Although numerous antibiotics for RTIs have been discovered thus far, most of them target the same or functionally similar molecules essential for the growth of bacteria. As

antibiotic resistance in bacteria, such as multidrug-resistant Streptococcus pneumoniae and β-lactamase-negative, ampicillin-resistant Haemophilus influenzae (BLNAR), is an emerging threat, especially to immunocompromised patients, there is check details an unmet medical need to provide antibiotics with novel modes of action for reducing the infections caused by such bacteria. To characterize the mode of action in drug-mediated bactericidal activity, it is important and valuable to confirm that loss of expression and/or function of the drug-targeted bacterial molecule induces bactericidal profiles. To evaluate such target gene profiles, several assay systems have been developed in Mycobacterium, such as antisense technology using IPTG inducible antisense expression (Kaur et al., 2009) and an inducible protein degradation system using selleck inhibitor Clp protease systems (Wei et al., 2011). However, to date, no such approach has been applied in Escherichia coli known as a model organism. In E. coli, Ptrp is a conditional promoter that is negatively regulated by the TrpR repressor protein. Repression of

the Ptrp promoter is relieved by switching to a low-tryptophan medium and the addition of indole acrylic Cyclooxygenase (COX) acid (IAA). IAA binds to the same Trp

repressor protein at the same site as tryptophan and prevents it from binding to Ptrp (Chevalet et al., 2000). The N-end rule describes the protein degradation system of E. coli and states that the nature of the N-terminal amino acids of a protein is an important factor in its half-life: methionine aminopeptidase cleaves off NH2-terminal methionine from target proteins in some conditions. When the target protein exposes a residual phenylalanine (Phe) at the NH2-terminus, an endogenous ClpAP protease further degrades the target protein. This NH2-terminal amino acid-dependent degradation process is quickly completed (t1/2: < 2 min) against endogenous cytoplasmic proteins and inner membrane proteins (Tobias et al., 1991; Varshavsky, 1996; Link et al., 1997a). In previous research, aimed at exposing a destabilizing N-terminal residue of a protein called the N-degron, a eukaryotic ubiquitin system was used. Namely, target molecules were genetically fused to the COOH terminus of Ubi4, a ubiquitin derived from Saccharomyces cerevisiae, with spacer amino acid followed by the N-degron sequence. The NH2-terminal ubiquitin of the fusion molecule is specifically cleaved off by ubiquitin protease, UBP1 (Tobias & Varshavsky, 1991). In this study, we constructed E.