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.     

Changes in the Redox State in the Retina and Brain During the Onset of Diabetes in Rats

Diabetic retinopathy is thought to result from chronic changes in the metabolic pathways of the retina. Hyperglycemia leads to increased intracellular glucose concentrations, alterations in glucose degradation and an increase in lactate/pyruvate ratio. We measured lactate content in retina and other ocular and non-ocular tissues from normal and diabetic rats in the early stages of streptozotocin-induced diabetes. The intracellular redox state was calculated from the cytoplasmic [lactate]/[pyruvate] ratio.Elevated lactate concentration were found in retina and cerebral cortex from diabetic rats. These concentrations led to a significant and progressive decrease in the NAD⁺/NADH ratio, suggesting that altered glucose metabolism is an initial step of retinopathy. It is thus possible that tissues such as cerebral cortex have mechanisms that prevent the damaging effect of lactate produced by hyperglycemia and/or alterations of the intracellular redox state     

Neuroprotection conferred by post‐ischemia ethanol therapy in experimental stroke: an inhibitory effect on hyperglycolysis and NADPH oxidase activation

Ethanol provides neuroprotection following ischemia/reperfusion. This study assessed ethanol's effect on hyperglycolysis and NADPH oxidase (NOX) activation. Adult, male Sprague–Dawley rats were subjected to middle cerebral artery occlusion (MCAO) for 2 h. Three sets of experiments were conducted to determine ethanol's effect on (i) conferring neuroprotection by measuring infarct volume and neurological deficits 24 h post reperfusion; (ii) cerebral glucose metabolism and lactic acidosis by measuring brain and blood glucose concentrations and protein expression of glucose transporter 1 and 3 (GLUT1, GLUT3), phosphofructokinase (PFK), as well as lactic acidosis by measuring lactate dehydrogenase (LDH), and lactate; and (iii) nicotinamide adenine dinucleotide phosphate (NADPH) oxidase (NOX) activation by detecting enzymatic activity and subunit expression at 3 h after reperfusion. When administered upon reperfusion, ethanol (1.5 g/kg) reduced infarct volume by 40% (p < 0.01) and neurological deficits by 48% at 24 h post reperfusion while reducing (p < 0.01) elevations in glycolytic protein expression and lactate levels during early reperfusion (3 h). Ethanol increased the reductions in cerebral glucose concentration at 3 h post reperfusion by 64% (p < 0.01) while enhancing (p < 0.01) post stroke blood glucose concentration, suggesting a reduced cellular glucose uptake and utilization. Ethanol decreased (p < 0.01) stroke‐induced NOX activation by reducing enzymatic activity and gp91^phox expression by 45% and 38%, respectively. Post‐ischemia ethanol treatment exerts neuroprotection through attenuation of hyperglycolysis and associated NOX activation. Because of the lack of associated hypoglycemia and selectivity toward decreasing cerebral metabolism, further investigation of ethanol's use as a post‐stroke therapy, especially in the context of hyperglycemia, seems warranted.     

LEVELS OF CEREBRAL CORTICAL GLYCOLYTIC AND CITRIC ACID CYCLE METABOLITES DURING HYPOGLYCEMIC STUPOR AND ITS REVERSAL

Abstract— Blood glucose, cerebral cortical glucose, and eight metabolites of the glycolytic pathway and citric acid cycle were measured during insulin hypoglycemic stupor and during the first 100s after glucose administration. In hypoglycemic mice that had lost righting ability, blood and brain glucose were decreased 89% and 96% respectively, but glucose-6-phosphate fell only 23%. Other glycolytic and citric acid cycle intermediates were decreased 31–77%. Fructose bisphosphate, 3-phosphoglycerate and phosphopyruvate fell more than glucose-6-phosphate, but less than pyruvate and lactate. Citrate fell less than a-ketoglutarate and malate. These results suggest that in severe hypoglycemia there is a decrease in brain glucose utilization, mediated by phosphofructokinase, but probably caused by decreased neuronal activity. An intravenous injection of glucose restored brain glucose to 75% of normal within 10s and caused return of righting ability within 60s. Glucose-6-phosphate, fructose bisphosphate, 3-phosphoglycerate, and phosphopyruvate rose to normal or near normal levels within 60s, whereas pyruvate, lactate, citrate, ã-ketoglutarate, and malate changed little in this period. This suggests that although glucose given to hypoglycemic animals rapidly enters the glycolytic pathway in brain (and behavior is almost normal), total neuronal activity, and hence overall glucose metabolism, remains subnormal for several minutes.     

RESTITUTION OF CEREBRAL ENERGY STATE, AS WELL AS OF GLYCOLYTIC METABOLITES, CITRIC ACID CYCLE INTERMEDIATES AND ASSOCIATED AMINO ACIDS AFTER 30 MINUTES OF COMPLETE ISCHEMIA IN RATS ANAESTHETIZED WITH NITROUS OXIDE OR PHENOBARBITAL

Restitution of cerebral cortex concentrations of organic phosphates, glycolytic metabolites, citric acid cycle intermediates, associated amino acids, and ammonia, following a 30 min period of complete ischemia, was studied in rats anaesthetized with either 70% N₂O or 150 mg·kg^-1 of phenobar-bital. Following a 90 min period of recirculation the pattern of restitution was similar in the two groups. Thus, all animals showed recovery of phosphocreatine concentrations, restitution of the adenylate energy charge to about 99% of control, and disappearance of lactate accumulated during the ischemia. Analyses of glycolytic metabolites indicated inhibition of glycolysis at the phosphofructokinase step, possibly caused by accumulation of citrate. Measured citric acid cycle intermediates indicated extensive normalization of mitochondrial metabolism. Changes in amino acid concentrations consisted of a fall in glutamate concentration, a rise in aspartate/glutamate ratio, a fall in GABA concentration, and a rise in alanine concentration. However, ammonia concentration was close to normal, and the size of the amino acid pool did not change. It is concluded that although the results do not exclude damage to a small part of the neuronal population, they demonstrate that, irrespective of the type of anaesthesia used, the majority of brain cells must have survived 30 min of complete ischemia without signs of irreversible metabolic damage.     

Effects of acute asphyxia on brain energy metabolism in fetal guinea pigs near term.

In a previous study we suggested that--unlike other forms of asphyxia--acute asphyxia caused by arrest of uterine blood flow is accompanied by a fall in oxygen delivery to the fetal brain (Jensen et al., 1987). This may change cerebral energy metabolism by causing an increase in the glycolytic rate. To test this hypothesis we studied the time course of the changes in the levels of high-energy phosphates and glycolytic intermediates in the cerebral cortex of unanaesthetized fetal guinea pigs near term before and after 2 and 4 min of acute asphyxia. During asphyxia there was a progressive fall of adenosine triphosphate, creatine-phosphate, glucose and fructose-1,6-diphosphate concentrations, whereas adenosine diphosphate, adenosine monophosphate and lactate concentrations increased. Pyruvate concentrations did not change. We conclude that fetal cerebral energy metabolism becomes increasingly anaerobic during acute asphyxia caused by arrest of uterine blood flow, because oxygen delivery to the fetal brain falls.     

Cerebral glucose metabolism and the glutamine cycle as detected by in vivo and in vitro 13C NMR spectroscopy

We review briefly 13C NMR studies of cerebral glucose metabolism with an emphasis on the roles of glial energetics and the glutamine cycle. Mathematical modeling analysis of in vivo 13C turnover experiments from the C4 carbons of glutamate and glutamine are consistent with: (i) the glutamine cycle being the major cerebral metabolic route supporting glutamatergic neurotransmission, (ii) glial glutamine synthesis being stoichiometrically coupled to glycolytic ATP production, (iii) glutamine serving as the main precursor of neurotransmitter glutamate and (iv) glutamatergic neurotransmission being supported by lactate oxidation in the neurons in a process accounting for 60-80% of the energy derived from glucose catabolism. However, more recent experimental approaches using inhibitors of the glial tricarboxylic acid (TCA) cycle (trifluoroacetic acid, TFA) or of glutamine synthase (methionine sulfoximine, MSO) reveal that a considerable portion of the energy required to support glutamine synthesis is derived from the oxidative metabolism of glucose in the astroglia and that a significant amount of the neurotransmitter glutamate is produced from neuronal glucose or lactate rather than from glial glutamine. Moreover, a redox switch has been proposed that allows the neurons to use either glucose or lactate as substrates for oxidation, depending on the relative availability of these fuels under resting or activation conditions, respectively. Together, these results suggest that the coupling mechanisms between neuronal and glial metabolism are more complex than initially envisioned.     

Chloramphenicol decreases brain glucose utilization and modifies the sleep-wake cycle architecture in rats

We studied the effects of chloramphenicol on brain glucose utilization and sleep-wake cycles in rat. After slightly anaesthetized animals were injected with [18F]fluoro-2-deoxy-D-glucose, we acquired time-concentration curves from three radiosensitive beta microprobes inserted into the right and left frontal cortices and the cerebellum, and applied a three-compartment model to calculate the cerebral metabolic rates for glucose. The sleep-wake cycle architecture was analysed in anaesthetic-free rats by recording electroencephalographic and electromyographic signals. Although chloramphenicol is a well-established inhibitor of oxidative phosphorylation, no compensatory increase in glucose utilization was detected in frontal cortex. Instead, chloramphenicol induced a significant 23% decrease in the regional cerebral metabolic rate for glucose. Such a metabolic response indicates a potential mismatch between energy supply and neuronal activity induced by chloramphenicol administration. Regarding sleep-wake states, chloramphenicol treatment was followed by a 64% increase in waking, a 20% decrease in slow-wave sleep, and a marked 59% loss in paradoxical sleep. Spectral analysis of the electroencephalogram indicates that chloramphenicol induces long-lasting modifications of delta-band power during slow-wave sleep.     

Metabolic Characterization of Acutely Isolated Hippocampal and Cerebral Cortical Slices Using [U-<Superscript>13</Superscript>C]Glucose and [1,2-<Superscript>13</Superscript>C]Acetate as Substrates

Brain slice preparations from rats, mice and guinea pigs have served as important tools for studies of neurotransmission and metabolism. While hippocampal slices routinely have been used for electrophysiology studies, metabolic processes have mostly been studied in cerebral cortical slices. Few comparative characterization studies exist for acute hippocampal and cerebral cortical slices, hence, the aim of the current study was to characterize and compare glucose and acetate metabolism in these slice preparations in a newly established incubation design. Cerebral cortical and hippocampal slices prepared from 16 to 18-week-old mice were incubated for 15–90 min with unlabeled glucose in combination with [U-¹³C]glucose or [1,2-¹³C]acetate. Our newly developed incubation apparatus allows accurate control of temperature and is designed to avoid evaporation of the incubation medium. Subsequent to incubation, slices were extracted and extracts analyzed for ¹³C-labeling (%) and total amino acid contents (µmol/mg protein) using gas chromatography–mass spectrometry and high performance liquid chromatography, respectively. Release of lactate from the slices was quantified by analysis of the incubation media. Based on the measured ¹³C-labeling (%), total amino acid contents and relative activity of metabolic enzymes/pathways, we conclude that the slice preparations in the current incubation apparatus exhibited a high degree of metabolic integrity. Comparison of ¹³C-labeling observed with [U-¹³C]glucose in slices from cerebral cortex and hippocampus revealed no significant regional differences regarding glycolytic or total TCA cycle activities. On the contrary, results from the incubations with [1,2-¹³C]acetate suggest a higher capacity of the astrocytic TCA cycle in hippocampus compared to cerebral cortex. Finally, we propose a new approach for assessing compartmentation of metabolite pools between astrocytes and neurons using ¹³C-labeling (%) data obtained from mass spectrometry. Based on this approach we suggest that cellular metabolic compartmentation in hippocampus and cerebral cortex is very similar.     

Toward an integrative theory of sleep and dreaming

Non-rapid-eye-movement sleep (NREMS) is triggered by the accumulation of adenosine, as a result of the perceptual overload of the brain cortex. NREMS starts in the most burdened regions of the cortex first and then eventually, after the released adenosine has reached the ventrolateral pre-optic nucleus area of the hypothalamus, triggers the "general NREMS pattern". This is accompanied by the usual familiar changes in the thalamocortical system. When NREMS reaches the slow-wave sleep (SWS) phase, with its predominant delta activity, brain metabolism drops significantly with the brain temperature, and this is recognized by the alarm system in the pre-optic anterior hypothalamus and/or the other thermostat circuit in the brainstem as a life-threatening situation. This alarm system triggers a reaction similar to abortive or partial awakening called rapid-eye-movement sleep (REMS), which is aimed at restoring the optimal body-core temperature. As soon as this restoration is accomplished by the activation of the brainstem-to-cortex ascending pathways, NREMS may continue, as may the interchange of the two sleep phases during the entire sleep period. During both NREMS and REMS, the same essential pattern occurs in the cortex: the loops "used" during the previous waking period, now deprived of external input, replay their waking activity at a lower frequency, one which enables them to restore the membrane's potential (possibly by means of LTD). During REMS, however, the cholinergic flood originating in the LTD/PPT nuclei of the pons tegmentum, increases in the basal forebrain and, provoking theta activity in the medial septum is extended to the hippocampus, causing the circuits that are active at that particular moment in the cortex, to store the information they carry as memory. This is the explanation of both the memory improvement known to be related to REMS and of dreams. Both phenomena are clearly side effects of REMS.     

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.     

A metabolic switch in brain: glucose and lactate metabolism modulation by ascorbic acid

In this review, we discuss a novel function of ascorbic acid in brain energetics. It has been proposed that during glutamatergic synaptic activity neurons preferably consume lactate released from glia. The key to this energetic coupling is the metabolic activation that occurs in astrocytes by glutamate and an increase in extracellular [K⁺]. Neurons are cells well equipped to consume glucose because they express glucose transporters and glycolytic and tricarboxylic acid cycle enzymes. Moreover, neuronal cells express monocarboxylate transporters and lactate dehydrogenase isoenzyme 1, which is inhibited by pyruvate. As glycolysis produces an increase in pyruvate concentration and a decrease in NAD⁺/NADH, lactate and glucose consumption are not viable at the same time. In this context, we discuss ascorbic acid participation as a metabolic switch modulating neuronal metabolism between rest and activation periods. Ascorbic acid is highly concentrated in CNS. Glutamate stimulates ascorbic acid release from astrocytes. Ascorbic acid entry into neurons and within the cell can inhibit glucose consumption and stimulate lactate transport. For this switch to occur, an ascorbic acid flow is necessary between astrocytes and neurons, which is driven by neural activity and is part of vitamin C recycling. Here, we review the role of glucose and lactate as metabolic substrates and the modulation of neuronal metabolism by ascorbic acid.     

Neurometabolic coupling between neural activity,glucose, and lactate in activated visual cortex

Neural activity is closely coupled with energy metabolism but details of the association remain to be identified. One basic area involves the relationships between neural activity and the main supportive substrates of glucose and lactate. This is of fundamental significance for the interpretation of non‐invasive neural imaging. Here, we use microelectrodes with high spatial and temporal resolution to determine simultaneous co‐localized changes in glucose, lactate, and neural activity during visual activation of the cerebral cortex in the cat. Tissue glucose and lactate concentration levels are measured with electrochemical microelectrodes while neural spiking activity and local field potentials are sampled by a microelectrode. These measurements are performed simultaneously while neurons are activated by visual stimuli of different contrast levels, orientations, and sizes. We find immediate decreases in tissue glucose concentration and simultaneous increases in lactate during neural activation. Both glucose and lactate signals return to their baseline levels instantly as neurons cease firing. No sustained changes or initial dips in glucose or lactate signals are elicited by visual stimulation. However, co‐localized measurements of cerebral blood flow and neural activity demonstrate a clear delay in the cerebral blood flow signal such that it does not correlate temporally with the neural response. These results provide direct real‐time evidence regarding the coupling between co‐localized energy metabolism and neural activity during physiological stimulation. They are also relevant to a current question regarding the role of lactate in energy metabolism in the brain during neural activation.

     

Thematic Review Series: Calorie Restriction and Ketogenic Diets: The collective therapeutic potential of cerebral ketone metabolism in traumatic brain injury

The postinjury period of glucose metabolic depression is accompanied by adenosine triphosphate decreases, increased flux of glucose through the pentose phosphate pathway, free radical production, activation of poly-ADP ribose polymerase via DNA damage, and inhibition of glyceraldehyde dehydrogenase (a key glycolytic enzyme) via depletion of the cytosolic NAD pool. Under these post-brain injury conditions of impaired glycolytic metabolism, glucose becomes a less favorable energy substrate. Ketone bodies are the only known natural alternative substrate to glucose for cerebral energy metabolism. While it has been demonstrated that other fuels (pyruvate, lactate, and acetyl-L-carnitine) can be metabolized by the brain, ketones are the only endogenous fuel that can contribute significantly to cerebral metabolism. Preclinical studies employing both pre- and postinjury implementation of the ketogenic diet have demonstrated improved structural and functional outcome in traumatic brain injury (TBI) models, mild TBI/concussion models, and spinal cord injury. Further clinical studies are required to determine the optimal method to induce cerebral ketone metabolism in the postinjury brain, and to validate the neuroprotective benefits of ketogenic therapy in humans.     

Growth hormone-releasing hormone: cerebral cortical sleep-related EEG actions and expression

Growth hormone-releasing hormone (GHRH), its receptor (GHRHR), and other members of the somatotropic axis are involved in non-rapid eye movement sleep (NREMS) regulation. Previously, studies established the involvement of hypothalamic GHRHergic mechanisms in NREMS regulation, but cerebral cortical GHRH mechanisms in sleep regulation remained uninvestigated. Here, we show that unilateral application of low doses of GHRH to the surface of the rat somatosensory cortex ipsilaterally decreased EEG delta wave power, while higher doses enhanced delta power. These actions of GHRH on EEG delta wave power occurred during NREMS but not during rapid eye movement sleep. Further, the cortical forms of GHRH and GHRHR were identical to those found in the hypothalamus and pituitary, respectively. Cortical GHRHR mRNA and protein levels did not vary across the day-night cycle, whereas cortical GHRH mRNA increased with sleep deprivation. These results suggest that cortical GHRH and GHRHR have a role in the regulation of localized EEG delta power that is state dependent, as well as in their more classic hypothalamic role in NREMS regulation.     

Synthesis of glycolytic and peroxisomal enzymes in Tetrahymena following a change in culture conditions

The specific activity of a peroxisomal enzyme, lactate oxidase, and of pyruvate kinase and lactate dehydrogenase, which are not peroxisomal, increased rapidly when shaken cultures of Tetrahymena were transferred to conditions of oxygen restriction and supplemented with glucose. Two other peroxisomal enzymes, catalase and TPN-linked isocitrate dehydrogenase, did not increase substantially, nor did succinate dehydrogenase. The increases were reduced if glucose was not added at the time of transfer, and were prevented by actinomycin D or cycloheximide, but not by chloramphenicol. The results suggest an involvement of peroxisomes in the metabolism of glycolytic endproducts when the availability of oxygen to the cell is limiting.     

Ex vivo analysis of lactate and glucose metabolism in the rat brain under different states of depressed activity

Brain metabolism of glucose and lactate was analyzed by ex vivo NMR spectroscopy in rats presenting different cerebral activities induced after the administration of pentobarbital, alpha-chloralose, or morphine. The animals were infused with a solution of either [1-(13)C]glucose plus lactate or glucose plus [3-(13)C]lactate for 20 min. Brain metabolite contents and enrichments were determined from analyses of brain tissue perchloric acid extracts according to their post-mortem evolution kinetics. When amino acid enrichments were compared, both the brain metabolic activity and the contribution of blood glucose relative to that of blood lactate to brain metabolism were linked with cerebral activity. The data also indicated the production in the brain of lactate from glycolysis in a compartment other than the neurons, presumably the astrocytes, and its subsequent oxidative metabolism in neurons. Therefore, a brain electrical activity-dependent increase in the relative contribution of blood glucose to brain metabolism occurred via the increase in the metabolism of lactate generated from brain glycolysis at the expense of that of blood lactate. This result strengthens the hypothesis that brain lactate is involved in the coupling between neuronal activation and metabolism.     

DEVELOPMENTAL CHANGES IN GLYCOLYSIS IN RAT CEREBRAL CORTEX

Abstract— The ATP concentration in infant rat cerebral cortex slices which were incubated aerobically with glucose (5 m m ) as substrate was much higher than in those from the adult. The higher ATP concentration in slices from young rat was also obtained when they were incubated aerobically with pyruvate (10 m m ), dl -lactate (20 m m ) and dl -3-nydroxybutyrate (20 m m ) However, when the slices were incubated anaerobically with glucose, the ATP concentration was very low. Thus, the formation of ATP in the slices from the young rat was thought to be mainly due to their oxidative metabolism, as in those from the adult. The amounts of glycolytic key enzymes in rat cerebral cortex (hexokinase. phosphofructokinase and pyruvate kinase) increased with age. Glycolysis was actually shown to be less active in the cerebral slices from young rats than from the adult. In addition it is known that the tricarboxylic acid cycle enzymes in rat cerebrum also increase with age. Consequently, the activity with respect to ATP formation must be lower in the cerebral cortex slices from young rats than from the adult. The fact that ATP was nevertheless higher in the slices from young rats may be explained by a lower rate of degradation. Developmental increases in the amounts of Na⁺-K⁺-ATPase and Mg²⁺ -ATPase in rat cerebral cortex were greater than those of the glycolytic key enzymes. These are discussed in relation to the observation that the rate of aerobic glycolysis in slices from cerebral cortex of young rats was not increased by d -glutamate (5 m m ) and high potassium (50 m m ).     

MicroRNA 132 alters sleep and varies with time in brain

MicroRNA (miRNA) levels in brain are altered by sleep deprivation; however, the direct effects of any miRNA on sleep have not heretofore been described. We report herein that intracerebroventricular application of a miRNA-132 mimetic (preMIR-132) decreased duration of non-rapid-eye-movement sleep (NREMS) while simultaneously increasing duration of rapid eye movement sleep (REMS) during the light phase. Further, preMIR-132 decreased electroencephalographic (EEG) slow-wave activity (SWA) during NREMS, an index of sleep intensity. In separate experiments unilateral supracortical application of preMIR-132 ipsilaterally decreased EEG SWA during NREMS but did not alter global sleep duration. In addition, after ventricular or supracortical injections of preMIR-132, the mimetic-induced effects were state specific, occurring only during NREMS. After local supracortical injections of the mimetic, cortical miRNA-132 levels were higher at the time sleep-related EEG effects were manifest. We also report that spontaneous cortical levels of miRNA-132 were lower at the end of the sleep-dominant light period compared with at the end of the dark period in rats. Results suggest that miRNAs play a regulatory role in sleep and provide a new tool for investigating sleep regulation.     

The effect of pretreatment with pentobarbital on the extent of [14C] incorporation from [U-14C]glucose into various rat brain glycolytic intermediates: relevance to regulation at hexokinase and phosphofrucktokinase

In the present investigation we monitored the incorporation of [¹⁴C] from [U-¹⁴C]glucose into various rat brain glycolytic intermediates of conscious and pentobarbital-anesthetized animals. Labeled glucose was delivered to brain by single bolus intracarotid injection and brain tissue was subsequently prepared at 15, 30 and 45 sec by freeze-blowing. Glycolytic intermediates were then separated by column chromatography. Our results showed a gradual decrease with time of¹⁴C-labeled glucose which gave a calculated rate for glucose metabolism of 0.86 mol/min/g and 0.56 mol/min/g in conscious and anesthetized animals, respectively. Compared to the results obtained using conscious animals the administration of pentobarbital not only resulted in a significant attenuation of the rate of glucose metabolism but also caused a similar reduction in the amount of¹⁴C incorporated into several glycolytic intermediates. These intermediates included: glucose 6-phosphate, fructose 6-phosphate, fructose, 1,6 diphosphate, dihydroxyacetone phosphate and post glycolytic compounds. In addition, pretreatment with pentobarbital resulted in a 75% increase in the endogenous concentration of glucose, 10% increase in glucose 6-phosphate, no change in fructose 6-phosphate and 42% decrease in lactate compared to levels in brains obtained from conscious animals. These results are discussed in relation to control of glycolysis through coupled regulation at hexokinase-phosphofructokinase.