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5. Paracrine effect of carbon monoxide - astrocytes promote neuroprotection through purinergic signaling in mice

Author

Queiroga, Cláudia S F, Alves, Raquel M A, Conde, Sílvia V, Alves, Paula M, Vieira, Helena L A, Centro de Estudos de Doenças Crónicas (CEDOC), NOVA Medical School|Faculdade de Ciências Médicas (NMS|FCM), and Instituto de Tecnologia Química e Biológica António Xavier (ITQB)

Subjects
Adenosine, Purinergic, Apoptosis, Preconditioning, Suramin, Models, Biological, Adenosine Triphosphate, Thioinosine, Paracrine Communication, Serine, Animals, Receptor, trkB, Cysteine, Gene Silencing, Carbon monoxide, Co-cultures, Neurons, Carbon Monoxide, Receptors, Adenosine A2, Receptors, Purinergic, Brain, Triazoles, Coculture Techniques, Neuroprotection, Mice, Inbred C57BL, Pyrimidines, nervous system, Astrocytes, Xanthines, Glycyrrhetinic Acid, Extracellular Space, Signal Transduction
Abstract

© 2016. Published by The Company of Biologists Ltd. The neuroprotective role of carbon monoxide (CO) has been studied in a cell-autonomous mode. Herein, a new concept is disclosed - CO affects astrocyte-neuron communication in a paracrine manner to promote neuroprotection. Neuronal survival was assessed when co-cultured with astrocytes that had been pre-treated or not with CO. The CO-pre-treated astrocytes reduced neuronal cell death, and the cellular mechanisms were investigated, focusing on purinergic signaling. CO modulates astrocytic metabolism and extracellular ATP content in the co-culture medium. Moreover, several antagonists of P1 adenosine and P2 ATP receptors partially reverted CO-induced neuroprotection through astrocytes. Likewise, knocking down expression of the neuronal P1 adenosine receptor A2A-R (encoded by Adora2a) reverted the neuroprotective effects of CO-exposed astrocytes. The neuroprotection of CO-treated astrocytes also decreased following prevention of ATP or adenosine release from astrocytic cells and inhibition of extracellular ATP metabolism into adenosine. Finally, the neuronal downstream event involves TrkB (also known as NTRK2) receptors and BDNF. Pharmacological and genetic inhibition of TrkB receptors reverts neuroprotection triggered by CO-treated astrocytes. Furthermore, the neuronal ratio of BDNF to pro-BDNF increased in the presence of CO-treated astrocytes and decreased whenever A2A-R expression was silenced. In summary, CO prevents neuronal cell death in a paracrine manner by targeting astrocytic metabolism through purinergic signaling. publishersversion published

Published
2016

6. Mitochondria and carbon monoxide: cytoprotection and control of cell metabolism – a role for Ca2+?

Author

R. Oliveira, Sara, Queiroga, Cláudia S. F., and Vieira, Helena L. A.

Subjects
Carbon Monoxide, Cell Death, Cytoprotection, Special section reviews: Gaseous regulation of Ca2+ homeostasis, for better or worse?, Animals, Humans, Calcium, Calcium Channels, Reactive Oxygen Species, Mitochondria
Abstract

Carbon monoxide (CO) is an endogenously produced gasotransmitter with important biological functions: anti-inflammation, anti-apoptosis, vasomodulation and cell metabolism modulation. The most recognized cellular target for CO is the mitochondria. Physiological concentrations of CO generate mitochondrial reactive oxygen species (ROS), which are signalling molecules for CO-induced pathways. Indeed, small amounts of ROS promote cytoprotection by a preconditioning effect. Furthermore, CO prevents cell death by limiting mitochondrial membrane permeabilization, which inhibits the release of pro-apoptotic factors into the cytosol; both events are ROS dependent. CO also increases the ability of mitochondria to take up Ca(2+) . Mitochondrial metabolism is modulated by CO, namely by increasing TCA cycle rate, oxidative phosphorylation and mitochondrial biogenesis, which, in turn, increases ATP production. CO's modulation of metabolism might be important for cellular response to diseases, namely cancer and ischaemic diseases. Finally, another cytoprotective role of CO involves the control of Ca(2+) channels. By limiting the activity of T-type and L-type Ca(2+) channels, CO prevents excitotoxicity-induced cell death and modulates cell proliferation. Several questions concerning Ca(2+) signalling, mitochondria and CO can be asked, for instance whether CO modulation of cell metabolism would be dependent on the mitochondrial Ca(2+) uptake capacity, since small amounts of Ca(2+) can increase mitochondrial metabolism. Whether CO controls Ca(2+) communication between mitochondria and endoplasmic reticulum is another open field of research. In summary, CO emerges as a key gasotransmitter in the control of several cellular functions of mitochondria: metabolism, cell death and Ca(2+) signalling.

Published
2015

7. Carbon monoxide and the CNS: challenges and achievements

Author

Queiroga, Cláudia S F, Vercelli, Alessandro, and Vieira, Helena L A

Subjects
Pharmacology, Carbon Monoxide, Cell Death, Themed Section: Pharmacology of the Gasotransmitters, brain, astrocytes, neurodegeneration, microglia, neurons, CO-releasing molecules, carbon monoxide, ischaemia, neuroinflammation, neuroprotection, Prognosis, Central Nervous System Diseases, Heme Oxygenase (Decyclizing), Animals, Homeostasis, Humans
Abstract

Haem oxygenase (HO) and its product carbon monoxide (CO) are associated with cytoprotection and maintenance of homeostasis in several different organs and tissues. This review focuses upon the role of exogenous and endogenous CO (via HO activity and expression) in various CNS pathologies, based upon data from experimental models, as well as from some clinical data on human patients. The pathophysiological conditions reviewed are cerebral ischaemia, chronic neurodegenerative diseases (Alzheimer's and Parkinson's diseases), multiple sclerosis and pain. Among these pathophysiological conditions, a variety of cellular mechanisms and processes are considered, namely cytoprotection, cell death, inflammation, cell metabolism, cellular redox responses and vasomodulation, as well as the different targeted neural cells. Finally, novel potential methods and strategies for delivering exogenous CO as a drug are discussed, particularly approaches based upon CO-releasing molecules, their limitations and challenges. The diagnostic and prognostic value of HO expression in clinical use for brain pathologies is also addressed.

Published
2014

8. Carbon Monoxide Modulates Apoptosis by Reinforcing Oxidative Metabolism in Astrocytes: ROLE OF Bcl-2*

Author

Almeida, Ana S., Queiroga, Cláudia S. F., Sousa, Marcos F. Q., Alves, Paula M., and Vieira, Helena L. A.

Subjects
Carbon Monoxide, Intracellular Space, Apoptosis, macromolecular substances, Cell Biology, Cell Hypoxia, Oxidative Phosphorylation, Mitochondria, Rats, Electron Transport Complex IV, Adenosine Triphosphate, Gene Expression Regulation, Proto-Oncogene Proteins c-bcl-2, Cytoprotection, Astrocytes, Reperfusion Injury, Animals, Oxidation-Reduction
Abstract

Modulation of cerebral cell metabolism for improving the outcome of hypoxia-ischemia and reperfusion is a strategy yet to be explored. Because carbon monoxide (CO) is known to prevent cerebral cell death; herein the role of CO in the modulation of astrocytic metabolism, in particular, at the level of mitochondria was investigated. Low concentrations of CO partially inhibited oxidative stress-induced apoptosis in astrocytes, by preventing caspase-3 activation, mitochondrial potential depolarization, and plasmatic membrane permeability. CO exposure enhanced intracellular ATP generation, which was accompanied by an increase on specific oxygen consumption, a decrease on lactate production, and a reduction of glucose use, indicating an improvement of oxidative phosphorylation. Accordingly, CO increased cytochrome c oxidase (COX) enzymatic specific activity and stimulated mitochondrial biogenesis. In astrocytes, COX interacts with Bcl-2, which was verified by immunoprecipitation; this interaction is superior after 24 h of CO treatment. Furthermore, CO enhanced Bcl-2 expression in astrocytes. By silencing Bcl-2 expression with siRNA transfection, CO effects in astrocytes were prevented, namely: (i) inhibition of apoptosis, (ii) increase on ATP generation, (iii) stimulation of COX activity, and (iv) mitochondrial biogenesis. Thus, Bcl-2 expression is crucial for CO modulation of oxidative metabolism and for conferring cytoprotection. In conclusion, CO protects astrocytes against oxidative stress-induced apoptosis by improving metabolism functioning, particularly mitochondrial oxidative phosphorylation.

Published
2012

9. Carbon Monoxide Targeting Mitochondria

Author

Queiroga, Cláudia S. F., Almeida, Ana S., and Vieira, Helena L. A.

Subjects
Article Subject
Abstract

Mitochondria present two key roles on cellular functioning: (i) cell metabolism, being the main cellular source of energy and (ii) modulation of cell death, by mitochondrial membrane permeabilization. Carbon monoxide (CO) is an endogenously produced gaseoustransmitter, which presents several biological functions and is involved in maintaining cell homeostasis and cytoprotection. Herein, mitochondrion is approached as the main cellular target of carbon monoxide (CO). In this paper, two main perspectives concerning CO modulation of mitochondrial functioning are evaluated. First, the role of CO on cellular metabolism, in particular oxidative phosphorylation, is discussed, namely, on: cytochrome c oxidase activity, mitochondrial respiration, oxygen consumption, mitochondrial biogenesis, and general cellular energetic status. Second, the mitochondrial pathways involved in cell death inhibition by CO are assessed, in particular the control of mitochondrial membrane permeabilization.

Published
2012
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12. Paracrine effect of carbon monoxide - astrocytes promote neuroprotection through purinergic signaling in mice.

Author

Queiroga, Cláudia S. F., Alves, Raquel M. A., Conde, Sílvia V., Alves, Paula M., and Vieira, Helena L. A.

Subjects
*CARBON monoxide, *ADENOSINES, *ADENINE, *CARBONYLATION, *POISONOUS gases
Abstract

The neuroprotective role of carbon monoxide (CO) has been studied in a cell-autonomous mode. Herein, a new concept is disclosed - CO affects astrocyte-neuron communication in a paracrine manner to promote neuroprotection. Neuronal survival was assessed when co-cultured with astrocytes that had been pre-treated or not with CO. The CO-pre-treated astrocytes reduced neuronal cell death, and the cellular mechanisms were investigated, focusing on purinergic signaling. CO modulates astrocytic metabolism and extracellular ATP content in the co-culture medium. Moreover, several antagonists of P1 adenosine and P2 ATP receptors partially reverted CO-induced neuroprotection through astrocytes. Likewise, knocking down expression of the neuronal P1 adenosine receptor A2A-R (encoded by Adora2a) reverted the neuroprotective effects of CO-exposed astrocytes. The neuroprotection of CO-treated astrocytes also decreased following prevention of ATP or adenosine release from astrocytic cells and inhibition of extracellular ATP metabolism into adenosine. Finally, the neuronal downstream event involves TrkB (also known as NTRK2) receptors and BDNF. Pharmacological and genetic inhibition of TrkB receptors reverts neuroprotection triggered by CO-treated astrocytes. Furthermore, the neuronal ratio of BDNF to pro-BDNF increased in the presence of CO-treated astrocytes and decreased whenever A2A-R expression was silenced. In summary, CO prevents neuronal cell death in a paracrine manner by targeting astrocytic metabolism through purinergic signaling. [ABSTRACT FROM AUTHOR]

Published
2016
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13. Mitochondria and carbon monoxide: cytoprotection and control of cell metabolism - a role for Ca2+?

Author

R. Oliveira, Sara, Queiroga, Cláudia S. F., and Vieira, Helena L. A.

Subjects
*MITOCHONDRIAL physiology, *PHYSIOLOGICAL effects of carbon monoxide, *CYTOPROTECTION, *CELL metabolism, *CALCIUM in the body, *ACTIVE oxygen in the body, *MEMBRANE permeability (Biology)
Abstract

Carbon monoxide (CO) is an endogenously produced gasotransmitter with important biological functions: anti-inflammation, anti-apoptosis, vasomodulation and cell metabolism modulation. The most recognized cellular target for CO is the mitochondria. Physiological concentrations of CO generate mitochondrial reactive oxygen species (ROS), which are signalling molecules for CO-induced pathways. Indeed, small amounts of ROS promote cytoprotection by a preconditioning effect. Furthermore, CO prevents cell death by limiting mitochondrial membrane permeabilization, which inhibits the release of pro-apoptotic factors into the cytosol; both events are ROS dependent. CO also increases the ability of mitochondria to take up Ca2+. Mitochondrial metabolism is modulated by CO, namely by increasing TCA cycle rate, oxidative phosphorylation and mitochondrial biogenesis, which, in turn, increases ATP production. CO's modulation of metabolism might be important for cellular response to diseases, namely cancer and ischaemic diseases. Finally, another cytoprotective role of CO involves the control of Ca2+ channels. By limiting the activity of T-type and L-type Ca2+ channels, CO prevents excitotoxicity-induced cell death and modulates cell proliferation. Several questions concerning Ca2+ signalling, mitochondria and CO can be asked, for instance whether CO modulation of cell metabolism would be dependent on the mitochondrial Ca2+ uptake capacity, since small amounts of Ca2+ can increase mitochondrial metabolism. Whether CO controls Ca2+ communication between mitochondria and endoplasmic reticulum is another open field of research. In summary, CO emerges as a key gasotransmitter in the control of several cellular functions of mitochondria: metabolism, cell death and Ca2+ signalling. [ABSTRACT FROM AUTHOR]

Published
2016
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14. Mitochondria and carbon monoxide: cytoprotection and control of cell metabolism - a role for Ca2+?

Author

R. Oliveira, Sara, Queiroga, Cláudia S. F., and Vieira, Helena L. A.

Subjects
MITOCHONDRIAL physiology, PHYSIOLOGICAL effects of carbon monoxide, CYTOPROTECTION, CELL metabolism, CALCIUM in the body, ACTIVE oxygen in the body, MEMBRANE permeability (Biology)
Abstract

Carbon monoxide (CO) is an endogenously produced gasotransmitter with important biological functions: anti-inflammation, anti-apoptosis, vasomodulation and cell metabolism modulation. The most recognized cellular target for CO is the mitochondria. Physiological concentrations of CO generate mitochondrial reactive oxygen species (ROS), which are signalling molecules for CO-induced pathways. Indeed, small amounts of ROS promote cytoprotection by a preconditioning effect. Furthermore, CO prevents cell death by limiting mitochondrial membrane permeabilization, which inhibits the release of pro-apoptotic factors into the cytosol; both events are ROS dependent. CO also increases the ability of mitochondria to take up Ca2+. Mitochondrial metabolism is modulated by CO, namely by increasing TCA cycle rate, oxidative phosphorylation and mitochondrial biogenesis, which, in turn, increases ATP production. CO's modulation of metabolism might be important for cellular response to diseases, namely cancer and ischaemic diseases. Finally, another cytoprotective role of CO involves the control of Ca2+ channels. By limiting the activity of T-type and L-type Ca2+ channels, CO prevents excitotoxicity-induced cell death and modulates cell proliferation. Several questions concerning Ca2+ signalling, mitochondria and CO can be asked, for instance whether CO modulation of cell metabolism would be dependent on the mitochondrial Ca2+ uptake capacity, since small amounts of Ca2+ can increase mitochondrial metabolism. Whether CO controls Ca2+ communication between mitochondria and endoplasmic reticulum is another open field of research. In summary, CO emerges as a key gasotransmitter in the control of several cellular functions of mitochondria: metabolism, cell death and Ca2+ signalling. [ABSTRACT FROM AUTHOR]

Published
2016
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16. Carbon Monoxide Modulates Apoptosis by Reinforcing Oxidative Metabolism in Astrocytes.

Author

Almeida, Ana S., Queiroga, Cláudia S. F., Sousa, Marcos F. Q., Alves, Paula M., and Vieira, Helena L. A.

Subjects
*CELL metabolism, *HYPOXEMIA, *ISCHEMIA, *REPERFUSION, *CARBON monoxide, *CELL death
Abstract

Modulation of cerebral cell metabolism for improving the outcome of hypoxia-ischemia and reperfusion is a strategy yet to be explored. Because carbon monoxide (CO) is known to prevent cerebral cell death; herein the role of CO in the modulation of astrocytic metabolism, in particular, at the level of mitochondria was investigated. Low concentrations of CO partially inhibited oxidative stress-induced apoptosis in astrocytes, by preventing caspase-3 activation, mitochondrial potential depolarization, and plasmatic membrane permeability. CO exposure enhanced intracellular ATP generation, which was accompanied by an increase on specific oxygen consumption, a decrease on lactate production, and a reduction of glucose use, indicating an improvement of oxidative phosphorylation. Accordingly, CO increased cytochrome c oxidase (COX) enzymatic specific activity and stimulated mitochondrial biogenesis. In astrocytes, COX interacts with Bcl-2, which was verified by immunoprecipitation; this interaction is superior after 24 h of CO treatment. Furthermore, CO enhanced Bcl-2 expression in astrocytes. By silencing Bcl-2 expression with siRNA transfection, CO effects in astrocytes were prevented, namely: (i) inhibition of apoptosis, (ii) increase on ATP generation, (iii) stimulation of COX activity, and (iv) mitochondrial biogenesis. Thus, Bcl-2 expression is crucial for CO modulation of oxidative metabolism and for conferring cytoprotection. In conclusion, CO protects astrocytes against oxidative stress-induced apoptosis by improving metabolism functioning, particularly mitochondrial oxidative phosphorylation. [ABSTRACT FROM AUTHOR]

Published
2012
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17. Carbon monoxide prevents hepatic mitochondrial membrane permeabilization.

Author

Queiroga, Cláudia S. F., Almeida, Ana S., Alves, Paula M., Brenner, Catherine, and Vieira, Helena L. A.

Subjects
*CELL membranes, *CARBON monoxide, *MITOCHONDRIA, *PROTOPLASM, *CYTOCHROMES
Abstract

Background: Low concentrations of carbon monoxide (CO) protect hepatocytes against apoptosis and confers cytoprotection in several models of liver. Mitochondria are key organelles in cell death control via their membrane permeabilization and the release of pro-apoptotic factors. Results: Herein, we show that CO prevents mitochondrial membrane permeabilization (MMP) in liver isolated mitochondria. Direct and indirect approaches were used to evaluate MMP inhibition by CO: mitochondrial swelling, mitochondrial depolarization and inner membrane permeabilization. Additionally, CO increases mitochondrial reactive oxygen species (ROS) generation, and their scavenging, by ß-carotene addition, decreases CO protection, which reveals the key role of ROS. Interestingly, cytochrome c oxidase transiently responds to low concentrations of CO by decreasing its activity in the first 5 min, later on there is an increase of cytochrome c oxidase activity, which were detected up to 30 min. Conclusion: CO directly prevents mitochondrial membrane permeabilization, which might be implicated in the hepatic apoptosis inhibition by this gaseoustransmitter. [ABSTRACT FROM AUTHOR]

Published
2011
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18. Identification of human circulating factors following remote ischemic conditioning (RIC): Potential impact on stroke.

Author

Mollet IG, Viana-Soares R, Cardoso-Pires C, Soares NL, Marto JP, Mendonça M, Queiroga CSF, Carvalho AS, Sequeira CO, Teixeira-Santos L, Fernandes TP, Aloria K, Pereira SA, Matthiesen R, Viana-Baptista M, and Vieira HLA

Subjects
Humans, Male, Adult, Female, Stroke blood, Stroke metabolism, Proteomics methods, Pilot Projects, Nitric Oxide metabolism, Nitric Oxide blood, Middle Aged, Young Adult, Glutathione blood, Glutathione metabolism, Ischemic Preconditioning methods
Abstract

Remote ischemic conditioning (RIC) is a procedure consisting of short cycles of ischemia applied in a limb that activates endogenous protection in distant organs, such as the brain. Despite the promising outcomes of RIC, the biochemical factors governing inter-organ communication remain largely unexplored, particularly in humans. A pilot study on 20 healthy humans was performed to identify potential circulating biochemical factors involved in RIC signalling. Blood was collected before and immediately, 4 and 22 h after the end of RIC. To characterize the responses triggered by RIC, a combination of biochemical and proteomic analysis, along with functional in vitro tests in human cells, were performed. RIC did not alter the levels of nitric oxide, bilirubin and cell-free mitochondrial DNA. In contrast, carboxyhaemoglobin levels increased following RIC at all time points and young subset, suggesting endogenous production of carbon monoxide that is a cytoprotective gasotransmitter. Additionally, the levels of glutathione and cysteinylglycine bound to proteins also increased after RIC, while glutathione catabolism decreased. Plasma proteomic analysis identified overall 828 proteins. Several steps of statistical analysis (Student's t-test, repeated measures ANOVA, with Holm corrected pairwise p-values <0.05 threshold and fold change higher or lower than 100 %) leaded to the identification of 9 proteins with altered circulating levels in response to RIC at 4h and 22h. All 9 proteins are from extracellular space or exosomes, being involved in inflammation, angiogenesis or metabolism control. In addition, RIC-conditioned plasma from young subjects protected microglial cell culture against inflammatory stimuli, indicating an anti-inflammatory effect of RIC. Nevertheless, other functional tests in neurons or endothelial cells had no effect. Overall, we present some evidence for RIC-induced anti-inflammatory and antioxidant responses in healthy human subjects, in particular in young subjects. This study is a first step towards the disclosure of signalling factors involved in RIC-mediated inter-organ communication., Competing Interests: Declaration of competing interest On the behalf of all authors, I declare no conflict of interest., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2024
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19. Glutathionylation of adenine nucleotide translocase induced by carbon monoxide prevents mitochondrial membrane permeabilization and apoptosis.

Author

Queiroga CS, Almeida AS, Martel C, Brenner C, Alves PM, and Vieira HL

Subjects
Animals, Astrocytes cytology, Brain metabolism, Cytochromes c metabolism, Male, Membrane Potentials, Oxidation-Reduction, Rats, Rats, Wistar, Reactive Oxygen Species, Apoptosis, Carbon Monoxide chemistry, Glutathione metabolism, Mitochondria metabolism, Mitochondrial ADP, ATP Translocases metabolism, Mitochondrial Membranes metabolism
Abstract

The present work demonstrates the ability of CO to prevent apoptosis in a primary culture of astrocytes. For the first time, the antiapoptotic behavior can be clearly attributed to the inhibition of mitochondrial membrane permeabilization (MMP), a key event in the intrinsic apoptotic pathway. In isolated non-synaptic mitochondria, CO partially inhibits (i) loss of potential, (ii) the opening of a nonspecific pore through the inner membrane, (iii) swelling, and (iv) cytochrome c release, which are induced by calcium, diamide, or atractyloside (a ligand of ANT). CO directly modulates ANT function by enhancing ADP/ATP exchange and prevents its pore-forming activity. Additionally, CO induces reactive oxygen species (ROS) generation, and its prevention by beta-carotene decreases CO cytoprotection in intact cells as well as in isolated mitochondria, revealing the key role of ROS. On the other hand, CO induces a slight increase in mitochondrial oxidized glutathione, which is essential for apoptosis modulation by (i) delaying astrocytic apoptosis, (ii) decreasing MMP, and (iii) enhancing ADP/ATP translocation activity of ANT. Moreover, CO and GSSG trigger ANT glutathionylation, a post-translational process regulating protein function in response to redox cellular changes. In conclusion, CO protects astrocytes from apoptosis by preventing MMP, acting on ANT (glutathionylation and inhibition of its pore activity) via a preconditioning-like process mediated by ROS and GSSG.

Published
2010
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