Acetylcholine Synthesis at the Rat Neuromuscular Junction

Acetylcholine (ACh) synthesis in homogenates of rat soleus muscles had two components. One component, specifically inhibited by bromoacetylcholine (BrACh), had a Km for choline of 0.26 mM; the other, resistant to BrACh, had a Km for choline of 45 mM. The component with a low Km was absent from denervated muscle, and was identical in kinetic terms to ACh synthesising activity in homogenates of sciatic nerve. It is therefore considered choline acetyltransferase (ChAT)-specific. The use of BrACh as a specific inhibitor of ChAT activity allowed the calculation of ACh synthesis at individual motor end-plates in the soleus muscle of the rat: 2.1 X 10(-3) nmol h-1. Since the number of muscle fibres and the number of motor units are known for this muscle, ACh synthesis per motor unit could be calculated: 0.15 nmol h-1. It is concluded that BrACh can be used as a specific inhibitor of ChAT activity in homogenates of skeletal muscle and that its use will obviate the necessity of dividing biopsied muscle or small rodent muscles into neural and aneural segments.     

Calcium Dependence of Synaptic Vesicle Recycling Before and After Synaptogenesis

Abstract: Using an immunocytochemical assay to monitor synaptic vesicle exocytosis/endocytosis independently of neurotransmitter release, we have investigated some aspects of vesicle recycling in hippocampal neurons at different developmental stages. A calcium- and depolarization-dependent exocytotic/endocytotic recycling of synaptic vesicles was found to take place in neurons already before the formation of synaptic contacts. The analysis of synaptic vesicle recycling at different calcium concentrations revealed the presence of two release components: the first one activated by low calcium concentrations and sustaining vesicle recycling before synaptogenesis, and a second one activated by high calcium concentrations, which is specifically turned on after the establishment of synaptic contacts. These data suggest that formation of synapses correlates with the activation of a putative low-affinity calcium sensor, which allows synaptic vesicle exocytosis to be triggered and turned off over extremely short time scales, in response to large increases in the level of intracellular calcium.     

Acetylcholine Receptor Binding Properties at the Rat Neuromuscular Junction During Aging

Specific binding characteristics of acetylcholine receptors at the diaphragm neuromuscular junction of rats aged 10 (mature adult) and 28 (aged) months were assayed by measuring 125I-alpha-bungarotoxin binding. Maximal binding to intact tissue samples was greater in the older rats; this could be attributed to an age-related increase in terminal branching. The toxin concentration at which half-maximal binding occurred increased in the older rats. Binding kinetics were assayed in finely minced tissue samples, and the association rate constant was observed to decrease in the 28-month animals. Retardation of the initial rate of toxin binding by d-tubocurarine (dTC) in minced tissue was described by a two-component nonlinear Hofstee plot; IC50 values (7.1-7.2 microM and 39.0-46.5 nM) were about the same for both age groups, but there was a significant shift toward the low-affinity values in the aged rats. Rhodamine-conjugated alpha-bungarotoxin was used to visualize receptor localization. There were no major changes in receptor distribution, and nerve terminals were consistently associated with receptors and vice versa. The data indicate a shift toward lower binding affinity during aging, which may involve changes either in one of the two toxin-binding sites on individual receptors, in dTC blocking of the channel moiety, or in receptor types.     

Identification and Characterization of the Major Proteins of Mammalian Brain Synaptic Vesicles

Highly purified rat and cow brain synaptic vesicles contain major proteins with molecular weights of approximately 74,000, 60,000, 57,000, 40,000, 38,000, and 34,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The presence of the major proteins on synaptic vesicles was confirmed by immunoprecipitation of intact rat brain synaptic vesicles with a synaptic vesicle-specific monoclonal antibody. The 40,000-Mr protein appeared to be identical to the 38,000-Mr integral membrane glycoprotein, p38 or synaptophysin, previously identified as a major component of mammalian synaptic vesicles. The isoelectric point of the 75,000-Mr proteins from either rat or cow brain synaptic vesicles is 5.0, and the pI of the 57,000-Mr protein is approximately 5.1 in both species. The similarity in size and charge of several major proteins in rat and cow synaptic vesicles suggests a high degree of structure conservation of these proteins in diverse mammalian species and raises the possibility that a set of functions common to most or all mammalian synaptic vesicles is mediated by these proteins.     

Mechanisms of synaptic vesicle recycling illuminated by fluorescent dyes

The recycling of synaptic vesicles in nerve terminals involves multiple steps, underlies all aspects of synaptic transmission, and is a key to understanding the basis of synaptic plasticity. The development of styryl dyes as fluorescent molecules that label recycling synaptic vesicles has revolutionized the way in which synaptic vesicle recycling can be investigated, by allowing an examination of processes in neurons that have long been inaccessible. In this review, we evaluate the major aspects of synaptic vesicle recycling that have been revealed and advanced by studies with styryl dyes, focussing upon synaptic vesicle fusion, retrieval, and trafficking. The greatest impact of styryl dyes has been to allow the routine visualization of endocytosis in central nerve terminals for the first time. This has revealed the kinetics of endocytosis, its underlying sequential steps, and its regulation by Ca2+. In studies of exocytosis, styryl dyes have helped distinguish between different modes of vesicle fusion, provided direct support for the quantal nature of exocytosis and endocytosis, and revealed how the probability of exocytosis varies enormously from one nerve terminal to another. Synaptic vesicle labelling with styryl dyes has helped our understanding of vesicle trafficking by allowing better understanding of different synaptic vesicle pools within the nerve terminal, vesicle intermixing, and vesicle clustering at release sites. Finally, the dyes are now being used in innovative ways to reveal further insights into synaptic plasticity.     

Separation of Recycling and Reserve Synaptic Vesicles from Cholinergic Nerve Terminals of the Myenteric Plexus of Guinea Pig Ileum

Acetylcholine-rich synaptic vesicles were isolated from myenteric plexus-longitudinal muscle strips derived from the guinea pig ileum by the method of Dowe, Kilbinger, and Whittaker [J. Neurochem. 35, 993-1003 (1980)] using either unstimulated preparations or preparations field-stimulated at 1 Hz for 10 min using pulses of 1 ms duration and 10 V . cm-1 intensity. The organ bath contained either tetradeuterated (d4) choline (50 microM) or [3H]acetate (2 muCi . ml-1); d4 acetylcholine was measured by gas chromatography-mass spectrometry. As with Torpedo electromotor cholinergic vesicle preparations made under similar conditions the distribution of newly synthesized (d4 or [3H]) acetylcholine in the zonal gradient from stimulated preparations was not identical with that of endogenous (d0, [1H]) acetylcholine, but corresponded to a subpopulation of denser vesicles (equivalent to the VP2 fraction from Torpedo) that had preferentially taken up newly synthesized transmitter. The density difference between the reserve (VP1) and recycling (VP2) vesicles was less than that observed in Torpedo but this smaller difference can be accounted for theoretically by the difference in size between the vesicles of the two tissues. At rest, a lesser incorporation of labelled acetylcholine into the vesicle fraction was observed, and the peaks of endogenous and newly synthesized acetylcholine coincided. Stimulation in the absence of label followed by addition of label did not lead to incorporation of labelled acetylcholine, suggesting that the synthesis and storage of acetylcholine in this preparation and its recovery from stimulation is much more rapid than in Torpedo.     

Ouabain evokes exocytosis dependent on ryanodine and mitochondrial calcium stores that is not followed by compensatory endocytosis at the neuromuscular junction

Ouabain is a cardiotonic glycoside that inhibits the sodium potassium ATPase pump leading to sodium accumulation in nerve terminals. At the frog neuromuscular junction, ouabain induces acetylcholine release and a rapid depletion of synaptic vesicles. In the present work, we used FM1–43 vital labeling to dissect the effect of ouabain on synaptic vesicles recycling. We first examined images of nerve-muscle preparations that were stained with FM1–43 by electrical stimulation of the nerve and destained with ouabain. We observed that ouabain induced exocytosis of synaptic vesicles independently of extracellular calcium, implying a mechanism of exocytosis that can bypass the requirement for extracellular calcium. We therefore tested the hypothesis that ouabain induces exocytosis by mobilizing intracellular calcium and we report that calcium release from endoplasmic reticulum through ryanodine receptors is necessary for ouabain-evoked exocytosis. In addition, the ouabain-evoked exocytosis was dependent on calcium released from mitochondria. We also investigated if exocytosis evoked by ouabain is followed by compensatory endocytosis. We observed that muscles incubated with FM1–43 in the presence of ouabain did not present significant staining. In conclusion, our data demonstrate that exocytosis evoked by ouabain is independent on extracellular calcium but dependent on calcium release from endoplasmic reticulum and mitochondrial stores. In addition, we suggest that ouabain can be used as a pharmacological tool to uncouple synaptic vesicles exocytosis from endocytosis at the neuromuscular junction.     

Identification of Actin in Highly Purified Synaptic Vesicles from the Electric Organ of Torpedo marmorata

Abstract: Evidence has been obtained that actin is a major constituent of highly purified synaptic vesicles isolated from the electric organ of Torpedo marmorata . The mobility of a prominent spot in the polypeptide pattern of vesicles in high-resolution two-dimensional polyacrylamide gel electrophoresis is very similar to the mobility of the main component in the actin preparation purified from the whole electric organ by affinity chromatography on immobilized pancreatic deoxyribonuclease I. The comparison of tryptic peptide maps obtained from the putative vesicle actin and authentic actin from the electric organ, both purified by two-dimensional gel electrophoresis and labeled in situ with ¹²⁵I, showed about 88% homology, thereby supporting the conclusion that the vesicle actin is indeed an actin isoform.     

Localization of the Repetitive Firing Generation Site Induced by 4-Aminopyridine at the Frog Neuromuscular Junction

In the neuromuscular junction, blockade of potassium channels can produce multiple discharges after single nerve stimulation. Multielectrode recording from the nerve trunk and myelinated and non-myelinated parts of the nerve ending demonstrated that repetitive presynaptic spikes elicited by 4-aminopyridine arise earliest within the part of the axon proximal to the motor nerve ending.     

Dynamic Storage of Dopamine in Rat Brain Synaptic Vesicles In Vitro

Abstract: The dynamics of catecholamine storage were studied in highly purified, small synaptic vesicles from rat brain both during active uptake or after inhibiting uptake with reserpine, tetrabenazine, or removal of external dopamine. To assess turnover during active uptake, synaptic vesicles were allowed to accumulate [³H]dopamine ([³H]DA) for ～10 min and then diluted 20-fold into a solution containing unlabeled DA under conditions such that active uptake could continue. After dilution, [³H]DA was lost with single exponential kinetics at a half-time of ～4 min at 30°C in 8 mM Cl^? medium, in which both voltage and H⁺ gradients are present in the vesicles. In 90 mM Cl^? medium, in which high H⁺ and Cl^? gradients but no voltage gradient are present, [³H]DA escaped at a half-time of ～7 min. In both high and low Cl^? media, ～40% of [³H]DA efflux was blocked by reserpine or tetrabenazine. The residual efflux also followed first-order kinetics. These results indicate that two efflux pathways were present, one dependent on DA uptake (and thus on the presence of external DA) and the other independent of uptake, and that both pathways function regardless of the type of electrochemical H⁺ gradient in the vesicles. The presence of both uptake-dependent and -independent efflux was observed in experiments using DA-free medium, instead of uptake inhibitors, to prevent uptake. Uptake-independent efflux showed molecular selectivity for catecholamines; [¹⁴C]DA was lost about three times faster than [³H]norepinephrine after adding tetrabenazine directly (without dilution) to vesicles that had taken up comparable amounts of each amine. In addition, the first-order rate constant for uptake-independent efflux showed little change over a 60-fold range of internal DA concentrations, which suggests that this pathway had a high transport capacity. All efflux was blocked at 0°C, suggesting that efflux did not occur through a large pore. There was little or no change in the proton gradient in synaptic vesicles, monitored by [¹⁴C]methylamine equilibration, during the experimental manipulations used here. Thus, the driving force for catecholamine uptake remained approximately constant. The physiological role of uptake-independent efflux could be to allow the monoamine content of synaptic vesicles to be regulated over a time range of minutes and, thereby, control the amount released by exocytosis. These results imply that catecholamines turn over with a half-time of minutes during active uptake by brain synaptic vesicles in vitro.     

Mechanisms of the Effect of Dimephosphone on Synaptic Transmission in the Frog Neuromuscular Junction

We studied the influence of dimephosphone, an organophosphorus drug with a broad spectrum of therapeutic effects on the peripheral and central nervous systems, on postsynaptic end-plate currents (EPC) in the frog neuromuscular junction. Dimephosphone was demonstrated to decrease in a voltage-independent manner the EPC amplitude and to prolong the EPC decay. These effects are not related to inhibition of acetylcholinesterase. We propose a theoretical interpretation of the observed phenomena based on the model of blockade of an open ion channel of the acetylcholine receptor and conclude that postsynaptic receptors are one of the most probable targets for the action of dimephosphone.     

Synaptic Vesicle Recycling in Cultured Cerebellar Granule Cells: Role of Vesicular Acidification and Refilling

Abstract: The role of the transvesicular protonmotive force in synaptic vesicle recycling was investigated in cultured cerebellar granule cells. The vesicular V-ATPase was inhibited by 1 µ M bafilomycin A1; as an alternative, the pH component of the gradient was selectively collapsed by equilibration of the cells with 10 m M methylamine and monitored with the fluorescent probe Lysosensor Green. Electrical field-evoked exocytosis of d -[³H]aspartate was inhibited by bafilomycin A1 but not by methylamine, indicating that a transvesicular membrane potential rather than pH gradient is required for transmitter retention within vesicles. In contrast, neither compound affected the field-evoked uptake, recycling, or destaining of the vesicle-specific dye FM2-10; thus, vesicles whose lumens were neutral and/or depleted of transmitter could still recycle in the nerve terminal. No exhaustion of d -[³H]aspartate exocytosis was observed when cells were subjected to six consecutive trains of field stimuli (40 Hz/10 s separated by 10 s). In contrast, the release of preloaded FM2-10 was reduced by ∼50%, with each stimulus indicating that unlabeled vesicles with accumulated d -[³H]aspartate were competing with labeled vesicles for exocytosis. As d -[³H]aspartate was accumulated rapidly across the vesicle membrane from the large cytoplasmic pool, the transmitter-loaded but unlabelled vesicles may represent refilled recycling vesicles. FM2-10 destaining and d -[³H]aspartate exocytosis were reduced in parallel at low frequencies, challenging a role for transient vesicle fusion.     

Effect of Maternal Iron Deficiency in Rat on Serotonin Uptake In Vitro by Brain Synaptic Vesicles in the Offspring

The effect of maternal dietary iron deficiency on brain synaptic vesicle [³H]serotonin (5-HT) uptake and iron content in the offspring was examined in rats. Pups born to iron-deficient mothers revealed significant deficits in vesicular [³H]5-HT uptake and iron concentration at 21 days of age. These changes were, however, found to be reversible with postweaning iron repletion.     

Presynaptic dense bars at neuromuscular synapses of the lobster,Homarus americanus

Summary The threedimensional ultrastructure of presynaptic dense bars was examined by serial section electron microscopy in the excitatory neuromuscular synapses of the accessory flexor muscle in the limbs of larval, juvenile, and adult lobsters. The cross-sectional profile of the dense bar resembles an asymmetric hourglass, the part contacting the presynaptic membrane being larger than that projecting into the terminal. The bar has a height of 55–65 nm and varies in length from 75–600 nm. In its dimensions it resembles the dense projections in the synapses of the CNS of insects and vertebrates. The usual location of these dense bars is at well defined synapses, though a few are found at extrasynaptic sites either in the axon or terminal. In the latter case the bars are close to synapse-bearing regions, particularly in the larval terminals, suggesting that the extrasynaptic bars denote early events in synapse formation. In all cases the bars are intimately associated with electron lucent, synaptic vesicles located on either side, in the indentation of its hourglass-shaped cross sectional profile. The vesicles occur along the length of the bar and contact the presynaptic membrane. Consequently the dense bar may serve to align the vesicles at the presynaptic membrane prior to exocytosis. A similar role has been suggested for the presynaptic dense bodies at the neuromuscular junction of the frog, where synaptic vesicles form a row on either side of this structure.Supported by Muscular Dystrophy Association of Canada and NSERCC. Generous use of laboratory facilities at Woods Hole was provided by the late Fred Lang     

Examination of Synaptic Vesicle Recycling Using FM Dyes During Evoked,Spontaneous, and Miniature Synaptic Activities

Synaptic vesicles in functional nerve terminals undergo exocytosis and endocytosis. This synaptic vesicle recycling can be effectively analyzed using styryl FM dyes, which reveal membrane turnover. Conventional protocols for the use of FM dyes were designed for analyzing neurons following stimulated (evoked) synaptic activity. Recently, protocols have become available for analyzing the FM signals that accompany weaker synaptic activities, such as spontaneous or miniature synaptic events. Analysis of these small changes in FM signals requires that the imaging system is sufficiently sensitive to detect small changes in intensity, yet that artifactual changes of large amplitude are suppressed. Here we describe a protocol that can be applied to evoked, spontaneous, and miniature synaptic activities, and use cultured hippocampal neurons as an example. This protocol also incorporates a means of assessing the rate of photobleaching of FM dyes, as this is a significant source of artifacts when imaging small changes in intensity.     

Inhibition of Glutamate Uptake and Proton Pumping in Synaptic Vesicles by S-Nitrosylation

Abstract: Nitric oxide (NO; including NO^•, NO⁺, and NO⁻) was found to inhibit glutamate uptake by isolated synaptic vesicles of rat brain. This was observed when two unrelated NO donors, S -nitrosogluthathione and S -nitroso- N -acetylpenicillamine, were used. The primary target of NO is the H⁺-ATPase found in the synaptic vesicles, which leads to dissipation of the electrochemical proton gradient and inhibition of glutamate uptake. Oxyhemoglobin (12 µ M ) and, to a much lesser extent, methemoglobin protected the vacuolar H⁺-ATPase from inhibition. Inhibition of H⁺ pumping by NO was reversed by addition of 0.5 m M dithiothreitol. The results indicate that the vacuolar H⁺-ATPase from synaptic vesicles is inhibited by NO by a mechanism that involves S -nitrosylation of critical sulfhydryl groups in the enzyme. The interaction of NO with synaptic vesicles might be of importance for the understanding of the multiple effects of NO in neurotransmission.     

Partial Purification and Characterization of the Vacuolar H+-ATPase of Mammalian Synaptic Vesicles

Several major proteins of synaptic vesicles from rat or cow brain sediment as a large complex on sucrose density gradients when solubilized in nonionic detergents. A vacuolar H(+)-ATPase identified by sensitivity to bafilomycin A1 appears to be associated with this oligomeric protein complex. Two subunits of this complex, synaptic vesicle proteins S and U, correspond to the 57-kDa (B) and 39-kDa accessory (Ac39) subunits, respectively, of bovine chromaffin granule vacuolar H(+)-ATPase as shown by Western immunoblot analysis. The five subunits of the oligomeric complex constitute approximately 20% of the total protein of rat brain synaptic vesicles. Taken together, these results strongly suggest that the abundant, multisubunit complex partially purified from brain synaptic vesicles by density gradient centrifugation is a vacuolar H(+)-ATPase. Bafilomycin A1 completely blocks proton pumping in rat brain synaptic vesicles as measured by [14C]methylamine uptake and also blocks catecholamine accumulation measured by [3H]dopamine uptake. Moreover, ATPase activity, [14C]methylamine uptake, and [3H]dopamine uptake are inhibited by bafilomycin A1 at similar I50 values of approximately 1.7 nmol/mg of protein. These findings indicate that the vacuolar H(+)-ATPase is essential for proton pumping as well as catecholamine uptake by mammalian synaptic vesicles.     

Facilitation at the sexually differentiated laryngeal synapse of Xenopus laevis

Under physiological conditions, the laryngeal synapse of male Xenopus laevis exhibits marked facilitation during repetitive nerve stimulation. The male laryngeal synapse is weak and requires facilitation to produce muscle action potentials and ultimately sound. The female laryngeal synapse is strong: muscle contractions are produced to single nerve stimuli. We sought to determine if laryngeal synapses of males and females also differ in their ability to facilitate. To measure facilitation, laryngeal muscle action potentials were suppressed either postsynaptically by bathing the preparation in saline containing curare or presynaptically by bathing the preparation in reduced calcium/elevated magnesium saline. Facilitation of postsynaptic potential amplitude or quantal content in response to paired pulses was measured in male and female larynges: there is no sex difference in paired pulse facilitation. Facilitation in response to trains of stimuli, in curare-blocked preparations, increased and reached plateau values more rapidly in females than in males, although the facilitation between the last and first pulses in the train was the same in the sexes. Thus, the sexually differentiated behavior of this synapse is controlled more by a sex difference in synaptic strength than by a sex difference in the ability to facilitate. Accepted: 14 June 1997     

Constitutive endocytosis in characean internodal cells is independent of an intact actin cytoskeleton

We have investigated constitutive endocytosis in internodal cells of the characean green algae. The endocytic tracer FM1-43 accumulated in distinct plasma membrane domains that are probably enriched in sterol-like substances. Internalization of the dye was active but independent of an intact actin or microtubule cytoskeleton.     

Bipolar nanosecond electric pulses are less efficient at electropermeabilization and killing cells than monopolar pulses

Multiple studies have shown that bipolar (BP) electric pulses in the microsecond range are more effective at permeabilizing cells while maintaining similar cell survival rates as compared to monopolar (MP) pulse equivalents. In this paper, we investigated whether the same advantage existed for BP nanosecond-pulsed electric fields (nsPEF) as compared to MP nsPEF. To study permeabilization effectiveness, MP or BP pulses were delivered to single Chinese hamster ovary (CHO) cells and the response of three dyes, Calcium Green-1, propidium iodide (PI), and FM1-43, was measured by confocal microscopy. Results show that BP pulses were less effective at increasing intracellular calcium concentration or PI uptake and cause less membrane reorganization (FM1-43) than MP pulses. Twenty-four hour survival was measured in three cell lines (Jurkat, U937, CHO) and over ten times more BP pulses were required to induce death as compared to MP pulses of similar magnitude and duration. Flow cytometry analysis of CHO cells after exposure (at 15 min) revealed that to achieve positive FITC-Annexin V and PI expression, ten times more BP pulses were required than MP pulses. Overall, unlike longer pulse exposures, BP nsPEF exposures proved far less effective at both membrane permeabilization and cell killing than MP nsPEF.