Sialidase activity in mouse neuroblastoma cell lines

Sialidase activity was determined for three different neuroblastoma clonal lines derived from the A/J strain mouse C1300 neuroblastoma line. For each cell line, the endogenous and exogenous activities were less than 1 nmol sialic acid released/mg protein/90 min and 50 min reaction time, respectively. The C1300 tumor had similarly low levels of sialidase activity. The sialidase activity associated with the neuroblastomas is less than that associated with synaptosomes. Each cell line had a distinctly different ganglioside pattern varying in complexity from G_M3 to G_D1a. Treatment of the cells withVibrio cholerae sialidase under isosmotic conditions showed that cell-surface sialyl residues were susceptible to sialidase activity, with some of the susceptible residues coming from the ganglioside constituents. Of the total number ofV. cholerae sialidase-releasable sialyl residues, 50–60% were released by the neuroblastoma sialidase acting on endogenous substrate.     

The biosynthesis of brain gangliosides. Ganglioside-glycosylating activity in rat brain neuronal perikarya fraction.

Rat brain homogenate and the synaptosmal and neuronal perikarya fractions from 17-day-old rats were compared for their activities in sialosylating endogenous gangliosides and transferring N-acetylneuraminic acid and galactose to several glycolipids in vitro. The sialosylation of endogenous gangliosides and the activities of sialosyltransferases acting either on lactosylceramide or haematoside as acceptors, as well as galactosyltransferase acting on Tay-Sachs ganglioside as acceptor, were between 3-and 12-fold higher in the neuronal perikarya fraction than in whole homgenate on a protein or ganglioside basis. The activities found in the synaptosomal fraction were negligible. No evidence was found to indicate that the low activities in this fraction were due to the presence of inhibitors of the transfer activities or to inacessibility of the substrates to their respective enzymes. These findings, and the time course of labelling of gangliosides of the neuronal perikarya and synaptosomes from rats that received an injection of N-[3H]acetylmannosamine, indicate that the main cellular site of glycosylation of neuronal gangliosides is in the neuronal perikarya.     

GANGLIOSIDE COMPOSITION AND CONTENT OF RAT-BRAIN SUBCELLULAR FRACTIONS

Abstract— The composition and content of gangliosides from rat-brain microsomal, synaptosomal, mitochondrial and myelin fractions were studied. Outer membranes of synaptosomes were also isolated, separated into subfractions and investigated. Of all the fractions studied the outer membranes of synaptosomes are richest in gangliosides, in one of their sub-fractions the concentration of gangliosides per mg of protein is five times higher than in the homogenate. Microsomes are rich in gangliosides as well, but to a lesser degree, whereas the mitochondrial fraction contains considerably smaller amounts of gangliosides per mg of protein than does the homogenate. The ganglioside pattern of outer membranes of synaptosomes and of their subfractions is somewhat different from that of the homogenate; the outer membranes contain approximately one-third less monosialogangliosides. On the contrary a very high content of monosialogangliosides is characteristic of the ganglioside pattern of the myelin fraction. In this fraction monosialoganglioside G_MI (nomenclature of Svennerholm, 1963) constitutes 60–63 per cent of ganglioside sialic acid, or 75–80 molar per cent of gangliosides, the content of di- and trisialogangliosides being much lower than in other fractions. Fatty acid and long chain base composition of gangliosides from synaptosomal and microsomal fractions and homogenate is very similar, almost identical. In gangliosides from myelin fractions the relaitve content of palmitic and monoenoic acids is higher and that of arachinic acid and C₂₀-sphingosine—lower than in other fractions studied. The difference in ganglioside composition of synaptosomes and their outer membranes and on the other hand of myelin appears to reflect the difference in ganglioside composition of neuronal and oligodendroglial plasma membranes.     

Sialidase activity in normal and atherosclerotic human aortic intima

Sialidase activity has been determined in homogenates of human aortic intima by measuring the amount of GM1 formed during the incubation of ganglioside GD1a with the tissue homogenates. Areas with atherosclerotic lesions as well as adjacent areas without histological evidence of atherosclerosis were taken for comparison. The rate of GM1 formation from GD1a in the presence of homogenates of the atherosclerotic intima was 20 pmol/h per mg protein. Homogenates of the unaffected intima did not desialylate GD1a. Sialidase activity of the atherosclerotic intima was linear for 1.5 h at GD1a content up to 1.5 nmol and at homogenate protein up to 1 g. NH₄Cl and NeuAc2en, inhibitors of lysosomal function and plasma membrane-bound sialidase, respectively, reduced sialidase activity of homogenates of the atherosclerotic intima by 94%. The results indicate that atherosclerotic lesions and unaffected intima differ in their activity and specificity of sialidases that cleave gangliosides.     

A radiometric assay for ganglioside sialidase applied to the determination of the enzyme subcellular location in cultured human fibroblasts

A radiometric method for the assay of ganglioside sialidase in cultured human fibroblasts was set up. As substrate, highly radioactive (1.28 Ci/mmol) ganglioside GDla isotopically tritium-labeled at carbon C-3 of the long chain base was employed; the liberated, and TLC separated [3H]GM1 was determined by computer-assisted radiochromatoscanning. Under experimental conditions that provided a low and quite acceptable (4-5%) coefficient of variation, the detection limit of the method was 0.1 nmol of liberated GM1, using as low as 10 micrograms of fibroblast homogenate as protein. The detection limit could be lowered to 0.02-0.03 nmol, adopting conditions that, however, carried a higher analytical error (coefficient of variation over 10%). The content of ganglioside sialidase in human fibroblasts cultured in 75-cm2 plastic flasks was 5.8 +/- 2.5 (SD) nmol liberated GM1 h-1 mg protein-1. Subfractionation studies performed on fibroblast homogenate showed that the ganglioside sialidase was mainly associated with the light membrane subfraction that was rich in plasma and intracellular membranes. This subfraction displayed almost no sialidase activity on the artificial substrate 4-methylumbelliferyl-D-N-acetylneuraminic acid. A small but measurable ganglioside sialidase activity was also present in the lysosome-enriched subfraction, which contained a very high sialidase activity on the above artificial substrate. All this supports the hypothesis that human fibroblasts contain sialidases with different subcellular location and substrate specificity. Particularly, the sialidase acting on gangliosides seems to have two sites of subcellular location, a major one at the level of plasma membranes and/or intracellular organelles functionally related with the plasma membranes and a minor one in the lysosomes.     

SUBCELLULAR FRACTIONATION OF GANGLIOSIDE SIALIDASE FROM HUMAN BRAIN

—A subcellular fractionation was performed on forebrain cortex from three human brains and the fractions obtained were assayed for ganglioside sialidase and four p-nitrophenyl glycohydrolases. Differences in the sedimentation patterns of the enzymes were observed. From 53 to 77 per cent of the recovered sialidase activity was found in the synaptosomal fraction, while the p-nitrophenyl glycosidases were mainly recovered in the lysosome-enriched fraction. Three possible interpretations of the sialidase sedimentation pattern are suggested: (1) The ganglioside sialidase is bound to the limiting membrane structure of the nerve ending. (2) The ganglioside sialidase is lysosomal, although bound to lysosomes of low density. (3) The enzyme occurs mainly in lysosomes primarily located in the nerve endings, being trapped under the formation of the synaptosomes.     

ATP citrate lyase in cholinergic nerve endings

The activity of ATP-citrate lyase in homogenates of five selected rat brain regions varied from 2.93 to 6.90 nmol/min/mg of protein in the following order: cerebellum < hippocampus < parietal cortex < striatum < medulla oblongata and that of the choline acetyltransferase from 0.15 to 2.08 nmol/min/mg of protein in cerebellum < parietal cortex < hippocampus=medulla oblongata < striatum. No substantial differences were found in regional activities of lactate dehydrogenase, pyruvate dehydrogenase, citrate synthase or acetyl-CoA synthase. High values of relative specific activities for both choline acetyltransferase and ATP-citrate lyase were found in synaptosomal and synaptoplasmic fractions from regions with a high content of cholinergic nerve endings. There are significant correlations between these two enzyme activities in general cytocol (S₃), synaptosomal (B) and synaptoplasmic (B_s) fractions from the different regions (r=0.92–0.99). These data indicate that activity of ATP-citrate lyase in cholinergic neurons is several times higher than that present in glial and noncholinergic neuronal cells.     

Subcellular distribution of carbonic anhydrase and Na+,K+-ATPase in the brain of the hyt/hyt hypothyroid mice

Activities of carbonic anhydrase and Na⁺,K⁺-ATPase in tissue homogenates and in subcellular fractions from different brain regions were studied in inherited primary hypothyroid (hyt/hyt) mice. The body weight, the weight of different brain regions, and the plasma thyroxine and triiodothyronine levels of hyt/hyt mice were significantly lower than those of the age-matched hyt/+ controls. In tissue homogenates of cerebral cortex, brain stem and cerebellum of hypothyroid mice, the activity of carbonic anhydrase (units/mg protein) was 59.2, 57.6, and 43.2%, and the activity of Na⁺,K⁺-ATPase (nmol Pi/mg protein/min) was 73.7, 74.4 and 68.7%, respectively, of that in corresponding regions of euthyroid littermates. The decrease in enzyme activity in tissue homogenates was also reflected in different subcellular fractions. In cerebral cortex and brain stem, carbonic anhydrase activity in cytosol, myelin and mitochondrial fractions of hypothyroid mice was about 45–50% of that in euthyroid mice, while in cerebellum the carbonic anhydrase activity in these subcellular fractions of hyt/hyt mice was only 33–38% of that in hyt/+ controls. Na⁺,K⁺-ATPase activity in myelin fraction of different brain regions of hyt/hyt mice was about 34–42% of that in hyt/+ mice, while in mitochondria, synaptosome and microsome fractions were about 44–52, 46–53, and 66–68%, respectively of controls. These data indicate that the activity of both carbonic anhydrase and Na⁺,K⁺-ATPase was affected more in the myelin than other subcellular fractions and more in the cerebellum than cerebral cortex and brain stem by deficiency of thyroid hormones. A reduction in the activity of transport enzymes in brain tissues as a result of thyroid hormone deficiency during the critical period of development may underlie permanent nervous disorders in primary hypothyroidism.     

Uptake and metabolism of glutamate and aspartate by astroglial and neuronal preparations of rat cerebellum

Astrocytes, neuronal perikarya and synaptosomes were prepared from rat cerebellum. Kinetics of high and low affinity uptake systems of glutamate and aspartate, nominal rates of¹⁴CO₂ production from [U–¹⁴C]glutamate, [U–¹⁴C]aspartate and [1–¹⁴C]glutamate and activities of enzymes of glutamate metabolism were studied in these preparations. The rate of uptake and the nomial rate of production of¹⁴CO₂ from these amino acids was higher in the astroglia than neuronal perikarya and synaptosomes. Activities of glutamine synthetase and glutamate dehydrogenase were higher in astrocytes than in neuronal perikarya and synaptosomes. Activities of glutaminase and glutamic acid decarboxylase were observed to be highest in neuronal perikarya and synaptosomes respectively. These results are in agreement with the postulates of theory of metabolic compartmentation of glutamate while others (presence of glutaminase in astrocytes and glutamine synthetase in synaptosomes) are not. Results of this study also indicated that (i) at high extracellular concentrations, glutamate/aspartate uptake may be predominantly into astrocytes while at low extracellular concentrations, it would be into neurons (ii) production of -ketoglutarate from glutamate is chiefly by way of transamination but not by oxidative deamination in these three preparations and (iii) there are topographical differences glutamate metabolism within the neurons.     

The effect of cold stress on ganglioside fatty acid composition and ganglioside-bound sialic acid content of rat brain subcellular fractions

The effect of cold stress on the ganglioside fatty acid composition and sialic acid content of brain subcellular fractions and homogenate of rats was studied, the animals were kept in a cold room with 12h light-dark cycles at 3 and 10 degrees C for 2 weeks. (1) The rat brain homogenate, synaptosomes and myelin of rats exposed to 3 degrees C contained significantly higher amounts of ganglioside-bound sialic acid per mg of protein than these fractions of control rats kept at 23 degrees C; the differences were less pronounced in rats exposed to 10 degrees C. (2) A small, but significant, diminution of relative palmitic acid content and an increase of stearic acid content was found to take place in gangliosides from rat brain synaptosomes, synaptosomal plasma membranes and homogenate as a result of the exposure of animals to 3 degrees C and to a lesser extent to 10 degrees C. (3) The content of unsaturated fatty acids in gangliosides from brain subcellular fractions was approximately the same in cold exposed and control rats.     

Thiamine, thiamine phosphates and thiamine metabolizing enzymes in synaptosomes of rat brain

Thiamine and thiamine mono-, pyro- and triphosphate were found at detectable levels in synaptosomes isolated from whole rat brain. Synaptosomes prepared from whole brain, cerebellum and medulla were also found to contain uridine and inosine mono- and diphosphatases as well as the thiamine pyrophosphate synthetizing and hydrolyzing enzymes, but no thiamine monophosphatase. By isoelectric focusing on thin layer polyacrylamide gel of Triton X-100 homogenates of synaptosomes, thiamine pyrophosphatase activity could be separated into 10 bands with different isoelectric points. The contents of thiamine compounds and enzymes in synaptosomes were generally lower than those found in neuronal cell bodies.     

Studies on lithium transport across the red cell membrane

Summary Binding of³H-saxitoxin to Na⁺ channels was studied in subcellular fractions prepared from rat brain homogenates. Saxitoxin binding to synaptosomes was saturable with an apparent dissociation constant of about 1nm; about 1 pmol/mg protein was bound at saturating saxitoxin concentrations. A linear, nonsaturable component of saxitoxin binding accounted for less than 3% of the total binding at 30nm. Saxitoxin binding to synaptosomes was unaffected by depolarization with elevated K⁺ concentrations, or by activation of the Na⁺ channels with batrachotoxin plus a purified polypeptide toxin from the scorpionLeiurus quinquestriatus. A procedure is described for preparing a membrane fraction that contains 70–80% of the total saxitoxin binding activity of the crude homogenate. The specific activity of this fraction was about 4 to 6 pmol/mg protein. About 60–70% of the saxitoxin binding sites were solubilized by incubating these membranes with the nonionic detergent Triton X-100; the detergent-solubilized binding sites eluted at a position corresponding to a mol wt of about 700,000 on gel filtration chromatography. Both membrane-bound and solubilized saxitoxin binding were assayed by a new cation exchange column method. The binding of saxitoxin to both membrane-bound and detergent-solubilized binding sites was saturable with an apparent dissociation constant of about 2nm. Dissociation of the saxitoxin-receptor complex followed a single exponential decay with a rate constant at 0° of 0.1 min^–1 for membrane bound and 0.2 min^–1 for detergent-solubilized binding sites. The measured association rate constant was 6×10⁸ m ^–1 min^–1 at 0° for membrane-bound saxitoxin binding sites.     

Ganglioside GM3 sialidase activity in fibroblasts of normal individuals and of patients with sialidosis and mucolipidosis IV. Subcellular distribution and and some properties.

Sensitive assays for the determination of the ganglioside sialidase activity of fibroblast homogenates were established using ganglioside GM3, 3H-labelled in the sphingosine moiety, as a substrate. Ganglioside GM3 sialidase activity was greatly stimulated by the presence of the non-ionic detergent Triton X-100 and was further enhanced by salts such as NaCl; the optimal pH was 4.5. The subcellular localization of this activity was determined by fractionation using free-flow electrophoresis and found to be exclusively associated with the marker for the plasma membrane, but not with that for lysosomes. This Triton-stimulated ganglioside sialidase activity was selectively inhibited by preincubating intact cells in the presence of millimolar concentrations of Cu2+, suggesting that the activity resides on the external surface of the plasma membrane. In normal fibroblasts homogenates, ganglioside GM3 sialidase was also greatly stimulated by sodium cholate. In contrast to the Triton X-100-activated reaction, however, it was not diminished by prior incubation of intact cells in the presence of Cu2+. Only after cell lysis was Cu2+ inhibitory. the cholate-stimulated ganglioside sialidase activity thus paralleled the behaviour of the lysosomal 4-methylumbelliferyl-alpha-D-N-acetylneuraminic acid (4-MU-NeuAc) sialidase. In fibroblasts from sialidosis patients, the cholate-stimulated ganglioside GM3 sialidase activity, but not that of the Triton-activated enzyme, was profoundly diminished. In fibroblasts from patients with mucolipidosis IV (ML IV), both the Triton X-100- and the cholate-stimulated ganglioside GM3 sialidase activities were in the range of normal controls. The Triton-activated enzyme was associated with the plasma membrane in the same manner as in normal cells. Our findings suggest that, in human fibroblasts, there exist two sialidases that degrade ganglioside GM3: one on the external surface of the plasma membrane, and another that is localized in lysosomes and seems identical with the activity that acts on sialyloligosaccharides and 4-MU-NeuAc. As neither activity was found to be deficient in ML IV fibroblasts, our results argue against the hypothesis of a primary involvement of a ganglioside GM3 sialidase in the pathogenesis of ML IV.     

The plasma membrane ganglioside sialidase cofractionates with markers of lipid rafts

Gangliosides of the plasma membrane are important modulators of cellular functions. Recent reports have shown their enrichment in glycosphingolipid-containing membrane microdomains, called glycosphingolipid-signaling domain or rafts, which can be isolated due to their insolubility in Triton X-100 and flotation through a sucrose gradient. In previous work on neuroblastoma cells we had found that a ganglioside-specific sialidase activity of the plasma membrane controlled proliferation and differentiation through selective ganglioside desialylation. Assuming the ganglioside sialidase to be close to its substrates in the membrane, we investigated its association with detergent-insoluble microdomains in the neuroblastoma cell line SK-N-MC. The results show that the ganglioside sialidase codistributes with the raft markers ganglioside GM1, flotillin, src family kinases, and glycosylphosphatidylinositol-anchored proteins in a fraction containing about 2% of cellular protein. The association of the ganglioside sialidase with glycosphingolipid-enriched membrane fractions therefore is in support of a role of this glycosidase in ganglioside-dependent signaling processes.     

Isolation of astrocytes,neurons, and synaptosomes of rat brain cortex

A simplified method was developed for the bulk separation of neuronal perikarya and astroglial celis from adult rat brain without the involvement of density gradients. Activities of various enzymes involved in glutamate metabolism were estimated and compared with those of synaptosomes. The activities of glutamate dehydrogenase and aspartate aminotransferase were higher in synaptosomes than in neuronal perikarya or glia. Glutamine synthetase was distributed in all the three fractions while glutaminase activity was higher in astrocytes than in synaptosomes and was not detectable in neuronal perikarya. The significance of these results in relation to metabolic compartmentation was discussed.     

Proteomic comparison of different synaptosome preparation procedures

Synaptosomes are frequently used research objects in neurobiology studies focusing on synaptic transmission as they mimic several aspects of the physiological synaptic functions. They contain the whole apparatus for neurotransmission, the presynaptic nerve ending with synaptic vesicles, synaptic mitochondria and often a segment of the postsynaptic membrane along with the postsynaptic density is attached to its outer surface. As being artificial functional organelles, synaptosomes are viable for several hours, retain their activity, membrane potential, and capable to store, release, and reuptake neurotransmitters. Synaptosomes are ideal subjects for proteomic analysis. The recently available separation and protein detection techniques can cope with the reduced complexity of the organelle and enable the simultaneous qualitative and quantitative analysis of thousands of proteins shaping the structural and functional characteristics of the synapse. Synaptosomes are formed during the homogenization of nervous tissue in the isoosmotic milieu and can be isolated from the homogenate by various approaches. Each enrichment method has its own benefits and drawbacks and there is not a single method that is optimal for all research purposes. For a proper proteomic experiment, it is desirable to preserve the native synaptic structure during the isolation procedure and keep the degree of contamination from other organelles or cell types as low as possible. In this article, we examined five synaptosome isolation methods from a proteomic point of view by the means of electron microscopy, Western blot, and liquid chromatography-mass spectrometry to compare their efficiency in the isolation of synaptosomes and depletion of contaminating subcellular structures. In our study, the different isolation procedures led to a largely overlapping pool of proteins with a fairly similar distribution of presynaptic, active zone, synaptic vesicle, and postsynaptic proteins; however, discrete differences were noticeable in individual postsynaptic proteins and in the number of identified transmembrane proteins. Much pronounced variance was observed in the degree of contamination with mitochondrial and glial structures. Therefore, we suggest that in selecting the appropriate isolation method for any neuroproteomics experiment carried out on synaptosomes, the degree and sort/source of contamination should be considered as a primary aspect.

     

Asparagine and glutamine metabolism in Rhodopseudomonas acidophila

Rhodopseudomonas acidophila strain 7050 achieved balanced growth when provided with either asparagine or glutamine as nitrogen source. Under these growth conditions R. acidophila synthesized a mixed amidase which exhibited similar activity (223–422 nmol/min·mg protein) against either nitrogen source. Determination of the free intracellular amino acid pools show that deamidation of asparagine and glutamine resulted in elevated levels of both aspartate and glutamate. Cell-free extracts of R. acidophila showed significant aminotransferase activity, particulary glutamine-oxaloacetate aminotransferase (89.7–209.3 nmol/min·mg protein), glycine oxaloacetate aminotransferase (135–227 nmol/min ·mg protein), alanine glyoxylate aminotransferase (66.3–163.2 nmol/min·mg protein) and serineglyoxylate aminotransferase (57.1–68.4 nmol/min ·mg protein). Short term labelling experiments using ¹⁴C-glyoxylate show that glycine plays an important role in amino nitrogen transfer in R. acidophila and that the enzymes for the metabolism of glyoxylate via glycine, serine and hydroxypyruvate were present in cell-free extracts. These data confirm that R. acidophila can satisfy all its' nitrogen requirements by transamination.Abbreviations GDH glutamate dehydrogenase - GS glutamine synthetase - GOGAT glutamate synthase - MSO methionine sulfoximine - GOT glutamate—oxaloacetate aminotransferase - GPT glutamate-pyruvate aminotransferase - AGAT alanineglyoxylate aminotransferase - GOAT glycine-oxaloacetate aminotransferase - GOGAT glycine-2-oxoglutarate aminotransferase - AOAT alanine-oxaloacetate aminotransferase - SGAT serineglyoxylate aminotransferase - INH isonicotinylhydrazide     

Effects of chronic ethanol administration on the activities and relative synthetic rates of myelin and synaptosomal plasma membrane-associated sialidase in the rat brain

In an attempt to understand the possible mechanism of chronic ethanol-induced generation of asialoconjugates in the brain and consequent behavioral abnormalities, we have studied the effects of chronic ethanol feeding to rats on the plasma membrane sialidase status in the various subcellular fractions of the brain. We determined sialidase activity using 3H-monosialoganglioside (3H-GM3), 2'-(4-methylumbelliferyl)-alpha-D-N-acetylneuraminic acid (4-MU-NeuAC) substrates and Amplex Red (Sialidase) kit. We determined the plasma membrane sialidase protein by Western blot using the anti-plasma membrane sialidase. We also determined its relative synthetic rate (RSR) by the 60 min incorporation of intracranially infused [35S]-methionine (50 microCi/100 g) into immunoprecipitable plasma membrane sialidase. Chronic ethanol administration stimulated the sialidase activity in the total brain homogenate as well as the myelin and synaptosomal membrane fractions, respectively, in all the three experimental models. Chronic ethanol also increased the concentration of the rat brain plasma membrane sialidase protein relative to that of glyceraldehyde-3-phosphate dehydrogenase by 2.4-, 1.62- and 1.51-fold in the total brain homogenate, myelin and synaptosomal membrane fractions, respectively. These increases in plasma membrane sialidase activity and its protein content were due to concomitant increases in their relative synthetic rates by 115% (p < 0.01) and 72% (p < 0.01) in the myelin and synaptosomal membrane fractions, respectively. Thus, our studies clearly show that chronic ethanol induced deglycosylation of brain gangliosides is in part, due to specific up-regulation of plasma membrane sialidase in the myelin and synaptosomal membrane fractions of the brain. This increase in plasma membrane sialidase may be responsible for chronic-ethanol-induced physiological and neurological impairment in the brain, presumably due to deglycosylation of gangliosides that are essential for crucial cellular and metabolic activities.     

Acetyl-coenzyme A hydrolase,an artifact? The conversion of acetyl-coenzyme A into acetate by the combined action of carnitine acetyltransferase and acetylcarnitine hydrolase

1. The nature of the acetyl-CoA hydrolase (EC 3.1.2.1) reaction in rat and sheep liver homogenates was investigated. 2. The activity determined in an incubated system was 5.10 and 3.28nmol/min per mg of protein for rat and sheep liver homogenate respectively. This activity was not affected by the addition of l-carnitine, but was decreased by the addition of d-carnitine. 3. No acetyl-CoA hydrolase activity could be detected in rat or sheep liver homogenates first treated with Sephadex G-25. This treatment decreased the carnitine concentrations of the homogenates to about one-twentieth. Subsequent addition of l-carnitine, but not d-carnitine, restored the apparent acetyl-CoA hydrolase activity. 4. Sephadex treatment did not affect acetyl-carnitine hydrolase activity of the homogenates, which was 5.8 and 8.1nmol/min per mg of protein respectively for rat and sheep liver. 5. Direct spectrophotometric assay of acetyl-CoA hydrolase, based on the reaction of CoA released with 5,5'-dithiobis-(2-nitrobenzoic acid), clearly demonstrated that after Sephadex treatment no activity could be measured. 6. Carnitine acetyltransferase (EC 2.3.1.7) activity measured in the same assay system in response to added l-carnitine was very low in normal rat liver homogenates, owing to the apparent high acetyl-CoA hydrolase activity, but was increased markedly after Sephadex treatment. The V(max.) for this enzyme in rat liver homogenates was increased from 3.4 to 14.8nmol/min per mg of protein whereas the K(m) for l-carnitine was decreased from 936 to 32mum after Sephadex treatment. 7. Acetyl-CoA hydrolase activity could be demonstrated in disrupted rat liver mitochondria but not in separated outer or inner mitochondrial membrane fractions. Activity could be demonstrated after recombination of outer and inner mitochondrial membrane fractions. The outer mitochondrial membrane fraction showed acetylcarnitine hydrolase activity and the inner mitochondrial membrane fraction showed carnitine acetyltransferase activity. 8. The results presented here demonstrate that acetyl-CoA hydrolase activity in rat and sheep liver is an artifact and the activity is due to the combined activity of carnitine acetyltransferase and acetylcarnitine hydrolase.     

NEURONAL AND GLIAL SYSTEMS FOR γ-AMINOBUTYRIC ACID METABOLISM

—Bulk prepared neuronal perikarya, nerve endings and glial cells have been used to study amino acid concentrations and GABA metabolism in vitro. All amino acids were more concentrated in synaptosomes and glial cells than in neuronal perikarya. Cell specificity was found with respect to the relative distribution of some amino acids. Glutamate decarboxylase activity was considerably higher in synaptosomes than in glial cells. The inhibitory effect of amino-oxyacetic acid on glutamate decarboxylase activity differed between synaptosomes and glial cells. γ-Aminobutyric acid-α-ketoglutarate transaminase had the highest activity in the glial cell fraction; the inhibition of amino-oxyacetic acid differed between glial and neuronal material. The metabolism of exogenous GABA just accumulated by a cell showed similar time characteristics in neuronal and glial material.