Plant coated vesicles

Abstract. Coated vesicles are organelles frequently encountered in many plant cell types often in association with the plasma membrane, Golgi apparatus, partially coated reticulum and multivesicular bodies. They are readily identified by a characteristic cage or basket composed of interlocking triskelions of the protein clathrin which are bound to the surface of the vesicle membrane. Although their transport function has been well studied and characterized in mammalian systems, the possible importance of coated vesicles as transport organelles in plant cells is only just beginning to be explored. In this review, the authors describe the structure of higher plant coated vesicles and discuss their possible involvement in the endocytosis of marcromolecules, in exocytosis and in the intracellular transport of material between cytoplasmic compartments. Their possible role in maintaining the macromolecular composition of the plasma membrane whilst allowing recycling of excess lipid bilayer and their potential application as vehicles for the introduction of foreign macromolecules into plant cells are discussed.     

Cellular and structural insight into dynamin function during endocytic vesicle formation: a tale of 50 years of investigation

Dynamin is one of the major proteins involved in endocytosis. First identified 50 years ago in a genetic screen in Drosophila melanogaster, it has become a central player in many forms of endocytosis, such as clathrin-mediated endocytosis or synaptic vesicle endocytosis, as well as other important cellular processes such as actin remodelling. Decades of work using biochemical and structural studies, cell-free assays, live cell imaging, acute inhibition and genetic studies have led to important insights on its mode of action. Dynamin is a remarkable mechano-GTPase, which can do a lot to membranes on its own but which is, in cells, at the centre of a vast protein and lipid network and cannot work in isolation. This review summarizes the main features of dynamin structure and function and its central role in membrane remodelling events, and give an update on the latest results.     

Synaptic Vesicle Generation from Central Nerve Terminal Endosomes

Central nerve terminals contain a small number of synaptic vesicles (SVs) that must sustain the fidelity of neurotransmission across a wide range of stimulation intensities. For this to be achieved, nerve terminals integrate a number of complementary endocytosis modes whose activation spans the breadth of these neuronal stimulation patterns. Two such modes are ultrafast endocytosis and activity‐dependent bulk endocytosis, which are triggered by stimuli at either end of the physiological range. Both endocytosis modes generate endosomes directly from the nerve terminal plasma membrane, before the subsequent production of SVs from these structures. This review will discuss the current knowledge relating to the molecular mechanisms involved in the generation of SVs from nerve terminal endosomes, how this relates to other mechanisms of SV production and the functional role of such SVs.      

网格蛋白介导的内吞作用机制

受体介导的内吞作用是目前公认的生物体摄取生物大分子的途径,而网格蛋白介导的内吞又是最主要的受体介导方式.结合国内外最新报道,介绍了网格蛋白和衔接蛋白的结构、分子特性和功能;从衔接蛋白、网格蛋白的招募;包被小凹的内陷、缢缩和包被液泡的芽殖和包被液泡的脱壳等过程,阐释了网格蛋白介导的内吞作用机制.     

Synaptic vesicle recycling: steps and principles

Synaptic vesicle recycling is one of the best‐studied cellular pathways. Many of the proteins involved are known, and their interactions are becoming increasingly clear. However, as for many other pathways, it is still difficult to understand synaptic vesicle recycling as a whole. While it is generally possible to point out how synaptic reactions take place, it is not always easy to understand what triggers or controls them. Also, it is often difficult to understand how the availability of the reaction partners is controlled: how the reaction partners manage to find each other in the right place, at the right time. I present here an overview of synaptic vesicle recycling, discussing the mechanisms that trigger different reactions, and those that ensure the availability of reaction partners. A central argument is that synaptic vesicles bind soluble cofactor proteins, with low affinity, and thus control their availability in the synapse, forming a buffer for cofactor proteins. The availability of cofactor proteins, in turn, regulates the different synaptic reactions. Similar mechanisms, in which one of the reaction partners buffers another, may apply to many other processes, from the biogenesis to the degradation of the synaptic vesicle.     

Coated Vesicles from the Protozoan Parasite Trypanosoma brucei: Purification and Characterization

ABSTRACT. A procedure was developed to purify a coated vesicle fraction from the protozoan parasite Trypanosoma brucei. Electron microscopy revealed a difference between T. brucei coated vesicles and clathrin-coated vesicles from other eukaryotes: trypanosome vesicles were larger (100 to ISO nm in diameter) and contained an inner coat of electron-dense material in addition to the external coat. Evidence suggests that the internal coat is the parasite's variant surface glycoprotein (VSG) coat. The SDS-PAGE analysis shows the major protein of T. brucei coated vesicles has a molecular mass of 61 kD, similar to VSG; this protein was recognized in an immunoblot by anti-VSG serum. Trypanosome coated vesicles also contain a protein which comigrates with the major protein (clathrin) of coated vesicles purified from rat brains. However, this protein is a minor component and it is not serologically cross-reactive with mammalian clathrin. Immunoblot analysis demonstrated that the parasite vesicles contained host IgG, IgM, and serum albumin.     

Limited proteolytic digestion of coated vesicle assembly polypeptides abolishes reassembly activity

We have previously identified a fraction containing several assembly polypeptides (AP) that promotes reassembly of clathrin into vesicle-free coat structures [Zaremba S, Keen JH: J Cell Biol 97:1339, 1983]. The AP are prepared from purified bovine brain-coated vesicles by extraction with 0.5 M TRIS-HCl followed by Sepharose CL-4B column chromatography. Centrifugation in sucrose gradients under nonassembly conditions supports earlier observations suggesting that four active polypeptides in the AP preparation, of Mr approximately 110,000, 100,000, 50,000, and 16,500 are present in a discrete complex that is incorporated as a unit into reassembled coats. The 16,500-dalton polypeptide does not coelectrophorese with authentic bovine brain calmodulin and does not exhibit calmodulin's Ca2+-induced shift in electrophoretic mobility. When the partially purified AP fraction was digested with elastase, the Mr approximately 110,000 and 100,000 polypeptides were rapidly degraded with little or no effect on the Mr approximately 50,000 and 16,500 bands. This treatment abolished the in vitro coat-forming ability of the AP fraction and the loss of activity closely parallels the loss of the Mr approximately 100,000 band. Disappearance of the Mr approximately 110,000 and 100,000 bands is accompanied by the generation of new bands at Mr approximately 76,000 and 65,000. When the elastase-treated AP is examined by sucrose gradient sedimentation in nonassembly buffers, the new bands continue to cosediment with the Mr approximately 50,000 and 16,500 polypeptides. This indicates that the elastase digestion has cleaved off a fragment of the Mr approximately 110,000 and 100,000 bands, leaving behind a truncated, inactive AP complex. A protein kinase activity has been detected in coated vesicle preparations that utilizes the 50,000-dalton AP as its preferred substrate [Keen JH, Zaremba S: J Cell Biol 97:174a, 1983]. Elastase treatment does not abolish this activity, indicating that the kinase by itself is not sufficient for maintaining reassembly activity.     

Synaptic vesicle exocytosis and increased cytosolic calcium are both necessary but not sufficient for activity‐dependent bulk endocytosis

Activity‐dependent bulk endocytosis (ADBE) is the dominant synaptic vesicle (SV) endocytosis mode in central nerve terminals during intense neuronal activity. By definition this mode is triggered by neuronal activity; however, key questions regarding its mechanism of activation remain unaddressed. To determine the basic requirements for ADBE triggering in central nerve terminals, we decoupled SV fusion events from activity‐dependent calcium influx using either clostridial neurotoxins or buffering of intracellular calcium. ADBE was monitored both optically and morphologically by observing uptake of the fluid phase markers tetramethylrhodamine‐dextran and horse radish peroxidase respectively. Ablation of SV fusion with tetanus toxin resulted in the arrest of ADBE, but had no effect on other calcium‐dependent events such as activity‐dependent dynamin I dephosphorylation, indicating that SV exocytosis is necessary for triggering. Furthermore, the calcium chelator EGTA abolished ADBE while leaving SV exocytosis intact, demonstrating that ADBE is triggered by intracellular free calcium increases outside the active zone. Activity‐dependent dynamin I dephosphorylation was also arrested in EGTA‐treated neurons, consistent with its proposed role in triggering ADBE. Thus, SV fusion and increased cytoplasmic free calcium are both necessary but not sufficient individually to trigger ADBE.

     

Imaging single endocytic events reveals diversity in clathrin, dynamin and vesicle dynamics

The dynamics of clathrin-mediated endocytosis can be assayed using fluorescently tagged proteins and total internal reflection fluorescence microscopy. Many of these proteins, including clathrin and dynamin, are soluble and changes in fluorescence intensity can be attributed either to membrane/vesicle movement or to changes in the numbers of individual molecules. It is important for assays to discriminate between physical membrane events and the dynamics of molecules. Two physical events in endocytosis were investigated: vesicle scission from the plasma membrane and vesicle internalization. Single vesicle analysis allowed the characterization of dynamin and clathrin dynamics relative to scission and internalization. We show that vesicles remain proximal to the plasma membrane for variable amounts of time following scission, and that uncoating of clathrin can occur before or after vesicle internalization. The dynamics of dynamin also vary with respect to scission. Results from assays based on physical events suggest that disappearance of fluorescence from the evanescent field should be re-evaluated as an assay for endocytosis. These results illustrate the heterogeneity of behaviors of endocytic vesicles and the importance of establishing suitable evaluation criteria for biophysical processes.     

Influence of buffer ions and divalent cations on coated vesicle disassembly and reassembly

Disruption of the coat of coated vesicles is accompanied by the release of clathrin and other proteins in soluble form. The ability of solubilized coated vesicle proteins to reassemble into empty coats is influenced by Mg²⁺, Tris ion concentration, pH, and ionic strength. The proteins solubilized by 2 M urea spontaneously reassemble into empty coats following dialysis into isolation buffer (0.1 M MES–1 mM EGTA–1 mM MgCl₂–0.02% NaN₃, pH 6.8). Such reassembled coats have sedimentation properties similar to untreated coated vesicles. Clathrin is the predominant protein of reassembled coats; most of the other proteins present in native coated vesicles are absent. We have found that Mg²⁺ is important in the coat assembly reaction. At pH 8 in 0.01 M or 0.1 M Tris, coats dissociate; however, 10 mM MgCl₂ prevents dissociation. If the coats are first dissociated at pH 8 and then the MgCl₂ raised to 10 mM, reassembly occurs. These results suggest that Mg²⁺ stabilizes the coat lattice and promotes reassembly. This hypothesis is supported by our observations that increasing Mg²⁺ (10 μM–10 mM) increases reassembly whereas chelation of Mg²⁺ by (EGTA) inhibits reassembly. Coats reassembled in low-Tris (0.01 M, pH 8) supernatants containing 10 mM MgCl₂ do not sediment, but upon dialysis into isolation buffer (pH 6.8), these coats become sedimentable. Nonsedimentable coats are noted also either when partially purified clathrin (peak I from Sepharose CL4B columns) is dialyzed into low-ionic-strength buffer or when peaks I and II are dialyzed into isolation buffer. Such nonsedimentable coats may represent intermediates in the assembly reaction which have normal morphology but lack some of the physical properties of native coats. We present a model suggesting that tightly intertwined antiparallel clathrin dimers form the edges of the coat lattice.     

Days and knights discussing membrane dynamics in endocytosis: meeting report from the Euresco/EMBL Membrane Dynamics in Endocytosis, 6--11 October in Tomar, Portugal

The Euresco/EMBL sponsored meeting on 'Membrane Dynamics in Endocytosis' took place on 6–11 October in Tomar, Portugal. Here we report on the 5 full days of exciting talks and active poster sessions that covered topics ranging from the mechanisms of clathrin-mediated endocytosis, the regulation of phagocytosis, caveolae dynamics and function, the role of lipids in regulating endocytic transport, the formation of and sorting into and out of multivesicular bodies, new links between the actin cytoskeleton and vesicular transport, and emerging roles for endocytic trafficking in signal transduction and development.     

Acid sensitive background potassium channels K2P3.1 and K2P9.1 undergo rapid dynamin-dependent endocytosis

Acid-sensitive, two-pore domain potassium channels, K_2P3.1 and K_2P9.1, are implicated in cardiac and nervous tissue responses to hormones, neurotransmitters and drugs. K_2P3.1 and K_2P9.1 leak potassium from the cell at rest and directly impact membrane potential. Hence altering channel number on the cell surface drives changes in cellular electrical properties. The rate of K_2P3.1 and K_2P9.1 delivery to and recovery from the plasma membrane determines both channel number at the cell surface and potassium leak from cells. This study examines the endocytosis of K_2P3.1 and K_2P9.1. Plasma membrane biotinylation was used to follow the fate of internalized GFP-tagged rat K_2P3.1 and K_2P9.1 transiently expressed in HeLa cells. Confocal fluorescence images were analyzed using Imaris software, which revealed that both channels are endocytosed by a dynamin-dependent mechanism and over the course of 60 min, move progressively toward the nucleus. Endogenous endocytosis of human K_2P3.1 and K_2P9.1 was examined in the lung carcinoma cell line, A549. Endogenous channels are endocytosed over a similar time-scale to the channels expressed transiently in HeLa cells. These findings both validate the use of recombinant systems and identify an endogenous model system in which K_2P3.1 and K_2P9.1 trafficking can be further studied.     

Unique biochemical and behavioral alterations in drosophilashibirets1 mutants imply a conformational state affecting dynamin subcellular distribution and synaptic vesicle cycling

ABSTRACT Dynamin is a GTPase protein that is essential for clathrin‐mediated endocytosis of synaptic vesicle membranes. The Drosophila dynamin mutation shi^ts1 changes a single residue (G273D) at the boundary of the GTPase domain. In cell fractionation of homogenized fly heads without monovalent cations, all dynamin was in pellet fractions and was minimally susceptible to Triton‐X extraction. Addition of Na⁺ or K⁺ can extract dynamin to the cytosolic (supernatant) fraction. The shi^ts1 mutation reduced the sensitivity of dynamin to salt extraction compared with other temperature‐sensitive alleles or wild type. Sensitivity to salt extraction in shi^ts1 was enhanced by GTP and nonhydrolyzable GTP‐γS. The shi^ts1 mutation may therefore induce a conformational change, involving the GTP binding site, that affects dynamin aggregation. Temperature‐sensitive shibire mutations are known to arrest endocytosis at restrictive temperatures, with concomitant accumulation of presynaptic collared pits. Consistent with an effect upon dynamin aggregation, intact shi^ts1 flies recovered much more slowly from heat‐induced paralysis than did other temperature‐sensitive shibire mutants. Moreover, a genetic mutation that lowers GTP abundance (awd^msf15), which reduces the paralytic temperature threshold of other temperature‐sensitive shibire mutations that lie closer to consensus GTPase motifs, did not reduce the paralytic threshold of shi^ts1. Taken together, the results may link the GTPase domain to conformational shifts that influence aggregation in vitro and endocytosis in vivo, and provide an unexpected point of entry to link the biophysical properties of dynamin to physiological processes at synapses. © 2002 Wiley Periodicals, Inc. J Neurobiol 53: 319–329, 2002     

Comparison of chemical properties of purified plasma membranes and secretory vesicle membranes from the bovine adrenal medulla

Summary A highly enriched fraction of plasma membranes from the bovine adrenal medulla has been isolated by differential and sucrose gradient centrifugation. The membranes were found to occur as 0.1–0.5 diameter vesicles and to equilibrate at a density of 1.13–1.14 g/ml. This fraction was characterized by 4-fold elevated levels of adenylate cyclase and 20-fold elevated levels of 5-nucleotidase. Secretory vesicle membranes, isolated by repeated hypotonie and hypertonic shocks of whole vesicles, were found to equilibrate between d = 1.08 and d = 1.12 on a sucrose density step gradient. These membranes were highly enriched in cytochrome b₅₆₂ and dopamine--hydroxylase. Proteins in the two membranes were compared by SDS gel electrophoresis. All protein size classes found in the vesicle membrane fraction were also represented in the plasma membrane fraction, though in different proportions on the basis of staining intensity. The plasma membrane fraction contained prominent bands co-migrating with the - and -bands of tubulin, as well as a component co-migrating with actin. These bands were absent from the vesicle membranes. Fingerprint analysis of stained bands from the membrane fraction demonstrated that the components were indeed tubulin and actin. The plasma membranes contained twice as much sialic acid residues as did the chromaffin granule membranes, but had only half the cholesterol content on a weight basis. The cholesterolphospholipid ratio in the plasma membranes was 0.63, while in the secretory vesicle membranes it was 1.04. These results show that plasma membranes and secretory vesicle membranes are functionally and structurally different.Supported, in part, by a stipend to O.Z. from The Grant Foundation, New York     

Apical membrane endocytosis via coated pits is stimulated by removal of antidiuretic hormone from isolated,perfused rabbit cortical collecting tubule

Summary Antidiuretic hormone increases the water permeability of the cortical collecting tubule and causes the appearance of intramembrane particle aggregates in the apical plasma membrane of principal cells. Particle aggregates are located in apical membrane coated pits during stimulation of collecting ducts with ADHin situ. Removal of ADH causes a rapid decline in water permeability. We evaluated apical membrane retrieval associated with removal of ADH by studying the endocytosis of horseradish peroxidase (HRP) from an isotonic solution in the lumen. HRP uptake was quantified enzymatically and its intracellular distribution examined by electron microscopy. When tubules were perfused with HRP for 20 min in the absence of ADH, HRP uptake was 0.5±0.3 pg/min/m tubule length (n=6). The uptake of HRP in tubules exposed continuously to ADH during the 20-min HRP perfusion period was 1.3±0.8 pg/min/m (n=8). HPR uptake increased markedly to 3.2±1.1 pg/min/m (n=14), when the 20-min period of perfusion with HRP began immediately after removal of ADH from the peritubular bath. Endocytosis of HRP occurred in both principal and intercalated cells via apical membrane coated pits. We suggest that the rapid decline in cortical collecting duct water permeability which occurs following removal of ADH is mediated by retrieval of water permeable membrane via coated pits.     

The Sla1 adaptor‐clathrin interaction regulates coat formation and progression of endocytosis

Clathrin‐mediated endocytosis is a fundamental transport pathway that depends on numerous protein‐protein interactions. Testing the importance of the adaptor protein‐clathrin interaction for coat formation and progression of endocytosis in vivo has been difficult due to experimental constrains. Here, we addressed this question using the yeast clathrin adaptor Sla1, which is unique in showing a cargo endocytosis defect upon substitution of 3 amino acids in its clathrin‐binding motif (sla1^AAA) that disrupt clathrin binding. Live‐cell imaging showed an impaired Sla1‐clathrin interaction causes reduced clathrin levels but increased Sla1 levels at endocytic sites. Moreover, the rate of Sla1 recruitment was reduced indicating proper dynamics of both clathrin and Sla1 depend on their interaction. sla1^AAA cells showed a delay in progression through the various stages of endocytosis. The Arp2/3‐dependent actin polymerization machinery was present for significantly longer time before actin polymerization ensued, revealing a link between coat formation and activation of actin polymerization. Ultimately, in sla1^AAA cells a larger than normal actin network was formed, dramatically higher levels of various machinery proteins other than clathrin were recruited, and the membrane profile of endocytic invaginations was longer. Thus, the Sla1‐clathrin interaction is important for coat formation, regulation of endocytic progression and membrane bending.      

In vitro, insulin receptor catalyses phosphorylation of clathrin heavy chain and a plasma membrane 180,000 molecular weight protein

Insulin receptor mutation studies that the receptor tyrosine kinase activity is necessary for receptor endocytosis, and several insulin receptor-containing tissues have a plasma membrane-associated protein (M_r 180,000, p180) whose tyrosine phosphorylation is receptor catalysed. Since clathrin heavy chain (M_r 180,000 in dodecyl sulphate gel electrophoresis) is a major component of coated vesicles, the latter functioning in receptor endocytosis, we investigated whether insulin receptors can catalyse clathrin phosphorylation and whether p180 is clathrin. Bovine brain triskelion or coated vesicles and ³²P-ATP were added to prephosphorylated insulin receptor preparations (wheat ferm agglutinin-purified human placenta membrane proteins). Antiphosphotyrosine immunoprecipitated a phosphorylated 180,000 molecular weight protein. Insulin (10⁻⁷M) increased the rate of phosphorylation. Monoclonal anti-clathrin antibody immunoprecipitated the phosphorylated 180,000 molecular weight protein, whereas monoclonal anti-insulin receptor antibodies (-IR1, MA10) immunoprecipitated both insulin receptors and the phosphorylated 180,000 molecular weight protein. In the absence of added clathrin, anticlathrin immunoprecipitated no proteins, and -IR1 imunoprecipitated only the insulin receptor. Density gradient (glycerol 7.5–30%, w/v) centrifugation separated human placenta microsomal membrane proteins into endosomal, plasma membrane, cytoplasmic and coated vesicle fractions. Antiphosphotyrosine immunoprecipitated phosphorylated-microsomal proteins that centrifugated into endosomal and plasma membrane fractions. Addition of glycerol gradient fractions to a prephosphorylated insulin receptor preparation, however, gave a tyrosine-phosphorylated 180,000 molecular weight protein when cytoplasmic and coated vesicle fractions were added. Taken together these results suggest: (1) that, in vitro, human placenta insulin receptors can phosphorylate bovine brain and human placenta clathrin heavy chain; (2) that both assembled and unassembled clathrin can be phosphorylated; and (3) that p180, the plasma membrane-associated insulin receptor substrate, is not clathrin heavy chain.     

Lipid bilayer dynamics in plasma and coated vesicle membranes from bovine adrenal cortex. Evidence of two types of coated vesicle involved in the LDL receptor traffic

Pure coated vesicles have been prepared from the bovine adrenal cortex and two homogeneous populations have been separated, one of large diameter (100 nm) and one of small diameter (70 nm). The chemical composition in lipids and proteins of coated vesicles has been compared with that of partially purified plasma membranes and evidences a higher protein/lipid ratio and a higher concentration in phosphatidylethanolamine and unsaturated fatty acids. Evaluation of the lateral diffusion of pyrene in the lipid bilayer of coated vesicles as compared to uncoated vesicles evidences a slowing-down effect of clathrin. Measurements of lipids' rotational diffusion by time-resolved fluorescence indicate a decrease in the order parameter of the lipids in the coated vesicles due to clathrin. A hypothesis is proposed for a possible role of the clathrin coat in the concerted motion of lipids and proteins toward coated pits and in the mechanism of formation of coated vesicles. Separation of the large from the small coated vesicles made it possible to reveal different protein components in the two types of vesicle by electrophoresis and autoradiograms of the [γ-³²P]adenosine triphosphate- (ATP-) treated vesicles. Visualisation of the low-density lipoprotein receptor by ligand blotting and enzyme-linked immunosorbent assay (ELISA) techniques indicates an increased low-density lipoprotein receptor binding capacity in small coated vesicles as compared to large ones and plasma membranes.