The synaptic vesicle membrane: origin, axonal distribution, protein components, exocytosis and recycling

The paper discusses functional and molecular aspects of the synaptic vesicle membrane during its life cycle. The distribution of the synaptic vesicle membrane compartment in an entire cholinergic neuron is monitored using colloidal gold labelling and a monoclonal antibody against the synaptic vesicle membrane protein SV2. This provides new insights concerning vesicle origin and fate in the various compartments of the neuron. A new synaptic vesicle membrane protein (svp25) of Mr 25,000 with properties similar to synaptophysin as well as a synaptic vesicle binding phosphoprotein of the presynaptic membrane (Mr 92,000) likely to be involved in vesicle exocytosis are described. The membrane compartment recycled on induced transmitter release contains synaptic vesicle but not plasma membrane markers and encloses both newly synthesized transmitter and a sample of extracellular medium.     

Studies of synaptic vesicle endocytosis in the nematode C. elegans

After synaptic vesicle exocytosis, synaptic vesicle proteins must be retrieved from the plasma membrane, sorted away from other membrane proteins, and reconstituted into a functional synaptic vesicle. The nematode Caenorhabditis elegans is an organism well suited for a genetic analysis of this process. In particular, three types of genetic studies have contributed to our understanding of synaptic vesicle endocytosis. First, screens for mutants defective in synaptic vesicle recycling have identified new proteins that function specifically in neurons. Second, RNA interference has been used to quickly confirm the roles of known proteins in endocytosis. Third, gene targeting techniques have elucidated the roles of genes thought to play modulatory or subtle roles in synaptic vesicle recycling. We describe a molecular model for synaptic vesicle recycling and discuss how protein disruption experiments in C. elegans have contributed to this model.     

Recent insights into the building and cycling of synaptic vesicles

The synaptic vesicle is currently the most well-characterized cellular organelle. During neurotransmitter release it undergoes multiple cycles of exo- and endocytosis. Despite this the vesicle manages to retain its protein and lipid composition. How does this happen? Here we provide a brief overview of the molecular architecture of the synaptic vesicle, and discuss recent studies investigating single vesicle behavior and the mechanisms controlling the vesicle’s molecular contents.     

神经末梢突触囊泡释放神经递质过程的调控蛋白

神经末梢突触囊泡释放神经递质是一个复杂且受到精细调控的过程,涉及多种蛋白质间的相互作用。位于突触囊泡膜上的突触囊泡蛋白／突触囊泡相关膜蛋白（synaptobrevin/VAMP),与位于突触前膜上的syntaxin和突触小体相关蛋白SNAP－25,三者聚合形成的可溶性N－甲基马来酰胺敏感因子（NSF）附着蛋白受体（SNARE）核心复合物是突触囊泡胞吐过程中的核心成分。本文主要围绕参与空触囊泡胞吐过程,以及调节SNARE核心复合物的形成,解离及其功能的蛋白质,并对突触囊泡胞吐过程的分子模型作一概述。     

Molecular Underpinnings of Synaptic Vesicle Pool Heterogeneity

Neuronal communication relies on chemical synaptic transmission for information transfer and processing. Chemical neurotransmission is initiated by synaptic vesicle fusion with the presynaptic active zone resulting in release of neurotransmitters. Classical models have assumed that all synaptic vesicles within a synapse have the same potential to fuse under different functional contexts. In this model, functional differences among synaptic vesicle populations are ascribed to their spatial distribution in the synapse with respect to the active zone. Emerging evidence suggests, however, that synaptic vesicles are not a homogenous population of organelles, and they possess intrinsic molecular differences and differential interaction partners. Recent studies have reported a diverse array of synaptic molecules that selectively regulate synaptic vesicles' ability to fuse synchronously and asynchronously in response to action potentials or spontaneously irrespective of action potentials. Here we discuss these molecular mediators of vesicle pool heterogeneity that are found on the synaptic vesicle membrane, on the presynaptic plasma membrane, or within the cytosol and consider some of the functional consequences of this diversity. This emerging molecular framework presents novel avenues to probe synaptic function and uncover how synaptic vesicle pools impact neuronal signaling.      

Calcium dependent neurotransmitter release and protein phosphorylation in synaptic vesicles.

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

Motorneurons require cysteine string protein-α to maintain the readily releasable vesicular pool and synaptic vesicle recycling

Cysteine string protein-α (CSP-α) is a synaptic vesicle protein that prevents activity-dependent neurodegeneration by poorly understood mechanisms. We have studied the synaptic vesicle cycle at the motor nerve terminals of CSP-α knock-out mice expressing the synaptopHluorin transgene. Mutant nerve terminals fail to sustain prolonged release and the number of vesicles available to be released decreases. Strikingly, the SNARE protein SNAP-25 is dramatically reduced. In addition, endocytosis during the stimulus fails to maintain the size of the recycling synaptic vesicle pool during prolonged stimulation. Upon depolarization, the styryl dye FM?2-10 becomes trapped and poorly releasable. Consistently with the functional results, electron microscopy analysis revealed characteristic features of impaired synaptic vesicle recycling. The unexpected defect in vesicle recycling in CSP-α knock-out mice provides insights into understanding molecular mechanisms of degeneration in motor nerve terminals.     

A Highlights from MBoC Selection: Synaptobrevin-2 dependent regulation of single synaptic vesicle endocytosis

Evidence from multiple systems indicates that vesicle SNARE (soluble NSF attachment receptor) proteins are involved in synaptic vesicle endocytosis, although their exact action at the level of single vesicles is unknown. Here we interrogate the role of the main synaptic vesicle SNARE mediating fusion, synaptobrevin-2 (also called VAMP2), in modulation of single synaptic vesicle retrieval. We report that in the absence of synaptobrevin-2, fast and slow modes of single synaptic vesicle retrieval are impaired, indicating a role of the SNARE machinery in coupling exocytosis to endocytosis of single synaptic vesicles. Ultrafast endocytosis was impervious to changes in the levels of synaptobrevin-2, pointing to a separate molecular mechanism underlying this type of recycling. Taken together with earlier studies suggesting a role of synaptobrevin-2 in endocytosis, these results indicate that the machinery for fast synchronous release couples fusion to retrieval and regulates the kinetics of endocytosis in a Ca²⁺-dependent manner.     

Liprin-α2 promotes the presynaptic recruitment and turnover of RIM1/CASK to facilitate synaptic transmission

The presynaptic active zone mediates synaptic vesicle exocytosis, and modulation of its molecular composition is important for many types of synaptic plasticity. Here, we identify synaptic scaffold protein liprin-α2 as a key organizer in this process. We show that liprin-α2 levels were regulated by synaptic activity and the ubiquitin–proteasome system. Furthermore, liprin-α2 organized presynaptic ultrastructure and controlled synaptic output by regulating synaptic vesicle pool size. The presence of liprin-α2 at presynaptic sites did not depend on other active zone scaffolding proteins but was critical for recruitment of several components of the release machinery, including RIM1 and CASK. Fluorescence recovery after photobleaching showed that depletion of liprin-α2 resulted in reduced turnover of RIM1 and CASK at presynaptic terminals, suggesting that liprin-α2 promotes dynamic scaffolding for molecular complexes that facilitate synaptic vesicle release. Therefore, liprin-α2 plays an important role in maintaining active zone dynamics to modulate synaptic efficacy in response to changes in network activity.     

SV2 and o-rab3 Remain Associated with Recycling Synaptic Vesicles

Abstract: o-rab3 is an electric ray homologue of low molecular weight GTP-binding proteins thought to be involved in targeting of secretory vesicles to sites of exocytosis. The stimulation-dependent association of o-rab3 with synaptic vesicles was compared with that of the membrane-integral synaptic vesicle protein 2 (SV2). On application of immunoelectron microscopy and the colloidal gold technique, antibodies against either protein labeled the synaptic vesicle membrane compartment. Synaptic vesicles recycled under conditions of low frequency stimulation (0.1 Hz) retained their complement of both SV2 and o-rab3. Isolation of synaptic vesicles by density-gradient centrifugation and subsequent column chromatography yielded no indication of a stimulation-dependent release of o-rab3 from synaptic vesicles. In contrast, multivesicular bodies and vacuoles occasionally observed in the nerve terminals contained SV2 but little if any o-rab3. It is concluded that o-rab3 remains associated with the synaptic vesicle membrane compartment during stimulation-induced cycles of repeated exo- and endocytosis. o-rab3 may be lost once the vesicle enters the prelysosomal pathway.     

神经递质释放过程中的可溶性NSF附着蛋白受体(SNARE)和相关蛋白

近年来,对突触小泡释放神经递质分子机制的研究迅速发展,发现了大量位于神经末梢的蛋白质.它们之间的相互作用与突触小泡释放神经递质相关,特别是位于突触小泡膜上的突触小泡蛋白/突触小泡相关膜蛋白(synaptobrevin/VAMP),位于突触前膜上的syntaxin和突触小体相关蛋白(synaptosome-associated protein of 25 ku),三者聚合形成的可溶性NSF附着蛋白受体(SNARE)核心复合体在突触小泡的胞裂外排、释放递质过程中有重要作用.而一些已知及未知的与SNARE蛋白有相互作用的蛋白质,可通过调节SNARE核心复合体的形成与解离来影响突触小泡的胞裂外排,从而可以调节突触信号传递的效率及强度,在突触可塑性的形成中起重要作用.     

Phosphorylation of Brain Synaptic and Coated Vesicle Proteins by Endogenous Ca2+/Calmodulin- and cAMP-Dependent Protein Kinases

Phosphorylation of brain synaptic and coated vesicle proteins was stimulated by Ca2+ and calmodulin. As determined by 5-15% sodium dodecylsulfate (SDS) polyacrylamide gel electrophoresis (PAGE), molecular weights (Mr) of the major phosphorylated proteins were 55,000 and 53,000 in synaptic vesicles and 175,000 and 55,000 in coated vesicles. In synaptic vesicles, phosphorylation was inhibited by affinity-purified antibodies raised against a 30,000 Mr protein doublet endogenous to synaptic and coated vesicles. When this doublet, along with clathrin, was extracted from coated vesicles, phosphorylation did not take place, implying that the protein doublet may be closely associated with Ca2+/calmodulin-dependent protein kinase. Affinity-purified antibodies, raised against clathrin used as a control antibody, failed to inhibit Ca2+/calmodulin-dependent phosphorylation in either synaptic or coated vesicles. Immunoelectron cytochemistry revealed that this protein doublet was present in axon terminal synaptic and coated vesicles. Synaptic vesicles also displayed cAMP-dependent kinase activity; coated vesicles did not. The molecular weights of phosphorylated synaptic vesicle proteins in the presence of Mg2+ and cAMP were: 175,000, 100,000, 80,000, 57,000, 55,000, 53,000, 40,000, and 30,000. Based on the different phosphorylation patterns observed in synaptic and coated vesicles, we propose that brain vesicle protein kinase activities may be involved in the regulation of exocytosis and in retrieval of synaptic membrane in presynaptic axon terminals.     

Molecular mechanisms in neurotransmitter release.

The vesicle hypothesis of neurotransmitter release was first formulated in the 1950s, but only recently have the molecular mechanisms involved in neurotransmitter release begun to be elucidated. This short review summarizes current concepts on neurosecretion and the available information on synaptic vesicle exocytosis.     

Immunocytochemical Analysis of Axonal Outgrowth in Synaptotagmin Mutations

Abstract: Synaptotagmin is a synaptic vesicle specific protein that binds calcium and phospholipids in vitro and is required for calcium-regulated fusion of synaptic vesicles with the presynaptic membrane. We have examined the possible requirement for synaptotagmin in axonal outgrowth by following neuronal development in Drosophila embryos deficient for the synaptotagmin gene. We find that synaptotagmin is expressed abundantly in axons and growth cones before synapse formation in wild-type embryos. Using antibodies to the intravesicular domain of synaptotagmin to label live embryos, we demonstrate that vesicle populations containing synaptotagmin actively undergo exocytosis during axonogenesis. We have used immunocytochemical techniques to examine the distribution of the axonal protein Fasciclin II, the presynaptic membrane protein syntaxin, and the synaptic vesicle protein cysteine string protein, in synaptotagmin null mutations. The distribution of these proteins is similar in wild-type and synaptotagmin mutant embryos, suggesting that synaptotagmin is not required for axonogenesis in the CNS or PNS. Based on these findings, we suggest that the molecular mechanisms underlying vesicular-mediated membrane expansion during axonal outgrowth are distinct from those required for synaptic vesicle fusion during neurotransmitter release.     

Inhibition of neurotransmitter release in the lamprey reticulospinal synapse by antibody-mediated disruption of SNAP-25 function

Exocytosis - syntaxin - synaptobrevin - SNARE synaptic vesicle The lamprey giant reticulospinal synapse can be used to manipulate the molecular machinery of synaptic vesicle exocytosis by presynaptic microinjection. Here we test the effect of disrupting the function of the SNARE protein SNAP-25. Polyclonal SNAP-25 antibodies were shown in an in vitro assay to inhibit the binding between syntaxin and SNAP-25. When microinjected presynaptically, these antibodies produced a potent inhibition of the synaptic response. Ba2+ spikes recorded in the presynaptic axon were not altered, indicating that the effect was not due to a reduced presynaptic Ca2+ entry. Electron microscopic analysis showed that synaptic vesicle clusters had a similar organization in synapses of antibody-injected axons as in control axons, and the number of synaptic vesicles in apparent contact with the presynaptic plasma membrane was also similar. Clathrin-coated pits, which normally occur at the plasma membrane around stimulated synapses, were not detected after injection of SNAP-25 antibodies, consistent with a blockade of vesicle cycling. Thus, SNAP-25 antibodies, which disrupt the interaction with syntaxin, inhibit neurotransmitter release without affecting the number of synaptic vesicles at the plasma membrane. These results provide further support to the view that the formation of SNARE complexes is critical for membrane fusion, but not for the targeting of synaptic vesicles to the presynaptic membrane.     

BDNF mobilizes synaptic vesicles and enhances synapse formation by disrupting cadherin-beta-catenin interactions

Neurons of the vertebrate central nervous system have the capacity to modify synapse number, morphology, and efficacy in response to activity. Some of these functions can be attributed to activity-induced synthesis and secretion of the neurotrophin brain-derived neurotrophic factor (BDNF); however, the molecular mechanisms by which BDNF mediates these events are still not well understood. Using time-lapse confocal analysis, we show that BDNF mobilizes synaptic vesicles at existing synapses, resulting in small clusters of synaptic vesicles "splitting" away from synaptic sites. We demonstrate that BDNF's ability to mobilize synaptic vesicle clusters depends on the dissociation of cadherin-beta-catenin adhesion complexes that occurs after tyrosine phosphorylation of beta-catenin. Artificially maintaining cadherin-beta-catenin complexes in the presence of BDNF abolishes the BDNF-mediated enhancement of synaptic vesicle mobility, as well as the longer-term BDNF-mediated increase in synapse number. Together, this data demonstrates that the disruption of cadherin-beta-catenin complexes is an important molecular event through which BDNF increases synapse density in cultured hippocampal neurons.     

Syndapin I, a Synaptic Dynamin-binding Protein that Associates with the Neural Wiskott-Aldrich Syndrome Protein

The GTPase dynamin has been clearly implicated in clathrin-mediated endocytosis of synaptic vesicle membranes at the presynaptic nerve terminal. Here we describe a novel 52-kDa protein in rat brain that binds the proline-rich C terminus of dynamin. Syndapin I (synaptic, dynamin-associated protein I) is highly enriched in brain where it exists in a high molecular weight complex. Syndapin I can be involved in multiple protein–protein interactions via a src homology 3 (SH3) domain at the C terminus and two predicted coiled-coil stretches. Coprecipitation studies and blot overlay analyses revealed that syndapin I binds the brain-specific proteins dynamin I, synaptojanin, and synapsin I via an SH3 domain-specific interaction. Coimmunoprecipitation of dynamin I with antibodies recognizing syndapin I and colocalization of syndapin I with dynamin I at vesicular structures in primary neurons indicate that syndapin I associates with dynamin I in vivo and may play a role in synaptic vesicle endocytosis. Furthermore, syndapin I associates with the neural Wiskott-Aldrich syndrome protein, an actin-depolymerizing protein that regulates cytoskeletal rearrangement. These characteristics of syndapin I suggest a molecular link between cytoskeletal dynamics and synaptic vesicle recycling in the nerve terminal.     

The synaptic vesicle proteome

Synaptic vesicles are key organelles in neurotransmission. Vesicle integral or membrane-associated proteins mediate the various functions the organelle fulfills during its life cycle. These include organelle transport, interaction with the nerve terminal cytoskeleton, uptake and storage of low molecular weight constituents, and the regulated interaction with the pre-synaptic plasma membrane during exo- and endocytosis. Within the past two decades, converging work from several laboratories resulted in the molecular and functional characterization of the proteinaceous inventory of the synaptic vesicle compartment. However, up until recently and due to technical difficulties, it was impossible to screen the entire organelle thoroughly. Recent advances in membrane protein identification and mass spectrometry (MS) have dramatically promoted this field. A comparison of different techniques for elucidating the proteinaceous composition of synaptic vesicles revealed numerous overlaps but also remarkable differences in the protein constituents of the synaptic vesicle compartment, indicating that several protein separation techniques in combination with differing MS approaches are required to identify and characterize the synaptic vesicle proteome. This review highlights the power of various gel separation techniques and MS analyses for the characterization of the proteome of highly purified synaptic vesicles. Furthermore, the newly detected protein assignments to synaptic vesicles, especially those proteins which are new to the inventory of the synaptic vesicle proteome, are critically discussed.     

Evidence for a primary endocytic vesicle involved in synaptic vesicle biogenesis

The regulated release of neurotransmitters at synapses is mediated by the fusion of neurotransmitter-filled synaptic vesicles with the plasma membrane. Continuous synaptic activity relies on the constant recycling of synaptic vesicle proteins into newly formed synaptic vesicles. At least two different mechanisms are presumed to mediate synaptic vesicle biogenesis at the synapse as follows: direct retrieval of synaptic vesicle proteins and lipids from the plasma membrane, and indirect passage of synaptic vesicle proteins through an endosomal intermediate. We have identified a vesicle population with the characteristics of a primary endocytic vesicle responsible for the recycling of synaptic vesicle proteins through the indirect pathway. We find that synaptic vesicle proteins colocalize in this vesicle with a variety of proteins known to recycle from the plasma membrane through the endocytic pathway, including three different glucose transporters, GLUT1, GLUT3, and GLUT4, and the transferrin receptor. These vesicles differ from "classical" synaptic vesicles in their size and their generic protein content, indicating that they do not discriminate between synaptic vesicle-specific proteins and other recycling proteins. We propose that these vesicles deliver synaptic vesicle proteins that have escaped internalization by the direct pathway to endosomes, where they are sorted from other recycling proteins and packaged into synaptic vesicles.     

Rab2 regulates presynaptic precursor vesicle biogenesis at the trans-Golgi

Reliable delivery of presynaptic material, including active zone and synaptic vesicle proteins from neuronal somata to synaptic terminals, is prerequisite for successful synaptogenesis and neurotransmission. However, molecular mechanisms controlling the somatic assembly of presynaptic precursors remain insufficiently understood. We show here that in mutants of the small GTPase Rab2, both active zone and synaptic vesicle proteins accumulated in the neuronal cell body at the trans-Golgi and were, consequently, depleted at synaptic terminals, provoking neurotransmission deficits. Ectopic presynaptic material accumulations consisted of heterogeneous vesicles and short tubules of 40 × 60 nm, segregating in subfractions either positive for active zone or synaptic vesicle proteins and LAMP1, a lysosomal membrane protein. Genetically, Rab2 acts upstream of Arl8, a lysosomal adaptor controlling axonal export of precursors. Collectively, we identified a Golgi-associated assembly sequence of presynaptic precursor biogenesis dependent on a Rab2-regulated protein export and sorting step at the trans-Golgi.