Abstract
Multidrug-resistant (MDR) bacteria have become a severe problem for public health. Developing new antibiotics for MDR bacteria is difficult, from inception to the clinically approved stage. Here, we have used a new approach, modification of an antibiotic, ciprofloxacin (CFX), with triphenylphosphonium (TPP, PPh3) moiety via ester- (CFX-ester-PPh3) and amide-coupling (CFX-amide-PPh3) to target bacterial membranes. In this study, we have evaluated the antibacterial activities of CFX and its derivatives against 16 species of bacteria, including MDR bacteria, using minimum inhibitory concentration (MIC) assay, morphological monitoring, and expression of resistance-related genes. TPP-conjugated CFX, CFX-ester-PPh3, and CFX-amide-PPh3 showed significantly improved antibacterial activity against Gram-positive bacteria, Staphylococcus aureus, including MDR S. aureus (methicillin-resistant S. aureus (MRSA)) strains. The MRSA ST5 5016 strain showed high antibacterial activity, with MIC values of 11.12 µg/mL for CFX-ester-PPh3 and 2.78 µg/mL for CFX-amide-PPh3. The CFX derivatives inhibited biofilm formation in MRSA by more than 74.9% of CFX-amide-PPh3. In the sub-MIC, CFX derivatives induced significant morphological changes in MRSA, including irregular deformation and membrane disruption, accompanied by a decrease in the level of resistance-related gene expression. With these promising results, this method is very likely to combat MDR bacteria through a simple TPP moiety modification of known antibiotics, which can be readily prepared at clinical sites.
Highlights
Antimicrobial resistance is considered to be one of the greatest threats to human health worldwide
We focused on the two mechanisms of action, first is the alteration of proton motive force (PMF), which affects the operation system of proton-dependent multidrug efflux system, and the other is collapsing the bacterial membrane
It is known that the covalently linked TPP moiety enhances the lipophilic character of TPP-conjugated CFXs derivatives, and this strategy has been used to increase the solubility of drugs and imaging agents, and improve their bioactivity [12,20]
Summary
Antimicrobial resistance is considered to be one of the greatest threats to human health worldwide. Microbes resistant to multiple anti-microbials are known as multidrug-resistant (MDR) and cannot be killed using the current drugs. The ESKAPE pathogens play a critical role in nosocomial infections and resist antimicrobial agents through drug resistance mechanisms [3]. Many approaches have been proposed to overcome MDR bacteria, including ESKAPE pathogens, such as use of drug combination, drug modification, and drug delivery systems [5]. Many new antimicrobial agents, such as inhibitors of quorum sensing (QS) [6], antimicrobial peptides (AMPs) [7], and bacteriophages [8], have been suggested, and they are based on the target of the molecular mechanisms of MDR. Various approaches based on inhibiting the formation of the negatively charged membrane bilayer, using cationic polymers and inhibitory integral proteins, similar to membrane bound multidrug efflux pumps, have been shown to be effective against both
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