Sec35p, a novel peripheral membrane protein, is required for ER to Golgi vesicle docking

Membrane transport: tethers and TRAPPs

Transport vesicles are tethered to their target membrane prior to the interaction of v-SNAREs and t-SNAREs across the membrane junction. Recent evidence suggests tethering is a complex process requiring multiple components.

Protein complexes in transport vesicle targeting

The transport of material between membrane-bounded organelles in eukaryotic cells requires the accurate delivery of different classes of carrier vesicles to specific target compartments. Recent studies indicate that different targeting reactions involve distinct protein complexes that act to mark the target organelle for incoming vesicles. This review focuses on the proteins and protein complexes that have been implicated in various targeting reactions.

TRAPP stably associates with the Golgi and is required for vesicle docking

Bet3p, a component of a large novel complex called TRAPP, acts upstream of endoplasmic reticulum (ER)-Golgi SNAREs. Unlike the SNAREs, which reside on multiple compartments, Bet3p is localized exclusively to Golgi membranes. While other proteins recycle from the Golgi to the ER, Bet3p and other TRAPP subunits remain associated with this membrane under conditions that block anterograde traffic. We propose that the persistent localization of TRAPP to the Golgi may be important for its role in docking vesicles to this membrane. Consistent with this proposal, we find that transport vesicles fail to bind to Golgi membranes in vitro in the absence of Bet3p. Binding is restored by the addition of cytosol containing Bet3p. These findings indicate that TRAPP stably associates with the Golgi and is required for vesicle docking.

Identification and characterization of five new subunits of TRAPP

TRAPP (transport protein particle), a multiprotein complex containing ten subunits, plays a key role in the late stages of endoplasmic reticulum to Golgi traffic in the yeast Saccharomyces cerevisiae. We previously described the identification of five TRAPP subunits (Bet5p, Trs20p, Bet3p, Trs23p and Trs33p). Now we report the identification of the remaining five subunits (Trs31p, Trs65p, Trs85p, Trs120p and Trs130p) as well as an initial characterization of the yeast complex and its human homologue. We find that three of the subunits are dispensable for growth and a novel sequence motif is found in Bet3p, Trs31p and Trs33p. Furthermore, biochemical characterization of both yeast and human TRAPP suggests that this complex is anchored to a Triton X-100 resistant fraction of the Golgi. Differences between yeast and human TRAPP as well as the relationship of TRAPP subunits to other docking/tethering factors are discussed.

The amino-terminal domain of the golgi protein giantin interacts directly with the vesicle-tethering protein p115

Giantin is thought to form a complex with p115 and Golgi matrix protein 130, which is involved in the reassembly of Golgi cisternae and stacks at the end of mitosis. The complex is involved in the tethering of coat protomer I vesicles to Golgi membranes and the initial stacking of reforming cisternae. Here we show that the NH(2)-terminal 15% of Giantin suffices to bind p115 in vitro and in vivo and to block cell-free Golgi reassembly. Because Giantin is a long, rod-like protein anchored to the membrane by its extreme COOH terminus, these results support the idea of a long, flexible tether linking vesicles and cisternae.

Yeast Golgi SNARE interactions are promiscuous

The transport of proteins between various compartments of the secretory pathway occurs by the budding of vesicles from one membrane and their fusion with another. A key event in this process is the selective recognition of the target membrane by the vesicle and the current view is that SNARE protein interactions likely play a central role in vesicle-target recognition and or membrane fusion. In yeast, only a single syntaxin (Sed5p) is required for Golgi transport and Sed5p is known to bind to at least 7 SNARE proteins. However, the number of Sed5p-containing SNARE complexes that exist in cells is not known. In this study we examined direct pair-wise interactions between full length soluble recombinant forms of SNAREs (Sed5p, Sft1p, Ykt6p, Vti1p, Gos1p, Sec22p, Bos1p, and Bet1p) involved in ER-Golgi and intra-Golgi membrane trafficking. In the binding assay that we describe here the majority of SNARE-binary interactions tested were positive, indicating that SNARE-SNARE interactions although promiscuous are not entirely non-selective. Interactions between a number of the genes encoding these SNAREs are consistent with our binding data and taken together our results suggest that functionally redundant Golgi SNARE-complexes exist in yeast. In particular, over-expression of Bet1p (a SNARE required for ER-Golgi and Golgi-ER traffic) and can bypass the requirement for the otherwise essential SNARE Sft1p (required for intra-Golgi traffic), suggesting that Bet1p either functions in a parallel pathway with Sft1p or can be incorporated into SNARE-complexes in place of Sftp1. None-the-less this result suggests that Bet1p can participate in two distinct trafficking steps, cycling between the ER and Golgi as well as in retrograde intra-Golgi traffic. In addition, suppressor genetics together with the analysis of the phenotypes of conditional mutations in Sft1p and Ykt6p, are consistent with a role for these SNAREs in more than one trafficking step. We propose that different combinations of SNAREs form complexes with Sed5p and are required for multiple steps in ER-Golgi and intra-Golgi vesicular traffic. And that the apparent promiscuity of SNARE-SNARE binding interactions, together with the requirement for some SNAREs in more than one trafficking step, supports the view that the specificity of vesicle fusion events cannot be explained solely on the basis of SNARE-SNARE interactions.

Vps52p, Vps53p, and Vps54p form a novel multisubunit complex required for protein sorting at the yeast late Golgi

The late Golgi of the yeast Saccharomyces cerevisiae receives membrane traffic from the secretory pathway as well as retrograde traffic from post-Golgi compartments, but the machinery that regulates these vesicle-docking and fusion events has not been characterized. We have identified three components of a novel protein complex that is required for protein sorting at the yeast late Golgi compartment. Mutation of VPS52, VPS53, or VPS54 results in the missorting of 70% of the vacuolar hydrolase carboxypeptidase Y as well as the mislocalization of late Golgi membrane proteins to the vacuole, whereas protein traffic through the early part of the Golgi complex is unaffected. A vps52/53/54 triple mutant strain is phenotypically indistinguishable from each of the single mutants, consistent with the model that all three are required for a common step in membrane transport. Native coimmunoprecipitation experiments indicate that Vps52p, Vps53p, and Vps54p are associated in a 1:1:1 complex that sediments as a single peak on sucrose velocity gradients. This complex, which exists both in a soluble pool and as a peripheral component of a membrane fraction, colocalizes with markers of the yeast late Golgi by immunofluorescence microscopy. Together, the phenotypic and biochemical data suggest that VPS52, VPS53, and VPS54 are required for the retrograde transport of Golgi membrane proteins from an endosomal/prevacuolar compartment. The Vps52/53/54 complex joins a growing list of distinct multisubunit complexes that regulate membrane-trafficking events.

Munc18c function is required for insulin-stimulated plasma membrane fusion of GLUT4 and insulin-responsive amino peptidase storage vesicles

To examine the functional role of the interaction between Munc18c and syntaxin 4 in the regulation of GLUT4 translocation in 3T3L1 adipocytes, we assessed the effects of introducing three different peptide fragments (20 to 24 amino acids) of Munc18c from evolutionarily conserved regions of the Sec1 protein family predicted to be solvent exposed. One peptide, termed 18c/pep3, inhibited the binding of full-length Munc18c to syntaxin 4, whereas expression of the other two peptides had no effect. In parallel, microinjection of 18c/pep3 but not a control peptide inhibited the insulin-stimulated translocation of endogenous GLUT4 and insulin-responsive amino peptidase (IRAP) to the plasma membrane. In addition, expression of 18c/pep3 prevented the insulin-stimulated fusion of endogenous and enhanced green fluorescent protein epitope-tagged GLUT4- and IRAP-containing vesicles into the plasma membrane, as assessed by intact cell immunofluorescence. However, unlike the pattern of inhibition seen with full-length Munc18c expression, cells expressing 18c/pep3 displayed discrete clusters of GLUT4 abd IRAP storage vesicles at the cell surface which were not contiguous with the plasma membrane. Together, these data suggest that the interaction between Munc18c and syntaxin 4 is required for the integration of GLUT4 and IRAP storage vesicles into the plasma membrane but is not necessary for the insulin-stimulated trafficking to and association with the cell surface.

Sec34p, a protein required for vesicle tethering to the yeast Golgi apparatus, is in a complex with Sec35p

A screen for mutants of Saccharomyces cerevisiae secretory pathway components previously yielded sec34, a mutant that accumulates numerous vesicles and fails to transport proteins from the ER to the Golgi complex at the restrictive temperature (Wuestehube, L.J., R. Duden, A. Eun, S. Hamamoto, P. Korn, R. Ram, and R. Schekman. 1996. Genetics. 142:393-406). We find that SEC34 encodes a novel protein of 93-kD, peripherally associated with membranes. The temperature-sensitive phenotype of sec34-2 is suppressed by the rab GTPase Ypt1p that functions early in the secretory pathway, or by the dominant form of the ER to Golgi complex target-SNARE (soluble N-ethylmaleimide sensitive fusion protein attachment protein receptor)-associated protein Sly1p, Sly1-20p. Weaker suppression is evident upon overexpression of genes encoding the vesicle tethering factor Uso1p or the vesicle-SNAREs Sec22p, Bet1p, or Ykt6p. This genetic suppression profile is similar to that of sec35-1, a mutant allele of a gene encoding an ER to Golgi vesicle tethering factor and, like Sec35p, Sec34p is required in vitro for vesicle tethering. sec34-2 and sec35-1 display a synthetic lethal interaction, a genetic result explained by the finding that Sec34p and Sec35p can interact by two-hybrid analysis. Fractionation of yeast cytosol indicates that Sec34p and Sec35p exist in an approximately 750-kD protein complex. Finally, we describe RUD3, a novel gene identified through a genetic screen for multicopy suppressors of a mutation in USO1, which suppresses the sec34-2 mutation as well.

High-copy suppressor analysis reveals a physical interaction between Sec34p and Sec35p, a protein implicated in vesicle docking

A temperature-sensitive mutant, sec34-2, is defective in the late stages of endoplasmic reticulum (ER)-to-Golgi transport. A high-copy suppressor screen that uses the sec34-2 mutant has resulted in the identification of the SEC34 structural gene and a novel gene called GRP1. GRP1 encodes a previously unidentified hydrophilic yeast protein related to the mammalian Golgi protein golgin-160. Although GRP1 is not essential for growth, the grp1Delta mutation displays synthetic lethal interactions with several mutations that result in ER accumulation and a block in the late stages of ER-to-Golgi transport, but not with those that block the budding of vesicles from the ER. Our findings suggest that Grp1p may facilitate membrane traffic indirectly, possibly by maintaining Golgi function. In an effort to identify genes whose products physically interact with Sec34p, we also tested the ability of overexpressed SEC34 to suppress known secretory mutations that block vesicular traffic between the ER and the Golgi. This screen revealed that SEC34 specifically suppresses sec35-1. SEC34 encodes a hydrophilic protein of approximately 100 kDa. Like Sec35p, which has been implicated in the tethering of ER-derived vesicles to the Golgi, Sec34p is predominantly soluble. Sec34p and Sec35p stably associate with each other to form a multiprotein complex of approximately 480 kDa. These data indicate that Sec34p acts in conjunction with Sec35p to mediate a common step in vesicular traffic.

Oligomeric complexes link Rab5 effectors with NSF and drive membrane fusion via interactions between EEA1 and syntaxin 13

SNAREs and Rab GTPases cooperate in vesicle transport through a mechanism yet poorly understood. We now demonstrate that the Rab5 effectors EEA1 and Rabaptin-5/Rabex-5 exist on the membrane in high molecular weight oligomers, which also contain NSF. Oligomeric assembly is modulated by the ATPase activity of NSF. Syntaxin 13, the t-SNARE required for endosome fusion, is transiently incorporated into the large oligomers via direct interactions with EEA1. This interaction is required to drive fusion, since both dominant-negative EEA1 and synthetic peptides encoding the FYVE Zn2+ finger hinder the interaction and block fusion. We propose a novel mechanism whereby oligomeric EEA1 and NSF mediate the local activation of syntaxin 13 upon membrane tethering and, by analogy with viral fusion proteins, coordinate the assembly of a fusion pore.

Membrane tethering in intracellular transport

Studies of various membrane trafficking steps over the past year indicate that membranes are tethered together prior to the interaction of v-SNAREs and t-SNAREs across the membrane junction. The tethering proteins identified to date are quite large, being either fibrous proteins or multimeric protein complexes. The tethering factors employed at different steps are evolutionarily unrelated, yet their function seems to be closely tied to the more highly conserved Rab GTPases. Tethering factors may collaborate with Rabs and SNAREs to generate targeting specificity in the secretory pathway.

Transport-vesicle targeting: tethers before SNAREs

Protein secretion and the transport of proteins between membrane-bound compartments are mediated by small, membrane-bound vesicles. Here I review what is known about the process by which vesicles are targeted to the correct destination. A growing family of proteins, whose precise modes of action are far from established, is involved in targeting. Despite the wide diversity in the identities of the players, some common themes are emerging that may explain how vesicles can identify their targets and release their cargo at the correct time and place in eukaryotic cells.

The Rab5 effector EEA1 is a core component of endosome docking

Intracellular membrane docking and fusion requires the interplay between soluble factors and SNAREs. The SNARE hypothesis postulates that pairing between a vesicular v-SNARE and a target membrane z-SNARE is the primary molecular interaction underlying the specificity of vesicle targeting as well as lipid bilayer fusion. This proposal is supported by recent studies using a minimal artificial system. However, several observations demonstrate that SNAREs function at multiple transport steps and can pair promiscuously, questioning the role of SNAREs in conveying vesicle targeting. Moreover, other proteins have been shown to be important in membrane docking or tethering. Therefore, if the minimal machinery is defined as the set of proteins sufficient to reproduce in vitro the fidelity of vesicle targeting, docking and fusion as in vivo, then SNAREs are not sufficient to specify vesicle targeting. Endosome fusion also requires cytosolic factors and is regulated by the small GTPase Rab5. Here we show that Rab5-interacting soluble proteins can completely substitute for cytosol in an in vivo endosome-fusion assay, and that the Rab5 effector EEA1 is the only factor necessary to confer minimal fusion activity. Rab5 and other associated proteins seem to act upstream of EEA1, implying that Rab5 effectors comprise both regulatory molecules and mechanical components of the membrane transport machinery. We further show that EEA1 mediates endosome docking and, together with SNAREs, leads to membrane fusion.

Characterization of the sequence and expression of a Ykt6 prenylated SNARE from rat

The Ykt6 protein represents a novel soluble N-ethylmaleimide-sensitive fusion protein receptor (SNARE), as it is the only one known without a hydrophobic transmembrane region at the carboxy terminus. For this SNARE, however, membrane interaction is thought to be mediated through a cysteine/aliphatic/aliphatic/methionine or histidine (CAAX) C-terminal motif, a consensus sequence involved in prenylated membrane anchoring. To date, two full-length Ykt6 cDNAs have been reported, these being in yeast and human, with a further protein predicted from a Caenorhabditis elegans cosmid. Using a mouse EST clone identified as having 65% homology with the human Ykt6, we isolated a cDNA clone encoding the rat Ykt6 homolog (rYkt6). Sequence analysis of rYkt6 demonstrated that a high level of species conservation exists between the rat and human prenylated SNAREs, as both the nucleotide and amino acid sequences share >90% homology. Mammalian Ykt6 is shown here for the first time to be constitutively expressed in a variety of tissues. The species conservation and ubiquitous expression of prenylated SNAREs hence may be indicative of an important and central role for these proteins in cellular protein trafficking.

Tethering molecules in membrane traffic

Membrane transport in eukaryotic cells proceeds through a variety of organelles. Specificity of a given fusion event between two membranes can be regulated at different levels of docking and fusion. This review summarises recent progress that has been made in understanding the molecular links between the core fusion machinery and upstream regulation.

Protein transport from the endoplasmic reticulum to the Golgi apparatus

As the first step of protein transport along the biosynthetic (secretory/exocytotic) pathway, transport from the endoplasmic reticulum (ER) to the Golgi apparatus has received much attention over the past several decades. The general structural organization underlying this transport process is becoming more defined. The major protein components participating in the budding, pre-docking, and docking/fusion events have been identified and their mechanistic aspects investigated. Conceptually, it is now clear that protein export from the ER is a selective process. Although much remains to be defined or refined, the general picture of this transport step has now emerged.