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.     

Na+-transporting ATPase in the plasma membrane of halotolerant microalga Dunaliella maritima operates as a Na+ uniporter

A fraction of inside-out membrane vesicles enriched in plasma membranes (PM) was isolated from Dunaliella maritima cells. Attempts were made to reveal ATP-driven Na⁺-dependent H⁺ efflux from the PM vesicles to external medium, as detected by alkalization of the vesicle lumen. In parallel experiments, ATP-dependent Na⁺ uptake and electric potential generation in PM vesicles were investigated. The alkalization of the vesicle lumen was monitored with an impermeant pH-sensitive optical probe pyranine (8-hydroxy-1,3,6-pyrenetrisulfonic acid), which was loaded into vesicles during the isolation procedure. Sodium uptake was measured with ²²Na⁺ radioactive label. The generation of electric potential in PM vesicles (positive inside) was recorded with a voltage-sensitive probe oxonol VI. Appreciable Na⁺-and ATP-dependent alkalization of vesicle lumen was only observed in the presence of a protonophore CCCP (carbonyl cyanide-chlorophenylhydrazone). In parallel experiments, CCCP accelerated the ATP-dependent ²²Na⁺ uptake and abolished the electric potential generated by the Na⁺-ATPase at the vesicle membrane. A permeant anion NO^? ₃ accelerated ATP-dependent ²²Na⁺ uptake and promoted dissipation of the electric potential like CCCP did. At the same time, NO^? ₃ inhibited the ATP-and Na⁺-dependent alkalization of the vesicle lumen. The results clearly show that the ATP-and Na⁺-dependent H⁺ efflux from PM vesicles of D. maritima is driven by the electric potential generated at the vesicle membrane by the Na⁺-ATPase. Hence, the Na⁺-transporting ATPase of D. maritima carries only one ion species, i.e., Na⁺. Proton is not involved as a counter-ion in the catalytic cycle of this enzyme.     

Processive interfacial catalytic turnover by Bacillus cereus sphingomyelinase on sphingomyelin vesicles

Sphingomyelinase (SMase), a water-soluble enzyme from Bacillus cereus, is shown to bind with high affinity to vesicles of sphingomyelin (SM) but not to vesicles of phosphatidylcholine (PC). The reaction progress by SMase bound to SM vesicles occurs in the scooting mode with virtually infinite processivity of the successive interfacial turnover cycles. Three conditions for the microscopic steady state during the reaction progress at the interface are satisfied: the bound SMase does not leave the interface even after all the SM in the outer layer is converted to ceramide; the SMase-treated vesicles remain intact; and the ceramide product does not exchange with SM present in excess vesicles or in the inner layer of the hydrolyzed vesicle. Within these constraints, on accessibility and replenishment of the substrate, the extent of hydrolysis in the scooting mode reaction progress is a measure of the number of vesicles containing enzyme. The slope of the Poisson distribution plot, for the enzyme per vesicle versus the logarithm of the fraction of the total accessible substrate remaining unhydrolyzed in excess vesicles, shows that a single 32 kDa subunit of SMase is fully catalytically active. The maximum initial rate of hydrolysis, at the limit of the maximum possible substrate mol fraction, X_S*=1, is 400 s^?1 in H₂O and 220 s^?1 in D₂O, which is consistent with the rate-limiting chemical step. The integrated reaction progress suggests that the ceramide product does not codisperse ideally on the hydrolyzed vesicles. Furthermore, complex reaction progress seen with covesicles of SM+PC are attributed to slow secondary changes in the partially hydrolyzed SM vesicles.     

19F-NMR of fluorine labeled acyl chains in phospholipid bilayer vesicles

¹⁹F-labeled phospholipids, L-α-bis-(ω-fluoro palmitoyl)phosphatidylcholine, L-α-bis-(12,12-difluoro stearoyl)phosphatidylcholine and L-α-bis-(6,6-difluoro palmitoyl)phosphatidylcholine, were incorporated in phospholipid vesicles by sonication of aqueous lipid emulsions. Vesicles were prepared both from the pure fluorine substituted phospholipids as well as from lipid mixtures obtained by combining the fluorine substituted lipids with the synthetic phospholipids, L-α-dilauroyl-, L-α-dimyristoyl-, L-α-dipalmitoyl- and L-α-distearoyl-phosphatidylcholine. Characterization by gel permeation chromatography showed that stable unilamellar vesicles with diameters of ≌200 Å could be obtained with a minimum or absence of multilamellar material. The vesicles give rise to two ¹⁹F resonances in most cases as observed previously [K.J. Longmuir and F.W. Dahlquist, Proc. Natl. Acad. Sci. U.S.A., 73 (1976) 2716]. The chemical shift differences undergo systematic changes that confirm the interpretations that the dual ¹⁹F resonances arise from the inner and outer halves of the vesicle bilayer. The shift separation increases systematically as the fluorine label is positioned closer to the phospholipid headgroup and decreases systematically with increasing temperature. Both observations agree with what is currently known about phospholipid vesicle structure. Anomalous results are obtained with DSPC as host vesicle since only a single resonance of inbedded fluorinated phospholipids is found.     

Transverse location of the retinal chromophore of rhodopsin in rod outer segment disc membranes

Diffusion-enhanced fluorescence energy transfer was used to study the structure of photoreceptor membranes from bovine retinal rod outer segments. The fluorescent energy donor was Tb³⁺ chelated to dipicolinate and the acceptor was the 11-cis retinal chromophore of rhodopsin in vesicles made from disc membranes. The rapid-diffusion limit for energy transfer was attained in these experiments because of the long excited state lifetime of the terbium donor (~2 ms). Under these conditions, energy transfer is very sensitive to a, the distance of closest approach between the donor and acceptor (Thomas et al., 1978). Vesicles containing terbium dipicolinate in their inner aqueous space were prepared by sonicating disc membranes in the presence of this chelate and chromatographing this mixture on a gel filtration column. The sidedness of rhodopsin in these vesicles was the same as in native disc membranes. The transfer efficiency from terbium to retinal in this sample was 43%. For an R₀ value of 46.7 Å and an average vesicle diameter of 650 Å, this corresponds to an a value of 22 Å from the inner aqueous space of the vesicle. The distance of closest approach from the external aqueous space, determined by adding terbium dipicolinate to a suspension of already formed vesicles, was found to be 28 Å. These values of a show that the retinal chromophore is far from both aqueous surfaces of the disc membrane. Hence, the transverse location of the retinal chromophore is near the center of the hydrophobic core of the disc membrane. These findings suggest that conformational changes induced by photoisomerization are transmitted through a distance of at least 20 Å within rhodopsin to trigger subsequent events in visual excitation.     

The interaction of lanthanide and calcium salts with phospholipid bilayer vesicles: The validity of the nuclear magnetic resonance method for determination of vesicle bilayer phospholipid surface ratios

Contrary to a recent report (B. Sears et al., Biochemistry 15 (1976) 1635), it has been determined that the ratio of the number of phospholipids on the inner and outer surfaces of phospholipid bilayer vesicles can be accurately determined by NMR paramagnetic ion shift reagent studies of vesicles. It is concluded that the metal interacts with all of the phospholipid on the exposed bilayer surface. A ratio of outer phospholipid to inner surface phospholipid of 2.1 ± 0.1 is obtained regardless of the nucleus studies, position of the nucleus relative to the metal ion binding site, molar ratio of metal to phospholipid over three orders of magnitude, or location of the metal ion on the inside or outside of the vesicle. Additionally, P-31 NMR studies using LaCl₃ and CaCl₂ indicate that Ca²⁺ weakly interacts with egg PC vesicles and than the lanthanides are adequate substitutes for Ca²⁺ since neither metal is found to perturb measurably the average polar head group conformation.     

Synaptophysin and synapsin I as tools for the study of the exo-endocytotic cycle

Synaptophysin, an integral protein of the synaptic vesicle membrane, and synapsin I, a phosphoprotein associated with the cytoplasmic side of synaptic vesicles, represent useful markers that allow to follow the movements of the vesicle membrane during recycling. The use of antibodies against these proteins to label nerve terminals during experimental treatments which stimulate secretion has provided evidence that during the exo-endocytotic cycle synaptic vesicles transiently fuse with the axolemma, from which they are specifically recovered. When recycling is blocked, exocytosis leads to the permanent incorporation of the synaptic vesicle membrane into the axolemma and to diffusion of the vesicle components in the plane of the membrane.     

Extracellular charge adsorption influences intracellular electrochemical homeostasis in amphibian skeletal muscle

The membrane potential measured by intracellular electrodes, E_m, is the sum of the transmembrane potential difference (E₁) between inner and outer cell membrane surfaces and a smaller potential difference (E₂) between a volume containing fixed charges on or near the outer membrane surface and the bulk extracellular space. This study investigates the influence of E₂ upon transmembrane ion fluxes, and hence cellular electrochemical homeostasis, using an integrative approach that combines computational and experimental methods. First, analytic equations were developed to calculate the influence of charges constrained within a three-dimensional glycocalyceal matrix enveloping the cell membrane outer surface upon local electrical potentials and ion concentrations. Electron microscopy confirmed predictions of these equations that extracellular charge adsorption influences glycocalyceal volume. Second, the novel analytic glycocalyx formulation was incorporated into the charge-difference cellular model of Fraser and Huang to simulate the influence of extracellular fixed charges upon intracellular ionic homeostasis. Experimental measurements of E_m supported the resulting predictions that an increased magnitude of extracellular fixed charge increases net transmembrane ionic leak currents, resulting in either a compensatory increase in Na⁺/K⁺-ATPase activity, or, in cells with reduced Na⁺/K⁺-ATPase activity, a partial dissipation of transmembrane ionic gradients and depolarization of E_m.     

The Role of Membrane Lateral Tension in Calcium-Induced Membrane Fusion

Calcium-induced fusion of liposomes was studied with a view to understand the role of membrane tension in this process. Lipid mixing due to fusion was monitored by following fluorescence of rhodamine-phosphatidyl-ethanolamine incorporated into liposomal membrane at a self-quenching concentration. The extent of lipid mixing was found to depend on the rate of calcium addition: at slow rates it was significantly lower than when calcium was injected instantly. The vesicle inner volume was then made accessible to external calcium by adding calcium ionophore A23187. No effect on fusion was observed at high rates of calcium addition while at slow rates lipid mixing was eliminated. Fusion of labeled vesicles with a planar phospholipid membrane (BLM) was studied using fluorescence microscopy. Above a threshold concentration specific for each ion, Ca²⁺, Mg²⁺, Cd²⁺ and La³⁺ induce fusion of both charged and neutral membranes. The threshold calcium concentration required for fusion was found to be dependent on the vesicle charge, but not on the BLM charge. Pretreatment of vesicles with ionophore and calcium inhibited vesicle fusion with BLM. This effect was reversible: chelation of calcium prior to the application of vesicle to BLM completely restored their ability to fuse. These results support the hypothesis that tension in the outer monolayer of lipid vesicle is a primary reason for membrane destabilization promoting membrane fusion. How this may be a common mechanism for both purely lipidic and protein-mediated membrane fusion is discussed. Received: 27 September 1999/Revised: 22 March 2000     

Optical study of active ion transport in lipid vesicles containing reconstituted Na,K-ATPase

Summary A fluorescence method is described for the measurement of ATP-driven ion fluxes in lipid vesicles containing purified Na,K-ATPase. The membrane voltage of enzyme containing vesicles was measured by using a voltage-sensitive indocyanine dye. By addition of valinomycin the vesicle membrane is made selectively permeable to K⁺ so that the membrane voltage approaches the Nernst potential for K⁺. With constant external K⁺ concentration, the time course of internal K⁺ concentration can be continuously measured as change of the fluorescence signal after activation of the pump. The optical method has a higher time resolution than tracer-flux experiments and allows an accurate determination of initial flux rates. From the temperature dependence of active K⁺ transport its activation energy was determined to be 115 kJ/mol. ATP-stimulated electrogenic pumping can be measured as a fast fluorescence change when the membrane conductance is low (i.e., at low or zero valinomycin concentration). In accordance with expectation, the amplitude of the fast signal change increases with decreasing passive ion permeability of the vesicle membrane. The resolution of the charge movement is so high that a few pump turnovers can be easily detected.     

Subaxolemmal filamentous network in the giant nerve fiber of the squid (Loligo pealei L.) and its possible role in excitability

A new technique utilizing the squid giant nerve fiber has been developed which permits direct examination of the inner face of the axolemma by scanning electron microscopy. The axoplasm was removed sequentially in a 15-mm long segment of the fiber by intracellular perfusion with a solution of KF, KCl, Ca++-containing seawater, or with pronase. The action potential of the fibers was monitored during these treatments. After brief prefixation in 1% paraformaldehyde and 1% glutaraldehyde, the perfused segment was opened by a lne could be related to information on the detailed morphology of the cytoplasmic face of the axolemma and the ectoplasm. The results obtained by scanning electron microscopy were further substantiated by transmission electron microscopy of thin sections. In addition, living axons were studied with polarized light during axoplasm removal, and the identification of actin by heavy meromyosin labeling and sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis was accomplished. These observations demonstrate that a three-dimensional network of interwoven filaments, consisting partly of an actinlike protein, is firmly attached to the axolemma. The axoplasmic face of fibers in which the filaments have been removed partially after perfusion with pronase displays smooth membranous blebs and large profiles which sppose the axolemma. In fibers where the excitability has been suppressed by pronase perfusion, approximately one-third of the inner face of the axolemma in the perfusion zone is free of filaments. It is hypothesized that the attachment of axoplasm filaments to the axolemma may have a role in the maintenance of the normal morphology of the axolemma, and, thus, in some aspect of excitability.     

Calculation of free energy barriers to the fusion of small vesicles

The fusion of small vesicles, either with a planar bilayer or with one another, is studied using a microscopic model in which the bilayers are composed of hexagonal- and lamellar-forming amphiphiles. The free energy of the system is obtained within the self-consistent field approximation. We find that the free energy barrier to form the initial stalk is hardly affected by the radius of the vesicle, but that the barrier to expand the hemifusion diaphragm and form a fusion pore decreases rapidly as the radius decreases. As a consequence, once the initial barrier to stalk formation is overcome, one which we estimate at 13 k_BT for biological membranes, fusion involving small vesicles should proceed with little or no further input of energy.     

Phospholipid vesicle fusion monitored by fluorescence energy transfer.

A method is presented which allows the observation of phospholipid vesicle fusion by the occurrence of Förster resonance energy transfer between the amphiphilic probes dansyldipalmitoylphosphatidylethanolamine and 3-[4-($\text{p}$-N,N-didecylaminostyryl)-1-pyridinium]-propylsulfonate. This method is applied to the Ca⁺⁺ mediated fusion of phosphatidyl serine vesicles.     

Calcium-induced potassium pathway in sided erythrocyte membrane vesicles

We have characterized the asymmetric effect of Ca²⁺ on passive K⁺ permeability in erythrocyte membranes, using inside out and right-side out vesicles. Ca²⁺, but not Mg²⁺, can induce an increase in K⁺ uptake in inside out vesicles. The half-maximal concentration of Ca²⁺ required to induce the K⁺ uptake is 0.2 mM, and the permeability increase is not specific for K⁺. Thus, the Ca²⁺-induced permeation process in inside out vesicles is changed from that in the energy-depleted intact cell which requires only micromolar concentrations of Ca²⁺ and is specific for K⁺. Removal of spectrin had no effect on the vesicle permeability increase due to Ca²⁺. Studies with $\text{N-}\text{ethylmaleimide}$ show that the vesicle channel opening is mediated by a protein and passage is controlled by sulfhydryl groups; furthermore, the Ca²⁺-induced vesicle pathway is distinct from the normal channel for passive K⁺ leak in the absence of Ca²⁺. The protein is sensitive to its phospholipid environment since removal of easily accessible phospholipid head groups on the cytoplasmic face of the vesicles inhibits the Ca²⁺-stimulated channel opening.     

Osmotic water permeability of small intestinal brush-border membranes

Summary A stopped-flow nephelometric technique was used to examine osmotic water flow across small intestinal brush-border membranes. Brush-border membrane vesicles (BBMV) were prepared from rat small intestine by calcium precipitation. Scattered 500 nm light intensity at 90° to incident was a linear function of the number of vesicles in suspension, and of the reciprocal of the suspending medium osmolality. When BBMV were mixed with hyperosmotic mannitol solutions there was a rapid increase in the intensity of scattered light that could be fit to a single exponential function. The rate constant for vesicle shrinking varied with temperature and the size of the imposed osmotic gradient. At 25°C and an initial osmotic gradient of 50 mOsm, the rate constant was 1.43±0.044 sec^–1. An Arrhenius plot of the temperature dependence of vesicle shrinking showed a break at about 25°C with an activation energy of 9.75±1.04 kcal/mole from 11 to 25°C and 17.2±0.55 kcal/mole from 25 to 37°C. The pore-forming antibiotic gramicidin increased the rate of osmotically driven water efflux and decreased the activation energy of the process to 4.51±0.25 kcal/mole. Gramicidin also increased the sodium permeability of these membranes as measured by the rate of vesicle reswelling in hyperosmotic NaSCN medium. Gramicidin had no effect on mannitol permeability. Assuming spherical vesicles of 0.1 m radius, an osmotic permeability coefficient of 1.2×10^–3 cm/sec can be estimated for the native brush-border membranes at 25°C. These fesults are consistent with the solubility-diffusion model for water flow across small intestinal BBMV but are inconsistent with the existence there of large aqueous pores.     

Activation energy and phospholipid requirements of membrane-bound adenosine triphosphatases

In order to evaluate the role of lipids in the function of membrane ATPase reactions, the apparent activation energies of membrane-bound (Na⁺ + K⁺)-ATPase and membrane-bound Mg²⁺-ATPase have been measured under conditions frequently supposed to alter the membrane lipids in vitro.In the case of (Na⁺ + K⁺)-ATPase, the untreated enzyme was shown to have two different activation energies as shown by an Arrhenius plot comprising two straight lines which intersect at the “critical temperature.” Treatment of the preparation with detergents or with phospholipase C causes some alteration in the spécifie activity of the enzyme but did not significantly alter the activation energies or the critical temperature. After treatment with phospholipase A, however, the Arrhenius plot appeared linear over the entire temperature range studied. Subsequent treatment of phospholipase A-treated preparations with phosphatidylserine restored the control response.Conversely, untreated preparations of Mg²⁺-ATPase give an Arrhenius plot which is neither linear nor composed of two intersecting straight lines. This plot, which we regard as curvilinear, does not permit a unique value of the activation energy to be determined. The shape of this plot is unaltered by detergent or by treatment with phospholipase C. In contrast to (Na⁺ + K⁺)-ATPase, it is also unaffected by treat-with phospholipase A or phospholipase A followed by phosphatidylserine.We conclude that although (Na⁺ + K⁺)-ATPase and Mg²⁺-ATPase are frequently closely associated in many membranes, their functions involve the presence of different membrane lipids.     

Spectrofluorimetric study of porphyrin incorporation into membrane models - evidence for pH effects

The effects of hydrophobicity and charges of dicarboxylic porphyrins upon their interactions with membrane model systems are investigated. Four protonation steps are evidenced from fluorescence emission studies of hematoporphyrin IX and its more hydrophobic parent compound lacking of alcoholic chain, deuteroporphyrin IX. They are attributed to the successive protonations of the inner nitrogens of the porphyrin cycle (pK = 4.7 and 2.9 for hematoporphyrin and 4.4 and 2.7 for deuteroporphyrin) and successive deprotonations of propionic groups (pK ≈ 5.0 and 5.5 for hematoporphyrin and 5.4 and 6.0 for deuteroporphyrin). These porphyrins, as well as their dimethyl ester forms, are shown to incorporate as monomers into the hydrophobic bilayer of egg phosphatidylcholine small unilamellar vesicles, although the esterified forms are highly aggregated in aqueous solutions. In the case of the non-esterified forms, the incorporation of the porphyrins into the lipidic bilayer is reversible and strongly pH-dependent. A theoretical model is presented which takes into account the various protonation steps and the partition equilibria of the porphyrin between the vesicle lipidic phase and the water medium. The neutral form of the porphyrin (i.e., carboxylic groups protonated) presents the higher affinity, with constants of K ≈ 2 · 10⁵ and K ≈ 6 · 10⁶ M⁻¹ (relative to lipid concentration) for hematoporphyrin and deuteroporphyrin, respectively. Protonation of one inner nitrogen leading to the monocationic form is sufficient to prevent incorporation into the hydrophobic bilayer. On the other hand, deprotonation of the peripheral propionic chains leading to anionic forms is less effective. These interactions between vesicles and porphyrins lead to shifts of the apparent pK of nitrogens and carboxylic groups, the latter one being now in the range of physiological pH. These results are discussed with regards to the hypothesis of a possible role of pH in the preferential uptake of porphyrins by tumors.     

Isolation and Characterization of Rapid Transport Vesicle Subtypes from Rabbit Optic Nerve

Subcellular fractionation of rabbit optic nerve resolves three populations of membranes that are rapidly labelled in the axon. The lightest membranes are greater than 200 nm and are relatively immobile. The intermediate density membranes consist of 84 nm vesicles which disappear from the nerve with kinetics identical to those of the rapid component. A third population of membranes, displaying a distinct protein profile, is present in the most dense region of the gradient. Immunological characterization of these membranes suggests the following. (1) The lightest peak contains rapidly transported glucose transporter and most of the total glucose transporters present in the nerve; this peak is therefore enriched in axolemma. (2) The intermediate peak contains rapidly transported glucose transporters and synaptophysin, an integral synaptic vesicle protein, and about half of the total synaptophysin; this peak therefore contains transport vesicles bound for both the axolemma and the nerve terminal, and these subpopulations can be separated by immunoadsorption with specific antibodies against the aforementioned proteins. (3) The heaviest peak contains rapidly transported synaptophysin and tachykinin neuromodulators and about half of the total synaptophysin, and 80% of the total tachykinins present in the nerve; this peak appears to represent a class of synaptic vesicle precursor bound for the nerve terminal exclusively. (4) Synaptophysin is present in the membranes of vesicles carrying tachykinins. (5) Both the intermediate and the heaviest peaks are enriched in kinesin heavy chain, suggesting that both vesicle classes may be transported by the same mechanism.