scholarly journals Endocytosis of VAMP is facilitated by a synaptic vesicle targeting signal.

1996 ◽  
Vol 132 (4) ◽  
pp. 537-547 ◽  
Author(s):  
E Grote ◽  
R B Kelly
Keyword(s):  
Plasma Membrane ◽  
Synaptic Vesicle ◽  
Cho Cells ◽  
Synaptic Vesicles ◽  
Synaptic Proteins ◽  
Vesicle Membrane ◽  
Transfected Cells ◽  
Pc12 Cell Line ◽  
Targeting Signal ◽  
Sequence Requirements

After synaptic vesicles fuse with the plasma membrane and release their contents, vesicle membrane proteins recycle by endocytosis and are targeted to newly formed synaptic vesicles. The membrane traffic of an epitope-tagged form of VAMP-2 (VAMP-TAg) was observed in transfected cells to identify sequence requirements for recycling of a synaptic vesicle membrane protein. In the neuroendocrine PC12 cell line VAMP-TAg is found not only in synaptic vesicles, but also in endosomes and on the plasma membrane. Endocytosis of VAMP-TAg is a rapid and saturable process. At high expression levels VAMP-TAg accumulates at the cell surface. Rapid endocytosis of VAMP-TAg also occurs in transfected CHO cells and is therefore independent of other synaptic proteins. The majority of the measured endocytosis is not directly into synaptic vesicles since mutations in VAMP-TAg that enhance synaptic vesicle targeting did not affect endocytosis. Nonetheless, mutations that inhibited synaptic vesicle targeting, in particular replacement of methionine-46 by alanine, inhibited endocytosis by 85% in PC12 cells and by 35% in CHO cells. These results demonstrate that the synaptic vesicle targeting signal is also used for endocytosis and can be recognized in cells lacking synaptic vesicles.

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.

scholarly journals Partial purification of presynaptic plasma membrane by immunoadsorption.

1982 ◽  
Vol 94 (1) ◽  
pp. 88-96 ◽  
Author(s):  
G P Miljanich ◽  
A R Brasier ◽  
R B Kelly
Keyword(s):  
Plasma Membrane ◽  
Synaptic Vesicle ◽  
Nerve Terminal ◽  
Specific Activity ◽  
Electric Organ ◽  
Partial Purification ◽  
Vesicle Membrane ◽  
Specific Activities ◽  
Active Zones ◽  
Presynaptic Plasma Membrane

During transmitter release, synaptic vesicle membrane is specifically inserted into the nerve terminal plasma membrane only at specialized sites or "active zones." In an attempt to obtain a membrane fraction enriched in active zones, we have utilized the electric organ of the marine ray. From this organ, a fraction enriched in nerve terminals (synaptosomes) was prepared by conventional means. These synaptosomes were bound to microscopic beads by an antiserum to purified electric organ synaptic vesicles (anti-SV). The success of this immunoadsorption procedure was demonstrated by increased specific activities of bead-bound nerve terminal cytoplasmic markers and decreased specific activities of markers for contaminating membranes. To obtain a presynaptic plasma membrane (PSPM) fraction, we lysed the bead-bound synaptosomes by hypoosmotic shock and sonication, resulting in complete release of cytoplasmic markers. When the synaptosomal fraction was surface-labeled with iodine before immunoadsorption, 10% of this label remained bead-bound after lysis, compared with 2% of the total protein, indicating an approximately fivefold enrichment of bead-bound plasma membrane. Concomitantly, the specific activity of bead-bound anti-SV increased approximately 30-fold, indicating an enrichment of plasma membrane which contained inserted synaptic vesicle components. This PSPM preparation is not simply synaptic vesicle membrane since two-dimensional electrophoresis revealed that the polypeptides of the surface-iodinated PSPM preparation include both vesicle and numerous nonvesicle components. Secondly, antiserum to the PSPM fraction is markedly different from anti-SV and binds to external, nonvesicle, nerve terminal components.

scholarly journals Endocytosis of synaptic vesicle membrane at the frog neuromuscular junction.

1984 ◽  
Vol 98 (2) ◽  
pp. 685-698 ◽  
Author(s):  
T M Miller ◽  
J E Heuser
Keyword(s):  
Plasma Membrane ◽  
Synaptic Vesicle ◽  
Thin Section ◽  
Nerve Terminal ◽  
Motor Nerve ◽  
Freeze Fracture ◽  
Frog Neuromuscular Junction ◽  
Vesicle Membrane ◽  
Coated Pits ◽  
Active Zones

Frog nerve-muscle preparations were quick-frozen at various times after a single electrical stimulus in the presence of 4-aminopyridine (4-AP), after which motor nerve terminals were visualized by freeze-fracture. Previous studies have shown that such stimulation causes prompt discharge of 3,000-6,000 synaptic vesicles from each nerve terminal and, as a result, adds a large amount of synaptic vesicle membrane to its plasmalemma. In the current experiments, we sought to visualize the endocytic retrieval of this vesicle membrane back into the terminal, during the interval between 1 s and 2 min after stimulation. Two distinct types of endocytosis were observed. The first appeared to be rapid and nonselective. Within the first few seconds after stimulation, relatively large vacuoles (approximately 0.1 micron) pinched off from the plasma membrane, both near to and far away from the active zones. Previous thin-section studies have shown that such vacuoles are not coated with clathrin at any stage during their formation. The second endocytic process was slower and appeared to be selective, because it internalized large intramembrane particles. This process was manifest first by the formation of relatively small (approximately 0.05 micron) indentations in the plasma membrane, which occurred everywhere except at the active zones. These indentations first appeared at 1 s, reached a peak abundance of 5.5/micron2 by 30 s after the stimulus, and disappeared almost completely by 90 s. Previous thin-section studies indicate that these indentations correspond to clathrin-coated pits. Their total abundance is comparable with the number of vesicles that were discharged initially. These endocytic structures could be classified into four intermediate forms, whose relative abundance over time suggests that, at this type of nerve terminal, endocytosis of coated vesicles has the following characteristics: (a) the single endocytotic event is short lived relative to the time scale of two minutes; (b) earlier forms last longer than later forms; and (c) a single event spends a smaller portion of its lifetime in the flat configuration soon after the stimulus than it does later on.

Neurotransmitter Release

2017 ◽  
Author(s):  
Peggy Mason
Keyword(s):  
Plasma Membrane ◽  
Synaptic Vesicle ◽  
Active Zone ◽  
Neurotransmitter Release ◽  
Synaptic Vesicles ◽  
Synaptic Cleft ◽  
Fusion Pore ◽  
Synaptic Membrane ◽  
Specialized Region ◽  
Synaptic Vesicle Fusion

The biochemical and physiological processes of neurotransmitter release from an active zone, a specialized region of synaptic membrane, are examined. Synaptic vesicles containing neurotransmitters are docked at the active zone and then primed for release by SNARE complexes that bring them into extreme proximity to the plasma membrane. Entry of calcium ions through voltage-gated calcium channels triggers synaptic vesicle fusion with the synaptic terminal membrane and the consequent diffusion of neurotransmitter into the synaptic cleft. Release results when the fusion pore bridging the synaptic vesicle and plasma membrane widens and neurotransmitter from the inside of the synaptic vesicle diffuses into the synaptic cleft. Membrane from the active zone membrane is endocytosed, and synaptic vesicle proteins are then reassembled into recycled synaptic vesicles, allowing for more rounds of neurotransmitter release.

scholarly journals The CHD Protein, Kismet, is Important for the Recycling of Synaptic Vesicles during Endocytosis

2019 ◽  
Vol 9 (1) ◽  
Author(s):  
Nina K. Latcheva ◽  
Taylor L. Delaney ◽  
Jennifer M. Viveiros ◽  
Rachel A. Smith ◽  
Kelsey M. Bernard ◽  
...  
Keyword(s):  
Synaptic Vesicle ◽  
Chromatin Remodeling ◽  
Neurodevelopmental Disorders ◽  
Synaptic Vesicles ◽  
Synaptic Function ◽  
Synaptic Proteins ◽  
Critical Feature ◽  
Synaptic Localization ◽  
Transcription Start Sites ◽  
Mature Neurons

AbstractChromatin remodeling proteins of the chromodomain DNA-binding protein family, CHD7 and CHD8, mediate early neurodevelopmental events including neural migration and differentiation. As such, mutations in either protein can lead to neurodevelopmental disorders. How chromatin remodeling proteins influence the activity of mature synapses, however, is relatively unexplored. A critical feature of mature neurons is well-regulated endocytosis, which is vital for synaptic function to recycle membrane and synaptic proteins enabling the continued release of synaptic vesicles. Here we show that Kismet, the Drosophila homolog of CHD7 and CHD8, regulates endocytosis. Kismet positively influenced transcript levels and bound to dap160 and endophilin B transcription start sites and promoters in whole nervous systems and influenced the synaptic localization of Dynamin/Shibire. In addition, kismet mutants exhibit reduced VGLUT, a synaptic vesicle marker, at stimulated but not resting synapses and reduced levels of synaptic Rab11. Endocytosis is restored at kismet mutant synapses by pharmacologically inhibiting the function of histone deacetyltransferases (HDACs). These data suggest that HDAC activity may oppose Kismet to promote synaptic vesicle endocytosis. A deeper understanding of how CHD proteins regulate the function of mature neurons will help better understand neurodevelopmental disorders.

Dynamin Mediates Membrane Vesiculation

1998 ◽  
Vol 4 (S2) ◽  
pp. 1022-1023
Author(s):  
Sharon M. Sweitzer ◽  
Jenny E. Hinshaw
Keyword(s):  
Drosophila Melanogaster ◽  
Plasma Membrane ◽  
Synaptic Vesicle ◽  
Mechanism Of Action ◽  
Synaptic Vesicles ◽  
Dominant Negative ◽  
Coated Pits ◽  
Vesicle Recycling ◽  
Membrane Vesiculation ◽  
Helical Tubes

Dynamin, a 100 kDa GTPase, is essential for receptor mediated endocytosis and synaptic vesicle recycling; however its mechanism of action is unknown. The requirement for dynamin was first elucidated by the discovery that the shibire gene product in Drosophila melanogaster was homologous to mammalian dynamin-1 (1,2). The shibire flies exhibit a depletion of synaptic vesicles and an accumulation of collared clathrin-coated pits at the plasma membrane of their nerve termini (3). It was later demonstrated that endocytosis was inhibited by the overexpression of dominant negative mutants of dynamin (4,5), and that purified dynamin can self-associate to form spirals which resemble the collars of shibire and structures seen in synaptosomes treated with GTPγS (6,7). These observations led to the speculation that dynamin pinches the clathrin-coated bud from the plasma membrane. In support of this hypothesis, we show that purified recombinant dynamin can bind to a lipid bilayer in a regular and repeating pattern to form helical tubes which vesiculate upon the addition of GTP.

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 A new life for an old pump: V-ATPase and neurotransmitter release

2014 ◽  
Vol 205 (1) ◽  
pp. 7-9 ◽  
Author(s):  
Stefano Vavassori ◽  
Andreas Mayer
Keyword(s):  
Plasma Membrane ◽  
Complex Formation ◽  
Membrane Fusion ◽  
Synaptic Vesicle ◽  
Neurotransmitter Release ◽  
Synaptic Vesicles ◽  
Snare Complex ◽  
Spontaneous Release ◽  
Synaptic Vesicle Fusion ◽  
Snare Complex Formation

Neurons fire by releasing neurotransmitters via fusion of synaptic vesicles with the plasma membrane. Fusion can be evoked by an incoming signal from a preceding neuron or can occur spontaneously. Synaptic vesicle fusion requires the formation of trans complexes between SNAREs as well as Ca2+ ions. Wang et al. (2014. J. Cell Biol. http://dx.doi.org/jcb.201312109) now find that the Ca2+-binding protein Calmodulin promotes spontaneous release and SNARE complex formation via its interaction with the V0 sector of the V-ATPase.

scholarly journals Structural changes after transmitter release at the frog neuromuscular junction.

1981 ◽  
Vol 88 (3) ◽  
pp. 564-580 ◽  
Author(s):  
J E Heuser ◽  
T S Reese
Keyword(s):  
Plasma Membrane ◽  
Synaptic Vesicle ◽  
Structural Changes ◽  
Frog Neuromuscular Junction ◽  
Vesicle Membrane ◽  
Intramembrane Particles ◽  
Synaptic Vesicle Exocytosis ◽  
Quick Freezing ◽  
Vesicle Exocytosis ◽  
Active Zones

The sequence of structural changes that occur during synaptic vesicle exocytosis was studied by quick-freezing muscles at different intervals after stimulating their nerves, in the presence of 4-aminopyridine to increase the number of transmitter quanta released by each stimulus. Vesicle openings began to appear at the active zones of the intramuscular nerves within 3-4 ms after a single stimulus. The concentration of these openings peaked at 5-6 ms, and then declined to zero 50-100 ms late. At the later times, vesicle openings tended to be larger. Left behind at the active zones, after the vesicle openings disappeared, were clusters of large intramembrane particles. The larger particles in these clusters were the same size as intramembrane particles in undischarged vesicles, and were slightly larger than the particles which form the rows delineating active zones. Because previous tracer work had shown that new vesicles do not pinch off from the plasma membrane at these early times, we concluded that the particle clusters originate from membranes of discharged vesicles which collapse into the plasmalemma after exocytosis. The rate of vesicle collapse appeared to be variable because different stages occurred simultaneously at most times after stimulation; this asynchrony was taken to indicate that the collapse of each exocytotic vesicle is slowed by previous nearby collapses. The ultimate fate of synaptic vesicle membrane after collapse appeared to be coalescence with the plasma membrane, as the clusters of particles gradually dispersed into surrounding areas during the first second after a stimulus. The membrane retrieval and recycling that reverse this exocytotic sequence have a slower onset, as has been described in previous reports.

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.

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