Enlightening molecular mechanisms through study of protein interactions (original) (raw)
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Binding of the Munc13-1 MUN Domain to Membrane-Anchored SNARE Complexes †
Biochemistry, 2008
The core of the membrane fusion machinery that governs neurotransmitter release includes the SNARE proteins syntaxin-1, SNAP-25 and synaptobrevin, which form a tight "SNARE complex", and Munc18-1, which binds to the SNARE complex and to syntaxin-1 folded into a closed conformation. Release is also controlled by specialized proteins such as complexins, which also bind to the SNARE complex, and unc13/Munc13s, which are crucial for synaptic vesicle priming and were proposed to open syntaxin-1, promoting SNARE complex assembly. However, the biochemical basis for unc13/Munc13 function and its relationship to other SNARE interactions are unclear. To address this question, we have analyzed interactions of the MUN domain of Munc13-1, which is key for this priming function, using solution binding assays and cofloatation experiments with SNARE-containing proteoliposomes. Our results indicate that the Munc13-1 MUN domain binds to membrane-anchored SNARE complexes, even though binding is barely detectable in solution. The MUN domain appears to compete with Munc18-1 but not with complexin-1 for SNARE complex binding, although more quantitative assays will be required to verify these conclusions. Moreover, our data also uncover interactions of membrane-anchored syntaxin-1/SNAP-25 heterodimers with the MUN domain, Munc18-1 and complexin-1. The interaction with complexin-1 is surprising, as it was not observed in previous solution studies. Our results emphasize the importance of studying interactions within the neurotransmitter release machinery in a native membrane environment, and suggest that unc13/Munc13s may provide a template to assemble syntaxin-1/SNAP-25 heterodimers, leading to an acceptor complex for synaptobrevin.
Neuron, 2013
Synaptic vesicle fusion during neurotransmitter release is mediated by assembly of SNARE-and SM-protein complexes composed of syntaxin-1, SNAP-25, synaptobrevin-2/VAMP2, and Munc18-1. Current models suggest that SNARE-complex assembly catalyzes membrane fusion by pulling the transmembrane regions (TMRs) of SNARE proteins together, thus allowing their TMRs to form a fusion pore. These models are consistent with the requirement for TMRs in viral fusion proteins. However, the role of the SNARE TMRs in synaptic vesicle fusion has not yet been tested physiologically. Here, we examined whether synaptic SNAREs require TMRs for catalysis of synaptic vesicle fusion, which was monitored electrophysiologically at millisecond time resolution. Surprisingly, we find that both lipid-anchored syntaxin-1 and lipid-anchored synaptobrevin-2 lacking TMRs efficiently promoted spontaneous and Ca 2+-triggered membrane fusion. Our data suggest that SNARE proteins function during fusion primarily as force generators, consistent with the notion that forcing lipid membranes close together suffices to induce membrane fusion.
Protein–protein interactions in neurotransmitter release
Neuroscience Research, 2000
The arrival of a nerve impulse at a nerve terminal leads to the opening of voltage-gated Ca 2 + channels and a rapid influx of Ca 2 +. The increase in Ca 2 + concentration at the active zone from the basal level of 100-200 mM triggers the fusion of docked synaptic vesicles, resulting in neurotransmitter release. A large number of proteins have been identified at nerve terminals and a cascade of protein-protein interactions has been suggested to be involved in the cycling of synaptic vesicle states. Functional studies in last half decade on synaptic-terminal proteins, including Ca 2 + channels, have revealed that the SNARE core complex, consisting of synaptobrevin VAMP, a synaptic vesicle-associated protein, syntaxin and SNAP-25, synaptic membrane-associated proteins, acts as the membrane fusion machinery and that proteins interacting with the SNARE complex play essential roles in synaptic vesicle exocytosis by regulating assembly and disassembly of the SNARE complex.
Ultrahigh-resolution imaging reveals formation of neuronal SNARE/Munc18 complexes in situ
Proceedings of the National Academy of Sciences, 2013
Significance Synaptic vesicle fusion is catalyzed by multiprotein complexes that bring two lipid bilayers into close opposition. Several assembly mechanisms have been proposed for the synaptic vesicle fusion machinery, but exactly how these proteins interact in vivo remains unclear. We developed two-color fluorescence nanoscopy to directly visualize molecular interactions in situ and discovered that syntaxin-1, SNAP-25, and Munc18-1 (mammalian uncoordinated-18), three essential components for neurotransmission, closely colocalize on the plasma membrane, suggesting possible pathways for SNARE-mediated membrane fusion. Our superresolution method provides a framework for delineating the molecular underpinnings of the synaptic vesicle fusion machinery.
Proceedings of the National Academy of Sciences, 2012
When nerve cells communicate, vesicles from one neuron fuse with the presynaptic membrane releasing chemicals that signal to the next. Similarly, when insulin binds its receptor on adipocytes or muscle, glucose transporter-4 vesicles fuse with the cell membrane, allowing glucose to be imported. These essential processes require the interaction of SNARE proteins on vesicle and cell membranes, as well as the enigmatic protein Munc18 that binds the SNARE protein Syntaxin. Here, we show that in solution the neuronal protein Syntaxin1a interacts with Munc18-1 whether or not the Syntaxin1a N-peptide is present. Conversely, the adipocyte protein Syntaxin4 does not bind its partner Munc18c unless the N-peptide is present. Solution-scattering data for the Munc18-1:Syntaxin1a complex in the absence of the N-peptide indicates that this complex adopts the inhibitory closed binding mode, exemplified by a crystal structure of the complex. However, when the N-peptide is present, the solution-scattering data indicate both Syntaxin1a and Syntaxin4 adopt extended conformations in complexes with their respective Munc18 partners. The low-resolution solution structure of the open Munc18:Syntaxin binding mode was modeled using data from cross-linking/mass spectrometry, small-angle X-ray scattering, and small-angle neutron scattering with contrast variation, indicating significant differences in Munc18:Syntaxin interactions compared with the closed binding mode. Overall, our results indicate that the neuronal Munc18-1:Syntaxin1a proteins can adopt two alternate and functionally distinct binding modes, closed and open, depending on the presence of the N-peptide, whereas Munc18c:Syntaxin4 adopts only the open binding mode. membrane fusion | protein interactions | small-angle neutron scattering | small-angle X-ray scattering M embrane trafficking is an essential and highly regulated process whereby cargo-carrying vesicles are directed to dock and fuse with specific cell membranes. The process requires soluble N-ethylmaleimide-sensitive factor attachment receptor (SNARE) proteins on vesicle and target membranes. These interact to form high-affinity SNARE complexes required for docking and membrane fusion (1, 2). Structurally, the SNARE complex is a parallel four-helix bundle comprising helices contributed from several partner SNAREs (3). This helical bundle promotes vesicle fusion by bringing the vesicle and plasma membranes into close proximity and by providing the energy required for membrane fusion (4, 5).
Munc18-1 binds directly to the neuronal SNARE complex
Proceedings of the National Academy of Sciences, 2007
Both SM proteins (for Sec1/Munc18-like proteins) and SNARE proteins (for soluble NSF-attachment protein receptors) are essential for intracellular membrane fusion, but the general mechanism of coupling between their functions is unclear, in part because diverse SM protein/SNARE binding modes have been described. During synaptic vesicle exocytosis, the SM protein Munc18-1 is known to bind tightly to the SNARE protein syntaxin-1, but only when syntaxin-1 is in a closed conformation that is incompatible with SNARE complex formation. We now show that Munc18-1 also binds tightly to assembled SNARE complexes containing syntaxin-1. The newly discovered Munc18-1/SNARE complex interaction involves contacts of Munc18-1 with the N-terminal H abc domain of syntaxin-1 and the four-helical bundle of the assembled SNARE complex. Together with earlier studies, our results suggest that binding of Munc18-1 to closed syntaxin-1 is a specialization that evolved to meet the strict regulatory requirements of neuronal exocytosis, whereas binding of Munc18-1 to assembled SNARE complexes reflects a general function of SM proteins involved in executing membrane fusion. exocytosis ͉ membrane fusion ͉ neurotransmitter release ͉ Sec1/Munc18-like proteins ͉ synapse
Journal of Neuroscience, 2007
The SM (Sec1/Munc18-like) protein Munc18-1 and the soluble N-ethylmaleimide-sensitive factor attachment protein (SNAP) receptor (SNARE) proteins syntaxin-1, SNAP-25, and synaptobrevin/VAMP (vesicle-associated membrane protein) constitute the core fusion machinery for synaptic vesicle exocytosis. Strikingly, Munc18-1 interacts with neuronal SNARE proteins in two distinct modes (i.e., with isolated syntaxin-1 alone in a "closed" conformation and with assembled SNARE complexes containing syntaxin-1 in an "open" conformation). However, it is unclear whether the two modes of Munc18/SNARE interactions are linked. We now show that both Munc18/ SNARE interaction modes involve the same low-affinity binding of the extreme syntaxin-1 N terminus to Munc18-1, suggesting that this binding connects the two Munc18/SNARE interaction modes to each other. Using transfected cells as an in vitro assay system, we demonstrate that truncated syntaxins lacking a transmembrane region universally block exocytosis, but only if they contain a free intact N terminus. This block is enhanced by coexpression of either Munc18-1 or SNAP-25, suggesting that truncated syntaxins block exocytosis by forming an untethered inhibitory SNARE complex/Munc18-1 assembly in which the N-terminal syntaxin/Munc18 interaction is essential. Introduction of an N-terminal syntaxin peptide that disrupts this assembly blocks neurotransmitter release in the calyx of Held synapse, whereas a mutant peptide that does not disrupt the SNARE complex/Munc18 assembly has no effect. Viewed together, our data indicate that binding of Munc18 to the syntaxin N terminus unites different modes of Munc18/SNARE interactions and is essential for exocytic membrane fusion.
Neuron, 2014
SNARE-complex assembly mediates synaptic vesicle fusion during neurotransmitter release and requires that the target-SNARE protein syntaxin-1 switches from a closed to an open conformation. Although many SNARE proteins are available per vesicle, only one to three SNARE complexes are minimally needed for a fusion reaction. Here, we use high-resolution measurements of synaptic transmission in the calyx-of-Held synapse from mutant mice in which syntaxin-1 is rendered constitutively open and SNARE-complex assembly is enhanced to examine the relation between SNARE-complex assembly and neurotransmitter release. We show that enhancing SNARE-complex assembly dramatically increases the speed of evoked release, potentiates the Ca 2+-affinity of release, and accelerates fusion-pore expansion during individual vesicle fusion events. Our data indicate that the number of assembled SNARE complexes per vesicle during fusion determines the presynaptic release probability and fusion kinetics and suggest a mechanism whereby proteins (Munc13 or RIM) may control presynaptic plasticity by regulating SNARE-complex assembly. Neuron SNAREs Control Ca 2+ Affinity of Release