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.

A Schwann cell-seeded intrinsic framework and its satisfactory biocompatibility for a bioartificial nerve graft.

To optimize the internal environment of a collagen nerve tube, we designed a Schwann cell-seeded intrinsic framework and its biocompatibility was investigated. We fixed 6-0 polyglactin woven filaments (Vicryl) or polydioxanone monofilaments (PDS) on a silicone ring in a net fashion. It was coated with matrigel and then incubated with cultured newborn or adult Schwann cells. Furthermore, we implanted 1.5-cm-long filament-filled collagen tubes in a rat model. Using a live/dead fluorescent assay and electron microscopy, we found that adherent Schwann cells onto filaments remained viable and oriented longitudinally along filaments. The preliminary in vivo study indicated that a mild inflammatory reaction was present around the tube wall. However, nerve regeneration occurred around and between filaments. We concluded that the arrangement of Schwann cell columns onto filaments was achieved, mimicking Bünger bands. It was shown that the biomaterials did not impede nerve regeneration.

Identification of the universal cofactor (auxilin 2) in clathrin coat dissociation.

Uncoating of clathrin-coated vesicles in neuronal cells requires hsc70 in concert with the cofactor auxilin which contains a J-domain as well as a domain with homology to dual specific phosphatases and tensin, known as PTEN. The question of whether an analogous factor operates in other cell types has until now remained unanswered. Here we show that it is the recently discovered and widely expressed cyclin G-associated protein kinase which fulfils the function of neuronal auxilin in hsc70-mediated clathrin coat dissociation. GAK possesses a J-domain, which stimulates the hsc70 ATPase, it competes with auxilin for clathrin binding and at sufficiently high concentrations acts as a clathrin assembly protein. Moreover, GAK binds to the gamma- and alpha-appendage domains of the adaptor proteins AP-1 and AP-2 in vitro and phosphorylates their medium chains. Cells that transiently overexpress GAK are impaired in respect of receptor-mediated endocytosis. In transfected cells clathrin is dislodged from coated pits/vesicles and co-localizes with GFP-GAK in the form of large aggregates. The cellular distribution of membrane-associated adaptors was unaffected by overexpression of GAK. Our results point to a hsc70/auxilin-based uncoating system as a ubiquitous feature of eukaryotic cells.

Clathrin: a good view of a shapely leg.

The crystal structure of an amino-terminal fragment of the clathrin heavy chain has recently been determined, revealing a globular beta-propeller domain attached by an alpha-zig-zag connecting rod to the heavy chain's distal segment. The structure sheds interesting new light on the design features of this versatile protein.

Functional interaction of the auxilin J domain with the nucleotide- and substrate-binding modules of Hsc70.

The uncoating of clathrin-coated vesicles requires the DnaJ homologue auxilin for targeting Hsc70 to clathrin coats. This function involves a transient interaction of the auxilin J domain with Hsc70. We have now identified the structural elements of Hsc70 that are responsible for the uncoating activity, and we show that the hitherto accepted view, which implicates the 10-kDa carboxyl-terminal variable domain of Hsc70, is incorrect. A 60-kDa chymotryptic or analogous recombinant fragment of Hsc70, which contains the ATPase- and substrate-binding domains, is sufficient to liberate clathrin from coated vesicles. Consistent with this was the observation that Hsp70 uncoats coated vesicles with the same efficacy as Hsc70 and that DnaK possesses vestigial uncoating activity. Direct binding studies demonstrated that the auxilin J domain undergoes an ATP-dependent reaction only with fragments of Hsc70 that contain both the ATPase- and substrate-binding domains. The individual domains by themselves did not bind to the J domain nor did a recombinant protein that contained the substrate-binding domain attached to the 10-kDa variable domain.

Mechanism of clathrin basket dissociation: separate functions of protein domains of the DnaJ homologue auxilin.

Auxilin was recently identified as cofactor for hsc70 in the uncoating of clathrin-coated vesicles (Ungewickell, E., H. Ungewickell, S.E. Holstein, R. Lindner, K. Prasad, W. Barouch, B. Martin, L.E. Greene, and E. Eisenberg. 1995. Nature (Lond.). 378: 632-635). By constructing different glutathione-S-transferase (GST)-auxilin fragments, we show here that cooperation of auxilin's J domain (segment 813-910) with an adjoining clathrin binding domain (segment 547-814) suffices to dissociate clathrin baskets in the presence of hsc70 and ATP. When the two domains are expressed as separate GST fusion proteins, the cofactor activity is lost, even though both retain their respective functions. The clathrin binding domain binds to triskelia like intact auxilin with a maximum stoichiometry of 3 and concomitantly promotes their assembly into regular baskets. A fragment containing auxilin's J domain associates in an ATP-dependent reaction with hsc70 to form a complex with a half-life of 8 min at 25 degrees C. When the clathrin binding domain and the J domain are recombined via dimerization of their GST moieties, cofactor activity is partially recovered. The interaction between auxilin's J domain and hsc70 causes rapid hydrolysis of bound ATP. Release of inorganic phosphate appears to be correlated with the disintegration of the complex between auxilin's J domain and hsc70. We infer that the metastable complex composed of auxilin, hsc70, ADP, and P(i) contains an activated form of hsc70, primed to engage clathrin that is brought into apposition with it by the DnaJ homologue auxilin.

Role of auxilin in uncoating clathrin-coated vesicles.

Clathrin-coated vesicles transport selected integral membrane proteins from the cell surface and the trans-Golgi network to the endosomal system. Before fusing with their target the vesicles must be stripped of their coats. This process is effected by the chaperone protein hsp70c together with a 100K cofactor which we here identify as the coat protein auxilin. Auxilin binds with high affinity to assembled clathrin lattices and, in the presence of ATP, recruits hsp70c. Dissociation of the lattice does not depend as previously supposed on clathrin light chains or on the amino-terminal domain of the heavy chain. The presence of a J-domain at its carboxy terminus now defines auxilin as a member of the DnaJ protein family. In conjunction with hsp70, DnaJ proteins catalyse protein folding, protein transport across membranes and the selective disruption of protein-protein interactions. We show that deletion of the J-domain of auxilin results in the loss of cofactor activity.

Primary structure of the neuronal clathrin-associated protein auxilin and its expression in bacteria.

The protein auxilin is a coat component of brain clathrin-coated vesicles. It interacts directly with the heavy chain of clathrin and supports its assembly into regular cages [Ahle, S. & Ungewickell, E. (1990) J. Cell Biol. 111, 19-29]. The combined open reading frames of three cow brain cDNA clones with a total of 4531 nucleotides predict a molecular mass of 99,504 Da for auxilin. The coding region is followed by a very long untranslated region of at least 1670 nucleotides. By Northern analysis, auxilin transcripts are found only in brain tissue. Auxilin is not related to any of the previously sequenced clathrin-binding proteins, but the region of positions 50-350 is 29% identical (similarity 56%) to the corresponding region of the actin-binding protein tensin from chicken fibroblasts. Recombinant auxilin expressed in and purified from bacteria by affinity chromatography is functional with respect to clathrin binding.

Different domains of the AP-1 adaptor complex are required for Golgi membrane binding and clathrin recruitment.

The assembly of clathrin-coated buds on the Golgi requires the recruitment of the heterotetrameric AP-1 adaptor complex, which is dependent on both guanine nucleotides and the small GTP-binding protein ADP-ribosylation factor (ARF). Here, we have investigated the structural domains of the AP-1 complex necessary for ARF-mediated translocation of the adaptor complex onto Golgi membranes and the subsequent recruitment of clathrin onto the membrane. Controlled proteolysis of purified AP-1, derived from bovine adrenal coated vesicles, was used to generate AP-1 core fragments composed of the amino-terminal trunk regions of the beta 1 and gamma subunits and associated mu 1 and sigma 1 subunits, and lacking either the beta 1 subunit carboxyl-terminal appendage or both beta 1 and gamma subunit appendages. On addition of these truncated fragments to AP-1-depleted adrenal cytosol, both types of core fragments were efficiently recruited onto Golgi membranes in the presence of GTP gamma S. Recruitment of both core fragments was inhibited by the fungal metabolite brefeldin A, indicative of an ARF-dependent process. Limited tryptic digestion of recruited, intact cytosolic AP-1 resulted in the quantitative release of the globular carboxyl-terminal appendage domains of the beta 1 and gamma subunits. The adaptor core complex remained associated with the Golgi membranes. Recruitment of cytosolic clathrin onto the Golgi membranes was strictly dependent on the presence of intact AP-1. Tryptic removal of the beta 1 subunit appendage prevented subsequent clathrin recruitment. We conclude that the structural determinants required for the ARF-mediated binding of cytosolic AP-1 onto Golgi membranes are contained within the adaptor core, and that the carboxyl-terminal appendage domains of the beta 1 and gamma subunits do not play any role in this process. Subsequent recruitment of cytosolic clathrin, however, requires an intact beta 1 subunit.

Inositol hexakisphosphate binds to clathrin assembly protein 3 (AP-3/AP180) and inhibits clathrin cage assembly in vitro.

We have isolated an inositol hexakisphosphate binding protein from rat brain by affinity elution chromatography from Mono S cation exchange resin using 0.1 mM inositol hexakisphosphate (InsP6). The amino acid sequences of six tryptic peptides from the protein were identical to the sequences predicted from the cDNA encoding a previously isolated protein designated as AP-3 or AP180. This protein is localized in nerve endings and promotes assembly of clathrin into coated vesicles. The isolated protein-bound InsP6 with a dissociation constant of 1.2 microM and a stoichiometry of 0.9 mol of InsP6 bound/mol of AP-3. Recombinant AP-3 expressed in Escherichia coli also bound InsP6 with a similar affinity. InsP6 inhibited clathrin cage assembly mediated by AP-3, in an in vitro assay, but had little effect AP-3 binding to preformed cages. We speculate that InsP6 and perhaps highly phosphorylated inositol lipids may play a role in coated vesicle formation.

Covalent anchoring of proteins onto gold-directed NHS-terminated self-assembled monolayers in aqueous buffers: SFM images of clathrin cages and triskelia.

N-Hydroxysuccinimide-terminated self-assembled monolayers with linear (CH2)10 chains were prepared on ultraflat Au(111) surfaces from dithiobis(succinimidylundecanoate). These monolayers, which are covalently chemisorbed to gold via thiolate bonds, form a highly reactive amino-group specific carpet at the liquid-solid interface. Proteins bind to it covalently in aqueous buffers under mild conditions; this provides a (general) procedure for protein immobilization for scanning probe microscopy. Using this technique, we have obtained what we believe are the first scanning force microscopy images of clathrin cages and of their in situ disassembly, yielding typical triskelia under non-denaturing conditions.

Purification of Golgi adaptor protein 1 from bovine adrenal gland and characterization of its beta 1 (beta') subunit by microsequencing.

A method for the purification of the Golgi adaptor protein 1 from bovine adrenal gland tissue was devised to investigate the relationship of its beta 1 (formerly referred to as beta') subunit to known beta-type sequences. Adrenal gland tissue was chosen for this study because it yielded 2-3 times more adaptor protein 1 than a comparable preparation from bovine brain. Like its neuronal isoform, the beta 1 subunit from adrenal gland adaptor protein 1 is readily cleaved by trypsin into a 63-kDa N-terminal fragment and a 40-kDa C-terminal fragment, while the gamma subunit is largely refractory to digestion. Based on microsequencing of 167 residues from the 63-kDa fragment, we noted 11 differences to the corresponding region of the beta 2 (formerly beta) subunit of the plasma membrane adaptor protein 2, but only one difference to the corresponding region of a beta-type protein encoded by the rat cDNA clone AP105a which is supposed to be a variant of the beta 2 subunit of the plasma membrane adaptor protein 2 [Kirchhausen, T., Nathanson, K. L., Matsui, W., Vaisberg, A., Chow, E. P., Burne, C., Keen, J. H. & Davis, A. E. (1989) Proc. Natl Acad. Sci. USA 84, 8805-8809]. Alignment of 187 residues from the 40-kDa beta 1 C-terminal fragment revealed differences in 77 positions to the corresponding region of the beta 2 subunit and differences in 23 positions compared to the supposed beta 2-like protein. These findings suggest that the protein encoded by the rat cDNA clone AP105a is more closely related to the beta 1 subunit of the bovine adrenal Golgi adaptor protein 1 than to the beta 2 subunit of the rat plasma membrane adaptor protein 2.

Interaction of vinculin with the clathrin heavy chain.

To further document the interaction of vinculin with the clathrin heavy chain (CHC) which was observed by using gel overlay, co-sedimentation experiments were performed and attempts were made to localize the domains involved on both molecules. The binding properties of proteolytic fragments of vinculin were investigated after cleavage with V8 protease. Neither the isolated globular domain, nor the C-terminal rod domain were able to interact with the CHC. Either the interaction involved the portion of vinculin which links these two domains, or the region of vinculin mediating the interaction was present on one of the two major fragments, but the cleavage itself resulted in conformational changes which abolished the binding. The first hypothesis could be ruled out using alpha-chymotrypsin generated fragments of vinculin, suggesting that the native conformation of vinculin might play an important role. Proteolytic cleavage of CHC with trypsin demonstrated that the interaction with vinculin is mediated by the proximal or distal segment of the CHC. Presence of clathrin light chain (CLC) associated with the CHC did not affect its interaction with vinculin. Vinculin did not interact with the CLC.

Absence of interaction between the 165-kDa fibronectin-binding protein involved in mouse odontoblast differentiation and vinculin.

Previous data suggested that matrix could control the organization of microfilaments in differentiating odontoblasts and that this process involved a complex of fibronectin-165-kDa membrane protein-vinculin. The use of two different gel systems and microsequence analysis demonstrated that two distinct 165-kDa proteins interact, one with fibronectin and the other with vinculin.

Clathrin assembly protein AP180: primary structure, domain organization and identification of a clathrin binding site.

Binding of AP180 to clathrin triskelia induces their assembly into 60-70 nm coats. The largest rat brain cDNA clone isolated predicts a molecular weight of 91,430 for AP180. Two cDNA clones have an additional small 57 bp insert. The deduced molecular weight agrees with gel filtration results provided the more chaotropic denaturant 6 M guanidinium thiocyanate is substituted for the weaker guanidinium chloride. The sequence and the proteolytic cleavage pattern suggest a three domain structure. The N-terminal 300 residues (pI 8.7) harbour a clathrin binding site. An acidic middle domain (pI 3.6, 450 residues), interrupted by an uncharged alanine rich segment of 59 residues, appears to be responsible for the anomalous physical properties of AP180. The C-terminal domain (166 residues) has a pI of 10.4. AP180 mRNA is restricted to neuronal sources. AP180 shows no significant homology to known clathrin binding proteins, but is nearly identical to a mouse phosphoprotein (F1-20). This protein, localized to synaptic termini, has so far been of unknown function.

Clathrin-associated proteins of bovine brain coated vesicles. An analysis of their number and assembly-promoting activity.

In search of hitherto undiscovered coat proteins, clathrin-associated proteins (APs) from coated vesicles of bovine brain were affinity-purified by one cycle of coat assembly and fractionated by gel filtration on Superose 6. Immunochemical and gel electrophoretic analysis of the fractions revealed, besides AP180, auxilin, HA1, and HA2, a component with M(r) approximately 140,000. This protein (p140) is present in coated vesicles in about equimolar proportion to auxilin. The contribution of HA1, HA2, AP180, and auxilin to the total assembly activity in the Tris-soluble coat protein fraction were quantitatively analyzed by measuring the reduction in activity when each protein was removed from the mixture by immunoaffinity chromatography. It was found that AP180 accounts for 61% and HA2 for 33% of the activity, whereas auxilin, HA1, and p140 made a negligible contribution. Based on the relative molar concentration of APs in the coat protein fraction, AP180 is about 4 times more active in promoting clathrin assembly than are HA2 or the other APs.

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.

Bovine brain clathrin light chains impede heavy chain assembly in vitro.

Intact bovine brain clathrin triskelia, comprising three heavy and three light chains, require either 2 mM calcium or the assistance of protein co-factors for efficient assembly into regular cage structures (Keen, J. H., Willingham, M. C., and Pastan, I. (1979) Cell 16, 303-312). In contrast light chain-free heavy chains assemble readily in the absence of co-factors or calcium. Reconstitution of intact clathrin from heavy and light chains restores the calcium requirement. Our data indicate that light chains impede assembly by creating a kinetic trap rather than by perturbing the affinity of heavy chains for each other. This property suggests a function for light chains as regulatory subunits for clathrin assembly.

Subunit interaction and function of clathrin-coated vesicle adaptors from the Golgi and the plasma membrane.

Clathrin in coated vesicles is linked to transmembrane receptors by adaptor protein complexes. The Golgi-associated adaptor complex HA1 is a tetramer, made up of beta', gamma, 47-kDa, and 20-kDa subunits, whereas the tetrameric plasma membrane adaptor, HA2, contains alpha, beta, 50-kDa, and 16-kDa subunits (Ahle, S., Mann, A., Eichelsbacher, U., and Ungewickell, E. (1988) EMBO J. 7, 919-929). Here we report on the structural organization of adaptor subunits as revealed by proteolytic dissection. We show that the beta' and gamma subunits of HA1 are cleaved into 60-67-kDa "trunk" and 32-44-kDa "head" fragments. Interactions between adaptor subunits involve the trunk domains only. In overall organization of their domains, the Golgi and plasma membrane adaptors are very similar. The similarity encompasses also the location of phosphorylated serine residues in the alpha a, beta, beta', and gamma subunits, which are found in the head domains in all cases. In the alpha a and beta subunits they probably occur in the proline- and glycine-rich hinge region, which connects the head to the trunk. Identical adaptor fragments were obtained by controlled digestion of clathrin-coated vesicles. Under conditions that did not affect the integrity of the clathrin heavy chain, the adaptor head fragments were always quantitatively released from coated vesicles. The release of the bulk of the adaptors occurred concomitantly with the cleavage of their beta-type subunits (beta and beta') and under buffer conditions that prevent aggregation of adaptors. These observations taken together with the results of reconstitution experiments confirm and extend previous data (Ahle, S., and Ungewickell, E. (1989) J. Biol. Chem. 264, 20089-20093) which suggested that adaptors attach to clathrin through their beta-type (beta and beta') subunits. Moreover, high affinity interaction between adaptors and clathrin requires the participation of regions from both the head and trunk domains of the beta-type subunits.