SNAP-23 functions in docking/fusion of granules at low Ca2+

Ca(2+)-triggered exocytosis of secretory granules mediates the release of hormones from endocrine cells and neurons. The plasma membrane protein synaptosome-associated protein of 25 kDa (SNAP-25) is thought to be a key component of the membrane fusion apparatus that mediates exocytosis in neurons. Recently, homologues of SNAP-25 have been identified, including SNAP-23, which is expressed in many tissues, albeit at different levels. At present, little is known concerning functional differences among members of this family of proteins. Using an in vitro assay, we show here that SNAP-25 and SNAP-23 mediate the docking of secretory granules with the plasma membrane at high (1 microM) and low (100 nM) Ca(2+) levels, respectively, by interacting with different members of the synaptotagmin family. In intact endocrine cells, expression of exogenous SNAP-23 leads to high levels of hormone secretion under basal conditions. Thus, the relative expression levels of SNAP-25 and SNAP-23 might control the mode (regulated vs. basal) of granule release by forming docking complexes at different Ca(2+) thresholds.     

Munc18a Does Not Alter Fusion Rates Mediated by Neuronal SNAREs,Synaptotagmin, and Complexin

Sec1/Munc18 (SM) proteins are essential for membrane trafficking, but their molecular mechanism remains unclear. Using a single vesicle-vesicle content-mixing assay with reconstituted neuronal SNAREs, synaptotagmin-1, and complexin-1, we show that the neuronal SM protein Munc18a/nSec1 has no effect on the intrinsic kinetics of both spontaneous fusion and Ca²⁺-triggered fusion between vesicles that mimic synaptic vesicles and the plasma membrane. However, wild type Munc18a reduced vesicle association ∼50% when the vesicles bearing the t-SNAREs syntaxin-1A and SNAP-25 were preincubated with Munc18 for 30 min. Single molecule experiments with labeled SNAP-25 indicate that the reduction of vesicle association is a consequence of sequestration of syntaxin-1A by Munc18a and subsequent release of SNAP-25 (i.e. Munc18a captures syntaxin-1A via its high affinity interaction). Moreover, a phosphorylation mimic mutant of Munc18a with reduced affinity to syntaxin-1A results in less reduction of vesicle association. In summary, Munc18a does not directly affect fusion, although it has an effect on the t-SNARE complex, depending on the presence of other factors and experimental conditions. Our results suggest that Munc18a primarily acts at the prefusion stage.     

高锶离子亲和力传感蛋白介导CALYX突触囊泡异步和自发释放

突触囊泡在钙离子(Ca2+)触发下释放神经递质普遍存在着同步和异步两种形式.突触囊泡膜蛋白(synaptotagmin 2,Syt-2)已被证实是Calyx of Held突触囊泡同步释放的Ca2+传感蛋白,而相关的异步释放Ca2+传感蛋白还有待于探索.虽然锶离子(Sr2+)因其物理和化学性质都接近Ca2+,且能触发更多的囊泡异步释放成分而成为研究异步释放机制的常用工具,但有关Sr2+触发异步释放的机制存在着争议.本文在胞外以Sr2+替换Ca2+的条件下,通过对野生型(WT)和Syt-2敲除型(Z2B-/-)小鼠Calyx突触囊泡自发和诱发释放的电生理特性分析,发现Syt-2是介导Sr2+诱发的突触囊泡快速释放的传感蛋白,但不是介导Sr2+相关神经递质异步释放和自发释放的传感蛋白;而未知的触发囊泡异步释放的传感蛋白相比Syt-2对Sr2+具有更高的亲和力,同时也介导突触囊泡的自发释放.这一研究为探索并最终发现触发囊泡异步释放的未知传感蛋白提供了新的线索.     

Calmodulin Suppresses Synaptotagmin-2 Transcription in Cortical Neurons

Calmodulin (CaM) is a ubiquitous Ca²⁺ sensor protein that plays a pivotal role in regulating innumerable neuronal functions, including synaptic transmission. In cortical neurons, most neurotransmitter release is triggered by Ca²⁺ binding to synaptotagmin-1; however, a second delayed phase of release, referred to as asynchronous release, is triggered by Ca²⁺ binding to an unidentified secondary Ca²⁺ sensor. To test whether CaM could be the enigmatic Ca²⁺ sensor for asynchronous release, we now use in cultured neurons short hairpin RNAs that suppress expression of ∼70% of all neuronal CaM isoforms. Surprisingly, we found that in synaptotagmin-1 knock-out neurons, the CaM knockdown caused a paradoxical rescue of synchronous release, instead of a block of asynchronous release. Gene and protein expression studies revealed that both in wild-type and in synaptotagmin-1 knock-out neurons, the CaM knockdown altered expression of >200 genes, including that encoding synaptotagmin-2. Synaptotagmin-2 expression was increased several-fold by the CaM knockdown, which accounted for the paradoxical rescue of synchronous release in synaptotagmin-1 knock-out neurons by the CaM knockdown. Interestingly, the CaM knockdown primarily activated genes that are preferentially expressed in caudal brain regions, whereas it repressed genes in rostral brain regions. Consistent with this correlation, quantifications of protein levels in adult mice uncovered an inverse relationship of CaM and synaptotagmin-2 levels in mouse forebrain, brain stem, and spinal cord. Finally, we employed molecular replacement experiments using a knockdown rescue approach to show that Ca²⁺ binding to the C-lobe but not the N-lobe of CaM is required for suppression of synaptotagmin-2 expression in cortical neurons. Our data describe a previously unknown, Ca²⁺/CaM-dependent regulatory pathway that controls the expression of synaptic proteins in the rostral-caudal neuraxis.     

Complexin clamps asynchronous release by blocking a secondary Ca(2+) sensor via its accessory α helix

Complexin activates and clamps neurotransmitter release; impairing complexin function decreases synchronous, but increases spontaneous and asynchronous synaptic vesicle exocytosis. Here, we show that complexin-different from the Ca(2+) sensor synaptotagmin-1-activates synchronous exocytosis by promoting synaptic vesicle priming, but clamps spontaneous and asynchronous exocytosis-similar to synaptotagmin-1-by blocking a secondary Ca(2+) sensor. Activation and clamping functions of complexin depend on distinct, autonomously acting sequences, namely its N-terminal region and accessory α helix, respectively. Mutations designed to test whether the accessory α helix of complexin clamps exocytosis by inserting into SNARE-complexes support this hypothesis, suggesting that the accessory α helix blocks completion of trans-SNARE-complex assembly until Ca(2+) binding to synaptotagmin relieves this block. Moreover, a juxtamembranous mutation in the SNARE-protein synaptobrevin-2, which presumably impairs force transfer from nascent trans-SNARE complexes onto fusing membranes, also unclamps spontaneous fusion by disinhibiting a secondary Ca(2+) sensor. Thus, complexin performs mechanistically distinct activation and clamping functions that operate in conjunction with synaptotagmin-1 by controlling trans-SNARE-complex assembly.     

Basal somatodendritic dopamine release requires snare proteins

Dopaminergic neurons have the capacity to release dopamine not only from their axon terminals, but also from their somatodendritic compartment. The actual mechanism of somatodendritic dopamine release has remained controversial. Here we established for the first time a rat primary neuron culture model to investigate this phenomenon and use it to study the mechanism under conditions of non-stimulated spontaneous firing (1-2 Hz). We found that we can selectively measure somatodendritic dopamine release by lowering extracellular calcium to 0.5 mm, thus confirming the previously established differential calcium sensitivity of somatodendritic and terminal release. Dopamine release measured under these conditions was dependent on firing activity and independent of reverse transport through the plasma membrane. We found that treatment with botulinum neurotoxins A and B strongly reduced somatodendritic dopamine release, thus demonstrating the requirement for SNARE proteins SNAP-25 and synaptobrevin. Our work is the first to provide such direct and unambiguous evidence for the involvement of an exocytotic mechanism in basal spontaneous somatodendritic dopamine release.     

A dominant-negative variant of SNAP-23 decreases the cell surface expression of the neuronal glutamate transporter EAAC1 by slowing constitutive delivery

A family of high-affinity transporters controls the extracellular concentration of glutamate in the brain, ensuring appropriate excitatory signaling and preventing excitotoxicity. There is evidence that one of the neuronal glutamate transporters, EAAC1, is rapidly recycled on and off the plasma membrane with a half-life of no more than 5-7 min in both C6 glioma cells and cortical neurons. Syntaxin 1A has been implicated in the trafficking of several neurotransmitter transporters and in the regulation of EAAC1, but it has not been determined if this SNARE protein is required for EAAC1 trafficking. Expression of two different sets of SNARE proteins was examined in C6 glioma with Western blotting. These cells did not express syntaxin 1A, vesicle-associated membrane protein-1 (VAMP1), or synaptosomal-associated protein of 25 kDa (SNAP-25), but did express a family of SNARE proteins that has been implicated in glucose transporter trafficking, including syntaxin 4, vesicle-associated membrane protein-2 (VAMP2), and synaptosomal-associated protein of 23 kDa (SNAP-23). cDNAs encoding variants of SNAP-23 were co-transfected with Myc-tagged EAAC1 to determine if SNAP-23 function was required for maintenance of EAAC1 surface expression. Expression of a dominant-negative variant of SNAP-23 that lacks a domain required for SNARE complex assembly decreased the fraction of EAAC1 found on the cell surface and decreased total EAAC1 expression, while two control constructs had no effect. The dominant-negative variant of SNAP-23 also slowed the rate of EAAC1 delivery to the plasma membrane. These data strongly suggest that syntaxin 1A is not required for EAAC1 trafficking and provide evidence that SNAP-23 is required for constitutive recycling of EAAC1.     

Neuronal calcium sensor synaptotagmin-9 is not involved in the regulation of glucose homeostasis or insulin secretion

Background

Insulin secretion is a complex and highly regulated process. It is well established that cytoplasmic calcium is a key regulator of insulin secretion, but how elevated intracellular calcium triggers insulin granule exocytosis remains unclear, and we have only begun to define the identities of proteins that are responsible for sensing calcium changes and for transmitting the calcium signal to release machineries. Synaptotagmins are primarily expressed in brain and endocrine cells and exhibit diverse calcium binding properties. Synaptotagmin-1, -2 and -9 are calcium sensors for fast neurotransmitter release in respective brain regions, while synaptotagmin-7 is a positive regulator of calcium-dependent insulin release. Unlike the three neuronal calcium sensors, whose deletion abolished fast neurotransmitter release, synaptotagmin-7 deletion resulted in only partial loss of calcium-dependent insulin secretion, thus suggesting that other calcium-sensors must participate in the regulation of insulin secretion. Of the other synaptotagmin isoforms that are present in pancreatic islets, the neuronal calcium sensor synaptotagmin-9 is expressed at the highest level after synaptotagmin-7.

Methodology/Principal Findings

In this study we tested whether synaptotagmin-9 participates in the regulation of glucose-stimulated insulin release by using pancreas-specific synaptotagmin-9 knockout (p-S9X) mice. Deletion of synaptotagmin-9 in the pancreas resulted in no changes in glucose homeostasis or body weight. Glucose tolerance, and insulin secretion in vivo and from isolated islets were not affected in the p-S9X mice. Single-cell capacitance measurements showed no difference in insulin granule exocytosis between p-S9X and control mice.

Conclusions

Thus, synaptotagmin-9, although a major calcium sensor in the brain, is not involved in the regulation of glucose-stimulated insulin release from pancreatic β-cells.     

Membrane fusion by VAMP3 and plasma membrane t-SNAREs

Pairing of SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteins on vesicles (v-SNAREs) and SNARE proteins on target membranes (t-SNAREs) mediates intracellular membrane fusion. VAMP3/cellubrevin is a v-SNARE that resides in recycling endosomes and endosome-derived transport vesicles. VAMP3 has been implicated in recycling of transferrin receptors, secretion of alpha-granules in platelets, and membrane trafficking during cell migration. Using a cell fusion assay, we examined membrane fusion capacity of the ternary complexes formed by VAMP3 and plasma membrane t-SNAREs syntaxin1, syntaxin4, SNAP-23 and SNAP-25. VAMP3 forms fusogenic pairing with t-SNARE complexes syntaxin1/SNAP-25, syntaxin1/SNAP-23 and syntaxin4/SNAP-25, but not with syntaxin4/SNAP-23. Deletion of the N-terminal domain of syntaxin4 enhanced membrane fusion more than two fold, indicating that the N-terminal domain negatively regulates membrane fusion. Differential membrane fusion capacities of the ternary v-/t-SNARE complexes suggest that transport vesicles containing VAMP3 have distinct membrane fusion kinetics with domains of the plasma membrane that present different t-SNARE proteins.     

The SNARE proteins SNAP-25 and SNAP-23 display different affinities for lipid rafts in PC12 cells. Regulation by distinct cysteine-rich domains

SNAP-25 and its ubiquitously expressed homologue, SNAP-23, are SNARE proteins that are essential for regulated exocytosis in diverse cell types. Recent work has shown that SNAP-25 and SNAP-23 are partly localized in sphingolipid/cholesterol-rich lipid raft domains of the plasma membrane and that the integrity of these domains is important for exocytosis. Here, we show that raft localization is mediated by a 36-amino-acid region of SNAP-25 that is also the minimal sequence required for membrane targeting; this domain contains 4 closely spaced cysteine residues that are sites for palmitoylation. Analysis of endogenous levels of SNAP-25 and SNAP-23 present in lipid rafts in PC12 cells revealed that SNAP-23 (54% raft-associated) was almost 3-fold more enriched in rafts when compared with SNAP-25 (20% raft-associated). We report that the increased raft association of SNAP-23 occurs due to the substitution of a highly conserved phenylalanine residue present in SNAP-25 with a cysteine residue. Intriguingly, although the extra cysteine in SNAP-23 enhances its raft association, the phenylalanine at the same position in SNAP-25 acts to repress the raft association of this protein. These different raft-targeting signals within SNAP-25 and SNAP-23 are likely important for fine-tuning the exocytic pathways in which these proteins operate.     

Synaptotagmin-12, a synaptic vesicle phosphoprotein that modulates spontaneous neurotransmitter release

Central synapses exhibit spontaneous neurotransmitter release that is selectively regulated by cAMP-dependent protein kinase A (PKA). We now show that synaptic vesicles contain synaptotagmin-12, a synaptotagmin isoform that differs from classical synaptotagmins in that it does not bind Ca(2+). In synaptic vesicles, synaptotagmin-12 forms a complex with synaptotagmin-1 that prevents synaptotagmin-1 from interacting with SNARE complexes. We demonstrate that synaptotagmin-12 is phosphorylated by cAMP-dependent PKA on serine(97), and show that expression of synaptotagmin-12 in neurons increases spontaneous neurotransmitter release by approximately threefold, but has no effect on evoked release. Replacing serine(97) by alanine abolishes synaptotagmin-12 phosphorylation and blocks its effect on spontaneous release. Our data suggest that spontaneous synaptic-vesicle exocytosis is selectively modulated by a Ca(2+)-independent synaptotagmin isoform, synaptotagmin-12, which is controlled by cAMP-dependent phosphorylation.     

Sequence-specific assignment of methyl groups from the neuronal SNARE complex using lanthanide-induced pseudocontact shifts

Neurotransmitter release depends critically on the neuronal SNARE complex formed by syntaxin-1, SNAP-25 and synaptobrevin, as well as on other proteins such as Munc18-1, Munc13-1 and synaptotagmin-1. Although three-dimensional structures are available for these components, it is still unclear how they are assembled between the synaptic vesicle and plasma membranes to trigger fast, Ca²⁺-dependent membrane fusion. Methyl TROSY NMR experiments provide a powerful tool to study complexes between these proteins, but assignment of the methyl groups of the SNARE complex is hindered by its limited solubility. Here we report the assignment of the isoleucine, leucine, methionine and valine methyl groups of the four SNARE motifs of syntaxin-1, SNAP-25 and synaptobrevin within the SNARE complex based solely on measurements of lanthanide-induced pseudocontact shifts. Our results illustrate the power of this approach to assign protein resonances without the need of triple resonance experiments and provide an invaluable tool for future structural studies of how the SNARE complex binds to other components of the release machinery.     

A dual role of SNAP‐25 as carrier and guardian of synaptic transmission

In this issue, Matteoli and colleagues show that SNAP-25 levels regulate the efficacy of presynaptic glutamate release and thereby alter short-term plasticity, with potential relevance for psychiatric diseases.EMBO reports(2013) 14 7, 645–651 doi:10.1038/embor.2013.75Control of exocytotic neurotransmitter release is essential for communication in the nervous system and for preventing synaptic abnormalities. The function of synaptosomal-associated protein of 25 kDa (SNAP-25) as a crucial component of the core machinery required for synaptic vesicle fusion is well established, but evidence is growing to suggest an additional modulatory role in neurotransmission. In this issue of EMBO reports, Antonucci et al show that the efficacy of evoked glutamate release is modulated by the expression levels of SNAP-25—a function that might relate to the ability of SNAP-25 to modulate voltage-gated calcium channels and presynaptic calcium ion concentration [1]. Altered synaptic transmission and short-term plasticity due to changes in SNAP-25 expression might have direct consequences for brain function and for the development of neuropsychiatric disorders.Communication between neurons is essential for brain function and occurs through chemical neurotransmission at specialized cell–cell contacts termed ‘synapses''. Within the nerve terminal of the presynaptic neuron electrical stimuli cause the opening of voltage-gated calcium channels (VGCCs), which results in the influx of calcium ions. This triggers the exocytic release of neurotransmitter by fusion of synaptic vesicles with the presynaptic membrane. Released neurotransmitter molecules are detected by specific receptors expressed by the postsynaptic neuron.Calcium-induced synaptic vesicle fusion requires complex assembly between the soluble N-ethylmaleimide-sensitive factor (NSF) attachment protein receptor (SNARE) synaptobrevin 2, located on the synaptic vesicle, and the abundant plasma membrane SNAREs SNAP-25 and syntaxin 1, on the opposing presynaptic plasma membrane. SNARE complex assembly is tightly regulated by Sec1/Munc18-like proteins [2]. Further regulatory factors such as the synaptic vesicle calcium-sensing protein synaptotagmin 1 couple the SNARE machinery to presynaptic calcium influx. SNARE-mediated neurotransmitter release occurs preferentially at the active zone—a presynaptic membrane domain specialized for exocytosis within which VGCCs are positioned close to docked synaptic vesicles through a proteinaceous cytomatrix and associated cell adhesion molecules [3,4].Altered short-term plasticity due to changes in SNAP-25 expression might have direct consequences for brain function and for the development of neuropsychiatric disordersAn unresolved conundrum in synaptic transmission remains—the observation that SNARE proteins, such as SNAP-25, are among the most highly expressed, in copy number, presynaptic proteins, whilst only a handful of SNARE complexes are needed to drive the fusion of a single synaptic vesicle [5]. Why, then, are SNAREs such as SNAP-25 so abundant? One possible explanation might be that SNARE proteins, in addition to forming trans-SNARE complexes, assemble with other proteins, and such partitioning might regulate neurotransmission. For example, SNAP-25 has been shown to negatively regulate VGCCs in glutamatergic but not in GABAergic neurons [6]. A secondary regulatory function of SNAP-25 is also supported by its genetic association with synaptic abnormalities such as schizophrenia and attention deficit hyperactivity disorder (ADHD) in humans [7]. SNAP-25 expression is reduced twofold in the hippocampus and frontal lobe from schizophrenic patients [8] and in animal models for ADHD [9]. Thus, SNAP-25 expression levels might crucially regulate normal synaptic function.A new study in this issue of EMBO reports by Antonucci and colleagues investigates the consequences of reduced SNAP-25 expression on synaptic function in SNAP-25^+/− heterozygous (Het) mutant mice. By using patch clamp electrophysiology, Antonucci et al revealed a selective enhancement of glutamatergic but not GABAergic neurotransmission as a result of reduced SNAP-25 expression. Several other parameters including the amplitude and frequency of miniature excitatory and inhibitory currents were unaffected. These data indicate that reduced levels of SNAP-25, an essential component of the fusion machinery, selectively enhance evoked release of glutamate whilst synaptic connectivity and postsynaptic glutamate receptor sensitivity remain unaltered. Further electrophysiological experiments in hippocampal neurons in culture showed that elevated glutamatergic transmission was probably due to increased release probability rather than changes in the number of fusion-prone, so-called ‘readily releasable synaptic vesicles''. This effect was occluded by pharmacologically induced calcium entry bypassing VGCCs, suggesting that altered calcium influx might underlie the differences in evoked glutamate release between wild-type and SNAP-25 Het neurons. As schizophrenia and ADHD are associated with changes in short-term plasticity, a paradigm reflecting presynaptic function, Antonucci et al analysed neurotransmission by paired-pulse stimulation—a protocol whereby two closely paired stimuli are applied within a 50 ms time interval. Wild-type neurons showed significant short-term facilitation, that is, a stronger response to the second stimulus as a result of increased calcium levels in the presynaptic compartment. By contrast, Het neurons had a reduced response to the second stimulus. Such paired-pulse depression is commonly viewed as a sign of increased release probability, which occurs when the first stimulus induces a partial depletion of release-ready synaptic vesicles during paired stimulation. As a consequence, the second stimulus evokes a comparably reduced response [3]. The switch from paired-pulse facilitation to depression was not fully reproduced in hippocampal slices from wild-type and Het mice, although facilitation seemed to be attenuated in SNAP-25 Het slices. One possible explanation for the apparent discrepancy between cultured neurons taken from newborn animals and acute slices from adult mice is the constant postnatal increase in SNAP-25 expression in SNAP-25 Het mice [10], which might partly counteract the defects caused by heterozygosity. Consistent with this explanation are data from rescue experiments by Antonucci et al, which showed that altered neurotransmission and defects in short-term plasticity in Het neurons can be gradually recovered in parallel with increased SNAP-25 expression. Moreover, cultured neurons show substantially higher levels of endogenous activity compared with acute slice preparations, leading to possible changes in the partitioning of SNAP-25 between SNARE complexes and association with VGCCs. Further experiments are clearly required to resolve these issues. Irrespective of these potential caveats, the combined data support the hypothesis that alterations in SNAP-25 expression underlie regulatory changes in neurotransmission, resulting in altered short-term plasticity and possibly disease.Many open questions remain. In particular, the precise mechanisms underlying elevated glutamatergic transmission and presynaptic plasticity under conditions of reduced SNAP-25 expression remain elusive. It has been shown before that free SNAP-25 inhibits Cav2.1-type VGCCs [6], an effect reversed by overexpression of synaptotagmin 1, which might associate with SNAP-25. Conversely, SNAP-25 occludes negative regulation of Cav2.2 VGCCs by free syntaxin 1 [3]. Hence, it is tempting to speculate that differential partitioning of SNAP-25 between free, SNARE-, synaptotagmin 1- and VGCC-complexed forms could regulate evoked neurotransmission (Fig 1). In this scenario, reduced SNAP-25 expression in Het animals and in schizophrenic and ADHD patients would be sufficient to sustain SNARE-mediated synaptic vesicle fusion but partially releases VGCCS from SNAP-25-mediated inhibition. This would result in elevated calcium influx and facilitated neurotransmission. Additional levels of regulation could be imposed by developmental switching between alternatively spliced ‘a'' and ‘b'' isoforms of SNAP-25 [11], age-dependent alterations in presynaptic protein turnover and post-translational modifications.Open in a separate windowFigure 1Effect of presynaptic SNAP-25 levels on calcium-induced glutamate release. Top: in wild-type (WT) neurons, SNARE-mediated calcium-triggered synaptic vesicle fusion is negatively regulated by complex formation between SNAP-25 and VGCCs. Bottom: reduced SNAP-25 expression in heterozygotes (Het;^+/−) partly releases VGCCs from SNAP-25-mediated clamping, resulting in elevated calcium influx through VGCCs and increased glutamate release through SNARE-mediated calcium-triggered synaptic vesicle fusion. Note that many key exocytotic proteins have been omitted for clarity. SNAP-25, synaptosomal-associated protein of 25 kDa; SNARE, soluble NSF attachment protein receptor; VGCC. voltage-gated calcium channel.Future studies need to address these possibilities, and their relationship to cognitive impairments and synaptic diseases, such as schizophrenia and ADHD.     

Distinct protein domains are responsible for the interaction of Hrs-2 with SNAP-25. The role of Hrs-2 in 7 S complex formation

Regulated secretion of neurotransmitter at the synapse is likely to be mediated by dynamic protein interactions involving components of the vesicle (vesicle-associated membrane protein; VAMP) and plasma membrane (syntaxin and synaptosomal associated protein of 25 kDa (SNAP-25)) along with additional molecules that allow for the regulation of this process. Recombinant Hrs-2 interacts with SNAP-25 in a calcium-dependent manner (they dissociate at elevated calcium levels) and inhibits neurotransmitter release. Thus, Hrs-2 has been hypothesized to serve a negative regulatory role in secretion through its interaction with SNAP-25. In this report, we show that Hrs-2 and SNAP-25 interact directly through specific coiled-coil domains in each protein. The presence of syntaxin enhances the binding of Hrs-2 to SNAP-25. Moreover, while both Hrs-2 and VAMP can separately bind to SNAP-25, they cannot bind simultaneously. Additionally, the presence of Hrs-2 reduces the incorporation of VAMP into the syntaxin.SNAP-25.VAMP (7 S) complex. These findings suggest that Hrs-2 may modulate exocytosis by regulating the assembly of a protein complex implicated in membrane fusion.     

Calcium regulation of exocytosis in PC12 cells

The calcium (Ca(2+)) regulation of neurotransmitter release is poorly understood. Here we investigated several aspects of this process in PC12 cells. We first showed that osmotic shock by 1 m sucrose stimulated rapid release of neurotransmitters from intact PC12 cells, indicating that most of the vesicles were docked at the plasma membrane. Second, we further investigated the mechanism of rescue of botulinum neurotoxin E inhibition of release by recombinant SNAP-25 COOH-terminal coil, which is known to be required in the triggering stage. We confirmed here that Ca(2+) was required simultaneously with the SNAP-25 peptide, with no significant increase in release if either the peptide or Ca(2+) was present during the priming stage as well as the triggering, suggesting that SNARE (soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptor) complex assembly was involved in the final Ca(2+)-triggered event. Using this rescue system, we also identified a series of acidic surface SNAP-25 residues that rescued better than wild-type when mutated, due to broadened Ca(2+) sensitivity, suggesting that this charged patch may interact electrostatically with a negative regulator of membrane fusion. Finally, we showed that the previously demonstrated stimulation of exocytosis in this system by calmodulin required calcium binding, since calmodulin mutants defective in Ca(2+)-binding were not able to enhance release.     

Interactions between proteins implicated in exocytosis and voltage-gated calcium channels

Neurotransmitter release from synaptic vesicles is triggered by voltage-gated calcium influx through P/Q-type or N-type calcium channels. Purification of N-type channels from rat brain synaptosomes initially suggested molecular interactions between calcium channels and two key proteins implicated in exocytosis: synaptotagmin I and syntaxin 1. Co-immunoprecipitation experiments were consistent with the hypothesis that both N- and P/Q-type calcium channels, but not L-type channels, are associated with the 7S complex containing syntaxin 1, SNAP-25, VAMP and synaptotagmin I or II. Immunofluorescence confocal microscopy at the frog neuromuscular junction confirmed that calcium channels, syntaxin 1 and SNAP-25 are co-localized at active zones of the presynaptic plasma membrane where transmitter release occurs. Experiments with recombinant proteins were performed to map synaptic protein interaction sites on the alpha 1A subunit, which forms the pore of the P/Q-type calcium channel. In vitro-translated 35S-synaptotagmin I bound to a site located on the cytoplasmic loop linking homologous domains II and III of the alpha 1A subunit. This direct link would target synaptotagmin, a putative calcium sensor for exocytosis, to a microdomain of calcium influx close to the channel mouth. Cysteine string proteins (CSPs) contain a J-domain characteristic of molecular chaperones that cooperate with Hsp70. They are located on synaptic vesicles and thought to be involved in modulating the activity of presynaptic calcium channels. CSPs were found to bind to the same domain of the calcium channel as synaptotagmin, and also to associate with VAMP. CSPs may act as molecular chaperones in association with Hsp70 to direct assembly or dissociation of multiprotein complexes at the calcium channel.     

Tomosyn inhibits synaptotagmin-1-mediated step of Ca2+-dependent neurotransmitter release through its N-terminal WD40 repeats

Neurotransmitter release is triggered by Ca(2+) binding to a low affinity Ca(2+) sensor, mostly synaptotagmin-1, which catalyzes SNARE-mediated synaptic vesicle fusion. Tomosyn negatively regulates Ca(2+)-dependent neurotransmitter release by sequestering target SNAREs through the C-terminal VAMP-like domain. In addition to the C terminus, the N-terminal WD40 repeats of tomosyn also have potent inhibitory activity toward Ca(2+)-dependent neurotransmitter release, although the molecular mechanism underlying this effect remains elusive. Here, we show that through its N-terminal WD40 repeats tomosyn directly binds to synaptotagmin-1 in a Ca(2+)-dependent manner. The N-terminal WD40 repeats impaired the activities of synaptotagmin-1 to promote SNARE complex-mediated membrane fusion and to bend the lipid bilayers. Decreased acetylcholine release from N-terminal WD40 repeat-microinjected superior cervical ganglion neurons was relieved by microinjection of the cytoplasmic domain of synaptotagmin-1. These results indicate that, upon direct binding, the N-terminal WD40 repeats negatively regulate the synaptotagmin-1-mediated step of Ca(2+)-dependent neurotransmitter release. Furthermore, we show that synaptotagmin-1 binding enhances the target SNARE-sequestering activity of tomosyn. These results suggest that the interplay between tomosyn and synaptotagmin-1 underlies inhibitory control of Ca(2+)-dependent neurotransmitter release.     

SNAP-25 is expressed in islets of Langerhans and is involved in insulin release

SNAP-25 is known as a neuron specific molecule involved in the fusion of small synaptic vesicles with the presynaptic plasma membrane. By immunolocalization and Western blot analysis, it is now shown that SNAP- 25 is also expressed in pancreatic endocrine cells. Botulinum neurotoxins (BoNT) A and E were used to study the role of SNAP-25 in insulin secretion. These neurotoxins inhibit transmitter release by cleaving SNAP-25 in neurons. Cells from a pancreatic B cell line (HIT) and primary rat islet cells were permeabilized with streptolysin-O to allow toxin entry. SNAP-25 was cleaved by BoNT/A and BoNT/E, resulting in a molecular mass shift of approximately 1 and 3 kD, respectively. Cleavage was accompanied by an inhibition of Ca(++)-stimulated insulin release in both cell types. In HIT cells, a concentration of 30-40 nM BoNT/E gave maximal inhibition of stimulated insulin secretion of approximately 60%, coinciding with essentially complete cleavage of SNAP-25. Half maximal effects in terms of cleavage and inhibition of insulin release were obtained at a concentration of 5-10 nM. The A type toxin showed maximal and half-maximal effects at concentrations of 4 and 2 nM, respectively. In conclusion, the results suggest a role for SNAP-25 in fusion of dense core secretory granules with the plasma membrane in an endocrine cell type- the pancreatic B cell.     

Association of botulinum neurotoxin serotype A light chain with plasma membrane-bound SNAP-25

The Clostridium botulinum neurotoxins (BoNTs) cleave SNARE proteins, which inhibit binding and thus fusion of neurotransmitter vesicles to the plasma membrane of peripheral neurons. BoNTs comprise an N-terminal light chain (LC) and C-terminal heavy chain, which are linked by a disulfide bond. There are seven serotypes (A-G) of BoNTs based upon immunological neutralization. Although the binding and entry of BoNT/A into neurons has been subjected to considerable investigation, the intracellular events that allow BoNT/A to efficiently cleave SNAP-25 within neurons is less well understood. Earlier studies showed that intracellular LC/A bound to the plasma membrane of neurons. In this study, intracellular LC/A is shown to directly bind SNAP-25 on the plasma membrane. Solid phase binding showed that the N-terminal residues of LC/A bound residues 80-110 of SNAP-25, which was also observed in cultured neurons. Association of the N-terminal 8 amino acids of LC/A and residues 80-110 of SNAP-25 also enhanced substrate cleavage. These findings explain how LC/A associates with SNAP-25 on the plasma membrane and provide a basis for LC/A cleavage of SNAP-25 within the SNARE complex.     

Tight coupling of the t-SNARE and calcium channel microdomains in adrenomedullary slices and not in cultured chromaffin cells

Regulated exocytosis involves calcium-dependent fusion of secretory vesicles with the plasma membrane with three SNARE proteins playing a central role: the vesicular synaptobrevin and the plasma membrane syntaxin1 and SNAP-25. Cultured bovine chromaffin cells possess defined plasma membrane microdomains that are specifically enriched in both syntaxin1 and SNAP-25. We now show that in both isolated cells and adrenal medulla slices these target SNARE (t-SNARE) patches quantitatively coincide with single vesicle secretory spots as detected by exposure of the intravesicular dopamine beta-hydroxylase onto the plasmalemma. During exocytosis, neither area nor density of the syntaxin1/SNAP-25 microdomains changes on the plasma membrane of both preparations confirming that preexisting clusters act as the sites for vesicle fusion. Our analysis reveals a high level of colocalization of L, N and P/Q type calcium channel clusters with SNAREs in adrenal slices; this close association is altered in individual cultured cells. Therefore, microdomains carrying syntaxin1/SNAP-25 and different types of calcium channels act as the sites for physiological granule fusion in "in situ" chromaffin cells. In the case of isolated cells, it is the t-SNAREs microdomains rather than calcium channels that define the sites of exocytosis.