Calmodulin binding and protein phosphorylation in adrenal medulla coated vesicles

Coated vesicles from bovine adrenal medulla contained clathrin and major detergent-insoluble polypeptides of 120-100, 51 and 49 kDa. Intact coated vesicles and vesicles lacking clathrin light chains were bound by immobilized calmodulin in the presence of Ca2+. Clathrin in the form of 700 A cages was not bound. The calmodulin binding components in intact coated vesicles are therefore contributed by the enclosed vesicle or by the 120-100, 50 or 49 kDa polypeptides. The 51 kDa component incorporated 32Pi from labelled ATP by an endogenous kinase activity; no other coat or vesicle membrane protein was phosphorylated in vitro, either by intrinsic or exogenous kinases.     

Calmodulin Affinity for Brain Coated Vesicle Proteins

A systematic characterization of the affinity of calmodulin for brain coated vesicles was undertaken. Binding of 125I-labeled calmodulin to coated vesicles was saturable and competed with unlabeled calmodulin, but not with troponin-C. Scatchard analysis revealed one high-affinity, low-capacity binding site, KD = 3.9 +/- 0.6 nM, Bmax = 16.3 +/- 2.4 pmol/mg, and one low-affinity, high-capacity binding site, KD = 102 +/- 15.0 nM, Bmax = 151 +/- 23.0 pmol/mg. Radioimmunoassay revealed that coated vesicles contain 1.05 microgram calmodulin/mg protein. Because this value remained constant even after removal of clathrin, the major coat protein, from the coated vesicle, it is apparent that calmodulin is associated with the vesicle per se rather than with its clathrin lattice. When a Triton X-100-treated extract of coated vesicles was passed through a Sepharose 4B-calmodulin affinity column, polypeptides with Mrs (molecular weights) of 100,000, 55,000, and 30,000 bound in a Ca2+-dependent manner. A 30,000 Mr protein doublet purified from coated vesicles was completely eluted by EGTA from the calmodulin affinity column, confirming that this protein doublet represents one of the coated vesicle calmodulin binding sites. Because calmodulin stimulated [Ca2+-Mg2+]-ATPase activity as well as Ca2+ uptake in coated vesicles, it is postulated that the 100,000 and 55,000 Mr calmodulin binding proteins represent the [Ca2+-Mg2+]-ATPase complex, the other coated vesicle calmodulin binding site.     

Identification of minor components of coated vesicles by use of permeation chromatography

Coated vesicles are thought to be vehicles for the intracellular transport of membranes. Clathrin is the major protein component of coated vesicles. Minor components of these organelles can be identified in highly purified preparations if they can be shown to copurify with clathrin. To show copurification we have made use of the relatively uniform diameter of coated vesicles (50-150 nm) to fractionate conventionally purified coated vesicles according to size in glass bead columns of 200-nm pore size. We have found that bovine brain coated vesicles prepared by the standard procedure of Pearse can be contaminated with large membrane fragments that are removed by permeation chromatography on such glass bead columns. Gel electrophoretic analysis of column fractions shows that only three major polypeptide chains, and a family of polypeptides with molecular weights close to 100,000 are always in constant ratio to clathrin, and are unique to fractions containing coated vesicles. Two other major polypeptides that appear to be components of coated vesicles are also present in other membrane fractions. We have also used permeation chromatography to monitor artifactual membrane trapping during vesicle isolation. Pure radiolabeled synaptic vesicle membranes were added to bovine brain tissue before homogenization. Considerable amounts of the added radioactivity could be recovered in the fractions conventionally pooled in the preparation of coated vesicles. After permeation chromatography, the radioactivity in the coated vesicle peak was reduced essentially to background.     

Solubilization of proteins from bovine brain coated vesicles by protein perturbants and Triton X-100

To identify integral and peripheral membrane proteins, highly purified coated vesicles from bovine brain were exposed to solutions of various pH, ionic strength, and concentrations of the nonionic detergent Triton X-100. At pH 10.0 or above most major proteins were liberated, but four minor polypeptides sedimented with the vesicles. From quantitative analysis of phospholipids in the pellet and extract, we determined that at a pH of up to 12 all phospholipids could be recovered in the pellet. Electron microscopic examination of coated vesicles at pH 12.0 showed all vesicles devoid of coat structures. Treatment with high ionic strength solutions (0-1.0 M KCl) at pH 6.5-8.5 also liberated all major proteins, except tubulin, which remained sedimentable. The addition of Triton X-100 to coated vesicles or to stripped vesicles from which 90% of the clathrin had been removed resulted in the release of four distinct polypeptides of approximate Mr 38,000, 29,000, 24,000 and 10,000. The 38,000-D polypeptide (pK approximately 5.0), which represents approximately 50% of the protein liberated by Triton X-100, appears to be a glycoprotein on the basis of its reaction with periodic acid-Schiff reagent. Extraction of 90% of the clathrin followed by extraction of 90% of the phospholipids with Triton X-100 produced a protein residue that remained sedimentable and consisted of structures that appeared to be shrunken stripped vesicles. Together our data indicate that most of the major polypeptides of brain coated vesicles behave as peripheral membrane proteins and at least four polypeptides behave as integral membrane proteins. By use of a monoclonal antibody, we have identified one of these polypeptides (38,000 mol wt) as a marker for a subpopulation of calf brain coated vesicles.     

Mis-assembly of clathrin lattices on endosomes reveals a regulatory switch for coated pit formation

The clathrin-coated pit lattice is held onto the plasma membrane by an integral membrane protein that binds the clathrin AP-2 subunit with high affinity. In vitro studies have suggested that this protein controls the assembly of the pit because membrane bound AP-2 is required for lattice assembly. If so, the AP-2 binding site must be a resident protein of the coated pit and recycle with other receptors that enter cells through this pathway. Proper recycling, however, would require the switching off of AP-2 binding to allow the binding site to travel through the endocytic pathway unencumbered. Evidence for this hypothesis has been revealed by the cationic amphiphilic class of drugs (CAD), which have previously been found to inhibit receptor recycling. Incubation of human fibroblasts in the presence of these drugs caused clathrin lattices to assemble on endosomal membranes and at the same time prevented coated pit assembly at the cell surface. These effects suggest that CADs reverse an on/off switch that controls AP-2 binding to membranes. We conclude that cells have a mechanism for switching on and off AP-2 binding during the endocytic cycle.     

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.     

Deep-etch visualization of proteins involved in clathrin assembly

Assembly proteins were extracted from bovine brain clathrin-coated vesicles with 0.5 M Tris and purified by clathrin-Sepharose affinity chromatography, then adsorbed to mica and examined by freeze-etch electron microscopy. The fraction possessing maximal ability to promote clathrin polymerization, termed AP-2, was found to be a tripartite structure composed of a relatively large central mass flanked by two smaller mirror-symmetric appendages. Elastase treatment quantitatively removed the appendages and clipped 35 kD from the molecule's major approximately 105-kD polypeptides, indicating that the appendages are made from portions of these polypeptides. The remaining central masses no longer promote clathrin polymerization, suggesting that the appendages are somehow involved in the clathrin assembly reaction. The central masses are themselves relatively compact and brick-shaped, and are sufficiently large to contain two copies of the molecule's other major polypeptides (16- and 50-kD), as well as two copies of the approximately 70-kD protease-resistant portions of the major approximately 105-kD polypeptides. Thus the native molecule seems to be a dimeric, bilaterally symmetrical entity. Direct visualization of AP-2 binding to clathrin was accomplished by preparing mixtures of the two molecules in buffers that marginally inhibit AP-2 aggregation and cage assembly. This revealed numerous examples of AP-2 molecules binding to the so-called terminal domains of clathrin triskelions, consistent with earlier electron microscopic evidence that in fully assembled cages, the AP's attach centrally to inwardly-directed terminal domains of the clathrin molecule. This would place AP-2s between the clathrin coat and the enclosed membrane in whole coated vesicles. AP-2s linked to the membrane were also visualized by enzymatically removing the clathrin from brain coated vesicles, using purified 70 kD, uncoating ATPase plus ATP. This revealed several brick-shaped molecules attached to the vesicle membrane by short stalks. The exact stoichiometry of APs to clathrin in such vesicles, before and after uncoating, remains to be determined.     

Clathrin functions in the absence of heterotetrameric adaptors and AP180-related proteins in yeast.

The major coat proteins of clathrin-coated vesicles are the clathrin triskelion and heterotetrameric associated protein (AP) complexes. The APs are thought to be involved in cargo capture and recruitment of clathrin to the membrane during endocytosis and sorting in the trans-Golgi network/endosomal system. AP180 is an abundant coat protein in brain clathrin-coated vesicles, and it has potent clathrin assembly activity. In Saccharomyces cerevisiae, there are 13 genes encoding homologs of heterotetrameric AP subunits and two genes encoding AP180-related proteins. To test the model that clathrin function is dependent on the heterotetrameric APs and/or AP180 homologs, yeast strains containing multiple disruptions in AP subunit genes, as well as in the two YAP180 genes, were constructed. Surprisingly, the AP deletion strains did not display the phenotypes associated with clathrin deficiency, including slowed growth and endocytosis, defective late Golgi protein retention and impaired cytosol to vacuole/autophagy function. Clathrin-coated vesicles isolated from multiple AP deletion mutants were morphologically indistinguishable from those from wild-type cells. These results indicate that clathrin function and recruitment onto membranes are not dependent upon heterotetrameric adaptors or AP180 homologs in yeast. Therefore, alternative mechanisms for clathrin assembly and coated vesicle formation, as well as the role of AP complexes and AP180-related proteins in these processes, must be considered.     

The subpopulation of brain coated vesicles that carries synaptic vesicle proteins contains two unique polypeptides

Coated vesicles have been purified in the past on the basis of their remarkably homogeneous structure, not their function. We have succeeded in isolating two subpopulations of bovine brain coated vesicles that carry specific "cargoes," in this case two synaptic vesicle membrane polypeptides (Mr = 95,000 and 65,000). Monoclonal antibodies that recognize cytoplasmic domains of these polypeptides can penetrate the clathrin coat and recognize them on the outer surface of the coated vesicle membrane. An immunoadsorption technique could therefore be used to fractionate coated vesicles on the basis of their membrane composition. The subpopulations have the normal complement of conventional coated vesicle proteins. Exclusive, however, to the subpopulations that carry synaptic vesicle polypeptides are two new coated vesicle polypeptides (Mr = 38,000 and 29,000).     

Tubulin: An Integral Protein of Mammalian Synaptic Vesicle Membranes

Abstract: The major protein in isolated synaptic vesicles from bovine cerebral cortex has been compared to tubulin by sodium dodecyl sulphate-urea polyacrylamide gel electrophoresis, by two-dimensional gel electrophoresis and by peptide mapping following limited proteolysis of the protein by Staphylococcus aureus protease. The results establish in purified synaptic vesicles the presence of tubulin, which is composed of the α and β subunits. In the presence of ethyleneglycol bis (aminoethyl ether)- N, N' -tetraacetic acid (EGTA) or magnesium in the isolation buffers, the synaptic vesicles contained mainly the α-tubulin whereas the β subunit was less abundant. Similarly, synaptosomal plasma membranes that were prepared in the presence of EGTA also contained more of α-tubulin than of the β subunit. Non-ionic detergents such as Triton X-100 or Nonidet P-40 failed to solubilize the tubulin from the synaptic vesicles. Ionic detergents such as deoxycholate and sodium dodecyl sulphate solubilized all the vesicle proteins, including tubulin. The results indicate that α-tubulin is an integral vesicle membrane protein, whereas most of the β sub-unit is peripherally attached and can be easily dissociated from the vesicle membrane with EGTA.     

Clathrin assembly proteins: affinity purification and a model for coat assembly

Assembly protein (AP) preparations from bovine brain coated vesicles have been fractionated by clathrin-Sepharose affinity chromatography. Two distinct fractions that possess coat assembly activity were obtained and are termed AP-1 and AP-2. The AP-1, not retained on the resin, has principal components with molecular weights of 108,000, 100,000, 47,000, and 19,000. The AP-2, bound to the resin and eluted by Tris-HCl at a concentration that parallels the latter's effect on coat disassembly, corresponds to the active complex described previously (Zaremba, S., and J. H. Keen, 1983, J. Cell Biol., 97:1339-1347). Its composition is similar to that of the AP-1 in that it contains 100,000-, 50,000-, and 16,000-mol-wt polypeptides in equimolar amounts; minor amounts of 112,000- and 115,000-mol-wt polypeptides are also present. Both are distinct from a recently described assembly protein of larger subunit molecular weight that we term AP-3. These results indicate the existence of a family of assembly proteins within cells. On incubation with clathrin both AP-1 and AP-2 induce the formation of coat structures, those containing AP-1 slightly smaller (mean diameter = 72 nm) than those formed in the presence of AP-2 (mean diameter = 79 nm); both structures have been detected previously in coated vesicle preparations from brain. Coats formed in the presence of AP-2 consistently contain approximately one molecule each of the 100,000-, 50,000-, and 16,000-mol-wt polypeptides per clathrin trimer. By low angle laser light scattering the molecular weight of native AP-2 was determined to be approximately 343,000, indicating that it is a dimer of each of the three subunits, and implying that it is functionally bivalent in clathrin binding. A model for AP-mediated coat assembly is proposed in which a bivalent AP-2 molecule bridges the distal legs or terminal domains of two clathrin trimers that are destined to occupy adjacent vertices in the assembled coat. Binding of a second AP-2 molecule locks these two trimers in register for assembly and further addition of AP-2 to free trimer legs promotes completion of the clathrin lattice. Effects of AP binding on the angle and flexibility of the legs at the hub of the trimer (the "pucker") are suggested to account for the characteristic size distributions of coats formed under varied conditions and, more speculatively, to contribute to the transformation of flat clathrin lattices to curved coated vesicles that are thought to occur during endocytosis.     

Transmembrane orientation of the mannose 6-phosphate receptor in isolated clathrin-coated vesicles

The mannose 6-phosphate (Man-6-P) receptor is an integral membrane glycoprotein which mediates intracellular transport and receptor-mediated endocytosis of lysosomal proteins. Clathrin-coated vesicles, which have been shown to be significantly involved in these processes, have also been shown to be a major subcellular site of the receptor. In order to define the orientation of the Man-6-P receptor within the coated vesicle membrane, highly purified preparations of coated vesicles were prepared from bovine brain employing D2O/sucrose gradient centrifugation and Sephacryl S-1000 column chromatography. Using [35S]methionine-labeled lysosomal enzymes secreted by Chinese hamster ovary cells as receptor ligand, significant binding activity was detected only upon permeabilization of the coated vesicle membranes with detergent. Prior treatment of intact vesicles with proteinase K resulted in similar binding activity upon permeabilization. However, examination of the receptor by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting with rabbit anti-receptor serum revealed that proteinase K treatment of intact vesicles reduced the size of the receptor by 12,000 daltons. A similar decrease in size was obtained when the vesicles were treated with carboxypeptidase Y. These results suggest that the Man-6-P receptor is a transmembrane protein with its lysosomal enzyme binding site oriented toward the lumen of the coated vesicle and its C-terminal end exposed to the exterior or cytoplasmic portion of the vesicle membrane.     

Purification and properties of a new clathrin assembly protein.

A clathrin assembly protein (AP180) has been purified and characterized from coated vesicles of bovine brain. This protein has hitherto escaped detection because in SDS-gel electrophoresis it is obscured by the 180 kd heavy chain of clathrin. Despite the similarity in electrophoretic mobility, AP180 differs from clathrin in both its subunit and native mol. wt, as well as hydrodynamic properties, surface charge and tryptic peptide composition. It also appears immunologically distinct from clathrin, since neither a polyclonal antiserum nor a monoclonal antibody, that have been shown to be specific for AP180, cross-react with the heavy chain of clathrin. AP180 binds to clathrin triskelia and thereby promotes clathrin assembly into regular polyhedral structures of narrow size-distribution (60-90 nm), reminiscent of the surface coat of coated vesicles. In this respect AP180 bears a functional resemblance to the 100-110 kd clathrin assembly polypeptides that have been previously described.     

The beta 1 and beta 2 subunits of the AP complexes are the clathrin coat assembly components.

The beta 1 and beta 2 subunits are the closely-related large chains of the trans-Golgi network AP-1 and the plasma membrane AP-2 clathrin-associated protein complexes, respectively. Recombinant beta 1 and beta 2 subunits have been generated in Escherichia coli. It was found that, in the absence of all the other AP subunits, beta 1 and beta 2 interact with clathrin and drive the efficient assembly of clathrin coats. In addition, beta 2 subunits and AP complexes compete for the same clathrin binding site. The appearance of the clathrin/beta coats is the same as the barrel-shaped structures formed with native AP complexes. It is proposed that the principal function of the beta subunits is to initiate coat formation, while the remaining subunits of the AP complexes have other roles in coated pit and coated vesicle function.     

Novel binding sites on clathrin and adaptors regulate distinct aspects of coat assembly

Clathrin-coated vesicles (CCVs) sort proteins at the plasma membrane, endosomes and trans Golgi network for multiple membrane traffic pathways. Clathrin recruitment to membranes and its self-assembly into a polyhedral coat depends on adaptor molecules, which interact with membrane-associated vesicle cargo. To determine how adaptors induce clathrin recruitment and assembly, we mapped novel interaction sites between these coat components. A site in the ankle domain of the clathrin triskelion leg was identified that binds a common site on the appendages of tetrameric [AP1 and AP2] and monomeric (GGA1) adaptors. Mutagenesis and modeling studies suggested that the clathrin-GGA1 appendage interface is nonlinear, unlike other peptide-appendage interactions, but overlaps with a sandwich domain binding site for accessory protein peptides, allowing for competitive regulation of coated vesicle formation. A novel clathrin box in the GGA1 hinge region was also identified and shown to mediate membrane recruitment of clathrin, while disruption of the clathrin-GGA1 appendage interaction did not affect recruitment. Thus, the distinct sites for clathrin-adaptor interactions perform distinct functions, revealing new aspects to regulation of CCV formation.     

Identification of three coated vesicle components as alpha- and beta- tubulin linked to a phosphorylated 50,000-dalton polypeptide

Coated vesicles are involved in the intracellular transport of membrane proteins between a variety of membrane compartments. The coats of bovine brain coated vesicles contain at least six polypeptides in addition to an 180,000-dalton polypeptide called clathrin. In this report we show that the 54,000- and 56,000-dalton coated vesicle polypeptides are alpha- and beta-tubulin, determined by immunoblotting and two-dimensional gel electrophoresis. An affinity-purified tubulin antiserum can precipitate coated vesicles. The tubulin polypeptides are tightly associated with a 50,000-dalton coated vesicle polypeptide, which is phosphorylated. The phosphorylated 50,000-dalton polypeptide appears to be related to brain microtubule-associated tau proteins since it can be specifically immunoprecipitated by an affinity-purified antiserum directed against these proteins. In addition, gel filtration experiments indicate that at least a fraction of the 50,000-dalton polypeptide may associate with the 100,000-dalton coated vesicle polypeptide. Since brain is a tissue rich in tubulins, liver coated vesicles were analyzed for the presence of alpha- and beta-tubulin. Like brain coated vesicles, liver coated vesicles also contain an endogenous kinase activity, which phosphorylates polypeptides of the same molecular weights and isoelectric points as the brain coated vesicle 50,000-dalton, tau-like polypeptide, and alpha- and beta-tubulin. The phosphorylated 50,000-dalton polypeptide may link the membrane and contents of coated vesicles with components of the cytoskeleton.     

An antibody against 100- to 116-kDa polypeptides in coated vesicles inhibits triskelion binding

There is considerable evidence that the 100- to 116-kDa polypeptides in calf brain coated vesicles are involved in the assembly of clathrin triskelions to form coated vesicles. We have raised polyclonal antibodies against these polypeptides. By Western blot analysis, these antibodies bind to a distinct subset of the six polypeptides in the region 100-116 kDa. Whole cell homogenates from calf brain, calf liver, and rat liver also show immunoreactivity in the 100-kDa region with no other cross reactivity. Isolated coated vesicles from calf liver, rat brain, and soybean roots also cross-react. Stripped coated vesicles, which are depleted of clathrin but which retain the 100- to 116-kDa polypeptides, quantitatively rebind 125I-triskelions. This binding is inhibited in a dose-dependent manner by 100- to 116-kDa antibody but not by nonimmune serum or by anti-clathrin polyclonal antibody. These studies indicate that (1) specific sites on the 100- to 116-kDa polypeptides are required for assembly of coated vesicles, and (2) this antibody will be useful in clarifying more precisely the role of the 100- to 116-kDa polypeptides in coated vesicle recycling.     

Clathrin-coated pits contain an integral membrane protein that binds the AP-2 subunit with high affinity

Coated pits will assemble onto purified plasma membranes that are attached to a poly-L-lysine coated substratum (Moore, M. S., Mahaffey, D. T., Brodsky, F. M., and Anderson, R. G. W. (1987) Science 236, 558-563; Mahaffey, D. T., Moore, M. S., Brodsky, F. M., and Anderson, R. G. W. (1989) J. Cell Biol. 108, 1615-1624). To better understand the assembly reaction, we have purified both clathrin triskelion and AP-2 subunits from bovine brain and assayed for their ability to bind to the cytoplasmic surface of attached membranes. Two types of membranes were analyzed: those washed with a high pH buffer that selectively removes triskelions and those washed with a high salt buffer that removes both the AP-2 and the triskelion subunits. We found that purified AP-2 subunits bind with high affinity (Kd approximately 3 x 10(-8) M) to salt stripped membranes. Binding is saturable and abolished by treating membranes with less than 20 micrograms/ml of elastase. When membranes were treated with elastase before the salt wash and then salt washed and assayed for AP-2 binding, normal binding was seen, which indicates that the presence of clathrin-coated pits protects the binding site from the protease. Membranes that had rebound AP-2 did not bind purified triskelions, even though high pH buffer-washed membranes that bear endogenous AP-2 bound triskelions with high affinity (Kd approximately 3 x 10(-9) M) and supported lattice assembly. We conclude that coated pit assembly is initiated by the binding of AP-2 to an integral membrane protein but that the AP-2 complex must be activated by an unknown process before the coated pit lattice will assemble.     

Immunofluorescent localization of 100K coated vesicle proteins

A family of coated vesicle proteins, with molecular weights of approximately 100,000 and designated 100K, has been implicated in both coat assembly and the attachment of clathrin to the vesicle membrane. These proteins were purified from extracts of bovine brain coated vesicles by gel filtration, hydroxylapatite chromatography, and preparative SDS PAGE. Peptide mapping by limited proteolysis indicated that the polypeptides making up the three major 100K bands have distinct amino acid sequences. When four rats were immunized with total 100K protein, each rat responded differently to the different bands, although all four antisera cross-reacted with the 100K proteins of human placental coated vesicles. After affinity purification, two of the antisera were able to detect a 100K band on blots of whole 3T3 cell protein and were used for immunofluorescence, double labeling the cells with either rabbit anti-clathrin or with wheat germ lectin as a Golgi apparatus marker. Both antisera gave staining that was coincident with anti-clathrin, with punctate labeling of the plasma membrane and perinuclear Golgi apparatus labeling. Thus, the 100K proteins are present on endocytic as well as Golgi-derived coated pits and vesicles. The punctate patterns were nearly identical with anti-100K and anti-clathrin, indicating that when vesicles become uncoated, the 100K proteins are removed as well as clathrin. One of the two antisera gave stronger plasma membrane labeling than Golgi apparatus labeling when compared with the anti-clathrin antiserum. The other antiserum gave stronger Golgi apparatus labeling. Although we have as yet no evidence that these two antisera label different proteins on blots of 3T3 cells, they do show differences on blots of bovine brain 100K proteins. This result, although preliminary, raises the possibility that different 100K proteins may be associated with different pathways of membrane traffic.     

Architecture of coatomer: molecular characterization of delta-COP and protein interactions within the complex

Coatomer is a cytosolic protein complex that forms the coat of COP I- coated transport vesicles. In our attempt to analyze the physical and functional interactions between its seven subunits (coat proteins, [COPs] alpha-zeta), we engaged in a program to clone and characterize the individual coatomer subunits. We have now cloned, sequenced, and overexpressed bovine alpha-COP, the 135-kD subunit of coatomer as well as delta-COP, the 57-kD subunit and have identified a yeast homolog of delta-COP by cDNA sequence comparison and by NH2-terminal peptide sequencing. delta-COP shows homologies to subunits of the clathrin adaptor complexes AP1 and AP2. We show that in Golgi-enriched membrane fractions, the protein is predominantly found in COP I-coated transport vesicles and in the budding regions of the Golgi membranes. A knock-out of the delta-COP gene in yeast is lethal. Immunoprecipitation, as well as analysis exploiting the two-hybrid system in a complete COP screen, showed physical interactions between alpha- and epsilon-COPs and between beta- and delta-COPs. Moreover, the two-hybrid system indicates interactions between gamma- and zeta-COPs as well as between alpha- and beta' COPs. We propose that these interactions reflect in vivo associations of those subunits and thus play a functional role in the assembly of coatomer and/or serve to maintain the molecular architecture of the complex.