THE FORMATION OF CHOLINE AND OF ACETYLCHOLTNE BY BRAIN IN VITRO

Abstract— Free choline and acetylcholine (ACh) in mouse or rat brain were assayed biologically. The subcellular distribution of ACh in brain slices that had been incubated in the presence of eserine was compared to that in control brain; during incubation, the ACh outside nerve endings increased four-fold, the ACh released from synaptosomes by osmotic shock doubled but the ACh bound firmly within nerve endings did not increase. The two nerve ending stores of ACh were labelled to similar specific radioactivities when slices were incubated with [³H]choline, but the specific radioactivity of the ACh formed was much lower than that of the added choline. Tissue incubated in the presence of eserine released choline and ACh into the medium and the tissue levels of both substances increased. Brain tissue exposed to Na⁺-free medium lost 84 per cent of its ACh and 66 per cent of its free choline; the amounts of both substances returned towards control values during subsequent incubation in a normal-Na⁺ medium (choline-free). Both the ACh outside nerve endings and the ACh associated with synaptosomes were depleted when tissue was incubated in Na⁺-free medium.     

THE LABELLING OF THE GANGLIOSIDIC FRACTION FROM BRAINS OF RATS EXPOSED TO DIFFERENT LEVELS OF STIMULATION AFTER INJECTION OF [6-3H]-GLUCOSAMINE

[6-³H] Glucosamine was injected into rats and then they were submitted for 1 h to light (about 1100 lux) and sound, while their controls were kept in darkness. Two series of experiments were done: in one, the animals received the injection intracerebrally; in the other, the injection was intraperitoneal. In both series the ratios of specific radioactivities (c.p.m./μmol of NANA) in mitochondria1 gangliosidic fractions to those in synaptosomal gangliosidic fractions were higher for rats exposed to illumination and sound ?+ 74 per cent, P < 0·01 and + 49 per cent, P < 0·001 (in respectively, experiments with intracerebral and intraperitoneal injections) than for animals kept in dark. For animals iqjected intraperitoneally the specific radioactivity of the mitochondria1 gangliosidic fraction from rats exposed to light was higher (+ 11 per cent, P < 0.05) than that obtained from animals kept in dark. For synaptosomes the specific radioactivity of the gangliosidic fraction obtained from animals exposed to light was lower (?15 per cent, P < 0.01) than that obtained from animals kept in dark. In animals kept under the experimental conditions already described for more than 1 h the differences tended to disappear. No differences were observed between the two groups of rats in the amounts of radioactivity found in the brain.     

THE METABOLISM OF [1-14C]ARACHIDONIC ACID IN THE NEUTRAL GLYCERIDES AND PHOSPHOGLYCERIDES OF MOUSE BRAIN1

Abstract— [1-¹⁴C]Arachidonic acid was incorporated into brain lipids with a half-life of approx. 5 min. Within 40 min after intra-cerebral injection, radioactivity was distributed mainly among the diacyl-sn-glycero-3-phosphorylcholine (45 per cent), diacyl-sn-glycero-3-phosphorylinositol (22 per cent), diacyl-sn-glycero-3-phosphorylethanolamine (14 per cent) and triacylglycerols (9 per cent). At comparable times, the proportions of radioactivity distributed in diacyl-sn-glycero-3-phosphorylserines and alkenylacyl-sn-glycero-3-phosphorylethanolamines were relatively small. Radioactivity was initially incorporated into the phosphatidio acids and diacylglycerols before labelling of the triacylglycerols and other phosphogly-cerides. The relative specific activity of diacylglycerols was maximum between 3–6 min after injection. Due to the small level of diacyl-sn-3-phosphorylinositol present in brain, its relative specific radioactivity was higher than other types of brain phosphoglycerides. Results of the experiment thus indicate that labelled arachidonic acid is an excellent precursor for metabolic studies with regard to acyl groups present in the 2-position of the phosphoglyceride molecules. Furthermore, this labelled precursor is specially useful in studies related to metabolism of diacyl-sn-glycero-3-phosphorylinositol in brain.     

The turnover of phosphoglycerides in the subcellular fractions of mouse brain: a study using (1-14C)oleic acid as precursor

Abstract— The turnover of phosphoglycerides in subcellular fractions of adult mouse brain was examined after intracerebral injection of [1-¹⁴C]oleic acid. Radioactivity of the total brain homogenate decreased rapidly thereafter, with only 4 per cent of the radioactivity remaining at the end of 3 months. The rate of decrease of radioactivity in the subcellular fractions was in the order: cytosol, microsomes, synaptosomes and myelin. Increasing amounts of radioactivity were detected in the alkenyl groups and cerebrosides, but metabolic conversions were not as extensive as found previously with the palmitoyl group. The specific radioactivities for diacyl sn-glycero-3-phosphorylcholine and diacyl sn-glycero-3-phosphorylethanolamine were highest in the microsomal fraction and decreased with time. The apparent half-lives for the diacyl sn-glycero-3-phosphorylcholine and the diacyl sn-glycero-3-phosphorylethanolamine in the microsome and synaptosome-rich fractions were 1-3.5 days when estimated between 1 and 7 days after injection. The rate of decay for the brain membrane phosphoglycerides was not linear with time, probably because of the extensive amount of recycling occurring within the system. Radioactivity was incorporated into the phosphoglycerides of the myelin but equilibration of radioactivity between microsomes and myelin required 7–14 days.     

Metabolism of cerebrosides and sulfatides in subcellular fractions of developing rat brain

Previous studies on myelinating rat brain indicated that microsomes, Golgi-enriched and cytosol fractions may process galactolipids destined for myelin. To extend these findings we labeled brain galactolipids in vivo and determined the specific radioactivity of cerebrosides and sulfatides in several subcellular fractions. 17-day-old rats were treated by intracranial injection with [14C]galactose 60 min prior to and [3H]galactose 15 min prior to killing. Subcellular fractions were prepared from brain stem, and concentrations of cerebrosides and sulfatides were determined, their radioactivity measured and the 3H/14C ratio compared. Our results showed that the heavier Golgi-enriched fraction (designated Fraction 2) is unique in its low galactolipid content and high specific radioactivities of cerebrosides and sulfatides. The low ratio of the specific activity of cerebroside to that of sulfatide in Fraction 2 compared to other fractions indicates that it may be the site of most rapid conversion of newly synthesized cerebrosides to sulfatides. The specific radioactivities of cerebrosides and sulfatides in cytosol are intermediate between those in Golgi-enriched Fraction 2 and microsomes and those in myelin, consistent with the role postulated for cytoplasmic elements in the transport of cerebrosides and sulfatides to myelin.     

METABOLISM IN VIVO OF BRAIN GALACTOLIPIDS: THE JIMPY MUTANT

Abstract— The incorporation in vivo of [U-¹⁴C]glucose into the galactolipids of the brain of control and Jimpy mutant mice was examined. Over a 24-h period of incorporation there was no indication of an increased rate of turnover of brain galactolipids in the mutant. The Jimpy mutant was identified at ages prior to and at the inception of myelination (7–10 days post partum) with a coat marker (Tabby). There was similar total radioactivity in galactolipids of the Jimpy at these ages but a reduction to 13 per Cent of control at 13 days and to 6 per cent at 16 days of postnatal age. This devetopmental pattern of galactolipid synthesis in Jimpy brain is not in accord with a primary defect in the biosynthesis of cerebrosides and sulphatides.     

DIFFERENTIAL DISTRIBUTION OF [U-14C]GLUCOSE AND [U-14C]GLYCEROL AMONG MOLECULAR SPECIES OF PHOSPHATIDYL CHOLINE,PHOSPHATIDYL ETHANOLAMINE AND 1,2-DIACYLGLYCEROL IN RABBIT BRAIN12

Specific radioactivities of molecular species of phosphatidyl choline(PC), phosphatidyl ethanolamine(PE) and 1,2-diacylglycerol were determined in rabbit brain 15 and 30 min after intraventricular injection of 10OpCi of either [U-¹⁴C]glucose or [U-¹⁴C]glycerol. The rate of de nouo synthesis of glycerophospholipids and their molecular species could be determined after glycerol labelling, since 94.0–99.7% of ¹⁴C activity was recovered in glyceryl moieties of brain lipids. After injection of glucose radioactivity was measured in both glyccrol and acyl residues of lipids. High incorporation rates were measured in species of PC, PE and 1,2-diacylglycerol with oleic acid in position 2 and with palmitic, stearic or oleic acids in position 1. The conclusion may therefore be drawn that these molecular species were preferably synthesized de novo by selective acylation of glycerol 3-phosphate. The lowest specific activities were observed for 1,2-dipalmitoyl- and l-stearoyl-2- arachidonoyl-glycerol, -PC and -PE. These turnover rates point to incorporation of arachidonate, and probably also of palmitate in dipalmitoyl-PC, amounting to 20% of total PC, via deacylation-acylation- cycle.     

ACETYLCHOLINE,CHOLINE AND CHOLINE ACETYLTRANSFERASE ACTIVITY IN THE DEVELOPING BRAIN OF NORMAL AND HYPOTHYROID RATS1

Abstract— Acetylcholine, choline and choline acetyltransferase activity were measured in the whole brains of normal and hypothyroid rats during development. At 1 day postpartum, brain acetylcholine was 73 per cent of adult levels. Propylthiouracil-induced hypothyroidism up to age 20 days did not alter brain acetylcholine concentrations, but at 30 days resulted in significantly decreased levels. At day 1, brain choline was 20 per cent higher than adult levels and decreased between days 8 and 10. In hypothyroid rats this phenomenon did not occur until days 15–20. At day 1 postnatally, choline acetyltransferase activity was only 7 per cent of adult levels, then between days 5 and 20 rose to 77 per cent of adult levels. Beginning at day 8, hypothyroidism resulted in significantly decreased enzyme levels. This effect could be reversed at day 17 by concurrent tri-iodothyronine substitution therapy. In hypothyroid rats, maximum brain choline acetyltransferase activity was 30 per cent less than normal adult levels.     

AXOPLASMIC TRANSPORT IN THE OPTIC NERVE AND TRACT OF THE RABBIT

The axonal transport of labelled proteins was studied in the optic system of adult rabbits after an intraocular injection of [³H]Ieucine. It was demonstrated that the precursor was incorporated into protein, which was transported along the axons of the retinal ganglion cells. Intraocularly injected puromycin inhibited protein synthesis in the retina and markedly inhibited the appearance of labelled protein in the optic nerve and tract. It was further demonstrated by intracisternal injection of [³H]leucine that an intraocular injection of puromycin did not affect the local protein synthesis in the optic nerve and tract. Cell fractionation studies of the optic nerve and tract showed that the rapidly migrating component, previously described as moving at an average rate of 110-150 mm/day, was largely associated with the microsomal fraction. About 40 per cent of the total protein-bound radioactivity in this component was found in the microsomal fraction and about 15 per cent was recovered in the soluble protein fraction. Most of the labelled material moving at a rate of 1-5-2 mm/day was soluble protein. The specific radioactivity of this component was about ten times greater than that of the fast one. In the slow component about 50 per cent of the radioactivity was found in the soluble protein fraction and about 10 per cent of the radioactivity was recovered in the microsomal fraction. Radioautography demonstrated incorporated label in the neuropil structures in the lateral geniculate body as early as 4-8 hr after intraocular injection. The labelling of the neuropil increased markedly during the first week, and could be observed after 3 weeks.     

[2-3H]GLYCEROL AS A PRECURSOR OF PHOSPHOLIPIDS IN RAT BRAIN: EVIDENCE FOR LACK OF RECYCLING

Abstract— When [2-³H]glycerol was injected intracranially into young rats, it was presented as a pulse label, leaving the brain rapidly and giving up much of its labelled hydrogen to water. [2-³H]glycerol was efficiently incorporated into brain lipids, especially into choline and ethanolamine phospholipids. Following injection of a mixture of [³H]- and [¹⁴C]-labelled glycerol, the ratio of ³H to ¹⁴C in the phospholipids of both whole brain and the microsomal fraction decreased as a function of time after injection. This finding indicated less recycling of the tritium label. This lack of recycling was further indicated by the finding that 94 per cent of the tritium label of phosphatidyl choline was in the glycerol portion of the molecule rather than in the fatty acids. At 2 weeks following injection with [³H]glycerol, 93 per cent of the total radioactivity in brain appeared in the lipid fraction. In contrast, following injection with [¹⁴C]glycerol, only 57 per cent of the radioactivity appeared in lipid, with about 20 per cent in protein.     

THE SUBCELLULAR LOCALIZATION OF CARBAMYLCHOLINE-STIMULATED PHOSPHATIDYL INOSITOL TURNOVER IN RAT CEREBRAL CORTEX IN VIVO

Abstract— The intraventricular injection of 40 μCi of ³²P_i (carrier free) into adult rats resulted in maximum incorporation of ³²P_i into the phosphatidyl inositol of the whole cortex after 20 h. A further intraventricular injection of 2 nmol carbamylcholine plus 0.02 nmol eserine resulted in a 23% decrease in the specific activity of phosphatidyl inositol after 20 min. The specific radioactivities of phosphatidyl choline, phosphatidyl ethanolarmine and phosphatidyl serine were not changed. Cerebral cortex from rats treated in this way was subjected to an extensive subcellular fractionation. It was found that the specific radioactivity of the phosphatidyl inositol of the synaptic vesicle fraction showed a reduction of 60%. No other fractions showed effects of this magnitude.     

BIOSYNTHESIS AND BIODEGRADATION OF RAT BRAIN GANGLIOSIDES STUDIED IN VIVO

Abstract— Metabolic relationships between the four major brain gangliosides, GM1, GD1a, GDlb and GT1 were studied in vivo . Labelled acetate and glucosamine were injected intracerebrally into 6–12-day-old rats and the radioactivities of the cerebral gangliosides were analysed. Radioactivity from [³H]acetate was determined in sialic acid, sphingosine and stearic acid and from [1-¹⁴C]glucosamine in hexosamine and sialic acid. The gangliosides were labelled in proportion to their pool size. In 6 day-old rats the labelling was approx. 30 per cent lower in the sialidase-stable sialyl group than in the labile one. When the brain gangliosides were labelled in 12-day-old rats, however, the specific activities of sialidase-labile and stable sialyl groups were the same at 0.5 months after the injection of precursors and disappeared at the same rate. The results indicate that at the age of 6 days a small pool of monosialogangliosides exists, which is converted to di- and trisialogangliosides. The degradation of gangliosides was studied by following the radioactivities in sphingosine and stearic acid from 2 to 6 months after the injection of labelled acetate. The specific activities of sphingosine and stearic acid decreased simultaneously at the same rate in all the four major gangliosides. The specific activity of stearic acid was the same in total brain lipids as in gangliosides. The half-lives for the degradation of the gangliosides were age-dependent and estimated to 60 days in adult rats. They were much shorter in younger rats but no reliable figures could be determined.     

COMPARTMENTATION AND LABELLING OF AMINO ACIDS IN THE DEVELOPING RAT BRAIN AFTER INJECTION OF [U-14C]RIBOSE

Abstract— [U-¹⁴C]Ribose was given by subcutaneous injection to young rats aged 2–56 days. During the first week after birth ¹⁴C in the brain was found mainly combined in glucose, fructose and sedoheptulose which contained 46–57 per cent of the ¹⁴C in the acid soluble metabolites in the rat brain. In contrast, during the critical period (10–15 days after birth) the ¹⁴C in the free sugars decreased from 24 to 3 per cent, while the ¹⁴C content of amino acids in the brain increased from 11 to 44 per cent of the total perchloric acid-soluble ¹⁴C. The increase in labelling of amino acids during the critical period was attributed to increased glycolysis and increased oxidation of pyruvate. The relative specific radioactivity of y -aminobutyrate and aspartate in the rat brain at 28 days after birth was equal to or greater than the relative specific radioactivity of glutamate. Assuming that the increase in amino acid content following the cessation of cell proliferation in the brain is located mainly in cell processes (cytoplasm of axons, dendrites, glial processes and nerve terminals), tentative values were estimated for the pool sizes of glutamate, glutamine, aspartate and y -amino butyrate.     

MANIFESTATION OF METABOLIC COMPARTMENTATION DURING THE MATURATION OF THE RAT BRAIN

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

SYNTHESIS OF ACETYLCHOLINE IN DIFFERENT COMPARTMENTS OF BRAIN NERVE TERMINALS IN VIVO AS STUDIED BY THE INCORPORATION OF CHOLINE FROM PLASMA AND THE EFFECT OF PENTOBARBITAL ON THIS PROCESS

The time course of the incorporation of choline from plasma into a high and a low molecular weight fraction from mouse brain synaptosomes was studied. The fractions were obtained from lysed synaptosomes by gel filtration on Sephadex G-25. An extremely rapid incorporation of radioactivity into acetylcholine was found in both fractions and in the time interval 0.25-9 min after the intravenous administration of labelled choline, higher specific radioactivities of acetylcholine were found in the high molecular weight fraction than in the low molecular weight fraction. However, the specific radioactivity of choline in the high molecular weight fraction was much lower than that of acetylcholine. It was found that barbiturate anaesthesia caused a marked decrease in the labelling of acetylcholine in the high molecular weight fraction while the incorporation into the low molecular weight fraction was affected to a much smaller extent. Acetylcholine of the high molecular weight fraction showed properties similar to those of vesicle-bound acetylcholine. The recoveries of labelled and endogenous acetylcholine and choline from the brain homogenates were calculated in different steps of the fractionation procedure. In the fraction containing lysed synaptosomes the recovery of radioactive acetylcholine was lower than that of endogenous acetylcholine. This may indicate the presence of two types of bound acetylcholine in the synaptosomes. Different models for the intraneuronal synthesis of acetylcholine are discussed and it is proposed that a site of acetylcholine synthesis in vivo may be closely associated with some constituent of the high molecular weight fraction and directly coupled with the storage of the transmitter.     

LABELLING OF ACETYLCHOLINE IN THE BRAIN OF MICE FED ON A DIET CONTAINING DEUTERIUM LABELLED CHOLINE: STUDIES UTILIZING GAS CHROMATOGRAPHY—MASS SPECTROMETRY

—A method to achieve labelling of the acetylcholine stores of the brain under ideal physiological conditions is described. To this end, mice fed on a choline free diet were supplied with deuterium labelled choline in the drinking water. Labelled and unlabelled choline in plasma and in the brain as well as labelled and unlabelled acetyicholine in the brain were measured by a gas chromatographic-mass spectrometric method. It was found that after 1–25 days on the deuterium choline diet, substantial amounts of the plasma choline and brain acetylcholine were displaced by deuterium choline and deuterium acetylcholine, respectively. Already on the first day, the mole ratio of deuterium choline/total choline in plasma was 0·22, and it approached a maximum of 0·57 on the 14th day. The mole ratios of deuterium acetylcholine/total acetylcholine in the brain were slightly but significantly lower than those of deuterium choline/total choline in plasma 1–14 days, but asymptotically approached the mole ratios of deuterium Ch/total Ch in plasma by 25 days. Intact brains submitted to incubation at room temperature for 10 min increased their total choline content by about 500 per cent. Concurrently, in brains from animals kept on a deuterium choline diet for 1–2 days, the level of deuterium choline rose only by 50 per cent after incubation. Deuterium choline levels increased, however, by 200–300 per cent in the brains from animals kept on the deuterium diet for longer time periods. On the basis of these data it is suggested that: (a) choline in plasma is partly supplied from the food and partly from endogenous sources; (b) plasma choline rapidly equilibrates (less than one day) with a pool of Ch in the brain which is responsible for biosynthesis of acetylcholine; (c) the size of this choline pool is in the order of 34–40 nmol/g.     

Incorporation of [14C] ethanolamine and [3H] Methionine into phospholipids of rat brain and liver in vivo and in vitro

Comparative studies were undertaken on the in vivo and in vitro incorporation of [¹⁴C] ethanolamine, [³H] methionine and [¹⁴C] S-adenosyl-methionine into phosphatidylethanolamine (PhE) and phosphatidylcholine (PhC) of rat liver and brain. It was observed that brain can synthesize de novo PhC from PhE via the transmethylation pathway, however synthesis rates were (1) markedly lower than those of liver and (2) decreased significantly with age. In the choline-containing lipids more than 95% of the radioactivity was found in PhC. Studies on the localization of the radioactivity in PhC following the intracranial injection of [³H] methionine or [¹⁴C] ethanolamine revealed that both precursors are incorporated almost exclusively into the choline moiety of this phospholipid. There was significant labeling of PhC only when the precursors were administered intracranially and much less incorporation was observed with the systemic routes. Thus following the intravenous administration of [¹⁴C] ethanolamine, the specific radioactivities of liver PhE and PhC were up to 75 times as high as those of brain and 4 to 5 times as high in the organs of the 20-day old as those of the adult. In contrast, when this precursor was administered intracranially the specific radioactivities of both phospholipids in liver were only twice as high as those of brain. Although the short-and long-term time-course studies on the in vivo incorporation of [¹⁴C] ethanolamine and [³H] methionine into PhC of both organs could suggest a precursor-product relationship between the biosynthesis of this phospholipid in liver and brain, this apparent relationship could also be due to the high turnover of PhE in liver, with half-life of 2.87 hr, and its low turnover in brain, with half-life of 10.7 days. The present findings on the low rate of formation of PhC from PhE in brain coupled with the fact that this conversion declines sharply with age, especially when the isotopes are administered systemically, could explain the observation of previous investigators that the brain cannot synthesize its own choline and thus it must derive its choline from exogenous sources such as lipid-choline. It was concluded that the brain can synthesize its own choline; however it remains also dependent on liver and dietary choline which are probably transported into the brain as free choline.     

Different metabolic rates for arachidonoyl molecular species of ethanolamine glycerophospholipids in rat brain

The ethanolamine glycerophospholipids (EGP) contain most of the arachidonate (20:4, n-6) and adrenate (22:4, n-6), potential precursors of biologically potent prostaglandins and related compounds. Much better methods utilizing high performance liquid chromatography (HPLC) techniques are now available for the study of the molecular species of all three classes, namely diacyl, alkenylacyl (plasmalogen), and alkylacyl. Different molecular species may have different functions. This possibility was studied by examining the rates of incorporation of [3H]arachidonic acid into the three major molecular species of each of the three classes of ethanolamine glycerophospholipids. After the intracerebral injection of [3H]20:4 into rat brain, it was rapidly converted to 22:4(n-6). Of the total radioactivity, 10-20% was located in 22:4 in alkenylacyl and diacyl-GPE. In the alkylacyl-GPE, labeled 22:4 was preferentially incorporated and accounted for 50-60% of the total radioactivity. The primary arachidonoyl molecular species of alkenylacyl, alkylacyl, and diacyl-GPE were the 18:1-20:4, 16:0-20:4, and 18:0-20:4 species. The alkylacyl class contained almost equal proportions of these three molecular species. On the other hand, the 20:4 in alkenylacyl and diacyl classes was combined largely with 18:0 groups at the sn-1 position. In particular, the 18:0-20:4 species comprised about 80% of arachidonoyl molecular species of the diacyl class. In all three classes, the highest specific radioactivities were found in the 18:1-20:4 species, whereas the 18:0-20:4 species had the lowest specific radioactivity. Over the period 60 min-24 hr, the diacyl 18:0-20:4 and all three arachidonoyl molecular species of the alkenylacyl class increased in specific radioactivity more rapidly than the other arachidonoyl molecular species.     

PROTEIN SYNTHESIS IN THE MEDULLA OF THE RAT BRAIN. REPRODUCIBILITY OF THE RESULTS

Abstract— [¹⁴C]Leucine was injected intracranially into the brainstem reticular formation at the level of the upper medulla by the stereotaxic method. Subcellular fractions prepared 3 hr after injection showed that the specific activities of leucine-incorporated proteins decreased in the order soluble, microsomal, nuclear and mitochondrial fractions. Specific activities of proteins in the sera were 2·2 per cent of whole homogenate proteins.
The results from 27 experiments showed that 66·6 per cent of the mean specific activities of proteins extracted from whole homogenates fell within ·1 s.d . and 100 per cent within ± 2 s.d . (close to a normal distribution). The coefficients of variation were between 40 and 50 per cent for whole homogenates, sera and all subcellular fractions. Reproducibility of results and factors concerned with possible errors in the technique are discussed.     

ENZYMATIC ACYLATION OF 1-ALKYL-, 1-ALKENYL-AND 1-ACYL GLYCERO-3-PHOSPHORYLETHANOLAMINE IN DEVELOPING RAT BRAIN

Abstract— Rat brain particulate fractions were shown to acylate [³²P]1-alkyl- sn -glycero-3-phosphorylethanolamine (GPE). While the main product is 1-alkyl-2-acyl GPE, about 12 per cent of the radioactivity was also found in 1-alkenyl-2-acyl GPE. The acyl transferase activity was completely dependent on added ATP and CoA and it was localized mainly in the microsomal fraction. A comparative study of acyl transferase activities to 1-alkyl-, 1-alkenyl-, and 1-acyl GPE by crude mitochondrial fraction and microsomes of 10, 16 and 22-day-old rat brains showed a progressive increase in activity with development. In the 22-day-old rat brain the order of activity towards the three substrates is as follows: 1-acyl GPE ± 1-alkenyl GPE ± 1-alkyl GPE with a crude mitochondrial fraction and 1-acyl GPE ± 1-alkyl GPE ± 1-alkenyl GPE with microsomes.