is shown to be reduced by phosphorothioate substitution of phosphate groups at or close to the sites of target DNA deformation. Interestingly, for one particular target DNA, a mutant form of HisG1 called MutF, the above phosphorothioate inhibition of strand transfer is suppressed by replacing Mg 2+ with Mn 2+. Based on these results a model for sequence-specific target capture is proposed which attempts to define possible relationships between transposase interactions with the target core and flanking sequences, transposase-induced DNA deformation of the target site and divalent metal ion binding to the target-capture complex.