THE EFFECT OF INDUCED HYPOTHERMIA UPON OXYGEN CONSUMPTION IN THE RAT BRAIN

The effect of hypothermia upon cerebral metabolic rate for oxygen (CMR_O2) was studied in artificially ventilated rats, anaesthetized with nitrous oxide. Cerebral blood flow was measured with a modification of the Kety and Schmidt technique using ¹³³xenon. CMR_O2, was found to decrease linearily with temperature in the temperature range 37°C-22°C. At normal temperatures CMR_O2, fell by about 5 per cent per degree C. At a body temperature of 22°C both cerebral blood flow and CMR_O2, were reduced to about 25 per cent of normal.     

BRAIN METABOLISM AT LOW TEMPERATURES

Abstract— Levels of ATP, ADP, phosphocreatine, glycogen, glucose, lactic acid and inorganic phosphate in the rabbit brain were determined after cerebral hypothermia to 24, 22, 20, 18 and 16°C brain temperature. Hypothermia was induced by isolated head perfusion by means of an extracorporeal device including a donor animal of the same species. In two experiments brains were cooled to 24 and 16°C, followed by rewarming to nearly normothermic values before brain biopsy was performed. In all experiments the electrical activity of the cerebral cortex was recorded intermittently.
No metabolic disturbances could be observed in 25 out of a total number of 26 experiments. Only one experiment showed a marked decrease in cerebral content of high-energy phosphates, glycogen and glucose and a corresponding increase of lactic acid and inorganic phosphate. These metabolic changes were caused in our opinion by convulsive activity of the brain induced by hypothermia. This was recorded in an electrocorticogram at a brain temperature ranging from 18·9 to 17·8°C over a 150 s period, 5 min before this brain was removed from the animal. These findings demonstrate that hypothermia per se to 24–16°C under our experimental conditions does not cause damage to the rabbit brain, generally, but under special conditions can provoke an increase in energy requirement which exceeds the energy available.     

ENZYMIC AND CEREBRAL METABOLIC EFFECTS OF 2-DEOXY-d-GLUCOSE

—The time course of effects of 2-deoxy-d -glucose on cerebral glucose metabolism has been studied in vivo and the inhibitory actions of 2-deoxy-d -glucose and 2-deoxy-d -glucose-6-phosphate on cerebral glycolytic enzymes in vitro. Mice were given 2-deoxy-d -glucose 3 g/kg intraperitoneally. Blood 2-deoxy-d -glucose/glucose ratio was 2–3 from 5 to 30 min after injection, the hyperglycaemic response to 2-deoxy-d -glucose having been suppressed with propranolol. Maximal cerebral 2-deoxy-d -glucose uptake observed was 1μ11 μmol/g/min between 5 and 10 min after injection. At 10 min brain concentrations of 2-deoxy-d -glucose and 2-deoxy-d -glucose-6-phosphate were 5·82 and 3·12 μmol/g. Analysis of the fate of d -[U-¹⁴C] glucose given subcutaneously 5 min before death showed that glucose uptake was reduced to 40–60 per cent of control from 5 to 30 min after 2-deoxy-d -glucose. However brain glucose concentration rose three to five-fold 20–30 min after 2-deoxy-d -glucose. The majority of glucose entering the brain after 10 min of 2-deoxy-d -glucose treatment was recovered as glucose. Conversion of brain glucose to other acid soluble components was reduced to 1/3 at 10 min and 1/5 at 20–30 min. Glucose-6-phosphate concentration rose from 5 min onwards and was maintained at twice control concentration from 10–30 min. However, because of the rapid entry of 2-deoxy-d -glucose and its conversion to 2-deoxy-d -glucose-6-phosphate, the 2-deoxy-d -glucose 6-P/glucose 6-P ratio was between 19 and 32. Brain adenosine triphosphate concentration did not change, creatine phosphate concentration fell after 25 min. Measurement of enzyme activities in cerebral homogenates (using 1 mivs substrate concentration) showed that hexokinase (EC 2.7.1.1) was 40 per cent inhibited by 5 mm -deoxy-d -glucose (but not by 2-deoxy-d -glucose 6-P). Glucose 6-P dehydrogenase (EC 1.1.1.49), 6-phosphogluconate dehydrogenase (EC 1.1.1.43) and phosphoglucomutase (EC 2.7.5.1) were not affected by either 2-deoxy-d -glucose (5 mm ) or 2-deoxy-d -glucose 6-P (5 or 20 mm ). Hexose-phosphate isomerase (EC 5.3.1.9) was 70 per cent inhibited by 20 mm -d -deoxy-d -glucose 6-P. Phosphofructokinase (EC 2.7.1.11) was inhibited by 17 per cent by 2-deoxy-d -glucose 6-P (20 mm ). During the initial impairment of cerebral function by 2-deoxy-d -glucose there is competitive inhibition of glucose transport into the brain; later, glycolysis is more powerfully depressed by the inhibition of isomerase produced by the high intracerebral concentration of 2-deoxyglucose-6-phosphate.     

THE EFFECT OF HYPERTHERMIA UPON OXYGEN CONSUMPTION AND UPON ORGANIC PHOSPHATES, GLYCOLYTIC METABOLITES, CITRIC ACID CYCLE INTERMEDIATES AND ASSOCIATED AMINO ACIDS IN RAT CEREBRAL CORTEX

The influence of hyperthermia on cerebral blood flow, cerebral metabolic rate for oxygen and cerebral metabolite levels was studied by increasing body temperature from 37° to 40°C and 42°C in rats under nitrous oxide anaesthesia maintained at constant arterial CO₂ tension. The metabolic rate for oxygen increased by 5-6% per degree centigrade. At 42°C the increase in cerebral blood Row was comparable to that in the metabolic rate. The increased temperatures were not accompanied by changes in organic phosphates (phosphocreatine, ATP, ADP or AMP) or in lactate/pyruvate ratio. There was an increase in the tissue to blood glucose concentration ratio. At steady state, there was an increase in glucose-6-phosphate but no other changes in glycolytic metabolites or citric acid cycle intermediates, and the only change in amino acids studied (glutamate, glutamine, aspartate, alanine and GABA) was an increase in glutamate concentration.     

EFFECT OF HYPOTHERMIA UPON ORGANIC PHOSPHATES, GLYCOLYTIC METABOLITES, CITRIC ACID CYCLE INTERMEDIATES AND ASSOCIATED AMINO ACIDS IN RAT CEREBRAL CORTEX

—The influence of hypothermia upon the metabolism of the brain was studied by reducing body temperature in N₂O-anaesthetized rats to 32, 27 or 22°C, with subsequent measurements of organic phosphates, glycolytic metabolites, citric acid cycle intermediates and associated amino acids. Hypothermia was maintained for either 1 or 2 h and the effect of anaesthesia was evaluated by maintaining unanaesthetized animals at 22°C. Hypothermia had no influence on the cerebral cortical concentrations of ATP, ADP or AMP and there was only a small increase in phosphocreatine. Since the tissue concentrations of glucose and glycogen were reduced, it is concluded that the well known resistance of the hypothermie brain to ischaemia is unrelated to increased energy stores. Hypothermia was accompanied by decreases in the tissue concentrations of fructose-1,6-diphosphate, dihydroxyacetone phosphate, 3-phosphoglycerate, pyruvate, lactate, α-ketoglutarate, succinate and malate, but not of glucose-6-phosphate or citrate. These results indicate that metabolic flux is retarded mainly at the phosphofructokinase and isocitrate dehydrogenase steps. The largest relative reduction was seen in α-ketoglutarate, which was possibly secondary to accumulation of ammonia. There was no change in GABA, but a decrease in glutamate and increases in aspartate and alanine. These, changes are compatible with shifts in the aspartate and alanine aminotransferase reactions, possibly induced by the fall in α-ketoglutarate.     

RATES OF CEREBRAL GLUCOSE UTILIZATION IN RATS ANAESTHETIZED WITH PHENOBARBITONE

Abstract—

• 1 Intraperitoneal injection of phenobarbitone (250 mg/kg body wt.) into rats caused increased brain concentrations of glucose (100 per cent), glucose 6-phosphate (16 per cent) and ATP (12 per cent) and decreased concentrations of lactate (33 per cent) and ADP (15 per cent). A 31 per cent decrease in glutamate content was not statistically significant. No significant change occurred in the cerebral contents of glycogen or creatine phosphate.
• 1 The rates of increase in the brain of specific activities, in the first few minutes after systemic injection of [U-¹⁴C]glucose, of glucose, lactate, glutamate and glycogen were all halved by phenobarbitone. Calculated flux rates of ¹⁴C from glucose into metabolic intermediates and from lactate to glutamate were also decreased by 27–47 per cent; the effects on rate constants showed inconsistencies. The rate constants for conversion of glucose to lactate and to glutamate were decreased by 60–70 per cent, but that from lactate to glutamate was virtually unchanged. The rate constant for the flux from glucose to glycogen was reduced by 39 per cent, but the accumulation of glucose meant that the actual flux into glycogen increased by 20 per cent.
• 1 The results are interpreted in terms of an effect of the barbiturate not only on glucose transport, but also at an enzymic stage in glycolysis, possibly hexokinase or phosphofructokinase.

     

MANIFESTATION OF METABOLIC COMPARTMENTATION DURING THE MATURATION OF THE RAT BRAIN

—(1) The fate of [U-¹⁴C]leucine was studied in rat brain in vivo from birth to five weeks of age. The major route of leucine metabolism at all ages was conversion into protein. The rate of protein synthesis was low in the newborn; it reached a peak at about 15 days and slowed down moderately later. Incorporation into brain lipids was relatively low under the experimental conditions (less than 2 per cent of the total tissue ¹⁴C). (2) The conversion of leucine-carbon into amino acids associated with the tricarboxylic acid cycle was low in the first 9 days after birth (less than 4 per cent of the acid-soluble ¹⁴C at 10 min after injection) and increased rapidly until 15 days when the level characteristic of the adult was approached (about 20 per cent of the acid-soluble ¹⁴C). The results indicated that the oxidation of acetyl-CoA derived from leucine reached the adult level at an earlier age than that derived from glucose. (3) The glutamine/glutamate specific radioactivity ratio was 0·3 in the brain of newborn animals and increased progressively; it was 1·3 and 2·4 at 15 and 35 days of age respectively. The specific radioactivity of aspartate and of GABA relative to that of glutamate was less than 1 throughout the experimental period. (4) The factors involved in the development of metabolic compartmentation in brain were analysed. It is proposed that although the experimental results show that a 'small’compartment becomes functionally manifested with maturation the primary cause is the development of the‘large’metabolic compartment. (5) Morphological correlates of the metabolic compartments in brain tissue are suggested and it is concluded that the manifestation of metabolic compartmentation is related to maturational changes in glia-neuronal relations rather than to developmental processes affecting the individual components only.     

Characterization of γ-glutamyltranspeptidase in the liver of the frog: 3. Response to freezing and thawing in the freeze-tolerant wood frog Rana sylvatica

The freeze tolerant wood frog Rana sylvatica was studied to determine the impact of the freezing and thawing of this frog on the activity of γ-glutamyltranspeptidase in the liver. On exposure to ?2·5°C, for 1, 12 and 24 h, frogs were found to be cool, covered with ice crystals and frozen, respectively. Thawing for 24 h at 4°C recovered the frogs completely. A 45 per cent decrease in the liver weight: body weight ratio was notable after 1 h at ?2·5°C, suggestive of an early hepatic capacitance response. A glycemic response to freezing was observed: blood glucose levels exhibited a 55 per cent decrease after 1 h at ?2·5°C on cooling; a 10·5-fold increase after 12 h at ?2·5°C on the initiation of freezing; and a 22-fold increase after 24 h at ?2·5°C in the fully frozen state. Blood glucose levels remained elevated four-fold in the thawed state. Plasma insulin levels were increased twofold in the frozen state and 1·8-fold in the thawed state, while plasma ketone levels were increased 1·8-fold in the frozen state and 1·5-fold in the thawed state. Plasma total T₃ levels were decreased by 22 per cent in the frozen state and normalized on thawing. In homogenates and plasma membranes isolated from the livers of Rana sylvatica, the activity of γ-glutamyltranspeptidase was found to be elevated at all stages of the freeze–thaw process. After 1, 12 and 24 h at ?2·5°C, activities were increased 2·5-, 2·3-, 2·4-fold respectively in the homogenates and 2·5-, 2·2-, 2·4-fold respectively in the plasma membranes. After thawing, activities were still increased 1·9-fold in both homogenates and plasma membranes. In homogenates prepared from the kidneys of Rana sylvatica, the activity of γ-glutamyltranspeptidase was increased 1·4-fold after 1 h at ?2·5°C after which it returned to normal. The role of thyroid hormone in producing the increase in γ-glutamyltranspeptidase in the liver of Rana sylvatica in response to freezing is discussed as is the significance of the enzyme increase in terms of hepatic cytoprotection and freeze tolerance.     

Changes in metabolites of the energy reserves in individual layers of mouse cerebral cortex and subjacent white matter during ischaemia and anaesthesia

The distribution of glucose, glycogen, ATP, P-creatine and inorganic phosphate was measured in layers I, III, IV, V and VI of cerebral cortex and subjacent white matter of mouse brain. ATP, P-creatine and inorganic phosphate were evenly distributed in all regions examined, whereas levels of glucose and glycogen were higher in white matter than the average for the other layers. Anaesthesia increased levels of glucose and P-creatine in layers I and V and subjacent white matter (other layers were not examined). Anaesthesia doubled the level of glycogen in molecular layer I with lesser increases in layers III, IV, V and VI, but with no change in white matter from the unanaesthetized control value. The metabolic rates in the individual layers were estimated from the rates of expenditure of energy reserves during total ischaemia. In non-anaesthetized mice, white matter had a higher metabolic rate than either layer I or V. Anaesthesia reduced the metabolic rates in all layers; however, the largest reduction occurred in subjacent white matter (86 per cent), with reductions of 54 per cent and 76 per cent respectively in layers I and V.     

Physiological and biochemical changes in frog sciatic nerve during anoxia and recovery

Frog (Rana pipiens) sciatic nerve was incubated, with and without stimulation, in an oil bath. The correlation between changes in the magnitude of the compound action potential (α and β) and changes in metabolites, particularly energy reserves, during anoxia and recovery from anoxia was studied. The time to extinction of the action potential in anoxia was frequency-dependent. The action potential could not be restored, nor its extinction delayed, by washing the nerve in O₂-free Ringer's solution. Therefore, in this system extracellular K⁺ accumulation was not a significant factor in blocking impulse conduction. At the time of complete nerve block resulting from anoxia (90 min at rest), ATP, P-creatine and glucose were 30, 10 and 10 per cent, respectively, of initial levels. Glycogen did not fall below 42 per cent of control levels even after 5 h of anoxia. Changes in the levels of energy reserves during anoxia were used to calculate the metabolic rate of nerves at rest and during stimulation. In one series of experiments, the resting metabolic rate was 0·12 mequiv. of ‘high-energy phosphate’ (～P)/kg/min. Stimulation increased the metabolic rate to 0·22 mequiv. of ～P/kg/min at 30 Hz and to 0·29 mequiv. of ～P/kg/min at 100 Hz. The change in metabolic rate when the nerve passed from the resting to the stimulated state was quite abrupt, an observation suggesting that the slow transition observed with methods monitoring O₂, consumption was largely instrumental. In nerve stimulated to exhaustion in the absence of O₂, neither ATP nor P-creatine had fully recovered within 60 min after O₂, was readmitted, although the action potential reached supranormal levels 15 min after return to O₂. The ratio of lactate: pyruvate, which increased as expected during anoxia, paradoxically increased even further after O₂, was readmitted. The rate of energy utilization during recovery was 0·30 mequiv. of ～P/kg/min. Nerves stimulated at 100–200 Hz in O₂, exhibited no changes in levels of P-creatine, ATP or lactate, an observation implying that the nerve could not be made to use ～P faster than oxidation of glucose could provide it. This meant that the maximal metabolic rate was not limited by the rate of supply of chemical energy. Instead, the limitation may have arisen as a result of a limited rate at which ionic imbalance can result from stimulation or a limited pump capacity of the axonal membrane. Nerves stimulated at 200 Hz in O₂ for 20 min and then transferred to an O₂-free environment without further stimulation exhibited an increase in the rate of energy utilization (nearly two-fold) over the resting rate, a finding that suggested a metabolic (ionic?) debt as a result of activity which could not be met even though the energy supply was adequate. Therefore, restriction of energy expenditure by a limiting pumping rate seemed to be the most likely explanation. The resting metabolic rate of frog sciatic nerve was only one-quarter to one-third of the rate for rat sciatic nerve, when compared at the same temperature (25°C).     

Changes in the rates of protein synthesis in the brain of goldfish at various temperatures.

Intraperitoneal injections of [¹⁴C] tyrosine suspension into goldfish produced a relatively constant specific activity of free tyrosine in the brain over an 8 hour experimental period. This made the measurement of the rate of cerebral protein synthesis in this time period possible. The increase of protein-bound [¹⁴C] tyrosine was linear with time and occured in most protein fractions. In the absence of a net increase of protein it was an indicator of the rate of cerebral protein turnover. Rates of incorporation of tyrosine into brain proteins were 0.52 per cent/hour at 34° and 0.026 per cent/hour at 10°, i.e., the rate at 34° was about 20-fold that at 10°. Temperature gradients of protein turnover were similar in fish and rat brain.     

Microdensitometric measures of cytoplasmic RNA and total protein in pyramidal neurons of the insular cortex and midfrontal gyrus in patients with Alzheimer's disease

Scanning and integrating microdensitometry of azure B- and Coomassie brilliant blue G-stained tissue sections was used to measure the levels of RNA and protein, respectively, in pyramidal neurons of the insular cortex (INS) and midfrontal gyrus (MFG) in patients with Alzheimer's disease (AD) and age-matched, nondemented control subjects. AD was associated with a decreased neuronal RNA (by 7·4 per cent) and protein (by 28·7 per cent) content in INS. Although the neuronal RNA content was maintained at the control amounts in MFG, the average protein level was lower (14·7 per cent) in AD patients. These results demonstrate a disease-related impairment in metabolic function in two brain regions connected via discrete corticocortical pathways. Such findings support the hypothesis that a primary site of pathology occurs in AD, and specific neural deficits occur secondarily in certain connected brain regions.     

MEASUREMENT OF THE RATE OF ACETYLCHOLINE DIFFUSION THROUGH A BRAIN SLICE AND ITS SIGNIFICANCE IN STUDIES OF THE CELLULAR DISTRIBUTION OF ACETYLCHOLINESTERASE

The rate of ACh diffusion through a 0·8 mm thick slice from the surface of the rat cerebral cortex, under aerobic conditions at 37°C, was determined by bathing the intact surface of the slice (compartment A) with ACh containing buffer and determining the concentration of ACh in buffer bathing the cut surface of the slice (compartment B). With 1 or 5 mM-ACh in compartment A no ACh was detectable in compartment B within 3 h unless at least 95 per cent of the AChE, as assessed on homogenates, was inhibited. With a given level of AChE inhibition, the rate of ACh diffusion was dependent on its concentration in compartment A. With 1 mM-ACh in compartment A the difference between the rates of hydrolysis of ACh during diffusion through slices with an AChE inhibition of 98·3 and 99·4 per cent, as assessed by AChE assays of homogenates made from the slices, was only 6 per cent of the difference between the rates of hydrolysis of 1 m-ACh by the homogenates of that part of the slices through which diffusion took place. For 5 mM-ACh and levels of 95 and 99·2 per cent inhibition the corresponding value was 10-3 per cent. Since the concentration of ACh must fall across the slice it is not possible to calculate from these figures the number of enzyme sites involved in the hydrolysis during diffusion, i.e. the concentration of extracellular AChE. The implications of these observations are discussed, particularly in relation to studies of the release of ACh from the cerebral cortex in vivo     

Respiratory metabolism of the semen of the honey-bee, Apis mellifera

Mean respiratory quotients determined on samples from individual drones by Cartesian diver respirometry averaged 0·64, suggesting that phospholipids constitute the major source of energy. The average sperm density of semen was 7·76 millions/μl. Dilution of semen increased the rate of oxygen consumption by 68 per cent. Semen stored at 13 to 14°C for 1 month showed only 40 per cent of the oxygen uptake of freshly ejaculated semen. Streptomycin sulphate treated samples of semen showed significantly lower rates of oxygen consumption than untreated samples. These results suggest that the high density of sperm in the semen and low metabolic activity during storage may be at least partly responsible for the successful long-term storage of honey-bee spermatozoa.     

REGIONAL γ-AMINOBUTYRIC ACID LEVELS IN RAT BRAIN DETERMINED AFTER MICROWAVE FIXATION

—GABA levels in rat whole brain were compared following three methods of sacrifice: rapid microwave fixation, decapitation into liquid nitrogen, and decapitation at 20°C. Levels were shown to be identical in animals sacrificed by microwave fixation and decapitation into liquid nitrogen. In contrast, rats decapitated at 20°C had 18 per cent higher GABA levels when determined immediately post-mortem and 48 per cent higher levels after 30 min at 20°C. Microwave treatment prevented these post-mortem increases. The increase in GABA after decapitation at 20°C was even greater in hypothalamus than in whole brain. A comparison of 3 GABA extraction methods following microwave fixation demonstrated that sodium acetate was 88 per cent as effective as 80 per cent ethanol and more effective than 0·5 n -perchloric acid in extracting GABA. Fifteen brain regions were dissected from microwave-treated brains and the GABA levels determined.     

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.     

Observational and experimental studies on the acquisition of Anisakis sp. larvae (nematoda: Ascaridida) by trout in fresh water

In the enclosed fresh-water environmsnt of Hanningfield Reservoir, Essex, England, Anisakis sp. larvae (parasites of marine fish) were found in 55 per cent of 40 brown trout and in 26·2 per cent of 61 rainbow trout. Experimental infection by intubating larvae into the stomach was more successful in brown trout (50·6 per cent recovery rate) than in rainbow trout (27 per cent recovery rate). Some larvae reached the body-cavity as early as 2 h after infection. They penetrated the region between the oesophagus and intestine immediately posterior to the caecal openings. Fewer larvae successfully penetrated the gut wall of brown trout within 24 h at 8°C than at 15 ± 1°C. It appears that the reservoir trout acquired Anisakis by being fed as juveniles on untreated marine fish offal containing live larvae.     

SODIUM-DEPENDENT EFFLUX AND EXCHANGE OF GABA IN SYNAPTOSOMES

Abstract— The influx and efflux of [³H]GABA were investigated in synaptosomes. Two efflux components were detected. The first, termed spontaneous efflux, was not affected by the external sodium chloride concentration. The second, termed GABA-stimulated efflux, was observed when low levels of GABA were added to the incubation medium and was found to require external sodium chloride. The rate of spontaneous efflux at 0°C was about 37 per cent of the rate at 27°C but both GABA-stimulated efflux and GABA influx were completely inhibited at 0°C. The stimulation of efflux by external GABA followed simple Michaelis–Menten kinetics with respect to external GABA. The concentration of external GABA required for half-maximal stimulation was 4·9 ± 1·4 μm and the V_max for efflux was 1·0 ± 0·6 nmol. min^-1.mg^-1 of protein. A similar stimulation of efflux was observed with GABA analogue l -2,4-diamino-butyric acid which is a competitive inhibitor of influx. The concentration of external l -2,4-diaminobutyric acid required for half-maximal stimulation of efflux was 51 ± 12 μm and the V_max for efflux was 0·8 ± 0·5 nmol.min^-1.mg^-1 of protein. Since the sodium-dependency, temperature sensitivity, and kinetic properties of the GABA-stimulated efflux system were similar to the influx system, GABA-stimulated efflux was attributed to carrier-mediated exchange diffusion. Measurement of efflux and influx in the same preparation showed there was a net efflux when total fluxes were considered and that the exchange ratio (influx to GABA-stimulated efflux) was 0·9 when carrier-mediated fluxes were considered. The effect of the temperature of the fluid used to rinse synaptosomes collected on filters in influx experiments was investigated. There was no detectable difference in measured values of influx between samples rinsed with cold fluid (0°C) and warm fluid (27°C). The endogenous GABA content of synaptosomes was found to be 20·3 ± 2·5 nmol GABA per mg of protein. From this value, the cytoplasmic concentration of GABA in synaptosomes was estimated to be a maximum of 40 mm . About 5 per cent of total cerebral cortical GABA was found in the synaptosomal fraction.     

Correlation between [U-14C]glucose metabolism and function in perfused cat brain

In brain perfusion experiments conducted with blood containing [U-14C]glucose the relative specific activity (RSA) of blood glucose carbon incorporated in brain intermediate metabolites was measured. It was demonstrated that the so-called metabolic pattern of Geiger is not constant, but it bears a close relation to the function of the brain. The results of the study may be summarized briefly as follows. (1) In a group (A) of cats with a high level of brain function, the RSA of lactic acid was 75 per cent; that of glutamic acid 80 per cent; aspartic acid 75 per cent; glutamine 61 per cent; GABA 43 per cent; and respiratory CO2 55 per cent. It was observed that the major part of the carbon of amino acids, such as glutamic acid and aspartic acid, which are directly associated with the tricarboxylic acid cycle are derived from blood glucose. (2) In a group (B) showing a low level of brain function, the RSA of each amino acid was considerably lowered. The RSA of glutamic acid and aspartic acid was about 50 per cent and that of respiratory CO2 was 27 per cent. (3) In a group (C) with a still lower level of brain function, each amino acid as well as the respiratory CO2 had still lower RSA values. (4) The metabolic pattern of Geiger corresponds to values obtained during low functional activity of the brain in our experiment.     

Energy metabolism in the brains of L-phenylalanine-treated chicks

Abstract— When day-old chicks were injected intraperitoneally with 1.62mmoles of l -phenylalanine, they developed a condition resembling narcosis. Simultaneously, whole brain levels of phenylalanine were 2–4 μmol/g, whereas those in control brain were 0.06 μmol/g. Examination of some glycolytic intermediates in the brain revealed significant decreases in fructose-1,6-diphosphate, l -α-glycerol phosphate and lactate, in comparison to the levels of these compounds in the saline-injected control animals. Levels of glucose and glucose-6-phosphate either increased or did not change, whereas levels of glycogen did not differ significantly. Phosphocreatine increased reciprocally with the decrease in inorganic phosphate. The levels of adenine nucleotide (energy charge) were not affected. Utilization of cerebral high-energy phosphates was depressed by 50–70 per cent when determined as a function of metabolic rate in the brain at 15- and 30-s periods of ischaemia according to the ‘closed-system’ technique. Explanations for these data have been examined, such as toxicity of phenylacetate and inhibition of glycolytic enzymes by phenylpyruvate and l -phenylalanine and their relevance to this study is discussed.