Topography of glycoproteins in the chick synaptosomal plasma membrane

Chick brain synaptosomes or synaptic subfractions were treated with neuraminidase (EC 3.2.1.18) and/or galactose oxidase (EC 1.1.3.9) preparations in which proteolytic activity was inhibited with phenylmethanesulfonyl fluoride followed, after washing, by reductive incorporation of sodium boro[³H]hydride to identify galactose residues exposed on the synaptosomal external surface. Control experiments to demonstrate restriction of labeling to the external surface involved comparing the radioactivity in synaptoplasmic, soluble polypeptides isolated after labeling with labeled, isolated synaptoplasm and examining incorporation into fractions incubated without enzymes. Intactness of the synaptic plasma membrane after labeling was shown by trypsin digestion studies. Polypeptides were separated on sodium dodecyl sulfate polyacrylamide gels and were detected by a liquid scintillation counting procedure. Eleven major radioactive peaks were found after galactose oxidase treatment and reduction of isolated synaptic membranes. When intact synaptosomes were labeled, the same components were detected. When isolated synaptic membranes or intact synaptosomes were treated with neuraminidase before galactose oxidase treatment, three additional components were labeled. These results suggest that (a) chick synaptic membranes have a complex mixture of glycoproteins, (b) all major chick synaptic membrane glycoproteins labeled by galactose oxidase have most or all carbohydrate groups exposed at the exterior surface of the synaptosome, (c) all major, externally-disposed polypeptides of these synaptic membranes are glycoproteins.     

Analysis of polypeptide disposition in human erythrocyte membranes employing membrane inversion

High resolution segregation of erythrocyte membrane polypeptides achieved by isoelectric focusing in 8 M urea was employed in conjunction with surface-restricted radioiodination to analyze the disposition of polypeptides within the human erythrocyte membrane. Several membrane polypeptides showed significant uptake of radioiodine, with the principal labeled component migrating between pH values of 3.0 and 3.5. Two approaches were taken in examining membrane polypeptide disposition on both faces of the erythrocyte membrane. Saturation labeling of the outer face of the membrane with one iodine isotope followed by cell lysis and re-iodination with a second iodine isotope did not prove feasible and another procedure based on surface iodination with ¹²⁵I, formation of sealed inside-out vesicles and re-iodination with ¹³¹I was adopted. Studies of sialic acid release from the membrane surface and trypsin cleavage of radioiodinated peptides indicated that selectively labeled, sealed inside-out vesicles had been formed. The ratio of ¹²⁵I to ¹³¹I in membrane polypeptides separated by isoelectric focusing confirmed the existence of externally disposed, internally disposed and spanning proteins.     

Analysis of polypeptide disposition in human erythrocyte membranes employing membrane inversion.

High resolution segregation of erythrocyte membrane polypeptides achieved by isoelectric focusing in 8 M urea was employed in conjunction with surface-restricted radioiodination to analyze the disposition of polypeptides within the human erythrocyte membrane. Several membrane polypeptides showed significant uptake of radioiodine, with the principal labeled component migrating between pH values of 3.0 and 3.5. Two approaches were taken in examining membrane polypeptide disposition on both faces of the erythrocyte membrane. Saturation labeling of the outer face of the membrane with one iodine isotope followed by cell lysis and reiodination with a second iodine isotope did not prove feasible and another procedure based on surface iodination with 125-I, formation of sealed inside-out vesicles and re-iodination with 131-I was adopted. Studies of sialic acid release from the membrane surface and trypsin cleavage of radioiodinated peptides indicated that selectively labeled, sealed inside-out vesicles had been formed. The ratio of 125-I to 131-I in membrane polypeptides separated by isoelectric focusing confirmed the existence of externally disposed, internally disposed and spanning proteins.     

Structure of the Mouse Mammary Tumor Virus: Polypeptides and Glycoproteins

The polypeptide and glycoprotein compositions of the mouse mammary tumor virus virion from primary monolayer cultures of BALB/cfC3H mouse mammary tumor cells were studied by polyacrylamide gel electrophoresis by using internal and external labeling and Coomassie blue and periodic acid Schiff (PAS) staining. Twelve polypeptides were reproducibly resolved by the combined methods. Five major polypeptides were demonstrable with estimated molecular weights of 52,000, 36,000, 28,000, 14,000, and 10,000. Seven minor polypeptides were also consistently detected and had estimated molecular weights of 70,000, 60,000, 46,000, 38,000, 30,000, 22,000, and 17,000. Carbohydrate was associated with five of these polypeptides as measured by PAS stain or [(3)H] glucosamine labeling, or both. These glycoproteins had estimated molecular weights of 70,000, 60,000, 52,000, 36,000 and 10,000. The majority of the PAS stain and glucosamine was found in the 52,000 and 36,000 dalton peaks.     

Synapsin I-mediated interaction of brain spectrin with synaptic vesicles

We have established a new binding assay in which 125I-labeled synaptic vesicles are incubated with brain spectrin covalently immobilized on cellulosic membranes in a microfiltration apparatus. We obtained saturable, high affinity, salt- (optimum at 50-70 mM NaCl) and pH- (optimum at pH 7.5-7.8) dependent binding. Nonlinear regression analysis of the binding isotherm indicated one site binding with a Kd = 59 micrograms/ml and a maximal binding capacity = 1.9 micrograms vesicle protein per microgram spectrin. The fact that the binding of spectrin was via synapsin was demonstrated in three ways. (a) Binding of synaptic vesicles to immobilized spectrin was eliminated by prior extraction with 1 M KCl. When the peripheral membrane proteins in the 1 M KCl extract were separated by SDS-PAGE, transferred to nitrocellulose paper and incubated with 125I-brain spectrin, 96% of the total radioactivity was associated with five polypeptides of 80, 75, 69, 64, and 40 kD. All five polypeptides reacted with an anti-synapsin I polyclonal antibody, and the 80- and 75-kD polypeptides comigrated with authentic synapsin Ia and synapsin Ib. The 69- and 64-kD polypeptides are either proteolytic fragments of synapsin I or represent synapsin IIa and synapsin IIb. (b) Pure synapsin I was capable of competitively inhibiting the binding of radioiodinated synaptic vesicles to immobilized brain spectrin with a Kl = 46 nM. (c) Fab fragments of anti-synapsin I were capable of inhibiting the binding of radioiodinated synaptic vesicles to immobilized brain spectrin. These three observations clearly establish that synapsin I is a primary receptor for brain spectrin on the cytoplasmic surface of the synaptic vesicle membrane.     

The subpopulation of brain coated vesicles that carries synaptic vesicle proteins contains two unique polypeptides

Coated vesicles have been purified in the past on the basis of their remarkably homogeneous structure, not their function. We have succeeded in isolating two subpopulations of bovine brain coated vesicles that carry specific "cargoes," in this case two synaptic vesicle membrane polypeptides (Mr = 95,000 and 65,000). Monoclonal antibodies that recognize cytoplasmic domains of these polypeptides can penetrate the clathrin coat and recognize them on the outer surface of the coated vesicle membrane. An immunoadsorption technique could therefore be used to fractionate coated vesicles on the basis of their membrane composition. The subpopulations have the normal complement of conventional coated vesicle proteins. Exclusive, however, to the subpopulations that carry synaptic vesicle polypeptides are two new coated vesicle polypeptides (Mr = 38,000 and 29,000).     

Sulfated glycoproteins synthesized by the corneal epithelium of chick embryo having the same molecular weights as cytokeratin polypeptides

The previous study from this laboratory demonstrated that the corneal epithelium of 19-d-old chick embryo synthesizes two classes of sulfated glycoconjugates consisting of sulfated glycoproteins and proteoglycans (Yonekura, H., Oguri, K., Nakazawa, K., Shimizu, S., Nakanishi, Y., & Okayama, M. (1982) J. Biol. Chem. 257, 11166-11175). The present study demonstrated that when the sulfated glycoproteins labeled metabolically with [35S]sulfate and [3H]glucosamine were analyzed by SDS-PAGE, the 70,000 component (accounting for approximately 30% of the 35S and 35% of the 3H of the total sulfated glycoprotein) co-migrated with five major proteins with apparent molecular weights (Mrs) of 70,000, 66,000, 58,000, 51,000, and 48,000, which together accounted for about 57% of the total tissue protein. All five proteins cross-reacted with an antibody against human sole keratin, indicating that they are cytokeratin polypeptides of the corneal epithelium. Amino acid analysis demonstrated that they had high contents of glycine, serine, glutamic acid, leucine, and aspartic acid. Two-dimensional tryptic peptide maps indicated that they were all different. Analysis of radiolabeled materials released by alkaline borohydride treatment of the sulfated glycoproteins which were synthesized in the presence and absence of tunicamycin and co-purified with the five cytokeratin polypeptides, revealed that they contained both N- and O-glycosidically linked sulfated oligosaccharides. All the results obtained in the present study indicate that the five sulfated glycoproteins are similar, if not identical, to the cytokeratin polypeptides. This is consistent with the result in the accompanying paper that these sulfated glycoproteins are localized intracellularly.     

Intermembrane protein transfer. Band 3, the erythrocyte anion transporter, transfers in native orientation from human red blood cells into the bilayer of phospholipid vesicles

Band 3, the erythrocyte anion transporter, has been shown to transfer between human erythrocytes and sonicated vesicles (Newton, A. C., Cook, S. L., and Huestis, W. H. (1983) Biochemistry 22, 6110-6117). Functional band 3 becomes associated with dimyristoylphosphatidylcholine vesicles incubated with human red blood cells. Proteolytic degradation patterns reveal that the transporter is transferred to the vesicles in native orientation. In erythrocytes, native band 3 is degraded on the exoplasmic membrane face by chymotrypsin and on the cytoplasmic surface by trypsin (Cabantchik, Z. I., and Rothstein, A. (1974) J. Membr. Biol. 15, 227-248; Jennings, M. L., Anderson, M. P., and Monaghan, R. (1986) J. Biol. Chem. 261, 9002-9010). Band 3 in intact protein-vesicle complexes is degraded by exogenous chymotrypsin but not by trypsin. In contrast, trypsin entrapped in the lumen of the vesicles proteolyses the vesicle-bound band 3 quantitatively. Band 3 remaining in the membranes of vesicle-treated cells and in cell fragments is not degraded detectably by vesicle-entrapped trypsin. These observations indicate that band 3 is unlikely to transfer between cell and vesicle membranes via a water-soluble form or to adhere nonspecifically to the vesicle surface; the aqueous contents of vesicles and cells (or membrane fragments) are not pooled during cell-vesicle incubations, hence no cell-vesicle fusion occurs; and the band 3 associated with the sonicated vesicle fraction is inserted in the vesicle bilayer in native orientation, with its cytoplasmic segment contacting the aqueous contents of the vesicle lumen.     

Orientation of the cytoplasmically made subunits of beef heart cytochrome c oxidase determined by protease digestion and antibody binding experiments

The topology of several of the cytoplasmically made subunits of beef heart cytochrome c oxidase has been determined by protease digestion of oriented membrane preparations, using subunit-specific antibodies to identify cleavage products. Reconstituted vesicles of cytochrome c oxidase and asolectin were used as a vesicle preparation with the C domain of the enzyme available for protease digestion. Submitochondrial particles were used as vesicles with the M domain outermost. Trypsin and/or proteinase K cleaved polypeptides CIV, ASA, AED, STA, and IHQ. Cleavage of CIV, STA, and IHQ was from the M domains only and involved the removal of a fragment from the N-terminus in each case. Polypeptide AED was cleaved from the C side in the N-terminal part, while ASA was cleaved from both the C and M domains. Polypeptide fragments were electroblotted from polyacrylamide gels onto derivatized glass paper and sites of proteolytic cleavage determined by N-terminal sequence analysis.     

Mutations in synaptojanin disrupt synaptic vesicle recycling

Synaptojanin is a polyphosphoinositide phosphatase that is found at synapses and binds to proteins implicated in endocytosis. For these reasons, it has been proposed that synaptojanin is involved in the recycling of synaptic vesicles. Here, we demonstrate that the unc-26 gene encodes the Caenorhabditis elegans ortholog of synaptojanin. unc-26 mutants exhibit defects in vesicle trafficking in several tissues, but most defects are found at synaptic termini. Specifically, we observed defects in the budding of synaptic vesicles from the plasma membrane, in the uncoating of vesicles after fission, in the recovery of vesicles from endosomes, and in the tethering of vesicles to the cytoskeleton. Thus, these results confirm studies of the mouse synaptojanin 1 mutants, which exhibit defects in the uncoating of synaptic vesicles (Cremona, O., G. Di Paolo, M.R. Wenk, A. Luthi, W.T. Kim, K. Takei, L. Daniell, Y. Nemoto, S.B. Shears, R.A. Flavell, D.A. McCormick, and P. De Camilli. 1999. Cell. 99:179-188), and further demonstrate that synaptojanin facilitates multiple steps of synaptic vesicle recycling.     

Purification of measles virus and characterization of subviral components.

Purified measles virus was obtained from [35S]methionine-labeled cells infected at 33 degrees C and maintained in the absence of fetal calf serum. The pellet that was produced by a single high-speed ultracentrifuge spin of culture medium contained virus of purity sufficient for structural analysis. Purified virions contain seven polypeptides with estimated molecular weights of: L, 200,000; G, 80,000; P2, 70,000; NP, 60,000; A, 43,000; F1, 41,000; and M, 37,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Treatment of virions with 0.25% trypsin resulted in a less dense particle which lacked polypeptides G and F1. Solubilization of the viral membrane with the detergent Triton X-100 in low-salt buffer resulted in the loss of the G polypeptide, whereas in the presence of 1 M KCl, Triton X-100 also removed most of the M polypeptide. The nucleocapsids (p = 1.3) obtained from virions treated with Triton X-100 and 1 M KCl contained the L, P2, NP, and M polypeptides. Nucleocapsids isolated from the cytoplasm of infected cells were predominantly composed of the NP polypeptide with smaller amounts of either polypeptide P2 or novel polypeptides, related to NP, with estimated molecular weights of 56,000 to 58,000 and 45,000 to 46,000. A significant amount of polypeptide L was always found in association with nucleocapsids isolated either from virions or from the cytoplasm of infected cells. A membrane component containing the viral membrane polypeptides G, F1, and M was also isolated from infected cells. The data presented here thus suggest that L is an integral part of the nucleocapsid complex. In addition, 37,000-molecular-weight polypeptide (M) appears to have the function described for the matrix proteins of other paramyxoviruses.     

Platelet plasma membrane glycoproteins Identification of a proteolytic substrate for thrombin

The surface glycoproteins of the platelet plasma membrane were labeled by oxidation with galactose oxidase followed by reduction with (³H)-sodium borohydride. Of the glycoproteins labeled, only glycoprotein V (apparent molecular weight of 89,000) was decreased as a result of thrombin action. The affected glycoprotein appeared to be completely removed at a concentration of 1 U thrombin per 10⁹ platelets. A soluble glycopeptide hydrolytic product with an apparent molecular weight of 70,000 was released into solution.     

Sugar transport and potassium permeability in yeast plasma membrane vesicles

Plasma membrane vesicles were isolated from homogenised yeast cells by filtration, differential centrifugation and aggregation of the mitochondrial vesicles at pH 4. As judged by biochemical, cell electrophoretic and electron microscopic criteria a pure plasma membrane vesicle preparation was obtained.The surface charge density of the plasma membrane vesicles is similar to that of intact yeast cells with an isoelectric point below pH 3. The mitochondrial vesicles have a higher negative surface charge density in the alkaline pH range. Their isoelectric point is near pH 4.5, where aggregation is maximal.The yield of vesicles sealed to K⁺ was maximal at pH 4 and accounted for about one third of the total vesicle volume.The plasma membrane vesicles demonstrate osmotic behaviour, they shrink in NaCl solutions when loosing K⁺.As in intact yeast cells the entry and exit of sugars like glucose or galactose in plasma membrane vesicles is inhibited by UO₂²⁺.Counter transport in plasma membrane vesicles with glucose and mannose and iso-counter transport with glucose suggests that a mobile carrier for sugar transport exists in the plasma membrane.After galactose pathway induction in the yeast cells and subsequent preparation of plasma membrane vesicles the uptake of galactose into the vesicles increased by almost 100% over the control value without galactose induction. This increase is explained by the formation of a specific galactose carrier in the plasma membrane.     

Ca2+ transport against its electrochemical gradient in cytochrome oxidase vesicles reconstituted with mitochondrial hydrophobic proteins

Cytochrome oxidase vesicles have recently been shown to accumulate Ca²⁺ in an energy-dependent manner. Energization of these vesicles with internally trapped cytochrome c and externally added ascorbate and phenazine methylsulfate generated an internally positive membrane potential and prevented Ca²⁺ influx (R. N. Rosier and T. E. Gunter, 1980, FEBS Lett.109, 99–103). In contradistinction, when cytochrome oxidase vesicles were reconstituted with complex V, a mitochondrial protein fraction containing the uncoupler binding site (Y. Hatefi, D. L. Stiggall, Y. Galante and W. G. Hanstein, 1974, Biochem. Biophys. Res. Commun.61, 313–321), both Ca²⁺ uptake and generation of an internally positive membrane potential were observed. The uptake was specifically dependent on energization of electron transport. Control experiments verified that the energization conditions used produced appropriately oriented membrane potentials. Other partially purified hydrophobic mitochondrial protein complexes were found to be less effective than complex V. The reconstituted system showed cation selectivity since Ca²⁺, Mn²⁺, and Rb⁺ were transported, while Na⁺ was not. Low levels of uncoupler, which did not affect oxidation rates, were found to partially inhibit Ca²⁺ uptake regardless of the membrane potential polarity. Uncoupling levels of uncoupler markedly inhibited Ca²⁺ uptake in internally negative cytochrome oxidase vesicles; however, inhibition in internally positive cytochrome oxidase vesicles was less relative to that at lower levels of uncoupler. The uncoupling combination of nigericin, valinomycin, and K⁺ was inhibitory to uptake regardless of membrane potential polarity. A reconstituted system of oxidative phosphorylation, which contains a hydrophobic protein fraction, energized with cytochrome oxidase similarly accumulated Ca²⁺ despite formation of an internally positive membrane potential. The results suggest that cytochrome oxidase, when coupled to appropriate hydrophobic mitochondrial proteins, can act as an electrogenic Ca²⁺ pump deriving its energy directly from electron transport.     

Calcium dependent neurotransmitter release and protein phosphorylation in synaptic vesicles.

A highly purified preparation of synaptic vesicles was prepared to study the relationship between calcium-dependent neurotransmitter release and protein phosphorylation. Calcium ions simultaneously produced significant increases in both the endogenous release of norepinephrine from the synaptic vesicles and the endogenous incorporation of [³²p] phosphate into specific synaptic vesicle proteins. The results are compatible with the hypothesis that the action of calcium on the phosphorylation of specific synaptic vesicle proteins is the molecular mechanism mediating some of the effects of calcium on neurotransmitter release and synaptic vesicle function.     

Topological localization of proteolytic sites of sodium and potassium ion stimulated adenosinetriphosphatase

The (Na+ and K+)-stimulated adenosinetriphosphatase [(Na+,K+)-ATPase] consists of two different polypeptides, alpha and beta, both of which are embedded in the plasma membrane. The alpha chain from dog kidney (Na+,K+)-ATPase can be hydrolyzed at specific sites by trypsin and chymotrypsin [Castro, J., & Farley, R. A. (1979) J. Biol. Chem. 254, 2221-2228]. In order to position these sites with respect to the lipid bilayer, we have treated sealed, inside out vesicles from human red cells and unsealed kidney enzyme membranes with trypsin and chymotrypsin and have used ouabain-stimulated phosphorylation to identify the (Na+,K+)-ATPase and its fragments. All of the proteolytic sites observed in the kidney membranes are accessible in the inside out vesicles. The ouabain-inhibitable uptake of 86Rb+ in human red blood cells is resistant to externally added chymotrypsin. These results indicate that the proteolytic sites of the (Na+,K+)-ATPase are exposed on the cytoplasmic side of the membrane.     

Synapsin I (protein I), a nerve terminal-specific phosphoprotein. III. Its association with synaptic vesicles studied in a highly purified synaptic vesicle preparation

Synapsin I (protein I) is a neuron-specific phosphoprotein, which is a substrate for cAMP-dependent and Ca/calmodulin-dependent protein kinases. In two accompanying studies (De Camilli, P., R. Cameron, and P. Greengard, and De Camilli, P., S. M. Harris, Jr., W. B. Huttner, and P. Greengard, 1983, J. Cell Biol. 96:1337-1354 and 1355-1373) we have shown, by immunocytochemical techniques at the light microscopic and electron microscopic levels, that synapsin I is present in the majority of, and possibly in all, nerve terminals, where it is primarily associated with synaptic vesicles. In the present study we have prepared a highly purified synaptic vesicle fraction from rat brain by a procedure that involves permeation chromatography on controlled-pore glass as a final purification step. Using immunological methods, synapsin I concentrations were determined in various subcellular fractions obtained in the course of vesicle purification. Synapsin I was found to copurify with synaptic vesicles and to represent approximately 6% of the total protein in the highly purified synaptic vesicle fraction. The copurification of synapsin I with synaptic vesicles was dependent on the use of low ionic strength media throughout the purification. Synapsin I was released into the soluble phase by increased ionic strength at neutral pH, but not by nonionic detergents. The highly purified synaptic vesicle fraction contained a calcium-dependent protein kinase that phosphorylated endogenous synapsin I in its collagenase-sensitive tail region. The phosphorylation of this region appeared to facilitate the dissociation of synapsin I from synaptic vesicles under the experimental conditions used.     

The effect of limited proteolysis on GTP-dependent Ca2+ efflux and GTP-dependent fusion in rat liver microsomal vesicles.

1. Limited proteolytic digestion of rat liver microsomes (microsomal fractions) with trypsin (5 micrograms/ml), proteinase K (1.0 microgram/ml) and Pronase (20 micrograms/ml final concns.) resulted in abolition of GTP-dependent vesicle fusion. 2. Vesicle fusion could be partially restored to microsomes which had undergone limited tryptic digestion, by the addition of untreated microsomal vesicles. 3. GTP-dependent Ca2+ efflux from rat liver microsomes was also observed to be inhibited by limited proteolysis with trypsin and proteinase K. 4. Limited proteolysis of rat liver microsomes had no effect on subsequent GTP-dependent phosphorylation of polypeptides of Mr 17,000 and 38,000, and thus it is unlikely that the phosphorylation of these proteins is involved in GTP-dependent Ca2+ efflux and GTP-dependent vesicle fusion. 5. GTP binding by Gn proteins [proteins which bind GTP after transfer to nitrocellulose, as defined by Bhullar & Haslam (1986) Biochem. J. 245, 617-620] was inhibited by pre-treatment of microsomes with trypsin, proteinase K and Pronase at concentrations similar to those which abolished GTP-dependent Ca2+ efflux and vesicle fusion. 6. We suggest that one or more of the Gn proteins may be involved in the molecular mechanisms of GTP-dependent vesicle fusion and Ca2+ efflux in rat liver microsomes and that limited proteolytic digestion may be a useful tool in further investigation of these processes.     

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     

A Semiquantitative Theory of Synaptic Vesicle Movements

Under the assumption that vesicles are the anatomic correlate of quantal release, the forces governing the movement of synaptic vesicles inside neurons are analyzed. Semiquantitative calculations are presented to show that a diffuse layer field penetrates a few Debye lengths into the axoplasm. This field binds tightly a monolayer of water to the membrane forming the potential barrier for miniature end-plate potential (mepp) release. The action potential destroys the monolayer and pulls the vesicle to the membrane. The vesicles are brought to the synaptic zone and held there by a Na⁺ leak in the synaptic membrane. A stochastic theory of synaptic vesicle release is presented to explain experimental results. The rate of vesicle release is fractionated into a rate of membrane contacts by a vesicle and a rate of vesicle discharge per contact.