Rat Syt1 cytoplasmic domain (residues 140–421, known as C2AB), C2A domain (residues 140–266), C2B domain (residues 270–421) and its mutants C2B_2RQ (residues 270–421, R398Q and R399Q), C2b (residues 270–421, D363N and D365N), full-length rat Munc18-1, full-length synaptobrevin-2 and its cytoplasmic domain (residues 29–93), rat syntaxin-1a cytoplasmic domain (residues 2–253) and its SNARE domain (H3, residues 191–253), rat Munc13-1 MUN domain (also known as MUN⁹³³, residues 933–1407, EF, 1453–1531), full-length Cricetulus griseus NSF and full-length Bos taurus α-SNAP were cloned into pGEX-KG vector. Full-length human SNAP-25a (with its four native cysteines mutated to serines), its C-terminal truncation SNAP-25a Δ9 (residues 1–197, with its four native cysteines mutated to serines) and full-length rat syntaxin-1a were cloned into pET28a vector (Novagen). The co-expressed full-length rat Munc18-1 and full-length rat syntaxin-1a, full-length rat Munc18-1 and rat syntaxin-1a cytoplasmic domain (residues 1–261) were cloned to pETDuet-1 vector (Novagen). Rat Munc13-1 C₁-C₂B-MUN fragment (residues 529–1407, EF, 1453–1531) was cloned into pFastBac™HtB vector (Invitrogen). All of the mutants used in this study were generated by using QuikChange Site-Directed Mutagenesis Kit (Stratagene).

Rat Munc13-1 C₁-C₂B-MUN fragment was expressed in Sf9 insect cells as previous described (Ma et al., 2013). All other proteins were expressed in E. coli BL21 DE3 by culturing the cells to 0.6–0.8 O.D.₆₀₀ at 37°C, then induced with 0.4 mM isopropyl-β-D-thiogalactoside (IPTG, Amresco) for 16–20 h at 20°C. Cultured cells were harvested by centrifuging at 4200 rpm in a J6-MI centrifuge equipped with JS-4.2 rotor (Beckman Coulter) at 4°C.

For GST-tagged proteins, cell pellets from 1 L of culture were resuspended with 50 mM Na₂HPO₄-NaH₂PO₄ pH 7.6, 300 mM NaCl, 10% (v/v) glycerol, 0.5% Triton X-100 (Sigma; lysis buffer A) supplied with 1 mM phenylmethanesulfonyl fluoride (PMSF, Amresco) and 5 mM 2-mercaptoethanol (2-ME, Amresco). Cells were broken using an AH-1500 Nano Homogenize Machine (ATS Engineering Inc.) at 1200 bar for three times at 4°C. Cell lysates were centrifuged at 16,000 rpm in a JA-25.50 rotor (Beckman Coulter) at 4°C. The supernatants were collected and mixed with 1 ml glutathione Sepharose 4B (GE Healthcare) affinity media. After 2 h rotation at 4°C, the mixture were washed twice with lysis buffer A supplied with 2 mM 2-ME. For purification of GST-syntaxin-1a H3 domain, GST-Munc18-1 and GST-MUN, proteins were eluted by a buffer containing 50 mM Tris-Cl, 300 mM NaCl, 10% (v/v) glycerol and 20 mM L-glutathione (GSH, Amresco), pH 8.0. Eluted proteins were desalted by PD-10 desalting column (GE Healthcare) using a buffer containing 25 mM HEPES-KOH, 150 mM KCl and 10% (v/v) glycerol, pH 7.6 (buffer H) supplied with 0.2 mM tris(2-carboxyethyl)phosphine (TCEP, Sigma). For purification tag-free proteins, GST-tag were removed by mixing 10 U/ml of thrombin (from bovine pancreatic) into the media in buffer H supplied with 0.2 mM TCEP at 4°C overnight. Eluted proteins were further purified by ion exchange chromatography (Source 15S/15Q, GE Healthcare) followed by size-exclusion chromatography (Superdex 75 pg/200 pg, GE Healthcare). For hexa-histidine tagged proteins, cell pellets from 1 L of culture were resuspended with 50 mM Tris-Cl pH 8.0, 300 mM NaCl, 10% (v/v) glycerol, 0.5% Triton X-100 (Sigma; lysis buffer B) supplied with 1 mM PMSF and 2 mM 2-ME. Cells were broken using an AH-1500 Nano Homogenize Machine (ATS Engineering Inc.) at 1200 bar for three times at 4°C. Cell lysates were centrifuged at 16,000 rpm in a JA-25.50 rotor (Beckman Coulter) at 4°C. The supernatants were collected and mixed with 1 ml Nickel-NTA agarose (Qiagen) affinity media. After 2 h rotation at 4°C, the mixture were washed twice with lysis buffer B supplied with 1 mM 2-ME and 30 mM imidazole followed by an additional wash step with Triton X-100-free lysis buffer B supplied with 1 mM 2-ME and 30 mM imidazole. Proteins were eluted with a buffer containing 20 mM Tris-Cl pH 8.0, 150 mM NaCl, 10% (v/v) glycerol (buffer T) supplied with 300 mM imidazole and 0.2 mM TCEP. For full-length syntaxin-1a and co-expressed full-length Munc18-1/syntaxin-1, proteins were eluted with buffer T supplied with 300 mM imidazole, 0.2 mM TCEP and 1% (w/v) sodium cholate (Aladdin, Shanghai, China). Eluted proteins were desalted by using PD-10 desalting column (GE Healthcare) and further purified by ion exchange chromatography (Source 15Q, GE Healthcare) followed by size-exclusion chromatography (Superdex 75 pg/200 pg, GE Healthcare).

Purification buffers for proteins with transmembrane domain were supplied with 1% (w/v) n-octyl-β-D-glucoside (β-OG, Amresco; for full-length synaptobrevin-2) or 1% (w/v) sodium cholate (Aladdin, Shanghai, China; for full-length syntaxin-1a and co-expressed full-length Munc18-1/syntaxin-1). Protein purities were checked using SDS-PAGE (>95%) and final concentrations were determined by A₂₈₀ on a P330 NanoPhotometer (Implen).

BODIPY FL [N-(2-aminoethyl)maleimide] (BDPY, Molecular Probes) and tetramethylrhodamine-5-maleimide, single isomer (TMR, Molecular Probes) were used as fluorescence resonance energy transfer (FRET) donor and acceptor in this study. Dye-protein conjugation was achieved by maleimide-cysteine conjugation (all cysteine mutants for dye conjugation were described in the figure). Powdered dyes were dissolved by using dimethylsulfoxide (DMSO, Sigma; for BDPY) or dimethyl formamide (DMF, Aladdin, Shanghai, China; for TMR) to a concentration of 40 mM and stored at −20°C. Purified proteins were dialyzed with buffer H containing 0.2 mM TCEP and 0.2 mM EDTA and diluted to a concentration of 20–40 μM. Dyes were gently added to the protein solutions with a protein-to-dye ratio of 1:5. Dye-protein mixtures were gently rotated overnight at 4°C in the dark room. Excess dyes were bleached by adding 10 mM dithiothreitol (DTT, Amresco) and removed by using PD-10 desalting column (GE Healthcare). Labeling/conjugation efficiency was calculated by: (1)E=AD∗εpεD∗(A280−AD∗C280)∗100%

where A_D is the peak absorbance of the dye; A₂₈₀ is the absorbance of the dye-protein compound at 280 nm; ε_p is the extinction coefficient of the protein at 280 nm; ε_D is the extinction coefficient of the dye at the absorption maximum; C₂₈₀ is the so called dye correction factor since some dyes display an absorbance at 280 nm. The C₂₈₀ is given as: (2)C280=εD280/εD

where ε_D280 is the extinction coefficient of the dye at 280 nm. About 90% of the labeling efficiency was reached for each samples.

Purified GST-syntaxin-1a H3 domain (residues 191–253) was incubated with purified SNAP-25a and the cytoplasmic domain of synaptobrevin-2 (residues 29–93) at 4°C overnight. The sample was analyzed by SDS-PAGE to confirm the SNARE complex formation. For GST pull-down assay, 20 μl 50% (v/v) glutathione Sepharose 4B affinity media (GE Healthcare) was mixed with 5 μM GST-SNARE complex, 5 μM GST-Munc18-1, 5 μM GST-Munc13-1 MUN domain (residues 933–1407, EF, 1453–1531), 5 μM GST, respectively and 10 μM Syt1 C2B domain to a final volume of 50 μl. The samples were gently rotated for 2 h at 4°C followed by washing with buffer H three times. Finally, the samples were analyzed by SDS-PAGE followed by coomassie brilliant blue staining and immunoblotting (anti-Syt1, rabbit polyclonal, Proteintech, Wuhan, China). All of the experiments were performed in the absence of Ca²⁺.

1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC), 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine (POPE), 1,2-dioleoyl-sn-glycero-3-phospho-L-serine (sodium salt; DOPS), L-α-phosphatidylinositol-4,5-bisphosphate (Brain, Porcine; ammonium salt; PI[4,5]P2), cholesterol (ovine wool; Chol) and 1-2-dioleoyl-sn-glycerol (DAG) were all obtained from Avanti Polar Lipids. T-liposome reconstituted with Munc18-1/syntaxin-1 and t’-liposome containing syntaxin-1/SNAP-25 Δ9 comprises 37% POPC, 20% POPE, 20% DOPS, 2% DAG, 1% PI(4,5)P2 and 20% Chol and v-liposome reconstituted with BDPY-labeled synaptobrevin-2 comprises 45% POPC, 20% POPE, 15% DOPS and 20% Chol, which are demonstrated in the schematic diagrams in each figures. Lipid mixtures in glass tubes were dried under nitrogen gas flow in water bath at 40°C followed by vacuuming in a vacuum desiccator for 3 h. Lipid films were dissolved in buffer H containing 0.2 mM TCEP and 1% (w/v) sodium cholate. After vortexing for 5 min, purified proteins (i.e., full-length syntaxin-1a, full-length Munc18-1/syntaxin-1 or BDPY-labeled full-length synaptobrevin-2) were added into the mixture to a protein-to-lipid ratio of 1:200. An additional round of vortex were performed to mix the proteins and lipid mixture. The proteoliposomes were formed by desalting the protein-lipid mixtures with PD-10 desalting column (GE Healthcare) in buffer H containing 0.2 mM TCEP. To remove any residual detergents and contaminants, a routine dialysis step was performed with buffer H containing 0.2 mM TCEP, 0.2 mM EDTA and 0.5 g/L Bio-beads SM2 (Bio-Rad).

All of the FRET assays in this study were carried out on a PTI QM-40 spectrophotometer with excitation and emission wavelength of 485 nm and 513 nm, respectively at 37°C.

For Syt1 stimulating ternary SNARE complex formation with and without Munc18-1 and Munc13-1 in membrane-free system (Figure 1 and Supplementary Figure S1), 5μM syntaxin-1a cytoplasmic domain (residues 2–253) were mixed with 5 μM TMR-labeled SNAP-25a (S187C), 1 μM BDPY-labeled synaptobrevin-2 cytoplasmic domain (residues 29–93, S61C) and 2 μM Syt1 fragment. Alternatively, pre-assembled syntaxin-1a cytoplasmic domain (residues 2–253) and TMR-labeled SNAP-25a (S187C) were added to 5 μM as well. Five micromolar co-expressed transmembrane-free Munc18-1/syntaxin-1 (residues 1–261) were mixed with 5 μM TMR-labeled SNAP-25a (S187C), 1 μM BDPY-labeled synaptobrevin-2 cytoplasmic domain (residues 29–93, S61C), 30 μM Munc13-1 MUN domain (residues 933–1407, EF, 1453–1531) and 2 μM Syt1 fragment. CaCl₂ were added, if indicated, at a final concentration of 1 mM.

For Syt1 stimulating ternary SNARE complex formation with Munc18-1 and Munc13-1 in the presence of membranes (Figures 2, 3), general procedures are the same to those in membrane-free system. Particularly, Munc13-1 MUN domain was replaced by Munc13-1 C₁-C₂B-MUN fragment (0.5 μM) and the amount of Syt1 fragments were reduced to 0.5 μM due to the recruiting effect of PI(4,5)P2 on t-liposomes. For trans SNARE complex formation, TMR labeled SNAP-25a Δ9 (residues 1–197, S187C) was applied. 0.4 μM full-length NSF, 1 μM α-SNAP, 2 mM ATP-2Na⁺ (Sangon, Shanghai, China) and 2 mM MgCl₂ were incorporated as indicated. 0.2 mM EDTA was present all the time to chelate residual Ca²⁺ in the reaction buffer.

Prism 6.01 (GraphPad) was used to graph and perform non-linear curve fits.

As introduced above, synaptic vesicle priming is generally believed to involve ternary SNARE complex formation. However, the action of Syt1 in ternary SNARE complex formation has been unclear. To this aim, we first examined whether the cytoplasmic fragment of Syt1 (referred to as C2AB) stimulates formation of the ternary SNARE complex in solution. Fluorescence donor and acceptor were separately labeled to synaptobrevin-2 (residues 29–93, S61C) and SNAP-25 (S187C), respectively, and ternary SNARE complex formation was measured by a decrease of donor fluorescence based on FRET (Figure 1A). Addition of C2AB did not influence formation of the ternary SNARE complex in the absence and presence of Ca²⁺ (Figures 1A,C). Similarly, C2AB did not affect formation of synaptobrevin-2 with preassembled syntaxin-1/SNAP-25 heterodimers in the absence and presence of Ca²⁺ (Figures 1B,C). These results are consistent with previous observations (Stein et al., 2007; Chicka et al., 2008), suggesting that Syt1 has no obvious effect on ternary SNARE complex formation when beginning merely with the three SNAREs.

In a physiological context, SNARE complex formation is highly regulated by Munc18-1 and Munc13-1, the two key factors required for synaptic vesicle priming (Augustin et al., 1999; Südhof and Rothman, 2009). We therefore explored whether Syt1 stimulates ternary SNARE complex formation in the presence of Munc18-1 and Munc13-1 using the FRET assay. As observed in our previous studies (Ma et al., 2011, 2013; Yang et al., 2015), the MUN domain, which contains the minimal priming activity of Munc13-1 (Basu et al., 2005), catalyzed the transition from the Munc18-1/syntaxin-1 complex to the ternary SNARE complex (Figures 1D,F). Intriguingly, further addition of C2AB strongly enhanced this transition in a Ca²⁺-independent manner (Figures 1D,F and Supplementary Figure S1), whereas this enhancement was not observed when the MUN domain was absent (Figures 1D,F). These results indicate that Syt1 stimulates ternary SNARE complex formation in a Munc18/Munc13-dependent manner.

We further identified the minimal requirement of Syt1 for its stimulation activity. We found that the C2B domain was sufficient for the stimulation, whereas the C2A domain was not (Figures 1D,F). These results suggest that the C2B domain mediates the stimulation activity of Syt1 in ternary SNARE complex formation dependent on Munc18-1 and Munc13-1.

Structurally, the C2B domain comprises several conserved basic residues at the “bottom” (the R398 R399 region) and at the “side” (a poly-basic stretch, referred to as the K326 K327 region; Figure 1A). Abundant positive charges contributed by these two basic regions endow the C2B domain with the ability to bind acidic SNARE complexes and acidic phospholipids, which helps to couple the functions of Syt1 and the SNAREs in synaptic exocytosis (Mohrmann et al., 2013; Brewer et al., 2015; Zhou et al., 2015; Wang et al., 2016). The K326 K327 region was implicated in recruitment of Syt1 onto the PI(4,5)P2-enriched plasma membrane (van den Bogaart et al., 2011; Park et al., 2015), whereas the R398 R399 region has been recently found to interact with the SNAREs and the SNARE complex (Zhou et al., 2015; Wang et al., 2016).

Therefore, we asked whether disruption of the R398 R399 region that is supposed to impair the SNARE binding affects the stimulation activity of the C2B domain. Indeed, mutation of the R398 R399 region of the C2B domain (R398Q/R399Q, referred to as C2B_2RQ) impeded the stimulation activity of the C2B domain in MUN-catalyzed transition from the Munc18-1/syntaxin-1 complex to the ternary SNARE complex (Figures 1E,F). In contrast, mutation of the Ca²⁺-binding sites of the C2B domain (D363N/D365N, referred to as C2b) had no such effect (Figures 1E,F). These results suggest that the C2B/SNARE interaction is important for the stimulation function of Syt1 in ternary SNARE complex formation dependent on Munc18-1 and Munc13-1.

On the other hand, we also tested the interactions of the C2B domain with the MUN domain and/or Munc18-1 for its stimulation activity. However, no detectable binding between the C2B domain and the MUN domain or Munc18-1 can be observed using GST pull-down assay in solution (Supplementary Figure S2). Despite that, considering that the stimulation effect of the C2B domain on ternary SNARE complex formation strictly requires both Munc18-1 and Munc13-1 (Figure 1D), there might have weak and cooperative interactions among the C2B domain, Munc18-1 and Munc13-1, which orchestrate the C2B/SNARE interaction. Therefore, we expected that, in the presence of membranes, the interactions among the above proteins would be increased due to the protein-recruitment function of several lipid molecules (e.g., PI(4,5)P2 and PS; Martin, 2015; Pinheiro et al., 2016), resulting in enhanced stimulation activity of Syt1 in SNARE complex formation.

We next explored the stimulation activity of Syt1 in the transition from the Munc18-1/syntaxin-1 complex to the ternary SNARE complex in a membrane-containing environment. To this goal, we developed a membrane-based FRET assay in which the Munc18-1/syntaxin-1 complex was reconstituted into liposomes (referred to as t-liposomes), whereas synaptobrevin-2 was present either in solution (using the cytoplasmic domain of synaptobrevin-2 (residues 29–93, S61C), see Figure 2A) or reconstituted onto liposomes (using full-length synaptobrevin-2 (residues 1–116, S61C), referred to v-liposomes, see Figure 2C). Note that, cis ternary SNARE complex formation was monitored by using SNAP-25 (S187C) and the cytoplasmic domain of synaptobrevin-2 in the presence of t-liposomes (Figure 2A); in contrast, full-length synaptobrevin-2 and a C-terminal truncated SNAP-25 fragment (residues 1–197, S187C, referred to as SNAP-25 Δ9) were applied to monitor trans ternary SNARE complex formation between t- and v-liposomes (Figure 2C), because SNAP-25 Δ9 can assemble into the trans ternary SNARE complex without inducing membrane fusion (Binz et al., 1994; Lu, 2015). Fluorescence donor and acceptor were separately labeled to synaptobrevin-2 and SNAP-25 as shown in Figures 2A,C, respectively. In this assay, a Munc13-1 C₁-C₂B-MUN fragment (which includes the C₁ and C₂B domains that bind to DAG and PI(4,5)P2 on t-liposomes, respectively), rather than the MUN domain, was applied, due to its high ability for membrane binding (Ma et al., 2013; Liu et al., 2016). Consistent with the results observed in solution (Figures 1D–F), we observed that both C2AB and C2B of Syt1 were able to stimulate the transition of the Munc18-1/syntaxin-1 complex to the ternary SNARE complex on membranes with the addition of the C₁-C₂B-MUN fragment and SNAP-25 (or SNAP-25 Δ9), no matter synaptobrevin-2 was present in a soluble state (Figures 2A,B) or embedded in the membrane (Figures 2C,D). As control, this stimulation was abrogated in the absence of the C₁-C₂B-MUN fragment (Figures 2A–D). In addition, C2B_2RQ lost the stimulation activity (Figures 2A–D). These data suggest that Syt1 stimulates both cis and trans ternary SNARE complex formation on membranes in the presence of Munc18-1 and Munc13-1.

We next analyzed the kinetics of the Syt1-stimulated transition reactions in the absence and presence of membranes (Table 1 and Supplementary Figure S3). Compared to membrane-free system (Supplementary Figure S3A), one-membrane system (i.e., t-liposomes and the cytoplasmic domain of synaptobrevin-2, see Supplementary Figure S3B) exhibited comparable reaction rate in the absence of C2AB (1.299 ± 0.100 × 10⁻³ s⁻¹ vs. 1.352 ± 0.039 × 10⁻³ s⁻¹), but displayed faster rate in the presence of C2AB (3.540 ± 0.090 × 10⁻³ s⁻¹ vs. 15.20 ± 0.69 × 10⁻³ s⁻¹; Table 1). This acceleration arises likely from robust association of C2AB with membranes via binding to PI(4,5)P2, thus increasing C2AB binding probability to the SNAREs, Munc18-1 and Munc13-1 on the membrane. In contrast to the membrane-free and one-membrane systems, two-membrane system (i.e., t-liposomes and v-liposomes, see Supplementary Figure S3C) showed even higher reaction rate both in the absence and presence of C2AB (12.29 ± 1.76 × 10⁻³ s⁻¹ and 24.93 ± 1.02 × 10⁻³ s⁻¹, respectively; Table 1), which arises likely because the C₁-C₂B-MUN fragment efficiently associates t- and v-liposomes into close proximity and thus further increases collision probabilities among these proteins (Liu et al., 2016). These results suggest that the membrane behaves as a perfect platform, enabling Syt1 cooperation with Munc18-1 and Munc13-1 to stimulate trans ternary SNARE complex formation more efficiently.

It was previously shown that, started with liposomes containing syntaxin-1/SNAP-25 heterodimers, the efficient lipid mixing with synaptobrevin-2 liposomes in the presence of Ca²⁺ and Syt1 (C2AB) was abolished by incorporation of NSF and α-SNAP because they disassemble syntaxin-1/SNAP-25 heterodimers (Ma et al., 2013; Liu et al., 2016). In the presence of NSF and α-SNAP, efficient membrane fusion requires both Munc18-1 and Munc13-1 (the C₁-C₂B-MUN fragment) to orchestrate SNARE-mediated membrane fusion in an NSF/α-SNAP-resistant manner (Ma et al., 2013; Liu et al., 2016). These results suggest that assembly and disassembly factors (i.e., Munc18-1/Munc13-1 and NSF/α-SNAP, respectively) function in alternation to catalyze cycles of membrane fusion (Hughson, 2013; Ma et al., 2013; Rizo and Xu, 2015). In this regard, we investigated whether Syt1 stimulates trans ternary SNARE complex formation starting with syntaxin-1/SNAP-25 heterodimers in the presence of Munc18-1, Munc13-1, NSF and α-SNAP in a membrane-containing environment.

To monitor the formation of trans ternary SNARE complexes on membranes, we routinely used synaptobrevin-2 (full-length, S61C) and SNAP-25 Δ9 (S187C) as FRET donor and acceptor, respectively (Figure 3A). Mixing syntaxin-1/SNAP-25 Δ9 liposomes (t’-liposomes) and synaptobrevin-2 liposomes (v-liposomes) produced trans ternary SNARE complex formation in the presence of Munc18-1, Munc13-1 (the C₁-C₂B-MUN fragment), NSF, α-SNAP, ATP and Mg²⁺ (Figures 3B,C). This result is in agreement with the notion that Munc18-1 captures the syntaxin-1 from the membrane-embedded syntaxin-1/SNAP-25 heterodimer assisted by NSF and α-SNAP, leading to the transition of the Munc18-1/syntaxin-1 complex to the ternary SNARE complex catalyzed by Munc13-1 through an NSF/α-SNAP-resistant pathway (Ma et al., 2013). Intriguingly, we observed that both C2AB and C2B, instead of C2A, were able to further stimulate trans ternary SNARE complex formation in the presence of Munc18-1, Munc13-1, NSF and α-SNAP (Figures 3B,C). In contrast, C2B_2RQ, but not C2b, abolished this stimulation (Figures 3B,C), reinforcing the importance of the C2B/SNARE interaction for the stimulation function of Syt1. However, the stimulation of Syt1 was abrogated when Munc18-1 and Munc13-1 were absent (Figures 3B,C), as NSF and α-SNAP disassemble the syntaxin-1/SNAP-25 complex to prevent SNARE complex formation (Supplementary Figure S4). These results imply that Syt1 cooperates with Munc18-1 and Munc13-1 to stimulate trans ternary SNARE complex on membranes in an NSF/α-SNAP-resistant manner.

We recently found that binding of Munc13-1 to the Munc18-1/syntaxin-1 complex induces a conformational rearrangement in the syntaxin-1 linker region that cause higher reactivity towards ternary SNARE complex formation (Wang et al., 2017; Figure 4A). With Munc13-1, transit of syntaxin-1 from the Munc18-1/syntaxin-1 complex to the ternary SNARE complex strictly requires the simultaneous existence of SNAP-25 and synaptobrevin-2 (Wang et al., 2017). It is thus conceivable that, the conformational change in the syntaxin-1 linker region induced by Munc13-1 would expose the N-terminal end of the H3 domain of syntaxin-1, providing a nucleation site for SNAP-25 and synaptobrevin-2 binding (Figure 4B). Subsequently, propagation of the four helical SNARE bundle toward the C-terminal end would eventually dissociate the H3 domain from the closed Munc18-1/syntaxin-1 complex (Figure 4C). This model challenges the current dogma on the role of the steadily preassembled syntaxin-1/SNAP-25 heterodimer (“t-SNARE”) as an “on-pathway” product in neuronal SNARE complex formation (Bhalla et al., 2006; Wiederhold and Fasshauer, 2009; Hui et al., 2011), suggesting a simultaneous “N-to-C” assembly of the three SNAREs chaperoned by Munc18-1 and Munc13-1 (Figures 4A–C). Based on this model and our present results, we hypothesize that, binding of Syt1 to a partially installed ternary SNARE assembly with Munc18-1 and Munc13-1 (Figure 4D), promotes SNARE zippering forward to the C-terminal end of the ternary SNARE complex. Indeed, this hypothesis is supported by our observation that disruption of the C2B/SNARE interaction by introducing the R398Q/R399Q mutations abolishes the stimulation function of Syt1 in ternary SNARE complex formation dependent on Munc18-1 and Munc13-1 (Figures 1–3).