Such plasmids can be selected and propagated in bacterial host strains that contain a corresponding chromosomal deletion or suppressible mutation of the essential gene [10]. In these plasmid systems,

antibiotic resistance markers can be circumvented and plasmid sizes are often very small. For example, Porter et al., have developed genetically engineered bacteria by deleting the essential single-strand binding protein (SSB) gene responsible for click here replication of the Escherichia coli chromosome and its single-stranded DNA phage, and instead complementing the ssb gene on a plasmid [42]. Plasmidless bacteria do not accumulate even after culture under non-selective condition. In fact, by using plasmid-displacement technique, other ssb-containing plasmids can be readily introduced into this E. coli strain. As another example, the pCOR vector has been totally redesigned to increase biosafety in terms of dissemination and selection during therapy and production

[25]. The pCOR vector backbone consists of R6Kγ conditional origin which requires cis or trans-acting R6Kπ initiator protein to be functional. This plasmid can only replicate in π-producing Tyrosine Kinase Inhibitor Library manufacturer bacteria which restrictive their production host range. Instead of harboring antibiotic resistance gene, a bacterial suppressor tRNA has been used as selectable marker to suppress a host chromosomal argE gene mutation, allowing for growth in minimal media lacking arginine. However, additional genes are required to be placed on plasmid in this system. In this system, the repressor titration was manipulated and affects a plasmid

selection pressure [10]. A multicopy plasmid containing the same operator sequence was used to derepresses a negatively-regulated chromosomal operator/promoter system controlling a conditionally essential gene. Under normal conditions, Carnitine dehydrogenase a repressor protein binds to the chromosomal operator and prevents transcription. The repressor is released when it binds to its inducer, which is often the substrate of the gene under control. Conversely, the present of molar excess operator sequence on a multicopy plasmid will titrate the repressor from the chromosomal operator which allows transcription to take place. For example, Cranenburgh et al. have constructed two novel E. coli strains (DH1lacdapD and DH1lacP2dapD) containing an ectopic copy of a dapD essential chromosomal gene, where expression driven under the control of the lac operator/promoter [43]. Three copies of the operator on the plasmid titrate the lac repressor, allowing expression of the dapD gene. However, dapD expression is inhibited and the E. coli cell dies in the absence of the multicopy plasmid. The advantage of such system is small size plasmid and elimination of antibiotic resistance gene. Another system that employs plasmid-mediated repressor titration was described in which the recombinant plasmid contained lacO while the host genome contained a kanamycin resistance gene under the control of the lacO promoter [44].