l-Glutamate effects on electrical potentials of synaptic plasma membrane vesicles

The electrogenic nature of the l-glutamate-stimulated Na⁺ flux was examined by measuring the distribution of the lipophilic anion [³⁵S]thiocyanate (SCN^?) into synaptic membrane vesicles that were incubated in a NaCl medium. Concentrations of l-glutamate from 10^?7 to 10^?4 M added to the incubation medium caused an enhanced intravesicular accumulation of SCN^?. Based on the SCN^? distribution in synaptic membrane vesicles it was calculated that 10 μM l-glutamate induced an average change in the membrane potential of + 13 mV. l-Glutamate enhanced both the Na⁺ and K⁺ conductance of these membranes as determined by increases in SCN^? influx. Other neuroexcitatory amino acids and amino acid analogs (d-glutamate, l-aspartate, l-cysteine sulfinate, kainate, ibotenate, quisqualate, $\text{N-}\text{methyl}\text{-}\text{d}\text{-}\text{aspartate}$, and dl-homocysteate) also increased SCN^? accumulation in synaptic membrane vesicles. These observations are indicative of the activation by l-glutamate and some of its analogs of excitatory amino acid receptor ion channel complexes in synaptic membranes.     

Tyrosine transport by membrane vesicles isolated from rat brain

Tyrosine uptake by membrane vesicles derived from rat brain has been investigated. The uptake is dependent on an Na⁺ gradient ([$\text{Na}{}^{\mathrm{+}}\text{]}\text{outside}\text{> [}\text{Na}{}^{\mathrm{+}}\text{]}\text{inside}$). The uptake is transport into an osmotically active space and not a binding artifact as indicated by the effect of increasing the medium osmolarity. The process is stimulated by a membrane potential (negative inside) as demonstrated by the effect of the ionophores valinomycin and carbonyl cyanide $\text{m-}\text{chlorophenylhydrazone}$ and anions with different permeabilities. Kinetic data show that tyrosine is accumulated by two systems with different affinities. Tyrosine uptake is inhibited by the presence of phenylalanine and tryptophan.     

神经末梢突触囊泡释放神经递质过程的调控蛋白

神经末梢突触囊泡释放神经递质是一个复杂且受到精细调控的过程,涉及多种蛋白质间的相互作用。位于突触囊泡膜上的突触囊泡蛋白／突触囊泡相关膜蛋白（synaptobrevin/VAMP),与位于突触前膜上的syntaxin和突触小体相关蛋白SNAP－25,三者聚合形成的可溶性N－甲基马来酰胺敏感因子（NSF）附着蛋白受体（SNARE）核心复合物是突触囊泡胞吐过程中的核心成分。本文主要围绕参与空触囊泡胞吐过程,以及调节SNARE核心复合物的形成,解离及其功能的蛋白质,并对突触囊泡胞吐过程的分子模型作一概述。     

Comparison of calmodulin binding to brain synaptic and coated vesicles

Several characteristics of calmodulin association with brain synaptic and coated vesicles were analyzed and compared. Radioimmunoassay revealed that both classes of vesicles contain approx. 1 μg of calmodulin per mg of vesicle protein. Discontinuous sucrose gradients revealed that coated and synaptic vesicles preparations were homogeneous and had different sedimentation properties. Binding of ¹²⁵I-labeled calmodulin to synaptic and coated vesicles was Ca²⁺ dependent and displaced by unlabeled calmodulin but not by troponin-C. Scatchard analysis revealed the presence of two binding sites. In both vesicle types there was one high-affinity, low-binding-capacity site ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}\text{= 1–39}\text{nM and B}{}_{\mathrm{<mtext>max</mtext>}}\text{= 4–16}\text{pmol}\text{/}\text{mg}$) and one low-affinity, high-binding-capacity site ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}\text{= 102–177}\text{nM and B}{}_{\mathrm{<mtext>max</mtext>}}\text{= 151–202}\text{pmol}\text{/}\text{mg}$). (Ca²⁺ + Mg²⁺)-ATPase activity was stimulated in both synaptic and coated vesicles by calmodulin. Thus synaptic and coated vesicles may possess similar calmodulin binding sites.     

Association of N-ethylmaleimide-sensitive factor with synaptic vesicles

N-Ethylmaleimide-sensitive factor (NSF) mediates docking and/or fusion of transport vesicles in the multi-pathways of vesicular transport. NSF was highly expressed in brain and adrenal gland. Immunostaining of cerebellum with an anti-NSF monoclonal antibody showed that NSF is predominantly localized in the molecular layers and the glomeruli of the granule cell layers. This distribution coincided well with that of synaptophysin, a marker protein of synaptic vesicles. Purification and immunoprecipitation revealed that NSF is associated with brain synaptic vesicles. The present results suggest that NSF is associated with synaptic vesicles without Ca²⁺ influx.     

Fluorescence changes of rhodamine 6G associated with changes in membrane potential in synaptosomes

The intensity of rhodamine 6G fluorescence was found to be a useful scale for measuring the membrane potential in synaptosomes. The fluorescence of rhodamine 6G in synaptosomal suspensions increases with depolarization in the synaptosomes induced by the replacement of cations in the medium or by the addition of agents known to depolarize the membrane potential. Considering the character of the dye, we have derived an equation which gives the relation between the fluorescence intensity of the dye and the membrane potential. The change in membrane potential (diffusion potential) of synaptosomes was calculated using the equation. The calculated membrane potential was proportional to the logarithm of the K⁺ concentration above 20 mM, and the slope of membrane potential against log[K⁺] was about 52 mV per decade of concentration. The permeability ratio ($\text{P}{}_{\mathrm{<mtext>X</mtext>}}\text{P}{}_{\mathrm{<mtext>K</mtext>}}$; the ratio of the permeability constants of a given cation, X⁺, and K⁺) was estimated from the calculated membrane potential.     

Kinetics of cation-induced aggregation of Torpedo electric organ synaptic vesicles

Synaptic vesicles from the Torpedo ray can be induced to aggregate in the presence of Ca²⁺ and K⁺ in the 4 mM and 50 mM range, respectively. The reactions are strikingly similar to those of chromaffin granule membranes reported previously (Morris, S.J., Chiu, V.C.K. and Haynes, D.H. (1979) Membrane Biochem. 2, 163–202). The Ca²⁺-induced reaction includes dimerization and higher order aggregation, and is shown to be due to electrostatic screening interactions and binding to negatively-charged groups on the membrane surface. The K⁺-induced reaction includes only dimerization and is shown to be due to screening interactions alone.The kinetics of the dimerization reactions were studied using the stopped-flow rapid mixing technique. The Ca²⁺-induced reaction has a ‘bimolecular’ rate constant of 4.77 · 10⁸ M^?1 · s^?1 while the value for the K⁺-induced reaction is 7.05 · 10⁹ M^?1 · s^?1. These values are close to the limit of diffusion control (8.03 · 10⁹ M^?1 · s^?1), indicating that no large energy barriers or structural barriers to aggregation exist. Arrhenius plots for the Ca²⁺-induced aggregation showed a break at 5°C. Above this temperature, the activation energy is low ($\text{+0.65}\text{kcal/mol}$), consistent with the above. Below this temperature, the activation energy is high, consistent with a membrane structure change increasing the energetic and structural barriers. This information, and the observation of a high stability constant of the complex, were taken as evidence for the involvement of ‘recognition sites’ on the membrane surface.     

Synaptic membrane proteins as substrates for cyclic AMP-stimulated protein phosphorylation in various regions of rat brain

Synaptosomal plasma membranes from mammalian brain contain protein kinase activity which phosphorylates endogenous membrane proteins and is stimulated by cyclic AMP. Using polyacrylamide gel electrophoresis it was shown that at least ten proteins in the synaptosomal plasma membrane fraction could be phosphorylated by endogenous cyclic AMP-stimulated protein kinase activity. The number of proteins whose phosphorylation was stimulated by cyclic AMP was strongly influenced by the pH and Mg²⁺ concentration used in the phosphorylation reaction. A complex pattern of cyclic AMP-stimulated protein phosphorylation was obtained only with synaptosomal plasma membranes and a crude microsomal fraction. Mitochondrial and myelin fractions exhibited no cyclic AMP-stimulated protein kinase activity. Investigation of the distribution of substrates for cyclic AMP-stimulated phosphorylation among various brain regions failed to reveal any regional differences.     

Mice lacking synaptophysin reproduce and form typical synaptic vesicles

Synaptophysin is one of the major integral membrane proteins of the small (30–50 nm diameter) electron-translucent transmitter-containing vesicles in neurons and of similar vesicles in neuroendocrine cells. Since its expression is tightly linked to the occurrence of these vesicle types, we mutated the X-chromosomally located synaptophysin gene in embryonic stem cells for the generation of synaptophysin-deficient mice in order to study the consequence of synaptophysin ablation for the formation and function of such vesicles in vivo. the behavior and appearance of mice lacking synaptophysin was indistinguishable from that of their litter mates and reproductive capacity was comparable to normal mice. Furthermore, no drastic compensatory changes were noted in the expression of several other neuronal polypeptides or in the mRNA levels of synaptophysin isoforms, the closely related neuronal synaptoporin/synaptophysinII, and the ubiquitous pantophysin. Immunofluorescence microscopy of several neuronal and neuroendocrine tissues showed that overall tissue architecture was maintained in the absence of synaptophysin, and that the distribution of other synaptic vesicle components was not visibly affected. In electron-microscopic preparations, large numbers of vesicles with a diameter of 39.9 nm and an electron-translucent interior were seen in synaptic regions of synaptophysin-deficient mice; these vesicles could be labeled by antibodies against synaptic vesicle proteins, such as synaptobrevin 2.This research was supported by the DFG-SFB 317     

Transport of carnosine by mouse intestinal brush-border membrane vesicles

The characteristics of carnosine (β-alanyl-l-histidine) transport have been studied using purified brush-border membrane vesicles from mouse small intestine. Uptake curves did not exhibit any overshoot phenomena, and were similar under Na⁺, K⁺ or choline⁺ gradient conditions (extravesicular > intravesicular). However, uptake of histidine showed an overshoot phenomenon in the presence of a Na⁺-gradient. There was no detectable hydrolysis of carnosine during 15 min of incubation with membrane vesicles under conditions used for transport experiments. Analysis of intravesicular contents further showed the complete absence of the constituent free amino acids of carnosine, and indicates that intact carnosine is transported. Studies on the effect of concentration on peptide uptake revealed that transport occurred by a saturable process conforming to Michaelis-Menten kinetics with a K_m of 9.6 ± 1.4 mM and a V_max of 2.9 ± 0.2 nmol / mg protein per 0.4 min. Uptake of carnosine was inhibited by both di- and tripeptides with a maximum inhibition of 68% by glycyl-l-leucyltyrosine. These results clearly demonstrate that carnosine is transported intact by a carrier-mediated, Na⁺-independent process.     

How synapsin I may cluster synaptic vesicles

Synapsin I is the most abundant brain phosphoprotein present in conventional synapses of the CNS. Knockout and rescue experiments have demonstrated that synapsin is essential for clustering of synaptic vesicles (SVs) at active zones and the organization of the reserve pool of SVs. However, in spite of intense efforts it remains largely unknown how exactly synapsin I performs this function. It has been proposed that synapsin I in its dephosphorylated state may tether SVs to actin filaments within the cluster from where SVs are released in response to activity-induced synapsin phosphorylation. Recent studies, however, have failed to detect actin filaments inside the vesicle cluster at resting central synapses. Instead, proteins with established functional roles in SV recycling have been found within this presynaptic compartment. Here we discuss potential alternative mechanisms of synapsin I-dependent SV clustering in the reserve pool.     

Differences in the osmotic fragility of recycling and reserve synaptic vesicles from the cholinergic electromotor nerve terminals of Torpedo and their possible significance for vesicle recycling

In this study we demonstrate differences in the osmotic fragility of two metabolically and physically heterogeneous synaptic vesicle populations from stimulated electromotor nerve terminals. When synaptic vesicles isolated on sucrose density gradients are submitted to solutions of decreasing osmolarity 50% of VP₂-type vesicles lysed at (mean + S.E. (number of experiments)) 332 ± 14 (4) mosM and 50% of VP₁-type vesicles lysed at 573 ± 8 (3) mosM. These results indicate that recycling vesicles are more resistant to hypo-osmotic lysis and they are consistent with our earlier conclusion that changes in water content on recycling are secondary to changes in the content of the osmotically active small-molecular-mass constituents acetylcholine and ATP.     

Highly enriched,minimally disrupted plasma membrane vesicles from aortic myocytes grown in primary culture

A plasma membrane-enriched fraction (fraction 1B) has been obtained from rat aortic myocytes grown in primary culture. Plasma membrane markers, 5′-nucleotidase and ouabain-sensitive (Na⁺ + K⁺)-ATPase, are enriched 4.1- and 8.7-fold, respectively, in this fraction. Although endoplasmic reticulum marker NADPH-cytochrome c reductase is the most enriched in mitochondrial and heavy sucrose density gradient fractions, substantial enrichment of this marker is also observed in membrane fraction 1. This membrane preparation therefore contains a certain quantity of endoplasmic reticulum. Cytochrome c oxidase is de-enriched by a factor of 0.04 in fraction 1, indicating that it is essentially clear of mitochondrial contamination. Homogenization of aortic media-intima layers using a whole-tissue technique induces greater disruption of mitochondria and subsequent contamination of membrane fractions than does the procedure for cell disruption. Analysis of electrophoretic gels, vesicle density distribution and electron micrographs of enriched membrane fractions provide evidence that plasma membrane enriched from cultured myocytes is less traumatized than comparable fractions obtained from intact tissue. The potential value of such a highly enriched, minimally disrupted plasma membrane preparation is discussed.     

A simple method for the isolation of basolateral plasma membrane vesicles from rat kidney cortex Enzyme activities and some properties of glucose transport

A procedure for preparing basolateral membrane vesicles from rat renal cortex was developed by differential centrifugation and Percoll density gradient centrifugation, and the uptake of d-[³H]glucose into these vesicles was studied by a rapid filtration technique. (Na⁺ + K⁺)-ATPase, the marker enzyme for basolateral membranes, was enriched 22-fold compared with that found in the homogenate. The rate of d-glucose uptake was almost unaffected by Na⁺ gradient (no overshoot).     

Membrane proteins of synaptic vesicles and cytoskeletal specializations at the node of Ranvier in electric ray and rat

Summary Binding sites for antibodies against membrane proteins of synaptic vesicles have been shown to be enhanced at nodes of Ranvier in electromotor axons of the electric ray Torpedo marmorata and sciatic nerve axons of the rat, using indirect immunofluorescence and monoclonal antibodies against the synaptic vesicle transmembrane proteins SV2 and synaptophysin (rat) or SV2 (Torpedo). In the electric lobe of Torpedo, vesicle-membrane constituents occurred at higher density in the proximal axon segments covered by oligodendroglia cells than in the distal axon segments where myelin is formed by Schwann cells. Antibody binding sites were enhanced at nodes forming the borderline of the central and peripheral nervous systems. Filamentous actin was present in the Schwann-cell processes covering both the nodal and the paranodal axon segments as suggested by the pattern of phalloidin labelling. Furthermore, in rat sciatic nerve, Schmidt-Lanterman incisures were intensely labelled by phalloidin. A similar nodal distribution was found for binding sites of antibodies against actin and myosin. Binding of antibodies to tubulin was enhanced at nodes in Torpedo electromotor axons. The apparent nodal accumulation of constituents of synaptic vesicle membranes and the presence of filamentous actin and of myosin are discussed in relation to the substantial constriction of the axoplasm at nodes of Ranvier.     

Glucose transport in thymocyte plasma-membrane vesicles

Calf-thymocyte membrane vesicles, prepared by hypotonic lysis and homogenization, were isolated by standard centrifugal techniques designed for enrichment of plasma membrane. At 20°C, these vesicles equilibrated with d-glucose and 3-O-methyl-d-glucose more rapidly than with l-glucose. About 25% of the equilibrium d-sugar space (6 μl/mg protein) was very slowly penetrated by l-glucose ( ). The time course of d-sugar accumulation in excess of l-glucose accumulation indicated that this space equilibrated with d-glucose and 3-O-methyl-d-glucose with half-times of approximately 0.2–0.4 min. The remainder of the equilibrium d-sugar space (about 75%) appeared equally accessible to both glucose isomers ( to 5 min). This was confirmed in studies of efflux from preloaded vesicles, where the d-glucose space fell with a short half-time (0.2 min) to the l-glucose space, after which the two isomers exited with the same half-time. Addition of sucrose to increase osmolarity reduced both spaces (specific and non-specific) in a manner which indicated that little if any of the vesicle sugar was bound. This was confirmed by the fact that equilibrium glucose space was independent of glucose concentration and by the fact that vesicles immediately lost their sugar when diluted with water at 0°C. These data indicate the presence of two vesicle types, discriminant and indiscriminant as regards transport of the glucose isomers. Entry of d-glucose into the discriminant (stereospecific) vesicles was temperature sensitive (Q₁₀ > 2), saturable (K_m 2 mM), and was inhibited by phloretin (K_i < 200 μM), N-ethylmaleimide (K_i < 10 mM) and cytochalasin B (K_i < 2 μM), suggesting that these vesicles contain the plasma-membrane glucose carrier. Entry of l- and d-glucose into the indiscriminant vesicles showed none of these properties. The equilibrium-exchange K_m and V were about five times the entry K_m and V, indicating the substrate loading greatly facilitates carrier translocation, at least in the outward direction.     

Satnav for cells: Destination membrane fusion

All eukaryotic cells, from budding yeast to plants and mammals, are elaborately subdivided into functionally distinct, membrane-enclosed compartments – or organelles. Each organelle contains its own characteristic set of enzymes and other specialized molecules, which allows for the segregation of distinct biochemical reactions. A complex distribution system transports specific products (or cargos) from one compartment to another, involving a cycle of trafficking vesicle formation from a precursor membrane, vesicle transport to its destination (which may involve use of the cytoskeleton and specific motor proteins) and finally vesicle fusion with its target membrane.In the central nervous system (CNS), rapid communication between neurons at synapses is achieved using such a specialized trafficking pathway. Small synaptic vesicles move to the presynaptic plasma membrane where they fuse in response to Ca²⁺ influx, releasing chemical messengers (neurotransmitters) into the synaptic cleft. Vesicles are then recovered, reformed and refilled with neurotransmitter, ready for subsequent rounds of release. This recycling process may involve fusion with, and reformation from, a specific endosomal recycling station.As correct recycling of synaptic vesicles is essential to maintain neuronal signaling, every aspect of the process has been intensively studied. Amazingly, the general principals elucidated in this system are shared across membrane trafficking pathways in eukaryotes, and are largely mediated by common protein-based machineries. Hence, in this article, I will use the example of neuronal exocytosis to illustrate concepts which currently dominate our thinking about membrane trafficking pathways. In particular, I intend to focus on the all-important issue of how specificity in vesicle transport and fusion is achieved.

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Depolarization-induced release of glycine and beta-alanine from plasma membrane vesicles derived from rat brain synaptosomes

Glycine and beta-alanine actively loaded into brain synaptic plasma membrane vesicles were released into the external medium by using the classical depolarization agents high K+ and veratridine. This release occurs via a Ca2+-independent process. Measurements of membrane depolarization using tetraphenylphosphonium uptake show a close correlation between changes in the membrane potential and stimulation of the efflux process. Results shown herein and previously reported by our group (Aragón, M.C. and Giménez, C. (1986) Biochim. Biophys. Acta 855, 257-264; Agulló, L., Jiménez, B., Aragón, M.C. and Giménez, C. (1986) Eur. J. Biochem. 159, 611-617), suggest that the glycine and beta-alanine transport systems in synaptic plasma membranes are susceptible of modulation by changes in ionic fluxes and hence in the membrane potential, similar to those occurring during depolarization and repolarization.     

Immunoisolation and subfractionation of synaptic vesicle proteins

Within recent years, the advances in proteomics techniques have resulted in considerable novel insights into the protein expression patterns of specific tissues, cells, and organelles. The information acquired from large-scale proteomics approaches indicated, however, that the proteomic analysis of whole cells or tissues is often not suited to fully unravel the proteomes of individual organellar constituents or to identify proteins that are present at low copy numbers. In addition, the identification of hydrophobic proteins is still a challenge. Therefore, the development of techniques applicable for the enrichment of low-abundance membrane proteins is essential for a comprehensive proteomic analysis. In addition to the enrichment of particular subcellular structures by subcellular fractionation, the spectrum of techniques applicable for proteomics research can be extended toward the separation of integral and peripheral membrane proteins using organic solvents, detergents, and detergent-based aqueous two-phase systems with water-soluble polymers. Here, we discuss the efficacy of a number of experimental protocols. We demonstrate that the appropriate selection of physicochemical conditions results in the isolation of synaptic vesicles of high purity whose proteome can be subfractionated into integral membrane proteins and soluble proteins by several phase separation techniques.     

Isolation and assay of corn root membrane vesicles with reduced proton permeability

Conditions promoting the formation of sealed membrane vesicles from corn roots with reduced proton permeability were examined using the probe 9-aminoacridine as a rapid indicator of pH gradient formation and dissipation. Plasma membrane vesicles isolated by differential and density gradient centrifugation were leaky to protons and rapidly equilibrated when exposed to artificially imposed pH gradients. The leaky plasma membrane vesicles showed reduced proton permeability when incubated with calcium or with excess phospholipids. However, these vesicles were unable to form ATP-induced pH gradients. Sealed vesicles isolated by discontinuous Ficoll gradient centrifugation of a microsomal fraction displayed reduced proton permeability and were osmotically active. In contrast to purified plasma membrane vesicles, the microsomal-derived vesicles were more suitable for studies of active proton transport.