Potentiating aminoglycoside antibiotics to reduce their toxic side effects

The lack of new antibiotics necessitates the improvement of existing ones, many of which are limited by toxic side effects. Aminoglycosides, antibiotics with excellent activity and low bacterial resistance, are hampered by dose-dependent toxic effects in patients (nephrotoxicity, ototoxicity). High...

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Bibliographic Details
Published in:PloS one 2020-09, Vol.15 (9), p.e0237948
Main Authors: Rosenberg, Christopher R, Fang, Xin, Allison, Kyle R
Format: Article
Language:English
Subjects:
Aminoglycoside antibiotics
Aminoglycosides
Antibiotics
Bacteria
Bacterial infections
Biofilms
Biology
Biology and Life Sciences
Biomedical engineering
Cytotoxicity
Dosage and administration
Drug dosages
Drug resistance
E coli
Genotype & phenotype
Glucose
Infections
Infectious diseases
Klebsiella
Low concentrations
Mannitol
Medicine and Health Sciences
Metabolism
Metabolites
Nutrients
Ototoxicity
Pathogens
Physical Sciences
Prevention
Protonmotive force
Salmonella
Side effects
Toxicity
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Summary:The lack of new antibiotics necessitates the improvement of existing ones, many of which are limited by toxic side effects. Aminoglycosides, antibiotics with excellent activity and low bacterial resistance, are hampered by dose-dependent toxic effects in patients (nephrotoxicity, ototoxicity). High antibiotic concentrations are often required to treat dormant, non-dividing bacteria, though previous studies show that aminoglycosides can be activated against such bacteria by specific metabolites. Here, we employed this mechanism to greatly boost the activity of low concentrations of aminoglycosides against prevalent Gram-negative pathogens (Escherichia coli, Salmonella enterica, and Klebsiella pneumoniae), suggesting that less toxic drug concentrations might be used effectively in patients. We go on to show that this effect improved treatment of biofilms, did not increase aminoglycoside resistance, and was due to the generation of proton-motive force (PMF). By single-cell microscopy, we demonstrate that stationary-phase cells, while non-dividing, actively maintain a growth-arrested state that is not reversed by metabolite addition. Surprisingly, within starved populations, we observed rare cells (3%) that divided without added nutrients. Additionally, we discovered that mannitol could directly protect human kidney cells from aminoglycoside cytotoxicity, independent of the metabolite's effect on bacteria. This work forwards a mechanism-based strategy to improve existing antibiotics by mitigating their toxic side effects.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0237948