Protein TrwC is the conjugative relaxase responsible for DNA processing in plasmid R388 bacterial conjugation. TrwC has two catalytic tyrosines, Y18 and Y26, both able to carry out cleavage reactions using unmodified oligonucleotide substrates. Suicide substrates containing a 3 0 -Sphosphorothiolate linkage at the cleavage site displaced TrwC reaction towards covalent adducts and thereby enabled intermediate steps in relaxase reactions to be investigated. Two distinct covalent TrwC-oligonucleotide complexes could be separated from noncovalently bound protein by SDS-PAGE. As observed by mass spectrometry, one complex contained a single, cleaved oligonucleotide bound to Y18, whereas the other contained two cleaved oligonucleotides, bound to Y18 and Y26. Analysis of the cleavage reaction using suicide substrates and Y18F or Y26F mutants showed that efficient Y26 cleavage only occurs after Y18 cleavage. Strand-transfer reactions carried out with the isolated Y18-DNA complex allowed the assignment of specific roles to each tyrosine. Thus, only Y18 was used for initiation. Y26 was specifically used in the second transesterification that leads to strand transfer, thus catalyzing the termination reaction that occurs in the recipient cell.
SummaryHorizontal transfer of antibiotic resistance genes carried by conjugative plasmids poses a serious health problem. As conjugative relaxases are transported to recipient cells during bacterial conjugation, we investigated whether blocking relaxase activity in the recipient cell might inhibit conjugation. For that purpose, we used an intrabody approach generating a single-chain Fv antibody library against the relaxase TrwC of conjugative plasmid R388. Recombinant single-chain Fv antibodies were engineered for cytoplasmic expression in Escherichia coli cells and either selected in vitro for their specific binding to TrwC, or in vivo by their ability to interfere with conjugation using a high-throughput mating assay. Several intrabody clones were identified showing specific inhibition against R388 conjugation upon cytoplasmic expression in the recipient cell. The epitope recognized by one of these intrabodies was mapped to a region of TrwC containing Tyr-26 and involved in the conjugative DNA-processing termination reaction. These findings demonstrate that the transferred relaxase plays an important role in the recipient cell and open a new approach to identify specific inhibitors of bacterial conjugation.
TrwC, the relaxase of plasmid R388, catalyzes a series of concerted DNA cleavage and strand transfer reactions on a specific site (nic) of its origin of transfer (oriT). nic contains the cleavage site and an adjacent inverted repeat (IR 2 ). Mutation analysis in the nic region indicated that recognition of the IR 2 proximal arm and the nucleotides located between IR 2 and the cleavage site were essential for supercoiled DNA processing, as judged either by in vitro nic cleavage or by mobilization of a plasmid containing oriT. Formation of the IR 2 cruciform and recognition of the distal IR 2 arm and loop were not necessary for these reactions to take place. On the other hand, IR 2 was not involved in TrwC single-stranded DNA processing in vitro. For single-stranded DNA nic cleavage, TrwC recognized a sequence embracing six nucleotides upstream of the cleavage site and two nucleotides downstream. This suggests that TrwC DNA binding and cleavage are two distinguishable steps in conjugative DNA processing and that different sequence elements are recognized by TrwC in each step. IR 2 -proximal arm recognition was crucial for the initial supercoiled DNA binding. Subsequent recognition of the adjacent single-stranded DNA binding site was required to position the cleavage site in the active center of the protein so that the nic cleavage reaction could take place.Bacterial conjugation is an efficient and sophisticated DNA transport mechanism, genetically encoded by self-transmissible plasmids. The transfer of DNA by bacterial conjugation plays an important role in the genetic variability of bacteria as well as in the propagation of antibiotic resistance and virulence factors (1). In order to avoid the spread of antibiotic resistance genes via bacterial conjugation, one promising strategy is the use of anti-conjugation-based antimicrobial agents (2, 3). Our group identified unsaturated fatty acids as conjugation inhibitors (4). Their target is unknown, although membrane-associated ATPases could be good candidates. Because the relaxase is the key catalytic enzyme in the conjugative process, it is, a priori, a better target for a specific inhibitor. Potts et al. (5) found that bisphosphonates inhibited the activity of plasmid F relaxase TraI. Their effect on conjugation inhibition was small, although, surprisingly, they could specifically kill relaxase-containing cells. Moreover, bacterial relaxases might find a use as tools for site-specific DNA delivery to target eukaryotic cells for gene therapy (6). Thus, a detailed study of the specificity determinants of the reaction performed by relaxases could lead to the a la carte design of relaxases able to act on any potentially interesting sequence (7).Conjugative DNA processing is carried out by the relaxosome, composed by the enzyme relaxase and auxiliary proteins that act on the oriT region (see Ref. 8 for a review). It starts by a site-and strand-specific DNA cleavage reaction that occurs at a specific oriT site called nic. The nic cleavage reaction is mediated by a tyrosin...
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