Metabolic Changes in Cerebral Cortex, Hippocampus, and Cerebellum During Sustained Bicuculline-Induced Seizures

Abstract— The objective of the present experiments was to study metabolic correlates to the localization of neuronal lesions during sustained seizures. To that end, status epilepticus was induced by i.v. administration of bicuculline in immobilized and artificially ventilated rats, since this model is known to cause neuronal cell damage in cerebral cortex and hippocampus but not in the cerebellum. After 20 or 120 min of continuous seizure activity, brain tissue was frozen in situ through the skull bone, and samples of cerebral cortex, hippocampus, and cerebellum were collected for analysis of glycolytic metabolites, phosphocreatine (PCr), ATP, ADP, AMP, and cyclic nucleotides. After 20 min of seizure activity, the two “vulnerable” structures (cerebral cortex and hippocampus) and the “resistant” one (cerebellum) showed similar changes in cerebral metabolic state, characterized by decreased tissue concentrations of PCr, ATP, and glycogen, and increased lactate concentrations and lactate/ pyruvate ratios. In all structures, though, the adenylate energy charge remained close to control. At the end of a 2-h period of status epilepticus, a clear deterioration of the energy state was observed in the cerebral cortex and the hippocampus, but not in the cerebellum. The reduction in adenylate energy charge in the cortex and hippocampus was associated with a seemingly paradoxical decrease in tissue lactate levels and with failure of glycogen resynthesis (cerebral cortex). Experiments with infusion of glucose during the second hour of a 2-h period of status epilepticus verified that the deterioration of tissue energy state was partly due to reduced substrate supply; however, even in animals with adequate tissue glucose concentrations, the energy charge of the two structures was significantly lowered. The cyclic nucleotides (cAMP and cGMP) behaved differently. Thus, whereas cAMP concentrations were either close to control (hippocampus and cerebellum) or moderately increased (cerebral cortex), the cGMP concentrations remained markedly elevated throughout the seizure period, the largest change being observed in the cerebellum. It is concluded that although the localization of neuronal damage and perturbation of cerebral energy state seem to correlate, the results cannot be taken as. evidence that cellular energy failure is the cause of the damage. Thus, it appears equally probable that the pathologically enhanced neuronal activity (and metabolic rate) underlies both the cell damage and the perturbed metabolic state. The observed changes in cyclic nucleotides do not appear to bear a causal relationship to the mechanisms of damage.     

METABOLIC CHANGES IN THE BRAINS OF MICE FROZEN IN LIQUID NITROGEN

Abstract— Autolytic changes in the mouse brain, occurring during immersion of the animal in liquid nitrogen, were evaluated by measuring the tissue concentrations of glucose, lactate, pyruvate, α-oxoglutarate, phosphocreatine, creatine, ATP, ADP and AMP. The values thus obtained were compared with those obtained in paralysed mice under nitrous oxide anaesthesia, the brains of which were frozen in such a way that arterial blood pressure and oxygénation were upheld during the freezing. Immersion of unanaesthetized mice in liquid nitrogen gave rise to significant alterations in phosphocreatine, creatine, lactate, lactate/pyruvate ratio, ADP and AMP. A comparison with values obtained in paralysed and anaesthetized mice that were frozen by immersion in liquid nitrogen showed that the metabolic changes observed in the unanaesthetized animals could not be caused by an anaesthetic effect on the metabolic pattern. It is concluded that autolysis in the mouse brain occurs during immersion of the animal in a coolant, mainly because arterial hypoxia develops before the tissue is frozen. A comparison with previous results on rat cerebral cortex indicates that mice offer no advantage for studies of cerebral metabolites in unanaesthetized animals. In both species, accurate analyses of labile cerebral metabolites require that the brain is frozen in a way that prevents arterial hypoxia during the fixation of the tissue.     

Influence of intermittent hypoxia and pyrimidinic nucleosides on cerebral enzymatic activities related to energy transduction

The effect of intermittent normobaric hypoxia and of biological pyrimidines (uridine and cytidine) on the specific activities of some enzymes related to cerebral energy metabolism were studied. Measurement were carried out on the following: (a) homogenate in toto; (b) purified mitochondrial fraction; (c) crude synaptosomal fraction, in different areas of rat brain: cerebral cortex, hippocampus, corpus striatum, hypothalamus, cerebellum, and medulla oblongata. Intermittent normobaric hypoxia (12 hours daily for 5 days) caused modifications of the enzyme activities in the homogenate in toto (decrease of hexokinase in cerebellum; increase of pyruvate kinase in medulla oblongata), in the purified mitochondrial fraction (increase of succinate dehydrogenase in the corpus striatum) and in the crude synaptosomal fraction (decrease of cytochrome oxidase activity in cerebral cortex, hippocampus, and cerebellum; decrease of malate dehydrogenase in hippocampus and cerebellum; decrease of lactate dehydrogenase in cerebellum). Daily treatment with cytidine or uridine altered some enzyme activities either affected or unaffected by intermittent hypoxia.     

Regional levels of glucose,amino acids,high energy phosphates,and cyclic nucleotides in the central nervous system during hypoglycemic stupor and behavioral recovery

The effects of insulin-induced hypoglycemic stupor and subsequent treatment with glucose on mouse cerebral cortical, cerebellar and brain stem levels of glucose, glycogen, ATP, phosphocreatine, glutamate, aspartate and GABA and on cerebral cortical and cerebellar levels of cyclic AMP and cyclic GMP have been measured. Hypoglycemia decreased glucose, glycogen and glutamate levels and had no effect on ATP levels in all three regions of brain. GABA levels were decreased only in cerebellum. Aspartate levels rose in cerebral cortex and brain stem, and creatine phosphate increased in cerebral cortex and cerebellum. In the hypoglycemic stuporous animals, cyclic GMP levels were elevated in cerebral cortex and depressed in cerebellum whereas cyclic AMP levels were unchanged from control values. Intravenous administration of 2.5-3.5 mmol/kg of glucose to the hypoglycemic stuporous animals produced recovery of near normal neurological function within 45 s. Only brain glucose and aspartate levels returned to normal prior to behavioral recovery. These results suggest that of the several substances examined in this study, only glucose and perhaps aspartate have important roles in the biochemical mechanisms producing neurological abnormalities in hypoglycemic animals.     

Ammonia Intoxication: Effects on Cerebral Cortex and Spinal Cord

The effect of an acute systemic ammonia intoxication on the metabolic states of the cerebral cortex and the spinal cord of the same animal was studied in the cat. The intravenous infusion of ammonium acetate (2 and 4 mmol/kg body weight/30 min) increased the gross levels of tissue NH4+, glutamine, glutamine/glutamate ratio, lactate, and the lactate/pyruvate ratio in the cerebral cortex and the spinal cord. Pyruvate increased, but significantly only in the spinal cord; aspartate decreased, but significantly only in the cerebral cortex. The infusion of ammonium acetate did not significantly change the levels of phosphocreatine, ATP, ADP, AMP, total adenine nucleotides, adenylate energy charge, glucose, glutamate, alpha-ketoglutarate, and malate in either tissue. The changes of NH4+, glutamine, and lactate levels as well as glutamine/glutamate and lactate/pyruvate ratios in the spinal cord correlated significantly with the corresponding changes of these metabolites in the cerebral cortex. Thus, cerebral cortex and spinal cord show certain specific and comparable metabolic changes in response to a systemic ammonia intoxication. The effect of ammonia intoxication on the increases of glutamine and lactate levels is discussed.     

PGF2 alpha, thromboxane B2 and HETE levels in gerbil brain cortex after ligation of common carotid arteries and decapitation.

The effects of ligation of both common carotid arteries in the gerbil on the levels of PGF2 alpha, TXB2, HETE and of energy metabolites in brain cortex, have been investigated. Also, in the same experimental conditions the changes of cyclic AMP in brain cortex, cerebellum, striatum and hippocampus have been monitored. ATP, glycogen, glucose and phosphocreatine decrease whereas, lactate and cyclic AMP are enhanced in the ischemic brain, as previously reported. In contrast, levels of arachidonic acid metabolites are not modified. During ischemia following decapitation, instead, PGF2 alpha, and TXB2, show considerable increase.     

RESPIRATION IN VITRO OF SYNAPTOSOMES FROM MAMMALIAN CEREBRAL CORTEX

Abstract— —(1) The respiratory properties of synaptosomes and mitochondria from mammalian cerebral cortex are compared.
(2) Synaptosome showed high and linear respiration with glucose and pyruvate as substrates in Krebs-Ringer media. Mitochondria showed such respiration only with pyruvate as substrate in media lacking Na and high in K and phosphate.
(3) Exposure of synaptosomes to hypotonic media caused loss of lactate dehydrogenase (LDH) and protein, and respiration diminished and became non-linear.
(4) Both ATP and phosphocreatine were synthesised by synaptosomes with glucose as substrate. ATP was synthesised by mitochondria in the presence of pyruvate.
(5) Synaptosome but not mitochondria showed some capacity for active accumulation of potassium.
(6) Both mitochondria and synaptosomes respired with glutamate as substrate. Glutamate caused 80 per cent loss of ATP and phosphocreatine in synaptosomes but did not diminish the level of mitochondrial ATP.     

Cerebral Metabolic State During the Ethanol Withdrawal Reaction in the Rat

Abstract: A severe ethanol withdrawal reaction was induced in rats by means of repeated intragastric intubation during a 4-day period. At the peak of the withdrawal reaction cerebral cortical tissue was frozen in situ for analysis of glycogen, glucose, phosphocreatine, creatine, ATP, ADP, AMP, lactate, pyruvate, GAB A, β-hydroxybutyrate, acetoacetate, cAMP and cGMP. Blood glucose concentration was also measured. The level of brain glycogen was decreased during ethanol withdrawal. Brain glucose concentration was increased, probably secondary to the increase in blood glucose concentration. The calculated NADH/NAD⁺ ratio was slightly increased during the withdrawal and brain ATP concentration and adenine nucleotide pool size were decreased. The adenylate energy charge remained unchanged. The overall changes in the metabolites were in agreement with the previously shown metabolic activation during ethanol withdrawal. The brain concentrations of ketone bodies (β-hydroxybutyrate and acetoacetate) during withdrawal did not deviate from controls, indicating that no abnormal ketone metabolism had developed as a consequence of the long-lasting ethanol intoxication. No changes were observed in the concentrations of GABA, cAMP, or cGMP in the rat cerebral cortex during ethanol withdrawal.     

PGF2α, thromboxane B2 and hete levels in gerbil brain cortex after ligation of common carotid arteries and decapitation

The effects of ligation of both common carotid arteries in the gerbil on the levels of PGF_2α, TXB₂, HETE and of energy metabolites in brain cortex, have been investigated. Also, in the same experimental conditions the changes of cyclic AMP in brain cortex, cerebellum, striatum and hippocampus have been monitored. ATP, glycogen, glucose and phosphocreatine decrease whereas, lactate and cyclic AMP are enhanced in the ischemic brain, as previously reported. In contrast, levels of arachidonic acid metabolites are not modified. During ischemia following decapitation, instead, PGF_2α, and TXB₂, show considerable increase.     

Mechanisms of Cyclic AMP Regulation in Cerebral Anoxia and Their Relationship to Glycogenolysis

Abstract: Anoxia elevates levels of cyclic AMP and depresses levels of cyclic GMP in cerebral cortex of mice. Similar effects are also observed in other regions of the brain. Aminophylline inhibits accumulation of cyclic AMP about 50% in hippocampus and cerebellum, but not in cerebral cortex and striaturn; however, this effect requires high doses (²⁵⁰ mgikg). Pretreatment of animals with reserpine, which depletes brain stores of norepinephrine, dopamine, and serotonin, and also produces sedation and mild hypothermia, markedly inhibits accumulation of cyclic AMP in all regions of anoxic brain. Destruction of norepinephrine terminals by treatment of neonatal animals with ⁶-OH- dopamine, which does not sedate or produce hypothermia, has an effect on cyclic AMP levels similar to that of reserpine. None of the above treatments modifies the effect of anoxia on cyclic GMP levels. These data indicate that norepinephrine is a major regulator of cyclic AMP levels in anoxic brain and that adenosine and, perhaps, other unidentified substances have lesser roles in this process. In contrast, biogenic amines and adenosine appear to have no effect on cyclic GMP regulation in anoxic brain. Reserpine slows the activation of phosphorylase and the utilization of ATP, and slightly attenuates the breakdown of glycogen caused by anoxia, but has no effect on the changes in glucose, lactate, or phosphocreatine. In contrast, ⁶-OH-dopamine has no effect on any of these anoxiainduced changes. It is concluded that the effect of reserpine on phosphorylase, glycogen, and ATP is most likely related to the hypothermic and sedative effect of the drug, and that either cyclic AMP is not responsible for initiating glycogenolysis in anoxic brain or only a small rise in cyclic AMP levels is necessary for this process.     

CEREBRAL METABOLIC CHANGES IN PROFOUND, INSULIN-INDUCED HYPOGLYCEMIA, AND IN THE RECOVERY PERIOD FOLLOWING GLUCOSE ADMINISTRATION

Severe hypoglycemia was induced by insulin in lightly anaesthetized (70°_o N₂O) and artificially ventilated rats. Brain tissue was frozen in situ after spontaneous EEG potentials had disappeared for 5. 10. 15 or 30 min and cerebral cortex concentrations of labile organic phosphates, glycolytic metabolites, ammonia and amino acids were determined. In other experiments, recovery was induced by glucose injection at the end of the period of EEG silence. All animals with an isoelectric EEG showed extensive deterioration of the cerebral energy state. and gross perturbation of amino acid concentrations. The latter included a 4-fold rise in aspartate concentration and reductions in glutamate and glutamine concentrations to 20 and 5^o_o of control levels respectively. There was an associated rise in ammonia concentration to about 3μmol-g^-1. Administration of glucose brought about extensive recovery of cerebral energy metabolism. For example, after an isoelectric period of 30 min tissue concentrations of phosphocreatine returned to or above normal, the accumulation of ADP and AMP was reversed, there was extensive resynthesis of glycogen and glutamine and full normalisation of tissue concentrations of pyruvate. α-ketoglutarate. GABA and ammonia. However, even after 3 h of recovery there was a reduction in the ATP concentration and thereby in adenine nucleotide pool, moderate elevations of lactate content and the lactate pyruvate ratio, and less than complete restoration of the amino acid pool. It is concluded that some cells may have been irreversibly damaged by the hypoglycemia.     

BRAIN ENERGETICS IN OXYGEN-INDUCED CONVULSIONS

Mice were exposed to 6 ATA of 100% oxygen. The effect of high oxygen pressure (OHP), disulphiram and both disulphiram and oxygen as a function of the length of oxygen exposure on cerebral cortical ATP, phosphocreatine, lactate, pyruvate and glucose was determined. Neither OHP nor disulphiram altered ATP prior to the onset of convulsions. The combination of OHP and disulphiram appeared to elevate cerebral ATP, particularly during the early exposure period. OHP had no effect on phosphocreatine, however, disulphiram, both alone and in combination with OHP increased cerebral cortical phosphocreatine. ATP and phosphocreatine were unchanged in mice sacrificed either at the onset or 9 s after the onset of oxygen convulsions. Lactate and pyruvate increased as the length of time the mice were exposed to OHP increased although neither lactate nor pyruvate levels differed significantly from control levels at either the onset or 9 s after the onset of convulsions. Disulphiram by itself lowered cerebral lactate, and prevented the increase in lactate and pyruvate in mice exposed to OHP. OHP and disulphiram increased cerebral glucose with the combination of both OHP and disulphiram appearing to have an additive effect. Glucose also remained elevated at the onset or 9 s after the onset of oxygen convulsions.     

Enzymic and metabolic adaptations in the gastrocnemius, plantaris and soleus muscles of hypocaloric rats.

1. The effect of hypocaloric feeding (25% of normal food intake for 21 days) of rats on the enzymic and metabolic adaptations in the gastrocnemius, plantaris and soleus muscles was studied. 2. In control and hypocaloric rats the muscle relaxation rates at 100 Hz were 35.76 and 11.38% force loss/10 ms respectively. Control rats exhibited enhanced force of muscle contraction as the frequency of stimulation increased from 10 to 100 Hz, with maximum force being at 100 Hz. Hypocaloric rats exhibited a decrease in the increment of force being exerted at high frequencies, with maintenance of force at lower stimulatory frequencies. 3. In muscles of hypocaloric rats, there were significant decreases in the maximal activities of hexokinase (17.6-37.0%), 6-phosphofructokinase (22.7-34.2%), pyruvate kinase (21.2-36.0%), citrate synthase (34.1-41.5%), oxoglutarate dehydrogenase (29.4-52.4%) and 3-hydroxyacyl-CoA dehydrogenase (26.7-32.1%), whereas the activities of glycogen phosphorylase increased (23.8-43.4%) compared with control values. 4. In soleus-muscle strip preparations of hypocaloric rats, there were significant decreases in the rates of lactate production (28.1%) and glucose oxidation (32.6%) compared with control preparations. 5. Mitochondrial preparations from muscles of hypocaloric rats incubated with various substrates exhibited decreased rates of oxygen uptake compared with control preparations. 6. In muscles of hypocaloric rats (gastrocnemius and soleus), there were significant decreases in the concentrations of glycogen (P less than 0.001) and phosphocreatine (P less than 0.001) and increases in those of pyruvate (P less than 0.001), lactate (P less than 0.001) and ADP (P less than 0.001), whereas those of ATP and AMP remained unchanged. 7. Calculated [lactate]/[pyruvate] and [ATP]/[ADP] ratios exhibited significant increases (P less than 0.05) and decreases (P less than 0.05) in muscles of hypocaloric rats respectively. 8. The results are discussed in relation to the genesis of muscle dysfunction caused by malnutrition.     

Dynamics of cerebral metabolism during moderate hypercapnia.

The effects of hypercapnia on the kinetics of cerebral energy metabolism were evaluated in adult rats by the closed system method of LOWRY et al. (1964). Moderate hypercapnia with a Pa_co2 of 61 torr sustained for 20 min resulted in intracellular brain acidosis (7.07-6.97). During hypercapnia the tissue content of glucose increased whereas phosphocreatine, ADP, pyruvate and lactate contents, and the lactate/pyruvate ratio decreased. The ATP/ADP ratio increased from 7.7 to 9.0; the cytoplasmic NADH/NAD + ratio decreased from 2.06 × 10^-3 to 1.49 × 10^-3. There was no change in Energy Charge. Turnover rate of phosphocreatine increased from 3.84 to 4.62 mmol/kg/min, but the turnover rates of ATP, glucose and glycogen were reduced (from 1.98 to 1.86, 6.24 to 4.80, and 3.96 to 2.94 mmol/kg/min, respectively). The utilization rate of total high energy phosphate decreased from 30.6 to 25.4 mmol/kg/min while the post-decapitation EEG during hypercapnia persisted longer than during normocapnia. These results indicate that moderate hypercapnia reduces the overall kinetic activity of cerebral energy metabolism. The steady Energy Charge suggests that the reduction in the rate of high energy phosphate use is proportionally balanced by a lowered production rate of ATP.     

The effect of electroshock on regional CNS energy reserves in mice

ATP, phosphocreatine, glycogen, glucose and lactate levels were measured in the cerebral cortex, thalamus, cerebellum, brain stem and spinal cord of mice following supramaximal electroshock. During the initial 17 s after the onset of a 2 s electrical stimulus high energy phosphate expenditure exceeded formation in all regions but was slower in spinal cord than in the other regions. In cerebral cortex high energy phosphate utilization continued to exceed formation for 32 s which was twice as long as in any other region studied. Altered levels of metabolites recovered most rapidly in spinal cord and least rapidly in cerebral cortex. Pretreatment with a non-anaesthetic dose of phenobarbitone influenced the effect of electroshock. Most of the clinical seizure was prevented, and increased high energy phosphate utilization was sustained for a much shorter period. Only in cerebral cortex did high energy phosphate expenditure exceed formation for as long as 15 s after the electrical stimulus; but even in this region the excess of expenditure over formation was much less than in untreated animals.     

Partial Restoration of Cerebral Myelination of the Congenitally Hypothyroid Mouse by Parenteral or Breast Milk Administration of Thyroxine

The objective of the present study was to assess metabolic changes in the neocortex and hippocampus of well-oxygenated or moderately hypoxic rats in which fluorothyl-induced seizures were sustained for 5 or 20 min, or which were allowed recovery periods of 5, 15, or 45 min following cessation of 20-min seizure activity by withdrawal of the convulsant gas. Sustained fluorothyl-induced seizures were found to cause metabolic alterations qualitatively and quantitatively similar to those previously observed with other commonly used convulsants. Thus, although the phosphorylation state of the adenine nucleotide pool remained only moderately perturbed, if at all, there were decreases in tissue concentrations of phosphocreatine and glycogen, and increases in those of cyclic AMP, lactate, and pyruvate, with a calculated fall in intracellular pH of about 0.15 units and a rise in the cytoplasmic NADH/NAD+ ratio. The enhanced metabolic rate was reflected in a marked reduction in the tissue-to-plasma glucose concentration ratio. Induced moderate hypoxia (arterial PO2 40-50 mm Hg) had no metabolic effect after 5 min of seizures but moderately increased lactate concentrations after 20 min (from about 10 to about 15 mumol X g-1). On cessation of seizure discharge cyclic AMP and phosphocreatine concentrations normalized already within 5 min, whereas glycogen and lactate concentrations normalized more slowly. In the neocortex (but not the hippocampus) postepileptic tissue-to-plasma glucose concentration ratios rose above control, probably reflecting metabolic depression. The results suggest that intracellular pH promptly returned to control, and that postepileptic alkalosis developed. They also suggest that some elevation of the NADH/NAD+ ratio persisted even after 45 min of recovery.     

CEREBRAL METABOLIC AND CIRCULATORY CHANGES INDUCED BY HYPOXIA IN STARVED RATS

In order to study cerebral metabolic and circulatory effects of hypoxia under conditions of restricted glucose supply, the arterial P_o2, was reduced to 25–30mm Hg in artificially ventilated and lightly anaesthetized rats that were starved for 24 or 48 h prior to experiments. Arterial glucose concentrations, that were initially around 6μmol g^-1, were significantly reduced after 15min of hypoxia, and decreased to 50^o of control after 30min. In animals studied after 30min of hypoxia (24 h of starvation), cerebral blood flow had increased 4-fold and there was a moderate (25%) rise in cerebral oxygen consumption. During the course of hypoxia, cerebral cortical concentrations of glucose fell to low values. In spite of this, concentrations of pyruvate and lactate rose with time, and the sum of citric acid cycle intermediates (citrate, α-ketoglutarate, fumarate. malate and oxaloacetate) increased. Changes in amino acids were dominated by a fall in aspartate and a rise in alanine concentration. There was a moderate reduction in phosphocreatine and a slight rise in ADP concentration, but concentrations at ATP and AMP were unchanged. The changes observed are similar to those previously obtained in fed animals. It is concluded that even if blood glucose concentrations fall to 3μmol g^-1, and cerebral energy flux is maintained, substrate supply is sufficient to cover the energy requirements of the tissue. Hypoxia was accompanied by increases in the lactate/pyruvate and β-hydroxybutyrate acetoacetate ratios of blood. In the tissue, NADH/NAD⁺ ratios derived from the lactate, malate and β-hydroxybutyrate dehydrogenase systems rose, while that derived from the glutamate dehydrogenase reaction fell. It is concluded that the latter system is not well suited for estimating mitochondrial redox changes in brain tissue.     

Relating Cerebral Ischemia and Hypoxia to Insult Intensity

The contributions of five variables believed to influence the brain's metabolism of O2 during hypoxia [duration, PaO2, delta CMRO2 (the difference between normal and experimental oxygen uptake), O2 availability (blood O2 content.CBF), and O2 deficit (delta CMRO2.duration)] were assessed by stepwise and multiple linear regression. Levels of brain tissue carbohydrates (lactate, glucose, and glycogen) and energy metabolites [ATP, AMP, and creatine phosphate (CrP)] were significantly influenced by O2 deficit during hypoxia, as was final CMRO2. After 60 min of reoxygenation, levels of tissue lactate, glucose, ATP, and AMP were related statistically to the O2 deficit during hypoxia; however, CMRO2 changes were always associated more significantly with O2 availability during hypoxia. Creatine (Cr) and CrP levels in the brain following reoxygenation were correlated more to delta CMRO2 during hypoxia. Changes in some brain carbohydrate (lactate and glucose), energy metabolite (ATP and AMP) levels, and [H+]i induced by complete ischemia were also influenced by O2 deficit. After 60 min of postischemic reoxygenation, brain carbohydrate (lactate, glucose, and glycogen) and energy metabolite (ATP, AMP, CrP, and Cr) correlated with O2 deficit during ischemia. We conclude that "O2 deficit" is an excellent gauge of insult intensity which is related to observed changes in nearly two-thirds of the brain metabolites we studied during and following hypoxia and ischemia.     

Glycogen, ammonia and related metabolities in the brain during seizures evoked by methionine sulphoximine

Abstract— The levels of ATP, P-creatine, glucose, glycogen, lactate, glutamate and ammonia were measured in mouse brain after administration of the convulsive agent methionine sulphoximine (MSO). No changes were observed in ATP and P-creatine levels either before or during the seizures. Lactate levels were unchanged until the onset of seizures (4–5 hr) at which time the levels increased an average of 65 per cent. Glucose and glycogen levels increased progressively. Just before the onset of seizures the levels had increased 95 and 62 per cent, respectively. During the seizures both substances had increased a total of 130 per cent. Comparable changes were found in cerebral cortex, cerebellum and subcortical forebrain. Through the use of quantitative histochemical methods it was found that the greatest increases in glycogen occurred in layers I and III (layers II and IV were not analysed). Progressively smaller changes were found in layers V and VI and no increase at all was found in the subjacent white matter. Glucose, in contrast to glycogen, increased to about the same degree in all cerebral layers and in subjacent white matter. The increase in glycogen after MSO administration may be related to the fact that MSO also causes an increase in the ratio of brain to serum glucose levels. This would indicate that an increase in intracellular glucose had occurred. Ammonia levels were increased 300–400 per cent in both cerebrum and cerebellum. A time study in cerebellum showed that the increase begins early and reaches maximal levels long before the onset of seizures. Glutamate levels were reduced by small but statistically significant amounts in both cerebrum and cerebellum. Administration of methionine sulphoximine completely prevented seizures and the increase in lactate, but did not prevent the increases in glycogen and glucose. The rise in ammonia was reduced but not prevented. During 20 sec of complete ischaemia (decapitation) ATP, P-creatine and glucose fell somewhat more rapidly than normal in brain of animals undergoing MSO seizures. From the changes it was calculated that the metabolic rate had been increased about 20 per cent by the seizure. A new sensitive and specific enzymic method for determination of tissue ammonia is presented together with evised enzymic procedures for lactate and glutamate.     

Metabolic adjustments in the common carp during prolonged hypoxia

Biochemical and respiratory changes in the common carp Cyprinus carpio , were studied 6, 24, 96 and 168 h upon exposure to hypoxia (0·5 mgO₂ l⁻¹). Modification of kinetic properties of phosphofructokinase (PFK-1), coupled with a decreased in PFK-1 activities, were evident in muscle. No changes in kinetics and activities could be observed in muscle pyruvate kinase (PK) and lactate dehydrogenase (LDH). A decrease in muscle citrate synthase (CS) and an increase in muscle cytochrome c oxidase (CCO) were found. The common carp was able to maintain a constant level of muscle glycogen, muscle ATP, and liver CS throughout the 168-h experimental period. Changes in activities of liver LDH and muscle CCO were observed only at 168 h, which indicates that common carp may switch to alternative metabolic pathway to deal with prolonged hypoxia. A severe decrease in liver glycogen was accompanied by increases in lactate levels in both the muscle and liver. Oxygen consumption rate was reduced under hypoxia, but resumed to normoxic levels within 2 h upon return to normoxic condition. Overall, these results indicate that carp adopt different strategies in an attempt to deal with short term and long term hypoxia in the natural environment.