Abstract
A biochemical reaction model clarifies for the first time how cold atmospheric plasmas (CAPs) affect mitochondrial redox homeostasis and energy metabolism. Fundamental mitochondrial functions in pyruvic acid oxidation, the tricarboxylic acid (TCA) cycle and oxidative phosphorylation involving the respiratory chain (RC), adenosine triphosphate/adenosine diphosphate (ATP/ADP) synthesis machinery and reactive oxygen species/reactive nitrogen species (ROS/RNS)-mediated mechanisms are numerically simulated. The effects of CAP irradiation are modelled as 1) the influx of hydrogen peroxide (H{}_{2}O{}_{2}) to an ROS regulation system and 2) the change in mitochondrial transmembrane potential induced by RNS on membrane permeability. The CAP-induced stress modifies the dynamics of intramitochondrial H{}_{2}O{}_{2} and superoxide anions, i.e., the rhythm and shape of ROS oscillation are disturbed by H{}_{2}O{}_{2} infusion. Furthermore, CAPs control the ROS oscillatory behaviour, nicotinamide adenine dinucleotide redox state and ATP/ADP conversion through the reaction mixture over the RC, the TCA cycle and ROS regulation system. CAPs even induce a homeostatic or irreversible state transition in cell metabolism. The present computational model demonstrates that CAPs crucially affect essential mitochondrial functions, which in turn affect redox signalling, metabolic cooporation and cell fate decision of survival or death.
Highlights
A biochemical reaction model clarifies for the first time how cold atmospheric plasmas (CAPs) affect mitochondrial redox homeostasis and energy metabolism
The first half of this paper focused on the intramitochondrial H2O2 dynamics and emphasised how the rhythm was modified by Cold atmospheric plasmas (CAPs)-originating H2O2
The biochemical modelling and numerical simulation quantitatively clarified for the first time how cold atmospheric plasmas affect cell fate decisions by controlling the mitochondrial redox homeostasis and energy metabolism
Summary
A biochemical reaction model clarifies for the first time how cold atmospheric plasmas (CAPs) affect mitochondrial redox homeostasis and energy metabolism. The effects of CAP irradiation are modelled as 1) the influx of hydrogen peroxide (H2O2) to an ROS regulation system and 2) the change in mitochondrial transmembrane potential induced by RNS on membrane permeability. Mitochondria have a central role in energy metabolism including adenosine triphosphate (ATP) and adenosine diphosphate (ADP) production and exchange[4] The integrity of these mitochondrial functions is fundamental to cell life[2,3,5]. CAPs have been widely applied in the field of biomedicine, such as blood coagulation[6], inactivation of bacteria, microorganisms or viruses[7,8], tumour or cancer treatment[9,10,11] and induction of apoptotic/necrotic cell death[12,13]. Significant gaps still exist in our knowledge of fundamental mechanisms that can bridge CAP physics and molecular biology
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