Your search keyword '"Egor Turovsky"' showing total 8 results

1. Novel Hydroxypyridine Compound Protects Brain Cells against Ischemic Damage In Vitro and In Vivo

Author

Ekaterina Blinova, Egor Turovsky, Elena Eliseikina, Alexandra Igrunkova, Elena Semeleva, Grigorii Golodnev, Rita Termulaeva, Olga Vasilkina, Sofia Skachilova, Yan Mazov, Kirill Zhandarov, Ekaterina Simakina, Konstantin Belanov, Saveliy Zalogin, and Dmitrii Blinov

Subjects

experimental brain ischemia, cerebral cortex cell culture, glucose-oxygen deprivation, hydroxypyridine compound, cell death, oxidative stress, Biology (General), QH301-705.5, Chemistry, QD1-999

Abstract

A non-surgical pharmacological approach to control cellular vitality and functionality during ischemic and/or reperfusion-induced phases of strokes remains extremely important. The synthesis of 2-ethyl-6-methyl-3-hydroxypyridinium gammalactone-2,3-dehydro-L-gulonate (3-EA) was performed using a topochemical reaction. The cell-protective effects of 3-EA were studied on a model of glutamate excitotoxicity (GluTox) and glucose-oxygen deprivation (OGD) in a culture of NMRI mice cortical cells. Ca2+ dynamics was studied using fluorescent bioimaging and a Fura-2 probe, cell viability was assessed using cytochemical staining with propidium iodide, and gene expression was assessed by a real-time polymerase chain reaction. The compound anti-ischemic efficacy in vivo was evaluated on a model of irreversible middle cerebral artery (MCA) occlusion in Sprague-Dawley male rats. Brain morphological changes and antioxidant capacity were assessed one week after the pathology onset. The severity of neurological disorder was evaluated dynamically. 3-EA suppressed cortical cell death in a dose-dependent manner under the excitotoxic effect of glutamate and ischemia/reoxygenation. Pre-incubation of cerebral cortex cells with 10–100 µM 3-EA led to significant stagnation in Ca2+ concentration in a cytosol ([Ca2+]i) of neurons and astrocytes suffering GluTox and OGD. Decreasing intracellular Ca2+ and establishing a lower [Ca2+]i baseline inhibited necrotic cell death in an acute experiment. The mechanism of 3-EA cytoprotective action involved changes in the baseline and ischemia/reoxygenation-induced expression of genes encoding anti-apoptotic proteins and proteins of the oxidative status; this led to inhibition of the late irreversible stages of apoptosis. Incubation of brain cortex cells with 3-EA induced an overexpression of the anti-apoptotic genes BCL-2, STAT3, and SOCS3, whereas the expression of genes regulating necrosis and inflammation (TRAIL, MLKL, Cas-1, Cas-3, IL-1β and TNFa) were suppressed. 3-EA 18.0 mg/kg intravenous daily administration for 7 days following MCA occlusion preserved rats’ cortex neuron population, decreased the severity of neurological deficit, and spared antioxidant capacity of damaged tissues. 3-EA demonstrated proven short-term anti-ischemic activity in vivo and in vitro, which can be associated with antioxidant activity and the ability to target necrotic and apoptotic death. The compound may be considered a potential neuroprotective molecule for further pre-clinical investigation.

Published

2022

2. NMDA receptor modulation of glutamate release in activated neutrophilsResearch in context

Author

Ana Gutierrez del Arroyo, Anna Hadjihambi, Jenifer Sanchez, Egor Turovsky, Vitaly Kasymov, David Cain, Tom D. Nightingale, Simon Lambden, Seth G.N. Grant, Alexander V. Gourine, and Gareth L. Ackland

Subjects

Medicine, Medicine (General), R5-920

Abstract

Background: Neutrophil depletion improves neurologic outcomes in experimental sepsis/brain injury. We hypothesized that neutrophils may exacerbate neuronal injury through the release of neurotoxic quantities of the neurotransmitter glutamate. Methods: Real-time glutamate release by primary human neutrophils was determined using enzymatic biosensors. Bacterial and direct protein-kinase C (Phorbol 12-myristate 13-acetate; PMA) activation of neutrophils in human whole blood, isolated neutrophils or human cell lines were compared in the presence/absence of N-Methyl-d-aspartic acid receptor (NMDAR) antagonists. Bacterial and direct activation of neutrophils from wild-type and transgenic murine neutrophils deficient in NMDAR-scaffolding proteins were compared using flow cytometry (phagocytosis, reactive oxygen species (ROS) generation) and real-time respirometry (oxygen consumption). Findings: Both glutamate and the NMDAR co-agonist d-serine are rapidly released by neutrophils in response to bacterial and PMA-induced activation. Pharmacological NMDAR blockade reduced both the autocrine release of glutamate, d-serine and the respiratory burst by activated primary human neutrophils. A highly specific small-molecule inhibitor ZL006 that limits NMDAR-mediated neuronal injury also reduced ROS by activated neutrophils in a murine model of peritonitis, via uncoupling of the NMDAR GluN2B subunit from its' scaffolding protein, postsynaptic density protein-95 (PSD-95). Genetic ablation of PSD-95 reduced ROS production by activated murine neutrophils. Pharmacological blockade of the NMDAR GluN2B subunit reduced primary human neutrophil activation induced by Pseudomonas fluorescens, a glutamate-secreting Gram-negative bacillus closely related to pathogens that cause hospital-acquired infections. Interpretation: These data suggest that release of glutamate by activated neutrophils augments ROS production in an autocrine manner via actions on NMDAR expressed by these cells. Fund: GLA: Academy Medical Sciences/Health Foundation Clinician Scientist. AVG is a Wellcome Trust Senior Research Fellow. Keywords: Glutamate, Inflammation

Published

2019

3. Size-Dependent Cytoprotective Effects of Selenium Nanoparticles during Oxygen-Glucose Deprivation in Brain Cortical Cells

Author

Egor Turovsky, Elena Varlamova, Egor Plotnikov, and Sergey Gudkov

Subjects

oxygen-glucose deprivation, cell death, cortex, astrocyte, neurons, cell protection, signaling, selenoproteins, selenium nanoparticles, calcium, gene expression, Organic Chemistry, Brain, General Medicine, Catalysis, Computer Science Applications, Oxygen, Inorganic Chemistry, Selenium, Glucose, Humans, Nanoparticles, Gliosis, Physical and Theoretical Chemistry, Molecular Biology, Spectroscopy

Abstract

It is known that selenium nanoparticles (SeNPs) obtained on their basis have a pleiotropic effect, inducing the process of apoptosis in tumor cells, on the one hand, and protecting healthy tissue cells from death under stress, on the other hand. It has been established that SeNPs protect brain cells from ischemia/reoxygenation through activation of the Ca2+ signaling system of astrocytes and reactive astrogliosis. At the same time, for a number of particles, the limitations of their use, associated with their size, are shown. The use of nanoparticles with a diameter of less than 10 nm leads to their short life-time in the bloodstream and rapid removal by the liver. Nanoparticles larger than 200 nm activate the complement system and are also quickly removed from the blood. The effects of different-sized SeNPs on brain cells have hardly been studied. Using the laser ablation method, we obtained SeNPs of various diameters: 50 nm, 100 nm, and 400 nm. Using fluorescence microscopy, vitality tests, PCR analysis, and immunocytochemistry, it was shown that all three types of the different-sized SeNPs have a cytoprotective effect on brain cortex cells under conditions of oxygen-glucose deprivation (OGD) and reoxygenation (R), suppressing the processes of necrotic death and inhibiting different efficiency processes of apoptosis. All of the studied SeNPs activate the Ca2+ signaling system of astrocytes, while simultaneously inducing different types of Ca2+ signals. SeNPs sized at 50 nm- induce Ca2+ responses of astrocytes in the form of a gradual irreversible increase in the concentration of cytosolic Ca2+ ([Ca2+]i), 100 nm-sized SeNPs induce stable Ca2+ oscillations without increasing the base level of [Ca2+]i, and 400 nm-sized SeNPs cause mixed patterns of Ca2+ signals. Such differences in the level of astrocyte Ca2+ signaling can explain the different cytoprotective efficacy of SeNPs, which is expressed in the expression of protective proteins and the activation of reactive astrogliosis. In terms of the cytoprotective efficiency under OGD/R conditions, different-sized SeNPs can be arranged in descending order: 100 nm-sized > 400 nm-sized > 50 nm-sized.

Published

2022

4. The Protective Mechanism of Deuterated Linoleic Acid Involves the Activation of the Ca2+ Signaling System of Astrocytes in Ischemia In Vitro

Author

Egor Turovsky, Elena Varlamova, Egor Plotnikov, and Sergey Gudkov

Subjects

oxygen-glucose deprivation, cell death, cortex, astrocyte, cell protection, signaling, ROS, deuterated linoleic polyunsaturated fatty acid, QH301-705.5, Organic Chemistry, General Medicine, Catalysis, Computer Science Applications, Inorganic Chemistry, Chemistry, nervous system, Biology (General), Physical and Theoretical Chemistry, QD1-999, Molecular Biology, Spectroscopy

Abstract

Ischemia-like (oxygen-glucose deprivation, OGD) conditions followed by reoxygenation (OGD/R) cause massive death of cerebral cortex cells in culture as a result of the induction of necrosis and apoptosis. Cell death occurs as a result of an OGD-induced increase in Ca2+ ions in the cytosol of neurons and astrocytes, an increase in the expression of genes encoding proapoptotic and inflammatory genes with suppression of protective genes. The deuterated form of linoleic polyunsaturated fatty acid (D4-Lnn) completely inhibits necrosis and greatly reduces apoptotic cell death with an increase in the concentration of fatty acid in the medium. It was shown for the first time that D4-Lnn, through the activation of the phosphoinositide calcium system of astrocytes, causes their reactivation, which correlates with the general cytoprotective effect on the cortical neurons and astrocytes in vitro. The mechanism of the cytoprotective action of D4-Lnn involves the inhibition of the OGD-induced calcium ions, increase in the cytosolic and reactive oxygen species (ROS) overproduction, the enhancement of the expression of protective genes, and the suppression of damaging proteins.

Published

2021

5. Neuronal Calcium Sensor-1 Protects Cortical Neurons from Hyperexcitation and Ca2+ Overload during Ischemia by Protecting the Population of GABAergic Neurons

Author

Egor Turovsky, Elena Varlamova, and Egor Plotnikov

Subjects

Inorganic Chemistry, Organic Chemistry, neuronal calcium sensor-1, oxygen-glucose deprivation, cell death, cortex, neurons, neuroprotection, signaling, calcium, gene expression, GABA, apoptosis, necrosis, General Medicine, Physical and Theoretical Chemistry, Molecular Biology, Spectroscopy, Catalysis, Computer Science Applications

Abstract

A defection of blood circulation in the brain leads to ischemia, damage, and the death of nerve cells. It is known that individual populations of GABAergic neurons are the least resistant to the damaging factors of ischemia and therefore they die first of all, which leads to impaired inhibition in neuronal networks. To date, the neuroprotective properties of a number of calcium-binding proteins (calbindin, calretinin, and parvalbumin), which are markers of GABAergic neurons, are known. Neuronal calcium sensor-1 (NCS-1) is a signaling protein that is expressed in all types of neurons and is involved in the regulation of neurotransmission. The role of NCS-1 in the protection of neurons and especially their individual populations from ischemia and hyperexcitation has not been practically studied. In this work, using the methods of fluorescence microscopy, vitality tests, immunocytochemistry, and PCR analysis, the molecular mechanisms of the protective action of NCS-1 in ischemia/reoxygenation and hyperammonemia were established. Since NCS-1 is most expressed in GABAergic neurons, the knockdown of this protein with siRNA led to the most pronounced consequences in GABAergic neurons. The knockdown of NCS-1 (NCS-1-KD) suppressed the basic expression of protective proteins without significantly reducing cell viability. However, ischemia-like conditions (oxygen-glucose deprivation, OGD) and subsequent 24-h reoxygenation led to a more massive activation of apoptosis and necrosis in neurons with NCS-1-KD, compared to control cells. The mass death of NCS-1-KD cells during OGD and hyperammonemia has been associated with the induction of a more pronounced network hyperexcitation symptom, especially in the population of GABAergic neurons, leading to a global increase in cytosolic calcium ([Ca2+]i). The symptom of hyperexcitation of neurons with NCS-1-KD correlated with a decrease in the level of expression of the calcium-binding protein-parvalbumin. This was accompanied by an increase in the expression of excitatory ionotropic glutamate receptors, N-methyl-D-aspartate and α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors (NMDAR and AMPAR) against the background of suppression of the expression of glutamate decarboxylase (synthesis of γ-aminobutyric acid).

Published

2022

6. Activation of Cx-43 Hemichannels Induces the Generation of Ca2+-Oscillations in White Adipocytes and Stimulates Lipolysis

Author

Maria Turovskaya and Egor Turovsky

Abstract

With fluorescence microscopy, it was revealed that a decrease in the concentration of extracellular calcium ([Ca2+]ex) results in two types of Ca2+-responses in white adipocytes: Ca2+-oscillations and transient Ca2+-signals. Activation of connexin hemichannels is involved in the mechanism of generation of Ca2+-oscillations, since the blockers of connexin hemichannels - carbenoxolone, octanol and proadifen, as well as Cx43 gene knock-down lead to complete suppression of these signals. TIRF microscopy confirmed activation of Cx-43 in response to the reduction of [Ca2+]ex. In response to the activation of Cx-43, the secretion of ATP-containing vesicles from adipocytes occurs. And this ATP release is suppressed in adipocytes along with the Cx43 gene knock-down and is inhibited by Bafilomycin A1, a vacuolar ATPase inhibitor. At the level of intracellular signaling, the generation of Ca2+-oscillations in white adipocytes in response to a decrease in [Ca2+]ex takes place due to the mobilization of Ca2 + ions from the thapsigargin-sensitive Ca2+-pool in the endoplasmic reticulum via IP3R as a result of the activation of P2Y1 purinergic receptors and the phosphoinositide signaling pathway. Such paracrine activation of white adipose tissue in response to the opening of Cx43 hemichannels leads to local signal propagation and regulation of gene expression. At 24 hours after activation of Cx-43 and generation of Ca2+-oscillations in white adipocytes, there is a change in the expression of key genes involved in the regulation of lipolysis, which is accompanied by a decrease in the number of adipocytes that contained lipid droplets. Meanwhile, inhibition or knock-down of Cx-43 leads to inhibition of lipolysis and accumulation of lipid droplets. In this study, we elucidate and research the mechanism of generation of Ca2+-oscillations in white adipocytes in response to decreased concentration of Ca2 + ions in the external environment and show the correlation between periodic Ca2+-modes and lipolysis/lipogenesis balance regulation.

Published

2021

7. Brain metabolic sensing and metabolic signaling at the level of an astrocyte

Author

Nephtali, Marina, Egor, Turovsky, Isabel N, Christie, Patrick S, Hosford, Anna, Hadjihambi, Alla, Korsak, Richard, Ang, Svetlana, Mastitskaya, Shahriar, Sheikhbahaei, Shefeeq M, Theparambil, and Alexander V, Gourine

Subjects

food intake, breathing, Astrocytes, chemoreception, REVIEW ARTICLES, Animals, Brain, Humans, Review Article, Glial Specific Contributions to Brain Energy Metabolism, metabolism, brainstem, gut hormone

Abstract

Astrocytes support neuronal function by providing essential structural and nutritional support, neurotransmitter trafficking and recycling and may also contribute to brain information processing. In this article we review published results and report new data suggesting that astrocytes function as versatile metabolic sensors of central nervous system (CNS) milieu and play an important role in the maintenance of brain metabolic homeostasis. We discuss anatomical and functional features of astrocytes that allow them to detect and respond to changes in the brain parenchymal levels of metabolic substrates (oxygen and glucose), and metabolic waste products (carbon dioxide). We report data suggesting that astrocytes are also sensitive to circulating endocrine signals—hormones like ghrelin, glucagon‐like peptide‐1 and leptin, that have a major impact on the CNS mechanisms controlling food intake and energy balance. We discuss signaling mechanisms that mediate communication between astrocytes and neurons and consider how these mechanisms are recruited by astrocytes activated in response to various metabolic challenges. We review experimental data suggesting that astrocytes modulate the activities of the respiratory and autonomic neuronal networks that ensure adaptive changes in breathing and sympathetic drive in order to support the physiological and behavioral demands of the organism in ever‐changing environmental conditions. Finally, we discuss evidence suggesting that altered astroglial function may contribute to the pathogenesis of disparate neurological, respiratory and cardiovascular disorders such as Rett syndrome and systemic arterial hypertension., Main Points Astrocytes are versatile CNS sensors capable of detecting various metabolic and endocrine signals.Astrocytes modulate the activities of the brainstem respiratory and autonomic neuronal circuits that ensure metabolic homeostasis.

Published

2017

8. Mechanisms of CO2/H+ Sensitivity of Astrocytes

Author

Egor, Turovsky, Shefeeq M, Theparambil, Vitaliy, Kasymov, Joachim W, Deitmer, Ana Gutierrez, Del Arroyo, Gareth L, Ackland, Jason J, Corneveaux, April N, Allen, Matthew J, Huentelman, Sergey, Kasparov, Nephtali, Marina, and Alexander V, Gourine

Subjects

Respiration, Sodium-Bicarbonate Symporters, Sodium, Carbon Dioxide, Hydrogen-Ion Concentration, In Vitro Techniques, Exocytosis, Sodium-Calcium Exchanger, Rats, Bicarbonates, Adenosine Triphosphate, Astrocytes, Animals, Calcium Signaling, Neuroglia, Research Articles, Hydrogen, Signal Transduction

Abstract

Ventral regions of the medulla oblongata of the brainstem are populated by astrocytes sensitive to physiological changes in PCO2/[H+]. These astrocytes respond to decreases in pH with elevations in intracellular Ca2+ and facilitated exocytosis of ATP-containing vesicles. Released ATP propagates Ca2+ excitation among neighboring astrocytes and activates neurons of the brainstem respiratory network triggering adaptive increases in breathing. The mechanisms linking increases in extracellular and/or intracellular PCO2/[H+] with Ca2+ responses in chemosensitive astrocytes remain unknown. Fluorescent imaging of changes in [Na+]i and/or [Ca2+]i in individual astrocytes was performed in organotypic brainstem slice cultures and acute brainstem slices of adult rats. It was found that astroglial [Ca2+]i responses triggered by decreases in pH are preceded by Na+ entry, markedly reduced by inhibition of Na+/HCO3− cotransport (NBC) or Na+/Ca2+ exchange (NCX), and abolished in Na+-free medium or by combined NBC/NCX blockade. Acidification-induced [Ca2+]i responses were also dramatically reduced in brainstem astrocytes of mice deficient in the electrogenic Na+/HCO3− cotransporter NBCe1. Sensitivity of astrocytes to changes in pH was not affected by inhibition of Na+/H+ exchange or blockade of phospholipase C. These results suggest that in pH-sensitive astrocytes, acidification activates NBCe1, which brings Na+ inside the cell. Raising [Na+]i activates NCX to operate in a reverse mode, leading to Ca2+ entry followed by activation of downstream signaling pathways. Coupled NBC and NCX activities are, therefore, suggested to be responsible for functional CO2/H+ sensitivity of astrocytes that contribute to homeostatic regulation of brain parenchymal pH and control of breathing.

Published

2016