The cold atmospheric pressure plasma-generated species superoxide, singlet oxygen and atomic oxygen activate the molecular chaperone Hsp33

Cold atmospheric pressure plasmas are used for surface decontamination or disinfection, e.g. in clinical settings. Protein aggregation has been shown to significantly contribute to the antibacterial mechanisms of plasma. To investigate the potential role of the redox-activated zinc-binding chaperone...

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Bibliographic Details
Published in:Journal of the Royal Society interface 2023-10, Vol.20 (207), p.20230300
Main Authors: Dirks, Tim, Krewing, Marco, Vogel, Katharina, Bandow, Julia E
Format: Article
Language:English
Subjects:
Escherichia coli - metabolism
Escherichia coli Proteins - metabolism
Heat-Shock Proteins - chemistry
Life Sciences–Physics interface
Molecular Chaperones - chemistry
Molecular Chaperones - metabolism
Oxidation-Reduction
Oxygen - metabolism
Plasma Gases - pharmacology
Protein Aggregates
Singlet Oxygen - metabolism
Superoxides - metabolism
Zinc - metabolism
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Summary:Cold atmospheric pressure plasmas are used for surface decontamination or disinfection, e.g. in clinical settings. Protein aggregation has been shown to significantly contribute to the antibacterial mechanisms of plasma. To investigate the potential role of the redox-activated zinc-binding chaperone Hsp33 in preventing protein aggregation and thus mediating plasma resistance, we compared the plasma sensitivity of wild-type to that of an deletion mutant lacking Hsp33 as well as an over-producing strain. Over-production of Hsp33 increased plasma survival rates above wild-type levels. Hsp33 was previously shown to be activated by plasma . For the PlasmaDerm source applied in dermatology, reversible activation of Hsp33 was confirmed. Thiol oxidation and Hsp33 unfolding, both crucial for Hsp33 activation, occurred during plasma treatment. After prolonged plasma exposure, however, unspecific protein oxidation was detected, the ability of Hsp33 to bind zinc ions was decreased without direct modifications of the zinc-binding motif, and the protein was inactivated. To identify chemical species of potential relevance for plasma-induced Hsp33 activation, reactive oxygen species were tested for their ability to activate Hsp33 . Superoxide, singlet oxygen and potentially atomic oxygen activate Hsp33, while no evidence was found for activation by ozone, peroxynitrite or hydroxyl radicals.
ISSN:1742-5662
1742-5689
1742-5662
DOI:10.1098/rsif.2023.0300