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.     

Adaptor complex-independent clathrin function in yeast

Clathrin-associated adaptor protein (AP) complexes are major structural components of clathrin-coated vesicles, functioning in clathrin coat assembly and cargo selection. We have carried out a systematic biochemical and genetic characterization of AP complexes in Saccharomyces cerevisiae. Using coimmunoprecipitation, the subunit composition of two complexes, AP-1 and AP-2R, has been defined. These results allow assignment of the 13 potential AP subunits encoded in the yeast genome to three AP complexes. As assessed by in vitro binding assays and coimmunoprecipitation, only AP-1 interacts with clathrin. Individual or combined disruption of AP-1 subunit genes in cells expressing a temperature-sensitive clathrin heavy chain results in accentuated growth and alpha-factor pheromone maturation defects, providing further evidence that AP-1 is a clathrin adaptor complex. However, in cells expressing wild-type clathrin, the same AP subunit deletions have no effect on growth or alpha-factor maturation. Furthermore, gel filtration chromatography revealed normal elution patterns of clathrin-coated vesicles in cells lacking AP-1. Similarly, combined deletion of genes encoding the beta subunits of the three AP complexes did not produce defects in clathrin-dependent sorting in the endocytic and vacuolar pathways or alterations in gel filtration profiles of clathrin-coated vesicles. We conclude that AP complexes are dispensable for clathrin function in S. cerevisiae under normal conditions. Our results suggest that alternative factors assume key roles in stimulating clathrin coat assembly and cargo selection during clathrin-mediated vesicle formation in yeast.     

Homology between antigenic determinants of bovine clathrin and clathrin from the brown alga Laminaria digitata

Coated vesicles, essential organelles of intracellular membrane traffic, have been extensively studied in animal and higher plant cells. In the algae, cytological studies only have been performed which demonstrate the presence of such coated vesicles with their surrounding clathrin lattice. The present work has been carried out on coated vesicles isolated for the first time from the brown algae Laminaria digitata. For comparison of the antigenic characteristics of clathrin prepared from the Bovine brain or adrenocortical cells and the clathrin prepared from algae, polyclonal antibodies have been raised to a purified Bovine brain clathrin in Goat and to Bovine adrenocortical clathrin in Rabbit. The positive immunological responses of the coated vesicles and the clathrin from Algae to these antibodies, evidence an homology between antigenic determinants of clathrin from animal and vegetal cells.     

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.     

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.     

Purification and characterization of two distinct complexes of assembly polypeptides from calf brain coated vesicles that differ in their polypeptide composition and kinase activities

The binding and assembly of clathrin triskelions on vesicle membranes seem to be mediated by certain assembly polypeptides (Keen, J.H., Willingham, M.C., and Pastau, I.H. (1979) Cell 16, 303-312). These assembly polypeptides were further purified into two distinct complexes using hydroxylapatite chromatography. Peak 1 consists of two major bands of 98 and 112 kDa, two minor bands of 103 and 118 kDa, and a polypeptide of 46 kDa. Peak 2 consists of one major band of 100 kDa, two minor bands of 103 and 115 kDa, and a polypeptide of 50 kDa. Both complexes have a native molecular mass of 290 kDa as determined by gel filtration. Each 290-kDa complex contains two polypeptides of 98-118/100-115 kDa and two polypeptides of 46/50 kDa. The 46-kDa polypeptide is not phosphorylated, whereas the 50-kDa polypeptide is. Both peaks contain 50-kDa kinase-like activity. Time courses of the 50-kDa phosphorylation show that the activity in peak 1 saturates much faster than the activity in peak 2; there may be two 50-kDa kinase activities in coated vesicles. A kinase that phosphorylates the polypeptides in 98-118-kDa group is present in peak 1 but not in peak 2. Both peaks assemble clathrin triskelions into cages under conditions in which the clathrin alone would not assemble. Both rotary shadowed and negatively stained preparations of these reassembled cages as well as the purified complexes were examined by electron microscopy. Thus, two complexes have been identified that differ in their polypeptide composition and kinase activities, but are similar in their ability to assemble clathrin triskelions into cages.     

Uncoating of clathrin-coated vesicles by uncoating ATPase from developing peas.

A cytosolic ATPase (an enzyme that dissociates clathrin from clathrin-coated vesicles in the presence of ATP) was isolated from developing pea (Pisum sativum L.) cotyledons using chromatography on ATP-agarose. After chromatography on phenyl Sepharose, the fraction with uncoating activity was enriched in a doublet of 70-kD peptides. Using chromatofocusing, it was possible to produce fractions enriched in the upper component of the doublet of 70-kD peptides; these fractions still retained ATP-dependent uncoating activity. In western blot analysis, antibodies against a member of the 70-kD family of heat-shock proteins interacted with the upper component of the doublet of the 70-kD peptides from the phenyl Sepharose-purified fractions. On the basis of these data, it appears that the uncoating ATPase may be a member of the 70-kD family of heat-shock proteins. The uncoating activity removed clathrin from both pea and bovine brain clathrin-coated vesicles. The uncoating ATPase from bovine brain also uncoated coated vesicles from peas. Pea clathrin-coated vesicles that were prepared by three different methods were uncoated to different extents by the plant uncoating ATPase. Different populations of clathrin-coated vesicles from the same preparation showed differential sensitivity to the uncoating ATPase. Limited proteolysis of the clathrin light chains in the protein coat abolished the susceptibility of the clathrin-coated vesicles to the uncoating ATPase. The properties of the uncoating ATPase isolated from developing pea cotyledons are similar to those of uncoating ATPases previously described from mammalian and yeast systems. It appears that despite dissimilarities in composition of the clathrin components of the vesicles from the respective sources, uncoating is achieved by a common mechanism.     

Eps15 homology domain-NPF motif interactions regulate clathrin coat assembly during synaptic vesicle recycling

Although genetic and biochemical studies suggest a role for Eps15 homology domain containing proteins in clathrin-mediated endocytosis, the specific functions of these proteins have been elusive. Eps15 is found at the growing edges of clathrin-coated pits, leading to the hypothesis that it participates in the formation of coated vesicles. We have evaluated this hypothesis by examining the effect of Eps15 on clathrin assembly. We found that although Eps15 has no intrinsic ability to assemble clathrin, it potently stimulates the ability of the clathrin adaptor protein, AP180, to assemble clathrin at physiological pH. We have also defined the binding sites for Eps15 on squid AP180. These sites contain an NPF motif, and peptides derived from these binding sites inhibit the ability of Eps15 to stimulate clathrin assembly in vitro. Furthermore, when injected into squid giant presynaptic nerve terminals, these peptides inhibit the formation of clathrin-coated pits and coated vesicles during synaptic vesicle endocytosis. This is consistent with the hypothesis that Eps15 regulates clathrin coat assembly in vivo, and indicates that interactions between Eps15 homology domains and NPF motifs are involved in clathrin-coated vesicle formation during synaptic vesicle recycling.     

Reversibility of coated vesicle dissociation

The dissociation of the coated vesicles to clathrin and uncoated vesicles and their reassociation have been studied under various conditions. The extent of reassociation is pH dependent and increases slightly with increasing concentrations of the components. Unlike the self-association of clathrin which is strongly salt dependent, the reassociation of clathrin and uncoated vesicles is practically independent of salt concentration. The coated vesicle gradually loses its coat with increasing pH, and the dissociation process is not an all or none reaction. Ca2+ inhibits dissociation of the coated vesicles and enhances the reassociation of clathrin and uncoated vesicles. Our results show that, although many conditions result in reassociation of protein and lipid vesicle, few conditions result in vesicles of both the same size and composition as native coated vesicles.     

Coat formation in coated vesicles

The proteins of Mr 100 000-110 000 present in the protein coat of coated vesicles have been shown to facilitate formation of a homogeneous small-size basket (coat) when added to clathrin [Zaremba, S., & Keen, J.H. (1983) J. Cell Biol. 97, 1339]. We have prepared this protein of coat proteins by two different methods and shown that they are very important for the binding of clathrin to uncoated vesicles to form coated vesicles. By labeling the three components (clathrin, 100 000-110 000 proteins, and uncoated vesicles) with different fluorescent markers and analyzing their distribution on sucrose gradients, we have been able to determine the composition of the products formed. In the presence of the 100 000-100 000 fraction of coat proteins, not only does the size distribution of the clathrin basket become uniform but also the rate of polymerization is strongly increased.     

Human erythrocyte clathrin and clathrin-uncoating protein

Clathrin, a Mr = 72,000 clathrin-associated protein, and myosin were purified in milligram quantities from the same erythrocyte hemolysate fraction. Erythrocyte clathrin closely resembled brain clathrin in several respects: (a) both are triskelions as visualized by electron microscopy with arms 40 nm in length with globular ends and a flexible hinge region in the middle of each arm, and these triskelions assemble into polyhedral "cages" at appropriate pH and ionic strength; (b) both molecules contain heavy chains of Mr = 170,000 that are indistinguishable by two-dimensional maps of 125I-labeled peptides; and (c) both molecules contain light chains of Mr approximately 40,000 in a 1:1 molar ratio with the heavy chain. Erythrocyte clathrin is not identical to brain clathrin since antibody raised against the erythrocyte protein reacts better with erythrocyte clathrin than with brain clathrin and since brain clathrin contains two light chains resolved on sodium dodecyl sulfate gels while the light chain of erythrocyte clathrin migrates as a single band. The erythrocyte Mr = 72,000 clathrin-associated protein is closely related to a protein in brain that mediates ATP-dependent disassembly of clathrin from coated vesicles and binds tightly to clathrin triskelions (Schlossman, D. M., Schmid, S. L., Braell, W. A., and Rothman, J. E. (1984) J. Cell Biol. 99, 723-733). The erythrocyte and brain proteins have identical Mr on sodium dodecyl sulfate gels and identical maps of 125I-labeled peptides, share antigenic sites, and bind tightly to ATP immobilized on agarose. Clathrin and the uncoating protein are not restricted to reticulocytes since equivalent amounts of these proteins are present in whole erythrocyte populations and reticulocyte-depleted erythrocytes. Clathrin is present at 6,000 triskelions/cells, while the uncoating protein is in substantial excess at 250,000 copies/cell.     

Heterogeneous distribution of synaptophysin and protein 65 in synaptic vesicles isolated from rat cerebral cortex

Rat brain cerebral cortex derived synaptic vesicles sedimenting on a 0.4 M sucrose solution were further fractionated according to size by column chromatography on Sephacryl-1000 and analyzed for their binding activities of antibodies directed against the vesicle-associated proteins synaptophysin, synapsin I, protein 65 and clathrin. Whereas synapsin I and particularly protein 65 and clathrin are associated with a large range of vesicle sizes, synaptophysin elutes with small vesicles only. Using monoclonal antibodies against either synaptophysin or protein 65 and polyacrylamide beads for solid matrix immunoprecipitation, significant differences could be revealed in the protein composition of the resulting vesicle populations. Whereas synapsin I is associated with both synaptophysin and protein 65 immunoprecipitated vesicle populations, synaptophysin appears to be only a minor constituent of vesicles precipitated with anti-protein 65. Vesicles precipitated with anti-synaptophysin antibodies are enriched in acetylcholine. Our results suggest that the vesicle membrane protein synaptophysin and protein 65 may not have a ubiquitous distribution among synaptic vesicles. Protein 65 containing large vesicle populations contain little synaptophysin and synaptophysin is mainly associated with synaptic vesicles of small diameter.     

Characterization of the coated vesicle uncoating ATPase: tissue distribution, association with and activity on intact coated vesicles

We have analyzed the uncoating process of clathrin-coated vesicles (CV) performed by an ATPase (UA; apparent molecular mass 70 kDa) prepared from various mammalian tissues. Our data show that this enzyme removes the clathrin coat from isolated, intact coated vesicles, as seen by sedimentation analysis on gels and also by electron microscopy. The isolated UA does not discriminate between CV from homologous or heterologous tissues. This finding implies that the brain-specific insertion in clathrin light chains cannot be essential for the binding of brain UA to target vesicles. Polyclonal antibodies were raised against UA and were found to inhibit UA activity. Immunoblotting of purified CV and immunoblotting of CV in situ indicate that a subpopulation of CV contains bound UA. However, most of the uncoating enzyme is not associated with coated structures in mammalian tissue culture cells. Our data support the hypothesis that the 70 kDa uncoating ATPase is responsible for the in vivo uncoating of coated vesicles.     

Phosphorylation of the medium chain subunit of the AP-2 adaptor complex does not influence its interaction with the tyrosine based internalisation motif of TGN38

Tyrosine based motifs conforming to the consensus YXXphi (where phi represents a bulky hydrophobic residue) have been shown to interact with the medium chain subunit of clathrin adaptor complexes. These medium chains are targets for phosphorylation by a kinase activity associated with clathrin coated vesicles. We have used the clathrin coated vesicle associated kinase activity to specifically phosphorylate a soluble recombinant fusion protein of mu2, the medium chain subunit of the plasma membrane associated adaptor protein complex AP-2. We have tested whether this phosphorylation has any effect on the interaction of mu2 with the tyrosine based motif containing protein, TGN38, that has previously been shown to interact with mu2. Phosphorylation of mu2 was shown to have no significant effect on the in vitro interaction of mu2 with the cytosolic domain of TGN38, indicating that reversible phosphorylation of mu2 does not play a role in regulating its direct interaction with tyrosine based internalisation motifs. In addition, although a casein kinase II-like activity has been shown to be associated with clathrin coated vesicles, we show that mu2 is not phosphorylated by casein kinase II implying that another kinase activity is present in clathrin coated vesicles. Furthermore the kinase activity associated with clathrin coated vesicles was shown to be capable of phosphorylating dynamin 1. Phosphorylation of dynamin 1 has previously been shown to regulate its interaction with other proteins involved in clathrin mediated endocytosis.     

The association of clathrin fragments with coated vesicle membranes

The association between clathrin triskelions and the clathrin-stripped membranes of coated vesicles has been investigated using a filter assay to separate bound from unbound clathrin. The filter assay is more sensitive and less cumbersome than a sedimentation assay used previously (1). While confirming the high affinity interaction between clathrin and the vesicle membrane, our results yield Scatchard plots that are curvilinear and consistent with a positively cooperative interaction between clathrin and the vesicle membranes. Controlled digestion with trypsin removes the distal portions of the triskelion legs leaving the proximal 31 nm portions that form the hub of the triskelions. These hubs are trimers of large 112,000- and 124,000-dalton fragments of clathrin heavy chains. They competitively inhibit the binding of 125I-labeled intact triskelions to stripped vesicles with a KI identical to the KD for the association of 125I-labeled intact triskelions to stripped vesicles. Furthermore, these large fragment trimers bind to stripped vesicles with approximately the same high affinity as do intact triskelions and also show evidence of a positively cooperative interaction. It is concluded that clathrin binds to coated vesicles by an interaction that is mediated by the proximal 112,000-dalton fragment of the clathrin heavy chains.     

Evidence for the interaction of alpha-actinin and calmodulin with the clathrin heavy chain

In the present study protein overlays were used to study the molecular interactions of clathrin with clathrin coat-associated proteins. Coated vesicles (CV) were isolated, subjected to sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), and transferred to nitrocellulose. The transfers were quenched and equilibrated in buffer, containing 1% Triton X-100. Alpha-Actinin and calmodulin, proteins known to interact with coated vesicles, were iodinated, placed in buffer, and incubated over the transfer for 1 h. After being rinsed extensively, the total amount of 125I associated with the filters was measured, and the filters were then processed for autoradiography. For alpha-actinin, the clathrin heavy chain and a series of lower molecular weight proteins were labeled. The binding of 125I alpha-actinin was inhibited with cold ligand and selectively released from the transfer with a buffer know to strip alpha-actinin from plasma membrane preparations. For 125I calmodulin the predominant binding site was also the clathrin heavy chain. Cold ligand inhibited binding and 60% of the detectable binding were calcium dependent. In addition, when these ligands were used in competition with each other, no significant inhibition was detected in the amount of binding associated with the clathrin heavy chain. These studies show that the clathrin heavy chain is a primary site of the clathrin cage receptive to intracellular interactions and furthermore suggest that the clathrin heavy chain consists of domains of biochemical specificity which may selectively affect the activities of coated vesicles.     

Filipin-cholesterol complexes form in uncoated vesicle membrane derived from coated vesicles during receptor-mediated endocytosis of low density lipoprotein

Filipin has been widely used as an electron microscopic probe to detect 3-beta-hydroxysterols, principally cholesterol, in cellular membranes. When it complexes with sterol, it forms globular deposits that disrupt the planar organization of the membrane. Previous studies have shown that coated pits and coated vesicles, specialized membranes involved in receptor-mediated endocytosis, do not appear to bind filipin. This has led to the suggestion that these membranes are low in cholesterol compared with the remainder of the plasma membrane. Since coated endocytic vesicles become uncoated vesicles during the transport of internalized ligands to the lysosome, we have carried out studies to determine whether or not the membranes that surround these transport vesicles are unable to bind filipin and therefore, are also low in cholesterol. Cells were incubated with ferritin-conjugated ligands that bind to low density lipoprotein (LDL) receptors in coated pits. After allowing internalization of the conjugates, we fixed the cells in either the presence or absence of filipin. This permitted us to identify all of the vesicles involved in the transport of LDL to the lysosome and to determine whether the membranes of these vesicles were able to bind filipin. We found that, coordinate with the dissociation of the clathrin coat from the endocytic vesicles, the membranes became sensitive to the formation of filipin-sterol complexes. Furthermore, all of the uncoated endocytic vesicle membranes, as well as the lysosomal membranes, bound filipin. This suggests either that coated membrane contains normal cholesterol levels, which is not easily detected with filipin, or that cholesterol rapidly moves into endocytic vesicles after the clathrin coat dissociates from the membrane.     

Site-specific disruption of clathrin assembly produces novel structures.

Clathrin assembly in vitro produces a highly ordered polyhedral structure (basket). This resembles clathrin assembled in situ on coated pits and vesicles which form during receptor-mediated endocytosis. Sites on clathrin involved in assembly were identified by assembling clathrin in the presence of anti-clathrin monoclonal antibodies. Three of the antibodies, as IgG, prevented the assembly of normal baskets, and their Fab fragments induced formation of two types of novel clathrin structures. Antibody effects on assembly and competitive binding data indicate these antibodies bind to two sites, critical for clathrin interactions, located in the same region of the clathrin heavy chain. Analysis of novel structures formed, suggested that nucleation but not further assembly was occurring, implying an ordered sequence of clathrin interactions during assembly.     

CVAK104 is a novel poly-L-lysine-stimulated kinase that targets the beta2-subunit of AP2

Isolated clathrin adaptor protein (AP) preparations are known to co-fractionate with endogenous kinase activities, including poly-L-lysine-stimulated kinases that target various constituents of the clathrin coat. We have identified CVAK104 (a coated vesicle-associated kinase of 104 kDa) using a mass spectroscopic analysis of adaptor protein preparations. CVAK104 is a novel serine/threonine kinase that belongs to the SCY1-like family of protein kinases, previously thought to be catalytically inactive. We found that CVAK104 co-fractionates with adaptor protein preparations extracted from clathrin-coated vesicles and directly binds to both clathrin and the plasma membrane adaptor, AP2. CVAK104 binds ATP, and kinase assays indicate that it functions in vitro as a poly-L-lysine-stimulated kinase that is capable of autophosphorylation and phosphorylating the beta2-adaptin subunit of AP2.     

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.