MOLECULAR PROPERTIES OF CHOLINE ACETYLTRANSFERASE FROM DIFFERENT SPECIES INVESTIGATED BY ISOELECTRIC FOCUSING AND ION EXCHANGE ADSORPTION

—The isoelectric point, surface charge and K_m for choline of choline acetyltransferase from different species were determined. Choline acetyltransferase from mouse and monkey brain was resolved into three molecular forms with isoelectric points at 7·1, 7·5, 8·4 and 7·0, 7·35, 8·35 respectively, whereas choline acetyltransferase from the electric organ of Torpedo and from rabbit brain showed a molecular form with isoelectric point 6·6 and 6·9, respectively. With the exception of rabbit brain enzyme, there was a good correlation between the isoelectric points and surface charges of the different choline acetyltransferases. The K_m's for choline were 0·66, 0·88, 0·92 and 3·5 mM for monkey, mouse, rabbit and Torpedo choline acetyltransferase respectively. The separated molecular forms of mouse and monkey enzymes did not show any significant difference in their affinity for choline.     

DETERMINATION OF BRAIN-SPECIFIC ANTIGENS IN SHORT TERM CULTIVATED RAT ASTROGLIAL CELLS AND IN RAT SYNAPTOSOMES

—The brain-specific antigens 14·3·2, GFA, A5, F3, D1, D2, D3 and C1 were quantitated in a short-term astroglial cell culture taken as a model of glial cells, and in synaptosomes, synaptosomal membranes and synaptic vesicles as neuronal material. Furthermore, the antigens were quantitated in newborn rat brain, as this served as the starting material for the cell culture. The membrane antigens C1, D1, D2 and D3 were absent from the cultured astroglia, indicating a neuronal origin for these antigens. C1 was enriched 3-fold in synaptosomes and synaptosomal membranes and more than 10-fold in synaptic vesicles indicating that this antigen might be a marker protein for nerve endings. The name Synaptin is introduced for this antigen. Conversely, the data on the antigens D1, D2 and D3 indicated that these antigens were not restricted to the synaptosomes although they were of neuronal origin. Trace amounts of the cathodal part of the heterogeneous cytoplasmic antigen 14·3·2 were present in the cell culture, possibly originating from a few contaminating neurons. The cytoplasmic antigens A5 and F3 were found both in the astroglial culture and in the synaptosomal fraction. F3, however, was found in low concentration in the synaptosomes and 3-fold enriched in newborn rat brain compared to rat brain from 35-day-old rats or to 21-day-old brain cell cultures. It was therefore regarded as a brain specific fetal antigen. The antigen GFA was highly enriched in the astroglial culture compared to whole brain and only trace amounts were found in the synaptosomal fraction supporting the astroglial origin of this antigen.     

Immunological,isoelectric, hydrophobic and molecular weight differences between soluble and ionically membrane-bound fractions of choline-o-acetyltransferase prepared from mouse and rat brain

Choline-O-acetyltransferase (EC 2.3.1.6; ChAT) was prepared from synaptosomal fractions (P₂) of mouse and rat brain in the presence of proteolytic inhibitors by the method of Gray and Whittaker (1962) as modified by (Salehmoghaddam and Collier, 1976). The P₂ fraction was hypo-osmotically shocked with glass distilled water and centrifuged to separate the cytoplasmic (S₃) and vesicle-bound (P₃) fractions. Fraction S₃ was saved for ChAT assay and compared with the ChAT fraction eluted from the P₃ by salt at a pH 7.4 or by detergent (Benishin and Carroll, 1983). These three fractions of ChAT were then compared by molecular weights, isoelectric points, immunoblotting with monoclonal or polyclonal antibodies and hydrophobicity. The results show that the S₃ fraction of ChAT has a molecular weight of 66 K_d, whereas the ionically-bound fraction of ChAT has a molecular weight of 73–78 K_d. SDS-PAGE of these two ChAT fractions followed by immunoblotting revealed the presence of two immunoreactive bands at 28–29 K_d and 50–51 K_d for the ionically bound ChAT fraction. Conversely, none of these antibodies immunostained any protein bands for the S₃ ChAT fraction even though one monoclonal antibody had been prepared against this ChAT fraction and the S₃ ChAT fraction had a similar specific activity prior to SDS-PAGE as did the salt solubilized ChAT fraction. However, anti-ChAT monoclonal antibody MB16 binds the native S₃ ChAT fraction in the co-precipitation assay.The S₃ fraction of ChAT had only one isoelectric point at pH 7.8, whereas the ionically bound and detergent soluble ChAT fractions had two isoelectric points at pH 8.1–8.15 and 7.45–7.5. The S₃ ChAT fraction also differed in hydrophobicity from the other two ChAT fractions. These differences between the S₃ and salt soluble ChAT fractions were not obviated by addition of Triton X-100 and thus could not be attributed to the association of lipids with either of the fractions. We conclude that the water soluble fraction of ChAT in central nerve terminals differs in its physical properties and its subcellular location from that which ionically binds to membranes.     

SODIUM-DEPENDENT EFFLUX AND EXCHANGE OF GABA IN SYNAPTOSOMES

Abstract— The influx and efflux of [³H]GABA were investigated in synaptosomes. Two efflux components were detected. The first, termed spontaneous efflux, was not affected by the external sodium chloride concentration. The second, termed GABA-stimulated efflux, was observed when low levels of GABA were added to the incubation medium and was found to require external sodium chloride. The rate of spontaneous efflux at 0°C was about 37 per cent of the rate at 27°C but both GABA-stimulated efflux and GABA influx were completely inhibited at 0°C. The stimulation of efflux by external GABA followed simple Michaelis–Menten kinetics with respect to external GABA. The concentration of external GABA required for half-maximal stimulation was 4·9 ± 1·4 μm and the V_max for efflux was 1·0 ± 0·6 nmol. min^-1.mg^-1 of protein. A similar stimulation of efflux was observed with GABA analogue l -2,4-diamino-butyric acid which is a competitive inhibitor of influx. The concentration of external l -2,4-diaminobutyric acid required for half-maximal stimulation of efflux was 51 ± 12 μm and the V_max for efflux was 0·8 ± 0·5 nmol.min^-1.mg^-1 of protein. Since the sodium-dependency, temperature sensitivity, and kinetic properties of the GABA-stimulated efflux system were similar to the influx system, GABA-stimulated efflux was attributed to carrier-mediated exchange diffusion. Measurement of efflux and influx in the same preparation showed there was a net efflux when total fluxes were considered and that the exchange ratio (influx to GABA-stimulated efflux) was 0·9 when carrier-mediated fluxes were considered. The effect of the temperature of the fluid used to rinse synaptosomes collected on filters in influx experiments was investigated. There was no detectable difference in measured values of influx between samples rinsed with cold fluid (0°C) and warm fluid (27°C). The endogenous GABA content of synaptosomes was found to be 20·3 ± 2·5 nmol GABA per mg of protein. From this value, the cytoplasmic concentration of GABA in synaptosomes was estimated to be a maximum of 40 mm . About 5 per cent of total cerebral cortical GABA was found in the synaptosomal fraction.     

SUBCELLULAR DISTRIBUTION AND SOME PROPERTIES OF ACETYL-COENZYME A HYDROLASE IN THE BRAIN

—The detailed subcellular distribution and some properties of acetyl-CoA hydrolase were studied in the rat brain. The brain homogenate (S₁) hydrolysed acetyl-CoA at a rate of approx 2·3 nmol/min/mg of protein at 37°C. The total activity of acetyl-CoA hydrolase was distributed in the following order: soluble > mitochondrial > microsomal, synaptosomal > myelin fraction. The order of the specific activity of the enzyme was: soluble, microsomal > mitochondrial > synaptosomal > myelin fraction. The synaptic vesicle fraction (D) had relatively high specific activity among the intraterminal particulate fractions, having two or three times higher specific activity than that of the synaptic cytoplasmic membrane fraction (F or G). Attempts to de-occlude acetyl-CoA hydrolase in the particulate fraction showed that only the enzyme activity in the myelin fraction was increased markedly by the treatment with ether or Triton X-100. Lineweaver-Burk plots gave straight lines for each subcellular fraction and apparent K_m values for acetyl-CoA were between 0·1 and 0·2 mM. Neither diisopropyl fluorophosphate nor physostigmine at the concentration of 0·1 mm inhibited the enzyme activity.     

DETERMINATION OF MONOAMINE OXIDASE IN RAT BRAIN BY ELECTRON SPIN RESONANCE TECHNIQUES

—The recent development of spin-labeling techniques has permitted its application to the measurement of the concentration of rat brain mitochondrial monoamine oxidase (MAO) and detection of possible multiple forms of this enzyme. Spin-labeled p-hydroxyamphetamine (SHA) was used as a probe of the active site of the enzyme. The binding of SHA to MAO was monitored by measuring the intensity of the × band ESR spectra obtained with a Varian V-4502 ESR spectrometer. The measured volume of each sample was about 0·02 ml and time required for each measurement was 5 min. In the presence of MAO, a linear relationship was observed between spectral intensity and the concentration of the spin-label in a range of 4 × 10^?6m to 10^?3m . A plot of the amount of enzyme-inhibitor complex formed against the concentration of SHA suggested the existence of at least three different affinities of SHA to the possible multiple forms of MAO. Measurements made using a constant concentration of the spin-label (3·21 × 10^?5m ) resulted in a calibration curve with two plateaus when the concentration of the enzyme-inhibitor complex was plotted against the apparent concentration of MAO. These data also suggested that spin-labeled hydroxyamphetamine had distinctly different affinities toward the multiple forms of MAO that were present in the partially purified preparation employed. Measurements made with constant concentrations of SHA and MAO but with varying temperatures (4-56°C) resulted in a curve with two plateaus which also suggested the existence of at least three different binding affinities of the enzyme preparation for the inhibitor. This ESR technique is simple, rapid, accurate and fairly sensitive. It was also applied to the measurement of MAO in human platelets.     

Isolation of plasma membrane and binding of the Ca2+ antagonist nimodipine in Chlamydomonas reinhardtii

Chlorophyll-free plasma membranes of the unicellular green alga Chlamydomonas reinhardtii Dangeard were purified from a microsomal fraction using an aqueous polymer two-phase system of 6.5% (w/w) dextran T500, 6·5% (w/w) polyethylene glycol 3350, 60 mM NaCI, 0 33 M sucrose and 5 mM potassium phosphate (pH 7·8). The plasma membrane fraction contained only 2·4% of the microsomal membrane protein. Specific activity of the plasma membrane marker enzyme, K*, Mg²⁺-ATPase (EC 3.6.1.3). was enriched 9-fold over the microsomal fraction, and 22% of total activity was recovered in the upper, polyethylene glycol-rich phase. Contamination from intracellular membranes was minimal. K*, Mg²⁺-ATPase showed a pH optimum at about 6·5, and addition of 0·05% (w/v) Triton X-100 stimulated the activity 3-fold. [³H]-Nimodipinc was employed to characterize 1,4-dihydropyridine-specific membrane receptors. Two apparent binding sites with different affinities to nimodipine were found in the crude microsomal fraction. The separation of plasma membranes from intracellular membranes revealed that one binding site with higher affinity (K_D= 9 nM) was located on the plasma membrane and a second binding site with lower affinity (K_D= 36 nM) on an intracellular membrane The apparent dissociation constants determined from the association and dissociation rate constants in kinetic experiments were comparable to those determined by equilibrium experiments. The maximum number of binding sites of the plasma membrane fraction and the intracellular membrane fraction was B_max= 440 and 470 fmol (mg protein)^-1, respectively. [³H]-Nimodipinc binding was inhibited by (±) verapamil and stimulated by D-cis-diltiazem in both fractions. Moreover, ethyle-neglycol-bis(2-aminoethylcther)-N, N'-tetraacctic acid (EGTA) inhibited [³H]-nimo-dipinc binding in the plasma membrane fraction but not in the intracellular membrane fraction This effect was cancelled by the addition of CaCl₂.     

ISOLATION AND CHARACTERIZATION OF SOLUBLE ACIDIC LIPOPROTEINS FROM RAT BRAIN SYNAPTIC VESICLES

—Highly purified fractions of synaptic vesicles were prepared from rat cerebrum or cerebral cortex by density gradient centrifugation. Treatment of synaptic vesicle fractions by autoincubation, freeze-thawing and sonication in an isotonic alkaline-salt medium or in 0·1-0·3% (v/v) Triton X-100 released increasing quantities of synaptic vesicle protein and phospholipid into solution. When the soluble synaptic vesicle proteins were extracted with 0·1% (v/v) Triton X-100, the insoluble residue consisted mostly of 5–8 nm-thick membranes resembling the limiting membranes of intact synaptic vesicles. This finding, together with other considerations, suggested that the soluble proteins and accompanying phospholipids originated from the interior of the synaptic vesicles. A 0·3% (v/v) Triton X-100 extract of synaptic vesicle was fractionated by ultracentrifugal flotation and dialysis into three lipoprotein fractions: a low density lipoprotein (d < 1·21 g/ml), a high density lipoprotein (d = 1·21–1·35 g/ml) and a very high density lipoprotein (d > 1·35 g/ml). The phospholipid contents of the low, high and very high density lipoprotein fractions were 0·74, 0·38 and 0·20 mg/mg of protein, respectively. All three apolipoproteins had a high ratio of acidic to basic, and of polar to nonpolar, amino acids, and were rich in glycine, alanine and serine. Polyacrylamide gel electrophoresis of the alkaline-salt and Triton X-100 extracts of synaptic vesicles at pH 8·8 resolved a single anionic component which stained for protein, lipid (Sudan black B; iodine) and anionic groups (acridine orange). Polyacrylamide gel electrophoresis of synaptic vesicle extracts at pH 2·7 in 5 m urea and 0·25% (v/v) Triton X-100 resolved about 20 protein components. However, the protein profiles of electropherograms of the Triton X-100 and alkaline-salt extracts differed in certain respects, suggesting that these media to some extent solubilized different proteins. However, most of the protein bands in electropherograms of the Triton X-100 and alkaline-salt extracts also stained for lipid and anionic groups. In addition, two lipoprotein components in the alkaline-salt extract and four in the Triton X-100 extract contained carbohydrate. Isoelectric focusing of synaptic vesicle extracts resolved 6–8 protein fractions. The major fraction in Triton X-100 and alkaline-salt extracts had an apparent isoelectric point of approximately 4·2 and contained 0·24 mg of phospholipid per mg of protein. Soluble synaptic vesicle proteins released by incubating, freeze-thawing and sonicating in the alkaline-salt medium, and protein fractions of the latter obtained by electrofocusing had an absorption maximum of 260–265 nm which was enhanced in a cold 0·5 n perchloric acid extract, an observation suggesting the presence of a bound nucleotide. These findings demonstrate that rat brain synaptic vesicles contain a heterogenous array of soluble acidic lipoproteins which vary in buoyant density, lipid content, amino acid and carbohydrate composition and electrophoretic mobility in polyacrylamide gels. These acidic lipoproteins apparently comprise the bulk of the macromolecular contents of synaptic vesicles and probably serve as ‘carrier’ proteins for the binding and sequestration of the neurotransmitters.     

EFFECT OF ELECTRICAL STIMULATION AND CHLORPROMAZINE ON THE UPTAKE AND RELEASE OF TAURINE, γ-AMINOBUTYRIC ACID AND GLUTAMIC ACID IN MOUSE BRAIN SYNAPTOSOMES

—The concentrations of taurine and GABA were determined in isolated mouse brain synaptosomes incubated in Krebs-Ringer phosphate medium (pH 7·4). The concentration of GABA gradually decreased during incubation, but that of taurine remained approximately unchanged. In the presence of chlorpromazine the amount of GABA in the synaptosomes increased, but the efflux and influx of GABA were slightly reduced. The content and efflux of both taurine and GABA increased in electrically stimulated synaptosomes, and the influx of taurine, GABA and glutamate into the synaptosomes similarly increased. All three amino acids are taken up by the synaptosomes through at least two mechanisms: low-affinity and high-affinity. In the high-affinity system the K_m values were 33 μm for taurine, 24 μm for GABA and 68 μm for glutamate, and in the low-affinity one 1·1 mil, 0·9 mm and 1·2mm , respectively. The influx capacity (V_max) was highest for glutamate, second highest for GABA and lowest for taurine.     

Cell surface proteoglycans as a negative modulator in concanavalin a-mediated agglutination of hepatoma cells

Proteoglycan (heparan sulfate-protein conjugate) was solubilized with 8 M urea from rat liver plasma membranes after enzymic (RNAase, neuraminidase) treatments and extensively purified by chromatography and gel filtration. The final products gave an average ratio of hexuronate to protein (weight) of approx. 1.5, contained hexosamine equimolar to hexuronate and were sensitive to β-elimination (the molecular weight being reduced from 20 · 10⁴ to 3 · 10⁴ (gel filtration)).The proteoglycan fraction, when added to trypsinized and untrypsinized ascites hepatoma (AH-130F(N)) cells, inhibited the concanavalin A-mediated agglutination of the cells. However, the alkali-treated proteoglycan (β-elimination) or acid mucopolysaccharide fraction prepared from liver plasma membranes by papain digestion were less effective, and a reference preparation of heparan sulfate was almost ineffective. It was confirmed that significant amounts of proteoglycan labelled with ³⁵SO₄^2? were firmly bound to or taken up by the trypsinized ascites hepatoma cells.These results together with the sensitization of lectin-mediated agglutination by mild protease treatment of cells suggest that cell surface proteoglycans may act as a negative modulator in the lectin-mediated agglutination of cells.     

THE ISOLATION OF A CELL MEMBRANE FRACTION FROM RAT LIVER

A procedure is described for isolating cell membranes from rat liver homogenates. 20 gm. of rat liver was homogenized in a Dounce homogenizer in ice cold water buffered to pH 7.5 with NaHCO₃, rupturing all of the cells and most nuclei. The diluted homogenate was filtered through cheesecloth to remove precipitated nucleoprotein and centrifuged at 1500 g, 10 minutes, to sediment a crude membrane fraction. The membrane containing sediment was recentrifuged 3 times in conical tubes (1220 g, 10 minutes), the top layer of the 2-layered sediment being retained. Flotation in a sucrose solution d = 1.22 freed the preparation from contaminating cell fragments and nuclear membranes not previously disintegrated. The floating material ~0.4 ml. was quite homogeneous and consisted of thin amorphous membranes. Electron micrographs revealed numerous double profiles similar in shape and dimensions to apposed liver cell membranes in intact tissue.     

MICROHETEROGENEITY OF BRAIN CYTOPLASMIC AND SYNAPTOPLASMIC ACTINS

Abstract— Actin present in whole rat brain cytoplasm and in synaptosomes was purified by DNase I affinity chromatography. By use of two-dimensional gels and one-dimensional isoelectric focusing gels, brain actin was shown to be composed of two isomeric forms. By comparison with muscle actins, brain actins were identified as the β and γ isomers. Muscle type α actin is not present in brain. Synaptosomal protein with high affinity for DNase I is primarily composed of β and γ actin, however, two minor synaptosomal proteins, S₁ and S₂, with similar DNase I affinity were also isolated. S₁1 and S₂ have the same apparent molecular weight as whole brain actin, are more acidic than the major actin forms and are distinct from a actin. Relative to β and γ actin, the content of S₁ and S₂ is 3-fOld greater in synaptosomes when compared to similar non-synaptosomal species. The results demonstrate heterogeneity of brain actins and compartmentalization of brain proteins with high affinity for DNase I at the synapse. It was also shown that tubulin has selective affinity for the DNase I-actin complex.     

PIG BRAIN GLUTAMINASE: PURIFICATION AND IDENTIFICATION OF DIFFERENT ENZYME FORMS

—Pig brain glutaminase (EC 3.5.1.2 L-glutamine amidohydrolase) has been purified about 5000-fold from acetone powder. Glutaminase exists in different molecular forms, dependent on the ionic composition of the buffer. The three main forms are similar to those of kidney glutaminase and therefore called the tris-HCl enzyme, the phosphate enzyme, and the phosphate-borate enzyme. The sedimentation coefficients, as estimated by sucrose gradient technique, are 7·3, 8·7, and 53, respectively. Glutaminase has a pH optimum of about 9, but the pH curves of the tris-HCl enzyme and the phosphate-borate enzyme have different shapes. The apparent pK₁ of the tris-HCl enzyme-substrate complex is similar to pK₂ of inorganic phosphate, the apparent pK₂ of both the tris-HCl and the phosphateborate enzyme complexes is similar to pK₂ of glutamine. By use of the electron microscope we were able to see the phosphate-borate enzyme.     

Isolation and chemical characterization of agelaiatoxin8 (AvTx8) from Agelaia vicina wasp venom and its biological effects on GABA neurotransmission

Arthropod venoms are sources of molecules that may be useful tools to investigate molecular mechanisms of putative new medicines and laboratory drugs. Here we show the effects of the compound agelaiatoxin‐8 (AVTx8), isolated from Agelaia vicina venom, on γ‐aminobutyric acid (GABA) neurotransmission in rat brain synaptosomes. Analysis reveals that AvTx8 is composed by 14 amino acid residues with a molecular weight (MW) of 1567 Da. AvTx8 increased GABA release and inhibited GABA uptake in synaptosomes from rat cerebral cortex. AvTx8 inhibited GABA uptake and increased GABA release in the presence of Ca⁺, Na⁺, and K⁺ channel blockers, suggesting that it acts directly on GABA transporters. In addition, AvTx8 significantly decreases GABA binding in synaptic membranes from rat brain cortex, suggesting that it also modulates the activity of GABA receptors. Moreover, AvTx8 decreased GAT‐1– and GAT‐3–mediated GABA uptake in transfected COS‐7 cells. Accordingly, we suggest that AvTx8 modulates GABA neurotransmission and might provide a novel entry point for identifying a new class of GABA‐modulating neuroprotective drugs.     

Multiple forms of choline acetyltransferase in several species demonstrated by isoelectric focusing

1. The behaviour of choline acetyltransferase from pigeon, guinea-pig, rat and cat brain on isoelectric focusing was studied. 2. Choline acetyltransferase from pigeon and guinea-pig brain showed single peaks with isoelectric points at pH6.6 and 6.8 respectively. Only one molecular form of the enzyme was therefore detected in these species. 3. Three peaks of choline acetyltransferase activities with isoelectric points 7.3-7.6, 7.7-7.9 and 8.3 were obtained with enzyme preparations from rat brain. 4. The separate identities of each of the three forms were confirmed by refocusing. 5. Choline acetyltransferase activity from a high-speed supernatant of rat brain homogenate was distributed similarly to a partially purified enzyme preparation from rat brain in the isoelectric gradient. 6. The enzyme activities from cat brain were separated into two distinct peaks with isoelectric points 7.0 and 8.4, and a possible third peak with isoelectric point 7.6. 7. The two main peaks showed considerable differences in stability on storage, and their identities were confirmed by refocusing. 8. The distribution of the enzyme activities was unaltered by isoelectric focusing in the presence of 3m-urea. 9. The apparent K(m) for choline of choline acetyltransferase from rat, cat and guinea-pig brain was 0.8mm, whereas for the pigeon enzyme it was 0.4mm.     

GABA-TRANSAMINASES OF HUMAN BRAIN AND PERIPHERAL TISSUES—KINETIC AND MOLECULAR PROPERTIES

Abstract— Kinetic experiments with 4-aminobutyrate-2-ketoglutarate transaminase (GABA-T), partially purified from human brain tissue, supported a Bi Bi Ping-Pong type of enzyme mechanism in which the enzyme oscillates between forms bound to pyridoxal phosphate and pyridoxamine phosphate. Extrapolated K _m values were 0.31 m m for γ-aminobutyrate, 0.16 m m for α-ketoglutarate, and 3.8 μ m for pyridoxal phosphate. Very similar kinetic parameters were observed with rat brain enzyme. Apparent molecular weight of human GABA-T by gel filtration was 70,000 ± 3000. Electrofucusing experiments indicated a single ionic form with isoelectric pH = 5.7. Enzyme activity was inhibited by Tris, halides, cadmium and cupric ions, and known GABA-T inhibitors.
GABA-transaminating enzymes isolated from human kidney and liver were found to be similar to the brain enzyme with respect to substrate affinities, cofactor requirements, isoelectric pH values, molecular weights, and response to inhibitors.     

Further studies on the specific interaction of S-100 protein with synaptosomal particulates.

Abstract— The specific interaction of S-100 protein with disrupted synaptosomes was further investigated. The specific binding is a saturable and reversible process, and is time, temperature, and strictly Ca²⁺ -dependent. Two affinities affect the interaction (K_ins= 7.04 × 10^?9 M. 1.28 × 10¹² binding sites/ mg protein; K_ins2= 3.91 × 10^?7M, 2.96 × 10¹³ binding sites/mg protein). The half-saturation time is about 5.5 min at 37°C. The half-life of the complex is 17 min at 37°C. At 0°C the binding is 75% slower than at 37° C, and only one-third of the binding sites are involved. The binding capacity is decreased by high NaCl concentrations and by pretreating membranes at high temperatures. Digestion of membranes with trypsin practically abolishes the specific binding. Treatment of membranes with phospholipase C decreases the specific binding, while phospholipase D enhances it to some extent. Other lipid extractors decrease significantly the extent of the interaction. Synaptic plasma membranes seem to be the synaptosomal component involved in the high affinity binding. The S-100 binding activity seems to undergo developmental changes, the adult values of kinetic parameters being reached around the 16th postnatal day in the rat. The results are discussed also in relation to the membrane-bound fraction of S-100.     

Choline acetyltransferase-like activity bound to neuronal plasma membranes

A form of CAT-like activity was found bound present in rat brain synaptosomal membranes which could be recovered in the Triton X-114 phase. The enzyme activity was slightly activated by NaCl, had a pH maximum around 8 and showed a temperature dependence with a Q₁₀ of 2.28. It was inhibited 100% by 10^–6 M naphthyl vinyl pyridinium but not by 10^–5 M diisopropyl phosphofluoridate. The kinetics of this bound form of CAT were similar to the soluble form of the enzyme. TheK _m was 405±58 M for choline and 62±8 M for AcCoA. Five isoelectric forms were found with pH's of 4.55, 6.05, 7.06, 7.36, and 8.00 which is in contrast to the three isoelectric forms found of the soluble enzyme in rat brain. The presence of a CAT-like activity in the plasma membrane was confirmed with experiments performed using intact synaptosomes and intact cells in culture. Acetylcholine, synthesized from radioactive AcCoA by intact rat brain synaptosomes, was recovered in the incubation medium and only in the presence of exogenous choline or when the production of choline was stimulated by oleate via the activation of phospholipase D. This was also seen in experiments with intact pheochromocytoma cell cultures (PC 12) which synthesize acetylcholine that was recoverved in the incubation medium. Acetylcholine formation in the presence of choline and AcCoA was stimulated in cells that had been grown in the presence of nerve growth factor (NGF). The localization of 1% of CAT activity in a transbilayer position in the plasma membrane, could suggest a possible role of this enzymatic form in the regulation of acetylcholine synthesis.     

ISOLATION OF AN ACID-SOLUBLE BASIC PROTEIN FROM MONKEY BRAIN

—A basic protein, soluble in 0·1 m -perchloric acid, has been purified from brain of Macaca irus. The protein is homogeneous as indicated by ultracentrifugation, gel filtration, gel isoelectric focusing and gel electrophoresis at pH 2·9, 4·3 and 7·5. The molecular weight is estimated to be 16,000 by electrophoresis in sodium dodecyl sulphate–polyacrylamide gels. This result is in agreement with the value of 16,728 obtained from the amino acid analysis. The protein dimerizes under alkaline conditions. The predominant amino acid is glycine (15%) and the protein also contains 4% cysteine. The ratio of acidic to basic amino acids is 1·6, but a high amide content gives the protein a basic character. An isoelectric point of 9·5 is observed in gel isoelectric focusing.