Docking of Yeast Vacuoles Is Catalyzed by the Ras-like GTPase Ypt7p after Symmetric Priming by Sec18p (NSF)

Vacuole inheritance in yeast involves the formation of tubular and vesicular “segregation structures” which migrate into the bud and fuse there to establish the daughter cell vacuole. Vacuole fusion has been reconstituted in vitro and may be used as a model for an NSF-dependent reaction of priming, docking, and fusion. We have developed biochemical and microscopic assays for the docking step of in vitro vacuole fusion and characterized its requirements. The vacuoles must be primed for docking by the action of Sec17p (α-SNAP) and Sec18p (NSF). Priming is necessary for both fusion partners. It produces a labile state which requires rapid docking in order to lead productively to fusion. In addition to Sec17p/Sec18p, docking requires the activity of the Ras-like GTPase Ypt7p. Unlike Sec17p/Sec18p, which must act before docking, Ypt7p is directly involved in the docking process itself.     

Homotypic vacuole fusion requires Sec17p (yeast alpha-SNAP) and Sec18p (yeast NSF).

In Saccharomyces cerevisiae, vacuoles are inherited by the formation of tubular and vesicular structures from the mother vacuole, the directed projection of these structures into the bud and the homotypic fusion of these vesicles. We have previously exploited a cell-free inheritance assay to show that the fusion step of vacuole inheritance requires cytosol, ATP and the GTPase Ypt7p. Here we demonstrate, using affinity-purified antibodies and purified recombinant proteins, a requirement for Sec17p (yeast alpha-SNAP) and Sec18p (yeast NSF) in homotypic vacuole fusion in vitro. Thus, Sec17p and Sec18p, which are typically involved in heterotypic transport steps, can also be involved in homotypic organelle fusion. We further show that vacuole-to-vacuole fusion is stimulated by certain fatty acyl-coenzyme A compounds in a Sec18p-dependent fashion. Finally, our data suggest the presence of a cytosolic factor which activates vacuole membrane-bound Sec18p.     

Thioredoxin is required for vacuole inheritance in Saccharomyces cerevisiae

The vacuole of Saccharomyces cerevisiae projects a stream of tubules a and vesicles (a segregation structure) into the bud in early S phase. We have described an in vitro reaction, requiring physiological temperature, ATP, and cytosol, in which isolated vacuoles form segregation structures and fuse. This in vitro reaction is defective when reaction components are prepared from vac mutants that are defective in this process in vivo, Fractionation of the cytosol reveals at least three components, each of which can support the vacuole fusion reaction, and two stimulatory fractions. Purification of one low molecular weight activity (LMA1) yields a heterodimeric protein with a thioredoxin subunit. Most of the thioredoxin of yeast is in this complex rather than the well-studied monomer. A deletion of both S. cerevisiae thioredoxin genes causes a striking vacuole inheritance defect in vivo, establishing a role for thioredoxin as a novel factor in this trafficking reaction.     

Coupled ER to Golgi Transport Reconstituted with Purified Cytosolic Proteins

A cell-free vesicle fusion assay that reproduces a subreaction in transport of pro-α-factor from the ER to the Golgi complex has been used to fractionate yeast cytosol. Purified Sec18p, Uso1p, and LMA1 in the presence of ATP and GTP satisfies the requirement for cytosol in fusion of ER-derived vesicles with Golgi membranes. Although these purified factors are sufficient for vesicle docking and fusion, overall ER to Golgi transport in yeast semi-intact cells depends on COPII proteins (components of a membrane coat that drive vesicle budding from the ER). Thus, membrane fusion is coupled to vesicle formation in ER to Golgi transport even in the presence of saturating levels of purified fusion factors. Manipulation of the semi-intact cell assay is used to distinguish freely diffusible ER- derived vesicles containing pro-α-factor from docked vesicles and from fused vesicles. Uso1p mediates vesicle docking and produces a dilution resistant intermediate. Sec18p and LMA1 are not required for the docking phase, but are required for efficient fusion of ER- derived vesicles with the Golgi complex. Surprisingly, elevated levels of Sec23p complex (a subunit of the COPII coat) prevent vesicle fusion in a reversible manner, but do not interfere with vesicle docking. Ordering experiments using the dilution resistant intermediate and reversible Sec23p complex inhibition indicate Sec18p action is required before LMA1 function.     

Ergosterol is required for the Sec18/ATP-dependent priming step of homotypic vacuole fusion

In vitro homotypic fusion of yeast vacuoles occurs in three stages: priming, the Sec18 (NSF)-mediated changes that precede vacuole association; docking, the Ypt7 and SNARE-mediated pairing of vacuoles; and fusion, mediated by calmodulin/V0/t-SNARE interactions. Defects in catalysts of each stage result in fragmented (unfused) vacuoles. Strains with deletions in any of ERG genes 3-6, lacking normal ergosterol biosynthesis, have fragmented vacuoles. The ergosterol ligands filipin, nystatin and amphotericin B block the in vitro fusion of vacuoles from wild-type cells. Each of these inhibitors acts at the priming stage to inhibit Sec17p release from vacuoles. A reversible delay in Sec18p action prevents vacuoles from acquiring resistance to any of these three drugs, confirming that their action is on the normal fusion pathway. Ergosterol or cholesterol delivery to wild-type vacuoles stimulates their in vitro fusion, and the in vitro fusion of ergDelta vacuoles requires added sterol. The need for ergosterol for vacuole priming underscores the role of lipids in organizing the membrane elements of this complex reaction.     

Vac8p release from the SNARE complex and its palmitoylation are coupled and essential for vacuole fusion

Activated fatty acids stimulate budding and fusion in several cell-free assays for vesicular transport. This stimulation is thought to be due to protein palmitoylation, but relevant substrates have not yet been identified. We now report that Vac8p, a protein known to be required for vacuole inheritance, becomes palmitoylated when isolated yeast vacuoles are incubated under conditions that allow membrane fusion. Similar requirements for Vac8p palmitoylation and vacuole fusion, the inhibition of vacuole fusion by antibodies to Vac8p and the strongly reduced fusion of vacuoles lacking Vac8p suggest that palmitoylated Vac8p is essential for homotypic vacuole fusion. Strikingly, palmitoylation of Vac8p is blocked by the addition of antibodies to Sec18p (yeast NSF) only. Consistent with this, a portion of Vac8p is associated with the SNARE complex on vacuoles, which is lost during Sec18p- and ATP-dependent priming. During or after SNARE complex disassembly, palmitoylation occurs and anchors Vac8p to the vacuolar membrane. We propose that palmitoylation of Vac8p is regulated by the same machinery that controls membrane fusion.     

Vam7p, a vacuolar SNAP-25 homolog, is required for SNARE complex integrity and vacuole docking and fusion.

The vacuole v-t-SNARE complex is disassembled by Sec17p/alpha-SNAP and Sec18p/NSF prior to vacuole docking and fusion. We now report a functional characterization of the vacuolar SNARE Vam7p, a SNAP-25 homolog. Although Vam7p has no hydrophobic domains, it is tightly associated with the vacuolar membrane. Vam7p is a constituent of the vacuole SNARE complex and is released from this complex by the Sec17p/Sec18p/ATP-mediated priming of the vacuoles. Even in the absence of the vacuolar v-SNARE Nyv1p, a subcomplex which includes Vam7p and the t-SNARE Vam3p is preserved. Vam7p is necessary for the stability of the vacuolar SNARE complex, since vacuoles from mutants deleted in VAM7 do not have a Vam3p-Nyv1p complex. Furthermore, Vam7p alone, in the absence of Nyv1p and Vam3p, cannot mediate fusion with wild-type vacuoles, whereas vacuoles with only Nyv1p or Vam3p alone can fuse with wild-type vacuoles in the absence of the other two SNAREs. Thus, Vam7p is important for the stable assembly and efficient function of the vacuolar SNARE complex and maintenance of the vacuolar morphology. This functional characterization of Vam7p suggests a general role for SNAP-25 homologs, not only on the plasma membrane but along the secretory pathway.     

The Vtc proteins in vacuole fusion: coupling NSF activity to V(0) trans-complex formation

The fusion of cellular membranes comprises several steps; membrane attachment requires priming of SNAREs and tethering factors by Sec18p/NSF (N-ethylmaleimide sensitive factor) and LMA1. This leads to trans-SNARE pairing, i.e. formation of SNARE complexes between apposed membranes. The yeast vacuole system has revealed two subsequent molecular events: trans-complex formation of V-ATPase proteolipid sectors (V(0)) and release of LMA1 from the membrane. We have now identified a hetero-oligomeric membrane integral complex of vacuolar transporter chaperone (Vtc) proteins integrating these events. The Vtc complex associates with the R-SNARE Nyv1p and with V(0). Subunits Vtc1p and Vtc4p control the initial steps of fusion. They are required for Sec18p/NSF activity in SNARE priming, membrane binding of LMA1 and V(0) trans-complex formation. In contrast, subunit Vtc3p is required for the latest step, LMA1 release, but dispensible for all preceding steps, including V(0) trans-complex formation. This suggests that Vtc3p might act close to or at fusion pore opening. We propose that Vtc proteins may couple ATP-dependent NSF activity to a subset of V(0) sectors in order to activate them for V(0) trans-complex formation and/or control fusion pore opening.     

Cdc42p Is Activated during Vacuole Membrane Fusion in a Sterol-dependent Subreaction of Priming

Cdc42p is a Rho GTPase that initiates signaling cascades at spatially defined intracellular sites for many cellular functions. We have previously shown that Cdc42p is localized to the yeast vacuole where it initiates actin polymerization during membrane fusion. Here we examine the activation cycle of Cdc42p during vacuole membrane fusion. Expression of either GTP- or GDP-locked Cdc42p mutants caused several morphological defects including enlarged cells and fragmented vacuoles. Stimulation of multiple rounds of fusion enhanced vacuole fragmentation, suggesting that cycles of Cdc42p activation, involving rounds of GTP binding and hydrolysis, are required to propagate Cdc42p signaling. We developed an assay to directly examine Cdc42p activation based on affinity to a probe derived from the p21-activated kinase effector, Ste20p. Cdc42p was rapidly activated during vacuole membrane fusion, which kinetically coincided with priming subreaction. During priming, Sec18p ATPase activity dissociates SNARE complexes and releases Sec17p, however, priming inhibitors such as Sec17p and Sec18p ligands did not block Cdc42p activation. Therefore, Cdc42p activation seems to be a parallel subreaction of priming, distinct from Sec18p activity. Specific mutants in the ergosterol synthesis pathway block both Sec17p release and Cdc42p activation. Taken together, our results define a novel sterol-dependent subreaction of vacuole priming that activates cycles of Cdc42p activity to facilitate membrane fusion.     

The docking of primed vacuoles can be reversibly arrested by excess Sec17p (alpha-SNAP)

Homotypic vacuole fusion occurs in ordered stages of priming, docking, and fusion. Priming, which prepares vacuoles for productive association, requires Sec17p (the yeast homolog of alpha-SNAP), Sec18p (the yeast NSF, an ATP-driven chaperone), and ATP. Sec17p is initially an integral part of the cis-SNARE complex together with vacuolar SNARE proteins and Sec18p (NSF). Previous studies have shown that Sec17p is rapidly released from the vacuole membrane during priming as the cis-SNARE complex is disassembled, but the order and causal relationship of these subreactions has not been known. We now report that the addition of excess recombinant his(6)-Sec17p to primed vacuoles can block subsequent docking. This inhibition is reversible by Sec18p, but the reaction cannot proceed to the tethering and trans-SNARE pairing steps of docking while the Sec17p block is in place. Once docking has occurred, excess Sec17p does not inhibit membrane fusion per se. Incubation of cells with thermosensitive Sec17-1p at nonpermissive temperature causes SNARE complex disassembly. These data suggest that Sec17p can stabilize vacuolar cis-SNARE complexes and that the release of Sec17p by Sec18p and ATP allows disassembly of this complex and activates its components for docking.     

ATP-independent control of Vac8 palmitoylation by a SNARE subcomplex on yeast vacuoles

Yeast vacuole fusion requires palmitoylated Vac8. We previously showed that Vac8 acylation occurs early in the fusion reaction, is blocked by antibodies against Sec18 (yeast N-ethylmaleimide-sensitive fusion protein (NSF)), and is mediated by the R-SNARE Ykt6. Here we analyzed the regulation of this reaction on purified vacuoles. We show that Vac8 acylation is restricted to a narrow time window, is independent of ATP hydrolysis by Sec18, and is stimulated by the ion chelator EDTA. Analysis of vacuole protein complexes indicated that Ykt6 is part of a complex distinct from the second R-SNARE, Nyv1. We speculate that during vacuole fusion, Nyv1 is the classical R-SNARE, whereas the Ykt6-containing complex has a novel function in Vac8 palmitoylation.     

Yeast lipin 1 orthologue pah1p regulates vacuole homeostasis and membrane fusion

Vacuole homotypic fusion requires a group of regulatory lipids that includes diacylglycerol, a fusogenic lipid that is produced through multiple metabolic pathways including the dephosphorylation of phosphatidic acid (PA). Here we examined the relationship between membrane fusion and PA phosphatase activity. Pah1p is the single yeast homologue of the Lipin family of PA phosphatases. Deletion of PAH1 was sufficient to cause marked vacuole fragmentation and abolish vacuole fusion. The function of Pah1p solely depended on its phosphatase activity as complementation studies showed that wild type Pah1p restored fusion, whereas the phosphatase dead mutant Pah1p(D398E) had no effect. We discovered that the lack of PA phosphatase activity blocked fusion by inhibiting the binding of SNAREs to Sec18p, an N-ethylmaleimide-sensitive factor homologue responsible for priming inactive cis-SNARE complexes. In addition, pah1Δ vacuoles were devoid of the late endosome/vacuolar Rab Ypt7p, the phosphatidylinositol 3-kinase Vps34p, and Vps39p, a subunit of the HOPS (homotypic fusion and vacuole protein sorting) tethering complex, all of which are required for vacuole fusion. The lack of Vps34p resulted in the absence of phosphatidylinositol 3-phosphate, a lipid required for SNARE activity and vacuole fusion. These findings demonstrate that Pah1p and PA phosphatase activity are critical for vacuole homeostasis and fusion.     

The N-terminal Domain of the t-SNARE Vam3p Coordinates Priming and Docking in Yeast Vacuole Fusion

Homotypic fusion of yeast vacuoles requires a regulated sequence of events. During priming, Sec18p disassembles cis-SNARE complexes. The HOPS complex, which is initially associated with the cis-SNARE complex, then mediates tethering. Finally, SNAREs assemble into trans-complexes before the membranes fuse. The t-SNARE of the vacuole, Vam3p, plays a central role in the coordination of these processes. We deleted the N-terminal region of Vam3p to analyze the role of this domain in membrane fusion. The truncated protein (Vam3 Delta N) is sorted normally to the vacuole and is functional, because the vacuolar morphology is unaltered in this strain. However, in vitro vacuole fusion is strongly reduced due to the following reasons: Assembly, as well as disassembly of the cis-SNARE complex is more efficient on Vam3 Delta N vacuoles; however, the HOPS complex is not associated well with the Vam3 Delta N cis-complex. Thus, primed SNAREs from Vam3 Delta N vacuoles cannot participate efficiently in the reaction because trans-SNARE pairing is substantially reduced. We conclude that the N-terminus of Vam3p is required for coordination of priming and docking during homotypic vacuole fusion.     

A soluble SNARE drives rapid docking, bypassing ATP and Sec17/18p for vacuole fusion

Membrane fusion requires priming, the disassembly of cis-SNARE complexes by the ATP-driven chaperones Sec18/17p. Yeast vacuole priming releases Vam7p, a soluble SNARE. Vam7p reassociation during docking allows trans-SNARE pairing and fusion. We now report that recombinant Vam7p (rVam7p) enters into complex with other SNAREs in vitro and bypasses the need for Sec17p, Sec18p, and ATP. Thus, the sole essential function of vacuole priming in vitro is the release of Vam7p from cis-SNARE complexes. In 'bypass fusion', without ATP but with added rVam7p, there are sufficient unpaired vacuolar SNAREs Vam3p, Vti1p, and Nyv1p to interact with Vam7p and support fusion. However, active SNARE proteins are not sufficient for bypass fusion. rVam7p does not bypass requirements for Rho GTPases,Vps33p, Vps39p, Vps41p, calmodulin, specific lipids, or Vph1p, a subunit of the V-ATPase. With excess rVam7p, reduced levels of PI(3)P or functional Ypt7p suffice for bypass fusion. High concentrations of rVam7p allow the R-SNARE Ykt6p to substitute for Nyv1p for fusion; this functional redundancy among vacuole SNAREs may explain why nyv1delta strains lack the vacuole fragmentation seen with mutants in other fusion catalysts.     

The Major Role of the Rab Ypt7p in Vacuole Fusion Is Supporting HOPS Membrane Association

Yeast vacuole fusion requires soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs), the Rab GTPase Ypt7p, vacuolar lipids, Sec17p and Sec18p, and the homotypic fusion and vacuole protein sorting complex (HOPS). HOPS is a multisubunit protein with direct affinities for SNAREs, vacuolar lipids, and the GTP-bound form of Ypt7p; each of these affinities contributes to HOPS association with the organelle. Using all-purified components, we have reconstituted fusion, but the Rab Ypt7p was not required. We now report that phosphorylation of HOPS by the vacuolar kinase Yck3p blocks HOPS binding to vacuolar lipids, making HOPS membrane association and the ensuing fusion depend on the presence of Ypt7p. In accord with this finding in the reconstituted fusion reaction, the inactivation of Ypt7p by the GTPase-activating protein Gyp1–46p only blocks the fusion of purified vacuoles when Yck3p is present and active. Thus, although Ypt7p may contribute to other fusion functions, its central role is to bind HOPS to the membrane.Rab proteins are small GTP-binding proteins involved in multiple steps of membrane traffic, including protein sorting, vesicle transport, and SNARE³-dependent membrane fusion (1). Rabs in their GTP-bound state bind proteins that are essential for mediating Rab function, which are therefore termed “effectors.” These effectors are diverse and perform various biochemical functions. For membrane fusion, Rabs and their effectors support tethering, the initial membrane contact that is needed for the subsequent assembly of trans-SNARE complexes between membranes (1, 2). A central question in organelle trafficking, which we now address, is whether Rabs are only required for binding their effectors to the membrane or whether they also activate the bound effector or provide some additional essential function for membrane fusion.We study membrane fusion using isolated yeast vacuoles (3). Yeast vacuole fusion requires the Rab GTPase Ypt7p, the heterohexameric HOPS complex, four vacuolar SNAREs, the SNARE disassembly chaperones Sec17p and Sec18p, and chemically minor yet functionally essential lipids, termed “regulatory” lipids. The HOPS complex is an effector of Ypt7p (4) and belongs to a group of functionally conserved large multisubunit tethering complexes, many of which are Rab effectors (5). The Vps39p subunit of HOPS is a nucleotide exchange factor for Ypt7p (6). HOPS is also a SNARE chaperone; its Vps33p subunit is a Sec1p/Munc18-1 family (SM) protein, HOPS binds multiple vacuolar SNAREs (7–9), and it proofreads SNARE complex structure (10). HOPS also binds to specific phosphoinositides (8), and these are among the regulatory lipids that are important for fusion (11–13).We have recently reconstituted membrane fusion using proteoliposomes of pure vacuolar proteins and lipids (13). HOPS and the regulatory lipids are crucial for rapid fusion of proteoliposome pairs bearing the three Q-SNAREs on one proteoliposome and the R-SNARE on the other and are absolutely required when all four SNAREs are present on each proteoliposome and Sec17p and Sec18p are present. Ypt7p is not required, showing that HOPS can stimulate SNARE-dependent fusion in vitro even in the absence of its Rab, although Ypt7p stimulates the fusion of these proteoliposomes.4Yeast vacuole fusion can be negatively regulated either by GTPase-activating proteins (GAPs) (14, 15) that promote GTP hydrolysis by Ypt7p or by the kinase Yck3p, which phosphorylates the Vps41p subunit of HOPS (16) and the vacuolar SNARE Vam3p (15). Yck3p is a palmitoylated (17), vacuole-localized kinase of the casein kinase I family (18). The complete fragmentation of vacuoles in vivo, indicating a block of fusion, requires both Ypt7p inactivation by a RabGAP and the presence of Yck3p (15). Yck3p is necessary for efficient vacuole inheritance (16) and normal vacuole morphology (19), suggesting that its function is part of the normal mechanism of vacuole segregation during the cell cycle. Although Yck3p clearly regulates vacuole fusion through phosphorylation of HOPS, it remains unclear which activities of HOPS are inhibited by Yck3p phosphorylation and whether Yck3p must also phosphorylate other vacuole fusion proteins such as Vam3p to block fusion.We now show that phosphorylation of the Vps41p subunit of HOPS by purified Yck3p reduces HOPS binding to membrane lipids, thereby making HOPS association with the membrane and the ensuing fusion of reconstituted proteoliposomes dependent on active Ypt7p. These data with proteoliposomes are supported by assays with purified vacuoles; the RabGAP Gyp1–46p only inhibits the in vitro fusion of yck3Δ vacuoles when purified Yck3p is added. As for Ypt7p and HOPS, the major function of other Rabs may also be to act as membrane receptors for their effectors.     

The SNARE Ykt6 mediates protein palmitoylation during an early stage of homotypic vacuole fusion

The NSF homolog Sec18 initiates fusion of yeast vacuoles by disassembling cis-SNARE complexes during priming. Sec18 is also required for palmitoylation of the fusion factor Vac8, although the acylation machinery has not been identified. Here we show that the SNARE Ykt6 mediates Vac8 palmitoylation and acts during a novel subreaction of vacuole fusion. This subreaction is controlled by a Sec17-independent function of Sec18. Our data indicate that Ykt6 presents Pal-CoA via its N-terminal longin domain to Vac8, while transfer to Vac8's SH4 domain occurs spontaneously and not enzymatically. The conservation of Ykt6 and its localization to several organelles suggest that its acyltransferase activity may also be required in other intracellular fusion events.     

Phosphatidic Acid Sequesters Sec18p from cis‐SNARE Complexes to Inhibit Priming

Yeast vacuole fusion requires the activation of cis‐SNARE complexes through priming carried out by Sec18p/N‐ethylmaleimide sensitive factor and Sec17p/α‐SNAP. The association of Sec18p with vacuolar cis‐SNAREs is regulated in part by phosphatidic acid (PA) phosphatase production of diacylglycerol (DAG). Inhibition of PA phosphatase activity blocks the transfer of membrane‐associated Sec18p to SNAREs. Thus, we hypothesized that Sec18p associates with PA‐rich membrane microdomains before transferring to cis‐SNARE complexes upon PA phosphatase activity. Here, we examined the direct binding of Sec18p to liposomes containing PA or DAG. We found that Sec18p preferentially bound to liposomes containing PA compared with those containing DAG by approximately fivefold. Additionally, using a specific PA‐binding domain blocked Sec18p binding to PA‐liposomes and displaced endogenous Sec18p from isolated vacuoles. Moreover, the direct addition of excess PA blocked the priming activity of isolated vacuoles in a manner similar to chemically inhibiting PA phosphatase activity. These data suggest that the conversion of PA to DAG facilitates the recruitment of Sec18p to cis‐SNAREs. Purified vacuoles from yeast lacking the PA phosphatase Pah1p showed reduced Sec18p association with cis‐SNAREs and complementation with plasmid‐encoded PAH1 or recombinant Pah1p restored the interaction. Taken together, this demonstrates that regulating PA concentrations by Pah1p activity controls SNARE priming by Sec18p.      

Trans-SNARE interactions elicit Ca2+ efflux from the yeast vacuole lumen

Ca2+ transients trigger many SNARE-dependent membrane fusion events. The homotypic fusion of yeast vacuoles occurs after a release of lumenal Ca2+. Here, we show that trans-SNARE interactions promote the release of Ca2+ from the vacuole lumen. Ypt7p-GTP, the Sec1p/Munc18-protein Vps33p, and Rho GTPases, all of which function during docking, are required for Ca2+ release. Inhibitors of SNARE function prevent Ca2+ release. Recombinant Vam7p, a soluble Q-SNARE, stimulates Ca2+ release. Vacuoles lacking either of two complementary SNAREs, Vam3p or Nyv1p, fail to release Ca2+ upon tethering. Mixing these two vacuole populations together allows Vam3p and Nyv1p to interact in trans and rescues Ca2+ release. Sec17/18p promote sustained Ca2+ release by recycling SNAREs (and perhaps other limiting factors), but are not required at the release step itself. We conclude that trans-SNARE assembly events during docking promote Ca2+ release from the vacuole lumen.     

The docking stage of yeast vacuole fusion requires the transfer of proteins from a cis-SNARE complex to a Rab/Ypt protein

The homotypic fusion of yeast vacuoles requires Sec18p (NSF)-driven priming to allow vacuole docking, but the mechanism that links priming and docking is unknown. We find that a large multisubunit protein called the Vam2/6p complex is bound to cis-paired SNAP receptors (SNAREs) on isolated vacuoles. This association of the Vam2/6p complex with the cis-SNARE complex is disrupted during priming. The Vam2/6p complex then binds to Ypt7p, a guanosine triphosphate binding protein of the Rab family, to initiate productive contact between vacuoles. Thus, cis-SNARE complexes can contain Rab/Ypt effectors, and these effectors can be mobilized by NSF/Sec18p-driven priming, allowing their direct association with a Rab/Ypt protein to activate docking.     

A Vacuolar v–t-SNARE Complex, the Predominant Form In Vivo and on Isolated Vacuoles, Is Disassembled and Activated for Docking and Fusion

Homotypic vacuole fusion in yeast requires Sec18p (N-ethylmaleimide–sensitive fusion protein [NSF]), Sec17p (soluble NSF attachment protein [α-SNAP]), and typical vesicle (v) and target membrane (t) SNAP receptors (SNAREs). We now report that vacuolar v- and t-SNAREs are mainly found with Sec17p as v–t-SNARE complexes in vivo and on purified vacuoles rather than only transiently forming such complexes during docking, and disrupting them upon fusion. In the priming reaction, Sec18p and ATP dissociate this v–t-SNARE complex, accompanied by the release of Sec17p. SNARE complex structure governs each functional aspect of priming, as the v-SNARE regulates the rate of Sec17p release and, in turn, Sec17p-dependent SNARE complex disassembly is required for independent function of the two SNAREs. Sec17p physically and functionally interacts largely with the t-SNARE. (a) Antibodies to the t-SNARE, but not the v-SNARE, block Sec17p release. (b) Sec17p is associated with the t-SNARE in the absence of v-SNARE, but is not bound to the v-SNARE without t-SNARE. (c) Vacuoles with t-SNARE but no v-SNARE still require Sec17p/Sec18p priming, whereas their fusion partners with v-SNARE but no t-SNARE do not. Sec18p thus acts, upon ATP hydrolysis, to disassemble the v–t-SNARE complex, prime the t-SNARE, and release the Sec17p to allow SNARE participation in docking and fusion. These studies suggest that the analogous ATP-dependent disassembly of the 20-S complex of NSF, α-SNAP, and v- and t-SNAREs, which has been studied in detergent extracts, corresponds to the priming of SNAREs for docking rather than to the fusion of docked membranes.