The art of selective killing: plasmid toxin/antitoxin systems and their technological applications.

Most bacterial strains harbor plasmids that are maintained with remarkable stability. A large variety of plasmids encode systems that act when other control mechanisms have failed, i.e., when plasmid-free progeny is generated during replication. The mechanisms that control plasmid maintenance by T/A loci are well known: the antagonistic regulators that neutralize the toxins are metabolically unstable. Rapid depletion of these unstable regulators occurs in newborn, plasmid-free cells. As the same cells have inherited stable toxin molecules from the mother cell, the toxin will no longer be neutralized by the antitoxin, leading to the killing of the plasmid-free cells. This mechanism effectively reduces the proliferation of plasmid-free cells in growing bacterial populations (1). The most widely studied T/A system so far is the ccd system located on the F plasmid (2). The ccd system is composed of two genes, ccdA and ccdB, encoding small proteins: the CcdA antidote (8.7 kDa) and the CcdB toxin (11.7 kDa). The CcdB protein acts as a poison because it selectively targets the Escherichia coli DNA gyrase, a bacterial topoisomerase II. Early studies of this T/A system were performed at the Université Libre de Bruxelles (ULB). Today new applications are commercialized by Delphi Genetics SA, a spin off company of the ULB founded by the researchers who developed the use of T/A systems as selectable markers. POSITIVE SELECTION VECTORS