Heavy isotope labeling and mass spectrometry reveal unexpected remodeling of bacterial cell wall expansion in response to drugs.

Antibiotics of the ß-lactam (penicillin) family inactivate target enzymes called D,D-transpeptidases or penicillin-binding proteins (PBPs) that catalyze the last cross-linking step of peptidoglycan synthesis. The resulting net-like macromolecule is the essential component of bacterial cell walls that sustains the osmotic pressure of the cytoplasm. In Escherichia coli, bypass of PBPs by the YcbB L,D-transpeptidase leads to resistance to these drugs. We developed a new method based on heavy isotope labeling and mass spectrometry to elucidate PBP- and YcbB-mediated peptidoglycan polymerization. PBPs and YcbB similarly participated in single-strand insertion of glycan chains into the expanding bacterial side wall. This absence of any transpeptidase-specific signature suggests that the peptidoglycan expansion mode is determined by other components of polymerization complexes. YcbB did mediate ß-lactam resistance by insertion of multiple strands that were exclusively cross-linked to existing tripeptide-containing acceptors. We propose that this undocumented mode of polymerization depends upon accumulation of linear glycan chains due to PBP inactivation, formation of tripeptides due to cleavage of existing cross-links by a ß-lactam-insensitive endopeptidase, and concerted cross-linking by YcbB.

Traceless Staudinger Ligation To Introduce Chemical Diversity on ß-Lactamase Inhibitors of Second Generation.

We explored the traceless Staudinger ligation for the functionalization of the C2 position of second generation ß-lactamase inhibitors based on a diazabicyclooctane (DBO) scaffold. Our strategy is based on the synthesis of phosphine phenol esters and their ligation to an azido-containing precursor. Biological evaluation showed that this route provided access to a DBO that proved to be superior to commercial relebactam for inhibition of two of the five ß-lactamases that were tested.

Diazabicyclooctane Functionalization for Inhibition of ß-Lactamases from Enterobacteria.

Second-generation ß-lactamase inhibitors containing a diazabicyclooctane (DBO) scaffold restore the activity of ß-lactams against pathogenic bacteria, including those producing class A, C, and D enzymes that are not susceptible to first-generation inhibitors containing a ß-lactam ring. Here, we report optimization of a synthetic route to access triazole-containing DBOs and biological evaluation of a series of 17 compounds for inhibition of five ß-lactamases representative of enzymes found in pathogenic Gram-negative bacteria. A strong correlation (Spearman coefficient of 0.87; p = 4.7 × 10-21) was observed between the inhibition efficacy of purified ß-lactamases and the potentiation of ß-lactam antibacterial activity, indicating that DBO functionalization did not impair penetration. In comparison to reference DBOs, avibactam and relebactam, our compounds displayed reduced efficacy, likely due to the absence of hydrogen bonding with a conserved asparagine residue at position 132. This was partially compensated for by additional interactions involving certain triazole substituents.

Impact of relebactam-mediated inhibition of Mycobacterium abscessus BlaMab ß-lactamase on the in vitro and intracellular efficacy of imipenem.

OBJECTIVES: Imipenem is one of the recommended ß-lactams for the treatment of Mycobacterium abscessus pulmonary infections in spite of the production of BlaMab ß-lactamase. Avibactam, a second-generation ß-lactamase inhibitor, was previously shown to inactivate BlaMab, but its partner drug, ceftazidime, is devoid of any antibacterial activity against M. abscessus. Here, we investigate whether relebactam, a novel second-generation inhibitor developed in combination with imipenem, improves the activity of this carbapenem against M. abscessus. METHODS: The impact of BlaMab inhibition by relebactam was evaluated by determining MICs, time-kill curves and M. abscessus intracellular proliferation in human macrophages. Kinetic parameters for the inhibition of BlaMab by relebactam were determined by spectrophotometry using nitrocefin as the substrate. The data were compared with those obtained with avibactam. RESULTS: Combination of relebactam (4 mg/L) with ß-lactams led to >128- and 2-fold decreases in the MICs of amoxicillin (from >4096 to 32 mg/L) and imipenem (from 8 to 4 mg/L). In vitro, M. abscessus was not killed by the imipenem/relebactam combination. In contrast, relebactam increased the intracellular activity of imipenem, leading to 88% killing. Relebactam and avibactam similarly potentiated the antibacterial activities of ß-lactams although BlaMab was inactivated 150-fold less effectively by relebactam than by avibactam. CONCLUSIONS: Inhibition of BlaMab by relebactam improves the efficacy of imipenem against M. abscessus in macrophages, indicating that the imipenem/relebactam combination should be clinically considered for the treatment of infections due to M. abscessus.

Tryptophan Fluorescence Quenching in ß-Lactam-Interacting Proteins Is Modulated by the Structure of Intermediates and Final Products of the Acylation Reaction.

In most bacteria, ß-lactam antibiotics inhibit the last cross-linking step of peptidoglycan synthesis by acylation of the active-site Ser of d,d-transpeptidases belonging to the penicillin-binding protein (PBP) family. In mycobacteria, cross-linking is mainly ensured by l,d-transpeptidases (LDTs), which are promising targets for the development of ß-lactam-based therapies for multidrug-resistant tuberculosis. For this purpose, fluorescence spectroscopy is used to investigate the efficacy of LDT inactivation by ß-lactams but the basis for fluorescence quenching during enzyme acylation remains unknown. In contrast to what has been reported for PBPs, we show here using a model l,d-transpeptidase (Ldtfm) that fluorescence quenching of Trp residues does not depend upon direct hydrophobic interaction between Trp residues and ß-lactams. Rather, Trp fluorescence was quenched by the drug covalently bound to the active-site Cys residue of Ldtfm. Fluorescence quenching was not quantitatively determined by the size of the drug and was not specific of the thioester link connecting the ß-lactam carbonyl to the catalytic Cys as quenching was also observed for acylation of the active-site Ser of ß-lactamase BlaC from M. tuberculosis. Fluorescence quenching was extensive for reaction intermediates containing an amine anion and for acylenzymes containing an imine stabilized by mesomeric effect, but not for acylenzymes containing a protonated ß-lactam nitrogen. Together, these results indicate that the extent of fluorescence quenching is determined by the status of the ß-lactam nitrogen. Thus, fluorescence kinetics can provide information not only on the efficacy of enzyme inactivation but also on the structure of the covalent adducts responsible for enzyme inactivation.

Pharmacological profile and efficiency in vivo of diflapolin, the first dual inhibitor of 5-lipoxygenase-activating protein and soluble epoxide hydrolase.

Arachidonic acid (AA) is metabolized to diverse bioactive lipid mediators. Whereas the 5-lipoxygenase-activating protein (FLAP) facilitates AA conversion by 5-lipoxygenase (5-LOX) to pro-inflammatory leukotrienes (LTs), the soluble epoxide hydrolase (sEH) degrades anti-inflammatory epoxyeicosatrienoic acids (EETs). Accordingly, dual FLAP/sEH inhibition might be advantageous drugs for intervention of inflammation. We present the in vivo pharmacological profile and efficiency of N-[4-(benzothiazol-2-ylmethoxy)-2-methylphenyl]-N'-(3,4-dichlorophenyl)urea (diflapolin) that dually targets FLAP and sEH. Diflapolin inhibited 5-LOX product formation in intact human monocytes and neutrophils with IC50 = 30 and 170 nM, respectively, and suppressed the activity of isolated sEH (IC50 = 20 nM). Characteristic for FLAP inhibitors, diflapolin (I) failed to inhibit isolated 5-LOX, (II) blocked 5-LOX product formation in HEK cells only when 5-LOX/FLAP was co-expressed, (III) lost potency in intact cells when exogenous AA was supplied, and (IV) prevented 5-LOX/FLAP complex assembly in leukocytes. Diflapolin showed target specificity, as other enzymes related to AA metabolism (i.e., COX1/2, 12/15-LOX, LTA4H, LTC4S, mPGES1, and cPLA2) were not inhibited. In the zymosan-induced mouse peritonitis model, diflapolin impaired vascular permeability, inhibited cysteinyl-LTs and LTB4 formation, and suppressed neutrophil infiltration. Diflapolin is a highly active dual FLAP/sEH inhibitor in vitro and in vivo with target specificity to treat inflammation-related diseases.