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6. Acute reduction in whole cell conductance in anoxic turtle brain

Author

GHAI, H. S. and BUCK, L. T.

Subjects
Adenosine -- Research, Calcium -- Research, Brain research -- Evaluation, Turtles -- Research, Biological sciences
Abstract

Ghai, H. S., and L. T. Buck. Acute reduction in whole cell conductance in anoxic turtle brain. Am. J. Physiol. 277 (Regulatory Integrative Comp. Physiol. 46): R887-R893, 1999.--We tested the effect of anoxia, a 'mimic' turtle artificial cerebrospinal fluid (aCSF) consisting of high [Ca.sup.2+] and [Mg.sup.2+] concentrations and low pH and adenosine perfusions, on whole cell conductance ([G.sub.w]) in turtle brain slices using a whole cell voltage-clamp technique. With EGTA in the recording electrode, anoxic or adenosine perfusions did not change [G.sub.w] significantly (values range between 2.15 [+ or -] 0.24 and 3.24 [+ or -] 0.56 nS). However, perfusion with normoxic or anoxic mimic aCSF significantly decreased [G.sub.w]. High [[Ca.sup.2+]] (4.0 or 7.8 mM) perfusions alone could reproduce the changes in [G.sub.w] found with the mimic perfusions. With the removal of EGTA from the recording electrode, [G.sub.w] decreased significantly during both anoxic and adenosine perfusions. The [A.sub.1]-receptor agonist [N.sub.6]-cyclopentyladenosine reduced [G.sub.w] in a dosedependent manner, whereas the Al-receptor specific antagonist 8-cyclopentyl-1,3-dipropylxanthine blocked both the adenosine-and anoxic-mediated changes in [G.sub.w]. These data suggest a mechanism involving [A.sub.1]-receptor-mediated changes in intracellular [[Ca.sup.2+]] that result in acute changes in [G.sub.w] with the onset of anoxia. calcium; channel arrest; cortical neurons; membrane conductance; western painted turtle

Published
1999

7. First aid kit for hypoxic survival: sensors and strategies

Author

López-Barneo, J, Nurse, C A, Nilsson, G E, Buck, L T, Gassmann, M, Bogdanova, A Yu, López-Barneo, J, Nurse, C A, Nilsson, G E, Buck, L T, Gassmann, M, and Bogdanova, A Yu

Abstract

Survival success under conditions of acute oxygen deprivation depends on efficiency of the central and peripheral chemoreception, optimization of oxygen extraction from the hypoxic environment and its delivery to the periphery, and adjustments of energy production and consumption. This article uses a comparative approach to assess the efficiency of adaptive strategies used by anoxia-tolerant and hypoxia-sensitive species to support survival during the first minutes to 1 h of oxygen deprivation. An aquatic environment is much more demanding in terms of diurnal and seasonal variations of the ambient oxygen availability from anoxia to hyperoxia than is an air environment. Therefore, fishes and aquatic turtles have developed a number of adaptive responses, which are lacking in most of the terrestrial mammals, to cope with these extreme conditions. These include efficient central and peripheral chemoreception, acute changes in respiratory rate and amplitude, and acute increase of the gas-exchange interface. A special set of adaptive mechanisms are engaged in reduction of the energy expenditure of the major oxygen-consuming organs: the brain and the heart. Both reduction of ATP consumption and a switch to alterative energy sources contribute to the maintenance of ATP and ion balance in hypoxia-tolerant animals. Hypoxia and hyperoxia are conditions favoring development of oxidative stress. Efficient protection from oxidation in anoxia-tolerant species includes reduction in the glutamate levels in the brain, stabilization of the mitochondrial function, and maintenance of nitric oxide production under conditions of oxygen deprivation. We give an overview of the current state of knowledge on some selected molecular and cellular acute adaptive mechanisms. These include the mechanisms of chemoreception in adult and neonatal mammals and in fishes, acute metabolic adaptive responses in the brain, and the role of nitrite in the preservation of heart function under hypoxic conditio

Published
2010

16. Transcriptome analysis of the central nervous system of the mollusc Lymnaea stagnalis.

Author

Feng, Z.-P., Zhang, Z., van Kesteren, R. E., Straub, V.A., van Nierop, P., Jin, K., Nejatbakhsh, N., Goldberg, J. I., Spencer, G. E., Yeoman, M. S., Wildering, W., Coorssen, J. R., Croll, R. P., Buck, L. T., Syed, N. I., and Smit, A. B.

Subjects
LYMNAEA stagnalis, NUCLEOTIDE sequence, GENOMES, GENETICS, GENE expression
Abstract

Background: The freshwater snail Lymnaea stagnalis (L. stagnalis) has served as a successful model for studies in the field of Neuroscience. However, a serious drawback in the molecular analysis of the nervous system of L. stagnalis has been the lack of large-scale genomic or neuronal transcriptome information, thereby limiting the use of this unique model. Results: In this study, we report 7,712 distinct EST sequences (median length: 847 nucleotides) of a normalized L. stagnalis central nervous system (CNS) cDNA library, resulting in the largest collection of L. stagnalis neuronal transcriptome data currently available. Approximately 42% of the cDNAs can be translated into more than 100 consecutive amino acids, indicating the high quality of the library. The annotated sequences contribute 12% of the predicted transcriptome size of 20,000. Surprisingly, approximately 37% of the L. stagnalis sequences only have a tBLASTx hit in the EST library of another snail species Aplysia californica (A. californica) even using a low stringency e-value cutoff at 0.01. Using the same cutoff, approximately 67% of the cDNAs have a BLAST hit in the NCBI non-redundant protein and nucleotide sequence databases (nr and nt), suggesting that one third of the sequences may be unique to L. stagnalis. Finally, using the same cutoff (0.01), more than half of the cDNA sequences (54%) do not have a hit in nematode, fruitfly or human genome data, suggesting that the L. stagnalis transcriptome is significantly different from these species as well. The cDNA sequences are enriched in the following gene ontology functional categories: protein binding, hydrolase, transferase, and catalytic enzymes. Conclusion: This study provides novel molecular insights into the transcriptome of an important molluscan model organism. Our findings will contribute to functional analyses in neurobiology, and comparative evolutionary biology. [ABSTRACT FROM AUTHOR]

Published
2009
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20. Oxidative Properties of Carp Red and White Muscle

Author

Moyes, C. D., Buck, L. T., Hochachka, P. W., and Suarez, R. K.

Abstract

Substrate preferences of isolated mitochondria and maximal enzyme activities were used to assess the oxidative capacities of red muscle (RM) and white muscle (WM) of carp (Cyprinus carpio). A 14-fold higher activity of citrate synthase (CS) in RM reflects the higher mitochondrial density in this tissue. RM mitochondria oxidize pyruvate and fatty acyl carnitines (8:0, 12:0, 16:0) at similarly high rates. WM mitochondria oxidize these fatty acyl carnitines at 35–70% the rate of pyruvate, depending on chain length. WM has only half the carnitine palmitoyl transferase/CS ratio of RM, but similar ratios of beta-hydroxyacyl CoA dehydro-genase/CS. Ketone bodies are poor substrates for mitochondria from both tissues. In both tissues mitochondrial alpha-glycerophosphate oxidation was minimal, and alpha-glycerophosphate dehydrogenase was present at low activities, suggesting the alpha-glycerophosphate shuttle is of minor significance in maintaining cytosolic redox balance in either tissue. The mitochondrial oxidation rates of other substrates relative to pyruvate are as follows: alpha-ketoglutarate 90% (RM and WM); glutamate 45% (WM) and 70% (RM); proline 20% (WM) and 45% (RM). Oxidation of neutral amino acids (serine, glycine, alanine, beta-alanine) was not consistently detectable. These data suggest that RM and WM differ in mitochondrial properties as well as mitochondrial abundance. Whereas RM mitochondria appear to be able to utilize a wide range of metabolic fuels (fatty acids, pyruvate, amino acids but not ketone bodies), WM mitochondria appear to be specialized to use pyruvate.

Published
1989
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21. Evidence of different climatic adaptation strategies in humans and non-human primates

Author

Buck, L. T., De Groote, I., Hamada, Y., Hassett, B. R., Ito, T., and Stock, J. T.

Subjects
141, 631/158/857, 13. Climate action, 123, article, 129, 15. Life on land, 631/181/19/2471
Abstract

To understand human evolution it is critical to clarify which adaptations enabled our colonisation of novel ecological niches. For any species climate is a fundamental source of environmental stress during range expansion. Mammalian climatic adaptations include changes in size and shape reflected in skeletal dimensions and humans fit general primate ecogeographic patterns. It remains unclear however, whether there are also comparable amounts of adaptation in humans, which has implications for understanding the relative importance of biological/behavioural mechanisms in human evolution. We compare cranial variation between prehistoric human populations from throughout Japan and ecologically comparable groups of macaques. We compare amounts of intraspecific variation and covariation between cranial shape and ecological variables. Given equal rates and sufficient time for adaptation for both groups, human conservation of non-human primate adaptation should result in comparable variation and patterns of covariation in both species. In fact, we find similar amounts of intraspecific variation in both species, but no covariation between shape and climate in humans, contrasting with strong covariation in macaques. The lack of covariation in humans may suggest a disconnect in climatic adaptation strategies from other primates. We suggest this is due to the importance of human behavioural adaptations, which act as a buffer from climatic stress and were likely key to our evolutionary success.

24. Environmental remodelling of GABAergic and glutamatergic neurotransmission: Rise of the anoxia-tolerant turtle brain.

Author

Hogg, D. W., Hawrysh, P. J., and Buck, L. T.

Subjects
*NEURAL transmission, *EXCITATORY amino acid agents, *CEREBRAL anoxia, *TURTLE physiology, *BRAIN physiology, *CLIMATE change
Abstract

Climate cooling over the past one hundred thousand years has resulted in seasonal ice cover at northern and southern latitudes that has selected for hypoxia and anoxia tolerance in some species, such as freshwater turtles. At the northern reaches of their range, North American freshwater turtles spend 4 months or more buried in the mud bottom of ice covered lakes and ponds. From a comparative perspective this gives us the opportunity to understand how an extremely oxygen-sensitive organ, such as the vertebrate brain, can function without oxygen for long periods. Brain function is based on complex excitatory (on) and inhibitory (off) circuits involving the major neurotransmitters glutamate and, γ-aminobutyric acid (GABA) respectively. When a mammalian brain becomes anoxic, glutamate levels rise within minutes resulting in excitotoxic cell death which does not occur in anoxic turtle brain. The response in turtle brain has been remodelled - GABA levels rise rapidly resulting in large inhibitory GABA receptor currents and inhibition of glutamate receptor function that together depress neuronal activity. [ABSTRACT FROM AUTHOR]

Published
2014
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25. Evidence of different climatic adaptation strategies in humans and non-human primates

Author

Laura T. Buck, Tsuyoshi Ito, I De Groote, Jay T. Stock, Brenna Hassett, Yuzuru Hamada, Buck, LT [0000-0002-1768-9049], De Groote, I [0000-0002-9860-0180], Apollo - University of Cambridge Repository, Buck, L. T. [0000-0002-1768-9049], and De Groote, I. [0000-0002-9860-0180]

Subjects
0301 basic medicine, Philosophy and Religion, 123, Range (biology), Biological anthropology, Acclimatization, lcsh:Medicine, Evolutionary ecology, BODY PROPORTIONS, MACAQUE, Macaque, MAXILLARY SINUS, 0302 clinical medicine, HOLOCENE, 129, lcsh:Science, Multidisciplinary, 631/181/19/2471, GF, 631/158/857, Human evolution, GN, FORM, 141, CRANIAL MORPHOLOGY, PLEISTOCENE, Climatic adaptation, Biology, Article, Intraspecific competition, Evolution, Molecular, MIDFACIAL MORPHOLOGY, 03 medical and health sciences, QH301, POPULATION HISTORY, biology.animal, JOMON FORAGERS, Animals, Humans, Ecological niche, QL, History and Archaeology, lcsh:R, Skull, 15. Life on land, Colonisation, 030104 developmental biology, 13. Climate action, Evolutionary biology, Macaca, lcsh:Q, Adaptation, 030217 neurology & neurosurgery
Abstract

To understand human evolution it is critical to clarify which adaptations enabled our colonisation of novel ecological niches. For any species climate is a fundamental source of environmental stress during range expansion. Mammalian climatic adaptations include changes in size and shape reflected in skeletal dimensions and humans fit general primate ecogeographic patterns. It remains unclear however, whether there are also comparable amounts of adaptation in humans, which has implications for understanding the relative importance of biological/behavioural mechanisms in human evolution. We compare cranial variation between prehistoric human populations from throughout Japan and ecologically comparable groups of macaques. We compare amounts of intraspecific variation and covariation between cranial shape and ecological variables. Given equal rates and sufficient time for adaptation for both groups, human conservation of non-human primate adaptation should result in comparable variation and patterns of covariation in both species. In fact, we find similar amounts of intraspecific variation in both species, but no covariation between shape and climate in humans, contrasting with strong covariation in macaques. The lack of covariation in humans may suggest a disconnect in climatic adaptation strategies from other primates. We suggest this is due to the importance of human behavioural adaptations, which act as a buffer from climatic stress and were likely key to our evolutionary success.

Published
2019

26. 50 years of comparative biochemistry: The legacy of Peter Hochachka.

Author

Buck LT, Burness G, Campbell KL, Darveau CA, Driedzic W, Guderley H, McClelland GB, Moon TW, Moyes CD, and Schulte PM

Subjects
Animals, Congresses as Topic, Female, History, 20th Century, History, 21st Century, Humans, Male, Manitoba, Portraits as Topic, Biochemistry history
Abstract

Peter Hochachka was an early pioneer in the field of comparative biochemistry. He passed away in 2002 after 4 decades of research in the discipline. To celebrate his contributions and to coincide with what would have been his 80th birthday, a group of his former students organized a symposium that ran as a satellite to the 2017 Canadian Society of Zoologists annual meeting in Winnipeg, Manitoba (Canada). This Special Issue of CBP brings together manuscripts from symposium attendees and other authors who recognize the role Peter played in the evolution of the discipline. In this article, the symposium organizers and guest editors look back on his career, celebrating his many contributions to research, acknowledging his role in training of generations of graduate students and post-doctoral fellows in comparative biochemistry and physiology., (Copyright © 2018. Published by Elsevier Inc.)

Published
2018
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27. Oxygen-sensitive reduction in Ca²⁺-activated K⁺ channel open probability in turtle cerebrocortex.

Author

Rodgers-Garlick CI, Hogg DW, and Buck LT

Subjects
6-Cyano-7-nitroquinoxaline-2,3-dione pharmacology, Animals, Biophysics, Calcium metabolism, Cerebral Cortex cytology, Cerebral Cortex drug effects, Dose-Response Relationship, Drug, Electric Stimulation, Excitatory Amino Acid Antagonists pharmacology, Female, Hypoxia physiopathology, In Vitro Techniques, Ion Channel Gating drug effects, Male, Membrane Potentials drug effects, Oxygen pharmacology, Patch-Clamp Techniques, Phorbol Esters pharmacology, Potassium Channel Blockers pharmacology, Pyramidal Cells drug effects, Sodium Channel Blockers pharmacology, Tetraethylammonium pharmacology, Tetrodotoxin pharmacology, Valine analogs & derivatives, Valine pharmacology, Cerebral Cortex physiology, Ion Channel Gating physiology, Oxygen metabolism, Potassium Channels, Calcium-Activated metabolism, Probability, Turtles physiology
Abstract

In response to low ambient oxygen levels the western painted turtle brain undergoes a large depression in metabolic rate which includes a decrease in neuronal action potential frequency. This involves the arrest of N-methyl-D-aspartate receptor (NMDAR) and α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid receptor (AMPAR) currents and paradoxically an increase in γ-aminobutyric acid receptor (GABAR) currents in turtle cortical neurons. In a search for other oxygen-sensitive channels we discovered a Ca(2+)-activated K(+) channel (K(Ca)) that exhibited a decrease in open time in response to anoxia. Single-channel recordings of K(Ca) activity were obtained in cell-attached and excised inside-out patch configurations from neurons in cortical brain sheets bathed in either normoxic or anoxic artificial cerebrospinal fluid (aCSF). The channel has a slope conductance of 223pS, is activated in response to membrane depolarization, and is controlled in a reversible manner by free [Ca(2+)] at the intracellular membrane surface. In the excised patch configuration anoxia had no effect on K(Ca) channel open probability (P(open)); however, in cell-attached mode, there was a reversible fivefold reduction in P(open) (from 0.5 ± 0.05 to 0.1 ± 0.03) in response to 30-min anoxia. The inclusion of the potent protein kinase C (PKC) inhibitor chelerythrine prevented the anoxia-mediated decrease in P(open) while drip application of a phorbol ester PKC activator decreased P(open) during normoxia (from normoxic 0.4 ± 0.05 to phorbol-12-myristate-13-acetate (PMA) 0.1 ± 0.02). Anoxia results in a slight depolarization of turtle pyramidal neurons (∼8 mV) and an increase in cytosolic [Ca(2+)]; therefore, K(Ca) arrest is likely important to prevent Ca(2+) activation during anoxia and to reduce the energetic cost of maintaining ion gradients. We conclude that turtle pyramidal cell Ca(2+)-activated K(+) channels are oxygen-sensitive channels regulated by cytosolic factors and are likely the reptilian analog of the mammalian large conductance Ca(2+)-activated K(+) channels (BK channels)., (Crown Copyright © 2013. Published by Elsevier Ltd. All rights reserved.)

Published
2013
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28. Adaptive responses of vertebrate neurons to anoxia--matching supply to demand.

Author

Buck LT and Pamenter ME

Subjects
Animals, Humans, Hypoxia pathology, Models, Biological, Potassium metabolism, Potassium Channels physiology, Vertebrates physiology, Acclimatization physiology, Adenosine Triphosphate metabolism, Hypoxia physiopathology, Neurons physiology
Abstract

Oxygen depleted environments are relatively common on earth and represent both a challenge and an opportunity to organisms that survive there. A commonly observed survival strategy to this kind of stress is a lowering of metabolic rate or metabolic depression. Whether metabolic rate is at a normal or a depressed level the supply of ATP (glycolysis and oxidative phosphorylation) must match the cellular demand for ATP (protein synthesis and ion pumping), a condition that must of course be met for long-term survival in hypoxic and anoxic environments. Underlying a decrease in metabolic rate is a corresponding decrease in both ATP supply and ATP demand pathways setting a new lower level for ATP turnover. Both sides of this equation can be actively regulated by second messenger pathways but it is less clear if they are regulated differentially or even sequentially with the onset of anoxia. The vertebrate brain is extremely sensitive to low oxygen levels yet some species can survive in oxygen depleted environments for extended periods and offer a working model of brain survival without oxygen. Hypoxia tolerant vertebrate brain will be the primary focus of this review; however, we will draw upon research involving hypoxia/ischemia tolerance mechanisms in liver and heart to offer clues to how brain can tolerate anoxia. The issue of regulating ATP supply or demand pathways will also be addressed with a focus on ion channel arrest being a significant mechanism to reduce ATP demand and therefore metabolic rate. Furthermore, mitochondria are ideally situated to serve as cellular oxygen sensors and mediator of protective mechanisms such as ion channel arrest. Therefore, we will also describe a mitochondria based mechanism of ion channel arrest involving ATP-sensitive mitochondrial K(+) channels, cytosolic calcium and reaction oxygen species concentrations.

Published
2006
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29. Succinate and alanine as anaerobic end-products in the diving turtle (Chrysemys picta bellii).

Author

Buck LT

Subjects
Anaerobiosis, Animals, Alanine metabolism, Succinates metabolism, Turtles metabolism
Abstract

The western painted turtle is an extremely anoxia-tolerant vertebrate capable of tolerating blood lactate levels of 150-200 mM. Since lactate increases to such high levels, other fermentation end-products such as succinate and alanine, which have not been previously measured in this species, might also be expected to increase. Therefore, I measured turtle heart, liver, and blood concentrations of lactate, succinate, and alanine following a 28-day anoxic dive at 5 degrees C. Succinate and lactate concentrations increased significantly in all three compartments while alanine increased significantly in the liver only. Lactate was found to accumulate by a similar amount in all three compartments (66.4-80.5 micromol g or ml(-1) in the blood compartment) and was used as a reference to which alanine and succinate concentrations could be compared. Succinate and alanine levels increased by 2 and 0.9% of lactate in liver, approximately 0.3 and 0.04% of lactate in blood, and 0.6 and 0.07% of lactate in heart, respectively. The contribution of each to the total anoxic heat production was calculated and accounted for an additional 1.5% of the previously measured exothermic gap. I conclude that succinate and alanine concentrations do increase in the anoxic turtle but are minor anaerobic end-products.

Published
2000
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30. Hypoxia-induced silencing of NMDA receptors in turtle neurons.

Author

Bickler PE, Donohoe PH, and Buck LT

Subjects
Adaptation, Physiological physiology, Animals, Calcium metabolism, Calcium Signaling physiology, Cell Membrane chemistry, Cell Membrane metabolism, Cell Survival physiology, Cerebral Cortex chemistry, Cerebral Cortex cytology, Cerebral Cortex metabolism, Female, Male, Neurons chemistry, Phosphoric Monoester Hydrolases metabolism, Phosphorylation, Down-Regulation physiology, Hypoxia, Brain metabolism, Neurons enzymology, Receptors, N-Methyl-D-Aspartate metabolism, Turtles physiology
Abstract

Hypoxia-induced suppression of NMDA receptors (NMDARs) in western painted turtle (Chrysemys picta) cortical neurons may be critical for surviving months of anoxic dormancy. We report that NMDARs are silenced by at least three different mechanisms operating at different times during anoxia. In pyramidal neurons from cerebrocortex, 1-8 min anoxia suppressed NMDAR activity (Ca(2+) influx and open probability) by 50-60%. This rapid decrease in receptor activity was controlled by activation of phosphatase 1 or 2A but was not associated with an increase in [Ca(2+)](i). However, during 2 hr of anoxia, [Ca(2+)](i) in cerebrocortical neurons increased by 35%, and suppression of NMDARs was predicted by the increase of [Ca(2+)](i) and controlled by calmodulin. An additional mechanism of NMDAR silencing, reversible removal of receptors from the cell membrane, was found in cerebrocortex of turtles remaining anoxic at 3 degrees C for 3-21 d. When suppression of NMDARs was prevented with phosphatase inhibitors, tolerance of anoxia was lost. Silencing of NMDARs is thus critical to the remarkable ability of C. picta to tolerate life without oxygen.

Published
2000

31. Adaptations of vertebrate neurons to hypoxia and anoxia: maintaining critical Ca2+ concentrations.

Author

Bickler PE and Buck LT

Subjects
Animals, Cell Hypoxia physiology, Adaptation, Physiological, Calcium metabolism, Calcium physiology, Neurons metabolism, Neurons physiology, Vertebrates physiology
Abstract

Down-regulation of ion channel activity ('channel arrest'), which aids in preserving critical ion gradients in concert with greatly diminished energy production, is one important strategy by which anoxia-tolerant neurons adapt to O2 shortage. Channel arrest results in the elimination of action potentials and neurotransmission and also decreases the need for ion transport, which normally requires a large energy expenditure. Important targets of this down-regulation may be channels in which activity would otherwise result in the toxic increases in intracellular [Ca2+] characteristic of anoxia-sensitive mammalian neurons. In turtles, Na+ channels and the Ca2+-permeable ion channel of the N-methyl-d-aspartate (NMDA)-type glutamate receptor undergo down-regulation during anoxia. Inactivation of NMDA receptors during hypoxia occurs by a variety of mechanisms, including alterations in the phosphorylation state of ion channel subunits, Ca2+-dependent second messenger activation, changes in Ca2+-dependent polymerization/depolymerization of actin to postsynaptic receptors and activation of other G-protein-coupled receptors. Release of inhibitory neurotransmitters (e.g. gamma-aminobutyrate) and neuromodulators (e.g. adenosine) into the brain extracellular fluids may play an important role in the down-regulation of these and other types of ion channels.

Published
1998
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32. Adenosine and anoxia reduce N-methyl-D-aspartate receptor open probability in turtle cerebrocortex.

Author

Buck LT and Bickler PE

Subjects
Animals, Calcium metabolism, Cerebral Cortex drug effects, Cerebral Cortex physiology, Magnesium metabolism, Membrane Potentials drug effects, Patch-Clamp Techniques, Receptors, N-Methyl-D-Aspartate drug effects, Receptors, N-Methyl-D-Aspartate physiology, Turtles, Adenosine pharmacology, Cerebral Cortex metabolism, Hypoxia metabolism, Receptors, N-Methyl-D-Aspartate metabolism
Abstract

During normoxia, glutamate and the glutamate family of ion channels play a key role in mediating rapid excitatory synaptic transmission in the central nervous system. However, during hypoxia, intracellular [Ca2+] increases to neurotoxic levels, mediated largely by the N-methyl-D-aspartate (NMDA) subfamily of glutamate receptors. Adenosine has been shown to decrease the magnitude of the hypoxia-induced increase in [Ca2+]i in mammalian brain slices, delaying tissue injury. Turtle brain is remarkably tolerant of anoxia, maintaining a pre-anoxic [Ca2+]i while cerebral adenosine levels increase 12-fold. Employing cell-attached single-channel patch-clamp techniques, we studied the effect of adenosine (200 micromol l-1) and anoxia on NMDA receptor open probability (Popen) and current amplitude. After 60 min of anoxic perfusion, channel Popen decreased by 65 % (from 6.8+/-1.6 to 2.4+/-0.8 %) an effect that could also be achieved with a normoxic perfusion of 200 micromol l-1 adenosine (Popen decreased from 5.8+/-1.1 to 2.3+/-1.2 %). The inclusion of 10 micromol l-1 8-phenyltheophylline, an A1 receptor blocker, prevented the adenosine- and anoxia-induced decrease in Popen. Mean single-channel current amplitude remained at approximately 2.7+/-0.23 pA under all experimental conditions. To determine whether a change in the membrane potential could be part of the mechanism by which Popen decreases, membrane and threshold potential were measured following each experiment. Membrane potential did not change significantly under any condition, ranging from -76.8 to -80.6 mV. Therefore, during anoxia, NMDA receptors cannot be regulated by Mg2+ in a manner dependent on membrane potential. Threshold potentials did decrease significantly following 60 min of anoxic or adenosine perfusion (control -33.3+/-1.9 mV, anoxia -28.4+/-1.5 mV, adenosine -23.4+/-2.8 mV). We conclude that anoxia modulates NMDA receptor activity and that adenosine plays a key role in mediating this change. This is the first direct measurement of ion channel activity in anoxic turtle brain and demonstrates that ion channel regulation is part of the naturally evolved anoxic defence mechanism of this species.

Published
1998
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33. Oxygen sensing and signal transduction in metabolic defense against hypoxia: lessons from vertebrate facultative anaerobes.

Author

Hochachka PW, Land SC, and Buck LT

Subjects
Animals, Brain cytology, Brain metabolism, Down-Regulation, Hypoxia metabolism, Liver cytology, Liver metabolism, Turtles, Up-Regulation, Energy Metabolism physiology, Hypoxia physiopathology, Oxygen metabolism, Signal Transduction physiology
Abstract

Earlier studies identified two main defense strategies against hypoxia in hypoxia tolerant animals: (1) reduction in energy turnover, and (2) improved energetic efficiency of those metabolic processes that remain. We used two model systems from the highly anoxia-tolerant aquatic turtle: (1) tissue slices of brain cortex (to probe cell level electrophysiological responses to oxygen limitation), and (2) isolated liver hepatocytes (to probe signalling and defense). In the latter, a cascade of processes underpinning hypoxia defense begins with an oxygen sensor that is probably a heme protein and a signal transduction pathway that leads to the specific activation of some genes (increased expression of several proteins) and to specific down-regulation of other genes (decreased expression of several other proteins). The pathway seems to have characteristics in common with oxygen-regulated control elements in other cells. The probable roles of the oxygen sensing and signal transduction system include coordinate down-regulation of energy demand and energy supply pathways in metabolism. Because of this coordination, hypoxia tolerant cells stay in energy balance even as they down-regulate to extremely low levels of ATP turnover. The main ATP-demanding processes in normoxia (protein synthesis, protein degradation, glucose synthesis, urea synthesis and maintenance of electrochemical gradients) are all turned down to variable degrees during anoxia or extreme hypoxia. Most striking is the observation that ion pumping is the main energy sink in anoxia-despite reductions in cell membrane permeability ("channel arrest"). Neurons also show a much lower permeability than do homologous mammalian cells but, in this case under acute anoxia, there is no further change in cell membrane conductivity. We consider that, through this recent work, it is becoming evident how normoxic maintenance ATP turnover rates can be down-regulated by an order of magnitude or more-to a new hypometabolic steady state that is prerequisite for surviving prolonged hypoxia or anoxia. The implications of these developments extend to many facets of biology and medicine.

Published
1997
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34. Effects of fructose-1,6-bisphosphate on glutamate release and ATP loss from rat brain slices during hypoxia.

Author

Bickler PE and Buck LT

Subjects
Analysis of Variance, Animals, Calcium Channel Blockers pharmacology, Cell Hypoxia, Cerebral Cortex drug effects, Cerebral Cortex physiology, Cyanides pharmacology, In Vitro Techniques, Membrane Potentials drug effects, Peptides pharmacology, Potassium Chloride pharmacology, Rats, Rats, Sprague-Dawley, omega-Conotoxin GVIA, Adenosine Triphosphate metabolism, Cerebral Cortex metabolism, Fructosediphosphates pharmacology, Glutamic Acid metabolism
Abstract

Fructose-1,6-bisphosphate (FBP), an intermediate of glucose metabolism, is neuroprotective in brain hypoxia or ischemia. Because the mechanisms for this protection are not clear, we examined the effects of FBP on two important events in brain ischemia, i.e., loss of ATP and release of the excitatory neurotransmitter glutamate. Glutamate release from cortical brain slices was measured fluorometrically (glutamate dehydrogenase-catalyzed conversion of glutamate to alpha-ketoglutarate) during hypoxia (PO2 15 mm Hg) or hypoxia plus 100 microM cyanide. FBP (3.5 mM, with glucose 20 mM) reduced glutamate release during hypoxia by 55% and during hypoxia/cyanide by 46% (p < 0.005), and prevented a significant fall in [ATP]. [ATP] was maintained in oxygenated glucose-free conditions with 20 but not 3.5 mM FBP, and fell to < 20% of normal with hypoxia. Despite the drop in [ATP], 3.5 or 20 mM FBP without glucose decreased hypoxia-evoked glutamate release. We conclude (1) FBP present without glucose preserves normal [ATP] only when oxygen is available, suggesting limited uptake and metabolism; and (2) FBP decreases hypoxia-evoked glutamate release by processes independent of [ATP]. These results suggest protective actions of FBP that are separate from augmentation of anaerobic energy production, as previously proposed.

Published
1996
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35. Volatile and intravenous anesthetics decrease glutamate release from cortical brain slices during anoxia.

Author

Bickler PE, Buck LT, and Feiner JR

Subjects
Animals, Cerebral Cortex drug effects, In Vitro Techniques, Rats, Rats, Sprague-Dawley, Anesthetics, Inhalation pharmacology, Anesthetics, Intravenous pharmacology, Cerebral Cortex metabolism, Enflurane pharmacology, Glutamic Acid metabolism, Halothane pharmacology, Hypoxia metabolism, Propofol pharmacology, Thiopental pharmacology
Abstract

Background: Extracellular accumulation of the excitatory neurotransmitter L-glutamate during cerebral hypoxia or ischemia contributes to neuronal death. Anesthetics inhibit release of synaptic neurotransmitters but it is unknown if they alter net extrasynaptic glutamate release, which accounts for most of the glutamate released during hypoxia or ischemia. The purpose of this study was to determine if different types of anesthetics decrease hypoxia-induced glutamate release from rat brain slices., Methods: Glutamate released from cortical brain slices was measured fluorometrically with the glutamate dehydrogenase catalyzed formation of the reduced form of nicotinamide adenine dinucleotide phosphate. Glutamate release was measured in oxygenated (PO2 = 400 mmHg), hypoxic ((PO2 = 20 mmHg), and anoxic ((PO2 = 20 mmHg plus 100 microM NaCN) solutions and with clinical concentrations of anesthetics (halothane 325 microM, enflurane 680 microM, propofol 200 microM, sodium thiopental 50 microM). The source of glutamate released during these stresses was defined with toxins inhibiting N and P type voltage-gated calcium channels, and with calcium-free medium., Results: Glutamate released during hypoxia or anoxia was 1.5 and 5.3 times greater, respectively, than that evoked by depolarization with 30 mM KCl. Hypoxia/anoxia-induced glutamate release was not mediated by synaptic voltage-gated calcium channels, but probably by the reversal of normal uptake mechanisms. Halothane, enflurane, and sodium thiopental, but not propofol, decreased hypoxia-evoked glutamate release by 50-70% (P < 0.05). None of the anesthetics alter basal glutamate release., Conclusions: The authors conclude that halothane, enflurane, and sodium thiopental but not propofol, at clinical concentrations, decrease extrasynaptic release of L-glutamate during hypoxic stress.

Published
1995
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36. Effects of isoflurane and hypothermia on glutamate receptor-mediated calcium influx in brain slices.

Author

Bickler PE, Buck LT, and Hansen BM

Subjects
Adenosine Triphosphate metabolism, Animals, Brain Ischemia enzymology, Brain Ischemia metabolism, Cytosol drug effects, Cytosol metabolism, In Vitro Techniques, L-Lactate Dehydrogenase metabolism, N-Methylaspartate pharmacology, Rats, Receptors, Glutamate metabolism, Brain drug effects, Brain metabolism, Calcium metabolism, Excitatory Amino Acid Antagonists pharmacology, Hypothermia metabolism, Isoflurane pharmacology, Receptors, Glutamate drug effects
Abstract

Background: To understand how volatile anesthetics protect neurons during cerebral ischemia, we studied the effects of isoflurane on cerebral glutamate receptor-mediated calcium influx. Calcium influx via these key excitatory receptors may mediate pain transmission, memory, and the pathophysiologic sequelae of cerebral anoxia or ischemia. Because cerebral protection by hypothermia may involve a decrease in glutamate receptor activity, we also examined the interaction of temperature and isoflurane on glutamate receptor inhibition., Methods: We measured glutamate receptor-mediated changes in cytosolic calcium in 300-microns-thick rat cortical brain slices. Temperature was varied to 28, 34, 37, or 39 degrees C and isoflurane partial pressure to 0.016-0.019 atm (equivalent to 1.16 minimum alveolar concentration [MAC], adjusted for temperature and age). Brain slices were loaded with fura-2 to permit measurement of cytosolic free calcium. Calcium changes due to the glutamate receptor agonist N-methyl-D-aspartate (NMDA) (50 microM), to ischemia levels of L-glutamate (1.0 mM) or to simulated ischemia (1.0 mM glutamate, 100 microM NaCN, and 3.5 mM iodoacetate) was then measured. Slice lactate dehydrogenase leakage and adenosine triphosphate were measured as indices of cellular integrity., Results: Isoflurane reduced both L-glutamate and NMDA-mediated calcium fluxes by approximately 60%. Neither the activity of the NMDA receptor nor its inhibition by isoflurane was altered by temperature. The rate of calcium influx during ischemia was significantly reduced both by temperature and by isoflurane (P < 0.05). Adenosine triphosphate loss and lactate dehydrogenase leakage were reduced by isoflurane during simulated ischemia by 37% and 73% (P < 0.05), respectively., Conclusions: (1) At 1.16 MAC, isoflurane potently inhibits glutamate receptors and delays cellular injury induced by simulated ischemia, and (2) hypothermia does not reduce the intrinsic activity of cortical glutamate receptors but delays calcium accumulation during simulated ischemia. Isoflurane reduces the severity of key pathophysiologic events in an in vitro model of simulated cerebral ischemia.

Published
1994
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