THE INCORPORATION OF LABELLED ACETATE INTO CEREBROSIDE AND OTHER LIPIDS OF THE DEVELOPING MOUSE BRAIN

—Cerebroside in the brain is highly localized in myelin and has a relatively slow turnover rate. The aim of this study was to evaluate the true cerebroside biosynthetic activity under conditions in which the degradation and reutilization of brain lipids were as small as possible. The 3-week-old mice were decapitated at 0·5, 1, 2·5, 5 and 15 min after the intraperitoneal injection of labelled acetate and the incorporation of radioactivity into each lipid class was examined. Even at 0·5 min, a considerable amount of radioactivity was found in simple lipids, especially in the free fatty acid fraction, and in the course of time the radioactivity of complex lipids increased. On the other hand, the incorporation of radioactivity into cerebrosides was extremely small throughout the experimental period. Results indicated that the low radioactivity of cerebroside might be due to its high content of long-chain fatty acids which were weakly labelled. The radioactivity of the sphingosine moiety was also low. In short, one of the rate-limiting steps of cerebroside synthesis in brain might exist in long-chain fatty acid and sphingosine synthesis. In addition, the incorporation curves of each component of cerebroside were compared with each other and the difference of the incorporation pattern of non-hydroxy fatty acids of cerebroside was noted.     

EFFECTS OF OXYGEN INDUCED CONVULSIONS ON THE UPTAKE OF ACETATE INTO RAT BRAIN LIPIDS1,2

Abstract— Rats were exposed to 5 atmospheres absolute of oxygen, and [1-¹⁴C]acetate was injected into the jugular vein either before or at the onset of electroencephalogram-defined convulsions. Levels of ¹⁴C observed 2.2 min after the injection were reduced in the total lipids of brain and elevated in the blood of convulsed rats when compared to the nonconvulsed controls. These differences between convulsed and nonconvulsed animals were less pronounced when measured 15 and 60 min after injection. Convulsions did not change the amount of ¹⁴C incorporated into the total lipids of plasma during the 60 min period studied. Six fractions obtained from total lipid extracts of brain by TEAE-cellulose showed similar ¹⁴C distributions in convulsed and control animals. The results suggest that oxygen-induced convulsions cause an impaired utilization of systemically administered acetate for fatty acid incorporation into the lipids of brain.     

INCORPORATION OF PHOSPHATE INTO RAT BRAIN DURING SLEEP AND WAKEFULNESS

Abstract— Labelled inorganic phosphate (³²P₁) was administered intraventricularly to unrestrained sleeping and waking adult rats. After about 20 min of sleep or a comparable period of wakefulness, as monitored by EEG and EMG, the animals were frozen in liquid nitrogen and the brains were analysed. One group of animals (A) was not previously acclimatized to the apparatus. A second group (B) was acclimatized. The specific radioactivity of a phosphoprotein fraction was elevated during sleep in group A but not in group B. The specific radioactivity of the phosphatides of group B was depressed in sleeping as compared with waking animals. This effect was not observed in group A. No significant difference was detected between the EEG patterns of sleeping animals in groups A and B, as evaluated by standard criteria. These observations suggest that the physiological conditions attributable to environmental, emotional or other determinants can influence shifts in brain metabolism during the sleep-wakefulness cycle.     

INTERACTION OF LEUCINE, GLUCOSE, AND KETONE METABOLISM IN RAT BRAIN IN VITRO

Brain cortex slices from fed, 48 h and 120 h fasted rats were incubated and ¹⁴CO₂ was measured from (a) [U-¹⁴C]glucose (5 mm ) either alone or in the presence of l -lcucine (0.1 or 1 mm ), and (b) [U-¹⁴C]leucine or [l-¹⁴C]leucine at 0.1 or 1 mm with or without glucose (5 mm ). In other experiments, sodium dl -3-hydroxybutyrate (3-OHB) or acetoacetate (AcAc) at 1 or 5 mm were added in the above incubation mixture. The rate of conversion of [U¹⁴C]glucose to CO₂ was decreased 20% by leucine at 1 mm and 30–50% by 3-OHB at 1 or 5 mm but not by leucine at 0.1 mm . The effects of 3-OHB and of leucine (1 mm ) were not additive. The effects of leucine were similar in the fed and fasted rats. The rate of conversion of [U-¹⁴C]leucine or [l-^,4C]leucine to ¹⁴CO₂ at 0.1 mm and 1.0 mm was increased by glucose (35%) in the fed or fasted rats. Ketone bodies in the absence of glucose had no effect on leucine oxidation. However, the stimulatory effect of glucose on the rate of conversion of leucine to CO₂ was inhibited by 3-OHB at 5 mm . These results suggest that (a) leucine in increased concentrations (1 mm ) may reduce glucose oxidation by brain cortex while itself becoming an oxidative fuel for brain, and (b) leucine oxidation by brain may be influenced by the prevailing glucose and ketone concentrations.     

THE INCORPORATION OF DOUBLE-LABELLED ACETATE INTO GLUTAMATE AND RELATED AMINO ACIDS FROM ADULT MOUSE BRAIN: COMPARTMENTATION OF AMINO ACID METABOLISM IN BRAIN

Abstract– We have determined the incorporation of [³H]-, [1-¹⁴C]- and [2-¹⁴C]acetate into glutamate, glutamine and aspartate of the adult mouse brain. All these three acetates were incorporated more extensively into glutamine than into glutamate. This has been reported by several authors for each of these labelled acetates in separate experiments. It was shown that [³H, 2-¹⁴C]acetate can be used to obtain an acetate labelling ratio analogous to the previously used [2-¹⁴C]acetate/[1-¹⁴C]acetate labelling ratio. From these acetate labelling ratios of glutamine and glutamate conclusions can be deduced about the dynamic relationship of these amino acids with each other and with the tricarboxylic acid cycle.
A fairly large isotope effect between acetate and glutamate was observed. As this isotope effect is very likely caused by the citrate synthase reaction, it can be argued that citrate synthase involved in the conversion of labelled acetate into glutamate is far out of equilibrium in vivo. Comparing our data with literature data, the possibility can be suggested that citrate synthase in the acetate metabolizing compartment is in situ kinetically distinct from citrate synthase in other compartments of the brain.     

THE EFFECT OF SLEEP DEPRIVATION UPON THE IN VIVO AND IN VITRO INCORPORATION OF TRITIATED AMINO ACIDS INTO BRAIN PROTEINS IN THE RAT AT THREE DIFFERENT AGE LEVELS

Abstract— The effect of sleep deprivation on the in vivo and in vitro tritiated amino acid incorporation into brain proteins was studied in the rat at three age levels. Sleep deprivation was induced either by water tank or handling methods. Three experimental groups of animals were used: control, sleep deprived and post deprivation sleeping rats.
A significant decrease of protein synthesis was found in the cerebellum, telencephalon and in crude subcellular fractions of brainstem of adult rats selectively deprived of paradoxical sleep. However, no alteration of protein synthesis was observed either in vivo or in vitro , in the same brain regions or in the liver after the rebound of paradoxical sleep following deprivation.
In four crude subcellular protein fractions a specific increase of the in vitro labelled amino acid incorporation was observed in the brain stem of 24-day-old rats allowed to recuperate after sleep deprivation as compared with the deprived rats. No significant changes were seen in the telencephalon.
No alteration of incorporation was found in 7-day-old rats deprived of sleep.
The possible functional significance of these results is discussed in relation to stress and to variations in the size of the precursor pool for protein synthesis.     

INCORPORATION OF LIPIDS INTO SUBCELLULAR FRACTIONS OF BRAIN OF QUAKING MUTANT

The synthesis of lipids and their assembly into subcellular membrane fractions of the myelin deficient Quaking mutant and control brains was studied in 18-, 24- and 41-day-old animals using a double label methodology with¹⁴C and ³H acetate as precursors. As a general procedure, Quaking mutants were injected intracranially with 50 μCi [¹⁴C]acetate and their littermate controls with 300 μCi [³H]acetate. The animals were killed 3 h post-injection, their brains were pooled and subcellular fractions prepared from the common homogenate. An 80-90% decrease in the incorporation of acetate into eleven lipids of myelin in the Quaking mutant was found. This occurred in the face of apparent normal incorporation (relative to microsomes) into lipids of the other main subcellular fractions (nuclear. mitochondrial and synaptosomal) with the exception of decreased incorporation into the myelin-like fraction at 18 and 24 days. Cholesterol and cerebroside were less readily incorporated into Quaking myelin than the other lipids. Although the microsomal synthesis of cholesterol and cerebroside was depressed by about 30% in the Quaking mutant, the incorporation of cholesterol into nuclear, synaptosomal and mitochondrial fractions was unaffected in the mutant. This indicates that sufficient cholesterol is synthesized for the normal assembly of these organelles. In contrast the incorporation of acetate into cholesterol and cerebroside of Quaking myelin was decreased much more than microsomal synthesis. This latter result is consistent with a defect in the process of myclin membrane assembly     

INCORPORATION IN VIVO OF RADIOACTIVE LEUCINE INTO NEURONAL AND GOAL NUCLEAR PROTEINS OF RAT BRAIN

Purified neuronal and glial nuclei were separated from rat brain cells. The fraction rich in neuronal nuclei contained 68 ± 9 per cent neuronal nuclei and the fraction rich in glial nuclei contained 89 ± 6 per cent glial nuclei. The fraction rich in neuronal nuclei isolated from cells of adult rat brain incorporated l -[4,5-³H]leucine into TCA-insoluble material at a rate comparable to those of the microsomal and the soluble fractions of the brain, and at a much higher rate than the fraction rich in glial nuclei. The proteins soluble in buffered-saline, the acid-soluble deoxyribonucleoproteins, and the residual proteins of the neuronal nuclei are apparently the proteins which account for the higher specific activity of neuronal proteins compared with glial nuclear proteins. In liver and kidney, the incorporation of [³H]leucine into nuclear proteins was lower than into other subcellular fractions from the same organs.     

EFFECTS OF ENVIRONMENTAL COMPLEXITY ON AMINO ACID INCORPORATION INTO RAT CORTEX AND HIPPOCAMPUS IN VIVO

Abstract— Amino acid incorporation in vivo was investigated in the cortex and hippocampus of rats raised in enriched and deprived environments for various periods of time following weaning. At early times after weaning (7 days), the incorporation of l -[³H]leucine into all sub-cellular fractions of both cortex and hippocampus was higher in enriched than in deprived rats. At 16 days, incorporation into synaptosomal sub-cellular fractions was higher in enriched than in deprived hippocampus, and lower in enriched than in deprived cortex; incorporation into perikaryal fractions of both brain regions was the same in the two groups of animals. Incorporation into subcortical nuclear protein fractions was higher in enriched rats at this time. At 35 days, the only difference between enriched and deprived rats was a lower incorporation into cortical synaptosomal sub-fractions in the former. Experiments involving double labelling and electrophoresis indicate that there is no stimulation or inhibition of the synthesis of any particular protein in hippocampal nuclear and synaptosomal sub-fractions of enriched rats. Synaptosomal proteins of cortex have a greater half-life in enriched than in deprived rats; proteins of perikaryal fractions of cortex, and of all fractions of hippocampus, are turning over at the same rate in enriched and deprived animals.     

THE INCORPORATION OF GLUCOSE INTO BRAIN GLYCOGEN AND THE ACTIVITIES OF CEREBRAL GLYCOGEN PHOSPHORYLASE AND SYNTHETASE: SOME EFFECTS OF AMPHETAMINE

Abstract— The effects of amphetamine sulphate (5 mg/kg intraperitoneally) on the incorporation of radioactive carbon from [U-¹⁴C]glucose into the glycogen of mouse cerebral cortex, midbrain and hind-brain have been investigated. In all brain regions studied amphetamine induced a rapid decrease in glycogen followed by a slower return to control values. No significant alterations were observed in the steady state concentration of cerebral glucose. The initial fall in glycogen was associated with a fall in its specific radioactivity relative to that of cerebral glucose, whereas the resynthesis of the polysaccharide was associated with a marked increase in the relative specific radioactivity of glycogen. Other experiments demonstrated that amphetamine initially stimulates the breakdown of prelabelled glycogen and that the resulting molecule has fewer 1,4 linked glucose side chains.
Studies of the relative forms of the enzymes glycogen phosphorylase and glycogen synthetase suggested that rapid post mortem changes were less likely to occur if cerebral tissue was fixed by means of a freeze-blowing technique. Amphetamine administration resulted in a rapid though transient elevation of phosphorylase a activity in mouse forebrain. The level of glycogen synthetase I activity was unchanged initially but was markedly elevated during the period when there was a large increase in the rate of incorporation of glucose into glycogen. It is suggested that cerebral glycogen metabolism is controlled, at least in part, by the interconversion of the 'active' and 'inactive' forms of glycogen phosphorylase and synthetase.     

THE INCORPORATION OF [1-14C]ACETATE INTO UNESTERIFIED FATTY ACIDS IN RAT CEREBRAL CORTEX IN VIVO

—The incorporation of [1-¹⁴C]acetate into unesterified fatty acids and into the fatty acids of neutral glycerides and of phospholipids has been measured in rat cerebral cortex in vivo. The most rapid incorporation is seen in the unesterified fatty acids which have a turnover time of 5-6 min. It is suggested that unesterified fatty acids are precursors to neutral glycerides and phospholipids rather than being derived from them by lipase activity.     

INCORPORATION OF 32P IN VITRO INTO TRIPHOSPHOINOSITIDE AND RELATED LIPIDS OF RAT SUPERIOR CERVICAL GANGLIA AND VAGUS NERVES

Abstract— Rat sympathetic ganglia, vagus nerve and sciatic nerve were each incubated with inorganic ³²P for various lengths of time and the resultant labelling of their inositol lipids was measured.
At all times up to 3 hr phosphatidylinositol was the most highly labelled lipid of ganglia, while triphosphoinositide was the most active lipid of vagus and sciatic nerves. Removal of calcium ions from the incubation media had no significant effect on the incorporation of phosphate into any of the inositol lipids of sympathetic ganglia.     

METABOLISM OF AMINO ACIDS AND AMMONIA IN RAT BRAIN CORTEX SLICES IN VITRO: A POSSIBLE ROLE OF AMMONIA IN BRAIN FUNCTION

Abstract— (1) The sum of the values of total (tissue + medium) amino acid-N of glutamate, glutamine, γ-aminobutyrate, and aspartate (referred to as the glutamate system) and of ammonia-N of incubated rat brain cortex slices is approximately constant under a variety of metabolic conditions (presence or absence of glucose or of oxygen or in the presence of metabolic inhibitors such as aminooxyacetate, malonate, methionine sulfoximine, fluoroacetate, ouabain, 2:4 dinitrophenol, or Amytal). Fluctuations in the value of one constituent are compensated by fluctuations in the values of other constituents. The same applies to infant rat brain cortex slices and to rat brain synaptosome preparations. It is suggested that the constancy of the glutamate-ammonia system implies a coupling of neurons and glia in such a manner that glutamate released from the neurons during excitation is taken up by the glia and there converted to glutamine. The glutamine is returned to the neurons where it is hydrolysed to glutamate and ammonia. The glia, on this view, exercise an important buffering effect on the extracellular content of the excitatory amino acid, glutamate, and possibly on that of other functionally active amino acids emanating from the neurons. (2) The magnitude of the glutamate-ammonia system in the infant rat brain cortex is about 43% of that in the adult. It is suggested that, with maturity, the development of the glutamate-ammonia system is linked with the development of the citric acid cycle of operations. (3) The ammonia in the system is tightly linked to the activity of the ATP-controlled glutamine synthetase. (4) Proteolytic ammonia and amino acids are formed, during the incubation, to values that seem to be independent of a wide variety of metabolic conditions. The total value is approximately 10 μmol/g in the first h of incubation. (5) As the ammonium ion is necessary for the return of glutamate to the neuron in the form of glutamine, it is inferred that the ion plays a functional role in the nervous system by helping to maintain the steady state of glutamate in the neuron.     

ANTI-WHOLE WHITE MATTER SERUM INHIBITS INCORPORATION OF GLUCOSE AND GALACTOSE INTO THE LIPIDS OF MYELINATING SPINAL CORD CULTURES

Myelin formation was inhibited in fetal mouse spinal cord cultures in the presence of serum from rabbits with experimental allergic encephalomyelitis produced by inoculation of whole bovine spinal cord white matter in complete Freund's adjuvant. Controls were exposed to decomplemented serum. Replacement of serum in inhibited cultures on the 18th day in vitro (DIV) with control serum (disinhibited) resulted in the appearance of visible myelin within 2–3 days. From 20 to 23 DIV, d -[U-¹⁴C]glucose or d -[U-¹⁴C]galactose was present in all media. Total protein, DNA, gangliosides and galactolipids were reduced by 21% in inhibited cultures, and activity of 2′,3′-cyclic nucleotide 3′-phosphohydrolase was reduced by 50%. There was little reduction in the incorporation of glucose carbon (21–23 DIV) into several lipid classes examined. Labelling of cerebrosides by galactose carbon in inhibited cultures was only 12% of that of controls while there was no reduction in the labelling of neutral lipid–cholesterol and the glycerophosphatides. Galactolipid labelling by [¹⁴C]galactose in the disinhibited cultures was intermediate between inhibited and control cultures. Differences in the effects of inhibiting medium on the incorporation of glucose and galactose carbon indicate that ceramide synthesis is less affected than is galactose incorporation to form cerebroside.     

FLOW OF GLUCOSE CARBON INTO BRAIN LIPIDS IN ADULT RATS FOLLOWING FOOD DEPRIVATION

Abstract— Rates of flow of glucose carbon in vivo into brain cholesterol, phospholipids, cerebrosides and gangliosides and concentrations of these lipids in the brain, were determined in adult rats after various periods of food deprivation. The rates were calculated from two measurements, the curve representing the decrease of plasma [¹⁴C]glucose specific activity with time and the specific activity of the brain lipid 180 min after intravenous injection of a tracer dose of d -[U-¹⁴C]glucose. Specific activities of brain lipids in rats deprived of food for 72h were significantly higher than in postabsorptive rats which were treated with the same dose of [¹⁴C]glucose. These higher specific activities were interpreted as a result of more labelled glucose available to lipid synthesis in the brain of fasted rats due to the substantial decrease in the rate of irreversible disposal of glucose by the whole body, commonly observed in fasted animals. The possibility that the higher specific activity values resulted from enhanced synthesis of brain lipids from glucose was ruled out since no changes were observed in the rate of flow of glucose carbon into brain lipids after food deprivation. The rate of flow of glucose carbon into gangliosides (15.4 ng C/min/mg C) was more than twice as fast as into either phospholipids or cerebrosides and about 4 times as fast as into cholesterol. The rates of carbon flow were used to calculate half lives of glucose carbon in the different classes of brain lipids. These half life values were 31 days for gangliosides, 72 days for phospholipids, 82 days for cerebrosides and 133 days for cholesterol. The results suggest that the synthesis of brain lipids from glucose is not affected by prolonged starvation in the adult rat.