COPII coat assembly and selective export from the endoplasmic reticulum

The coat protein complex II (COPII) generates transport vesicles that mediate protein transport from the endoplasmic reticulum (ER). Recent structural and biochemical studies have suggested that the COPII coat is responsible for direct capture of membrane cargo proteins and for the physical deformation of the ER membrane that drives the transport vesicle formation. The COPII-coated vesicle formation at the ER membrane is triggered by the activation of the Ras-like small GTPase Sar1 by GDP/GTP exchange, and activated Sar1 in turn promotes COPII coat assembly. Subsequent GTP hydrolysis by Sar1 leads to disassembly of the coat proteins, which are then recycled for additional rounds of vesicle formation. Thus, the Sar1 GTPase cycle is thought to regulate COPII coat assembly and disassembly. Emerging evidence suggests that the cargo proteins modulate the Sar1 GTP hydrolysis to coordinate coat assembly with cargo selection. Here, I discuss the possible roles of the GTP hydrolysis by Sar1 in COPII coat assembly and selective uptake of cargo proteins into transport vesicles.     

Structures and mechanisms of vesicle coat components and multisubunit tethering complexes

Eukaryotic cells face a logistical challenge in ensuring prompt and precise delivery of vesicular cargo to specific organelles within the cell. Coat protein complexes select cargo and initiate vesicle formation, while multisubunit tethering complexes participate in the delivery of vesicles to target membranes. Understanding these macromolecular assemblies has greatly benefited from their structural characterization. Recent structural data highlight principles in coat recruitment and uncoating in both the endocytic and retrograde pathways, and studies on the architecture of tethering complexes provide a framework for how they might link vesicles to the respective acceptor compartments and the fusion machinery.     

ARFGAP1 promotes the formation of COPI vesicles,suggesting function as a component of the coat

The role of GTPase-activating protein (GAP) that deactivates ADP-ribosylation factor 1 (ARF1) during the formation of coat protein I (COPI) vesicles has been unclear. GAP is originally thought to antagonize vesicle formation by triggering uncoating, but later studies suggest that GAP promotes cargo sorting, a process that occurs during vesicle formation. Recent models have attempted to reconcile these seemingly contradictory roles by suggesting that cargo proteins suppress GAP activity during vesicle formation, but whether GAP truly antagonizes coat recruitment in this process has not been assessed directly. We have reconstituted the formation of COPI vesicles by incubating Golgi membrane with purified soluble components, and find that ARFGAP1 in the presence of GTP promotes vesicle formation and cargo sorting. Moreover, the presence of GTPgammaS not only blocks vesicle uncoating but also vesicle formation by preventing the proper recruitment of GAP to nascent vesicles. Elucidating how GAP functions in vesicle formation, we find that the level of GAP on the reconstituted vesicles is at least as abundant as COPI and that GAP binds directly to the dilysine motif of cargo proteins. Collectively, these findings suggest that ARFGAP1 promotes vesicle formation by functioning as a component of the COPI coat.     

Probing intracellular vesicle trafficking and membrane remodelling by cryo-EM

Protein transport between the membranous compartments of the eukaryotic cells is mediated by the constant fission and fusion of the membrane-bounded vesicles from a donor to an acceptor membrane. While there are many membrane remodelling complexes in eukaryotes, COPII, COPI, and clathrin-coated vesicles are the three principal classes of coat protein complexes that participate in vesicle trafficking in the endocytic and secretory pathways. These vesicle-coat proteins perform two key functions: deforming lipid bilayers into vesicles and encasing selective cargoes. The three trafficking complexes share some commonalities in their structural features but differ in their coat structures, mechanisms of cargo sorting, vesicle formation, and scission. While the structures of many of the proteins involved in vesicle formation have been determined in isolation by X-ray crystallography, elucidating the proteins' structures together with the membrane is better suited for cryogenic electron microscopy (cryo-EM). In recent years, advances in cryo-EM have led to solving the structures and mechanisms of several vesicle trafficking complexes and associated proteins.     

Cargo selection in vesicular transport: the making and breaking of a coat

Intracellular traffic is mediated by vesicular/tubular carriers. The carriers are formed by the activity of cytosolic coat proteins that are recruited to their target membranes and deform these membranes into buds and vesicles. Specific interactions between recruited coat subunits and short peptide sequences (transport motifs) on cargo proteins direct the incorporation of cargo into budded vesicles. Here, we focus on cargo selection reactions mediated by COPII and AP-2/clathrin vesicle coat complexes to explore common mechanisms by which coat assembly support localized and selective cargo sorting. Recent findings suggest that multiple, low-affinity interactions are employed in a cooperative manner to support coat assembly and enable cargo recognition. Thus low-binding affinities between coat subunits and transport motifs are transiently transformed into high-avidity, multivalent and selective interactions at vesicle bud sites. The temporal and regulated nature of the interactions provide the key to cargo selection.     

COPI budding within the Golgi stack

The Golgi serves as a hub for intracellular membrane traffic in the eukaryotic cell. Transport within the early secretory pathway, that is within the Golgi and from the Golgi to the endoplasmic reticulum, is mediated by COPI-coated vesicles. The COPI coat shares structural features with the clathrin coat, but differs in the mechanisms of cargo sorting and vesicle formation. The small GTPase Arf1 initiates coating on activation and recruits en bloc the stable heptameric protein complex coatomer that resembles the inner and the outer shells of clathrin-coated vesicles. Different binding sites exist in coatomer for membrane machinery and for the sorting of various classes of cargo proteins. During the budding of a COPI vesicle, lipids are sorted to give a liquid-disordered phase composition. For the release of a COPI-coated vesicle, coatomer and Arf cooperate to mediate membrane separation.     

Conformational changes of coat proteins during vesicle formation

In coated vesicle formation, coat protein recruitment needs to be spatially and temporally controlled. The coating process involves conformational changes of the coat protein complexes that activate them for interaction with cargo or machinery components and coat polymerization. Here we discuss mechanisms that have emerged recently from studies of the clathrin adaptor and the COPI systems.     

Emergent properties of proteostasis-COPII coupled systems in human health and disease

In eukaryotic membrane trafficking, emergent protein folding pathways dictated by the proteostasis network (the 'PN') in each cell type are linked to the coat protein complex II (COPII) system that initiates transport through the exocytic pathway. These coupled pathways direct the transit of protein cargo from the endoplasmic reticulum (ER) to diverse subcellular and extracellular destinations. Understanding how the COPII system selectively manages the trafficking of distinct folded states of nascent cargo (comprising one-third of the proteins synthesized by the eukaryotic genome) in close cooperation with the PN remains a formidable challenge to the field. Whereas the PN may contain a thousand component, the minimal COPII coat components that drive all vesicle budding from the ER include Sar1 (a GTPase), Sec12 (a guanine nucleotide exchange factor), Sec23-Sec24 complexes (protein cargo selectors) and the Sec13-Sec31 complex (that functions as a protein cargo collector and as a polymeric lattice generator to promote vesicle budding). A wealth of data suggests a hierarchical role of the PN and COPII components in coupling protein folding with recruitment and assembly of vesicle coats on the ER. In this minireview, we focus on insights recently gained from the study of inherited human disease states of the COPII machinery. We explore the relevance of the COPII system to human biology in the context of its inherent link with the remarkably flexible folding capacity of the PN in each cell type and in response to the environment. The pharmacological manipulation of this coupled system has important therapeutic implications for restoration of function in human disease.     

真核细胞内膜泡运输的分子机制

真核细胞内一些蛋白质需靠膜泡进行定向运输,膜泡是在外衣蛋白的作用下形成的,根据外衣蛋白的不同,膜泡分为笼蛋白,COPⅠ和COPⅡ外衣膜泡,这些外衣膜泡分别在细胞内不同供膜（donor membrane)处形成,因为被运输蛋白具有分选信号可与供膜上相应的受体结合,所以能被包裹在特异的膜泡之中,在膜泡形成过程中,外衣蛋白在“芽生”膜泡的细胞质侧组装成笼状外衣,帮助“芽生”膜泡从供膜处脱落,一旦笼状外衣膜泡脱离供膜,笼状外衣蛋白便发生解聚而成为无衣膜泡,无衣膜泡在Rab蛋白的调控下可定向运输蛋白质,而解聚后的外衣蛋白可重新介导新的外衣膜泡形成。     

Coordination of COPII vesicle trafficking by Sec23

Coat protein complex II (COPII) is a multi-subunit protein complex responsible for the formation of membrane vesicles at the endoplasmic reticulum. The assembly of this complex on the endoplasmic reticulum membrane needs to be tightly regulated to ensure efficient and specific incorporation of cargo proteins into nascent vesicles. Recent studies of a genetic disease affecting COPII function, and a structural analysis of COPII subunit interactions emphasize the central role of the Sec23 subunit in COPII coat assembly. Similarly, the demonstration that Sec23 interacts physically and functionally with proteins involved in both vesicle tethering and the transport along microtubules indicates that the Sec23 subunit is crucially important in linking COPII vesicle formation to anterograde transport events.     

The interplay between clathrin-coated vesicles and cell signalling

Internalization of cargo proteins and lipids at the cell surface occurs in both a constitutive and signal-regulated manner through clathrin-mediated and other endocytic pathways. Clathrin-coated vesicle formation is a principal uptake route in response to signalling events. Protein-lipid and protein-protein interactions control both the targeting of signalling molecules and their binding partners to membrane compartments and the assembly of clathrin coats. An emerging aspect of membrane trafficking research is now addressing how signalling cascades and vesicle coat assembly and subsequently disassembly are integrated.     

Coats, tethers, Rabs, and SNAREs work together to mediate the intracellular destination of a transport vesicle

Tethering factors have been shown to interact with Rabs and SNAREs and, more recently, with coat proteins. Coat proteins are required for cargo selection and membrane deformation to bud a transport vesicle from a donor compartment. It was once thought that a vesicle must uncoat before it recognizes its target membrane. However, recent findings have revealed a role for the coat in directing a vesicle to its correct intracellular destination. In this review we will discuss the literature that links coat proteins to vesicle targeting events.     

Mechanisms of COPII vesicle formation and protein sorting

The evolutionarily conserved coat protein complex II (COPII) generates transport vesicles that mediate protein transport from the endoplasmic reticulum (ER). COPII coat is responsible for direct capture of cargo proteins and for the physical deformation of the ER membrane that drives the COPII vesicle formation. In addition to coat proteins, recent data have indicated that the Ras-like small GTPase Sar1 plays multiple roles, such as COPII coat recruitment, cargo sorting, and completion of the final fission. In the present review, we summarize current knowledge of COPII-mediated vesicle formation from the ER, as well as highlighting non-canonical roles of COPII components.     

Mise en place-this bud's for the Golgi

Selective cargo export from the endoplasmic reticulum is brought about by the budding of COPII vesicles. While the main structural components of the COPII coat have been identified and characterized, the regulatory event(s) promoting COPII vesicle biogenesis and cargo selection still remains largely unknown. New data by Glick and colleagues suggest that Sec12 and COPII function may be downstream of important early events coordinated by transitional ER (tER) exit sites.     

Structural basis for cargo regulation of COPII coat assembly

Using cryo-electron microscopy, we have solved the structure of an icosidodecahedral COPII coat involved in cargo export from the endoplasmic reticulum (ER) coassembled from purified cargo adaptor Sec23-24 and Sec13-31 lattice-forming complexes. The coat structure shows a tetrameric assembly of the Sec23-24 adaptor layer that is well positioned beneath the vertices and edges of the Sec13-31 lattice. Fitting the known crystal structures of the COPII proteins into the density map reveals a flexible hinge region stemming from interactions between WD40 beta-propeller domains present in Sec13 and Sec31 at the vertices. The structure shows that the hinge region can direct geometric cage expansion to accommodate a wide range of bulky cargo, including procollagen and chylomicrons, that is sensitive to adaptor function in inherited disease. The COPII coat structure leads us to propose a mechanism by which cargo drives cage assembly and membrane curvature for budding from the ER.     

Regulation of the clathrin-coated vesicle cycle by reversible phosphorylation

Reversible phosphorylation has long been an attractive mechanism to control cycles of coat assembly and disassembly during clathrin-mediated endocytosis. Many of the coat proteins are phosphorylated in vivo and in vitro. Our work has focused on the role of phosphorylation of the mu2 subunit of AP-2 (adaptor protein 2), which appears to be necessary for efficient cargo recruitment. Studies to probe the regulation of mu2 phosphorylation demonstrated that clathrin is a specific activator of the mu2 kinase, and, in permeabilized cells, cargo sequestration, driven by exogenously added clathrin, results in elevated levels of m2 phosphorylation. Furthermore, phosphorylated mu2 is mainly associated with assembled clathrin in vivo and its steady-state level is strongly reduced in cells depleted of clathrin heavy chain. Our results imply a central role for clathrin in the regulation of cargo selection via modulation of phospho-mu2 levels. This is therefore a novel regulatory role for clathrin that is independent of its structural role and that provides elegant spatial control of AP-2 and cargo interactions, ensuring that AP-2 is only activated at the correct cellular location and in the correct functional context. Ongoing studies are exploring further the roles of reversible phosphorylation in the coated vesicle cycle.     

Sed4p stimulates Sar1p GTP hydrolysis and promotes limited coat disassembly

The coat protein complex II (COPII) generates transport vesicles that mediate protein export from the endoplasmic reticulum (ER). The first step of COPII vesicle formation involves conversion of Sar1p-GDP to Sar1p-GTP by guanine-nucleotide-exchange factor (GEF) Sec12p. In Saccharomyces cerevisiae, Sed4p is a structural homolog of Sec12p, but no GEF activity toward Sar1p has been found. Although the role of Sed4p in COPII vesicle formation is implied by the genetic interaction with SAR1, the molecular basis by which Sed4p contributes to this process is unclear. This study showed that the cytoplasmic domain of Sed4p preferentially binds the nucleotide-free form of Sar1p and that Sed4p binding stimulates both the intrinsic and Sec23p GTPase-activating protein (GAP)-accelerated GTPase activity of Sar1p. This stimulation of Sec23p GAP activity by Sed4p leads to accelerated dissociation of coat proteins from membranes. However, Sed4p binding to Sar1p occurs only when cargo is not associated with Sar1p. On the basis of these findings, Sed4p appears to accelerate the dissociation of the Sec23/24p coat from the membrane, but the effect is limited to Sar1p molecules that do not capture cargo protein. We speculate that this restricted coat disassembly may contribute to the concentration of specific cargo molecules into the COPII vesicles.     

A structural view of the COPII vesicle coat

The COPII vesicle coat coordinates the budding of transport vesicles from the endoplasmic reticulum in the initial step of the secretory pathway. The coat orchestrates a sequence of events including self-assembly on the membrane, cargo and SNARE molecule selection, and deformation of the membrane into a bud to drive vesicle fission. Recent molecular-level studies have helped to explain how the three components of yeast COPII - Sar1 GTPase, the Sec23/24 subcomplex and the Sec13/31 subcomplex - combine to organize this complex process.     

New Insights into the Structural Mechanisms of the COPII Coat

In eukaryotes, coat protein complex II (COPII) proteins are involved in transporting cargo proteins from the endoplasmic reticulum (ER) to the Golgi apparatus. The COPII proteins, Sar1, Sec23/24, and Sec13/31 polymerize into a coat that gathers cargo proteins into a coated vesicle. Structures have been recently solved of individual COPII proteins, COPII proteins in complex with cargo, and higher‐order COPII coat assemblies. In this review, we will summarize the latest developments in COPII structure and discuss how these structures shed light on the functional mechanisms of the COPII coat.     

Molecular mechanism and physiological functions of clathrin-mediated endocytosis

Clathrin-mediated endocytosis is the endocytic portal into cells through which cargo is packaged into vesicles with the aid of a clathrin coat. It is fundamental to neurotransmission, signal transduction and the regulation of many plasma membrane activities and is thus essential to higher eukaryotic life. Morphological stages of vesicle formation are mirrored by progression through various protein modules (complexes). The process involves the formation of a putative FCH domain only (FCHO) initiation complex, which matures through adaptor protein 2 (AP2)-dependent cargo selection, and subsequent coat building, dynamin-mediated scission and finally auxilin- and heat shock cognate 70 (HSC70)-dependent uncoating. Some modules can be used in other pathways, and additions or substitutions confer cell specificity and adaptability.