Recognition sites for clathrin-associated proteins AP-2 and AP-3 on clathrin triskelia.

AP-2 and AP-3 are cellular proteins that drive the in vitro polymerization of clathrin triskelia into cage structures. The interaction of these two types of assembly proteins (APs) with preassembled clathrin cages has been studied in order to identify the sites on the triskelia required for binding. Comparing binding of the APs to intact or to proteolytically clipped cages, we attempted to distinguish between binding to the terminal domain, the globular end of the heavy chain, and binding to the hub of the clathrin triskelia, the portion that remains assembled after trypsin treatment. AP-3 binds to intact clathrin cages but not to those that were treated with trypsin. AP-3 also bound to cages consisting solely of clathrin heavy chains; proteolysis of these cages also eliminated AP-3 binding. In addition, AP-3 did not bind to either isolated hubs or terminal domains that had been immobilized on Sepharose. These data indicate that clathrin light chains are not required for binding of AP-3, and that neither terminal domain nor hubs alone will suffice. However, an intact heavy chain is both necessary and sufficient for the binding of AP-3. Previous work has demonstrated one binding site for AP-2 on proteolyzed cages containing only clathrin hubs; the existence of a second binding site associated with the terminal domain was hypothesized. Here we provide direct evidence for recognition by AP-2 of isolated terminal domains immobilized on Sepharose and show that the core of the AP-2 molecule is responsible for this interaction. These results provide the first demonstration of a functional role for the conserved terminal domain of the clathrin heavy chain.     

Clathrin coats at 21 A resolution: a cellular assembly designed to recycle multiple membrane receptors.

We present a map at 21 A resolution of clathrin assembled into cages with the endocytic adaptor complex, AP-2. The map was obtained by cryo-electron microscopy and single-particle reconstruction. It reveals details of the packing of entire clathrin molecules as they interact to form a cage with two nested polyhedral layers. The proximal domains of each triskelion leg depart from a cage vertex in a skewed orientation, forming a slightly twisted bundle with three other leg domains. Thus, each triskelion contributes to two connecting edges of the polyhedral cage. The clathrin heavy chains continue inwards under the vertices with local 3-fold symmetry, the terminal domains contributing to 'hook-like' features which form an intermediate network making possible contacts with the surface presented by the inner adaptor shell. A node of density projecting inwards from the vertex may correspond to the C-termini of clathrin heavy chains which form a protrusion on free triskelions at the vertex. The inter-subunit interactions visible in this map provide a structural basis for considering the assembly of clathrin coats on a membrane and show the contacts which will need to be disrupted during disassembly.     

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.     

γ Subunit of the AP-1 Adaptor Complex Binds Clathrin: Implications for Cooperative Binding in Coated Vesicle Assembly

The heterotetrameric AP-1 adaptor complex is involved in the assembly of clathrin-coated vesicles originating from the trans-Golgi network (TGN). The beta 1 subunit of AP-1 is known to contain a consensus clathrin binding sequence, LLNLD (the so-called clathrin box motif), in its hinge segment through which the beta chain interacts with the N-terminal domains of clathrin trimers. Here, we report that the hinge region of the gamma subunit of human and mouse AP-1 contains two copies of a new variant, LLDLL, of the clathrin box motif that also bind to the terminal domain of the clathrin heavy chain. High-affinity binding of the gamma hinge to clathrin trimers requires both LLDLL sequences to be present and the spacing between them to be maintained. We also identify an independent clathrin-binding site within the appendage domain of the gamma subunit that interacts with a region of clathrin other than the N-terminal domain. Clathrin polymerization is promoted by glutathione S-transferase (GST)-gamma hinge, but not by GST-gamma appendage. However, the hinge and appendage domains of gamma function in a cooperative manner to recruit and polymerize clathrin, suggesting that clathrin lattice assembly at the TGN involves multivalent binding of clathrin by the gamma and beta1 subunits of AP-1.     

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.     

Complete reconstitution of clathrin basket formation with recombinant protein fragments: adaptor control of clathrin self-assembly

Clathrin polymerization into a polyhedral basket, surrounding budding membrane vesicles, mediates protein sorting during endocytosis and organelle biogenesis. Adaptor proteins target clathrin assembly to specific membrane sites and sequester receptors into the clathrin coat. We have reconstituted complete clathrin basket formation from recombinantly expressed fragments of clathrin and adaptors. This reconstitution reveals a hierarchy of clathrin self-assembly interactions and demonstrates that adaptors control basket formation by alignment of the distal domains of the clathrin triskelion leg through their binding to the terminal domain.     

The appendage domain of the AP-2 subunit is not required for assembly or invagination of clathrin-coated pits

Coated pits contain a resident membrane molecule(s) that binds clathrin AP-2 with high affinity. AP-2 binding to this site is likely to be the first step in coated pit assembly because this subunit functions as a template for the polymerization of clathrin into flat polygonal lattices. Integral membrane proteins involved in receptor mediated endocytosis cluster in the newly assembled pits as they invaginate and bud from the membrane. The AP-2 subunit is a multi-domain, molecular complex that can be separated by proteolysis into a brick-shaped core and ear-like appendage domains. We have used this property to identify the domain involved in the various stages of coated pit assembly and budding. We found that the core of AP-2 is the domain that binds both to membranes and to triskelions during assembly. Triskelions are perfectly capable of forming lattices on the membrane bound cores. Clathrin lattices bound only to core domains were also able to invaginate normally. Limited proteolysis was also useful for further characterizing the AP-2 binding site. Elastase treatment of the inside membrane surface released a peptide fraction that is able to bind AP-2 in solution and prevent it from interacting with membranes. Affinity purification of binding activity yielded a collection of peptides that was dominated by a 45-kD species. This is the candidate peptide for containing the AP-2-binding site. Therefore, the appendage domain does not directly participate in any of the assembly or invagination events required for coated pit function.     

Interaction of phosphoinositide cycle intermediates with the plasma membrane-associated clathrin assembly protein AP-2.

Several components of the phosphoinositide cycle have been found to interact specifically and at physiological concentrations with the plasma membrane-associated clathrin assembly (adaptor) protein AP-2. These include phosphatidylinositol 4,5-bisphosphate and inositol 1,4,5-trisphosphate, which are present at the plasma membrane, as well as other polyphosphoinositols. ATP and other polyphosphate molecules complete with the polyphosphoinositols, however, they are at least 80-fold less potent. Also, the effect of ATP, unlike the polyphosphoinositols, is blocked by physiological concentrations of Mg2+. Photoaffinity labeling of AP-2 by [alpha-32P]8-azidoadenosine 5'-triphosphate and its competition by polyphosphoinositols has been used to identify the alpha subunit of the AP-2 complex as the site of specific interaction with the polyphosphoinositols and to confirm direct ultrafiltration binding experiments. Proteolytic dissection of the labeled AP-2 demonstrated that binding occurred exclusively on the N-terminal portion of the alpha subunit. Interaction of purified AP-2 with sub-microM concentrations of polyphosphoinositols has inhibitory effects on a novel AP-2 self-association described in the accompanying paper (Beck, K. A., and Keen, J. H., J. Biol. Chem. 266, 4437-4441), and at higher concentrations on the binding of AP-2 to dissociated clathrin trimers as well as AP-2-mediated clathrin coat assembly. Review of the literature shows that several physiological stimuli that are known to result in increased coat pit formation in intact cells correlate with increased phosphoinositide turnover. These in vivo correlations and the in vitro observations reported here suggest that coated membrane and phosphoinositide cycles may be interdependent within cells.     

Clathrin self-assembly involves coordinated weak interactions favorable for cellular regulation

The clathrin triskelion self-assembles into a polyhedral coat surrounding membrane vesicles that sort receptor cargo to the endocytic pathway. A triskelion comprises three clathrin heavy chains joined at their C-termini, extending into proximal and distal leg segments ending in a globular N-terminal domain. In the clathrin coat, leg segments entwine into parallel and anti-parallel interactions. Here we define the contributions of segmental interactions to the clathrin assembly reaction and measure the strength of their interactions. Proximal and distal leg segments were found to lack sufficient affinity to form stable homo- or heterodimers under assembly conditions. However, chimeric constructs of proximal or distal leg segments, trimerized by replacement of the clathrin trimerization domain with that of the invariant chain protein, were able to self-assemble in reversible reactions. Thus clathrin assembly occurs because weak leg segment affinities are coordinated through trimerization, sharing a dependence on multiple weak interactions with other biopolymers. Such polymerization is sensitive to small environmental changes and is therefore compatible with cellular regulation of assembly, disassembly and curvature during formation of clathrin-coated vesicles.     

Two classes of binding sites for uncoating protein in clathrin triskelions

Clathrin released from coated vesicles or empty cages by the ATP-dependent action of uncoating protein exists as a complex with the uncoating protein. Despite its apparent consumption during a round of uncoating, we have found that uncoating protein functions as an enzyme in that it rapidly and spontaneously recycles from its product (triskelions) to its substrate (cages). The binding of uncoating protein to clathrin triskelions is a complex equilibrium that involves the interaction of uncoating protein with at least two distinct sites on the clathrin molecule. Limited proteolysis dissected clathrin into two domains, each of which contained distinct binding sites. Binding to one of these sites, located on the proximal leg of a triskelion, was dependent upon the presence of light chains and was unstable to gel filtration. Binding to the second kind of site, located on the distal portion of a triskelion leg, was stable to gel filtration and was independent of the presence of light chains.     

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.     

Interaction of assembly protein AP-2 and its isolated subunits with clathrin

The clathrin assembly protein complex AP-2 is a multimeric subunit complex consisting of two 100-115-kDa subunits known as alpha and beta and 50- and 16-kDa subunits. The subunits have been dissociated and separated by ion-exchange chromatography in 7.5 M urea. Fractions highly enriched in either the alpha or beta subunit were obtained. The alpha fraction interacted with clathrin as evidenced by its ability to bind to preassembled clathrin cages. It also reacted with dissociated clathrin trimers under conditions that favor assembly of coat structures, but did not yield discrete clathrin polygonal lattices. The enriched beta fraction (containing small amounts of alpha) reacted with clathrin to yield intact coats with the incorporation of approximately equivalent amounts of alpha and beta subunits into the polymerized species; excess free beta subunit was unreactive. The AP-2 complex was also completely dissociated in a highly denaturing solvent, 6 M Gdn.HCl, and the constituent subunits of 100-115, 50, and 16 kDa were separated by gel filtration. In a coassembly assay with clathrin, the clathrin polymerizing activity was exclusively associated with the 100-kDa subunit fraction with stoichiometric incorporation of both alpha and beta subunits of 100 kDa into the polymerized coats, and with no requirement for 50- or 16-kDa subunits. These observations demonstrate that the assembly activity of the complex is associated with the alpha and beta subunits and suggest that both subunits, through independent interactions with clathrin, are required for expression of complete lattice assembly activity.     

Clathrin heavy chain, light chain interactions

Purified pig brain clathrin can be reversibly dissociated and separated into heavy chain trimers and light chains in the presence of non-denaturing concentrations of the chaotrope thiocyanate. The isolated heavy chain trimers reassemble into regular polygonal cage structures in the absence of light chains. The light chain fraction can be further resolved into its two components L alpha and L beta which give different one-dimensional peptide maps. Radiolabelled light chains bind with high affinity (KD < 10(-10) M) to heavy chain trimers, to heavy chain cages and to a 110,000 mol. wt. tryptic fragment of the heavy chain. Both light chains compete with each other and with light chains from other sources for the same binding sites on heavy chains and c.d. spectroscopy shows that the two pig brain light chains possess very similar structures. We conclude that light chains from different sources, despite some heterogeneity, have a highly conserved, high affinity binding site on the heavy chain but are not essential for the formation of regular cage structures.     

The LDL Receptor Clustering Motif Interacts with the Clathrin Terminal Domain in a Reverse Turn Conformation

Previously the hexapeptide motif FXNPXY₈₀₇ in the cytoplasmic tail of the LDL receptor was shown to be essential for clustering in clathrin-coated pits. We used nuclear magnetic resonance line-broadening and transferred nuclear Overhauser effect measurements to identify the molecule in the clathrin lattice that interacts with this hexapeptide, and determined the structure of the bound motif. The wild-type peptide bound in a single conformation with a reverse turn at residues NPVY. Tyr₈₀₇Ser, a peptide that harbors a mutation that disrupts receptor clustering, displayed markedly reduced interactions. Clustering motif peptides interacted with clathrin cages assembled in the presence or absence of AP2, with recombinant clathrin terminal domains, but not with clathrin hubs. The identification of terminal domains as the primary site of interaction for FXNPXY₈₀₇ suggests that adaptor molecules are not required for receptor-mediated endocytosis of LDL, and that at least two different tyrosine-based internalization motifs exist for clustering receptors in coated pits.     

AP180 and AP-2 interact directly in a complex that cooperatively assembles clathrin.

Clathrin-coated vesicles are involved in protein and lipid trafficking between intracellular compartments in eukaryotic cells. AP-2 and AP180 are the resident coat proteins of clathrin-coated vesicles in nerve terminals, and interactions between these proteins could be important in vesicle dynamics. AP180 and AP-2 each assemble clathrin efficiently under acidic conditions, but neither protein will assemble clathrin efficiently at physiological pH. We find that there is a direct, clathrin-independent interaction between AP180 and AP-2 and that the AP180-AP-2 complex is more efficient at assembling clathrin under physiological conditions than is either protein alone. AP180 is phosphorylated in vivo, and in crude vesicle extracts its phosphorylation is enhanced by stimulation of casein kinase II, which is known to be present in coated vesicles. We find that recombinant AP180 is a substrate for casein kinase II in vitro and that its phosphorylation weakens both the binding of AP-2 by AP180 and the cooperative clathrin assembly activity of these proteins. We have localized the binding site for AP-2 to amino acids 623-680 of AP180. The AP180/AP-2 interaction can be disrupted by a recombinant AP180 fragment containing the AP-2 binding site, and this fragment also disrupts the cooperative clathrin assembly activity of the AP180-AP-2 complex. These results indicate that AP180 and AP-2 interact directly to form a complex that assembles clathrin more efficiently than either protein alone. Phosphorylation of AP180, by modulating the affinity of AP180 for AP-2, may contribute to the regulation of clathrin assembly in vivo.     

Multi‐modal adaptor‐clathrin contacts drive coated vesicle assembly

Clathrin‐coated pits are formed by the recognition of membrane and cargo by the AP2 complex and the subsequent recruitment of clathrin triskelia. A role for AP2 in coated‐pit assembly beyond initial clathrin recruitment has not been explored. Clathrin binds the β2 subunit of AP2, and several binding sites have been identified, but our structural knowledge of these interactions is incomplete and their functional importance during endocytosis is unclear. Here, we analysed the cryo‐EM structure of clathrin cages assembled in the presence of β2 hinge‐appendage (β2HA). We find that the β2‐appendage binds in at least two positions in the cage, demonstrating that multi‐modal binding is a fundamental property of clathrin‐AP2 interactions. In one position, β2‐appendage cross‐links two adjacent terminal domains from different triskelia. Functional analysis of β2HA‐clathrin interactions reveals that endocytosis requires two clathrin interaction sites: a clathrin‐box motif on the hinge and the “sandwich site” on the appendage. We propose that β2‐appendage binding to more than one triskelion is a key feature of the system and likely explains why assembly is driven by AP2.     

Overexpression of the myelin proteolipid protein leads to accumulation of cholesterol and proteolipid protein in endosomes/lysosomes: implications for Pelizaeus-Merzbacher disease

The mouse mutants mocha and pearl are deficient in the AP-3 delta and beta3A subunits, respectively. We have used cells from these mice to investigate both the assembly of AP-3 complexes and AP-3 function. In mocha cells, the beta3 and mu3 subunits coassemble into a heterodimer, whereas the sigma3 subunit remains monomeric. In pearl cells, the delta and sigma3 subunits coassemble into a heterodimer, whereas mu3 gets destroyed. The yeast two hybrid system was used to confirm these interactions, and also to demonstrate that the A (ubiquitous) and B (neuronal-specific) isoforms of beta3 and mu3 can interact with each other. Pearl cell lines were generated that express beta3A, beta3B, a beta3Abeta2 chimera, two beta3A deletion mutants, and a beta3A point mutant lacking a functional clathrin binding site. All six constructs assembled into complexes and were recruited onto membranes. However, only beta3A, beta3B, and the point mutant gave full functional rescue, as assayed by LAMP-1 sorting. The beta3Abeta2 chimera and the beta3A short deletion mutant gave partial functional rescue, whereas the beta3A truncation mutant gave no functional rescue. These results indicate that the hinge and/or ear domains of beta3 are important for function, but the clathrin binding site is not needed.     

Multiple interactions of auxilin 1 with clathrin and the AP-2 adaptor complex

The removal of the clathrin coat is essential for vesicle fusion with acceptor membranes. Disassembly of the coat involves hsc70, which is specifically recruited by members of the auxilin protein family to clathrin lattices. In vitro, this function of auxilin does not require the globular amino-terminal domain of the clathrin heavy chain, which is known to play a prominent role in the interaction of clathrin with adaptors and numerous endocytic accessory proteins. Here we report the unexpected finding that the neuron-specific form of auxilin (auxilin 1) can also associate with the clathrin amino-terminal domain. This interaction is mediated through tandemly arranged sites within the auxilin 1 carboxyl-terminal segment 547-910. The overlapping auxilin 1 fragments 547-714 and 619-738 bind the clathrin terminal domain with high affinity, whereas auxilin 1-(715-901) interacts only poorly with it. All three fragments also associate with the clathrin distal domain and the alpha-appendage domain of AP-2. Moreover, they support efficient assembly of clathrin triskelia into regular cages. A novel uncoating assay was developed to demonstrate that auxilin 1-(715-901) functions efficiently as a cofactor for hsc70 in the uncoating of clathrin-coated vesicles. The multiple protein-protein interactions of auxilin 1 suggest that its function in endocytic trafficking may be more complex than previously anticipated.     

Sorting it out: AP-2 and alternate clathrin adaptors in endocytic cargo selection

The AP-2 adaptor complex is widely viewed as a linchpin molecule in clathrin-mediated endocytosis, simultaneously binding both clathrin and receptors. This dual interaction couples cargo capture with clathrin coat assembly, but it has now been discovered that the association with cargo is tightly regulated. Remarkably, AP-2 is not obligatory for all clathrin-mediated uptake, and several alternate adaptors appear to perform similar sorting and assembly functions at the clathrin bud site.     

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.