Plasmid RK2 toxin protein ParE: purification and interaction with the ParD antitoxin protein

The parDE operon, located within the 3.2-kb stabilization region of plasmid RK2, encodes antitoxin (ParD) and toxin (ParE) proteins that stabilize the maintenance of this broad-host-range plasmid via a postsegregational killing mechanism. A ParE protein derivative, designated ParE', was purified by construction of a fusion protein, GST-ParE, followed by glutathione-agarose binding and cleavage of the fusion protein. ParE' has three additional amino acids on the N terminus and a methionine residue in place of the native leucine residue. The results of glutathione-agarose affinity binding and glutaraldehyde cross-linking indicate that ParE' exists as a dimer in solution and that it binds to the dimeric form of ParD to form a tetrameric complex. The formation of this complex is presumably responsible for the ability of ParD to neutralize ParE toxin activity. Previous studies demonstrated that the parDE operon is autoregulated as a result of the binding of the ParD protein to the parDE promoter. ParE' also binds to the parDE promoter but only in the presence of the autoregulatory ParD protein. ParE', in the presence or absence of the ParD protein, does not bind to any other part of the 3.2-kb stabilization region. The binding of the ParE' protein to ParD did not alter the DNase I footprint pattern obtained as a result of ParD binding to the parDE promoter. The role of ParE in binding along with ParD to the promoter, if any, remains unclear.

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