Cold atmospheric plasma (CAP) is a promising innovative technology for microbial inactivation on food surfaces. In this study, we evaluated the potential of CAP at low (CAP-O3) and high (CAP-NOx) power using Aspergillus chevalieri as a fungal model, one of the most xerophilic and xerotolerant molds causing food spoilage, We observed a strong reduction in mycelial growth (60%) and conidial germination (90%) after 30 min of CAP-NOx, while CAP-O3 was less effective showing no reduction in mycelia growth and only 36% of spore germination reduction. Furthermore, cell death was accompanied by a loss of cellular and mitochondrial potential membrane, a significant (p < 0.05) increase in intracellular ROS, RNS, calcium, and DNA damage. For the first time, we reported that trehalose, glycerol, chitin and glucan accumulation are some adaptive mechanisms of A. chevalieri to counteract CAP stress, with CAP-NOx treatments inducing a major accumulation of these two osmolites. Our results suggested that Cold atmospheric plasma-induced cell death can be explained by oxidative stress-dependent through a cascade of reactions initiated by membrane depolarization.

A comparative study on the antifungal efficacy of cold atmospheric plasma at low and high surface density on Aspergillus chevalieri and mechanisms of action

Molina-Hernandez J. B.;Laika J.;Gioia L.;Valbonetti L.;Chaves-Lopez C.
2022-01-01

Abstract

Cold atmospheric plasma (CAP) is a promising innovative technology for microbial inactivation on food surfaces. In this study, we evaluated the potential of CAP at low (CAP-O3) and high (CAP-NOx) power using Aspergillus chevalieri as a fungal model, one of the most xerophilic and xerotolerant molds causing food spoilage, We observed a strong reduction in mycelial growth (60%) and conidial germination (90%) after 30 min of CAP-NOx, while CAP-O3 was less effective showing no reduction in mycelia growth and only 36% of spore germination reduction. Furthermore, cell death was accompanied by a loss of cellular and mitochondrial potential membrane, a significant (p < 0.05) increase in intracellular ROS, RNS, calcium, and DNA damage. For the first time, we reported that trehalose, glycerol, chitin and glucan accumulation are some adaptive mechanisms of A. chevalieri to counteract CAP stress, with CAP-NOx treatments inducing a major accumulation of these two osmolites. Our results suggested that Cold atmospheric plasma-induced cell death can be explained by oxidative stress-dependent through a cascade of reactions initiated by membrane depolarization.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11575/125691
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