Hierarchy of protein assembly at the vertex ring domain for yeast vacuole docking and fusion

Vacuole tethering, docking, and fusion proteins assemble into a "vertex ring" around the apposed membranes of tethered vacuoles before catalyzing fusion. Inhibitors of the fusion reaction selectively interrupt protein assembly into the vertex ring, establishing a causal assembly hierarchy: (a) The Rab GTPase Ypt7p mediates vacuole tethering and forms the initial vertex ring, independent of t-SNAREs or actin; (b) F-actin disassembly and GTP-bound Ypt7p direct the localization of other fusion factors; (c) The t-SNAREs Vam3p and Vam7p regulate each other's vertex enrichment, but do not affect Ypt7p localization. The v-SNARE Vti1p is enriched at vertices by a distinct pathway that is independent of the t-SNAREs, whereas both t-SNAREs will localize to vertices when trans-pairing of SNAREs is blocked. Thus, trans-SNARE pairing is not required for SNARE vertex enrichment; and (d) The t-SNAREs regulate the vertex enrichment of both G-actin and the Ypt7p effector complex for homotypic fusion and vacuole protein sorting (HOPS). In accord with this hierarchy concept, the HOPS complex, at the end of the vertex assembly hierarchy, is most enriched at those vertices with abundant Ypt7p, which is at the start of the hierarchy. Our findings provide a unique view of the functional relationships between GTPases, SNAREs, and actin in membrane fusion.     

Purification of active HOPS complex reveals its affinities for phosphoinositides and the SNARE Vam7p

Coupling of Rab GTPase activation and SNARE complex assembly during membrane fusion is poorly understood. The homotypic fusion and vacuole protein sorting (HOPS) complex links these two processes: it is an effector for the vacuolar Rab GTPase Ypt7p and is required for vacuolar SNARE complex assembly. We now report that pure, active HOPS complex binds phosphoinositides and the PX domain of the vacuolar SNARE protein Vam7p. These binding interactions support HOPS complex association with the vacuole and explain its enrichment at the same microdomains on docked vacuoles as phosphoinositides, Ypt7p, Vam7p, and the other SNARE proteins. Concentration of the HOPS complex at these microdomains may be a key factor for coupling Rab GTPase activation to SNARE complex assembly.     

Distinct targeting and fusion functions of the PX and SNARE domains of yeast vacuolar Vam7p

Regulated membrane fusion requires organelle tethering, enrichment of selected proteins and lipids at the fusion site, bilayer distortion, and lipid rearrangement. Yeast vacuole homotypic fusion requires regulatory lipids (ergosterol, diacylglycerol, and phosphoinositides), the Rab family GTPase Ypt7p, the multisubunit Ypt7p-effector complex HOPS (homotypic fusion and vacuole protein sorting), and four SNAREs. One SNARE, Vam7p, has an N-terminal PX domain which binds to phosphatidylinositol 3-phosphate (PI(3)P) and to HOPS and a C-terminal SNARE domain but no apolar membrane anchor. We have exploited an in vitro reaction of vacuole fusion to analyze the functions of each domain, removing the PX domain or mutating it to abolish its PI(3)P affinity. Lowering the PI(3)P affinity of the PX domain, or even deleting the PX domain, affects the fusion K(m) for Vam7p but not the maximal fusion rate. Fusion driven by the SNARE domain alone is strikingly enhanced by the PLC inhibitor U73122 through enhanced binding of Vam7p SNARE domain to vacuoles, and the further addition of Plc1p blocks this U73122 effect. The PX domain, through its affinities for phosphoinositides and HOPS, is thus exclusively required for enhancing the targeting of Vam7p rather than for execution of the Vam7p functions in HOPS.SNARE complex assembly and fusion.     

Stringent 3Q.1R composition of the SNARE 0-layer can be bypassed for fusion by compensatory SNARE mutation or by lipid bilayer modification

SNARE proteins form bundles of four alpha-helical SNARE domains with conserved polar amino acids, 3Q and 1R, at the "0-layer" of the bundle. Previous studies have confirmed the importance of 3Q.1R for fusion but have not shown whether it regulates SNARE complex assembly or the downstream functions of assembled SNAREs. Yeast vacuole fusion requires regulatory lipids (ergosterol, phosphoinositides, and diacylglycerol), the Rab Ypt7p, the Rab-effector complex HOPS, and 4 SNAREs: the Q-SNAREs Vti1p, Vam3p, and Vam7p and the R-SNARE Nyv1p. We now report that alterations in the 0-layer Gln or Arg residues of Vam7p or Nyv1p, respectively, strongly inhibit fusion. Vacuoles with wild-type Nyv1p show exquisite discrimination for the wild-type Vam7p over Vam7(Q283R), yet Vam7(Q283R) is preferred by vacuoles with Nyv1(R191Q). Rotation of the position of the arginine in the 0-layer increases the K(m) for Vam7p but does not affect the maximal rate of fusion. Vam7(Q283R) forms stable 2Q.2R complexes that do not promote fusion. However, fusion is restored by the lipophilic amphiphile chlorpromazine or by the phospholipase C inhibitor U73122, perturbants of the lipid phase of the membrane. Thus, SNARE function as regulated by the 0-layer is intimately coupled to the lipids, which must rearrange for fusion.     

Sec17p and HOPS, in distinct SNARE complexes, mediate SNARE complex disruption or assembly for fusion

SNARE functions during membrane docking and fusion are regulated by Sec1/Munc18 (SM) chaperones and Rab/Ypt GTPase effectors. These functions for yeast vacuole fusion are combined in the six-subunit HOPS complex. HOPS facilitates Ypt7p nucleotide exchange, is a Ypt7p effector, and contains an SM protein. We have dissected the associations and requirements for HOPS, Ypt7p, and Sec17/18p during SNARE complex assembly. Vacuole SNARE complexes bind either Sec17p or the HOPS complex, but not both. Sec17p and its co-chaperone Sec18p disassemble SNARE complexes. Ypt7p regulates the reassembly of unpaired SNAREs with each other and with HOPS, forming HOPS.SNARE complexes prior to fusion. After HOPS.SNARE assembly, lipid rearrangements are still required for vacuole content mixing. Thus, Sec17p and HOPS have mutually exclusive interactions with vacuole SNAREs to mediate disruption of SNARE complexes or their assembly for docking and fusion. Sec17p may displace HOPS from SNAREs to permit subsequent rounds of fusion.     

Vacuole fusion at a ring of vertex docking sites leaves membrane fragments within the organelle

Three membrane microdomains can be identified on docked vacuoles: "outside" membrane, not in contact with other vacuoles, "boundary" membrane that contacts adjacent vacuoles, and "vertices," where boundary and outside membrane meet. In living cells and in vitro, vacuole fusion occurs at vertices rather than from a central pore expanding radially. Vertex fusion leaves boundary membrane within the fused organelle and is an unexpected pathway for the formation of intralumenal membranes. Proteins that regulate docking and fusion (Vac8p, the GTPase Ypt7p, its HOPS/Vps-C effector complex, the t-SNARE Vam3p, and protein phosphatase 1) accumulate at these vertices during docking. Their vertex enrichment requires cis-SNARE complex disassembly and is thus part of the normal fusion pathway.     

Yeast vacuolar HOPS,regulated by its kinase,exploits affinities for acidic lipids and Rab:GTP for membrane binding and to catalyze tethering and fusion

Fusion of yeast vacuoles requires the Rab GTPase Ypt7p, four SNAREs (soluble N-ethylmaleimide–sensitive factor attachment protein receptors), the SNARE disassembly chaperones Sec17p/Sec18p, vacuolar lipids, and the Rab-effector complex HOPS (homotypic fusion and vacuole protein sorting). Two HOPS subunits have direct affinity for Ypt7p. Although vacuolar fusion has been reconstituted with purified components, the functional relationships between individual lipids and Ypt7p:GTP have remained unclear. We now report that acidic lipids function with Ypt7p as coreceptors for HOPS, supporting membrane tethering and fusion. After phosphorylation by the vacuolar kinase Yck3p, phospho-HOPS needs both Ypt7p:GTP and acidic lipids to support fusion.     

Membrane dynamics and fusion at late endosomes and vacuoles--Rab regulation, multisubunit tethering complexes and SNAREs

Membrane fusion at late endosomes and vacuoles depends on a conserved machinery, which includes Rab GTPases, their binding to tethering complexes and SNAREs. Fusion is initiated by the interaction of Rabs with tethering complexes. At the endosome, the CORVET complex interacts with the Rab5 GTPase Vps21, whereas the homologous HOPS complex binds the Rab7-like Ypt7 at the late endosome and vacuole. Activation of Ypt7 requires the recruitment of the Mon1-Ccz1 complex to the late endosome, which occurs via the CORVET complex. The interaction of Rab and the tethering complex is followed by the assembly of SNAREs, which leads to bilayer mixing. In this review, we will summarize our current knowledge on the mechanisms and regulation of endosome and vacuole membrane dynamics, and their role in organelle physiology.     

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 yeast vacuolar Rab GTPase Ypt7p has an activity beyond membrane recruitment of the homotypic fusion and protein sorting-Class C Vps complex

A previous report described lipid mixing of reconstituted proteoliposomes made using lipid mixtures that mimic the composition of yeast vacuoles. This lipid mixing required SNARE {SNAP [soluble NSF (N-ethylmaleimide-sensitive factor)-attachment protein] receptor} proteins, Sec18p and Sec17p (yeast NSF and α-SNAP) and the HOPS (homotypic fusion and protein sorting)-Class C Vps (vacuole protein sorting) complex, but not the vacuolar Rab GTPase Ypt7p. The present study investigates the activity of Ypt7p in proteoliposome lipid mixing. Ypt7p is required for the lipid mixing of proteoliposomes lacking cardiolipin [1,3-bis-(sn-3'-phosphatidyl)-sn-glycerol]. Omission of other lipids with negatively charged and/or small head groups does not cause Ypt7p dependence for lipid mixing. Yeast vacuoles made from strains disrupted for CRD1 (cardiolipin synthase) fuse to the same extent as vacuoles from strains with functional CRD1. Disruption of CRD1 does not alter dependence on Rab GTPases for vacuole fusion. It has been proposed that the recruitment of the HOPS complex to membranes is the main function of Ypt7p. However, Ypt7p is still required for lipid mixing even when the concentration of HOPS complex in lipid-mixing reactions is adjusted such that cardiolipin-free proteoliposomes with or without Ypt7p bind to equal amounts of HOPS. Ypt7p therefore must stimulate membrane fusion by a mechanism that is in addition to recruitment of HOPS to the membrane. This is the first demonstration of such a stimulatory activity--that is, beyond bulk effector recruitment--for a Rab GTPase.     

HOPS proofreads the trans-SNARE complex for yeast vacuole fusion

The fusion of yeast vacuoles, like other organelles, requires a Rab-family guanosine triphosphatase (Ypt7p), a Rab effector and Sec1/Munc18 (SM) complex termed HOPS (homotypic fusion and vacuole protein sorting), and soluble N-ethylmaleimide-sensitive factor attachment protein receptors (SNAREs). The central 0-layer of the four bundled vacuolar SNAREs requires the wild-type three glutaminyl (Q) and one arginyl (R) residues for optimal fusion. Alterations of this layer dramatically increase the K(m) value for SNAREs to assemble trans-SNARE complexes and to fuse. We now find that added purified HOPS complex strongly suppresses the fusion of vacuoles bearing 0-layer alterations, but it has little effect on the fusion of vacuoles with wild-type SNAREs. HOPS proofreads at two levels, inhibiting the formation of trans-SNARE complexes with altered 0-layers and suppressing the ability of these mismatched 0-layer trans-SNARE complexes to support membrane fusion. HOPS proofreading also extends to other parts of the SNARE complex, because it suppresses the fusion of trans-SNARE complexes formed without the N-terminal Phox homology domain of Vam7p (Q(c)). Unlike some other SM proteins, HOPS proofreading does not require the Vam3p (Q(a)) N-terminal domain. HOPS thus proofreads SNARE domain and N-terminal domain structures and regulates the fusion capacity of trans-SNARE complexes, only allowing full function for wild-type SNARE configurations. This is the most direct evidence to date that HOPS is directly involved in the fusion event.     

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.     

The Habc Domain of the SNARE Vam3 Interacts with the HOPS Tethering Complex to Facilitate Vacuole Fusion

Membrane fusion at vacuoles requires a consecutive action of the HOPS tethering complex, which is recruited by the Rab GTPase Ypt7, and vacuolar SNAREs to drive membrane fusion. It is assumed that the Sec1/Munc18-like Vps33 within the HOPS complex is largely responsible for SNARE chaperoning. Here, we present direct evidence for HOPS binding to SNAREs and the H_abc domain of the Vam3 SNARE protein, which may explain its function during fusion. We show that HOPS interacts strongly with the Vam3 H_abc domain, assembled Q-SNAREs, and the R-SNARE Ykt6, but not the Q-SNARE Vti1 or the Vam3 SNARE domain. Electron microscopy combined with Nanogold labeling reveals that the binding sites for vacuolar SNAREs and the H_abc domain are located in the large head of the HOPS complex, where Vps16 and Vps33 have been identified before. Competition experiments suggest that HOPS bound to the H_abc domain can still interact with assembled Q-SNAREs, whereas Q-SNARE binding prevents recognition of the H_abc domain. In agreement, membranes carrying Vam3ΔH_abc fuse poorly unless an excess of HOPS is provided. These data suggest that the H_abc domain of Vam3 facilitates the assembly of the HOPS/SNARE machinery at fusion sites and thus supports efficient membrane fusion.     

Structural Identification of the Vps18 β-Propeller Reveals a Critical Role in the HOPS Complex Stability and Function

Membrane fusion at the vacuole, the lysosome equivalent in yeast, requires the HOPS tethering complex, which is recruited by the Rab7 GTPase Ypt7. HOPS provides a template for the assembly of SNAREs and thus likely confers fusion at a distinct position on vacuoles. Five of the six subunits in HOPS have a similar domain prediction with strong similarity to COPII subunits and nuclear porins. Here, we show that Vps18 indeed has a seven-bladed β-propeller as its N-terminal domain by revealing its structure at 2.14 Å. The Vps18 N-terminal domain can interact with the N-terminal part of Vps11 and also binds to lipids. Although deletion of the Vps18 N-terminal domain does not preclude HOPS assembly, as revealed by negative stain electron microscopy, the complex is instable and cannot support membrane fusion in vitro. We thus conclude that the β-propeller of Vps18 is required for HOPS stability and function and that it can serve as a starting point for further structural analyses of the HOPS tethering complex.     

The HOPS/Class C Vps Complex Tethers High‐Curvature Membranes via a Direct Protein–Membrane Interaction

Membrane tethering is a physical association of two membranes before their fusion. Many membrane tethering factors have been identified, but the interactions that mediate inter‐membrane associations remain largely a matter of conjecture. Previously, we reported that the homotypic fusion and protein sorting/Class C vacuolar protein sorting (HOPS/Class C Vps) complex, which has two binding sites for the yeast vacuolar Rab GTPase Ypt7p, can tether two low‐curvature liposomes when both membranes bear Ypt7p. Here, we show that HOPS tethers highly curved liposomes to Ypt7p‐bearing low‐curvature liposomes even when the high‐curvature liposomes are protein‐free. Phosphorylation of the curvature‐sensing amphipathic lipid‐packing sensor (ALPS) motif from the Vps41p HOPS subunit abrogates tethering of high‐curvature liposomes. A HOPS complex without its Vps39p subunit, which contains one of the Ypt7p binding sites in HOPS, lacks tethering activity, though it binds high‐curvature liposomes and Ypt7p‐bearing low‐curvature liposomes. Thus, HOPS tethers highly curved membranes via a direct protein–membrane interaction. Such high‐curvature membranes are found at the sites of vacuole tethering and fusion. There, vacuole membranes bend sharply, generating large areas of vacuole‐vacuole contact. We propose that HOPS localizes via the Vps41p ALPS motif to these high‐curvature regions. There, HOPS binds via Vps39p to Ypt7p in an apposed vacuole membrane.      

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 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.     

Phosphorylation of the effector complex HOPS by the vacuolar kinase Yck3p confers Rab nucleotide specificity for vacuole docking and fusion

The homotypic fusion of yeast vacuoles requires the Rab-family GTPase Ypt7p and its effector complex, homotypic fusion and vacuole protein sorting complex (HOPS). Although the vacuolar kinase Yck3p is required for the sensitivity of vacuole fusion to proteins that regulate the Rab GTPase cycle-Gdi1p (GDP-dissociation inhibitor [GDI]) or Gyp1p/Gyp7p (GTPase-activating protein)-this kinase phosphorylates HOPS rather than Ypt7p. We addressed this puzzle in reconstituted proteoliposome fusion reactions with all-purified components. In the presence of HOPS and Sec17p/Sec18p, there is comparable fusion of 4-SNARE (soluble N-ethylmaleimide-sensitive factor attachment protein receptor) proteoliposomes when they have Ypt7p bearing either GDP or GTP, a striking exception to the rule that only GTP-bound forms of Ras-superfamily GTPases have active conformations. However, the phosphorylation of HOPS by recombinant Yck3p confers a strict requirement for GTP-bound Ypt7p for binding phosphorylated HOPS, for optimal membrane tethering, and for proteoliposome fusion. Added GTPase-activating protein promotes GTP hydrolysis by Ypt7p, and added GDI captures Ypt7p in its GDP-bound state during nucleotide cycling. In either case, the net conversion of Ypt7:GTP to Ypt7:GDP has no effect on HOPS binding or activity but blocks fusion mediated by phosphorylated HOPS. Thus guanine nucleotide specificity of the vacuolar fusion Rab Ypt7p is conferred through downstream posttranslational modification of its effector complex.     

Fusion Proteins and Select Lipids Cooperate as Membrane Receptors for the Soluble N-Ethylmaleimide-sensitive Factor Attachment Protein Receptor (SNARE) Vam7p

Vam7p, the vacuolar soluble Q_c-SNARE, is essential for yeast vacuole fusion. The large tethering complex, homotypic fusion and vacuole protein sorting complex (HOPS), and phosphoinositides, which interact with the Vam7p PX domain, have each been proposed to serve as its membrane receptors. Studies with the isolated organelle cannot determine whether these receptor elements suffice and whether ligands or mutations act directly or indirectly on Vam7p binding to the membrane. Using pure components that are active in reconstituted vacuolar fusion, we now find that Vam7p binds to membranes through its combined affinities for several vacuolar membrane constituents: HOPS, phosphatidylinositol 3-phosphate, SNAREs, and acidic phospholipids. Acidic lipids allow low concentrations of Vam7p to suffice for fusion; without acidic lipids, the block to fusion is partially bypassed by high concentrations of Vam7p.     

Efficient termination of vacuolar Rab GTPase signaling requires coordinated action by a GAP and a protein kinase

Rab guanosine triphosphatases (GTPases) are pivotal regulators of membrane identity and dynamics, but the in vivo pathways that control Rab signaling are poorly defined. Here, we show that the GTPase-activating protein Gyp7 inactivates the yeast vacuole Rab Ypt7 in vivo. To efficiently terminate Ypt7 signaling, Gyp7 requires downstream assistance from an inhibitory casein kinase I, Yck3. Yck3 mediates phosphorylation of at least two Ypt7 signaling targets: a tether, the Vps-C/homotypic fusion and vacuole protein sorting (HOPS) subunit Vps41, and a SNARE, Vam3. Phosphorylation of both substrates is opposed by Ypt7-guanosine triphosphate (GTP). We further demonstrate that Ypt7 binds not one but two Vps-C/HOPS subunits: Vps39, a putative Ypt7 nucleotide exchange factor, and Vps41. Gyp7-stimulated GTP hydrolysis on Ypt7 therefore appears to trigger both passive termination of Ypt7 signaling and active kinase-mediated inhibition of Ypt7's downstream targets. We propose that signal propagation through the Ypt7 pathway is controlled by integrated feedback and feed-forward loops. In this model, Yck3 enforces a requirement for the activated Rab in docking and fusion.