S-Glutathionylation and S-Nitrosylation in Mitochondria: Focus on Homeostasis and Neurodegenerative Diseases

Vrettou, Sofia; Wirth, Brunhilde

doi:10.3390/ijms232415849

Cited by 20 publications

(13 citation statements)

References 287 publications

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“…The S-glutathionylation is an oxidative and reversible modification that involves the attachment of glutathione to the cysteine residue of the protein of interest [88]. This process is abundant in mitochondria.…”

Section: Potassium Channels Regulation Via Gasotransmitters: Nitric O...mentioning

confidence: 99%

Redox Regulation of Mitochondrial Potassium Channels Activity

Lewandowska,

Kalenik,

Wrzosek

et al. 2024

Antioxidants

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Redox reactions exert a profound influence on numerous cellular functions with mitochondria playing a central role in orchestrating these processes. This pivotal involvement arises from three primary factors: (1) the synthesis of reactive oxygen species (ROS) by mitochondria, (2) the presence of a substantial array of redox enzymes such as respiratory chain, and (3) the responsiveness of mitochondria to the cellular redox state. Within the inner mitochondrial membrane, a group of potassium channels, including ATP-regulated, large conductance calcium-activated, and voltage-regulated channels, is present. These channels play a crucial role in conditions such as cytoprotection, ischemia/reperfusion injury, and inflammation. Notably, the activity of mitochondrial potassium channels is intricately governed by redox reactions. Furthermore, the regulatory influence extends to other proteins, such as kinases, which undergo redox modifications. This review aims to offer a comprehensive exploration of the modulation of mitochondrial potassium channels through diverse redox reactions with a specific focus on the involvement of ROS.

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Section: Potassium Channels Regulation Via Gasotransmitters: Nitric O...mentioning

confidence: 99%

Redox Regulation of Mitochondrial Potassium Channels Activity

Lewandowska,

Kalenik,

Wrzosek

et al. 2024

Antioxidants

View full text Add to dashboard Cite

show abstract

“…This nitrosative stress can induce chronic inflammation and apoptosis, contributing to sleep–wake disturbance [ 42 , 176 ]. For example, excess amyloid-β peptide in the brain of Alzheimer’s disease patients (who are prone to sleep disorders) promotes high levels of • NO that lead to S-nitrosylation of the mitochondrial fission protein DRP1, causing mitochondrial fission/fragmentation, mitophagy and neuronal damage [ 44 , 85 , 177 , 178 ]. Therefore, reports on metabolic syndrome and neurodegenerative diseases indicate disturbed redox-regulated rhythmicity, one of the redox–bioenergetics–temperature regulatory components of sleep–wake phases.…”

Section: Implications Of the Hypothesismentioning

confidence: 99%

“…Gut microbiota dysbiosis can lead to damage-associated molecular patterns (DAMPs), inflammasome activation and excessive • NO production that is immunosuppressive. • NO-mediated S-nitrosylation of mitochondrial CI-V and DRP1 can lead to mitophagy ( Section 5.4.2 ) [ 178 ]. The risk of developing metabolic syndrome and cancer is associated with night-shift workers such as nurses, likely due to circadian rhythm disruption [ 192 ].…”

Section: Implications Of the Hypothesismentioning

confidence: 99%

Mitochondria Need Their Sleep: Redox, Bioenergetics, and Temperature Regulation of Circadian Rhythms and the Role of Cysteine-Mediated Redox Signaling, Uncoupling Proteins, and Substrate Cycles

Richardson

Mailloux

2023

Antioxidants

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Although circadian biorhythms of mitochondria and cells are highly conserved and crucial for the well-being of complex animals, there is a paucity of studies on the reciprocal interactions between oxidative stress, redox modifications, metabolism, thermoregulation, and other major oscillatory physiological processes. To address this limitation, we hypothesize that circadian/ultradian interaction of the redoxome, bioenergetics, and temperature signaling strongly determine the differential activities of the sleep–wake cycling of mammalians and birds. Posttranslational modifications of proteins by reversible cysteine oxoforms, S-glutathionylation and S-nitrosylation are shown to play a major role in regulating mitochondrial reactive oxygen species production, protein activity, respiration, and metabolomics. Nuclear DNA repair and cellular protein synthesis are maximized during the wake phase, whereas the redoxome is restored and mitochondrial remodeling is maximized during sleep. Hence, our analysis reveals that wakefulness is more protective and restorative to the nucleus (nucleorestorative), whereas sleep is more protective and restorative to mitochondria (mitorestorative). The “redox–bioenergetics–temperature and differential mitochondrial–nuclear regulatory hypothesis” adds to the understanding of mitochondrial respiratory uncoupling, substrate cycling control and hibernation. Similarly, this hypothesis explains how the oscillatory redox–bioenergetics–temperature–regulated sleep–wake states, when perturbed by mitochondrial interactome disturbances, influence the pathogenesis of aging, cancer, spaceflight health effects, sudden infant death syndrome, and diseases of the metabolism and nervous system.

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“…Particularly, these molecules can cause post-translational modification (PTMs) in proteins, leading to structural changes that lead to protein destabilization and aggregation. An example of this is represented by both S-nitrosylation and S-glutathionylation in reactive thiols by the protein disulfide isomerase [ 76 ]. S-nitrosylation consists of the addition of a nitric oxide to the thiol group of a cysteine, while S-glutathionylation is referred to a glutathione group (GSH) added at the thiol group of a cysteine [ 77 ].…”

Section: Cellular Pathways Of Redox Imbalancementioning

confidence: 99%

Redox Imbalance in Neurological Disorders in Adults and Children

et al. 2023

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Oxygen is a central molecule for numerous metabolic and cytophysiological processes, and, indeed, its imbalance can lead to numerous pathological consequences. In the human body, the brain is an aerobic organ and for this reason, it is very sensitive to oxygen equilibrium. The consequences of oxygen imbalance are especially devastating when occurring in this organ. Indeed, oxygen imbalance can lead to hypoxia, hyperoxia, protein misfolding, mitochondria dysfunction, alterations in heme metabolism and neuroinflammation. Consequently, these dysfunctions can cause numerous neurological alterations, both in the pediatric life and in the adult ages. These disorders share numerous common pathways, most of which are consequent to redox imbalance. In this review, we will focus on the dysfunctions present in neurodegenerative disorders (specifically Alzheimer’s disease, Parkinson’s disease and amyotrophic lateral sclerosis) and pediatric neurological disorders (X-adrenoleukodystrophies, spinal muscular atrophy, mucopolysaccharidoses and Pelizaeus–Merzbacher Disease), highlighting their underlining dysfunction in redox and identifying potential therapeutic strategies.

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S-Glutathionylation and S-Nitrosylation in Mitochondria: Focus on Homeostasis and Neurodegenerative Diseases

Cited by 20 publications

References 287 publications

Redox Regulation of Mitochondrial Potassium Channels Activity

Redox Regulation of Mitochondrial Potassium Channels Activity

Mitochondria Need Their Sleep: Redox, Bioenergetics, and Temperature Regulation of Circadian Rhythms and the Role of Cysteine-Mediated Redox Signaling, Uncoupling Proteins, and Substrate Cycles

Redox Imbalance in Neurological Disorders in Adults and Children

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