REGIONAL AND SUBCELLULAR DISTRIBUTION OF AMINOTRANSFERASES IN RAT BRAIN

Abstract— Aminotransferase activity was measured in various areas of the nervous system of the rat (cortical grey matter, midbrain, corpus callosum, spinal cord and sciatic nerve) and in subcellular fractions of rat brain (nuclei, mitochondria and cytosol). Activity was low or absent in the sciatic nerve relative to that in the other areas, with the exception of incubation of glutamate with oxaloacetate (25 per cent of the activity found in brain) and of asparagine with 2-oxoglutarate (65 per cent of the activity found in brain). The distribution of enzymic activity was not homogeneous; alanine-2-oxoglutarate aminotransferase was highest in cortical grey matter; leucine- and GABA-2-oxoglutarate aminotransferases were highest in midbrain. Incubation of phenylalanine or tyrosine with 2-oxoglutarate gave similar activities in grey matter and midbrain. Activity generally was higher in the grey matter than in corpus callosum or spinal cord. However, incubations of methionine with 2-oxoglutarate, or glutamine with glyoxylate, gave similar activities in the three areas studied from the brain, whereas incubations of glutamate with glyoxylate gave highest activity in the corpus callosum. Only incubations of asparagine with 2-oxoglutarate, and glutamate with glyoxylate, gave significant activity in the nuclear subcellular fraction. Aminotransferase activity of phenylalanine, tyrosine or GABA with 2-oxoglutarate, or ornithine or glutamine with glyoxylate, was localized to mitochondria. The remaining reactions studied (glutamate with oxaloacetate; leucine, alanine, methionine or asparagine with 2-oxoglutarate and glutamate with glyoxylate) demonstrated activity in both the mitochondrial fraction and the soluble supernatant fraction.     

THE POSTNATAL DEVELOPMENT OF CATECHOL-O-METHYL TRANSFERASE IN THE RAT BRAIN

Abstract— The postnatal development of three enzymes in the rat forebrain was studied. When expressed per tissue weight the catechol- O -methyl transferase (COMT) increased 2-fold from birth to adult age, the lactate dehydrogenase (LDH) 4-fold and the monoamine oxidase (MAO) 12-fold. Expressed per mg protein the increase in the enzyme activities in the subcellular fractions which contained the main part of the different enzymes was still 2–4-fold for COMT and LDH while for MAO it was 4-fold.
There was a relative increase in the COMT activity in the P₂ fraction (synaptosomes and mitochondria). This increase was identical with a corresponding increase in LDH activity and protein and was probably due to growth of nerve terminals. The COMT in the cytoplasm of the synaptosomes showed the same increase relative to the proteins as did the 'free' cytoplasmic enzyme.
The conclusion is drawn that the enzymes in the rat brain show a certain degree of development during brain growth. An additional increase of some enzymes is due to the development of specialized structures such as mitochondria and nerve terminals with synapses. COMT is not related to any such specialized structure.     

THE SUBCELLULAR DISTRIBUTION OF PARTICLE-BOUND NEGATIVE CHARGES IN RAT BRAIN

Abstract— Ferritin cationized with Girard's reagent T [(CH₃)₃NCH₂CONHNH₂] was used as a marker for negative electric charges on subcellular components of rat brain. Pre- and postsynaptic membranes did not bind cationic ferritin, either on their outer or their inner surface. Vesicular membranes, however, were heavily labelled with cationic ferritin. Post- and presynaptic densities appeared to carry a large number of negative charges. Cationic ferritin was also bound within the synaptic cleft. The density varied, however, from synapse to synapse: in general, binding within the cleft was significantly reduced when the synaptosomes were pretreated with 1 M-NaCl. Cationic ferritin was observed in high density on the outer surface of myelin sheaths and even between the lamellae at the intraperiod lines. Neuro-tubules and neurofilaments bound cationic ferritin in significant amounts. The results are discussed in relation to the mechanism of neurotransmission and to the binding and transport of drugs.     

REGIONAL AND SUBCELLULAR DISTRIBUTION OF PROTEIN CARBOXYMETHYLASE IN BRAIN AND OTHER TISSUES

Protein carboxymethylase, an enzyme that transfcrs the methyl group of S-adenosyl-L-methionine to carboxyl groups of proteins and endogenous acceptor proteins were examined in nerve and endocrine tissues. The highest protein carboxymethylase activity was found in the brain, followed by the testis, pituitary and heart. On the other hand, the tissue with the highest level of endogenous substrate(s) was the pituitary. The nearly identical specific activity ratio for two different protein substrates in all tissues examined, suggests that one enzyme is responsible for carboxymethylase activity in different tissues. The subcellular distribution of the enzyme in brain showed a high concentration in the soluble fraction, presumably representative of the enzyme in the cytosol of cell bodies. Considerable enzyme activity was also found in brain synaptosomes which was increased by osmotic lysis. Protein carboxymethylase was shown to accumulate proximally to a ligation of the rat sciatic nerve. A possible physiological role for protein carboxymethylase in neuronal function is discussed.     

SUBCELLULAR DISTRIBUTION OF d-AMINO ACID OXIDASE AND CATALASE IN RAT BRAIN

—Rat brain d -amino acid oxidase was found to be confined to the hindbrain, distributed more or less equally between cerebellum and medulla. Histochemical staining showed the enzyme to be localized largely in the molecular layer of the cerebellum. After fractionation by means of several distinct density gradient centrifugation procedures exploiting differences in sedimentation coefficient or in density or in both, the enzyme was found to be entirely or almost entirely associated with cytoplasmic particles with a median diameter of the order of 0·2 μm, and a median equilibrium density in aqueous sucrose of 1·18. Comparison with the behavior of cytochrome oxidase and of N-acetyl-β-glucosaminidase indicates that these particles are not mitochondria and are unlikely to be lysosomes. They also differ significantly from the bulk of the catalase-containing particles, which on an average appear to be somewhat smaller. The possibility that they might contain some catalase activity, and thereby qualify as ‘peroxisomes’, can however not be excluded. In any case, they differ profoundly from the peroxisomes of liver or kidney.     

SUBCELLULAR AND SUBMICROSOMAL DISTRIBUTION OF GLYCOLIPID-SYNTHESIZING TRANSFERASES IN YOUNG RAT BRAIN

The subcellular and submicrosomal distributions of four glycolipid-synthesizing transferases were studied in young rat brains. (1) Two galactosyl transferases involved in the synthesis of cerebrosides, the cerebroside sulphotransferase which catalyses the synthesis of sulphatides, and the glucosyl transferase which plays an important role in the ganglioside biosynthesis were localized essentially in the microsomal fraction. Only low activities were detected in the crude mitochondrial and synaptosome-enriched fractions. (2) A comparison of the activities of these enzymes in the crude myelin and two myelin subfractions showed that the galactosyl transferases and the cerebroside sulphotransferase had similar activities in the crude myelin and myelin-like fractions. A considerable galactosyl transferase activity was found in purified myelin. In this respect these two enzymes were different from cerebroside sulphotransferase, whose activity was much lower in purified myelin. On the other hand, glucosyl transferase had a relatively low specific activity in all three myelin fractions. Analysis of different markers showed that the activities were considerably higher than those expected from the maximum microsomal contamination calculated. (3) Subfractionation of the microsomes demonstrated that the galactosyl transferases were more concentrated in the lower parts of the gradient, containing vesicles with attached ribosomes. Cerebroside sulphotransferase and glucosyl transferase were found predominantly in the upper and intermediate parts of the gradient, which were composed essentially of smooth-surfaced vesicles and membrane fragments. Chemical analysis of submicrosomal fractions confirmed the morphological observations.     

THE SUBCELLULAR DISTRIBUTION OF CARBONIC ANHYDRASE IN HOMOGENATES OF PERFUSED RAT BRAIN

Abstract— The distribution of carbonic anhydrase was examined in subcellular fractions of perfused rat brain and compared with those of markers for cytosol (lactic dehydrogenase), mitochondrial matrix (glutamic dehydrogenase), and mitochondrial membranes (succinic dehydrogenase). About half of the total carbonic anhydrase was found in particulate fractions, with the greatest part of this in the crude mitochondrial fraction. This fraction was separated into its components on a discontinuous sucrose gradient either as such or after isotonic mechanical disruption with a French pressure cell, and the resultant fractions were characterized by electron microscopy and by assay of marker enzymes.
Carbonic anhydrase was solubilized by mechanical disruption, but not to the same extent as lactic dehydrogenase. The highest specific activity for carbonic anhydrase was found in the myelin fraction of the gradient. A mitochondrial locus for carbonic anhydrase is unlikely, but the presence of the enzyme in synaptosomes remains in question.
Addition of soluble carbonic anhydrase did not significantly increase the activity of particulate fractions. Treatment of particulate fractions with detergent was necessary to reveal latent activity; this procedure resulted in a more than ten-fold increase in the measurable carbonic anhydrase activity of myelin fragments.     

TRIPHOSPHOINOSITIDE PHOSPHODIESTERASE IN DEVELOPING BRAIN OF THE RAT AND IN SUBCELLULAR FRACTIONS OF BRAIN

Abstract— An assay system for the measurement of triphosphoinositide phosphodiesterase in homogenates of rat brain is described. With triphosphoinositide (TPI) as substrate, and in the presence of 0·1 m -KCI and saturating amounts of diethyl ether, the activity of phosphodiesterase in myelinated brain was 400–500 μmoles of TPI hydrolysed per g wet wt. per hr. One quarter of the adult level of the enzyme was present in rat brain one day after birth, with the remainder being added prior to and during the early stages of myelination. On subfractionation of brain homogenates, substantial activity of the enzyme was located in the soluble portion and in the paniculate fractions enriched in myelin and synaptosomes. The enzyme associated with the particulate fractions could not be detached from the membranes by any of several methods employed. There was a rough correlation between distribution of phosphodiesterase and that of 5'-nucleotidase, an enzyme associated with plasma membrane in a number of tissues. Some implications of the results are discussed.     

PROPERTIES AND REGIONAL DISTRIBUTION OF HISTIDINE DECARBOXYLASE IN RAT BRAIN

—Properties of the histamine-forming enzyme in rat brain were studied, utilizing a sensitive fluorometric assay. The optimum pH was related to substrate concentration and found to be6·4 at 10^?2m -histidine; the apparent Km was about 4·10^?4m ; enzyme activity was inhibited by α-hydrazino -histidine and brocresine but was not affected by α-methyl DOPA or benzene. These different data suggest that the 'specific’histidine decarboxylase (EC 4.1.1.22)—and not the aromatic l -aminoacid decarboxylase—is involved. Determination of enzyme activity and histamine level in different areas of the rat brain revealed important regional differences, the two values being roughly parallel.     

THE SUBCELLULAR DISTRIBUTION OF β-PHENYLETHYLAMINE, p-TYRAMINE AND TRYPTAMINE IN RAT BRAIN

—The quantitative subcellular distribution of β-phenylethylamine, p-tyramine and tryptamine in rat brain was investigated using the mass spectrometric integrated ion current technique. More of the total cellular tryptamine was found to be associated with paniculate fractions than was the case for phenyiethylamine and p-tyramine but a significant amount of this tryptamine was found to be labile. Analysis of the particulate fractions indicated that each of the amines was localized predominantly in the crude P₂ pellet and that the bulk of this was associated with the synaptosomal (P₂B) fraction. Inhibition of monoamine oxidase systems with pargyline caused an increase in the level of all three amines in all fractions, but the increase was greater in the supernatant than in the combined particulate fractions. This treatment produced changes in the distribution of β-phenylethylamine and p-tyramine between the various particulate subcellular fractions but did not markedly alter the distribution of tryptamine between the same fractions.     

REGIONAL AND SUBCELLULAR DISTRIBUTION AND KINETIC PROPERTIES OF RAT BRAIN CHOLINE ACETYLTRANSFERASE–SOME FUNCTIONAL CONSIDERATIONS

The kinetic properties of soluble and membrane-bound choline acetyltransferase (ChAc) were determined as a function of homogenization media and solubilization procedure in various regions of rat brain. Treatment of homogenate and/or subcellular fractions with KCl, Triton X-100, or ether dramatically altered the apparent V_max and the degree of solubilization of the enzyme, but no fraction exhibited K_m values substantially different from 12 μM for acetyl-CoA and 200 μM for choline. On the other hand, increasing the ionic strength of the assay medium for a given fraction from 0-02 M to 0-5 M increased both V_max and K_m values for both substrates. The absolute levels and subcellular distribution of ChAc were determined in 11 brain regions to localize cholinergic cell bodies and nerve endings. Levels of ChAc varied from 139 m-units/g tissue in caudate-putamen to 5-7 m-units/g tissue in cerebellum. The fraction of ChAc activity associated with synaptosomes varied from near 75 per cent in caudate-putamen, hippocampus and cortical regions to near 20 per cent in septum, locus coeruleus area and substantia nigra area. The apparent parallel distribution of cholinergic and catecholaminergic nerve endings is discussed in terms of a hypothetical model for the pathophysiology and treatment of Parkinson's syndrome.     

THE EFFECTS OF METOPIRONE AND ADRENALECTOMY ON THE REGULATION OF THE ENZYMES MONOAMINE OXIDASE AND CATECHOL-O-METHYL TRANSFERASE IN DIFFERENT BRAIN REGIONS

Abstract— The role of glucocorticoids in the regulation of the enzymes monoamine oxidase (MAO) and catechol- O -methyltransferase (COMT) in brain regions has been studied. Glucocorticoids were blocked by Metopirone. The activities of MAO and COMT were determined in the hypophysis, hypothalamus, pineal gland and in the rest of brain. All the cerebral tissues except the pineal gland demonstrated highest MAO activity 8 h after Metopirone administration, when glucocorticoids were at the lowest level. Prolonged treatment for 10 days significantly augmented MAO activity in brain, hypophysis and hypothalamus, and COMT in the hypophysis increased by 56 per cent. The COMT activity in the rest of the brain did not change significantly with either short or prolonged administration. Complete ablation of the adrenal cortex resulted in a 167 per cent rise in MAO activity of the hypophysis. Metopirone and hydrocortisone inhibit MAO and COMT in vitro. The results suggest that glucocorticoids in the circulation of normal animals inhibit the activities of MAO and COMT. The inhibition or ablation of these hormones removes this rate-limiting control of catecholamine degradation resulting in higher activities of MAO and COMT. Metopirone, an inhibitor of MAO and COMT in vitro , acts in the opposite direction in vivo due to its inhibitory effects on corticoid biosynthesis.     

EFFECT OF TRANQUILIZERS ON REGIONAL DISTRIBUTION OF ASCORBIC ACID IN THE RAT BRAIN

—Studies were made of the effects of fluphenazine, chlorpromazine and triflupromazine on tissue concentration, liver synthesis of ascorbic acid and its distribution in different areas of the brain. All the three drugs were found to increase liver concentration and synthesis of the vitamin at 24 hr after administration of a single oral dose of the vitamin, but only fluphenazine was found to increase its concentration in the adrenals and brain; the increase in the latter case was found to vary in different regions of the brain, the olfactory lobes, hypothalamus and residual brain showing maximum increases, andthe basal ganglia, visual cortex and remaining dorsal cortex showing minimum increases. The effects were found to be reversed 72 hr after drug treatment.     

REGIONAL DISTRIBUTION OF GLUTAMIC ACID DECARBOXYLASE IN THE DEVELOPING BRAIN OF THE PYRIDOXINE-DEFICIENT RAT

—Glutamic acid decarboxylase was determined in seven brain regions: hypo-thalamus; midbrain; thalamus; corpus striatum; cerebral cortex-hippocampus; medulla-pons; and cerebellum, of suckling rats subjected to Vitamin B₆ deficiency for 2 weeks from birth; of adult rats subjected to the deficiency for 5 weeks and of their respective controls. Large regional variations in the enzyme activity were found in brains of both adult and suckling control rats. The activity of the enzyme (assayed without pyridoxal phosphate) and its saturation with endogenous cofactor were markedly reduced in all brain regions of both suckling and adult pyridoxine-deficient rats. The apoenzyme (activity assayed with pyridoxal phosphate), in adult rat brain, showed no change with the deficiency in all regions except in the cerebellum where it increased slightly. In pyridoxine-deficient suckling rat brain, the apoenzyme increased substantially in all regions suggesting a process of enzyme induction. The increase in apoenzyme varied from region to region.     

REGIONAL DISTRIBUTION AND RATE OF PRODUCTION OF FREE FATTY ACIDS IN RAT BRAIN

Abstract— We have found the levels of free fatty acids (FFA) in rat brain to be much lower than had been previously supposed.
An unusually rapid and linear production of FFA occurred in brains of adult rats during the period from 30 s to 4 min after decapitation. Under the same conditions the production of FFA in the brain of the newborn rat or in the liver or spleen of the adult rat was much slower. The major sources of the FFA produced in the brain of the adult rat under these conditions were lipids other than triglycerides. FFA, like norepinephrine, occurred in much higher concentration in the hypothalamic region and the brain stem than in the remainder of the brain.
We have proposed a hypothesis suggesting that norepinephrine might regulate membrane-associated processes in the central nervous system by stimulating the enzymic splitting of the polar lipids of neuronal membranes. This action of norepinephrine might be mediated by adenosine 3',5'-phosphate in a manner analogous to that by which norepinephrine stimulates the enzymic splitting of triglycerides in adipose tissue.
Liquid nitrogen and Freon-12 have been compared for their respective efficacies in the rapid freezing of rat brain in situ.     

不饱和脂肪酸在牛、大鼠脑亚细胞组分中分布的比较

采用密度梯度离心等方法,从牛和大鼠脑组织中分别分离得到髓磷脂（A）、突触囊（B）、轻突触体（C）、重突触体（D）、线粒体（E）和微粒体（F）六个亚细胞组分。通过气相色谱－质谱联用手段和内标法测定了不饱和脂肪酸在各个亚细胞组分中的含量,结果表明牛和大鼠脑不饱和脂肪酸的亚细胞分布存在明显的差异。这种差异可能与动物种属、动物生活习惯等因素有关。     

SUBCELLULAR DISTRIBUTION OF 5-HYDROXYTRYPTAMINE IN RAT BRAIN DURING DEVELOPMENT: EFFECT OF DRUGS AND FASTING

Abstract— Distribution of brain 5-HT content between the high-speed supernatant and particulate fractions under normal and experimental conditions was studied in postnatal and adult rats. In adult and 35-day-old rats the 5-HT content of the supernatant fraction was about 25% of that of the total homogenate and significantly higher than that in 1, 7 and 21-day-old rats. In 1-day-old rats fasting caused an increase of 100% in the turnover, 50% in the content and no alteration in the subcellular distribution of brain 5-HT, which suggests that under normal conditions 5-HT stores may be filled near to capacity. After 5-hydroxytryptophan administration, the 5-HT content of the adult rat brain increased 3-fold and that of the supernatant fraction to 35% of 5-HT content of the total homogenate. In postnatal rats, the brain 5-HT content rose to an adult level and the supernatant 5-HT percentage to a markedly higher than adult level, probably because of the known higher than adult 5-hydroxytryptophan decarboxylase activity of brain capillaries. Administration of tranylcypromine to adult rats caused a 2.6-fold increase of brain 5-HT content and a slight increase of the supernatant 5-HT percentage. At various times after the administration of the MAO inhibitors (tranylcypromine or pargyline) and fasting to the 1-day-old rats, brain 5-HT content increased 4, 5 and 7-fold, respectively, and the supernatant 5-HT rose consistently and, as in the adult, to about 30% of the 5-HT content of the total homogenate. After pargyline following reserpine pretreatment, the 5-HT content of the adult and 1-day-old rat brain increased to 2–3 times the control level and that of the supernatant fraction to about 40% of the 5-HT content of the total homogenate. The adult values for 5-HT in the particulate fraction of the 1-day-old rats after the drug treatments are in sharp contradiction to the low endogenous 5-HT content and known lack of nerve terminals and synaptic vesicles in their brains, and suggest that after MAO inhibition brain 5-HT neurons may bind the amine by some other mechanism than the Mg²⁺-ATP-dependent, reserpine-sensitive granular storage.