A spin label method for measuring internal volumes in liposomes or cells, applied to Ca-dependent fusion of negatively charged vesicles

A new spin label - broadening agent system for measuring trapped volumes of vesicles or cells is described. The method seems to be more advantageous than existing procedures when volumes of highly negatively charged vesicles are to be determined. The membrane permeable spin label is TEMPONE (2,2,6,6-tetramethyl piperidone-N-oxyl), and the nonpermeable broadening agent is chromium oxalate (K3Cr(C2O4)3). Absolute values for the trapped volumes down to 0.1% in 0.1 ml can be measured with an accuracy of about +/- (1-10%). The method is used to study the final volume of fused phosphatidylserine vesicles as a function of the temperature at which the Ca-induced fusion takes place.     

A method for replacing intravesicular contents of golgi vesicles using an air-driven ultracentrifuge

Golgi membrane vesicles can be easily and very rapidly (within 10 min.) loaded with solutions of desired composition by centrifugation of the vesicles at high g force in an air-driven ultracentrifuge and subsequent resuspension of the vesicle pellet. This centrifugal/mechanical loading procedure does not destroy the integrity of these vesicles, as demonstrated by the ability of loaded vesicles to (i) retain their contents, (ii) maintain a K+ gradient when loaded with K+ ions, and (iii) exchange internal UMP for external [3H]UMP when loaded with UMP. When radiolabeled solutes are loaded into vesicles, the displaced internal volume can be measured using a rapid filtration assay. This simple and rapid technique of replacing the intravesicular contents of Golgi membrane vesicles should prove useful in studying transport across this membrane and may have a variety of other applications, such as intravesicular volume measurements, macromolecule and drug delivery protocols, and the study of membrane fusion events.     

pKa Values and Partition Coefficients of Nitroxide Spin Probes for Membrane Bioenergetics Measurements

Knowledge of pK_a's is necessary to calculate intracellular/intravesicular pH values from nitroxide accumulation in cells or vesicles as detected with electron spin resonance (ESR) spectroscopy. pK_a values were confirmed in lipid vesicles of known internal pH. To help select probes that do not accumulate in lipid membranes, octanol/buffer partition coefficients of uncharged nitroxides were determined. As an application of selected probes, pH gradients and internal aqueous volumes were analyzed in mitochondria (one internal compartment) and in the cyanobacterium Synechococcus 6311 (two internal compartments). The combination of 3-carboxy-, 3-amino- and 3-aminocarbonyl-2,2,5,5-tetramethylpyrrolidin-1-yloxyl was found to be most satisfactory for determinations of internal pH and volumes.     

Light-induced proton gradients and internal volumes in chromatophores of Rhodopseudomonas sphaeroides

To test the predictions of the chemiosmotic hypothesis, it is essential to have sensitive and accurate measures of the aqueous volume and pH within membrane compartments. One unique feature of the present investigation is the application of electron spin resonance probes to determine internal aqueous volume and pH changes in bacterial chromatophores under virtually identical conditions. Volumes of the chromatophores ranged from 6 to 16 microliter/mg bacteriochlorophyll among different preparations, and were sensitive to the osmolarity of the suspending buffer. pH gradients reached two units in illuminated chromatophores as determined with ESR methods, and increased when KCl and valinomycin were added to the assay. Measurements with the fluorescent dye 9-amino-acridine yielded similar pH gradients, provided that an operational vesicle volume, which corrected for the binding of the dye to the membrane, was used in the calculation. The sensitivity of the ESR method allowed the measurement of pH gradients resulting from only a few light flashes. A plot of pH gradients versus number of flashes was linear up to about 30 flashes, and intercepted the origin. This result is consistent with proton release into the bulk aqueous phase after only a single light flash. This ability to measure small pH gradients offers new opportunities for the study of energy-transducing mechanisms.     

Passive transport of calcium into plasma membrane fractions of myometrium cells

The apparent values of intravesicular volume (45 microliter/mg of protein), maximal capacity of adsorbed calcium binding on the inner surface of the vesicles (4.5 nmol/mg of protein) and dissociation constants for the Ca2+-binding site complexes (36 microM) were determined from the analysis of peculiarities of passive transport of 45Ca2+ into cow myometrium sarcolemmal vesicles. The kinetics of passive efflux of ionized Ca2+ from the vesicles is described by a two-phase exponential curve. Dilution of the vesicles with a dilution medium is associated with a rapid efflux of ionized Ca2+ from the intravesicular space resulting in dissociation of the Ca2+-binding site complexes on the inner surface of the vesicles and, correspondingly, in the passage from a rapid to the slow phase of Ca2+ efflux from the vesicles which is limited by the dissociation of the Ca2+-binding site complexes. The values of the apparent rate constants for the transmembrane transfer of Ca2+ and dissociation of the Ca2+-binding site complexes (0.73 and 0.02 min-1, respectively) and the permeability of sarcolemmal vesicles for the cation (10(-15) mol of Ca2+/cm2.s) were determined. Alkalinization of the dilution medium stimulates 45Ca2+ release from the vesicles. The blockers of passive Co2+ and Mn2+ transport injected into the vesicles inhibit the efflux of 45Ca2+ from the vesicles. The data obtained were used to analyze the role of sarcolemma in the Ca2+ control of myometrium contraction.     

A spin-label assay for metal ion chelation and complex formation.

The electron spin resonance (ESR) lines of nitroxide spin labels are broadened by electron spin exchange reactions that take place during collisions with paramagnetic ions. The degree of line broadening is greatly reduced when the paramagnetic ion forms a coordination bond with certain functional groups on organic molecules. These observations form the basis for a spin-label assay for metal ion chelation and complex formation. This paper describes the characteristics of such an assay for divalent nickel ions and the spin label TEMPONE (2,2,6,6-tetramethylpiperidone-N-oxyl). The chelation of Ni²⁺ by cysteine and the interaction of Ni²⁺ with sodium dodecyl sulfate micelles and phospholipid vesicles are demonstrated. In addition to monitoring interactions of paramagnetic ions, the assay also allows the detection of interactions of nonparamagnetic ions that compete with the paramagnetic ions for binding sites. A kinetic analysis of competition between Ni²⁺ and Zn²⁺ ions for binding sites on phospholipid vesicles is presented. There are several advantages of the spin-label line-broadening assay compared to other conventional assays for metal chelation and complex formation. The line-broadening assay does not require that the sample be optically clear or chemically defined, it requires only very small quantities of material, it can detect as little as 0.4 to 1 μmol of complexing agent, and it may be utilized in complex biological systems including subcellular organelles and macromolecules.     

Spin label studies on osmotically-induced changes in the aqueous cytoplasm of Phaeodactylum tricornutum

The effects of hyperosmotic stress and adaption on the aqueous cytoplasm of Phaeodactylum tricornutum have been studied with spin labels using 0.2M external Ni2+ to obtain spectra solely from labels within the cells. From partitioning of the TEMPO spin label between the internal aqueous phase and the membrane it is found that the internal volume of the cells decreased by approx. 50-60% in media of high osmotic strength (1.9 osmol/l). During the accumulation of proline in the cells (8.8 mg/ml packed cells) on incubation in the medium of high osmolarity for 3 days, the recovery of the volume was 80%. Further addition of proline to the medium resulted in an increase in the proline concentration in the cells (12.2 mg/ml packed cells) and a recovery in volume of 90%. Cells incubated in the absence of any nitrogen source showed very little recovery and were in a stressed state even in the absence of an osmotic gradient. From the rotational correlation times of the TEMPONE spin label it was found that the effective microviscosity in the cytoplasm of normal cells (approx. 3-8 cP) was considerably higher than that of the external medium (1 cP) and increased 1.5-2-fold under high osmotic stress (1.9 osmol/l). Adaption during the accumulation of proline only decreased the effective microviscosity by approx. 50% of the stressed-induced increase, a considerably smaller recovery than that of the cell volume.     

Spin label studies on osmotically-induced changes in the aqueous cytoplasm of Phaeodactylum tricornutum

The effects of hyperosmotic stress and adaption on the aqueous cytoplasm of Phaeodactylum tricornutum have been studied with spin labels using 0.2 M external Ni²⁺ to obtain spectra solely from labels within the cells. From partitioning of the TEMPO spin label between the internal aqueous phase and the membrane it is found that the internal volume of the cells decreased by approx. 50–60% in media of high osmotic strength (1.9 osmol/l). During the accumulation of proline in the cells (8.8 mg/ml packed cells) on incubation in the medium of high osmolarity for 3 days, the recovery of the volume was 80%. Further addition of proline to the medium resulted in an increase in the proline concentration in the cells (12.2 mg/ml packed cells) and a recovery in volume of 90%. Cells incubated in the absence of any nitrogen source showed very little recovery and were in a stressed state even in the absence of an osmotic gradient. From the rotational correlation times of the TEMPONE spin label it was found that the effective microviscosity in the cytoplasm of normal cells (approx. 3–8 cP) was considerably higher than that of the external medium (1 cP) and increased 1.5–2-fold under high osmotic stress (1.9 osmol/l). Adaption during the accumulation of proline only decreased the effective microviscosity by approx. 50% of the stressed-induced increase, a considerably smaller recovery than that of the cell volume.     

Potential-dependent passive transport of calcium in myocardium sarcolemma vesicles

The effect of membrane potential on passive Ca2+ transport in isolated cardiac sarcolemmal vesicles was investigated. The membrane potentials were induced by creating potassium gradients across the vesicular membranes in the presence of valinomycin. The fluorescence changes in the voltage-sensitive dye, dis-C3(5), were consistent with the induction of potassium equilibrium potentials. The rate of 45Ca2+ efflux from inside-out vesicles was considerably greater at 0 than at -80 or +55 mV; prepolarization of the membrane to +90 mV did not enhance the 45Ca2+ efflux upon subsequent depolarization. The voltage-dependent 45Ca2+ efflux increased with a rise in internal Ca2+ concentration and exhibited a saturation effect. Furthermore, evaluation of the rate of 45Ca2+ efflux over a wide range of membrane potentials produced a profile similar to that of current-voltage relationships for single calcium channels in isolated cardiomyocytes. It is concluded that the voltage-dependent Ca2+ efflux from the vesicles occurs via Ca2+-channels.     

Induction of 86Rb fluxes by Ca2+ and volume changes in thymocytes and their isolated membranes

Cell swelling and elevated intracellular Ca2+ increase K+ permeability in lymphocytes. Experiments were performed to test whether these effects can also be elicited in isolated plasma membrane vesicles. Rabbit thymocytes, used as a source of membrane vesicles, were found to regain their volume after swelling in hypotonic, low-K+ media. This regulatory volume decrease (RVD) was inhibited by quinine and trifluoperazine, but not affected by ouabain. Both efflux and uptake of K+ (86Rb) were stimulated by hypotonicity. Addition of A23187 plus Ca2+ also increased 86Rb fluxes. Ca2+- and volume-induced 86Rb fluxes were also studied in isolated membranes. A plasma membrane-rich vesicle fraction, enriched over 11-fold in 5'-nucleotidase, was isolated from thymocytes. The vesicles were about 35% inside-out and trapped 86Rb in an osmotically active compartment of approximately 1.3 microliter/mg protein. Equilibrium exchange fluxes of 86Rb in the vesicles were unaffected by Ca2+ with or without A23187. Calmodulin had no effect on 86Rb permeability but stimulated ATP-dependent Ca2+ accumulation. Hypotonic swelling increased both uptake and efflux of 86Rb from vesicles. However, this increase was not blocked by either quinine or trifluoperazine, was not specific for K+ (86Rb), and is probably unrelated to RVD. It is concluded that components essential for the volume- and Ca2+-induced changes in K+ permeability are lost or inactivated during membrane isolation. An intact cytoarchitecture may be required for RVD.     

Fusion of small unilamellar liposomes with phospholipid planar bilayer membranes and large single-bilayer vesicles

Small unilamellar phosphatidylserine/phosphatidylcholine liposomes incubated on one side of planar phosphatidylserine bilayer membranes induced fluctuations and a sharp increase in the membrane conductance when the Ca2+ concentration was increased to a threshold of 3--5 mM in 100 mM NaCl, pH 7.4. Under the same ionic conditions, these liposomes fused with large (0.2 micrometer diameter) single-bilayer phosphatidylserine vesicles, as shown by a fluorescence assay for the mixing of internal aqueous contents of the two vesicle populations. The conductance behavior of the planar membranes was interpreted to be a consequence of the structural rearrangement of phospholipids during individual fusion events and the incorporation of domains of phosphatidylcholine into the Ca2+-complexed phosphatidylserine membrane. The small vesicles did not aggregate or fuse with one another at these Ca2+ concentrations, but fused preferentially with the phosphatidylserine membrane, analogous to simple exocytosis in biological membranes. Phosphatidylserine vesicles containing gramicidin A as a probe interacted with the planar membranes upon raising the Ca2+ concentration from 0.9 to 1.2 mM, as detected by an abrupt increase in the membrane conductance. In parallel experiments, these vesicles were shown to fuse with the large phosphatidylserine liposomes at the same Ca2+ concentration.     

A permeability change of myelin membrane vesicles towards cations is induced by MgATP but not by phosphorylation of myelin basic proteins

The existence of an endogenous protein kinase activity and protein phosphatase activity in myelin membrane from mammalian brain has now been well established. We found that under all conditions tested the myelin basic protein is almost the only substrate of the endogenous protein kinase in myelin of bovine brain. The protein kinase activity is stimulated by Ca2+ in the micromolar range. Optimal activity is reached at a free Ca2+ concentration of about 2 microM. Myelin membrane vesicles were prepared and then shown to be sealed by a light-scattering technique. After preloading with 45Ca2+, 86Rb+, or 22Na+, the self-diffusion (passive outflux) of these ions from myelin membrane vesicles was measured. Ionophores induced a rapid, concentration-dependent outflux of 80--90% of the cations, indicating that only a small fraction of the trapped ions was membrane bound. There was no difference in the diffusion rates of the three cations whether phosphorylated (about 1 mol phosphate per myelin basic protein) or non-phosphorylated vesicles were tested. In contrast, a small but significant decrease in permeability for Rb+ and Na+ was measured, when the vesicles were pretreated with ATP and Mg2+.     

Global structural changes in annexin 12. The roles of phospholipid,Ca2+, and pH

Ca2+-dependent membrane interaction has long been recognized as a general property of the annexin (ANX) family of proteins. More recently, it has become clear that ANXs can also undergo Ca2+-independent membrane interactions at mildly acidic pH. Here we use site-directed spin labeling in combination with circular dichroism and biochemical labeling methods to compare the structure and membrane topography of these two different membrane-bound forms of ANX12. Our results reveal strong similarities between the solution structure and the structure of the Ca2+-dependent membrane-bound form at neutral pH. In contrast, all Ca2+-independent membrane interactions tested resulted in large scale conformational changes and membrane insertion. Pairs of spin labels that were in close proximity across the interface of different domains of the protein in both the soluble and Ca2+-dependent membrane form were >25 A apart in the Ca2+-independent membrane-bound form. Despite these major conformational changes, the overall secondary structure content did not appear to be strongly altered and ANX12 remained largely helical. Thus, Ca2+-independent membrane interaction leads to massive refolding but not unfolding. Refolding did not occur at low pH in the absence of membranes but occurred within a few seconds after phospholipid vesicles were added. The phospholipid composition of the vesicles was an important modulator of Ca2+-independent membrane interaction. For example, cardiolipin-containing vesicles induced Ca2+-independent membrane interaction even at near neutral pH, thereby raising the possibility that lipid composition could induce relatively rapid Ca2+-independent membrane interaction in vivo.     

Rapid filtration studies of Ca2+-induced Ca2+ release from skeletal sarcoplasmic reticulum. Role of monovalent ions

We have developed a rapid filtration technique for the measurement of Ca2+ release from isolated sarcoplasmic reticulum vesicles. Using this technique, we have studied the Ca2+-induced Ca2+ release of sarcoplasmic reticulum vesicles from rabbit skeletal muscle passively loaded with 5 mM Ca2+. The effect of known effectors (adenine nucleotides and caffeine) and inhibitors (Mg2+ and ruthenium red) of this release were investigated. In a medium composed of 100 mM KCl buffered at pH 6.8 with 20 mM K/3-(N-morpholino)propanesulfonic acid the Ca2+ release rate was maximal (500 nmol of Ca2+ released.(mg of protein)-1.s-1) at 1 micron external Ca2+ and 5 mM ATP. We also observed a rapid Ca2+ release induced by micromolar Ag+ in the presence of ATP (at 1 nM Ca2+). The Ag+-induced Ca2+ release was totally inhibited by 5 micron ruthenium red. We have also investigated the effect of monovalent ions on the Ca2+ release elicited by Ca2+ or Ag+. We show that the Ca2+ release rate: 1) was dependent upon the presence of K+ or Na+ in the release medium and 2) was influenced by a K+ gradient created across the sarcoplasmic reticulum membrane. These results directly support the idea of the involvement of an influx of K+ (through K+ channels) during the Ca2+ release and allow to reconsider a possible influence of the membrane potential of the sarcoplasmic reticulum on the Ca2+ release.     

Effects of phorbol ester and teleocidin on Ca2+-induced fusion of liposomes

The effects of different types of lipid membrane defects on Ca2+-induced fusion of liposomes containing phosphatidylserine (PS) were investigated using fluorescent probes. Teleocidin enhanced the fusion of phospholipid vesicles in an assay system using terbium/dipicolinic acid during mixing of internal aqueous phases of vesicles upon fusion. 12-O-Tetradecanoylphorbol-13-acetate (TPA) suppressed the fusion. This latter phenomenon was also observed by measuring the excitation energy transfer. The promotion of membrane fusion by teleocidin was ascribed to dehydration of the membrane surface, the suppressive effect of TPA to desorption of Ca2+ from the membrane surface. Thus, Ca2+-induced fusion of PS vesicles was shown to be sensitive to defects of the membrane surface, but insensitive to defects of the hydrophobic core of the lipid membrane.     

Control of the Ca2+-triggered bioluminescence of Veretillum cynomorium lumisomes.

Calcium ions can trigger an emission of light from Veretillum cynomorium lumisomes (bioluminescent vesicles) under conditions where they are not lysed. This process does not require a metabolically-linked source of energy, but is dependent upon the nature of the ions present inside and outside the vesicles. The Ca2+-triggered bioluminescence is stimulated by an asymmetrical distribution of cations or anions. Either high internal sodium or high external chloride is required for the maximal effect. When sodium is present outside the structure and potassium inside, the slow inward diffusion of calcium is decreased. Unbalanced diffusion of internal cations also stimulates the bioluminescence, suggesting control of the calcium influx by an electrochemical gradient. It is assumed that rapid outward diffusion of sodium or inward diffusion of chloride generates an electrical potential difference (inside negative) which drives the Ca2+-influx. With purified lumisomes it has been shown that Ca2+-triggered bioluminescence and calcium uptake (presumably net uptake) were correlated. In two instances uptake of the lipophilic cation dibenzyldimethylammonium has given direct evidence for the existence of a potential difference. With NaCl-loaded vesicles, it has not been possible to demonstrate an uptake of lipophilic cations but experiments with 22Na and 42D indicated a higher rate of sodium efflux, in accord with the proposed hypothesis.     

Calcium-induced condensation-reorganization phenomena in multilamellar vesicles of phosphatidic acid. pH potentiometric and 31P-NMR, Raman and ESR spectroscopic studies

In biological membranes, the anionic characteristics of the polar headgroup of phosphatidic acids are responsible for structural changes induced by Ca2+ in many cellular processes. The very simple headgroup structure of dipalmitoylphosphatidic acid (DPPA) offers particular advantages as a model to study the interactions between Ca2+ and natural phosphatidic acids such as cardiolipin and phosphatidylserine. The effects of calcium ions on DPPA membranes have been studied as a function of temperature by potentiometry and by Raman, ESR and 31P-NMR spectroscopies. The protons in monosodic DPPA liposomes have been considered as a probe to detect pH variations resulting from introduction of Ca2+ inside the membrane. This method has also allowed us to determine the stoichiometry of this reaction: 2 DPPA(H) + Ca2+----Ca(DPPA)2 + 2H+. 31P-NMR spectroscopy has been used to detect reorganization-condensation phenomena in multilamellar vesicles of DPPA under the influence of calcium and temperature. Furthermore, the temperature profiles obtained from Raman spectra for Ca(DPPA)2 membranes provide conclusive evidence that Ca2+ induces major reorganization of the phosphatidic acid component into a highly ordered phase. Quantitative estimates of the degree of motional restriction of spin-labeled soaps embedded inside membranes composed of DPPA with or without Ca2+ have been made using ESR technique. These results are discussed and compared to those found previously for a natural phosphatidic acids such as phosphatidylserine.     

Probes of membrane electrostatics: synthesis and voltage-dependent partitioning of negative hydrophobic ion spin labels in lipid vesicles.

Two spin-labeled derivatives of the hydrophobic anion trinitrophenol have been synthesized and characterized in lipid vesicles. In the presence of lipid vesicles, the electron paramagnetic resonance (EPR) spectra of these probes are a composite of both membrane-bound and aqueous populations; as a result, the membrane-aqueous partitioning can be determined from their electron paramagnetic resonance spectra. The effect of transmembrane potentials on the membrane-aqueous partitioning of these spin-labeled hydrophobic ions was examined in phosphatidylcholine vesicles formed by extrusion. Inside positive membrane potentials promote an increase in the binding of these probes that is quantitatively accounted for by a simple thermodynamic model used previously to describe the partitioning of paramagnetic phosphonium ions. The transmembrane migration rates of these ions are dependent on the dipole potential, indicating that these ions transit the membrane in a charged form. The partitioning of the probe is also sensitive to the membrane surface potential, and this dependence is accurately accounted for using the Gouy-Chapman Stern formalism. As a result of the membrane dipole potential, these probes exhibit a stronger binding and a more rapid transmembrane migration rate compared with positive hydrophobic ion spin labels and provide a new set of negatively charged hydrophobic ion probes to investigate membrane electrostatics.     

Physiological characterization of viable-but-nonculturable Campylobacter jejuni cells

Campylobacter jejuni is a pathogenic, microaerophilic, gram-negative, mesophilic bacterium. Three strains isolated from humans with enteric campylobacteriosis were able to survive at high population levels (10(7) cells ml-1) as viable-but-nonculturable (VBNC) forms in microcosm water. The VBNC forms of the three C. jejuni strains were enumerated and characterized by using 5-cyano-2,3-ditolyl tetrazolium chloride-4',6-diamino-2-phenylindole staining. Cellular volume, adenylate energy charge, internal pH, intracellular potassium concentration, and membrane potential values were determined in stationary-phase cell suspensions after 48 h of culture on Columbia agar and after 1 to 30 days of incubation in microcosm water and compared. A notable increase in cell volume was observed with the VBNC state; the average cell volumes were 1.73 microliter mg of protein-1 for the culturable form and 10.96 microliter mg of protein-1 after 30 days of incubation in microcosm water. Both the internal potassium content and the membrane potential were significantly lower in the VBNC state than in the culturable state. Culturable cells were able to maintain a difference of 0.6 to 0.9 pH unit between the internal and external pH values; with VBNC cells this difference decreased progressively with time of incubation in microcosm water. Measurements of the cellular adenylate nucleotide concentrations revealed that the cells had a low adenylate energy charge (0.66 to 0.26) after 1 day of incubation in microcosm water, and AMP was the only nucleotide detected in the three strains after 30 days of incubation in microcosm water.     

The asymmetric effect of lanthanides on Na+-gradient-dependent Ca2+ transport in synaptic plasma membrane vesicles

Lanthanides (La3+, Pr3+ and Tb3+) inhibit Na+-gradient-dependent Ca2+ influx into synaptic plasma membrane vesicles. 50% inhibition is obtained by 7 microM lanthanide concentration. The inhibition of the Na+-gradient-dependent Ca2+ uptake exhibits competitive kinetic behaviour. The apparent Km of the Ca2+ influx is increased from 50 microM in the absence of lanthanides to 118 microM in the presence of La3+, 170 microM in the presence of Pr3+ and 130 microM in the presence of Tb3+. The maximal reaction velocity is not altered (8.35 nmol Ca2+ transported per mg protein per min in the absence of lanthanides and 8.16 nmol/mg per min in the presence of lanthanides). Lanthanides also inhibited Na+-gradient-dependent Ca2+ efflux from synaptic plasma membrane vesicles that were preloaded with Ca2+ in a Na+-gradient-dependent manner. Introduction of La3+ into the interior of the synaptic plasma membrane vesicles by rapid freezing of the vesicles in liquid N2 and slow thawing had no effect on either Na+-gradient-dependent Ca2+ influx or efflux. Synaptic plasma membrane vesicles can be preloaded with Ca2+ also in an ATP-dependent manner. This form of Ca2+ uptake is also inhibited by La3+ though at higher concentrations than the Na+-gradient-dependent Ca2+ uptake. Na+-gradient-dependent efflux from synaptic plasma membrane vesicles preloaded in an ATP-dependent fashion ('inside-out' vesicles) unlike efflux from synaptic plasma membrane vesicles preloaded in a Na+-gradient-dependent manner was not inhibited by La3+. These findings suggest that the inhibition by La3+ is manifested asymmetrically on both sides of the synaptic plasma membrane. Lanthanides are probably not transported via the Na+-Ca2+ exchanger since Tb3+ entry measured by fluorescence of Tb3+-dipicolinic acid complex formation occurred at high Tb3+ concentrations only (1.5 mM or above) and was not Na+-gradient dependent.