Involvement of cholesterol in synaptic vesicle swelling

2010 ◽  
Vol 235 (4) ◽  
pp. 470-477 ◽  
Author(s):  
Jin-Sook Lee ◽  
Won Jin Cho ◽  
Leah Shin ◽  
Bhanu P Jena
Keyword(s):  
Synaptic Vesicle ◽  
Synaptic Vesicles ◽  
Critical Role ◽  
Water Channel ◽  
Secretory Vesicle ◽  
Significant Loss ◽  
Cell Secretion ◽  
Vesicle Membrane ◽  
First Time

Studies demonstrate that cholesterol plays a critical role in the regulation of neurotransmitter release and that secretory vesicle swelling is a requirement for the regulated expulsion of intravesicular contents during cell secretion. In view of this, the involvement of cholesterol in synaptic vesicle swelling was hypothesized and tested in the present study, using isolated synaptic vesicles from rat brain and the determination of their swelling competency in the presence and absence of cholesterol. The involvement of the water channel aquaporin-6 (AQP-6) and proton pump vH+-ATPase in GTP-G αo-mediated synaptic vesicle swelling has been reported previously. Mastoparan, the amphiphilic tetradecapeptide from wasp venom, known to activate the GTPase activity of G αo/i proteins, stimulates synaptic vesicle swelling in the presence of GTP. In the current study, using nanometer-scale precision measurements of isolated synaptic vesicles, we report for the first time that depletion of cholesterol from synaptic vesicle membrane results in a significant loss of GTP-mastoparan-stimulable synaptic vesicle swelling. In contrast, incorporation of cholesterol into the synaptic vesicle membrane potentiates GTP-mastoparan-stimulable vesicle swelling. Our study further demonstrates that this effect of cholesterol is due, in part, to its involvement in the interactions between AQP-6, vH+-ATPase and the GTP-binding G αo protein at the synaptic vesicle membrane.

Molecular Machinery and Mechanism of Cell Secretion

2005 ◽  
Vol 230 (5) ◽  
pp. 307-319 ◽  
Author(s):  
Bhanu P. Jena
Keyword(s):  
Lipid Membrane ◽  
Secretory Vesicle ◽  
Secretory Process ◽  
Secretory Vesicles ◽  
Cell Secretion ◽  
Vesicle Membrane ◽  
Cellular Processes ◽  
Molecular Machinery ◽  
Secretory Products ◽  
First Time

Secretion occurs in all living cells and involves the delivery of intracellular products to the cell exterior. Secretory products are Packaged and stored in membranous sacs or vesicles within the cell. When the cell needs to secrete these products, the secretory vesicles containing them dock and fuse at plasma membrane-associated supramolecular structures, called poro-somes, to release their contents. Specialized cells for neurotransmission, enzyme secretion, or hormone release use a highly regulated secretory process. Similar to other fundamen-tal cellular processes, cell secretion is precisely regulated. During secretion, swelling of secretory vesicles results in a build-up of intravesicular pressure, allowing expulsion of vesicular contents. The extent of vesicle swelling dictates the amount of vesicular contents expelled. The discovery of the Porosome as the universal secretory machinery, its isolation, its structure and dynamics at nanometer resolution and in real time, and its biochemical composition and functional reconstitution into artificial lipid membrane have been determined. The Molecular mechanism of secretory vesicle swelling and the fusion of opposing bilayers, that is, the fusion of secretory vesicle membrane at the base of the porosome membrane, have also been resolved. These findings reveal, for the first time, the universal molecular machinery and mechanism of secretion in cells.

scholarly journals Botulinum Neurotoxin a Blocks Synaptic Vesicle Exocytosis but Not Endocytosis at the Nerve Terminal

1999 ◽  
Vol 147 (6) ◽  
pp. 1249-1260 ◽  
Author(s):  
Elaine A. Neale ◽  
Linda M. Bowers ◽  
Min Jia ◽  
Karen E. Bateman ◽  
Lura C. Williamson
Keyword(s):  
Synaptic Vesicle ◽  
Nerve Terminal ◽  
Neurotransmitter Release ◽  
Synaptic Vesicles ◽  
Botulinum Neurotoxin ◽  
Vesicle Membrane ◽  
Botulinum Neurotoxin A ◽  
Synaptic Vesicle Exocytosis ◽  
Vesicle Exocytosis ◽  
Botulinum Neurotoxins

The supply of synaptic vesicles in the nerve terminal is maintained by a temporally linked balance of exo- and endocytosis. Tetanus and botulinum neurotoxins block neurotransmitter release by the enzymatic cleavage of proteins identified as critical for synaptic vesicle exocytosis. We show here that botulinum neurotoxin A is unique in that the toxin-induced block in exocytosis does not arrest vesicle membrane endocytosis. In the murine spinal cord, cell cultures exposed to botulinum neurotoxin A, neither K+-evoked neurotransmitter release nor synaptic currents can be detected, twice the ordinary number of synaptic vesicles are docked at the synaptic active zone, and its protein substrate is cleaved, which is similar to observations with tetanus and other botulinal neurotoxins. In marked contrast, K+ depolarization, in the presence of Ca2+, triggers the endocytosis of the vesicle membrane in botulinum neurotoxin A–blocked cultures as evidenced by FM1-43 staining of synaptic terminals and uptake of HRP into synaptic vesicles. These experiments are the first demonstration that botulinum neurotoxin A uncouples vesicle exo- from endocytosis, and provide evidence that Ca2+ is required for synaptic vesicle membrane retrieval.

scholarly journals Interactions of synapsin I with phospholipids: possible role in synaptic vesicle clustering and in the maintenance of bilayer structures.

1993 ◽  
Vol 123 (6) ◽  
pp. 1845-1855 ◽  
Author(s):  
F Benfenati ◽  
F Valtorta ◽  
M C Rossi ◽  
F Onofri ◽  
T Sihra ◽  
...  
Keyword(s):  
Synaptic Vesicle ◽  
Synaptic Vesicles ◽  
High Surface ◽  
Resonance Spectroscopy ◽  
Synapsin I ◽  
Hydrophobic Core ◽  
Membrane Phospholipids ◽  
Head Region ◽  
Vesicle Membrane ◽  
Liposome Fusion

Synapsin I is a synaptic vesicle-specific phosphoprotein composed of a globular and hydrophobic head and of a proline-rich, elongated and basic tail. Synapsin I binds with high affinity to phospholipid and protein components of synaptic vesicles. The head region of the protein has a very high surface activity, strongly interacts with acidic phospholipids and penetrates the hydrophobic core of the vesicle membrane. In the present paper, we have investigated the possible functional effects of the interaction between synapsin I and vesicle phospholipids. Synapsin I enhances both the rate and the extent of Ca(2+)-dependent membrane fusion, although it has no detectable fusogenic activity per se. This effect, which appears to be independent of synapsin I phosphorylation and localized to the head region of the protein, is attributable to aggregation of adjacent vesicles. The facilitation of Ca(2+)-induced liposome fusion is maximal at 50-80% of vesicle saturation and then decreases steeply, whereas vesicle aggregation does not show this biphasic behavior. Association of synapsin I with phospholipid bilayers does not induce membrane destabilization. Rather, 31P-nuclear magnetic resonance spectroscopy demonstrated that synapsin I inhibits the transition of membrane phospholipids from the bilayer (L alpha) to the inverted hexagonal (HII) phase induced either by increases in temperature or by Ca2+. These properties might contribute to the remarkable selectivity of the fusion of synaptic vesicles with the presynaptic plasma membrane during exocytosis.

scholarly journals Synuclein Regulates Synaptic Vesicle Clustering and Docking at a Vertebrate Synapse

2021 ◽  
Vol 9 ◽  
Author(s):  
Kaitlyn E. Fouke ◽  
M. Elizabeth Wegman ◽  
Sarah A. Weber ◽  
Emily B. Brady ◽  
Cristina Román-Vendrell ◽  
...  
Keyword(s):  
Synaptic Vesicle ◽  
Active Zone ◽  
Synaptic Vesicles ◽  
Significant Loss ◽  
Binding Partner ◽  
Reserve Pool ◽  
Associated Proteins ◽  
Dose Dependent ◽  
Total Membrane ◽  
Synapsin 1

Neurotransmission relies critically on the exocytotic release of neurotransmitters from small synaptic vesicles (SVs) at the active zone. Therefore, it is essential for neurons to maintain an adequate pool of SVs clustered at synapses in order to sustain efficient neurotransmission. It is well established that the phosphoprotein synapsin 1 regulates SV clustering at synapses. Here, we demonstrate that synuclein, another SV-associated protein and synapsin binding partner, also modulates SV clustering at a vertebrate synapse. When acutely introduced to unstimulated lamprey reticulospinal synapses, a pan-synuclein antibody raised against the N-terminal domain of α-synuclein induced a significant loss of SVs at the synapse. Both docked SVs and the distal reserve pool of SVs were depleted, resulting in a loss of total membrane at synapses. In contrast, antibodies against two other abundant SV-associated proteins, synaptic vesicle glycoprotein 2 (SV2) and vesicle-associated membrane protein (VAMP/synaptobrevin), had no effect on the size or distribution of SV clusters. Synuclein perturbation caused a dose-dependent reduction in the number of SVs at synapses. Interestingly, the large SV clusters appeared to disperse into smaller SV clusters, as well as individual SVs. Thus, synuclein regulates clustering of SVs at resting synapses, as well as docking of SVs at the active zone. These findings reveal new roles for synuclein at the synapse and provide critical insights into diseases associated with α-synuclein dysfunction, such as Parkinson’s disease.

Identification of synapsin I peptides that insert into lipid membranes

2001 ◽  
Vol 354 (1) ◽  
pp. 57-66 ◽  
Author(s):  
James J. CHEETHAM ◽  
Sabine HILFIKER ◽  
Fabio BENFENATI ◽  
Thomas WEBER ◽  
Paul GREENGARD ◽  
...  
Keyword(s):  
Synaptic Vesicle ◽  
Synaptic Vesicles ◽  
Molecular Mechanisms ◽  
Phospholipid Bilayer ◽  
Synapsin I ◽  
Affinity Binding ◽  
Hydrophobic Core ◽  
Vesicle Membrane ◽  
High Affinity Binding ◽  
High Affinity

The synapsins constitute a family of synaptic vesicle-associated phosphoproteins essential for regulating neurotransmitter release and synaptogenesis. The molecular mechanisms underlying the selective targeting of synapsin I to synaptic vesicles are thought to involve specific protein–protein interactions, while the high-affinity binding to the synaptic vesicle membrane may involve both protein–protein and protein–lipid interactions. The highly hydrophobic N-terminal region of the protein has been shown to bind with high affinity to the acidic phospholipids phosphatidylserine and phosphatidylinositol and to penetrate the hydrophobic core of the lipid bilayer. To precisely identify the domains of synapsin I which mediate the interaction with lipids, synapsin I was bound to liposomes containing the membrane-directed carbene-generating reagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine and subjected to photolysis. Isolation and N-terminal amino acid sequencing of 125I-labelled synapsin I peptides derived from CNBr cleavage indicated that three distinct regions in the highly conserved domain C of synapsin I insert into the hydrophobic core of the phospholipid bilayer. The boundaries of the regions encompass residues 166–192, 233–258 and 278–327 of bovine synapsin I. These regions are surface-exposed in the crystal structure of domain C of bovine synapsin I and are evolutionarily conserved among isoforms across species. The present data offer a molecular explanation for the high-affinity binding of synapsin I to phospholipid bilayers and synaptic vesicles.

scholarly journals Synaptic vesicle membrane proteins interact to form a multimeric complex.

1992 ◽  
Vol 116 (3) ◽  
pp. 761-775 ◽  
Author(s):  
M K Bennett ◽  
N Calakos ◽  
T Kreiner ◽  
R H Scheller
Keyword(s):  
Membrane Proteins ◽  
Membrane Protein ◽  
Synaptic Vesicle ◽  
Protein Interactions ◽  
Synaptic Vesicles ◽  
Spatial Organization ◽  
Gel Filtration ◽  
Vesicle Membrane ◽  
Multicomponent Complex ◽  
Membrane Components

Potential interactions between membrane components of rat brain synaptic vesicles were analyzed by detergent solubilization followed by size fractionation or immunoprecipitation. The behavior of six synaptic vesicle membrane proteins as well as a plasma membrane protein was monitored by Western blotting. Solubilization of synaptic vesicle membranes in CHAPS resulted in the recovery of a large protein complex that included SV2, p65, p38, vesicle-associated membrane protein, and the vacuolar proton pump. Solubilization in octylglucoside resulted in the preservation of interactions between SV2, p38, and rab3A, while solubilization of synaptic vesicles with Triton X-100 resulted in two predominant interactions, one involving p65 and SV2, and the other involving p38 and vesicle-associated membrane protein. The multicomponent complex preserved with CHAPS solubilization was partially reconstituted following octylglucoside solubilization and subsequent dialysis against CHAPS. Reduction of the CHAPS concentration by gel filtration chromatography resulted in increased recovery of the multicomponent complex. Examination of the large complex isolated from CHAPS-solubilized vesicles by negative stain EM revealed structures with multiple globular domains, some of which were specifically labeled with gold-conjugated antibodies directed against p65 and SV2. The protein interactions defined in this report are likely to underlie aspects of neurotransmitter secretion, membrane traffic, and the spatial organization of vesicles within the nerve terminal.

scholarly journals Retrieval and recycling of synaptic vesicle membrane in pinched-off nerve terminals (synaptosomes).

1978 ◽  
Vol 78 (3) ◽  
pp. 685-700 ◽  
Author(s):  
R C Fried ◽  
M P Blaustein
Keyword(s):  
Synaptic Vesicle ◽  
Synaptic Vesicles ◽  
Plasma Membranes ◽  
Large Diameter ◽  
Small Diameter ◽  
Physiological Saline ◽  
Nerve Terminals ◽  
Vesicle Membrane ◽  
Thorium Dioxide ◽  
Vesicular Exocytosis

The morphological features of pinched-off presynaptic nerve terminals (synaptosomes) from rat brain were examined with electron microscope techniques; in many experiments, an extracellular marked (horseradish peroxidase or colloidal thorium dioxide) was included in the incubation media. When incubated in physiological saline, most terminals appeared approximately spherical, and were filled with small (approximately 400-A diameter) "synaptic vesicles"; mitochondria were also present in many of the terminals. In a number of instances the region of synaptic contact, with adhering portions of the postsynaptic cell membrane and postsynaptic density, could be readily discerned. Approximately 20--30% of the terminals in our preparations exhibited clear evidence of damage, as indicated by diffuse distribution of extracellular markers in the cytoplasm; the markers appeared to be excluded from the intraterminal vesicles under these circumstances. The markers were excluded from the cytoplasm in approximately 70--80% of the terminals, which may imply that these terminals have intact plasma membranes. When the terminals were treated with depolarizing agents (veratridine or K-rich media), in the presence of Ca, many new, large (600--900-A diameter) vesicles and some coated vesicles and new vacuoles appeared. When the media contained an extracellular marker, the newly formed structures frequently were labeled with the marker. If the veratridine-depolarized terminals were subsequently treated with tetrodotoxin (to repolarize the terminals) and allowed to "recover" for 60--90 min, most of the large marker-containing vesicles disappeared, and numerous small (approximately 400-A diameter) marker-containing vesicles appeared. These observations are consistent with the idea that pinched-off presynaptic terminals contain all of the machinery necessary for vesicular exocytosis and for the retrieval and recycling of synaptic vesicle membrane. The vesicle membrane appears to be retrieval primarily in the form of large diameter vesicles which are subsequently reprocessed to form new "typical" small-diameter synaptic vesicles.

scholarly journals Cross-linking mass spectrometry uncovers protein interactions and functional assemblies in synaptic vesicle membranes

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Sabine Wittig ◽  
Marcelo Ganzella ◽  
Marie Barth ◽  
Susann Kostmann ◽  
Dietmar Riedel ◽  
...  
Keyword(s):  
Mass Spectrometry ◽  
Synaptic Vesicle ◽  
Protein Interactions ◽  
Synaptic Vesicles ◽  
Large Scale ◽  
Cross Linking ◽  
Synaptic Membrane ◽  
Biophysical Parameters ◽  
Vesicle Membrane ◽  
Pass Through

AbstractSynaptic vesicles are storage organelles for neurotransmitters. They pass through a trafficking cycle and fuse with the pre-synaptic membrane when an action potential arrives at the nerve terminal. While molecular components and biophysical parameters of synaptic vesicles have been determined, our knowledge on the protein interactions in their membranes is limited. Here, we apply cross-linking mass spectrometry to study interactions of synaptic vesicle proteins in an unbiased approach without the need for specific antibodies or detergent-solubilisation. Our large-scale analysis delivers a protein network of vesicle sub-populations and functional assemblies including an active and an inactive conformation of the vesicular ATPase complex as well as non-conventional arrangements of the luminal loops of SV2A, Synaptophysin and structurally related proteins. Based on this network, we specifically target Synaptobrevin-2, which connects with many proteins, in different approaches. Our results allow distinction of interactions caused by ‘crowding’ in the vesicle membrane from stable interaction modules.

scholarly journals EVIDENCE FOR RECYCLING OF SYNAPTIC VESICLE MEMBRANE DURING TRANSMITTER RELEASE AT THE FROG NEUROMUSCULAR JUNCTION

1973 ◽  
Vol 57 (2) ◽  
pp. 315-344 ◽  
Author(s):  
J. E. Heuser ◽  
T. S. Reese
Keyword(s):  
Plasma Membrane ◽  
Synaptic Vesicle ◽  
Synaptic Vesicles ◽  
Motor Nerve ◽  
Coated Vesicles ◽  
Synaptic Membrane ◽  
Nerve Terminals ◽  
Frog Neuromuscular Junction ◽  
Vesicle Membrane ◽  
Intracellular Compartments

When the nerves of isolated frog sartorius muscles were stimulated at 10 Hz, synaptic vesicles in the motor nerve terminals became transiently depleted. This depletion apparently resulted from a redistribution rather than disappearance of synaptic vesicle membrane, since the total amount of membrane comprising these nerve terminals remained constant during stimulation. At 1 min of stimulation, the 30% depletion in synaptic vesicle membrane was nearly balanced by an increase in plasma membrane, suggesting that vesicle membrane rapidly moved to the surface as it might if vesicles released their content of transmitter by exocytosis. After 15 min of stimulation, the 60% depletion of synaptic vesicle membrane was largely balanced by the appearance of numerous irregular membrane-walled cisternae inside the terminals, suggesting that vesicle membrane was retrieved from the surface as cisternae. When muscles were rested after 15 min of stimulation, cisternae disappeared and synaptic vesicles reappeared, suggesting that cisternae divided to form new synaptic vesicles so that the original vesicle membrane was now recycled into new synaptic vesicles. When muscles were soaked in horseradish peroxidase (HRP), this tracerfirst entered the cisternae which formed during stimulation and then entered a large proportion of the synaptic vesicles which reappeared during rest, strengthening the idea that synaptic vesicle membrane added to the surface was retrieved as cisternae which subsequently divided to form new vesicles. When muscles containing HRP in synaptic vesicles were washed to remove extracellular HRP and restimulated, HRP disappeared from vesicles without appearing in the new cisternae formed during the second stimulation, confirming that a one-way recycling of synaptic membrane, from the surface through cisternae to new vesicles, was occurring. Coated vesicles apparently represented the actual mechanism for retrieval of synaptic vesicle membrane from the plasma membrane, because during nerve stimulation they proliferated at regions of the nerve terminals covered by Schwann processes, took up peroxidase, and appeared in various stages of coalescence with cisternae. In contrast, synaptic vesicles did not appear to return directly from the surface to form cisternae, and cisternae themselves never appeared directly connected to the surface. Thus, during stimulation the intracellular compartments of this synapse change shape and take up extracellular protein in a manner which indicates that synaptic vesicle membrane added to the surface during exocytosis is retrieved by coated vesicles and recycled into new synaptic vesicles by way of intermediate cisternae.

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