Functional Role of YnfA, an Efflux Transporter in Resistance to Antimicrobial Agents in Shigella flexneri.

Shigella flexneri has become a significant public health concern accounting for the majority of shigellosis cases worldwide. Even though a multitude of efforts is being made into the development of a vaccine to prevent infections, the absence of a licensed global vaccine compels us to enormously depend on antibiotics as the major treatment option. The extensive-unregulated use of antibiotics for treatment along with natural selection in bacteria has led to the rising of multidrug-resistance Shigella strains. Out of the various mechanisms employed by bacteria to gain resistance, efflux transporters are considered to be one of the principal contributors to antimicrobial resistance. The small multidrug-resistance family consists of unique small proteins that act as efflux pumps and are involved in extruding various antimicrobial compounds. The present study aims to demonstrate the role of an efflux transporter YnfA belonging to the SMR family and its functional involvement in promoting antimicrobial resistance in S. flexneri. Employing various genetic, computational, and biochemical techniques, we show how disrupting the YnfA transporter, renders the mutant Shigella strain more susceptible to some antimicrobial compounds tested in this study, and significantly affects the overall transport activity of the bacteria against ethidium bromide and acriflavine when compared with the wild-type Shigella strain. We also assessed how mutating some of the conserved amino acid residues of YnfA alters the resistance profile and efflux activity of the mutant YnfA transporter. This study provides a functional understanding of an uncharacterized SMR transporter YnfA of Shigella.

Theoretical analysis of bacterial efflux pumps inhibitors: Strategies in-search of competent molecules and develop next.

Multi-drug resistance (MDR) bacteria pose a significant threat to our ability to effectively treat infections due to the development of several antibiotic resistant mechanisms. A major component in the development of the MDR phenotype in MDR bacteria is over expression of different-type of efflux pumps, which actively pump out antibacterial agents and biocides from the periplasm to the outside of the cell. Consequently, bacterial efflux pumps are an important target for developing novel antibacterial treatments. Potent efflux pump inhibitors (EPIs) could be used as adjunctive therapies that would increase the potency of existing antibiotics and decrease the emergence of MDR bacteria. Several potent inhibitors of efflux pumps have been reported which has been summarized here. All the natural and synthetic EPIs were optimized with Gaussian and Avogadro software. The optimized structures were docked with each class of efflux pumps and their bonding parameters were computed. The theoretical analyses were performed with density functional theory (DFT). Overall, computational study revealed a good trend of electrophilicity and ionization potential of the EPIs, the obtained average values are within in the range of 0.001414 AU ± 0.00032 and 0.208821 AU ± 0.015545, respectively. Interestingly, cathinone interacts with most of the efflux pumps among the tested inhibitors. The electrophilicity and ionization potential of cathinone are 0.00198 and 0.2388 AU, respectively. The study opens a new road for designing future-generation target-specific efflux pump inhibitors, as well as one molecule with multiple inhibition abilities.

AcrAB-TolC Inhibition by Peptide-Conjugated Phosphorodiamidate Morpholino Oligomers Restores Antibiotic Activity in Vitro and in Vivo.

Overexpression of bacterial efflux pumps is a driver of increasing antibiotic resistance in Gram-negative pathogens. The AcrAB-TolC efflux pump has been implicated in resistance to a number of important antibiotic classes including fluoroquinolones, macrolides, and ß-lactams. Antisense technology, such as peptide-conjugated phosphorodiamidate morpholino oligomers (PPMOs), can be utilized to inhibit expression of efflux pumps and restore susceptibility to antibiotics. Targeting of the AcrAB-TolC components with PPMOs revealed a sequence for acrA, which was the most effective at reducing antibiotic efflux. This acrA-PPMO enhances the antimicrobial effects of the levofloxacin and azithromycin in a panel of clinical Enterobacteriaceae strains. Additionally, acrA-PPMO enhanced azithromycin in vivo in a K. pneumoniae septicemia model. PPMOs targeting the homologous resistance-nodulation-division (RND)-efflux system in P. aeruginosa, MexAB-OprM, also enhanced potency to several classes of antibiotics in a panel of strains and in a cell culture infection model. These data suggest that PPMOs can be used as an adjuvant in antibiotic therapy to increase the efficacy or extend the spectrum of useful antibiotics against a variety of Gram-negative infections.

A liposomal method for evaluation of inhibitors of H(+)-coupled multidrug transporters.

INTRODUCTION: This paper describes a novel technique, Fluorosomes, applied to investigating the interaction of antimicrobials with proton driven microbial efflux transporters. These transporters remove toxic compounds from the cytoplasm, including antibiotics and are involved in antibiotic resistance. METHODS: To assess transporter activity we developed a methodology to generate a proton gradient across Fluorosome membranes into which selected purified fully active efflux transporters were reconstituted. The interior of the Fluorosome particle (a unilamellar liposome) contains a fluorescent drug sensing probe whose fluorescence is quantitatively quenched by transporter substrates. Using an injecting fluorescence plate reader to initiate a proton gradient and to monitor subsequent fluorescence change, real time transport kinetics can be followed and transport inhibition characterized. RESULTS: Fluorosomes containing the Escherichia coli EmrE efflux pump demonstrated transport of two known EmrE substrates, ethidium and methyl viologen upon creation of a proton gradient. For Fluorosomes containing the inactive EmrE mutant, E14Q, no transport was observed. When the gradient was fully collapsed by the addition of nigericin, full inhibition of substrate transport was observed. The IC50 for nigericin inhibition of ethidium was shown to be 0.71 µM. DISCUSSION: We have for the first time prepared and validated a single bacterial efflux pump assay, Fluorosome-trans-EmrE, that faithfully mimics properties of the transporter in vivo. It is faster than whole cell screens, simple to use, amenable to robotics, and reports on very specific targets. We have demonstrated proof of principle with EmrE and have created the first of an intended series of proton driven Fluorosomes.