Aminoacyl-tRNA-synthetase activity of subcellular fractions of cerebral cortex]

The total activity of aminoacyl-tRNA-synthetases of myelin, synaptic membranes, heavy and light synaptosomes, mitochondria and soluble fractions of rat cerebral cortex was studied. It was found that the highest activity of the enzymes is localized in the fractions of synaptic membranes and heavy and light synaptosomes and is practically absent in the myelin fraction. The specific activity of the total aminoacyl-tRNA-synthetase fraction in the soluble fraction is 2 times as low as compared to the synaptic membranes and light and heavy synaptosomes.     

Activation of calcium transport in synaptosomes by phosphatidylinositol-specific phospholipase C

The isotope labeling method was used to study the influence of phospholipases C of different origin and specificity on Ca2+ accumulation in rat brain synaptosomes. It was found that phospholipases C specific to phosphatidylinositides (PI) stimulate Ca2+ transport into synaptosomes, while non-specific phospholipase C, which hydrolyzes different membrane lipid fractions, decreases the Ca2+ content in synaptosomes. It is supposed that the stimulating effect of PI-specific phospholipases C is determined by the activation of PI metabolism, which results in an increase in the content of some PI metabolism products serving as Ca2+ ionophores in synaptosomal membranes. The inhibition of Ca2+ uptake by synaptosomes treated with non-specific phospholipase C is thought to result from partial disruption of synaptosomal membranes.     

ATP-driven proton fluxes across membranes of secretory organelles

The ATP-dependent proton uptake by chromaffin granule membranes, lysosomes, and synaptosomes was examined. In synaptosomes the reaction was absolutely dependent on the presence of chloride, while in chromaffin granules chloride had a profound effect and in lysosomes only a minor effect. The presence of chloride markedly increases the rate of collapse of delta pH by carbonyl cyanide p-trifluoromethoxyphenylhydrazone in all three organelles. Ascorbate with phenazine methosulfate uncoupled the ATP-dependent proton uptake by chromaffin granules, but had no effect on lysosomes and synaptosomes. Proton uptake by submitochondrial particles was about 50-fold more sensitive to dicyclohexylcarbodiimide than the proton uptake by chromaffin granule membranes. Chromaffin granule membranes were treated with 2 M sodium bromide to inactivate the mitochondrial ATPase. The treatment caused a complete inhibition of the ATP-dependent proton uptake. Solubilization of these membranes by sodium cholate, followed by reconstitution by cholate dilution revealed the ATP-dependent proton uptake of the system. It is concluded that the genuine ATPase enzyme of chromaffin granules is a proton translocator.     

Effect of antidepressants on reverse neuromediator uptake by the synaptosomes in control and stressed rats

The influence of chemically different antidepressants on the uptake of 5-HT, dopamine and GABA by the rat brain synaptosomes was tested, using radioisotope technique in control and chronically stressed (14 days) animals. Drugs were more potent inhibitors of neurotransmitter uptake in synaptosomes of stressed animals, as compared to synaptosomes from control ones, the activity increasing proportionally to the changes in a particular uptake system. It is suggested that the drugs inhibit the uptake of neurotransmitters studied by changing the properties of synaptosomal membrane lipid bilayer. It is also evident that neurochemical properties of psychotropic drugs must be evaluated on the membranes from animals in the model of experimental psychopathology.     

A rapid Percoll gradient procedure for preparation of synaptosomes

Homogenization of fresh brain tissue in isotonic medium shears plasma membranes causing nerve terminals to become separated from their axons and postsynaptic connections. The nerve terminal membranes then reseal to form synaptosomes. The discontinuous Percoll gradient procedure described here is designed to isolate synaptosomes from brain homogenates in the minimum time to allow functional experiments to be performed. Synaptosomes are isolated using a medium-speed centrifuge, while maintaining isotonic conditions and minimizing mechanically damaging resuspension steps. This protocol has advantages over other procedures in terms of speed and by producing relatively homogeneous synaptosomes, minimizing the presence of synaptic and glial plasma membranes and extrasynaptosomal mitochondria. The purified synaptosomes are viable and take up and release neurotransmitters very efficiently. A typical yield of synaptosomes is between 2.5 and 4 mg of synaptosomal protein per gram rat brain. The procedure takes approximately 1 h from homogenization of the brain until collection of the synaptosomal suspension from the Percoll gradient.     

Internalization and degradation of latrotoxin bound to rat brain synaptosomes]

The accessibility to trypsin of 125I-labeled latrotoxin bound to rat brain synaptosomes was investigated. It was shown that latrotoxin bound to synaptosomes in the cold can be practically completely removed by trypsin treatment. The resistance of latrotoxin to proteolysis increases during its incubation with synaptosomes (37 degrees C). Concanavalin A (10(-6) M) decreases toxin binding by 30%, but fully prevents internalization (incorporation). Moreover, latrotoxin is not incorporated into synaptosomal membrane fragments irrespective of duration and temperature of incubation. Latrotoxin incorporated into synaptosomal membranes undergoes degradation by endogenous proteases resulting in the formation of TCA-soluble products.     

ATP-dependent Ca2+-transporting system in the rat brain during an early period of acute radiation injury

The rate of Mg2+, Ca2+-ATPase reaction and ATP-dependent Ca2+ accumulation in a preparation of plasma membranes from brain synaptosomes increases 60 min following whole-body X-irradiation of rats with a dose of 0.21 C/kg, a calcium sensitivity of both processes being increased. A unidirectional change in their kinetics indicates the early radiosensitivity of Ca2+ transfer systems in the brain synaptosome membranes. There is an increase in the availability of SH-groups of membrane preparation proteins for SH-reagents and in the sensitivity of Mg2+, Ca2+-ATPase reaction and ATP-dependent Ca2+ accumulation to trifluoperazine, a calmodulin inhibitor. Both processes lose their ability to be activated by exogenous calmodulin. It is suggested that at an early stage of radiation affection, a change occurs in the molecular organization of the ATPase-calmodulin membrane complex in plasma membranes of rat brain synaptosomes.     

Marker enzymes,phospholipids and acyl group composition of a somal plasma membrane fraction isolated from rat cerebral cortex: a comparison with microsomes and synaptic plasma membranes

Subjecting brain homogenates to differential speed and sucrose density gradient centrifugation resulted in the isolation of a membrane fraction from the post-mitochondrial supernatant with properties and marker enzyme profiles typical of plasma membranes. This membrane fraction is compared with the microsomes and the synaptic plasma membranes isolated from synaptosomes. Like the synaptic plasma membranes, membranes obtained from the post-mitochondrial supernatant were enriched five-fold in 5′-nucleotidase activity. However, the latter membranes were lower in (Na⁺, K⁺)-ATPase activity and higher in NADPH-cytochrome C reductase activity as compared to the synaptic plasma membranes. The post-mitochondrial plasma membranes were also different from the microsomes in their respective marker enzyme activities. Electron microscopic examination indicated largely membranous vesicles for both plasma membrane fractions with little contamination by myelin, mitochondra and intact synaptosomes. The phospholipid and acyl group profiles of the two plasma membrane fractions were surprisingly similar, but they were different from the characteristic profiles of myelin and mitochondria. It is concluded that plasma membranes isolated from the post-mitochondrial supernatant fraction are derived largely from neuronal and glial soma and are thus designated the somal plasma membrane fraction.     

Localization of Thiamine-Binding Protein in Synaptosomes from the Rat Brain

Using preparations of synaptosomes and subsynaptosomal fractions from the rat brain, we studied the localization of thiamine-binding protein (TBP) in the subcellular structures of the neurons. In addition, we studied the distribution in synaptosomes of two types of activity typical of TBP (thiamine triphosphatase and thiamine-binding activities), as well as the effects of factors destroying the plasma membrane of synaptosomes on binding of [¹⁴C]thiamine with the latter. We found that the thiamine-associated activity of TBP was the highest in fractions of the synaptic vesicles and plasma membranes. Hydrolysis of thiamine triphosphate was also most active in these structures. Our results allow us to conclude that TBP is localized mostly in the synaptic vesicles and plasma membranes of synaptosomes.     

Stabilizing effect of hydroxybenzimidazole and its derivatives on biological membranes during activation of lipid peroxidation

Inhibition of lipid peroxidation (LPO) by oxybenzimidazole (OBI) and its derivatives--alkyloxybenzimidazole (AOBI) and alkylethoxybenzimidazole (AEBI) was studied in liver microsomes and brain synaptosomes. It has been shown that both OBI and AOBI strongly inhibit LPO in microsomes and not synaptosomes. AEBI failed to inhibit LPO in microsomes. AOBI is more potent than OBI both in ascorbate- and NADPH-dependent LPO of microsomes. An antioxidant effect of both compounds is more marked in ascorbate-dependent LPO. The investigation of the possible use of AOBI for the protection of liver membranes in various pathological conditions associated with LPO activation seems promising.     

Variations in Membrane Sensitivity of Brain Region Synaptosomes to the Effects of Ethanol In Vitro and Chronic In Vivo Treatment

The effects of chronic ethanol treatment on the membrane order of synaptosomes from the cerebral cortex, striatum, cerebellum, brainstem, and hippocampus of rats were determined by measuring the fluorescence polarization of diphenylhexatriene (DPH) that had been incorporated into the synaptosomal membranes. Fischer-344 rats either were fed a nutritionally complete ethanol-containing liquid diet for 5 months or pair-fed with a diet that contained sucrose substituted isocalorically for ethanol. Polarization values for synaptosomes from all the brain regions studied were similar except for those from cerebral cortical synaptosomal membranes, which were significantly less ordered. Ethanol in vitro (30-500 mM) decreased the polarization values in synaptosomes from sucrose-control rats for all brain regions, although the sensitivity of cerebellar synaptosomes to the membrane disordering effects of ethanol in vitro was significantly greater that of synaptosomes from other brain regions. Chronic ethanol treatment did not alter baseline polarization for any brain region. Cerebellar and brainstem synaptosomes from the ethanol-fed rats were significantly less susceptible to the membrane disordering effects of ethanol in vitro compared to their sucrose controls, suggesting that chronic ethanol administration results in tolerance to ethanol's membrane effects. Striatal synaptosomes exhibited intermediate tolerance, whereas the sensitivities of cortical and hippocampal synaptosomes to membrane disordering by ethanol in vitro were not significantly affected by the chronic ethanol treatment. These results suggest that synaptosomal membranes have different membrane order requirements depending on the brain region from which they are prepared. Variations in brain regional neuronal membrane sensitivity to ethanol and differential tolerance development may contribute to some of the acute and chronic behavioral effects of ethanol.     

Proteolipids of brain myelin and synaptosomes in the frog and hen

Proteolipid complex of Folch-Lees has been obtained and purified from the myelin and synaptosomes of the brain of the frog Rana temporaria and hen Gallus domesticus. Relative content of this proteolipid and glycolipids in the myelin is almost twice higher, whereas that of phospholipids--1 1/2 times lower than in the synaptosomal membranes of the same animal. Protein content of this complex is higher for myelin than for synaptosomal membranes; opposite relation was found with respect to phospholipid content. Within this complex, lipids are presented mainly by phospholipids, especially by acid ones which amount to 30-60%. Proteolipid complexes fro the myelin and synaptosomes differ from each other by their lipid component. Myelin proteolipid complex contains mainly phosphatidylserine and phosphatid acid, whereas synaptosomal one--phosphatidylserine and diphosphatediglycerol. No significant differences were found in fatty acid composition of phospholipids from proteolipid complex from myelin and synaptosomes as compared to this composition in the initial membranes.     

Na, K-ATPase activity of the meninges in electroshock and the action of the anticonvulsant agent, diazepam]

It was shown that the phenomenon of inactivation of Na, K-ATPase of the non-purified fraction of the rat cortical synaptosomes under electroshock may be related to "modification" of the potassium active center of the enzyme. The anticonvulsant diazepam injected intramuscularly also inhibits Na, K-ATPase of the cerebral membranes. However, in subsequent electrical stimulation of the brain the drug activates Na, K-ATPase as compared to controls. Diazepam also abolishes clonic convulsions induced by electrical stimulation of the brain. At the same time it does not eliminate compensatory shifts in the activity of acetyl-cholinesterase of the rat cerebral and spinal synaptosomes, characteristic of electroshock. The results are discussed from the standpoint that inhibition of the activity of Na, K-ATPase of the nerve endings membranes may underlie the pathogenetic mechanism of the convulsive activity.     

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.     

Ultrahistochemical localization of adenylate cyclase activity in the electric organ of Torpedo marmorata

The lead pyrophosphate precipitation technique was used to visualize adenylate cyclase activity with the electron microscope in unfixed electric organ and synaptosomes of Torpedo marmorata, with special attention to presynaptic membranes. Specificity of the deposition of reaction product was ensured by using 5'-adenylyl imidodiphosphate as substrate and 5'-guanylyl imidodiphosphate and sodium fluoride as activators. Under suitable conditions a reaction product was deposited on the Schwann cell, on presynaptic vesicles, on the inner side of membranes of cisternae and on glycogen granules of the presynaptic region of the endplate. In some cases, a precipitate was also found on postsynaptic membranes of the synaptic cleft and on mitochondria. In isolated synaptosomes localization of the reaction product was identical with that of minced tissue. However, most strikingly, on presynaptic membranes no precipitate was ever found, neither in pieces of electric organ nor in isolated synaptosomes. Furthermore, the extended membrane system of the postsynaptic region of the electroplax remained always free of lead pyrophosphate precipitate.     

Membrane-bound histamine N-methyltransferase in mouse brain: possible role in the synaptic inactivation of neuronal histamine

In the CNS, histamine is a neurotransmitter that is inactivated by histamine N-methyltransferase (HNMT), a soluble enzyme localized to the cytosol of neurons and endothelial cells. However, it has not been established how extracellular histamine, a charged molecule at physiological pH, reaches intracellular HNMT. Present studies investigated two potential routes of histamine inactivation in mouse brain nerve terminal fractions (synaptosomes): (i) histamine uptake and (ii) histamine metabolism by HNMT. Intact synaptosomes demonstrated a weak temperature-dependent histamine uptake (0.098 pmol/min-mg protein), but contained a much greater capacity to metabolize histamine by HNMT (1.4 pmol/min-mg protein). Determination of the distribution of HNMT within synaptosomes revealed that synaptosomal membranes (devoid of soluble HNMT) contribute HNMT activity equivalent to intact synaptosomes (14.3 +/- 2.2 and 18.2 +/- 4.3 pmol/min-tube, respectively) and suggested that histamine-methylating activity is associated with the membrane fraction. Additional experimental findings that support this hypothesis include: (i) the histamine metabolite tele-methylhistamine (tMH) was found exclusively in the supernatant fraction following an HNMT assay with intact synaptosomes; (ii) the membrane-bound HNMT activity was shown to increase 6.5-fold upon the solubilization of the membranes with 0.1% Triton X-100; and (iii) HNMT activity from the S2 fraction, ruptured synaptosomes, and synaptosomal membranes displayed different stability profiles when stored over 23 days at - 20 degrees C. Taken together, these studies demonstrate functional evidence for the existence of membrane-bound HNMT. Although molecular studies have not yet identified the nature of this activity, the present work suggests that levels of biologically active histamine may be controlled by an extracellular process.     

Participation of gangliosides in protection of beta adrenergic receptors from damaging effect induced by lipid peroxidation in synaptosome membranes]

The induction of lipid peroxidation (LPO) in rat brain synaptosomes was shown to result in considerable decrease of the level of specific [3H]-dihydroalprenolol binding, decrease of Bmax and increase of KD. It was revealed that the preincubation of rat brain synaptosomes with monosialoganglioside GM1 (10(-8) M) or alpha-tocopherol (10(-6) M) led to a decrease in MDA accumulation after LPO induction by Fe(2+)-ascorbate system. AT the same time GM1 prevents damage of beta-adrenoreceptors, caused by LPO induction, having no effect on the functional state of beta-adrenoreceptors in control preparations. Partial normalization of the ligand affinity of the receptors was observed after preincubation of synaptosomes with GM1 and alpha-tocopherol. The various mechanisms of stabilization of synaptosomal membranes by gangliosides and natural antioxidant-tocopherol is suggested.     

Transbilayer distribution of alpha-tocopherol and lipid asymmetry in nerve tissue membranes

The alpha-tocopherol content and fatty acid composition of lipids in various types of nervous tissue membranes were studied. The transbilayer distribution of alpha-tocopherol and polyunsaturated fatty acids in liposomes and plasma membranes of synaptosomes was examined. It was shown that both phosphatidylethanolamine and phosphatidylserine are localized predominantly in the inner monolayer and they contain the bulk of polyenoic fatty acid residues. alpha-Tocopherol incorporated into liposomes from synaptosome plasma membrane lipids and present in synaptosome plasma membranes is also predominantly localized in the inner monolayers. No asymmetrical distribution of incorporated alpha-tocopherol was observed in liposomes prepared from a single phospholipid, e.g., dioleoylphosphatidylcholine.     

Calcium-Activated ATPases in Presynaptic Nerve Endings

We studied the properties of calcium-activated ATPases present in preparations of isolated presynaptic nerve ending (synaptosome) and its subfractions from mouse brain. ATPase activity in the preparation was stimulated by Ca2+ and by Mg2+, but not by Na+ and K+, when each was added alone. The substrate specificities were found to be similar. The ATPases hydrolyzed only the high-energy phosphate bond and similar activity was exhibited for all nucleoside triphosphates tested (ATP, CTP, GTP, UTP). Moreover, the enzymes were insensitive to mitochondrial markers and to ouabain, but were inhibited by La3+. La3+ produced uncompetitive inhibition of Ca2+-ATPase in intact synaptosomes. Inhibition by La3+ was greatly increased after lysis of the synaptosomes, suggesting that the active sites of the enzymes may be on the cytosolic face of the membranes. The Ca2+-ATPase activity in synaptosomes was increased by increasing concentrations of external K+, suggesting that Ca2+ influx may be involved The Ca2+-ATPase in synaptosomal plasma membranes and synaptic vesicles had higher specific activities than those of intact synaptosomes and were activated, both in the presence and the absence of Mg2+, by Ca2+ concentrations approximating the intracellular level (10(-7) M). It is concluded that the nonmitochondrial synaptosomal Ca2+-ATPase may play an important role in the regulation of intracellular Ca2+.     

BIOCHEMICAL CHARACTERIZATION OF THE NEURON: RIBONUCLEIC ACID COMPOSITION OF THE NEURONAL CELL BODIES

Abstract— The fluorescence of chlorotetracycline (CTC) in the presence of synaptosomes isolated from sheep brain is selectively increased by Ca²⁺ under conditions in which Mg²⁺, Na⁺, K⁺, Li⁺ or choline have only a small effect. The monovalent cations release bound Ca²⁺ from synaptosomes, and this effect is reflected by a decrease in the CTC fluorescence. Under optimal conditions there is a near parallelism between Ca²⁺ and CTC binding to the synaptosomes membranes, and Li⁺ is the monovalent cation tested which interferes the most with the binding of both substances. These results obtained in a predominantly sucrose medium become less distinct when media simulating physiological composition are utilized, which limits the usefulness of the method. Brain mitochondria and myelin also bind Ca²⁺ and CTC. The ratio of the fluorescence signal (or CTC bound) to Ca²⁺ bound is highest of all for mitochondrial membranes, and the apparent fluorescence quantum yield of CTC is also the highest in these membranes, which suggests that the Ca²⁺ in these membranes is localized in a more apolar region than is the case for synaptosomes and myelin.