Assessment of ROS Production in the Mitochondria of Live Cells
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01.01.2021 |
Angelova P.R.
Dinkova-Kostova A.T.
Abramov A.Y.
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Methods in molecular biology (Clifton, N.J.) |
10.1007/978-1-0716-0896-8_2 |
0 |
Ссылка
Production of reactive oxygen species (ROS) in the mitochondria plays multiple roles in physiology, and excessive production of ROS leads to the development of various pathologies. ROS in the mitochondria are generated by various enzymes, mainly in the electron transporvt chain, and it is important to identify not only the trigger but also the source of free radical production. It is important to measure mitochondrial ROS in live, intact cells, because activation of ROS production could be initiated by changes in extramitochondrial processes which could be overseen when using isolated mitochondria. Here we describe the approaches, which allow to measure production of ROS in the matrix of mitochondria in live cells. We also demonstrate how to measure kinetic changes in lipid peroxidation in mitochondria of live cells. These methods could be used for understanding the mechanisms of pathology in a variety of disease models and also for testing neuro- or cardioprotective chemicals.
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Assessment of ROS Production in the Mitochondria of Live Cells
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01.01.2021 |
Angelova P.R.
Dinkova-Kostova A.T.
Abramov A.Y.
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Methods in molecular biology (Clifton, N.J.) |
10.1007/978-1-0716-0896-8_2 |
0 |
Ссылка
Production of reactive oxygen species (ROS) in the mitochondria plays multiple roles in physiology, and excessive production of ROS leads to the development of various pathologies. ROS in the mitochondria are generated by various enzymes, mainly in the electron transporvt chain, and it is important to identify not only the trigger but also the source of free radical production. It is important to measure mitochondrial ROS in live, intact cells, because activation of ROS production could be initiated by changes in extramitochondrial processes which could be overseen when using isolated mitochondria. Here we describe the approaches, which allow to measure production of ROS in the matrix of mitochondria in live cells. We also demonstrate how to measure kinetic changes in lipid peroxidation in mitochondria of live cells. These methods could be used for understanding the mechanisms of pathology in a variety of disease models and also for testing neuro- or cardioprotective chemicals.
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Mitochondrial damage & lipid signaling in traumatic brain injury
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01.07.2020 |
Lamade A.M.
Anthonymuthu T.S.
Hier Z.E.
Gao Y.
Kagan V.E.
Bayır H.
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Experimental Neurology |
10.1016/j.expneurol.2020.113307 |
0 |
Ссылка
© 2020 Elsevier Inc. Mitochondria are essential for neuronal function because they serve not only to sustain energy and redox homeostasis but also are harbingers of death. A dysregulated mitochondrial network can cascade until function is irreparably lost, dooming cells. TBI is most prevalent in the young and comes at significant personal and societal costs. Traumatic brain injury (TBI) triggers a biphasic and mechanistically heterogenous response and this mechanistic heterogeneity has made the development of standardized treatments challenging. The secondary phase of TBI injury evolves over hours and days after the initial insult, providing a window of opportunity for intervention. However, no FDA approved treatment for neuroprotection after TBI currently exists. With recent advances in detection techniques, there has been increasing recognition of the significance and roles of mitochondrial redox lipid signaling in both acute and chronic central nervous system (CNS) pathologies. Oxidized lipids and their downstream products result from and contribute to TBI pathogenesis. Therapies targeting the mitochondrial lipid composition and redox state show promise in experimental TBI and warrant further exploration. In this review, we provide 1) an overview for mitochondrial redox homeostasis with emphasis on glutathione metabolism, 2) the key mechanisms of TBI mitochondrial injury, 3) the pathways of mitochondria specific phospholipid cardiolipin oxidation, and 4) review the mechanisms of mitochondria quality control in TBI with consideration of the roles lipids play in this process.
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Mitochondrial damage & lipid signaling in traumatic brain injury
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01.07.2020 |
Lamade A.M.
Anthonymuthu T.S.
Hier Z.E.
Gao Y.
Kagan V.E.
Bayır H.
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Experimental Neurology |
10.1016/j.expneurol.2020.113307 |
0 |
Ссылка
© 2020 Elsevier Inc. Mitochondria are essential for neuronal function because they serve not only to sustain energy and redox homeostasis but also are harbingers of death. A dysregulated mitochondrial network can cascade until function is irreparably lost, dooming cells. TBI is most prevalent in the young and comes at significant personal and societal costs. Traumatic brain injury (TBI) triggers a biphasic and mechanistically heterogenous response and this mechanistic heterogeneity has made the development of standardized treatments challenging. The secondary phase of TBI injury evolves over hours and days after the initial insult, providing a window of opportunity for intervention. However, no FDA approved treatment for neuroprotection after TBI currently exists. With recent advances in detection techniques, there has been increasing recognition of the significance and roles of mitochondrial redox lipid signaling in both acute and chronic central nervous system (CNS) pathologies. Oxidized lipids and their downstream products result from and contribute to TBI pathogenesis. Therapies targeting the mitochondrial lipid composition and redox state show promise in experimental TBI and warrant further exploration. In this review, we provide 1) an overview for mitochondrial redox homeostasis with emphasis on glutathione metabolism, 2) the key mechanisms of TBI mitochondrial injury, 3) the pathways of mitochondria specific phospholipid cardiolipin oxidation, and 4) review the mechanisms of mitochondria quality control in TBI with consideration of the roles lipids play in this process.
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Mitochondrial permeability transition pore is involved in oxidative burst and NETosis of human neutrophils
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01.05.2020 |
Vorobjeva N.
Galkin I.
Pletjushkina O.
Golyshev S.
Zinovkin R.
Prikhodko A.
Pinegin V.
Kondratenko I.
Pinegin B.
Chernyak B.
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Biochimica et Biophysica Acta - Molecular Basis of Disease |
10.1016/j.bbadis.2020.165664 |
0 |
Ссылка
© 2020 Elsevier B.V. Neutrophils release neutrophil extracellular traps (NETs) in response to numerous pathogenic microbes as the last suicidal resource (NETosis) in the fight against infection. Apart from the host defense function, NETs play an essential role in the pathogenesis of various autoimmune and inflammatory diseases. Therefore, understanding the molecular mechanisms of NETosis is important for regulating aberrant NET release. The initiation of NETosis after the recognition of pathogens by specific receptors is mediated by an increase in intracellular Ca2+ concentration, therefore, the use of Ca2+ ionophore A23187 can be considered a semi-physiological model of NETosis. Induction of NETosis by various stimuli depends on reactive oxygen species (ROS) produced by NADPH oxidase, however, NETosis induced by Ca2+ ionophores was suggested to be mediated by ROS produced in mitochondria (mtROS). Using the mitochondria-targeted antioxidant SkQ1 and specific inhibitors of NADPH oxidase, we showed that both sources of ROS, mitochondria and NADPH oxidase, are involved in NETosis induced by A23187 in human neutrophils. In support of the critical role of mtROS, SkQ1-sensitive NETosis was demonstrated to be induced by A23187 in neutrophils from patients with chronic granulomatous disease (CGD). We assume that Ca2+-triggered mtROS production contributes to NETosis either directly (CGD neutrophils) or by stimulating NADPH oxidase. The opening of the mitochondrial permeability transition pore (mPTP) in neutrophils treated by A23187 was revealed using the electron transmission microscopy as a swelling of the mitochondrial matrix. Using specific inhibitors, we demonstrated that the mPTP is involved in mtROS production, NETosis, and the oxidative burst induced by A23187.
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Lipid peroxidation is involved in calcium dependent upregulation of mitochondrial metabolism in skeletal muscle
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01.03.2020 |
Al-Menhali A.
Banu S.
Angelova P.
Barcaru A.
Horvatovich P.
Abramov A.
Jaganjac M.
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Biochimica et Biophysica Acta - General Subjects |
10.1016/j.bbagen.2019.129487 |
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© 2019 Elsevier B.V. Background: Skeletal muscle cells continuously generate reactive oxygen species (ROS). Excessive ROS can affect lipids resulting in lipid peroxidation (LPO). Here we investigated the effects of myotube intracellular calcium-induced signaling eliciting contractions on the LPO induction and the impact of LPO-product 4-hydroxynonenal (4-HNE) on physiology/pathology of myotubes using C2C12 myoblasts. Methods: C2C12 myoblasts were differentiated into myotubes, stimulated with caffeine and analyzed for the induction of LPO and formation of 4-HNE protein adducts. Further effects of 4-HNE on mitochondrial bioenergetics, NADH level, mitochondrial density and expression of mitochondrial metabolism genes were determined. Results: Short and long-term caffeine stimulation of myotubes promoted superoxide production, LPO and formation of 4-HNE protein adducts. Furthermore, low 4-HNE concentrations had no effect on myotube viability and cellular redox homeostasis, while concentrations from 10 μM and above reduced myotube viability and significantly disrupted homeostasis. A time and dose-dependent 4-HNE effect on superoxide production and mitochondrial NADH-autofluorescence was observed. Finally, 4-HNE had strong impact on maximal respiration, spare respiratory capacity, ATP production, coupling efficiency of mitochondria and mitochondrial density. Conclusion: Data presented in this work make evident for the first time that pathological 4-HNE levels elicit damaging effects on skeletal muscle cells while acute exposure to physiological 4-HNE induces transient adaptation. General significance: This work suggests an important role of 4-HNE on the regulation of myotube's mitochondrial metabolism and cellular energy production. It further signifies the importance of skeletal muscle cells hormesis in response to acute stress in order to maintain essential biological functions.
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Dietary nitrate attenuates high-fat diet-induced obesity via mechanisms involving higher adipocyte respiration and alterations in inflammatory status
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01.01.2020 |
Peleli M.
Ferreira D.
Tarnawski L.
McCann Haworth S.
Xuechen L.
Zhuge Z.
Newton P.
Massart J.
Chagin A.
Olofsson P.
Ruas J.
Weitzberg E.
Lundberg J.
Carlström M.
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Redox Biology |
10.1016/j.redox.2019.101387 |
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© 2019 The Authors Emerging evidence indicates that dietary nitrate can reverse several features of the metabolic syndrome, but the underlying molecular mechanisms still remain elusive. The aim of the present study was to explore mechanisms involved in the effects of dietary nitrate on the metabolic dysfunctions induced by high-fat diet (HFD) in mice. Four weeks old C57BL/6 male mice, exposed to HFD for ten weeks, were characterised by increased body weight, fat content, increased fasting glucose and impaired glucose clearance. All these metabolic abnormalities were significantly attenuated by dietary nitrate. Mechanistically, subcutaneous primary mouse adipocytes exposed to palmitate (PA) and treated with nitrite exhibited higher mitochondrial respiration, increased protein expression of total mitochondrial complexes and elevated gene expression of the thermogenesis gene UCP-1, as well as of the creatine transporter SLC6A8. Finally, dietary nitrate increased the expression of anti-inflammatory markers in visceral fat, plasma and bone marrow-derived macrophages (Arginase-1, Egr-2, IL-10), which was associated with reduction of NADPH oxidase-derived superoxide production in macrophages. In conclusion, dietary nitrate may have therapeutic utility against obesity and associated metabolic complications possibly by increasing adipocyte mitochondrial respiration and by dampening inflammation and oxidative stress.
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In silico simulation of reversible and irreversible swelling of mitochondria: The role of membrane rigidity
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01.01.2020 |
Makarov V.
Khmelinskii I.
Khuchua Z.
Javadov S.
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Mitochondrion |
10.1016/j.mito.2019.09.006 |
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Ссылка
© 2019 Elsevier B.V. and Mitochondria Research Society Mitochondria have been widely accepted as the main source of ATP in the cell. The inner mitochondrial membrane (IMM) is important for the maintenance of ATP production and other functions of mitochondria. The electron transport chain (ETC) generates an electrochemical gradient of protons known as the proton-motive force across the IMM and thus produces the mitochondrial membrane potential that is critical to ATP synthesis. One of the main factors regulating the structural and functional integrity of the IMM is the changes in the matrix volume. Mild (reversible) swelling regulates mitochondrial metabolism and function; however, excessive (irreversible) swelling causes mitochondrial dysfunction and cell death. The central mechanism of mitochondrial swelling includes the opening of non-selective channels known as permeability transition pores (PTPs) in the IMM by high mitochondrial Ca2+ and reactive oxygen species (ROS). The mechanisms of reversible and irreversible mitochondrial swelling and transition between these two states are still unknown. The present study elucidates an upgraded biophysical model of reversible and irreversible mitochondrial swelling dynamics. The model provides a description of the PTP regulation dynamics using an additional differential equation. The rigidity tensor was used in numerical simulations of the mitochondrial parameter dynamics with different initial conditions defined by Ca2+ concentration in the sarco/endoplasmic reticulum. We were able to estimate the values of the IMM rigidity tensor components by fitting the model to the previously reported experimental data. Overall, the model provides a better description of the reversible and irreversible mitochondrial swelling dynamics.
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Interrogating Parkinson's disease associated redox targets: Potential application of CRISPR editing
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20.11.2019 |
Artyukhova M.
Tyurina Y.
Chu C.
Zharikova T.
Bayır H.
Kagan V.
Timashev P.
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Free Radical Biology and Medicine |
10.1016/j.freeradbiomed.2019.06.007 |
1 |
Ссылка
© 2019 Elsevier Inc. Loss of dopaminergic neurons in the substantia nigra is one of the pathogenic hallmarks of Parkinson's disease, yet the underlying molecular mechanisms remain enigmatic. While aberrant redox metabolism strongly associated with iron dysregulation and accumulation of dysfunctional mitochondria is considered as one of the major contributors to neurodegeneration and death of dopaminergic cells, the specific anomalies in the molecular machinery and pathways leading to the PD development and progression have not been identified. The high efficiency and relative simplicity of a new genome editing tool, CRISPR/Cas9, make its applications attractive for deciphering molecular changes driving PD-related impairments of redox metabolism and lipid peroxidation in relation to mishandling of iron, aggregation and oligomerization of alpha-synuclein and mitochondrial injury as well as in mechanisms of mitophagy and programs of regulated cell death (apoptosis and ferroptosis). These insights into the mechanisms of PD pathology may be used for the identification of new targets for therapeutic interventions and innovative approaches to genome editing, including CRISPR/Cas9.
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The 808 nm and 980 nm infrared laser irradiation affects spore germination and stored calcium homeostasis: A comparative study using delivery hand-pieces with standard (Gaussian) or flat-top profile
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01.10.2019 |
Ferrando S.
Agas D.
Mirata S.
Signore A.
De Angelis N.
Ravera S.
Utyuzh A.
Parker S.
Sabbieti M.
Benedicenti S.
Amaroli A.
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Journal of Photochemistry and Photobiology B: Biology |
10.1016/j.jphotobiol.2019.111627 |
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© 2019 Elsevier B.V. Photobiomodulation relies on the transfer of energy from incident photons to a cell photoacceptor. For many years the concept of photobiomodulation and its outcome has been based upon a belief that the sole receptor within the cell was the mitochondrion. Recently, it has become apparent that there are other photoacceptors operating in different regions of the electromagnetic spectrum. Alternative photoacceptors would appear to be water and mechanisms regulating calcium homeostasis, despite a direct effect of laser photonic energy on intracellular calcium concentration outwith mitochondrial activity or influence, have not been clearly demonstrated. Therefore, to increase the knowledge of intracellular‑calcium and laser photon interaction, as well as to demonstrate differences in irradiation profiles with modern hand-pieces, we tested and compared the photobiomodulatory effect of 808 nm and 980 nm diode laser light by low- and higher-energy (60s, 100 mW/cm2, 100 mW/cm2, 500 mW/cm2, 1000 mW/cm2, 1500 mW/cm2, 2000 mW/cm2) irradiated with a “standard” (Gaussian fluence distribution) hand-piece or with a “flat-top” (uniform fluence) hand-piece. For this purpose, we used the eukaryote unicellular-model Dictyostelium discoideum. The 808 nm and 980 nm infrared laser light, at the energy tested directly affect the stored Ca2+ homeostasis, independent of the mitochondrial respiratory chain activities. From an organism perspective, the effect on Ca2+-dependent signal transduction as the regulator of spore germination in Dictyostelium, demonstrates how a cell can respond quickly to the correct laser photonic stimulus through a different cellular pathway than the known light-chromophore(mitochondria) interaction. Additionally, both hand-piece designs tested were able to photobiomodulate the D. discoideum cell; however, the hand-piece with a flat-top profile, through uniform fluence levels allows more effective and reproducible effects.
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Olesoxime in neurodegenerative diseases: Scrutinising a promising drug candidate
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01.10.2019 |
Weber J.
Clemensson L.
Schiöth H.
Nguyen H.
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Biochemical Pharmacology |
10.1016/j.bcp.2019.07.002 |
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Ссылка
© 2019 Elsevier Inc. Over the last years, the experimental compound olesoxime, a mitochondria-targeting cholesterol derivative, has emerged as a promising drug candidate for neurodegenerative diseases. Numerous preclinical studies have successfully proved olesoxime's neuroprotective properties in cell and animal models of clinical conditions such as amyotrophic lateral sclerosis, Huntington disease, Parkinson disease, peripheral neuropathy and spinal muscular atrophy. The beneficial effects were attributed to olesoxime's potential impact on oxidative stress, mitochondrial permeability transition or cholesterol homoeostasis. Although no significant benefits have been demonstrated in patients of amyotrophic lateral sclerosis, and only the first 12 months of a phase II/III clinical trial showed an improvement in motor symptoms of spinal muscular atrophy, this orphan drug may still offer undiscovered potential in the treatment of neurological diseases. In our earlier preclinical studies, we demonstrated that administration of olesoxime in mouse and rat models of Huntington disease improved psychiatric and molecular phenotypes. Aside from stabilising mitochondrial function, the drug reduced the overactivation of calpains, a class of calcium-dependent proteases entangled in neurodegenerative conditions. This observation may be credited to olesoxime's action on calcium dyshomeostasis, a further hallmark in neurodegeneration, and linked to its targets TSPO and VDAC, two proteins of the outer mitochondrial membrane associated with mitochondrial calcium handling. Further research into the mode of action of olesoxime under pathological conditions, including its effect on neuronal calcium homeostasis, may strengthen the untapped potential of olesoxime or other similar compounds as a therapeutic for neurodegenerative diseases.
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Mitochondrial calcium uniporter structure and function in different types of muscle tissues in health and disease
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01.10.2019 |
Tarasova N.
Vishnyakova P.
Logashina Y.
Elchaninov A.
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International Journal of Molecular Sciences |
10.3390/ijms20194823 |
1 |
Ссылка
© 2019 by the authors. Licensee MDPI, Basel, Switzerland. Calcium ions (Ca2+) influx to mitochondrial matrix is crucial for the life of a cell. Mitochondrial calcium uniporter (mtCU) is a protein complex which consists of the pore-forming subunit (MCU) and several regulatory subunits. MtCU is the main contributor to inward Ca2+ currents through the inner mitochondrial membrane. Extensive investigations of mtCU involvement into normal and pathological molecular pathways started from the moment of discovery of its molecular components. A crucial role of mtCU in the control of these pathways is now recognized in both health and disease. In particular, impairments of mtCU function have been demonstrated for cardiovascular and skeletal muscle-associated pathologies. This review summarizes the current state of knowledge on mtCU structure, regulation, and function in different types of muscle tissues in health and disease.
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Insulin Protects Cortical Neurons Against Glutamate Excitotoxicity
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24.09.2019 |
Krasil’nikova I.
Surin A.
Sorokina E.
Fisenko A.
Boyarkin D.
Balyasin M.
Demchenko A.
Pomytkin I.
Pinelis V.
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Frontiers in Neuroscience |
10.3389/fnins.2019.01027 |
0 |
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© Copyright © 2019 Krasil’nikova, Surin, Sorokina, Fisenko, Boyarkin, Balyasin, Demchenko, Pomytkin and Pinelis. Glutamate excitotoxicity is implicated in the pathogenesis of numerous diseases, such as stroke, traumatic brain injury, and Alzheimer’s disease, for which insulin resistance is a concomitant condition, and intranasal insulin treatment is believed to be a promising therapy. Excitotoxicity is initiated primarily by the sustained stimulation of ionotropic glutamate receptors and leads to a rise in intracellular Ca2+ ([Ca2+]i), followed by a cascade of intracellular events, such as delayed calcium deregulation (DCD), mitochondrial depolarization, adenosine triphosphate (ATP) depletion that collectively end in cell death. Therefore, cross-talk between insulin and glutamate signaling in excitotoxicity is of particular interest for research. In the present study, we investigated the effects of short-term insulin exposure on the dynamics of [Ca2+]i and mitochondrial potential in cultured rat cortical neurons during glutamate excitotoxicity. We found that insulin ameliorated the glutamate-evoked rise of [Ca2+]i and prevented the onset of DCD, the postulated point-of-no-return in excitotoxicity. Additionally, insulin significantly improved the glutamate-induced drop in mitochondrial potential, ATP depletion, and depletion of brain-derived neurotrophic factor (BDNF), which is a critical neuroprotector in excitotoxicity. Also, insulin improved oxygen consumption rates, maximal respiration, and spare respiratory capacity in neurons exposed to glutamate, as well as the viability of cells in the MTT assay. In conclusion, the short-term insulin exposure in our experiments was evidently a protective treatment against excitotoxicity, in a sharp contrast to chronic insulin exposure causal to neuronal insulin resistance, the adverse factor in excitotoxicity.
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Neuroprotective effects of mitochondria-targeted plastoquinone in a rat model of neonatal hypoxic–ischemic brain injury
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01.08.2018 |
Silachev D.
Plotnikov E.
Pevzner I.
Zorova L.
Balakireva A.
Gulyaev M.
Pirogov Y.
Skulachev V.
Zorov D.
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Molecules |
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6 |
Ссылка
© 2018 by the authors. Neonatal hypoxia–ischemia is one of the main causes of mortality and disability of newborns. To study the mechanisms of neonatal brain cell damage, we used a model of neonatal hypoxia–ischemia in seven-day-old rats, by annealing of the common carotid artery with subsequent hypoxia of 8% oxygen. We demonstrate that neonatal hypoxia–ischemia causes mitochondrial dysfunction associated with high production of reactive oxygen species, which leads to oxidative stress. Targeted delivery of antioxidants to the mitochondria can be an effective therapeutic approach to treat the deleterious effects of brain hypoxia–ischemia. We explored the neuroprotective properties of the mitochondria-targeted antioxidant SkQR1, which is the conjugate of a plant plastoquinone and a penetrating cation, rhodamine 19. Being introduced before or immediately after hypoxia–ischemia, SkQR1 affords neuroprotection as judged by the diminished brain damage and recovery of long-term neurological functions. Using vital sections of the brain, SkQR1 has been shown to reduce the development of oxidative stress. Thus, the mitochondrial-targeted antioxidant derived from plant plastoquinone can effectively protect the brain of newborns both in pre-ischemic and post-stroke conditions, making it a promising candidate for further clinical studies.
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Mitochondrial membrane potential
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01.07.2018 |
Zorova L.
Popkov V.
Plotnikov E.
Silachev D.
Pevzner I.
Jankauskas S.
Babenko V.
Zorov S.
Balakireva A.
Juhaszova M.
Sollott S.
Zorov D.
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Analytical Biochemistry |
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63 |
Ссылка
© 2017 The mitochondrial membrane potential (ΔΨm) generated by proton pumps (Complexes I, III and IV) is an essential component in the process of energy storage during oxidative phosphorylation. Together with the proton gradient (ΔpH), ΔΨm forms the transmembrane potential of hydrogen ions which is harnessed to make ATP. The levels of ΔΨm and ATP in the cell are kept relatively stable although there are limited fluctuations of both these factors that can occur reflecting normal physiological activity. However, sustained changes in both factors may be deleterious. A long-lasting drop or rise of ΔΨm vs normal levels may induce unwanted loss of cell viability and be a cause of various pathologies. Among other factors, ΔΨm plays a key role in mitochondrial homeostasis through selective elimination of dysfunctional mitochondria. It is also a driving force for transport of ions (other than H+) and proteins which are necessary for healthy mitochondrial functioning. We propose additional potential mechanisms for which ΔΨm is essential for maintenance of cellular health and viability and provide recommendations how to accurately measure ΔΨm in a cell and discuss potential sources of artifacts.
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Proteomics of mammalian mitochondria in health and malignancy: From protein identification to function
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01.07.2018 |
Eremina L.
Pashintseva N.
Kovalev L.
Kovaleva M.
Shishkin S.
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Analytical Biochemistry |
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3 |
Ссылка
© 2017 Elsevier Inc. The mitochondrial set of proteins is a dynamic system, crucial for multiple functions of this organelle. Differential expression of genes in various tissues, alternative splicing, post-translational modifications, turnover and spatial dynamics of proteins are the factors that influence mitochondrial proteomes increasing their versatility. A wide range of high-throughput proteomic approaches are extensively used for identification, quantification and functional assessment of human and other mammalian mitochondrial proteins. This article reviews the methods and approaches which can be utilized for achieving one or another specific goal in mitochondrial investigations, and the recent advances in application of proteomics to study the roles of mitochondria in tumorigenesis and cancer progression.
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Effects of laser radiation on mitochondria and mitochondrial proteins subjected to nitric oxide
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01.04.2018 |
Osipov A.
Machneva T.
Buravlev E.
Vladimirov Y.
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Frontiers in Medicine |
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0 |
Ссылка
© 2018 Osipov, Machneva, Buravlev and Vladimirov. The biological roles of heme and nonheme nitrosyl complexes in physiological and pathophysiological conditions as metabolic key players are considered in this study. Two main physiological functions of protein nitrosyl complexes are discussed-(1) a depot and potential source of free nitric oxide (NO) and (2) a controller of crucial metabolic processes. The first function is realized through the photolysis of nitrosyl complexes (of hemoglobin, cytochrome c, or mitochondrial iron-sulfur proteins). This reaction produces free NO and subsequent events are due to the NO physiological functions. The second function is implemented by the possibility of NO to bind heme and nonheme proteins and produce corresponding nitrosyl complexes. Enzyme nitrosyl complex formation usually results in the inhibition (or enhancement in the case of guanylate cyclase) of its enzymatic activity. Photolysis of protein nitrosyl complexes, in this case, will restore the original enzymatic activity. Thus, cytochrome c acquires peroxidase activity in the presence of anionic phospholipids, and this phenomenon can be assumed as a key step in the programmed cell death. Addition of NO induces the formation of cytochrome c nitrosyl complexes, inhibits its peroxidase activity, and hinders apoptotic reactions. In this case, photolysis of cytochrome c nitrosyl complexes will reactivate cytochrome c peroxidase activity and speed up apoptosis. Control of mitochondrial respiration by NO by formation or photolytic decay of iron-sulfur protein nitrosyl complexes is an effective instrument to modulate mitochondrial metabolism. These questions are under discussion in this study.
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Effects of laser radiation on mitochondria and mitochondrial proteins subjected to nitric oxide
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01.04.2018 |
Osipov A.
Machneva T.
Buravlev E.
Vladimirov Y.
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Frontiers in Medicine |
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1 |
Ссылка
©2018 Osipov, Machneva, Buravlev and Vladimirov. The biological roles of heme and nonheme nitrosyl complexes in physiological and pathophysiological conditions as metabolic key players are considered in this study. Two main physiological functions of protein nitrosyl complexes are discussed-(1) a depot and potential source of free nitric oxide (NO) and (2) a controller of crucial metabolic processes. The first function is realized through the photolysis of nitrosyl complexes (of hemoglobin, cytochrome c, or mitochondrial iron-sulfur proteins). This reaction produces free NO and subsequent events are due to the NO physiological functions. The second function is implemented by the possibility of NO to bind heme and nonheme proteins and produce corresponding nitrosyl complexes. Enzyme nitrosyl complex formation usually results in the inhibition (or enhancement in the case of guanylate cyclase) of its enzymatic activity. Photolysis of protein nitrosyl complexes, in this case, will restore the original enzymatic activity. Thus, cytochrome c acquires peroxidase activity in the presence of anionic phospholipids, and this phenomenon can be assumed as a key step in the programmed cell death. Addition of NO induces the formation of cytochrome c nitrosyl complexes, inhibits its peroxidase activity, and hinders apoptotic reactions. In this case, photolysis of cytochrome c nitrosyl complexes will reactivate cytochrome c peroxidase activity and speed up apoptosis. Control of mitochondrial respiration by NO by formation or photolytic decay of iron-sulfur protein nitrosyl complexes is an effective instrument to modulate mitochondrial metabolism. These questions are under discussion in this study.
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Ultrastructural and morphofunctional changes in the mitochondrial apparatus of hepatocytes in experimental diffuse purulent peritonitis
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01.01.2018 |
Yarotskaya N.
Gostishev V.
Kosinets V.
Samsonova I.
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Novosti Khirurgii |
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0 |
Ссылка
© 2018 Vitebsk State Medical University. All rights reserved. Objective: To study the ultrastructural changes in the liver mitochondria in experimental diffuse purulent peritonitis against the background of the metabolic support. Methods: The morphometric evaluation of the rabbit liver mitochondria electron microscopic images (n=55) was performed in experimental diffuse purulent peritonitis. The obtained electron diffraction patterns were estimated using the ImageJ 1.45s program, in which the number of mitochondria sections, the number of intermithochondrial contacts and the number of damaged and intact mitochondria were counted. The average area, perimeter, and specific volume (measured in %) were calculated for the undamaged mitochondrial profiles. Metabolic agents with energotropic properties, phosphocreatine preparations containing creatine phosphate and preparations containing the succinic acid, niacinamide, inosine diphosphate and riboflavin were used. Results: Electron microscopic analysis of mitochondria of hepatocytes made it possible to reveal significant changes in their structure, caused by the development of purulent peritonitis. Morphometric evaluation of electron diffraction patterns showed changes in the quantitative and qualitative characteristics of mitochondria: the ratio of the damaged and intact mitochondria, their size, perimeter and specific volume of all groups. The use of metabolic support permitted to reduce the negative effect of purulent peritonitis in the postoperative period, which is exerted on the liver mitochondria, in comparison with the control group of animals that did not receive any metabolic support. Conducting a comparative analysis revealed a higher efficacy of the metabolic agent containing the succinic acid, niacinamide, inosine diphosphate and riboflavin, which resulted in more intensive restoration of the mitochondrial membrane structure. Conclusions: The development of purulent peritonitis is accompanied by a violation of the ultrastructural organization of the liver mitochondria in all studied groups. Metabolic correction allows restoring the membrane structure of mitochondria, and as the result improving the energy supply of cells to combat the negative consequences of endotoxicosis in peritonitis.
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Ventilator-induced diaphragm dysfunction
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01.01.2018 |
Babaev М.
Bykov D.
Birg Т.
Vyzhigina М.
Eremenko А.
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Obshchaya Reanimatologiya |
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© 2018, V.A. Negovsky Research Institute of General Reanimatology. All rights reserved. Mechanical ventilation is associated with a number of complications that increase the cost of treatment and the hospital mortality rate. In 2004, the term «ventilator-induced diaphragm dysfunction» (VIDD) was proposed to explain one of the reasons for the failure of respiratory support. At present, this term is understood as a combination of atrophy and weakness of the contractile function of the diaphragm caused directly by a long-term mechanical lung ventilation. Oxidative stress, proteolysis, mitochondrial dysfunction, as well as passive overdistension of the diaphragm fibers contribute greatly to the pathogenesis of VIDD. Since 30—80% of patients in the ICU require mechanical respiratory support and even 6—8 hours of mechanical lung ventilation can contribute to the development of a significant weakness of the diaphragm, it can be concluded that the VIDD is an extremely urgent problem in most patients. Its typical clinical presentation is characterized by impaired breathing mechanics and unsuccessful attempts to switch the patient to the spontaneous breathing in the absence of other valid reasons for respiratory disorders. The sonography is the most informative and accessible diagnostic method, and preservation of spontaneous breathing activity and the use of the latest mechanical ventilation modes are considered a promising approach to prevention and correction of the disorders. The search for an optimal strategy for lung ventilation, development of diagnostic and physiotherapeutic methods, as well as the consolidation of the work of a multidisciplinary team of specialists (anesthesiologists and intensive care specialists, neurologists, pulmonologists, surgeons, etc.) can help in solving this serious problem. A review of 122 sources about the VIDD presented data on the background of the issue, the definition of the problem, etiology and pathogenesis, clinical manifestations, methods of diagnosis, the effect of drugs, prevention and therapy.
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