Contrast variation studies of clathrin coated vesicles by small-angle neutron scattering

Structural information on clathrin coated vesicles has been obtained by small angle neutron scattering using contrast variation. A characteristic peak in the neutron scattering profile, which is apparent in 75 % D₂O, as well as in H₂O, disappears when contrast matching the protein component of the coated vesicles in 42% D₂O. Neutron, as well as dynamic, light scattering give a coated vesicle size of about 900 Å in H₂O and D₂O, but for neutron scattering the diameter decreases when matching out the protein coat of the clathrin coated vesicles. From the match point for the clathrin coated vesicles it is demonstrated that the clathrin cages do contain internal membrane. The mass of 34 MD and composition of 75% protein and 25% lipid found from the analysis of the small-angle scattering data are both in good agreement with the values reported in the literature. Electron microscopy gives an average outer diameter of 880 Å for the coated vesicles and an average diameter of 460 Å for the vesicle itself. Offprint requests to: Correspondence to: R. Bauer     

Location of the 100 kd-50 kd accessory proteins in clathrin coats.

We present a three-dimensional map of the clathrin coat of coated vesicles, generated from tilt series of electron micrographs of unstained specimens embedded in vitreous ice. We have examined native placental coated vesicles and coats reassembled from their purified constituents, namely clathrin triskelions and accessory proteins of approximate mol. wts 100 kd and 50 kd. Our results show that the accessory proteins contribute a further shell of density within the double shell of the clathrin cage, extending from the terminal domains of the clathrin to the membrane of the vesicle. The thickness of the complete coat is approximately 22 nm.     

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.     

Membrane contents of distinct subpopulations of coated vesicles determined by scanning transmission electron microscopy

In order to investigate the heterogeneity of clathrin-coated vesicles purified from rat liver, and to quantitate rigorously their membrane contents, we have analyzed scanning transmission electron micrographs of unstained coated vesicles before and after extraction with the non-ionic detergent Triton X-100, as well as of vesicles whose coats had been removed by dialysis against 10 mM or 100 mM Tris (pH 8.2). Their respective distributions of particle masses were thus determined and compared, in light of complementary biochemical quantitations of lipid and protein. Smaller coated particles, 25-45 MDa in mass and 60-80 nm in diameter, lose no mass when extracted with Triton, and disappear when their coats are dissociated. We conclude that they do not contain membrane vesicles, although they have dense, presumably proteinaceous, cores. They may represent particles generated during tissue homogenization or, possibly, a storage form of clathrin. The remaining 70% contain bona fide vesicles: these particles are 75-150 nm in diameter, and their average mass is about 80 MDa, of which 48 MDa is contributed by coat proteins, 10-12 MDa by phospholipid and cholesterol, and 20-22 MDa by vesicle-associated proteins. Their vesicles are of two types: smaller, denser, vesicles that contain substantial amounts of internalized material, and larger, less dense, vesicles that do not. The distinction between them may, in view of other findings, reflect a difference between coated vesicles derived respectively from the Golgi and the plasma membrane.     

Three-dimensional structure of clathrin cages in ice.

We have collected tilt series of electron micrographs from unstained clathrin cages embedded in vitreous ice. From these micrographs we have generated three-dimensional reconstructions of individual hexagonal barrels, which show details of the internal structure. Four types of preparation have been examined: (i) coated vesicles; (ii) cages reassembled from clathrin heavy and light chains; (iii) reassembled cages treated with elastase to remove the light chains; and (iv) reassembled cages treated with trypsin to remove the light chains and the terminal domains of the clathrin heavy chains. In the intact and elastase-treated cages, the clathrin extends from the vertices into the interior of the polyhedron and forms an inner shell of material. Limited digestion with trypsin removes the inner shell, which indicates that this material corresponds to the terminal domains of the clathrin heavy chains.     

Purification and properties of 100-kd proteins from coated vesicles and their reconstitution with clathrin.

Bullock brain coated vesicles contain a family of at least six 100-kd polypeptides which have the property of promoting clathrin assembly. These proteins have been purified from Triton X-100-extracted coated vesicles by a combination of gel filtration and chromatography on hydroxylapatite and DE-52 cellulose. Three major 100-kd species occur as complexes with a stoichiometric amount of a 50-kd polypeptide. On cross-linking these complexes, the chief products appear to contain two polypeptides of 100 kd and two of 50 kd. These 100-kd/50-kd complexes will polymerise with low concentrations of clathrin to give a relatively homogeneous population of coats predominantly of the 'barrel' size. In contrast, three other polypeptides of 100 kd lack the 50-kd protein but polymerise with clathrin under the same conditions to yield coats of a wide range of sizes including 'barrels', truncated icosahedra and particles of greater than 100 nm diameter. When clathrin cages are reassembled with a saturating amount of 100-kd/50-kd complexes and studied by electron microscopy, the additional proteins appear to follow the underlying geometry of the clathrin polyhedra, partially filling in the polygonal faces of the cage structures. Saturation appears to require approximately 3 molecules of 100-kd polypeptide per clathrin trimer.     

Light-chain-independent binding of adaptors, AP180, and auxilin to clathrin

Binding of coated vesicle assembly proteins to clathrin causes it to assemble into regular coat structures. The assembly protein fraction of bovine brain coated vesicles comprises AP180, auxilin, and HA1 and HA2 adaptors. Clathrin heavy chains, separated from their light chains, polymerize with unimpaired efficiency when assembly proteins are added. The reassembled coats were purified by sucrose gradient centrifugation and examined for composition by SDS-PAGE and immunoblotting. We found that all four major coat proteins are incorporated in the presence and absence of light chains. Moreover, each of the purified coat proteins is able to associate directly with clathrin heavy chains in preassembled cages as efficiently as with intact clathrin. We conclude that light chains are not essential for the interaction of AP180, auxilin, and HA1 and HA2 with clathrin.     

Auxilin facilitates membrane traffic in the early secretory pathway

Coat protein complexes contain an inner shell that sorts cargo and an outer shell that helps deform the membrane to give the vesicle its shape. There are three major types of coated vesicles in the cell: COPII, COPI, and clathrin. The COPII coat complex facilitates vesicle budding from the endoplasmic reticulum (ER), while the COPI coat complex performs an analogous function in the Golgi. Clathrin-coated vesicles mediate traffic from the cell surface and between the trans-Golgi and endosome. While the assembly and structure of these coat complexes has been extensively studied, the disassembly of COPII and COPI coats from membranes is less well understood. We describe a proteomic and genetic approach that connects the J-domain chaperone auxilin, which uncoats clathrin-coated vesicles, to COPII and COPI coat complexes. Consistent with a functional role for auxilin in the early secretory pathway, auxilin binds to COPII and COPI coat subunits. Furthermore, ER–Golgi and intra-Golgi traffic is delayed at 15°C in swa2Δ mutant cells, which lack auxilin. In the case of COPII vesicles, we link this delay to a defect in vesicle fusion. We propose that auxilin acts as a chaperone and/or uncoating factor for transport vesicles that act in the early secretory pathway.     

Assembly polypeptides from coated vesicles mediate reassembly of unique clathrin coats

A protein activity has been identified in extracts of coated vesicles that enables purified clathrin triskelions to reassemble in vitro into coat structures of uniform size. Coats formed in the presence of this preparation, regardless of the buffer system employed, are uniform in size with a mean diameter of 78 nm (+/- 5 nm SD) and a sedimentation coefficient (S20,w) of approximately 250S. Analysis of the reassembled coats on dodecyl sulfate acrylamide gels reveals that they have specifically incorporated three polypeptides from the preparation: those of Mr congruent to 52,000, 100,000, and 110,000. The 52,000-, 100,000-, and 110,000-mol-wt polypeptides are incorporated in molar ratios of 0.85, 1.11, and 0.26, respectively, per three clathrin monomers (equivalent to one triskelion). We therefore designate these as assembly polypeptides (AP). In contrast, coats formed from clathrin alone, under permissive buffer conditions, are larger (400S), more heterogeneous in size (101 nm +/- 15 nm SD), and are composed only of clathrin and its associated light chains. These biochemical and biophysical characteristics distinguish AP-reassembled coats from coats formed by triskelions alone. AP-reassembled coats can be isolated, dissociated, then reassembled in the absence of any other factors. This recycling indicates that all the information needed for reassembly is present in the coat-incorporated polypeptides themselves. Reassembly is stoichiometric and saturable with respect to both clathrin and AP concentration. In the presence of AP, significant coat reassembly occurs at clathrin concentrations as low as 0.06 mg/ml. AP-mediated reassembly proceeds at 4 degrees, 22 degrees, and 37 degrees C. Coat formation also proceeds efficiently at intracellular pH values (7.2- 7.5) in the presence of AP. In its absence, reassembly does not occur at all above pH 6.7. In summary, AP promotes clathrin reassembly into coat structures of uniform size and distinctive composition under physiologically relevant salt, temperature, and pH conditions. In addition, the close similarity in size between AP-reassembled coats in vitro and coated membranes in the Golgi region in vivo raises the possibility that AP in the cell may be associated with this subpopulation of coat structures.     

A new type of coated vesicular carrier that appears not to contain clathrin: its possible role in protein transport within the Golgi stack

Isolated Golgi membranes incubated in the presence of ATP and a cytosolic protein fraction form a population of coated buds or vesicles from the Golgi cisternae. The coats do not have the characteristic hexagonal-pentagonal basketwork of clathrin, and do not react with anti-clathrin polyclonal antibody. The conditions that produce these apparently nonclathrin-coated buds also reconstitute protein transport between compartments of the Golgi stack. The membrane of the buds contains the glycoprotein in transit through these Golgi stacks (VSV-encoded G protein). This suggests that protein transport through the Golgi stack is mediated by a new type of coated vesicle that does not contain clathrin. The concentration of G protein in the coated buds reflects the local concentration of G protein in the cisternae, raising the possibility that the Golgi coated vesicles may be "bulk" membrane carriers.     

Assembly of the mannose-6-phosphate receptor into reconstituted clathrin coats.

In ionic conditions in which clathrin coats are stable, the mannose-6-phosphate receptor associates with the 100-kd/50-kd coat complexes purified from bullock brain coated vesicles. These aggregates exist as striking spherical structures of 300-1000 A diameter. When clathrin is included in the assembly mixture, cages are formed which apparently encapsulate these aggregates, giving, in the absence of lipid, structures resembling full coated vesicles.     

Cryo-electron tomography of clathrin-coated vesicles: structural implications for coat assembly

Clathrin-coated vesicles mediate vesicular traffic in cells. Three-dimensional image reconstructions of homogenous populations of in vitro assembled clathrin coats have yielded a molecular model for clathrin and its interactions with some of its partners. The intrinsic averaging required for those calculations has precluded detailed analysis of heterogeneous populations of clathrin-coated vesicles isolated from cells. We have therefore used cryo-electron tomography to study the lattice organization of individual clathrin-coated vesicles and the disposition of the captured vesicle with respect to the surrounding coat. We find a wide range of designs for the clathrin lattice, with different patterns of pentagonal, hexagonal, and occasionally heptagonal facets. Many coats, even smaller ones, enclose membrane vesicles, which are generally offset from the center of the clathrin shell. The electron density distribution between the coat and the underlying vesicle is not uniform, and the number of apparent contacts that anchor the clathrin lattice to the vesicle membrane is significantly less than the number of clathrin heavy chains in the assembly. We suggest that the eccentric position of the vesicle reflects the polarity of assembly, from initiation of coat formation to membrane pinching.     

Distinct Dynamics of Endocytic Clathrin-Coated Pits and Coated Plaques

Clathrin is the scaffold of a conserved molecular machinery that has evolved to capture membrane patches, which then pinch off to become traffic carriers. These carriers are the principal vehicles of receptor-mediated endocytosis and are the major route of traffic from plasma membrane to endosomes. We report here the use of in vivo imaging data, obtained from spinning disk confocal and total internal reflection fluorescence microscopy, to distinguish between two modes of endocytic clathrin coat formation, which we designate as “coated pits” and “coated plaques.” Coated pits are small, rapidly forming structures that deform the underlying membrane by progressive recruitment of clathrin, adaptors, and other regulatory proteins. They ultimately close off and bud inward to form coated vesicles. Coated plaques are longer-lived structures with larger and less sharply curved coats; their clathrin lattices do not close off, but instead move inward from the cell surface shortly before membrane fission. Local remodeling of actin filaments is essential for the formation, inward movement, and dissolution of plaques, but it is not required for normal formation and budding of coated pits in the cells we have studied. We conclude that there are at least two distinct modes of clathrin coat formation at the plasma membrane—classical coated pits and coated plaques—and that these two assemblies interact quite differently with other intracellular structures.     

Bilayered clathrin coats on endosomal vacuoles are involved in protein sorting toward lysosomes

In many cells endosomal vacuoles show clathrin coats of which the function is unknown. Herein, we show that this coat is predominantly present on early endosomes and has a characteristic bilayered appearance in the electron microscope. By immunoelectron microscopy we show that the coat contains clathrin heavy as well as light chain, but lacks the adaptor complexes AP1, AP2, and AP3, by which it differs from clathrin coats on endocytic vesicles and recycling endosomes. The coat is insensitive to short incubations with brefeldin A, but disappears in the presence of the phosphatidylinositol 3-kinase inhibitor wortmannin. No association of endosomal coated areas with tracks of tubulin or actin was found. By quantitative immunoelectron microscopy, we found that the lysosomal-targeted receptors for growth hormone (GHR) and epidermal growth factor are concentrated in the coated membrane areas, whereas the recycling transferrin receptor is not. In addition, we found that the proteasomal inhibitor MG 132 induces a redistribution of a truncated GHR (GHR-369) toward recycling vesicles, which coincided with a redistribution of endosomal vacuole-associated GHR-369 to the noncoated areas of the limiting membrane. Together, these data suggest a role for the bilayered clathrin coat on vacuolar endosomes in targeting of proteins to lysosomes.     

Involvement of beta-COP in membrane traffic through the Golgi complex

Non-clathrin-coated vesicles mediate membrane traffic through the Golgi complex. The proteins that constitute the coats of these vesicles have similar molecular weights to the clathrin coat proteins. A major component of the coat of non-clathrin-coated vesicles, beta-COP, has significant homology with the clathrin coat protein beta-adaptin, indicating that the coats of the two different classes of vesicles may be structurally and functionally homologous.     

Brain Coated Vesicle Destabilization and Phosphorylation of Coat Proteins

Abstract: Two basic polypeptides, bee venom melittin and poly-L-lysine, induced concentration-dependent destabilization of bovine brain coated vesicles. Ultrastructurally the changes observed were aggregation of clathrin coats and segregation of the vesicle membrane, concomitant with the appearance of elongated cisternae of various sizes. Changes in coated vesicle morphology induced by melittin and poly-L-lysine were concurrent with stimulation of phosphate incorporation in proteins of the coat lattice: M, 33,000 and 100,000. Melittin-stimulated phosphorylation was Ca²⁺ sensitive and inhibited by EGTA. The initiation of vesicle membrane segregation by melittin, followed by fusion and formation of elongated membrane cisternae, paralleled an increase of endogenous phospholipase A₂ activity. The data suggest that a correlation exists between the state of assembly of the coat proteins on coated vesicles and protein phosphorylation.     

Stabilization of clathrin coats by the core of the clathrin-associated protein complex AP-2

AP-2 is the class of clathrin-associated protein complex found in coated vesicles derived from the plasma membrane of eukaryotic cells. We demonstrate here, using a chemical method, that an AP-2 complex is an asymmetric structure consisting of one large alpha chain, one large beta chain, one medium AP50 chain, and one small AP17 chain. The complex has been shown to contain a core and two appendages. The AP core includes the small AP17 and the medium AP50 chains together with the amino-terminal domains of the large alpha and beta chains. One appendage corresponds to the carboxy-terminal domain of the beta chain. We find that as in the case of the beta chains, the carboxy-terminal portion of the alpha chains is an independently folded domain corresponding to the second appendage. We use limited tryptic proteolysis of clathrin/AP-2 coats to show the release of the appendages from the interior of the coats and the retention of the AP core by the remaining clathrin lattice. In addition, we find that the AP core stabilizes the coat and prevents its depolymerization. These results are consistent with the proposal that the AP core contains the binding site(s) for clathrin, while the alpha- and beta-chain appendages interact with membrane components of coated pits and coated vesicles.     

Identification of the Plasma Membrane Proteolipid Protein as a Constituent of Brain Coated Vesicles and Synaptic Plasma Membrane

We have analyzed brain coated vesicles and synaptic plasma membrane for the presence of the plasma membrane proteolipid protein. Coated vesicles were isolated from calf brain gray matter with a final purification on Sephacryl S-1000 and reisolated twice by chromatography to ensure homogeneity. Fractions were analyzed by gel electrophoresis, immunoblotting for clathrin heavy chain, and by electron microscopy. Using an immunoblotting assay we were able to demonstrate the presence of the plasma membrane proteolipid protein in these coated vesicles at a significant level (i.e., approximately 1% of the bilayer protein of these vesicles). Reisolation of coated vesicles did not diminish the concentration of the protein in this fraction. Removal of the clathrin coat proteins or exposure of the coated vesicles to 0.1 M Na2CO3 showed that the plasma membrane proteolipid protein is not removed during uncoating and lysis but is intrinsic to the membrane bilayer of these vesicles. These studies demonstrate that plasma membrane proteolipid protein represents a significant amount of the bilayer protein of coated vesicles, suggesting that these vesicles may be a transport vehicle for the intracellular movement of the plasma membrane proteolipid protein. Isolation of synaptic plasma membranes proteolipid adult rat brain and estimation of the plasma membrane proteolipid protein content using the immunoblotting method confirmed earlier studies that show this protein is present in this membrane fraction at high levels as well (approximately 1-2%). The level of this protein in the synaptic plasma membrane suggests that the synaptic plasma membrane is one major site to which these vesicles may be targeted or from which the protein is being retrieved.     

Both clathrin-positive and -negative coats are involved in endosomal sorting of the EGF receptor

Sorting of endocytosed EGF receptor (EGFR) to internal vesicles of multivesicular bodies (MVBs) depends on sustained activation and ubiquitination of the EGFR. Ubiquitination of EGFR is mediated by the ubiquitin ligase Cbl, being recruited to the EGFR both directly and indirectly through association with Grb2. Endosomal sorting of ubiquitinated proteins further depends on interaction with ubiquitin binding adaptors like Hrs. Hrs localizes to flat, clathrin-coated domains on the limiting membrane of endosomes. In the present study, we have investigated the localization of EGFR, Cbl and Grb2 with respect to coated and non-coated domains of the endosomal membrane and to vesicles within MVBs. Both EGFR, Grb2, and Cbl were concentrated in coated domains of the limiting membrane before translocation to inner vesicles of MVBs. While almost all Hrs was in clathrin-positive coats, EGFR and Grb2 in coated domains only partially colocalized with Hrs and clathrin. The extent of colocalization of EGFR and Grb2 with Hrs and clathrin varied with time of incubation with EGF. These results demonstrate that both clathrin-positive and clathrin-negative electron dense coats exist on endosomes and are involved in endosomal sorting of the EGFR.     

Isolation and partial characterization of clathrin-coated vesicles from pea (Pisum sativum L.) cotyledons

Summary Clathrin-coated vesicles have been isolated from cotyledons of both developing and germinating pea seeds using differential centrifugation, ribonuclease treatment, discontinuous sucrose gradients, and isopycnic centrifugation on a linear D₂O-Ficoll gradient. The yield of coated vesicles from developing pea cotyledons was exceptional, being 1.6 × higher than the yield from hog and bovine brain, 5.3 × higher than the yield from carrot suspension cultures, and 13 × the yield from cotyledons of germinating pea seeds. The pea coated vesicles are similar to other plant coated vesicles in size (approximately 80 nm in diameter) and in having a clathrin heavy chain of 190,000 M_r. The lipid phosphorus to protein ratio, 190–250 nmol P per mg protein, of the coated vesicles from plants is comparable to that reported for highly purified coated vesicles from animals. The nondenatured pea clathrin reacted weakly with an antiserum to bovine brain clathrin, but pea clathrin denatured by sodium dodecyl sulfate did not.Abbreviations CLC Clathrin light chain - CHC clathrin heavy chain - CV coated vesicle - DTT dithiothreitol - EGTA ethyleneglycol-bis-(-aminoethyl ether) N,N-tetraacetic acid - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - TBS Tris buffered saline