In vitro and intracellular activity of vaborbactam combined with ß-lactams against Mycobacterium abscessus.

OBJECTIVES: Mycobacterium abscessus has emerged as an opportunistic pathogen responsible for lung infections, especially in cystic fibrosis patients. In spite of the production of the broad-spectrum ß-lactamase BlaMab, the carbapenem imipenem is recommended in the initial phase of the treatment of pulmonary infections. Here, we determine whether the addition of vaborbactam, a second-generation ß-lactamase inhibitor belonging to the boronate family, improves the activity of ß-lactams against M. abscessus. METHODS: The activity of ß-lactams, alone or in combination with vaborbactam, was evaluated against M. abscessus CIP104536 by determining MICs, time-killing and intramacrophage activity. Kinetic parameters for the inhibition of BlaMab by vaborbactam were determined by spectrophotometry. RESULTS: The combination of vaborbactam (8 mg/L) with ß-lactams decreased more than 8 times the MIC of amoxicillin (from >1024 to 128 mg/L) and 2 times the MICs of meropenem (from 16 to 8 mg/L) and imipenem (from 4 to 2 mg/L). The reduction of the MICs was less than that obtained with avibactam at 4 mg/L for amoxicillin (from >1024 to 16 mg/L, more than 64 times less) and for meropenem (from 16 to 4 mg/L, 4 times less). In vitro and intracellularly, M. abscessus was not killed by the meropenem/vaborbactam combination, in spite of significant in vitro inhibition of BlaMab by vaborbactam. CONCLUSIONS: Inhibition of BlaMab by vaborbactam decreases the MIC of ß-lactams, including that of meropenem. As meropenem/vaborbactam is clinically available, this combination offers an alternative therapeutic option that should be evaluated for the treatment of pulmonary infections due to M. abscessus.

Monitoring Drug-Protein Interactions in the Bacterial Periplasm by Solution Nuclear Magnetic Resonance Spectroscopy.

The rapid spread of antimicrobial resistance across bacterial pathogens poses a serious risk to the efficacy and sustainability of available treatments. This puts pressure on research concerning the development of new drugs. Here, we present an in-cell NMR-based research strategy to monitor the activity of the enzymes located in the periplasmic space delineated by the inner and outer membranes of Gram-negative bacteria. We demonstrate its unprecedented analytical power in monitoring in situ and in real time (i) the hydrolysis of ß-lactams by ß-lactamases, (ii) the interaction of drugs belonging to the ß-lactam family with their essential targets, and (iii) the binding of inhibitors to these enzymes. We show that in-cell NMR provides a powerful analytical tool for investigating new drugs targeting the molecular components of the bacterial periplasm.