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Photodynamic Inactivation of Bacteria with Porphyrin Derivatives: Effect of Charge, Lipophilicity, ROS Generation, and Cellular Uptake on Their Biological Activity In Vitro
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Photodynamic Inactivation of Bacteria with Porphyrin Derivatives: Effect of Charge, Lipophilicity, ROS Generation, and Cellular Uptake on Their Biological Activity In Vitro
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Journal Article
Photodynamic Inactivation of Bacteria with Porphyrin Derivatives: Effect of Charge, Lipophilicity, ROS Generation, and Cellular Uptake on Their Biological Activity In Vitro
2020
Overview
Resistance of microorganisms to antibiotics has led to research on various therapeutic strategies with different mechanisms of action, including photodynamic inactivation (PDI). In this work, we evaluated a cationic, neutral, and anionic meso-tetraphenylporphyrin derivative’s ability to inactivate the Gram-negative and Gram-positive bacteria in a planktonic suspension under blue light irradiation. The spectroscopic, physicochemical, redox properties, as well as reactive oxygen species (ROS) generation capacity by a set of photosensitizers varying in lipophilicity were investigated. The theoretical calculations were performed to explain the distribution of the molecular charges in the evaluated compounds. Moreover, logP partition coefficients, cellular uptake, and phototoxicity of the photosensitizers towards bacteria were determined. The role of a specific microbial efflux pump inhibitor, verapamil hydrochloride, in PDI was also studied. The results showed that E. coli exhibited higher resistance to PDI than S. aureus (3–5 logs) with low light doses (1–10 J/cm2). In turn, the prolongation of irradiation (up to 100 J/cm2) remarkably improved the inactivation of pathogens (up to 7 logs) and revealed the importance of photosensitizer photostability. The PDI potentiation occurs after the addition of KI (more than 3 logs extra killing). Verapamil increased the uptake of photosensitizers (especially in E. coli) due to efflux pump inhibition. This effect suggests that PDI is mediated by ROS, the electrostatic charge interaction, and the efflux of photosensitizers (PSs) regulated by multidrug-resistance (MDR) systems. Thus, MDR inhibition combined with PDI gives opportunities to treat more resistant bacteria.
Publisher
MDPI AG,MDPI
Subject
/ Bacteria
/ Bacteria - radiation effects
/ Cancer
/ Chlorine
/ Drug Resistance, Bacterial - drug effects
/ Drugs
/ Escherichia coli - drug effects
/ Escherichia coli - metabolism
/ Escherichia coli - radiation effects
/ Gram-Negative Bacteria - drug effects
/ Gram-Negative Bacteria - metabolism
/ Gram-Negative Bacteria - radiation effects
/ Gram-Positive Bacteria - drug effects
/ Gram-Positive Bacteria - metabolism
/ Gram-Positive Bacteria - radiation effects
/ Hydrophobic and Hydrophilic Interactions
/ Light
/ Microscopy, Electron, Scanning
/ Multidrug resistant organisms
/ Photosensitizing Agents - chemistry
/ Photosensitizing Agents - pharmacology
/ Reactive Oxygen Species - metabolism
/ Staphylococcus aureus - drug effects
