THE METABOLISM OF PALMITIC ACID IN THE PHOSPHOLIPIDS, NEUTRAL GLYCERIDES AND GALACTOLIPIDS OF MOUSE BRAIN

Abstract— Following intracerebral injection, [¹⁴C]palmitic acid was rapidly incorporated into a variety of brain lipids. After 12 hr, 78 per cent of the lipid radioactivity was in phospholipids, 15 per cent was in triacylglycerols, 1 per cent each was in free fatty acids and galactolipids, and the remainder was in other neutral glycerides. Over 65 per cent of the phospholipid radioactivity was found in the choline phosphoglycerides but this proportion decreased substantially with time. At later times, increasing portions of the radioactivity were present in the monounsaturated acyl groups and the alkenyl groups but no radioactivity was detected in cholesterol or polyunsaturated acyl groups. These results indicate that most of the extensive recycling of radioactivity took place without oxidative degradation of the palmitoyl groups. The relative rates of incorporation of radioactivity were compared at 12 hr after injection. The specific radioactivities of the serine, ethanolamine, and choline phosphoglycerides had ratios of 6:3:2 based on the palmitoyl group content and 1:2:4 based on their phosphorus content. The specific radioactivities of galactolipids with O -acyl groups were higher than the specific radioactivitiesof cerebrosides or cerebroside sulphates. A new solvent mixture for thin-layer chromatography of brain galactolipids was described (chloroform-acetone-methanol-water, 60:20:20:1, by vol.).     

COMPOSITION OF CEREBRAL LIPIDS IN MURINE SUDANOPHILIC LEUCODYSTROPHY: THE JIMPY MUTANT

Abstract— The composition of sphingolipids and phospholipids of mouse brain during myelination was determined in normal animals and in mice with a genetically-determined disorder of myelin formation. Myelination was normally characterized by a two-fold increase in total phospholipids of brain, a four-fold increase in total sphingolipids, and a six-fold increase in cerebrosides. The Jimpy mutant, with defective formation of myelin in the central nervous system, demonstrated a marked deficiency of cerebrosides and a significantly lower content of total sphingolipids, without alteration of the composition of phospholipids. The increasing content of cerebrosides in the brains of the leucodystrophic mutant at the time in development when myelination is most active and the subsequent relative deficit suggest that the failure of myelin formation is not the result of a defect in biosynthesis of cerebrosides.     

BIOSYNTHESIS OF FREE AMINO ACIDS IN THE BRAIN OF JIMPY MICE

—The metabolism of free amino acids: γ-aminobutyric acid (GABA), glutamine, glycine and glutathione has been studied. The labelling of these free amino acids in normal and in myelin-deficient brains of Jimpy mice was followed after intraperitoneal injection of ¹⁴C-labelled glucose precursor. The quantitative distribution of these amino acids in the two kinds of mouse brain has been compared. A higher level of GABA and a faster labelling of the amino acids in Jimpy than in normal mouse brain was observed.     

GLUTAMATE METABOLISM IN OCTOPUS BRAIN IN VIVO;ABSENCE OF A WAELSCH EFFECT

Abstract— The metabolism of [U-¹⁴C]glutamate was followed in vivo in the octopus Eledone cirrhosa following intracranial injection, and compared with that in the mammalian brain.
By contrast with the rat brain, the specific activity of glutamine recovered from Eledone optic and vertical lobes was lower than that of glutamate at short time intervals after injection. Thus the Waelsch effect was not apparent in this species. Again, in contrast with the rat brain, radioactivity could be found in alanine but not in GABA following [U-¹⁴C]glutamate injection. This was compatible with observations made previously in vitro.
The significance of these intraspecies differences in metabolism and compartmentation is discussed.     

THE REGULATION OF PYRUVATE DEHYDROGENASE IN BRAIN IN VIVO

—The activity of pyruvate dehydrogenase in the brains of mice frozen in liquid nitrogen was 14·0 nmol/min per mg protein. It rose to 23·8 nmol/min per mg protein after incubation of the brain homogenate with 10mm -MgCl₂ to activate (dephosphorylate) the enzyme, indicating that approx 60% of the enzyme was originally in the active form. Treatment with amobarbital or pentobarbital halved the proportion of pyruvate dehydrogenase in the active form. The proportion of pyruvate dehydrogenase in the active form increased during ischemia, activation being complete within one min. Anesthesia with amobarbital slowed the activation during ischemia but did not alter the total amount of pyruvate dehydrogenase activity. The concentration of ATP, the ATP/ADP ratio and the adenylate energy charge increased as the proportion of pyruvate dehydrogenase in the active form decreased during barbiturate anesthesia, and they decreased as the proportion of pyruvate dehydrogenase in the active form increased during ischemia. After treatment with insulin, the proportion of pyruvate dehydrogenase in the active form increased by 30%. but the energy charge did not change. Treatment of mice with ether, morphine, ethanol, or diazepam did not change the proportion of pyruvate dehydrogenase in the active form although these treatments have been reported to alter pyruvate oxidation in brain in vivo. Treatments which altered pyruvate oxidation in the brain did not consistently alter the proportion of pyruvate dehydrogenase in the active form, unless they also altered energy charge.     

THE MEASUREMENT OF TRIGLYCERIDE IN BRAIN AND THE METABOLISM OF BRAIN TRIGLYCERIDE IN VITRO

Abstract—

• 1 Triglyceride has been isolated from brain by thin-layer chromatography and determined by absorption of the carbonyl group at 1740 cm^?1. The means of yields from whole mouse brain, whole rat brain, rat brain grey matter, rat brain stem, and incubated slices of rat brain cortex were 0.15–0.17 μmole/g tissue.
• 2 The distribution of fatty esters varied from preparation to preparation. Palmitate, stearate and oleate usually occurred in greatest amounts. Hydrolysis of a preparation of triglyceride from whole rat brain with pancreatic lipase indicated that palmitate was equally distributed between the α and β esters.
• 3 [1-¹⁴C]Acetate was rapidly incorporated into triglyceride of slices of incubated rat brain cortex. When the resulting triglyceride was hydrolysed with pancreatic lipase the distribution of radioactivity amongst the hydrolysis products was consistent with both the α and β esters of the triglyceride having been radioactively labelled.

     

EFFECTS OF LITHIUM TREATMENT IN VITRO AND IN VIVO ON ACETYLCHOLINE METABOLISM IN RAT BRAIN

Abstract— The effects of LiCl on cholinergic function in rat brain in vitro and in vivo have been investigated. The high affinity transport of choline and the synthesis of acetylcholine in synaptosomes were reduced when part (25-75%) of the NaCl in the buffer was replaced with LiCl or sucrose. This appeared to be due to lack of Na⁺ rather than to Li⁺, as addition of LiCl to normal buffer had little effect. Following an injection of LiCl (10mmol/kg, i.p.) into rats the concentration of a pulsed dose of [²H₄]choline (20 μmol/kg, i.v., 1 min) and its conversion to [²H₄]acetylcholine, and the concentrations of [²H₂]acetylcholine and [²H₀]choline were measured in the striatum, cortex, hippocampus and cerebellum. The [²H₄]choline and [²H₄]acetylcholine were initially (15 min after LiCl) reduced (to ?30% in the cortex) and later (24 h after LiCl) increased (to + 50% in the striatum). There was a corresponding initial increase (to +50% in the cerebellum) and later decrease (to ?30% in the hippocampus) of the endogenous acetylcholine and choline. These results indicate an initial decrease and later increase in the utilization of acetylcholine after acute treatment with LiCl. Following 10 days of treatment with LiCl there was an increased rate of synthesis of [²H₄]acetylcholine from pulsed [²H₄]choline in the striatum, hippocampus and cortex (P < 0.05). The high affinity transport of [²H₄]choline and its conversion to [²H₄]acetylcholine was activated (131% of control; P < 0.01) in synaptosomes isolated from brains of 10-day treated rats. Investigation of synaptosomes isolated from striatum, hippocampus and cortex revealed that only striatal [²H₄]acetylcholine synthesis was significantly stimulated. Kinetic analysis demonstrated that the apparent K_T for choline was decreased by 30% in striatal synaptosomes isolated from rats treated for 10 days with LiCl. Striatal synaptosomes from 10-day treated rats compared to striatal synaptosomes from untreated rats also released acetylcholine at a stimulated rate in a medium containing 35 mM-KCl. These results indicate that LiCl treatment stimulates cholinergic activity in certain brain regions and this may play a significant role in the therapeutic effect of LiCl in neuropsychiatric disorders.     

THE FATTY ACID COMPOSITION OF PHOSPHOLIPIDS AND GLYCOLIPIDS IN JIMPY MOUSE BRAIN

Abstract— Phospholipids and sphingolipids from brains of normal and Jimpy mice were isolated in a pure form by thin-layer chromatographic procedures. The fatty acid composition of the major phospholipids, i.e. ethanolamine glycerophospholipids, serine glycerophospholipids, choline glycerophospholipids and inositol glycerophospholipids, as well as sphingomyelin, cerebrosides and sulphatides was determined by gas-liquid chromatography. A specific fatty acid pattern for each of the four glycerophospholipids was found. The fatty acid composition of inositol glycerophospholipid, which has not previously been studied in mouse brain, was characterized by a high concentration of arachidonic acid. After 16 days of age, fatty acid analysis showed definite differences between the phospholipids from normal and mutant brains. A small increase of polyunsaturated fatty acids in glycerophospholipids of ethanolamine, serine and choline from the Jimpy central nervous system was found, which has been explained by the myelin deficiency. Sphingomyelin, cerebrosides and sulphatide analyses showed a wide distribution of saturated and mono-unsaturated fatty acids in both normal and mutant mice. A reduction in the amount of long-chain fatty acids was demonstrated in mutant brain sphingolipids; in sulphatides and cerebrosides, the amount of non-hydroxy fatty acids was reduced to a greater extent than in sphingomyelin. The distribution of fatty acids in sphingolipids from the myelin and microsomal fractions was also investigated in both types of mice. Cerebrosides were characterized by a high content of long-chain fatty acids in myelin as well as in microsomes. Sulphatides and sphingomyelin, on the other hand, showed a higher content of medium-chain fatty acids in microsomes than in myelin. In the mutant brain, the amount of long-chain fatty acids was reduced in both subcellular fractions. The deviation from normal in the pattern of fatty acid distribution in Jimpy brain is discussed in relation to the current concepts of glycolipid biosynthesis.     

EFFECT OF INSULIN ON LEVELS AND TURNOVER OF INTERMEDIATES OF BRAIN CARBOHYDRATE METABOLISM IN VIVO

Abstract— –The rates of incorporation of ¹⁴C from [U-^l4C]glucose into intermediary metabolites have been measured in rat brain in vivo. The time course of labelling of glycogen was similar to that of glutamate and of glucose, which were all maximally labelled between 20 and 40min, but different from lactate, which lost radioactivity rapidly after 20min. The extent of labelling of glycogen (d.p.m./ μ mol of glucose) was of the same order as that of glutamate at 20 and 40 min after injection of [¹⁴C]glucose. However, calculations of turnover rates showed that glutamate turns over some 8-10 times faster than glycogen. Insulin, intracisternally applied, produced after 4-5 h a 60 per cent increase in glucose-6-P and a 50 per cent increase in glycogen. There was no change in the levels of glucose, glutamate or lactate, nor in the activity or properties of the particulate and soluble hexokinase of the brain. The injection of insulin affected neither the glycogen nor glucose contents of skeletal muscle from the same animals. The effects of insulin on the incorporation of ^l4C into the metabolites contrasted with its effects on their levels. The specific activities of glycogen and glucose were unchanged and there was a slight but non-significant increase in the specific activity of glutamate. The time course of incorporation into lactate was unaffected up to 20 min, but a significant delay in the loss of ¹⁴C after 20 min occurred as a result of the insulin injection. At 40 min, the specific activity of cerebral lactate was 60 per cent higher in insulin-treated animals than in control animals. The results are interpreted in terms of an effect of insulin on glucose uptake to the brain, with possibly an additional effect on a subsequent stage in metabolism, which involves lactate.     

METABOLISM OF THE PHOSPHOINOSITIDES IN GUINEA-PIG BRAIN SYNAPTOSOMES

Abstract— The subcellular distribution of a number of enzymes concerned with inositol lipid metabolism has been studied in sub-fractions of disrupted guinea-pig brain synaptosomes. The enzymes were CDP-diglyceride: inositol phosphatidate transferase, phospha-tidylinositol kinase, diphosphoinositide kinase, diphosphoinositide phosphomonoesterase and diphosphoinositide diesterase. The distribution of phosphatidylinositol kinase in sub-fractions from water-treated synaptosomes was compared with that of other plasma membrane enzymes. After partial solubilization of synaptosomes by Triton X-100 the activities of phosphatidylinositol kinase and several other enzymes were examined.
Distribution of phosphatidylinositol kinase closely resembled that of acetylcholinesterase in sub-fractions of synaptosomes. Both enzymes appeared to be localised in the outer membrane of the synaptosome. CDP-diglyceride: inositol phosphatidate transferase was present in all types of synaptosomal membrane. All three enzymes concerned with diphosphoinositide metabolism were found in the cytoplasm of the synaptosome.     

THE LABELLING OF NERVE ENDING PHOSPHOLIPIDS IN GUINEA-PIG BRAIN IN VIVO AND THE EFFECT OF ELECTRICAL STIMULATION ON PHOSPHATIDYLINOSITOL METABOLISM IN PRELABELLED SYNAPTOSOMES

The intracerebral injection of ³²P_i into guinea-pig cortex resulted in a steady rate of incorporation into all phospholipids over a 20 h period. The specific radioactivities of phosphatidate and phos-phatidylinositol in synaptosomes prepared from cortex prelabelled, in vivo, were at a maximum after 2 h and the respective activities were 3–8 times higher than in whole cortex. This peak in labelling corresponded with the maximum specific activity of the brain ATP. No similar differential labelling pattern was observed for phosphatidylethanolamine, phosphatidylcholine and phosphatidylserine. Electrical stimulation of the prelabelled synaptosomes produced a rapid drop in the specific activity of phosphatidylinositol and phosphatidate and an increase in the specific activity of CDP-diacylglycerol. The specific activity of synaptosomal ATP was not affected. Study of the subsynaptosomal fractions obtained after osmotic rupture of the synaptosomes revealed that the most highly labelled phosphatidylinositol was in the synaptic vesicle fraction (D) and the most active phosphatidate was in a ‘microsomal’ fraction (E). Electrical stimulation caused a loss of phosphatidylinositol radioactivity from fraction D and a loss of phosphatidate radioactivity from fraction E. The specific activity of these lipids in other fractions was not affected. A possible role for presynaptic phosphatidylinositol is suggested.     

DECREASED METABOLISM IN VIVO OF GLUCOSE INTO AMINO ACIDS OF THE BRAIN OF THIAMINE-DEFICIENT RATS AFTER TREATMENT WITH PYRITHIAMINE

Abstract— Thiamine deficiency produced by administration of pyrithiamine to rats maintained on a thiamine-deficient diet resulted in a marked disturbance in amino acid and glucose levels of the brain. In the two pyrithiamine-treated groups of rats (Expt. A and Expt. B) there was a significant decrease in the levels of glutamate (23%, 9%) and aspartate (42%, 57%), and an increase in the levels of glycine (26%, 27%) in the brain, irrespective of whether the animals showed signs of paralysis (Expt. A) or not (Expt. B). as a result of thiamine deficiency. A significant decrease in the levels of γ-aminobutyrate (22%) and serine (28%) in the brain was also observed in those pyrithiamine-treated rats which showed signs of paralysis (Expt. A). Threonine content increased by 57% in Expt. A and 40% in Expt. B in the brain of pyrithiamine-treated rats, but these changes were not statistically significant. The utilization of [U-¹⁴C]glucose into amino acids decreased and accumulation of glucose and [U-¹⁴C]glucose increased significantly in the brain after injection of [U-¹⁴C]glucose to pyrithiamine-treated rats which showed abnormal neurological symptoms (Expt. A). The decrease in ¹⁴C-content of amino acids was due to decreased conversion of [U-¹⁴C]glucose into alanine, glutamate, glutamine, aspartate and γ-aminobutyrate. The flux of [¹⁴C]glutamate into glutamine and γ-aminobutyrate also decreased significantly only in the brain of animals paralysed on treatment with pyrithiamine. The decrease in the labelling of, amino acids was attributed to a decrease in the activities of pyruvate dehydrogenase and α-oxoglutarate dehydrogenase in the brain of pyrithiamine-treated rats. The measurement of specific radioactivity of glucose, glucose-6-phosphate and lactate also indicated a decrease in the activities of glycolytic enzymes in the brain of pyrithiamine-treated animals in Expt. A only. It was suggested that an alteration in the rate of oxidation in vivo of pyruvate in the brain of thiamine-deficient rats is controlled by the glycolytic enzymes, probably at the hexokinase level. The lack of neurotoxic effect and absence of significant decrease in the metabolism of [U-¹⁴C]glucose in the brain of pyrithiamine-treated animals in Expt. B were probably due to the fact that animals in Expt. B were older and weighed more than those in Expt. A, both at the start and the termination of the experiments.     

FATTY ACID COMPOSITION OF CEREBROSIDES, SULPHATIDES AND CERAMIDES IN MURINE SUDANOPHILIC LEUCODYSTROPHY: THE JIMPY MUTANT

The fatty acid composition of cerebrosides, sulphatides and ceramides was determined at 15-16 days post partum in the brain of the Jimpy mutant and in littermate controls. There was a marked deficit in the long chain fatty acids (C₂₂-C₂₄) of cerebrosides and sulphatides of Jimpy brain, with the unsubstituted fatty acids affected more than the alpha-hydroxy fatty acids. A decrease of long chain normal fatty acids was also found in the ceramides of Jimpy brain. The deficit of long chain fatty acids in these sphingolipids of the Jimpy brain was more severe than that found in the Quaking mutant which has a less extensive disorder of myelin formation.     

IN VIVO METABOLISM OF [G-3H]LIGNOCERIC ACID IN DEVELOPING RAT BRAIN1

Abstract— [G-³H]Lignoceric acid (tetracosanoic acid) was injected into the brains of 20-day-old rats, and the animals were killed after 8, 24, or 72 h. Various lipids were isolated from these brains, and the distribution of radioactivity was determined. The injected free acid rapidly disappeared, and the radioactivity was incorporated into varying chain-length nonhydroxy- and hydroxy saturated fatty acids of sphingolipids and phospholipids. Little radioactivity was found in unsaturated acids, sphingo-sine, and cholesterol. A time-dependent shift of the label among various fatty acids was relatively small 8 h after injection, probably because of the metabolic stability of the brain sphingolipids. In cerebrosides, the radioactivity was equally distributed between nonhydroxy and x-hydroxy fatty acids of all chain lengths. C₂₃ and C₂₂ fatty acids contained equal total radioactivities; C₂₃ and C₂₄ fatty acids contained similar specific activities. These results confirm the significant role of a-hydroxylation and 2-oxidation in the synthesis of very long-chain fatty acids in brain. In total lipid fatty acids, docosanoic acid (22:0) contained more radioactivity than its α-oxidation precursor, α-hydroxytricosanoic acid (23h:0) at all times. In sphingolipid fatty acids, the specific activity of 21:0 was always higher than that of its ct-oxidation precursor 22:0. These observations indicate that part of the 22:0 and 21:0 was derived by β-oxidation from the injected lignoceric acid or its α-oxidation product, respectively.     

ON THE TURNOVER OF ACETYLCHOLINE IN NERVE ENDINGS OF MOUSE BRAIN IN VIVO

Abstract— Acetylcholine is synthesized and stored in the nerve endings from which the liberation of the nerve transmittor is regulated by the nerve activity. The aim of the present investigation was to measure the in vivo turnover of acetylcholine in this subcellular acetylcholine pool. This has been carried out by injecting labelled choline intravenously and then by measuring at different time intervals the ratio between labelled choline and acetylcholine in the fractions obtained after subcellular fractionation. It was found that the ratio radioactive choline to radioactive acetylcholine was the same (2:1) in whole brain and in the nerve ending fraction 2 to 20 min after injection. Since it was assumed that the same ratio is true also for the endogenous compounds the choline pool in the nerve terminals was considered to make up 13 nmoles/g brain. The results also indicate that plasma choline is rapidly equilibrated with the nerve terminals and transformed to acetylcholine at a rate of about 5 nmoles/g brain/min.     

FREEZE-BLOWING: A NEW TECHNIQUE FOR THE STUDY OF BRAIN IN VIVO

Abstract— A new apparatus is described which removes and freezes brains of conscious rats more rapidly than was heretofore possible. The apparatus consists of two probes which are driven simultaneously into the cranial vault of the rat immobilized in a specially constructed restraining cage. When in position, air under pressure enters through one probe and blows the supratentorial portion of the brain tissue (situated between the olfactory bulbs and the superior colliculi) out the other probe and into a thin chamber previously cooled in liquid N₂. This method stops brain tissue metabolism more rapidly than the previously-described methods of microwave irradiation, decapitation into liquid N₂, or whole-animal immersion into liquid N₂, as evidenced by the measurement of labile metabolites and redox states. Thus, samples of freeze-blown brain had higher levels of a-oxoglutarate, creatine phosphate, pyruvate, glucose and glucose-6-phosphate and lower levels of lactate, malate and AMP than brain tissue obtained by the other methods. The free cytoplasmic [NAD⁺]/[NADH₂], [NADP⁺]/[NADPH₂] and [ATP]/[ADP] [HPO₄^2-] ratios were higher in freeze-blown samples. These data indicate that more extensive anoxic metabolism occurred when methods other than freeze-blowing were used. We conclude that the levels of metabolites measured in brain obtained with the freeze-blowing technique more closely resemble those which occur in vivo.     

METABOLISM OF THE ASPARTYL MOIETY OF N-ACETYL-l-ASPARTIC ACID IN THE RAT BRAIN

The metabolism of N-acetyl-l -aspartic acid (NAA) was studied in rat brain. [Aspartyl-U-¹⁴C]NAA was metabolized predominantly by deacylation. Studies of NAA biosynthesis from l -[U-¹⁴C]aspartic acid have confirmed previous reports that NAA turns over slowly in rat brain. However, intracerebrally-injected N-acetyl-l -[U-¹⁴C]asparticacid was rapidly metabolized. Exogenous NAA appears to be taken up rapidly into a small, metabolically-active pool. This pool serves as substrate for a tricarboxylic acid cycle associated with the production of glutamate for the biosynthesis of glutamine. The bulk of the NAA content in brain appears to be relatively inactive metabolically.