The K-ATP channel regulates the effect of Ca2+ on gap junction permeability in cultured astrocytes

Using the scrape-loading technique we show that tolbutamide and glybenzcyclamide, two inhibitors of the K+ channel sensitive to ATP (K-ATP channel), partially prevent the inhibition of gap junction permeability promoted by Ca2+ in cultured astrocytes. This effect was dose-dependent, reaching a maximum at 400 microM and 1 microM of tolbutamide and glybenzcyclamide, respectively. The presence of the Ca2+ ionophore A-23187 strongly reduced the concentration of Ca2+ required to block gap junction permeability but did not abolish the effect of tolbutamide and glybenzcyclamide. These results suggest that the effect of these two compounds are not brought about by control of the intracellular concentration of Ca2+ but probably by the promotion of plasma membrane depolarization.

Glutamate neurotoxicity is associated with nitric oxide-mediated mitochondrial dysfunction and glutathione depletion

The role of mitochondrial energy metabolism in glutamate mediated neurotoxicity was studied in rat neurones in primary culture. A brief (15 min) exposure of the neurones to glutamate caused a dose-dependent (0.01-1 mM) increase in cyclic GMP levels together with delayed (24 h) neurotoxicity and ATP depletion. These effects were prevented by either the nitric oxide (.NO) synthase (NOS) inhibitor Nomega-nitro-L-arginine methyl ester (NAME; 1 mM) or by the N-methyl-D-aspartate (NMDA) glutamate-subtype receptor antagonist D-(-)-2-amino-5-phosphonopentanoate (APV; 0.1 mM). Glutamate exposure (0.1 mM and 1 mM) followed by 24 h of incubation caused the inhibition of succinate-cytochrome c reductase (20-25%) and cytochrome c oxidase (31%) activities in the surviving neurones, without affecting NADH-coenzyme-Q1 reductase activity. The rate of oxygen consumption was impaired in neurones exposed to 1 mM glutamate, either with glucose (by 26%) or succinate (by 39%) as substrates. These effects on the mitochondrial respiratory chain and neuronal respiration, together with the observed glutathione depletion (20%) by glutamate exposure were completely prevented by NAME or APV. Our results suggest that mitochondrial dysfunction and impairment of antioxidant status may account for glutamate-mediated neurotoxicity via a mechanism involving .NO biosynthesis.

Nitric oxide mediates brain mitochondrial damage during perinatal anoxia

The possible role of nitric oxide (.NO) in brain energy metabolism during perinatal asphyxia in the rat was studied. Exposure of early neonates to 5 min of anoxia significantly inhibited brain mitochondrial complex II-III activity by 25%, without affecting complex I, complex IV or citrate synthase activities. This insult was accompanied by ATP depletion (54%) and increased concentration of nitrites plus nitrates (1.4-fold), suggesting enhanced .NO synthesis. Administration of Nomega-nitro-L-arginine monomethyl ester (L-NAME) to the mothers inhibited neonatal brain .NO synthase activity, as reflected by the decreased (23%) cyclic GMP concentration. These L-NAME-treated neonates showed complete resistance to anoxic-mediated brain mitochondrial complex II-III damage. Our results suggest that brain mitochondrial dysfunction leading to energy deficiency during perinatal asphyxia is a .NO-mediated process.

A rapid method for the isolation of metabolically active mitochondria from rat neurons and astrocytes in primary culture

A rapid method (about 1.5 h) for the isolation of intact functional mitochondria from neurons and astrocytes in primary culture is described. Mitochondria isolated by this method are metabolically active and tightly coupled as shown by respiratory control ratio values, which were about 4 with glutamate-malate as substrate. The activities of marker enzymes revealed the occurrence of a low degree of cytosolic (5%) or synaptosomal (5.5%) contamination in the mitochondrial fractions. In addition, the activity of citrate synthase was increased by 4 fold in both neuronal and astrocytic mitochondria with respect to values found in cell homogenates. These results confirm that the method affords mitochondrial preparations from cultured brain cells at suitable levels of purity and enrichment for the study of their mitochondrial function. Since mitochondrial damage has been associated with the pathogenesis of certain neurodegenerative diseases, such as Alzheimer's and Parkinson's diseases (P. Chagnon, C. Betard, Y. Robitaille, A. Cholette, D. Gauvreau, Distribution of brain cytochrome oxidase activity in various neurodegenerative disease, Neuroreport 6 (1995) 711-715 [6]; S.J. Kish, C. Bergeron, A. Rajput, S. Dozic, F. Mastrogiacomo, L. Chang, J.M. Wilson, L.M. DiStefano, J.N. Nobrega, Brain cytochrome oxidase in Alzheimer's disease, J. Neurochem. 59 (1992) 776-779 [10]; A.H.V. Schapira, J.M. Cooper, D. Dexter, J.B. Clark, P. Jenner, C.D. Marsden, Mitochondrial complex I deficiency in Parkinson's disease, J. Neurochem. 54 (1990) 823-827 [15]), the method described here shed light on the possible susceptibility of neuronal or astrocytic mitochondria to deleterious effects of these diseases.

cAMP and Ca2+ involvement in the mitochondrial response of cultured fetal rat hepatocytes to adrenaline

The effect of adrenaline on the control of respiratory activity of mitochondria from fetal hepatocytes in primary culture was studied. In the absence of adrenaline, the respiratory control ratio (RCR) of mitochondria increased during the first 3 days of culture due to a decrease in the rate of state 4 respiration. The presence of adrenaline in the incubation medium further increased the mitochondrial RCR through a decrease in the rate of respiration in state 4 and to an increase in the respiration rate in state 3. The effect of adrenaline was mimicked by dibutyryl-cAMP, forskolin, and isobutyl methyl xanthine. All these compounds increased cAMP concentrations, suggesting that cAMP may be involved in the effect of adrenaline. The increase in intracellular free Ca2+ concentrations caused by phenylephrine, vasopressin, or thapsigargin was also accompanied by an increase in the RCR, suggesting that both phenomena are associated. Dibutyryl-cAMP also increased free Ca2+ concentrations, suggesting that the effects of cAMP may be mediated by free Ca2+ concentrations. Adrenaline, dibutyryl-cAMP, phenylephrine, vasopressin, and thapsigargin promoted adenine nucleotide accumulation in mitochondria; this may be an intermediate step in the activation of mitochondrial respiratory function. These results suggest that the stimulatory effect of adrenaline on mitochondrial maturation in cultured fetal rat hepatocytes may be exerted through a mechanism in which both cAMP and Ca2+ act as second messengers. It is concluded that the effect of adrenaline on mitochondrial maturation is exerted by both alpha- and beta-adrenergic mechanisms and is mediated by the increase in adenine nucleotide contents of mitochondria.

Metabolic trafficking through astrocytic gap junctions

Astrocytes are interposed between the pericapillary space and neuronal membranes. Consequently, they may represent an important intermediary element between the source of energetic substrates and the main site of energy-consuming elements, respectively, the blood circulation and the neurons. A typical feature of astrocytes is the connections they establish between each other by specialized membrane structures, defined as gap junctions. These intercellular junctions allow direct cell-to-cell exchanges of ions and small molecules, including several compounds involved in major metabolic pathways occurring in astrocytes. The permeability of astrocytes gap junction channels is controlled by several endogenous compounds released by astrocytes themselves or by other brain cell types, including neurons and endothelial cells. In primary cultures of astrocytes, the intercellular diffusion, the utilization and the uptake of glucose and derivates are modified when gap junctional permeability is inhibited by uncoupling agents. Altogether these observations indicate that intercellular pathways constituted by groups of coupled astrocytes could participate to the metabolism and the distribution of energetic substrates throughout the brain.

Oleic acid inhibits gap junction permeability and increases glucose uptake in cultured rat astrocytes

The role of oleic acid in the modulation of gap junction permeability was studied in cultured rat astrocytes by the scrape-loading/Lucifer yellow transfer technique. Incubation with oleic acid caused a dose-dependent inhibition of gap junction permeability by 79.5% at 50 microM, and no further inhibition was observed by increasing the oleic acid concentration to 100 microM. The oleic acid-mediated inhibition of gap junction permeability was reversible and was prevented by bovine serum albumin. The potency of oleic acid-related compounds in inhibiting gap junction permeability was arachidonic acid > oleic acid > oleyl alcohol > palmitoleic acid > stearic acid > octanol > caprylic acid > palmitic acid > methyloleyl ester. Oleic acid and arachidonic acid, but not methyloleyl ester, increased glucose uptake by astrocytes. Neither oleic acid nor arachidonic acid increased glucose uptake in the poorly coupled glioma C6 cells. These results support that the inhibition of gap junction permeability is associated with the increase in glucose uptake. We suggest that oleic acid may be a physiological mediator of the transduction pathway leading to the inhibition of intercellular communication.

Isolation and characterization of tightly coupled mitochondria from neurons and astrocytes in primary culture

This work provides a rapid method for isolation of intact functional mitochondria from neurons and astrocytes in primary culture. By using this method, it was found that the respiratory control ratio was 1.5-fold greater in neuronal than in astrocytic mitochondria using both NAD-linked (glutamate/malate) and FAD-linked (succinate) substrates. The difference observed in RCR values was due to the lower rate of respiration in state 4 found in neurons as compared to that found in astrocytes, because both cell types showed the same rate of respiration in state 3. The P/O ratio was also higher in neurons than in astrocytes. Our results suggest that the coupling between the mitochondrial respiratory chain and oxidative phosphorylation is stronger in neurons than in astrocytes. These results may be of relevance for the understanding of the differential susceptibility of brain cells to impairments of energy metabolism observed in certain neurodegenerative diseases.

[Blood lead in the inhabitants of 4 Peruvian localities]

During 1994 and 1995, a cross-sectional study was carried out to investigate the concentrations of lead in the blood of inhabitants of four Peruvian cities (Lima, Huancayo, La Oroya, and Yaupi) with different population densities and degrees of industrial development. In a random sample of 180 men and 180 women without occupational exposure to lead, blood lead levels were measured by the atomic absorption method with a Perkin Elmer 603 spectrophotometer without a graphite oven. The results revealed blood lead concentrations of 269 +/- 63 micrograms per liter (micrograms/L) in Lima, 224 +/- 47 micrograms/L in Huancayo; 348 +/- 40 micrograms/L in La Oroya, and 140 +/- 27 micrograms/L in Yaupi. It was concluded that blood lead levels in the inhabitants of these cities were related to the degree of industrialization and the population density of each locality.

Thyroid hormones regulate the onset of osmotic activity of rat liver mitochondria after birth

The effect of thyroid hormone deprivation on the osmotic activity of liver mitochondria from early newborn rats was studied. Experimentally induced hypothyroidism prevented the increase in the osmotic activity of mitochondria observed immediately after birth. Osmotic activity was restored by T4 and T3 treatment to hypothyroid newborns but not when this treatment was supplemented with cycloheximide. Under the same circumstances, streptomycin had no effect. Hypothyroidism abolished the change in the slope of the osmotic curve (plot of inverse absorbance of mitochondrial suspensions incubated in sucrose solutions vs. inverse sucrose concentration) observed in mitochondria from euthyroid newborns at 110-120 mOsm sucrose, suggesting that hypothyroidism prevents the formation of tight physical connections between mitochondrial outer and inner membranes. Thyroid hormone deprivation increased the passive permeability of the mitochondrial inner membrane to protons, resulting in a decreased respiratory control ratio. Hypothyroidism prevented the sharp decrease in the affinity of mitochondria for ATP observed in euthyroid newborns immediately after birth. These results corroborate our previous suggestion (Endocrinology, 1995, 136:4448) that, during the early neonatal period, thyroid hormones control the synthesis of some nucleus-coded protein(s) involved in the assembly of F0,F1-ATPase.

Effect of valproate on the metabolism of the central nervous system

The effects of valproate on brain energy and lipid metabolism is reviewed. Increasing evidence suggests that valproate uses the monocarboxylic acid carrier in order to cross the blood brain barrier (BBB) and the neural cell plasma membranes. The uptake of valproate into the brain through this mechanism would compete with the uptake of energy precursors, such as the monocarboxylic acids 3-hydroxybutyrate, lactate or pyruvate and with some amino acids, but not with glucose. This could impair brain fuel utilization, specially during the neonatal period or childhood, when lactate or 3-hydroxybutyrate furnishes alternative substrates to glucose for the brain. It is concluded that valproate interference with energy metabolism may have implications for the therapeutic action of the drug, stressing the possibility that valproate-mediated alterations in brain lipid synthesis may contribute to the pharmacological action of the drug.

Lactate spares glucose as a metabolic fuel in neurons and astrocytes from primary culture

The effect of lactate on glucose metabolism in neurons and astrocytes from primary culture has been studied. The rates of glucose metabolism through the pentose-phosphate shunt, the pyruvate dehydrogenase-catalyzed reaction, the tricarboxylic acid cycle, the total lipogenesis and the synthesis of glycerol-borne lipids in astrocytes were 2-3 fold higher than in neurons. However, the rate of glucose incorporation into sterols and esterified fatty acids was similar in both types of cells. Total glucose utilization was inhibited by lactate to the same extend in both neurons and astrocytes. Lactate strongly inhibited glucose oxidation through the pyruvate dehydrogenase-catalyzed reaction and the tricarboxylic acid cycle, in both neurons (60 and 44%, respectively) and astrocytes (64 and 62%, respectively). Glucose incorporation into sterols and fatty acids was also inhibited by lactate in both neurons and astrocytes (57 and 76%, respectively) while the oxidation of glucose in the pentose-phosphate shunt and the synthesis of glycerol-borne lipids was not significantly affected. These results suggest that in the presence of lactate both neurons and astrocytes can utilize lactate as the major metabolic substrate, sparing glucose for the synthesis of NADPH(H+), ribose-5-phosphate and/or glycerol-borne lipids. An interaction between glucose and lactate metabolism at the level of the pyruvate dehydrogenase-catalyzed reaction is suggested.

Inhibition of astrocyte gap junctional communication by ATP depletion is reversed by calcium sequestration

We have studied the possible role of cellular energy status in the regulation of gap junction permeability in rat astrocytes in primary culture. Incubation with the mitochondrial respiratory chain inhibitor antimycin (5 ng/ml) for 16 h caused a significant decrease in ATP concentrations. This effect was accompanied by a dose-dependent inhibition of gap junction permeability as assessed by the scrape-loading/Lucifer yellow transfer technique. No cell death was observed following this treatment. Restoration of cellular ATP levels by a further 24 h incubation in antimycin-free medium reversed the inhibition of Lucifer yellow transfer caused by antimycin. The inhibition of Lucifer yellow transfer brought about by antimycin treatment was also reversed by a short incubation of the cells with the calcium chelator EGTA plus the calcium ionophore A23187. These results suggest that ATP depiction causes a reversible inhibition of gap junction permeability through a calcium-mediated mechanism.

Fuel utilization by early newborn brain is preserved under congenital hypothyroidism in the rat

Mental retardation associated with hypothyroidism may be caused by impairment of brain ketone body-metabolizing enzymes during the suckling period. However, much evidence suggests that, immediately after delivery, lactate, instead of ketone bodies or glucose, may be the best substrate for the brain. In this work, we have studied the effect of experimentally induced congenital hypothyroidism on the rate of lactate, glucose, and 3-hydroxybutyrate utilization in early neonatal brain slices. Methimazole (MMI) administration to the mothers caused a 5.4- and 1.7-fold decrease in neonatal plasma concentrations of L-thyroxine (T4) and 3,5,3'-triiodo-L-thyronine (T3), respectively. Propylthiouracil (PTU) administration to the mothers caused a 7.3- and > 2-fold decrease in plasma T4 and T3 concentrations, respectively. MMI-induced hypothyroidism did not significantly modify the rate of lactate, glucose, or 3-hydroxybutyrate oxidation to CO2 and their incorporation into lipids by the neonatal brain. However, PTU-induced hypothyroidism decreased the rate of lactate and glucose oxidation to CO2 and their incorporation into lipids by 17% (p < 0.05). 3-Hydroxybutyrate utilization was not modified by this treatment. Separation by HPLC of the lipids revealed that PTU-mediated inhibition of lipid synthesis from lactate and glucose may be accounted for by specific inhibition of the rate of sterol synthesis (15%, p < 0.05), whereas the rate of phospholipid synthesis was unaffected. These results suggest that the early newborn may develop mechanisms aimed at avoiding the possible brain damage caused by the inhibition of lipid synthesis brought about by mild neonatal hypothyroidism.

Induction of nitric oxide synthase inhibits gap junction permeability in cultured rat astrocytes

Nitric oxide (.NO) synthase (NOS) was induced in cultured rat astrocytes by incubation with lipopolysaccharide (LPS) for 18 h and gap junction permeability was assessed by the scrape-loading/Lucifer yellow transfer technique. Induction of NOS was confirmed by determining either the NG-methyl-L-arginine (NMMA)-inhibitable production of nitrites and nitrates or the conversion of L-[3H]arginine to L-[3H]citrulline. Incubation with LPS dose-dependently inhibited gap junction permeability to 63.3% at 0.05 microgram/ml LPS and no further inhibition was observed on increasing the LPS concentration up to 0.5 microgram/ml. LPS-mediated gap junction inhibition was irreversible but was prevented by incubation with the NOS inhibitor NMMA and with the superoxide anion (O2.-) scavenger superoxide dismutase. Incubation of the cells with both the .NO donor S-nitroso-N-acetylpenicillamine and the O2.(-)-generating system xanthine/xanthine oxidase inhibited gap junction permeability. These results suggest that the in situ reaction between .NO and O2.-, to form the peroxynitrite anion (ONOO-), may be responsible for the inhibition of gap junction permeability. Scavenging the ONOO- derivative hydroxyl radical (.OH) with either dimethyl sulfoxide or mannitol prevented the LPS-mediated inhibition of gap junction permeability. Finally, exposure of astrocytes to authentic ONOO- caused a dose-dependent inhibition of gap junction permeability (65.7% of inhibition at 0.5 mM ONOO-). The pathophysiological relevance of ONOO(-)-mediated inhibition of gap junctional communication in astrocytes after NOS induction by LPS is discussed, stressing the possible role played by this mechanism in some neurodegenerative diseases.

Endothelin-1 regulates glucose utilization in cultured astrocytes by controlling intercellular communication through gap junctions

The role played by endothelin-1 and intercellular communication mediated by gap junctions in the regulation of glucose disposal by astrocytes has been studied in primary culture. Endothelin-1 increased glucose uptake by astrocytes as did one of its putative messenger arachidonic acid and the non-physiological gap junction uncoupler alpha-glycyrrhetinic acid (AGA). None of these agents increased glucose uptake by C6 glioma cells, a cell line in which gap junction proteins are poorly expressed. In confluent astrocytes, the inhibition of gap junction permeability caused by AGA doubled the activity of the pentose phosphate shunt with minimal changes in the activity of the pyruvate dehydrogenase-catalyzed reaction and that of the tricarboxylic acid cycle. By contrast, these effects were not observed in dissociated astrocytes in which intercellular communication is lacking. The scraped loading dye transfer technique was modified to follow the passage of glucose and its metabolites through astrocyte gap junctions. The diffusion of glucose, the phosphorylated derivative glucose-6-phosphate, the phosphorylisable but not metabolisable derivative ortho-methyl-glucose, and the anaerobic glycolytic product L-lactate was much higher in astrocytes than in C6 glioma cells and was inhibited by the inhibition of gap junction permeability caused by endothelin-1, arachidonic acid, octanol, or AGA. It is concluded that gap junction permeability may regulate brain metabolism by controlling the uptake, utilization, and intercellular distribution of glucose and its metabolites in astrocytes.

Astrocyte differentiation in primary culture followed by flow cytometry

Astrocyte proliferation and differentiation in primary culture were followed by flow cytometry. The time-courses of the percentages of astrocytes in the different cell-cycle phases suggest that astrocytes proliferate during the first 10 days in culture thereafter reaching confluence. Two types of astrocytes are identified immunocytochemically: one growing in the bed monolayer, identified as type-1 astrocytes, and another growing on the top of the monolayer, identified as type-2 astrocytes. In addition, three populations identified as being formed of type-1, type-2 and putative progenitor cells, respectively, were followed by flow cytometry. Progenitor cells were the major type 2 h after plating (89%) but their percentage decreases sharply (to 16%) during the first 5 days in culture, with no ensuing changes. In contrast, the percentage of type-1 cells (11%) rapidly increased after plating reaching a maximum 5 days later (73%). Later, it decreased (to 47%) and was maintained thereafter. The percentage of type-2 cells was undetectable immediately after plating but increased from the 3rd to the 10th day with no further changes. Our results suggest that progenitor cells differentiate into type-1 astrocytes triggered by the culture medium but the differentiation of progenitor cells into type-2 astrocytes is brought about by some type-1-secreted factor. In this work we report a rapid and simple method for following the growth and differentiation of rat brain astrocytes in primary culture.

Metabolic fuel utilization and pyruvate oxidation during the postnatal period

The transplacental supply of nutrients is interrupted at birth, which diverts maternal metabolism to lactation. After birth, energy homeostasis is rapidly regained through milk nutrients which supply the newborn with the fatty acids and ketone bodies required for neonatal development. However, immediately after birth and before the onset of suckling there is a time lapse in which the newborn undergoes a unique kind of starvation. During this period glucose is scarce and ketone bodies are not available owing to the delay in ketogenesis. Under these circumstances, the newborn is supplied with another metabolic fuel, lactate, which is utilized as a source of energy and carbon skeletons. Neonatal rat lung, heart, liver and brain utilize lactate for energy production and lipogenesis. Lactate is also utilized by the brain of human babies with type I glycogenosis. Both rat neurons and astrocytes in primary culture actively use lactate as an oxidizable substrate and as a precursor of phospholipids and sterols. Lactate oxidation is enhanced by dichloroacetate, an inhibitor of the pyruvate dehydrogenase kinase in neurons but not in astrocytes, suggesting that the pyruvate dehydrogenase is regulated differently in each type of cell. Despite the low activity of this enzyme in newborn brain, pyruvate decarboxylation is the main fate of glucose in both neurons and astrocytes. The occurrence of a yeast-like pyruvate decarboxylase activity in neonatal brain may explain these results.

Changes in adult rat liver mitochondrial populations at different energy states analyzed by flow cytometry

The present work studies the changes in green fluorescence intensity after Rh-123 staining of the low (LFP) and the high fluorescence populations (HFP) in isolated mitochondria from rat liver. The results show that the HFP represents a mitochondrial compartment less sensitive to changes in energy states. In addition, it is concluded that the use of Rh-123 to monitor changes in mitochondrial membrane potential should be undertaken with caution because, under certain circumstances, there is no correlation between the Rh-123 intensity of fluorescence due to its uptake by mitochondria and previously reported changes in the mitochondrial membrane potential.

Hypothyroidism prevents postnatal changes in rat liver mitochondrial populations defined by rhodamine-123 staining

The effect of hypothyroidism on the percentages of low fluorescence population (LFP) and high fluorescence population (HFP) rhodamine-123-stained mitochondria, respiratory parameters, and ATPase activity were studied in liver mitochondria from early newborn rats. Hypothyroidism prevented the decrease in the percentage of HFP and the subsequent increase in LFP that occurs immediately after birth. This effect coincides with the impairment of mitochondrial respiratory function, as shown by the low respiratory control ratio and the low activity of F0,F1-ATPase found in hypothyroid newborns. All of these changes were reversed by the administration of thyroid hormones. ATP in vitro promotes the conversion of HFP into LFP and increases the respiratory control ratio in hypothyroid newborns, although this effect was not observed after thyroid hormone treatment. The effect of thyroid hormones on both the postnatal changes in mitochondrial populations and in F0,F1-ATPase activity was prevented by cycloheximide, but not by streptomycin. Thus, the observed effects of thyroid hormones on neonatal mitochondria must be accomplished by the induction of the synthesis of some nuclei-coded protein, possibly involved in F0,F1-ATPase assembly.

Effect of ethanol consumption on adult rat liver mitochondrial populations analyzed by flow cytometry

In the present study, the effects of administering ethanol to adult male rats on the distribution of the low fluorescence population (LFP) and high fluorescence population (HFP), and the rhodamine-123 fluorescence intensity of these groups of mitochondria are analyzed by flow cytometry. Our results show that ethanol administration to adult male rats induces a redistribution of the HFP and LFP mitochondrial populations leading to an increase of the less functional HFP mitochondria. In addition, ethanol induced an increase in the mean intensity of green fluorescence of the HFP that is probably related to an increased number of rhodamine-123 binding sites per mitochondria resulting from mitochondria enlargement.

Postnatal changes in rhodamine-123 stained mitochondrial populations are sensitive to protein synthesis inhibitors but mimicked in vitro by ATP

The incubation of term fetus mitochondria with ATP mimicked in vitro the increase in the respiratory control index and in the percentage of the rhodamine-123-low fluorescence population that occurred in vivo immediately after birth, suggesting that both phenomena are closely associated. The administration of streptomycin inhibited the increase in the percentage of the low fluorescence population that occurred immediately after birth, while the administration of cycloheximide even reversed these changes. These results suggest that the in vivo interconversion between mitochondrial forms depends on both cytosolic and mitochondrial protein synthesis.

Inhibition of neonatal brain fuel utilization by valproate and E-delta 2-valproate is not a consequence of the stimulation of the gamma-aminobutyric acid shunt

Stimulation of the gamma-aminobutyric acid (GABA) shunt by valproate and its major metabolite, E-delta 2-valproate, has been proposed to decrease brain energy metabolism. In order to elucidate this hypothesis, the effect of these drugs on substrate utilization in neonatal rat brain slices was studied. The overall rate of lactate utilization was dose-dependently inhibited by both drugs. Valproate and E-delta 2-valproate inhibited both sterol and fatty acid syntheses from 3-hydroxybutyrate. The rate of glucose utilization was not affected by valproate nor E-delta 2-valproate. The inhibition of the GABA aminotransferase by aminooxyacetate decreased lipogenesis from lactate, 3-hydroxybutyrate and glucose. The inhibitor of the mitochondrial pyruvate carrier, alpha-cyano-4-hydroxycinnamate, strongly decreased the rate of lactate, 3-hydroxybutyrate and glucose utilization, suggesting that the inhibition of pyruvate mitochondrial carrier is not the mode of action of these drugs. It is suggested that inhibition of plasma membrane monocarboxylate carrier by valproate and E-delta 2-valproate, but not the activation of the GABA shunt, is responsible for the inhibition of the brain fuel utilization.