The MSMEG_1586 of M. smegmatis Is a Penicillin-Interactive Enzyme That Can Potentially Hydrolyse Aztreonam and Cephalosporins.

Mycobacteria are intrinsically resistant to beta-lactams as they possess several putative penicillin-interactive enzymes (PIEs), some of those are with dual-activity, namely DD-carboxypeptidase and beta-lactamase. Here, with help of molecular approaches, we elucidated the nature of one such putative PIE, MSMEG_1586, in Mycobacterium smegmatis. The in vivo expression of the membrane-bound form of MSMEG_1586 enhanced the beta-lactam resistance of a beta-lactamase deleted host E. coli strain (AM1OC), particularly for aztreonam (eight-fold) and cephalosporins (8-16 fold). To understand the reason for such elevation of resistance, soluble-form of MSMEG_1586 (sMSMEG_1586) was created by removing signal peptides and partially eliminating the amphipathic helix, and finally, expressed and purified. The purified sMSMEG_1586 was active and manifested a strong penicillin-binding affinity as shown by its ability to bind to fluorescent penicillin (Bocillin-FL). Interestingly, the steady-state kinetics apparently confirmed the hydrolytic ability of sMSMEG_1586 towards cefotaxime and aztreonam where hydrolysing aztreonam is a unique and rare behaviour among the beta-lactamases. However, sMSMEG_1586 was devoid of exerting DD-carboxypeptidase like activity. Finally, in silico analysis of MSMEG_1586 revealed a special folding that resembles class C beta-lactamase, except for the absence of a characteristic R2 loop. Overall, MSMEG_1586 could be categorized as a cephalosporinase with the ability to hydrolyse aztreonam.

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.

Antimicrobial Peptides Designed against the Ω-Loop of Class A ß-Lactamases to Potentiate the Efficacy of ß-Lactam Antibiotics.

Class A serine ß-lactamases (SBLs) have a conserved non-active site structural domain called the omega loop (Ω-loop), in which a glutamic acid residue is believed to be directly involved in the hydrolysis of ß-lactam antibiotics by providing a water molecule during catalysis. We aimed to design and characterise potential pentapeptides to mask the function of the Ω-loop of ß-lactamases and reduce their efficacy, along with potentiating the ß-lactam antibiotics and eventually decreasing ß-lactam resistance. Considering the Ω-loop sequence as a template, a group of pentapeptide models were designed, validated through docking, and synthesised using solid-phase peptide synthesis (SPPS). To check whether the ß-lactamases (BLAs) were inhibited, we expressed specific BLAs (TEM-1 and SHV-14) and evaluated the trans-expression through a broth dilution method and an agar dilution method (HT-SPOTi). To further support our claim, we conducted a kinetic analysis of BLAs with the peptides and employed molecular dynamics (MD) simulations of peptides. The individual presence of six histidine-based peptides (TSHLH, ETHIH, ESRLH, ESHIH, ESRIH, and TYHLH) reduced ß-lactam resistance in the strains harbouring BLAs. Subsequently, we found that the combinational effect of these peptides and ß-lactams sensitised the bacteria towards the ß-lactam drugs. We hypothesize that the antimicrobial peptides obtained might be considered among the novel inhibitors that can be used specifically against the Ω-loop of the ß-lactamases.

Probiotic and Functional Characterization of Pediococcus acidilactici Isolated from Bhaati jaanr, Traditional Fermented Rice Porridge.

Traditional fermented foods are the ideal source of novel probiotic isolates which are known to have significant therapeutic benefits and play a vital role as bioprotective agents. Bhaati jaanr is an ethnic fermented rice beverage popularly consumed in sub-Himalayan regions. The strain UAMS was isolated from Bhaati jaanr based on high butyrate production and evaluated for the potential probiotic characteristics. MALDI-TOF MS and 16 s rRNA gene sequencing revealed the identity of strains as Pediococcus acidilactici. The isolated strain exhibited high tolerance to gastric and bile stress, autoaggregation, hydrophobicity, and adherence to colon cells. Antibiotic susceptibility testing results showed the resistance of the isolated strain toward tested common antibiotics and the pathogenic determinants were absent in PCR-based detection. Moreover, the organism was able to inhibit the growth of Listeria, Salmonella, Staphylococcus, and Enterococcus species. The isolate was found to be a high butyrate producer along with other short-chain fatty acids and exhibited an anti-proliferative effect against colon cancer cells HT29 and SW480. Therefore, our study represents Pediococcus acidilactici UAMS as a potent putative probiotic with bioprotective abilities.

Deciphering the role of residues in the loops nearing the active site of OXA-58 in imparting beta-lactamase activity.

The existence of OXA-58 carbapenemase alone or in combination with other beta-lactam resistance factors poses significant beta-lactam resistance. The exact mechanism of action of OXA type beta-lactamases is debatable due to the involvement of multiple residues within or outside the active site. In the present work, we have elucidated the relative role of residues present in the putative omega (W169, L170, K171) and ß6-ß7 (A226 and D228) loops on the activity of OXA-58 by substituting into alanine (and aspartate for A226) through site-directed mutagenesis. E. coli cells harbouring OXA-58, substituted at the putative omega loop, manifest a significant decrease in the beta-lactam resistance profile than that of the cells expressing OXA-58. Further, a reduction in the catalytic efficiency is observed for the purified variants of OXA-58 carrying individual substitutions in the putative omega loop than that of OXA-58. However, the addition of NaHCO3 (for carbamylation of K86) increases catalytic efficiency of the individual protein as revealed by nitrocefin hydrolysis assay and steady state kinetics. Moreover, W169A and K171A substitutions show significant effects on the thermal stability of OXA-58. Therefore, we conclude that the putative omega loop residues W169, L170 and K171, individually, have significant role in the activity and stability of OXA-58, mostly by stabilising carbamylated lysine of active site.

Comparative insight into the roles of the non active-site residues E169 and N173 in imparting the beta-lactamase activity of CTX-M-15.

CTX-M-15 is a major extended-spectrum beta-lactamase disseminated throughout the globe. The roles of amino acids present in the active-site are widely studied though little is known about the role of the amino acids lying at the close proximity of the CTX-M-15 active-site. Here, by using site-directed mutagenesis we attempted to decipher the role of individual amino acids lying outside the active-site in imparting the beta-lactamase activity of CTX-M-15. Based on the earlier evidence, three amino acid residues namely, Glu169, Asp173 and Arg277 were substituted with alanine. The antibiotic susceptibility of E. coli cells harboring E169A and N173A substituted CTX-M-15 were enhanced by ∼ >32 fold for penicillins and ∼ 4-32 fold for cephalosporins, in comparison to CTX-M-15. However, cells carrying CTX-M-15_R277A did not show a significant difference in antibiotic susceptibility as compared to the wild-type. Further, the catalytic efficiency of the purified CTX-M-15_E169A and CTX-M-15_N173A were compromised when compared with the efficient beta-lactam hydrolysis of purified CTX-M-15. Moreover, the thermal stability of the mutated proteins CTX-M-15_E169A and CTX-M-15_N173A were reduced as compared to the wild type CTX-M-15. Therefore, we conclude that E169 and N173 are crucial non-active-site amino acids that are able to govern the CTX-M-15 activity.

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.

MSMEG_2432 of Mycobacterium smegmatis mc2155 is a dual function enzyme that exhibits DD-carboxypeptidase and ß-lactamase activities.

Mycobacterial peptidoglycan (PG) is an unsolved puzzle due to its complex structure and involvement of multiple enzymes in the process of its remodelling. dd-Carboxypeptidases are low molecular mass penicillin-binding proteins (LMM-PBPs) that catalyzes the cleavage of terminal d-Ala of muramyl pentapeptide branches and thereby helps in the PG remodelling process. Here, we have assigned the function of a putative LMM-PBP, MSMEG_2432 of Mycobacterium smegmatis, by showing that it exhibits both dd-CPase and ß-lactamase activities. Like conventional dd-CPase (PBP5 from E. coli), upon ectopic complementation in a deformed seven PBP deletion mutant of E. coli, MSMEG_2432 has manifested its ability to restore ~75 % of the cell population to their normal rod shape. Further, in vitrodd-CPase assay has confirmed its ability to release terminal d-Ala from the synthetic tripeptide and the peptidoglycan mimetic pentapeptide substrates ending with d-Ala-d-Ala. Also, elevated resistance against penicillins and cephalosporins upon ectopic expression of MSMEG_2432 suggests the presence of ß-lactamase activity, which is further confirmed in vitro through nitrocefin hydrolysis assay. Moreover, it is found apparent that D169A substitution in MSMEG_2432 influences both of its in vivo and in vitrodd-CPase and ß-lactamase activities. Thus, we infer that MSMEG_2432 is a dual function enzyme that possesses both dd-CPase and ß-lactamase activities.

Glutamic acid at position 152 and serine at position 191 are key residues required for the metallo-ß-lactamase activity of NDM-7.

New Delhi metallo-ß-lactamase (NDM) is of significant public-health concern due to its enormous potential to hydrolyse all of the major ß-lactams, including carbapenems. Previous reports indicate that amino acid substitutions affect NDM activity despite being located outside of the active site. In this study, we attempted to identify specific mutations in loops near the active site that can influence the function of NDM-7. Overall, six substitutions were performed through site-directed mutagenesis near the active-site of NDM-7 and the change in antimicrobial resistance was subsequently monitored by expressing each mutant in a suitable bacterial host. Among the six mutants, serine at position 191 (S191) and glutamic acid at position 152 (E152) were identified as the most influencing residues for NDM-7. ß-Lactam resistance of NDM-7 was remarkably affected by substitution of both residues with alanine, and the results were in accordance with the changes in kinetic parameters. Purified NDM-7 ordinarily hydrolyses ß-lactams efficiently, but purified NDM-7_E152A, NDM-7_S191A and the double mutant NDM-7_E152A+S191A had lost their ability to hydrolyse the ß-lactams tested, especially penicillins and carbapenems. Although the substitutions did not affect the overall folding pattern of the NDM-7 enzyme, substantial differences in thermal stability were observed. Therefore, we hypothesise that the residues S191 and E152 together play a crucial role in conferring the ß-lactamase character of NDM-7.

Rapid Fluorescent-Based Detection of New Delhi Metallo-ß-Lactamases by Photo-Cross-Linking Using Conjugates of Azidonaphthalimide and Zinc(II)-Chelating Motifs.

A method for rapid detection of metallo-ß-lactamases NDM-5 and NDM-7 using conjugates of azidonaphthalimide and Zn(II) chelating motifs (like sulfonamides, hydroxamate, and terpyridine) is described. Incubation and irradiation, followed by gel electrophoresis, clearly show the presence of NDMs. The o-sulfonamide-based probe has the highest efficiency of detection for both the NDMs. The proteins are detectable at nM concentrations, and the method is also selective, works both in vitro and in vivo, as revealed by cellular imaging and also with clinical isolates.