Rapid structural change in synaptosomal-associated protein 25 (SNAP25) precedes the fusion of single vesicles with the plasma membrane in live chromaffin cells

Zhao, Ying; Fang, Qinghua; Herbst, Adam Drew; Berberian, Khajak; Almers, Wolfhard; Lindau, Manfred

doi:10.1073/pnas.1306699110

Cited by 44 publications

(68 citation statements)

References 23 publications

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“…These experiments revealed a rapid conformational change in SNAP-25 that occurred specifically at the sites of fusion events and preceded fusion pore formation by ϳ90 ms (70). This FRET change may result from the formation of trans SNARE complexes that form after cross-linking the vesicle and plasma membranes via the synaptotagmin C2B domain, as recently proposed (22,63).…”

Section: The Mechanism By Which the Force Transfer Leads To Fusion Posupporting

confidence: 52%

How Could SNARE Proteins Open a Fusion Pore?

Fang

Lindau

2014

Physiology

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The SNARE (Soluble NSF Attachment protein REceptor) complex, which in mammalian neurosecretory cells is composed of the proteins synaptobrevin 2 (also called VAMP2), syntaxin, and SNAP-25, plays a key role in vesicle fusion.In this review, we discuss the hypothesis that, in neurosecretory cells, fusion pore formation is directly accomplished by a conformational change in the SNARE complex via movement of the transmembrane domains.Qinghua Fang 1,2 and Manfred Lindau (49) has three components. The v-SNARE synaptobrevin 2 (syb2 also called VAMP2) is a 116-amino acid protein anchored in the vesicle membrane by a single transmembrane (TM) domain. Syntaxin (stx) is correspondingly anchored in the plasma membrane via a single TM helix. The third component, SNAP-25, has lipid anchors in the plasma membrane. SNAP-25 and stx are called t-SNAREs, being in the target membrane for fusion of secretory vesicles. The key importance of these proteins in the fusion mechanism has been demonstrated by the finding that proteolytic cleavage of the SNARE proteins by specific neurotoxins results in strong inhibition of transmitter release in neurons as well as in chromaffin cells (42,44). One example for the medical relevance of the SNARE complex is the BoTox treatment, which exerts its function through inhibition of transmitter release by specific cleavage of the SNARE protein SNAP-25. The cytosolic so-called SNARE domains of these three proteins form a coiled coil, which incorporates one helix each from syb2 and stx and two helices (named SN1 and SN2) from SNAP-25. The coiled coil structure of the SNARE domains has been solved by X-ray crystallography several years ago (57). Based on this structure, the configuration shown in FIGURE 1A was proposed for a trans configuration, in which a SNARE complex links the vesicle membrane and plasma membrane. The arrows indicate the cleavage sites for the neurotoxins mentioned above. More recently, a crystal structure of the SNARE complex, including the syb2 and stx TM helices, was solved (56), which shows helical extension from the SNARE domains through the linkers into the TM domains (FIGURE 1B). This structure is thought to resemble a post-fusion state in which all components of the SNARE complex are in a cis configuration, located in the same fused membrane.Synaptic vesicles contain ϳ70 copies of syb2 (59), but it is unknown and controversial how many of these copies are acting together in the formation of a fusion pore (43). Interestingly, neurosecretory vesicles in PC 12 cells recruit t-SNARE clusters containing a similar number of stx and SNAP-25 molecules (26). It has been shown that in reconstituted systems a single SNARE complex is sufficient to promote lipid vesicle fusion (50, 62). However, at least three SNARE complexes appear to be required for fast membrane fusion kinetics (8,17,41,50). In cultured hippocampal neurons, two copies of syb2 were found to be sufficient for fusion, but the experiments were performed with low time resolution (52). The Triggering MechanismTransmitter rel...

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Section: The Mechanism By Which the Force Transfer Leads To Fusion Posupporting

confidence: 52%

How Could SNARE Proteins Open a Fusion Pore?

Fang

Lindau

2014

Physiology

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“…Especially, the temporal interplay between myosin II, dynamin, PtdIns(4,5)P 2 and Arp2/3 seems a logical target for an in-depth analysis. High sensitivity FRET and correlation measurements (Zhao et al, 2013) exocytosis by controlling fusion profiles through plasma membrane tension (Wen et al, 2016).…”

Section: Future Directionsmentioning

confidence: 99%

Membrane shaping by actin and myosin during regulated exocytosis

Papadopulos

2017

Molecular and Cellular Neuroscience

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The cortical actin network in neurosecretory cells is a dense mesh of actin filaments underlying the plasma membrane. Interaction of actomyosin with vesicular membranes or the plasma membrane is vital for tethering, retention, transport as well as fusion and fission of exo-and endocytic membrane structures. During regulated exocytosis the cortical actin network undergoes dramatic changes in morphology to accommodate vesicle docking, fusion and replenishment. Most of these processes involve plasma membrane Phosphoinositides (PIP) and investigating the interactions between the actin cortex and secretory structures has become a hotbed for research in recent years. Actin remodelling leads to filopodia outgrowth and the creation of new fusion sites in neurosecretory cells and actin, myosin and dynamin actively shape and maintain the fusion pore of secretory vesicles. Changes in viscoelastic properties of the actin cortex can facilitate vesicular transport and lead to docking and priming of vesicle at the plasma membrane. Small GTPase actin mediators control the state of the cortical actin network and influence vesicular access to their docking and fusion sites. These changes potentially affect membrane properties such as tension and fluidity as well as the mobility of embedded proteins and could influence the processes leading to both exo-and endocytosis. Here we discuss the multitudes of actin and membrane interactions that control successive steps underpinning regulated exocytosis.

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“…0.5 µm 2 . 43) In chromaffin cells, the conformational changes in SNAP25 during exocytosis were examined with the combined use of a FRET probe of SNAP25 (SNARE complex reporter), 42,44) TIRF microscopy, and amperometry. The average FRET signal from 900 fusion events was reported to precede the opening of the fusion pore by 90 ms, and ca.…”

Section: Mode Of Exocytosismentioning

confidence: 99%

“…7% of the FRET probe molecules were estimated to be involved in the transient FRET increase within the area of the exocytic site (0.1 µm 2 ). 44) Because two-photon microscopy utilizes an ultra-short pulse laser, it is also suited for fluorescence lifetime imaging, 45) which enables the quantification of intermolecular as well as intramolecular FRET. Combined with simultaneous multicolor imaging, the molecular mechanisms of exocytosis are expected to be elucidated in living tissues.…”

Section: Mode Of Exocytosismentioning

confidence: 99%

Imaging Analysis of Insulin Secretion with Two-Photon Microscopy

Takahashi

2015

Biological & Pharmaceutical Bulletin

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High-resolution deep tissue imaging is possible with two-photon excitation microscopy. With the combined application of two-photon imaging and perfusion with a polar fluorescent tracer, we have established a method to detect exocytic events inside secretory tissues. This method displays the spatiotemporal distribution of exocytic sites, dynamics of fusion pores, and modes of exocytosis. In glucose-stimulated pancreatic islets, exocytic events were observed to be synchronized with an increase in cytosolic Ca 2 concentrations. Full fusion of a single secretory granule is the typical mode of exocytosis and compound exocytosis is inhibited. Because two-photon excitation enables simultaneous multicolor imaging due to the broadened excitation spectra, the distributions and conformational changes in fluorescent-labeled molecules can be simultaneously visualized with exocytic events. Therefore, we can analyze the dynamics of the molecules involved in membrane fusion and their association with exocytosis in living tissues.

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Rapid structural change in synaptosomal-associated protein 25 (SNAP25) precedes the fusion of single vesicles with the plasma membrane in live chromaffin cells

Cited by 44 publications

References 23 publications

How Could SNARE Proteins Open a Fusion Pore?

How Could SNARE Proteins Open a Fusion Pore?

Membrane shaping by actin and myosin during regulated exocytosis

Imaging Analysis of Insulin Secretion with Two-Photon Microscopy

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