ABC superfamily transporter Rv1273c of Mycobacterium tuberculosis acts as a multidrug efflux pump.

Efflux pump-mediated drug resistance in bacteria is a common occurrence effective for the general survival of the organism. The Mycobacterium tuberculosis genome has an abundance of adenosine triphosphate (ATP) dependent cassette transporter genes but only a handful of them are documented for their contribution to drug resistance. In this study, we inspected the potential of an ABC transporter Rv1273c from M. tuberculosis as a multidrug efflux pump and a contributor to intrinsic drug resistance. Expression of Rv1273c in Escherichia coli and M. smegmatis conferred tolerance to various structurally unrelated antibiotics. Lower accumulation of fluoroquinolones in intact E. coli and M. smegmatis cells expressing the transporter implied its active efflux activity. Energy-dependent efflux by Rv1273c was observed in real time using the lipophilic dye Nile Red. Expression of Rv1273c also resulted in an increase in biofilm formation by E. coli and M. smegmatis cells. Overall, the results indicate the possibility that Rv1273c might be a multidrug transporter with a wide substrate range and a probable contributor to biofilm formation.

Involvement of the non-active site Residues in the Catalytic Activity of NDM-4 Metallo beta-lactamase.

The rise of New Delhi metallo beta-lactamase (NDM) producing bacteria imposes a significant threat to the treatment of bacterial infections due to their broad spectrum against beta-lactams. The activity of metallo beta-lactamases is affected by active site residues as well as residues near the active site. Therefore, we aimed to identify the amino acid residues around the active site of NDM-4 which influence its function. To achieve that, seven substitution mutations (S191A, D192A, S213A, K216A, S217A, D223A and D225A) of NDM-4 were generated through site-directed mutagenesis. Out of these, expression of NDM-4_D192A and NDM-4_S217A in Escherichia coli cells increased the beta-lactam susceptibility as compared to NDM-4. Further, proteins were purified to assess the effect of substitution mutations on zinc content, in vitro catalytic efficiency, and stability of NDM-4. The catalytic efficiency was reduced for these mutants (D192A and S217A) towards beta-lactam substrates, while the thermal stability remained insubstantial as compared to NDM-4. However, the purified NDM-4_D192A exhibited altered zinc content. In silico studies reveal that these changes might be the outcomes of alterations in hydrogen bonding networks and substrate interactions. Taken together, we infer that the D192 and the S217 residues play a substantial role in the activity of NDM-4.

Two non-active site residues W165 and L166 prominently influence the beta-lactam hydrolytic ability of OXA-23 beta-lactamase.

Dissemination of class D OXA-type carbapenemases is one of the significant causes of beta-lactam resistance in Gram-negative bacteria. The amino acid residues present near the active site are involved in hydrolytic mechanism of class D carbapenemases, though it is not identified in OXA-23. Here, with the help of site-directed mutagenesis, we aimed to explicate the importance of the residues W165, L166 and V167 of the possible omega loop and residue D222 in the short ß5-ß6 loop on the activity of OXA-23. All the residues were substituted with alanine. The resultant proteins were assayed for the changes in activity in E. coli cells and purified for in vitro activity, and stability assessment. E. coli cells harboring OXA-23_W165A and OXA-23_L166A, individually, exhibited a significant decrease in resistance towards beta-lactam antibiotics as compared to OXA-23. Further, purified OXA-23_W165A and OXA-23_L166A imparted about >4-fold decrease in catalytic efficiency and displayed reduced thermal stability as compared to OXA-23. Bocillin-FL binding assay revealed that W165A substitution results in improper N-carboxylation of K82, leading to deacylation deficient OXA-23. Therefore, we infer that the residue W165 maintains the integrity of N-carboxylated lysine (K82) of OXA-23 and the residue L166 might be responsible for properly orientating the antibiotic molecules.

The Putative Major Facilitator Superfamily (MFS) Protein Named Rv1877 in Mycobacterium tuberculosis Behaves as a Multidrug Efflux Pump.

Efflux pumps are one of the major contributors in the intrinsic multidrug resistance of Mycobacterium tuberculosis. These active transporters, localized in the cytoplasmic membrane, often carry an array of unrelated substances, from toxic substances to metabolites and maintain cellular homeostasis. Rv1877, a putative Major Facilitator Superfamily efflux pump from M. tuberculosis, was investigated in this study. Expression of Rv1877 in Escherichia coli resulted in elevated resistance towards antibiotics of various families. A reversal of this resistance was observed in the presence of sub-inhibitory concentration of the uncoupler carbonyl cyanide-m-chlorophenylhydrazone, indicating its dependence on proton motive force (pmf). Lower intracellular accumulation of the fluoroquinolones ofloxacin and levofloxacin in E. coli cells harbouring Rv1877 implied an active efflux of the drugs. Interestingly, real time, energy-dependent efflux was demonstrated by cells expressing Rv1877 with a lipophilic dye Nile Red. In addition, expression of Rv1877 in trans increased the biofilm formation by the host E. coli cells. Moreover, in silico docking analysis of the molecular interactions between Rv1877 and antibiotics corroborated the experimental observations. Based on the in vivo analyses of Rv1877 in E. coli, it could be designated as a pmf-dependent multidrug transporter with the ability of extruding structurally unrelated antibiotics, preferably some of the fluoroquinolones, and a facilitator of biofilm formation.

Role of AmpC-Inducing Genes in Modulating Other Serine Beta-Lactamases in Escherichia coli.

The consistently mutating bacterial genotypes appear to have accelerated the global challenge with antimicrobial resistance (AMR); it is therefore timely to investigate certain less-explored fields of targeting AMR mechanisms in bacterial pathogens. One of such areas is beta-lactamase (BLA) induction that can provide us with a collection of prospective therapeutic targets. The key genes (ampD, ampE and ampG) to which the AmpC induction mechanism is linked are also involved in regulating the production of fragmented muropeptides generated during cell-wall peptidoglycan recycling. Although the involvement of these genes in inducing class C BLAs is apparent, their effect on serine beta-lactamase (serine-BLA) induction is little known. Here, by using ∆ampD and ∆ampE mutants of E. coli, we attempted to elucidate the effects of ampD and ampE on the expression of serine-BLAs originating from Enterobacteriaceae, viz., CTX-M-15, TEM-1 and OXA-2. Results show that cefotaxime is the preferred inducer for CTX-M-15 and amoxicillin for TEM-1, whereas oxacillin for OXA-2. Surprisingly, exogenous BLA expressions are elevated in ∆ampD and ∆ampE mutants but do not always alter their beta-lactam susceptibility. Moreover, the beta-lactam resistance is increased upon in trans expression of ampD, whereas the same is decreased upon ampE expression, indicating a differential effect of ampD and ampE overexpression. In a nutshell, depending on the BLA, AmpD amidase moderately facilitates a varying level of serine-BLA expression whereas AmpE transporter acts likely as a negative regulator of serine-BLA.

Effect of single-dose carbapenem exposure on transcriptional expression of blaNDM-1 and mexA in Pseudomonas aeruginosa.

The therapeutic option of a carbapenem antibiotic is compromised in Pseudomonas aeruginosa owing both to acquired and intrinsic resistance mechanisms. In recent years, New Delhi metallo-ß-lactamase has been the focus as a predominant carbapenem resistance determinant. However, it is unclear which of the mechanisms might be adopted by a P. aeruginosa strain possessing both blaNDM-1 and an overexpressed MexAB-OprM system during carbapenem therapy. This study investigated the interplay of both mechanisms in clinical isolates of P. aeruginosa when exposed to meropenem. Five strains were used: (i) strain overexpressing MexAB-OprM but with no blaNDM-1; (ii) strain harbouring blaNDM-1 but expressing MexAB-OprM at basal level; (iii) strain possessing blaNDM-1 and overexpressing MexAB-OprM; (iv) P. aeruginosa PAO1; and (v) P. aeruginosa K2733-PAO1 (ΔMexAB-OprMΔMexCD-OprJΔMexEF-OprNΔMexXY-OprM) into which blaNDM-1 was cloned. Strains were incubated in Luria-Bertani broth with and without 1µg/mL meropenem. Total RNA was isolated at 45-min intervals and was immediately reverse transcribed to cDNA. This was repeated for 6h. Quantitative real-time PCR was performed for both resistance mechanisms. Meropenem exposure did not significantly elevate transcription of either the blaNDM-1 or mexA gene. However, an interesting finding was that upon single-dose exposure to carbapenem, the efflux pump system played a major role in bacterial survival compared with NDM-1. This study gives an insight into the bacterial response to carbapenem antibiotic when two different resistance mechanisms coexist. This type of study would be helpful in designing future antimicrobials.