Dopamine metabolism by a monoamine oxidase mitochondrial shuttle activates the electron transport chain

Graves, Steven M.; Xie, Zhong; Stout, Kristen A.; Zampese, Enrico; Burbulla, Lena F.; Shih, Jean C.; Kondapalli, Jyothisri; Patriarchi, Tommaso; Tian, Lin; Brichta, Lars; Greengard, Paul; Krainc, Dimitri; Schumacker, Paul T.; Surmeier, D. James

doi:10.1038/s41593-019-0556-3

Cited by 126 publications

(125 citation statements)

References 27 publications

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“…The cyclization of dopamine quinones forms aminochrome, which generates superoxide and down-regulates antioxidative nicotinamide adenine dinucleotide phosphate (NADPH) [ 8 ]. The metabolism of DA by monoamine oxidase-B (MAO-B) generates 3,4-dihydroxyphenyl-acetaldehyde, ammonia and H 2 O 2 [ 9 ]. H 2 O 2 in DAergic neurons reacts with Fe 2+ to form hydroxyl radical [ 10 , 11 ].…”

Section: Ros Production In the Pd Brainmentioning

confidence: 99%

The Role of Oxidative Stress in Parkinson’s Disease

2020

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Parkinson’s disease (PD) is caused by progressive neurodegeneration of dopaminergic (DAergic) neurons with abnormal accumulation of α-synuclein in substantia nigra (SN). Studies have suggested the potential involvement of dopamine, iron, calcium, mitochondria and neuroinflammation in contributing to overwhelmed oxidative stress and neurodegeneration in PD. Function studies on PD-causative mutations of SNCA, PRKN, PINK1, DJ-1, LRRK2, FBXO7 and ATP13A2 further indicate the role of oxidative stress in the pathogenesis of PD. Therefore, it is reasonable that molecules involved in oxidative stress, such as DJ-1, coenzyme Q10, uric acid, 8-hydroxy-2’-deoxyguanosin, homocysteine, retinoic acid/carotenes, vitamin E, glutathione peroxidase, superoxide dismutase, xanthine oxidase and products of lipid peroxidation, could be candidate biomarkers for PD. Applications of antioxidants to modulate oxidative stress could be a strategy in treating PD. Although a number of antioxidants, such as creatine, vitamin E, coenzyme Q10, pioglitazone, melatonin and desferrioxamine, have been tested in clinical trials, none of them have demonstrated conclusive evidence to ameliorate the neurodegeneration in PD patients. Difficulties in clinical studies may be caused by the long-standing progression of neurodegeneration, lack of biomarkers for premotor stage of PD and inadequate drug delivery across blood–brain barrier. Solutions for these challenges will be warranted for future studies with novel antioxidative treatment in PD patients.

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Section: Ros Production In the Pd Brainmentioning

confidence: 99%

The Role of Oxidative Stress in Parkinson’s Disease

2020

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“…Interestingly, a recent paper has confirmed in hippocampal neurons that Ca 2+ influx through Cav1 channels combined with CICR can regulate mitochondria ATP production, although in these non-pacemaking neurons mitochondrial contribution to cell bioenergetic seems to be relatively small and this mechanism is activated only upon stimulation [ 163 ]. At axonal DA release sites, Ca 2+ stimulated mitochondrial OXPHOS is complemented by another feedforward system in which DA transiting the cytosol is metabolized by monoamine oxidase (MAO) anchored to the outer membrane of mitochondria; in so doing, MAO generates an electron that is shuttled to the ETC, which supports the electrochemical gradient used by complex V to generate ATP [ 164 ]. Thus, feedforward control of mitochondrial OXPHOS is a mechanism by which SN DAergic neurons can maximize their functionality and promote organismal survival.…”

Section: Ca 2+ Signaling In Sn Daergic Neuronsmentioning

confidence: 99%

Calcium, Bioenergetics, and Parkinson’s Disease

Zampese

Surmeier

2020

Cells

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Degeneration of substantia nigra (SN) dopaminergic (DAergic) neurons is responsible for the core motor deficits of Parkinson’s disease (PD). These neurons are autonomous pacemakers that have large cytosolic Ca2+ oscillations that have been linked to basal mitochondrial oxidant stress and turnover. This review explores the origin of Ca2+ oscillations and their role in the control of mitochondrial respiration, bioenergetics, and mitochondrial oxidant stress.

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“…Numerous studies have reported the successful application of genetically encoded biosensors that are sensitive to a variety of metabolites and signaling molecules, including ions and neurotransmitters, to investigate the functioning of neurons and glia in in vitro systems under diverse physiological (spontaneous and evoked activity of neuronal and glial cells) or pathological (Parkinson’s disease, Rett syndrome, and spinal muscular atrophy) conditions. Genetically encoded biosensors were applied to visualize the release of neurotransmitters and their intracellular dynamics [ 260 , 261 , 262 ], to observe the metabolic activity (glucose, pyruvate, ATP) and functioning of second messenger systems (Ca 2+ , cAMP) [ 263 , 264 , 265 , 266 ], to detect the formation of ROS [ 267 , 268 , 269 , 270 ], and to record the responses of cellular redox systems [ 183 , 271 , 272 , 273 , 274 , 275 ]. However, many fewer studies have attempted to exploit genetically encoded sensors for the real-time evaluation of alterations in cell signaling and metabolism in in vitro models of brain hypoxic injury.…”

Section: In Vitro Models For Real-time Imaging Of Cell Signaling Amentioning

confidence: 99%

Genetically Encoded Tools for Research of Cell Signaling and Metabolism under Brain Hypoxia

et al. 2020

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Hypoxia is characterized by low oxygen content in the tissues. The central nervous system (CNS) is highly vulnerable to a lack of oxygen. Prolonged hypoxia leads to the death of brain cells, which underlies the development of many pathological conditions. Despite the relevance of the topic, different approaches used to study the molecular mechanisms of hypoxia have many limitations. One promising lead is the use of various genetically encoded tools that allow for the observation of intracellular parameters in living systems. In the first part of this review, we provide the classification of oxygen/hypoxia reporters as well as describe other genetically encoded reporters for various metabolic and redox parameters that could be implemented in hypoxia studies. In the second part, we discuss the advantages and disadvantages of the primary hypoxia model systems and highlight inspiring examples of research in which these experimental settings were combined with genetically encoded reporters.

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Dopamine metabolism by a monoamine oxidase mitochondrial shuttle activates the electron transport chain

Cited by 126 publications

References 27 publications

The Role of Oxidative Stress in Parkinson’s Disease

The Role of Oxidative Stress in Parkinson’s Disease

Calcium, Bioenergetics, and Parkinson’s Disease

Genetically Encoded Tools for Research of Cell Signaling and Metabolism under Brain Hypoxia

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