Discovery of environment-sensitive fluorescent probes for detecting and inhibiting metallo-ß-lactamase.

Metallo-ß-lactamases (MßLs) hydrolyze almost all ß-lactam antibiotics, including last-resort carbapenems, and is emerging as a global antibiotic resistance threat. Discovering novel fluorescent molecules for visualizing MßLs has proved challenging. Herein, based on covalent and Zn(II)-binding scaffold of MßLs inhibitor, we designed and synthesized a novel series of environment-sensitive fluorescent probes ESA, DHA and DHS, to detect and inhibit the enzymatic activity of MßLs. Of these probes, ESA is a highly active NDM-1 inhibitor (IC50 = 81 nM), which exhibited excellent turn-on fluorescent properties to effectively distinguish NDM-1 (B1), ImiS (B2) and L1 (B3) in vitro. Cell imaging indicated that ESA can label and track the distribution process of the intracellular protein NDM-1 in living cells. Molecular docking further elucidated the environment-sensitive fluorescent response nature of ESA to the NDM-1. Significantly, ESA showed excellent synergistic antibacterial effect, combined with meropenem, to overcome NDM-1-mediated drug-resistant pathogens.

Dithiocarbamates combined with copper for revitalizing meropenem efficacy against NDM-1-producing Carbapenem-resistant Enterobacteriaceae.

The worldwide prevalence of NDM-1-producing Gram-negative pathogens has drastically undermined the clinical efficacy of carbapenems, prompting a need to devise an effective strategy to preserve their clinical value. Here we constructed a focused compound library of dithiocarbamates and systematically evaluated their potential synergistic antibacterial activities combined with copper. SA09-Cu exhibited excellent inhibition against a series of clinical NDM-1-producing carbapenem-resistant Enterobacteriaceae (CRE) in restoring meropenem effect, and slowed down the development of carbapenem resistance. Enzymatic kinetic and isothermal titration calorimetry studies demonstrated that SA09-Cu was a noncompetitive NDM-1 inhibitor. The electron paramagnetic resonance (EPR) and X-ray photoelectron spectroscopy (XPS) revealed a novel inhibition mechanism, which is that SA09-Cu could convert NDM-1 into an inactive state by oxidizing the Zn(II)-thiolate site of the enzyme. Importantly, SA09-Cu showed a unique redox tuning ability, and avoided to be reduced by intracellular thiols of bacteria. In vivo experiments indicated that SA09 combined with CuGlu could effectively potentiate MER's effect against NDM-1-producing E. coli (EC23) in the murine infection model. This study provides a highly promising scaffold in developing novel inhibitors to combat NDM-1-producing CREs.

Quinolinyl sulfonamides and sulphonyl esters exhibit inhibitory efficacy against New Delhi metallo-ß-lactamase-1 (NDM-1).

The "superbug" infection caused by metallo-ß-lactamases (MßLs) has grown into anemergent health threat, and development of effective MßL inhibitors to restore existing antibiotic efficacy is an ideal alternative. Although the serine-ß-lactamase inhibitors have been used in clinical settings, MßL inhibitors are not available to date. In this work, thirty-one quinolinyl sulfonamides 1a-p and sulphonyl esters 2a-o were synthesized and assayed against MßL NDM-1. The obtained molecules specifically inhibited NDM-1, 1a-p and 2a-o exhibited an IC50 value in the range of 0.02-1.4 and 8.3-24.8 µM, respectively, and 1e and 1f were found to be the most potent inhibitors, with an IC50 of 0.02 µM using meropenem (MER) as substrate. Structure-activity relationship reveals that the substitute phenyl and the phenyl with a halogen atom more significantly improve inhibitory effect of quinolinederivatives on NDM-1. 1a-p restored antimicrobial effect of MER on E. coli with NDM-1, EC01 and EC08, resulting in a 2-64-fold reduction in MIC values. Most importantly, 1e synergized MER and significantly reduced the load of EC08 in the spleen and liver of mice after a single intraperitoneal dose. Docking studies suggested that the endocyclic nitrogen of the quinoline ring, and exocyclic nitrogen of the sulfonamide functional group are coordinate with Zn(II) ion at active sites of NDM-1. Cytotoxicity assays indicated that 1e had low cytotoxicity. This work offers potential lead compounds for further development of the clinically useful inhibitor targeting NDM-1.

Aromatic Schiff bases confer inhibitory efficacy against New Delhi metallo-ß-lactamase-1 (NDM-1).

The irregular use of antibiotics has created a natural selection pressure for bacteria to adapt resistance. Bacterial resistance caused by metallo-ß-lactamases (MßLs) has been the most prevalent in terms of posing a threat to human health. The New Delhi metallo-ß-lactamase-1 (NDM-1) has been shown to be capable of hydrolyzing almost all ß-lactams. In this work, eight aromatic Schiff bases 1-8 were prepared and identified by enzyme kinetic assays to be the potent inhibitors of NDM-1 (except 4). These molecules exhibited a more than 95 % inhibition, and an IC50 value in the range of 0.13-19 µM on the target enzyme, and 3 was found to be the most effective inhibitor (IC50 = 130 nM). Analysis of structure-activity relationship revealed that the o-hydroxy phenyl improved the inhibitory activity of Schiff bases on NDM-1. The inhibition mode assays including isothermal titration calorimetry (ITC) disclosed that both compounds 3 and 5 exhibited a reversibly mixed inhibition on NDM-1, with a Ki value of 1.9 and 10.8 µM, respectively. Antibacterial activity tests indicated that a dose of 64 µg·mL-1 Schiff bases resulted in 2-128-fold reduction in MICs of cefazolin on E. coli producing NDM-1 (except 4). Cytotoxicity assays showed that both Schiff bases 3 and 5 have low cytotoxicity on the mouse fibroblast (L929) cells at a concentration of up to 400 µM. Docking studies suggested that the hydroxyl group interacts with Gln123 and Glu152 of NDM-1, and the amino groups interact with the backbone amide groups of Glu152 and Asp223. This study provided a novel scaffold for the development of NDM-1 inhibitors.

Hydroxamate and thiosemicarbazone: Two highly promising scaffolds for the development of SARS-CoV-2 antivirals.

The emerging COVID-19 pandemic generated by Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) has severely threatened human health. The main protease (Mpro) of SARS-CoV-2 is promising target for antiviral drugs, which plays a vital role for viral duplication. Development of the inhibitor against Mpro is an ideal strategy to combat COVID-19. In this work, twenty-three hydroxamates 1a-i and thiosemicarbazones 2a-n were identified by FRET screening to be the potent inhibitors of Mpro, which exhibited more than 94% (except 1c) and more than 69% inhibition, and an IC50 value in the range of 0.12-31.51 and 2.43-34.22 µM, respectively. 1a and 2b were found to be the most effective inhibitors in the hydroxamates and thiosemicarbazones, with an IC50 of 0.12 and 2.43 µM, respectively. Enzyme kinetics, jump dilution and thermal shift assays revealed that 2b is a competitive inhibitor of Mpro, while 1a is a time-dependently inhibitor; 2b reversibly but 1a irreversibly bound to the target; the binding of 2b increased but 1a decreased stability of the target, and DTT assays indicate that 1a is the promiscuous cysteine protease inhibitor. Cytotoxicity assays showed that 1a has low, but 2b has certain cytotoxicity on the mouse fibroblast cells (L929). Docking studies revealed that the benzyloxycarbonyl carbon of 1a formed thioester with Cys145, while the phenolic hydroxyl oxygen of 2b formed H-bonds with Cys145 and Asn142. This work provided two promising scaffolds for the development of Mpro inhibitors to combat COVID-19.

Dihydroxyphenyl-substituted thiosemicarbazone: A potent scaffold for the development of metallo-ß-lactamases inhibitors and antimicrobial.

The superbug infection mediated by metallo-ß-lactamases (MßLs) has grown into anemergent health threat, and development of MßL inhibitors is an ideal strategy to combat the infection. In this work, twenty-five thiosemicarbazones 1a-e, 2a-e, 3a-e, 4a-d, 5a-d and 6a-b were synthesized and assayed against MßLs ImiS, NDM-1 and L1. The gained molecules specifically inhibited NDM-1 and ImiS, exhibiting an IC50 value in the range of 0.37-21.35 and 0.45-8.76 µM, and 2a was found to be the best inhibitor, with an IC50 of 0.37 and 0.45 µM, respectively, using meropenem (MER) as substrate. Enzyme kinetics and dialysis tests revealed and confirmed by ITC that 2a is a time-and dose-dependent inhibitor of ImiS and NDM-1, it competitively and reversibly inhibited ImiS with a Ki value of 0.29 µM, but irreversibly inhibited NDM-1. Structure-activity relationship disclosed that the substitute dihydroxylbenzene significantly enhanced inhibitory activity of thiosemicarbazones on ImiS and NDM-1. Most importantly, 1a-e, 2a-e and 3a-b alone more strongly sterilized E. coli-ImiS and E. coli-NDM-1 than the MER, displaying a MIC value in the range of 8-128 µg/mL, and 2a was found to be the best reagent with a MIC of 8 and 32 µg/mL. Also, 2a alone strongly sterilized the clinical isolates EC01, EC06-EC08, EC24 and K. pneumonia-KPC-NDM, showing a MIC value in the range of 16-128 µg/mL, and exhibited synergistic inhibition with MER on these bacteria tested, resulting in 8-32-fold reduction in MIC of MER. SEM images shown that the bacteria E. coli-ImiS, E. coli-NDM-1, EC24, K. pneumonia-KPC and K. pneumonia-KPC-NDM treated with 2a (64 µg/mL) suffered from distortion, emerging adhesion between individual cells and crumpled membranes. Mice tests shown that monotherapy of 2a evidently limited growth of EC24 cells, and in combination with MER, it significantly reduced the bacterial load in liver and spleen. Docking studies suggest that the 2,4-dihydroxylbenzene of 2a acts as zinc-binding group with the Zn(II) and the residual amino acids in CphA active center, tightly anchoring the inhibitor at active site. This work offered a promising scaffold for the development of MßLs inhibitors, specifically the antimicrobial for clinically drug-resistant isolates.

A Modified Vancomycin Molecule Confers Potent Inhibitory Efficacy against Resistant Bacteria Mediated by Metallo-ß-Lactamases.

Multidrug-resistant bacterial infections mediated by metallo-ß-lactamases (MßLs) have grown into an emergent health threat, and development of novel antimicrobials is an ideal strategy to combat the infections. Herein, a novel vancomycin derivative Vb was constructed by conjugation of triazolylthioacetamide and vancomycin molecules, characterized by reverse-phase high performance liquid chromatography (HPLC) and confirmed by matrix-assisted laser desorption/ionization-time of flight mass spectrometry (MALDI-TOF MS). The biological assays revealed that Vb effectively inhibited S. aureus and methicillin-resistant S. aureus (MRSA), gradually increased the antimicrobial effect of ß-lactam antibiotics (cefazolin, meropenem and penicillin G) and exhibited a dose-dependent synergistic antibacterial effect against eight resistant strains tested, which was confirmed by the time-kill curves determination. Most importantly, Vb increased the antimicrobial effect of meropenem against the clinical isolates EC08 and EC10 and E. coli producing ImiS and CcrA, resulting in a 4- and 8-fold reduction in MIC values, respectively, at a dose up to 32 µg/mL. This work offers a promising scaffold for the development of MßLs inhibitors, specifically antimicrobials for clinically drug-resistant isolates.

Dipyridyl-substituted thiosemicarbazone as a potent broad-spectrum inhibitor of metallo-ß-lactamases.

To combat the superbug infection caused by metallo-ß-lactamases (MßLs), a dipyridyl-substituted thiosemicarbazone (DpC), was identified to be the broad-spectrum inhibitor of MßLs (NDM-1, VIM-2, IMP-1, ImiS, L1), with an IC50 value in the range of 0.021-1.08 µM. It reversibly and competitively inhibited NDM-1 with a Ki value of 10.2 nM. DpC showed broad-spectrum antibacterial effect on clinical isolate K. pneumonia, CRE, VRE, CRPA and MRSA, with MIC value ranged from 16 to 32 µg/mL, and exhibited synergistic antibacterial effect with meropenem on MßLs-producing bacteria, resulting in a 2-16-, 2-8-, and 8-fold reduction in MIC of meropenem against EC-MßLs, EC01-EC24, K. pneumonia, respectively. Moreover, mice experiments showed that DpC also had synergistic antibacterial action with meropenem. In this work, DpC was identified to be a potent scaffold for the development of broad-spectrum inhibitors of MßLs.

Diaryl-substituted thiosemicarbazone: A potent scaffold for the development of New Delhi metallo-ß-lactamase-1 inhibitors.

The superbug infection caused by New Delhi metallo-ß-lactamase (NDM-1) has become an emerging public health threat. Inhibition of NDM-1 has proven challenging due to its shuttling between pathogenic bacteria. A potent scaffold, diaryl-substituted thiosemicarbazone, was constructed and assayed with metallo-ß-lactamases (MßLs). The obtained twenty-six molecules specifically inhibited NDM-1 with IC50 0.038-34.7 µM range (except 1e, 2e, and 3d), and 1c is the most potent inhibitor (IC50 = 0.038 µM). The structure-activity relationship of synthetic thiosemicarbazones revealed that the diaryl-substitutes, specifically 2-pyridine and 2-hydroxylbenzene improved inhibitory activities of the inhibitors. The thiosemicarbazones exhibited synergistic antimycobacterial actions against E. coli-NDM-1, resulted a 2-512-fold reduction in MIC of meropenem, while 1c restored 16-256-, 16-, and 2-fold activity of the antibiotic on clinical isolates ECs, K. pneumonia and P. aeruginosa harboring NDM-1, respectively. Also, mice experiments showed that 1c had a synergistic antibacterial ability with meropenem, reduced the bacterial load clinical isolate EC08 in the spleen and liver. This work provided a highly promising scaffold for the development of NDM-1 inhibitors.

N-acylhydrazones confer inhibitory efficacy against New Delhi metallo-ß-lactamase-1.

The expression of ß-lactamases, especially metallo-ß-lactamases (MßLs) in bacteria is one of the main causes of drug resistance. In this work, an effective N-acylhydrazone scaffold as MßL inhibitor was constructed and characterized. The biological activity assays indicated that the synthesized N-acylhydrazones 1-11 preferentially inhibited MßL NDM-1, and 1 was found to be the most effective inhibitor with an IC50 of 1.2 µM. Analysis of IC50 data revealed a structure-activity relationship, which is that the pyridine and hydroxylbenzene substituents at 2-position improved inhibition of the compounds on NDM-1. ITC and enzyme kinetics assays suggested that it reversibly and competitively inhibited NDM-1 (Ki = 0.29 ± 0.05 µM). The synthesized N-acylhydrazones showed synergistic antibacterial activities with meropenem, reduced 4-16-fold MIC of meropenem on NDM-1- producing E. coli BL21 (DE3), while 1 restored 4-fold activity of meropenem on K. pneumonia expressing NDM-1 (NDM-K. pneumoniae). The mice experiments suggested that 1 combined meropenem to fight against NDM-K. pneumoniae infection in the spleen and liver. Cytotoxicity assays showed that 1 and 2 have low cytotoxicity. This study offered a new framework for the development of NDM-1 inhibitors.

Ebsulfur and Ebselen as highly potent scaffolds for the development of potential SARS-CoV-2 antivirals.

The emerging COVID-19 pandemic caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has raised a global catastrophe. To date, there is no specific antiviral drug available to combat this virus, except the vaccine. In this study, the main protease (Mpro) required for SARS-CoV-2 viral replication was expressed and purified. Thirty-six compounds were tested as inhibitors of SARS-CoV-2 Mpro by fluorescence resonance energy transfer (FRET) technique. The half-maximal inhibitory concentration (IC50) values of Ebselen and Ebsulfur analogs were obtained to be in the range of 0.074-0.91 µM. Notably, the molecules containing furane substituent displayed higher inhibition against Mpro, followed by Ebselen 1i (IC50 = 0.074 µM) and Ebsulfur 2k (IC50 = 0.11 µM). The action mechanism of 1i and 2k were characterized by enzyme kinetics, pre-incubation and jump dilution assays, as well as fluorescent labeling experiments, which suggested that both compounds covalently and irreversibly bind to Mpro, while molecular docking suggested that 2k formed an SS bond with the Cys145 at the enzymatic active site. This study provides two very potent scaffolds Ebsulfur and Ebselen for the development of covalent inhibitors of Mpro to combat COVID-19.

Silver Nanoparticle Conjugated Star PCL-b-AMPs Copolymer as Nanocomposite Exhibits Efficient Antibacterial Properties.

The traditional antibiotics have specific intracellular targets and disinfect in chemical ways, and the drug-resistance induced by the antibiotics has grown into an emerging threat. It is urgent to call for novel strategies and antibacterial materials to control this situation. Herein, we report a class of silver-decorated nanocomposite AgNPs@PCL-b-AMPs as potent nanoantibiotic, constructed by ring-opening polymerization of the monomers ε-caprolactone, Z-Lys-N-carboxyanhydrides (NCAs), and Phe-NCAs, then decorated with AgNPs, and characterized by SEM, TEM, and DLS. The biological assays revealed that the nanocomposite possessed strong antibacterial efficacy against both Gram-positive and Gram-negative bacteria including clinical isolated bacteria MRSA, VRE, P. aeruginosa, and K. pneumonia, exhibiting a MIC value range in 2-8 µg/mL. Importantly, the S. aureus and P. aeruginosa treated with the nanocomposite did not show drug-resistance even after 21 passages. Also, in vivo anti-infective assays showed that the nanocomposite was able to effectively kill bacteria in the infected viscera of mice. The study of the sterilization mechanism showed that the nanocomposite exhibited a multimodal antimicrobial mechanism, including irreversibly damaging the membrane structure, making the leakage of intracellular ions and subsequently inducing generation of the reactive oxygen species (ROS), ultimately sterilizing the bacteria. The nanocomposite exhibits effective broad-spectrum antibacterial properties and shows low toxicity to the mammalian cells/animal. Overall, the AgNPs@PCL-b-AMPs gained in this work show great potential as a highly promising antibacterial material for biomedical applications including drug-resistant bacterial infection.

Hydroxamic acid with benzenesulfonamide: An effective scaffold for the development of broad-spectrum metallo-ß-lactamase inhibitors.

Given that ß-lactam antibiotic resistance mediated by metallo-ß-lactamases (MßLs) seriously threatens human health, we designed and synthesized nineteen hydroxamic acids with benzenesulfonamide, which exhibited broad-spectrum inhibition against four tested MßLs ImiS, L1, VIM-2 and IMP-1 (except 6, 13 and 18 on IMP-1, and 18 on VIM-2), with an IC50 value in the range of 0.6-9.4, 1.3-27.4, 5.4-43.7 and 5.2-49.7 µM, respectively, and restored antibacterial activity of both cefazolin and meropenem, resulting in a 2-32-fold reduction in MIC of the antibiotics. Compound 17 shows reversible competitive inhibition on L1 with a Ki value of 2.5 µM and significantly reduced the bacterial load in the spleen and liver of mice infected by E. coli expressing L1. The docking studies suggest that 17 tightly binds to the Zn(Ⅱ) of VIM-2 and CphA by the oxygen atoms of sulfonamide group, but coordinates with the Zn(II) of L1 through the oxygen atoms of hydroxamic acid group. These studies reveal that the hydroxamic acids with benzenesulfonamide are the potent scaffolds for the development of MßL inhibitors.

Real-time monitoring of D-Ala-D-Ala dipeptidase activity of VanX in living bacteria by isothermal titration calorimetry.

The d,d-dipeptidase enzyme VanX is the main cause of vancomycin resistance in gram-positive bacteria because of hydrolysis of the D-Ala-D-Ala dipeptide used in cell-wall biosynthesis. Continuous assay of VanX has proven challenging due to lack of a chromophoric substrate. Here, we report a direct approach for continuous assay of VanX in vitro and in vivo from hydrolysis of D-Ala-D-Ala, based on the heat-rate changes measured with isothermal titration calorimetry (ITC). With the ITC approach, determination of kinetic parameters of VanX hydrolyzing D-Ala-D-Ala and the inhibition constant of d-cysteine inhibitor yielded KM of 0.10 mM, kcat of 11.5 s-1, and Ki of 18.8 µM, which are consistent with the data from ninhydrin/Cd(II) assays. Cell-based ITC studies demonstrated that the VanX expressed in E. coli and in clinical strain VRE was inhibited by d-cysteine with IC50 values of 29.8 and 28.6 µM, respectively. Also, the total heat from D-Ala-D-Ala (4 mM) hydrolysis decreases strongly (in absolute value) from 1.26 mJ for VRE to 0.031 mJ for E. faecalis, which is consistent with the large MIC value of vancomycin of 512 µg/mL for VRE and the much smaller value of 4 µg/mL for E. faecalis. The ITC approach proposed here could be applied to screen and evaluate small molecule inhibitors of VanX or to identify drug resistant bacteria.

Amino Acid Thioesters Exhibit Inhibitory Activity against B1-B3 Subclasses of Metallo-ß-lactamases.

Superbug infection caused by metallo-ß-lactamases (MßLs) is a global public health threat. Previous studies reported that the thioesters specifically inhibited the B3 subclass MßL L1. In this work, nine amino acid thioesters 1-9 were synthesized, the activity evaluation revealed that all of these molecules exhibited broad-spectrum inhibitory efficacy against ImiS, IMP-1, NDM-1, and L1, with IC50 values range of 0.02-54.9 µM (except 5 and 7 on NDM-1), and 1 was found to be the best inhibitor with IC50 range of 0.02-16.63 µM. Minimal inhibitory concentration (MIC) assays showed that thioesters 1, 5 and 9 restored 2-32-fold antibacterial activity of cefazolin and/or imipenem against both Escherichia coli BL21 and DH10B strain expressing ImiS, L1, IMP-1 and NDM-1 (except 5 on NDM-1), and also, thioester 1 increased 2-4-fold antimicrobial activity of cefazolin on two clinical strains Pseudomonas aeruginosa and Klebsiella pneumoniae producing NDM-1. Stability evaluation indicated that thioester 1 was partially hydrolysed by MßLs to be converted into the mercaptoacetic acid, revealing that the thioester and its hydrolysate mercaptoacetic acid jointly inhibit MßLs. Isothermal titration calorimetry (ITC) monitoring showed that thioester 1 exhibited dose-dependent inhibition on four MßLs tested, and the binding of 1/L1 showed mainly enthalpy driven, while 1/NDM-1 was found to be more entropy driven. Docking studies suggested that 1 bound to Zn(II) ion(s) preferentially via its carboxylate group, while other moieties interacted mostly with the conserved active site residues.

Characterization of ß-lactamase activity using isothermal titration calorimetry.

BACKGROUND: Hydrolysis of ß-lactam antibiotic by ß-lactamase is the most common mechanism of ß-lactam resistance in clinical isolates. Timely detection and characterization of ß-lactamases are therefore of utmost biomedical importance. Conventional spectrophotometric method is time-consuming and cannot provide thermodynamic information on ß-lactamases. METHODS: A new assay was developed for the study of ß-lactamase activity in protein solutions (Metallo-ß-lactamase L1) and in clinical bacterial cells, based on heat-flow changes derived from enzymatic hydrolysis of ß-lactams using isothermal titration calorimetry. RESULTS: (1) The thermokinetic parameters of three antibiotics (penicillin G, cefazolin and imipenem) and the inhibition constant of an azolylthioacetamide inhibitor were determined using the calorimetric assay. The results from the calorimetric assays were consistent with the data from the spectrophotometric assay. (2) The values of heat change in the calorimetric assay using two clinical Escherichia coli strains correlated well with their antibiotic susceptibility results from the broth dilution experiment. The subtypes of ß-lactamase were also determined in the calorimetric assay. CONCLUSIONS: The ITC assay is a reliable and fast method to study ß-lactamase enzyme kinetics and inhibition. It can also provide thermodynamic information on antibiotic hydrolysis, which has been taken advantage of in this work to study ß-lactamase activity in two clinical Escherichia coli isolates. GENERAL SIGNIFICANCE: As the first calorimetric study of ß-lactamase activity, it may provide a new assay to assist biomedical validation of new ß-lactamase inhibitors, and also has potential applications on rapid antibiotic susceptibility testing and screening ß-lactamase producing bacteria.

Azolylthioacetamides as a potent scaffold for the development of metallo-ß-lactamase inhibitors.

In an effort to develop new inhibitors of metallo-ß-lactamases (MßLs), twenty-eight azolylthioacetamides were synthesized and assayed against MßLs. The obtained benzimidazolyl and benzioxazolyl substituted 1-19 specifically inhibited the enzyme ImiS, and 10 was found to be the most potent inhibitor of ImiS with an IC50 value of 15 nM. The nitrobenzimidazolyl substituted 20-28 specifically inhibited NDM-1, with 27 being the most potent inhibitor with an IC50 value of 170 nM. Further studies with 10, 11, and 27 revealed a mixed inhibition mode with competitive and uncompetitive inhibition constants in a similar range as the IC50 values. These inhibitors resulted in a 2-4-fold decrease in imipenem MIC values using E. coli cells producing ImiS or NDM-1. While the source of uncompetitive (possibly allosteric) inhibition remains unclear, docking studies indicate that 10 and 11 may interact orthosterically with Zn2 in the active site of CphA, while 27 could bridge the two Zn(II) ions in the active site of NDM-1 via its nitro group.

Optimization of amino acid thioesters as inhibitors of metallo-ß-lactamase L1.

The emergence of antibiotic resistance caused by metallo-ß-lactamases (MßLs) is a global public health problem. Recently, we found amino acid thioesters to be a highly promising scaffold for inhibitors of the MßL L1. In order to optimize this series of inhibitors, nine new amino acid thioesters were developed by modifying the substituents on the N-terminus of the thioesters and the groups representing the amino acid side chain. Biological activity assays indicate that all of them are very potent inhibitors of L1 with an IC50 value range of 20-600nM, lower than those of most of the previously reported inhibitors of this scaffold. Analysis of structure-activity relationship reveals that big hydrophobic substituents on the N-terminus and a methionine amino acid side chain improves inhibitory activity of the thioesters. All these inhibitors are able to restore antibacterial activity of a ß-lactam antibiotic against Escherichia coli BL21(DE3) cells producing L1 to that against E. coli cells lacking a ß-lactamase. Docking studies reveal that a large N-terminal hydrophobic group results in a slightly different binding mode than smaller hydrophobic groups at the same position.

Discovery of hydroxamate as a promising scaffold dually inhibiting metallo- and serine-ß-lactamases.

The bacterial infection mediated by ß-lactamases MßLs and SßLs has grown into an emergent health threat, however, development of a molecule that dual inhibits both MßLs and SßLs is challenging. In this work, a series of hydroxamates 1a-g, 2a-e, 3a-c, 4a-c were synthesized, characterized by 1H and 13C NMR and confirmed by HRMS. Biochemical assays revealed that these molecules dually inhibited MßLs (NDM-1, IMP-1) and SßLs (KPC-2, OXA-48), with an IC50 value in the range of 0.64-41.08 and 1.01-41.91 µM (except 1a and 1d on SßLs, IC50 > 50 µM), and 1f was found to be the best inhibitor with an IC50 value in the range of 0.64-1.32 and 0.57-1.01 µM, respectively. Mechanism evaluation indicated that 1f noncompetitively and irreversibly inhibited NDM-1 and KPC-2, with Ki value of 2.5 and 0.55 µM, is a time- and dose-dependent inhibitor of both MßLs and SßLs. MIC tests shown that all hydroxamates increased the antimicrobial effect of MER on E. coli-NDM-1 and E. coli-IMP-1 (expect 1b, 1d, 1g and 2d), resulting in a 2-8-fold reduction in MICs of MER, 1e-g, 2b-d, 3a-c and 4b-c decreased 2-4-fold MICs of MER on E. coli-KPC-2, and 1c, 1f-g, 2a-c, 3b, 4a and 4c decreased 2-16-fold MICs of MER on E. coli-OXA-48. Most importantly, 1f-g, 2b-c, 3b and 4c exhibited the dual synergizing inhibition against both E. coli-MßLs and E. coli-SßLs tested, resulting in a 2-8-fold reduction in MICs of MER, and 1f was found to have the best effect on the drug-resistant bacteria tested. Also, 1f shown synergizing antimicrobial effect on five clinical isolates EC04, EC06, EC08, EC10 and EC24 that produce NDM-1, resulting in a 2-8-fold reduction in MIC of MER, but its effect on E. coli and K. pneumonia-KPC-NDM was not to be observed using the same dose of inhibitor. Mice tests shown that the monotherapy of 1f or 4a in combination with MER significantly reduced the bacterial load of E. coli-NDM-1 and E. coli-OXA-48 cells in liver and spleen, respectively. The discovery in this work offered a promising bifunctional scaffold for creating the specific molecules that dually inhibit MßLs and MßLs, in combating antibiotic-resistant bacteria.

Novel fluorescent risedronates: synthesis, photodynamic inactivation and imaging of Bacillus subtilis.

Novel fluorescently-labeled conjugates of risedronate were synthesized using an epoxide linker, enabling conjugation of risedronate via its pyridyl nitrogen with the aromatic succinimidyl esters. The compounds were characterized by using (1)H NMR, (13)C NMR, (31)P NMR, UV-vis and fluorescence emission spectroscopies. Biological activity assays showed that the conjugates 14 and 15 exhibited photodynamic inactivation of Bacillus subtilis (ATCC 6633) with 91% and 47% bacterial lethality at 10 µM upon visible light irradiation, respectively. Both 14 and 15 could be also used for fluorescence imaging of Bacillus subtilis.