Crystals of an ATPase fragment of bovine clathrin uncoating ATPase

A 44,000 Mr amino-terminal, clathrin-independent ATPase fragment of the bovine clathrin uncoating ATPase has been crystallized in a form suitable for X-ray diffraction studies. The crystals are orthorhombic, space group P2(1)2(1)2(1), a = 145.3 A, b = 65.0 A, c = 46.9 A, with one protein molecule per asymmetric unit (1 A = 0.1 nm).     

Dissociation of clathrin coats coupled to the hydrolysis of ATP: role of an uncoating ATPase

ATP hydrolysis was used to power the enzymatic release of clathrin from coated vesicles. The 70,000-mol-wt protein, purified on the basis of its ATP-dependent ability to disassemble clathrin cages, was found to possess a clathrin-dependent ATPase activity. Hydrolysis was specific for ATP; neither dATP nor other ribonucleotide triphosphates would either substitute for ATP or inhibit the hydrolysis of ATP in the presence of clathrin cages. The ATPase activity is elicited by clathrin in the form of assembled cages, but not by clathrin trimers, the product of cage disassembly. The 70,000-mol-wt polypeptide, but not clathrin, was labeled by ATP in photochemical cross-linking, indicating that the hydrolytic site for ATP resides on the uncoating protein. Conditions of low pH or high magnesium concentration uncouple ATP hydrolysis from clathrin release, as ATP is hydrolyzed although essentially no clathrin is released. This suggests that the recognition event triggering clathrin-dependent ATP hydrolysis occurs in the absence of clathrin release, and presumably precedes such release.     

The ATPase core of a clathrin uncoating protein

Chymotryptic digestion of bovine brain uncoating ATPase produced a 60-kDa fragment that was subsequently proteolyzed to 44 kDa. Loss of clathrin cage uncoating activity paralleled the conversion of the intact 70-kDa enzyme to the 60-kDa fragment, while clathrin binding activity was lost as the 60-kDa fragment was degraded to 44 kDa. This 44-kDa fragment has been purified to homogeneity and characterized as a clathrin-independent ATPase. The 44-kDa ATPase domain has been localized within the intact enzyme by the use of amino-terminal specific antibodies. This localization relates to the conserved nature of the 70-kDa heat shock protein family, of which bovine brain uncoating ATPase is a constitutively expressed member.     

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.     

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.     

Coat proteins isolated from clathrin coated vesicles can assemble into coated pits

Isolated human fibroblast plasma membranes that were attached by their extracellular surface to a solid substratum contained numerous clathrin coated pits that could be removed with a high pH buffer (Moore, M.S., D.T. Mahaffey, F.M. Brodsky, and R.G.W. Anderson. 1987. Science [Wash. DC]. 236:558-563). When these membranes were incubated with coat proteins extracted from purified bovine coated vesicles, new coated pits formed that were indistinguishable from native coated pits. Assembly was dependent on the concentration of coat protein with half maximal assembly occurring at 7 micrograms/ml. Assembly was only slightly affected by the presence of divalent cations. Whereas normal appearing lattices formed in a low ionic strength buffer, when assembly was carried out in a low pH buffer, few coated pits were evident but numerous small clathrin cages decorated the membrane. Coated pits did not form randomly on the surface; instead, they assembled at differentiated regions of membrane that could be distinguished in carbon/platinum replicas of frozen and etched membranes by the presence of numerous particles clustered into patches the size and shape of a coated pit.     

Assembly polypeptides from coated vesicles mediate reassembly of unique clathrin coats

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

Structural characterization of labeled clathrin and coated vesicles

Clathrin (8 S) and coated vesicles have been covalently labeled by using the sulfhydryl-labeling fluorescent probe N-(1-anilinonaphthalene)maleimide. A large increase in energy transfer from Trp to anilinonaphthalene (AN) residues was observed in clathrin in the pH range approximately 6.5-6.0, where the rate of clathrin self-association increased rapidly. The change in energy transfer was indicative of a conformational rearrangement, which could be responsible for the initiation of the clathrin self-association reaction to form coat structure. The AN label was found in both the coat and membrane proteins after dissociation of coated vesicles at pH 8.5. The labeled coat and membrane proteins readily recombined to form coated vesicles after reducing the pH to 6.5, indicating that the labeling did not interfere with the ability of clathrin to self-associate and interact with uncoated vesicles to form coat structure. A comparison of the AN fluorescence with the Coomassie blue pattern after electrophoresis in sodium dodecyl sulfate-gels revealed that a 180,000-Da protein (clathrin) was mainly labeled in coated vesicles, while a 110,000-Da protein was also strongly labeled in uncoated vesicles. AN-labeled baskets and coated vesicles have been prepared. Trypsin digestion reduced the sedimentation rate of baskets from 150 S to 120 S and of coated vesicles from 200 S to 150 S. Gel electrophoresis of baskets and coated vesicles showed extensive conversion of clathrin (Mr 180,000) to a product of Mr approximately equal to 110,000, suggesting equivalent structural organization of the coat in coated vesicles as in baskets. In both cases, the peptide(s) released from the vesicles by digestion were essentially free of fluorescent label. In the case of the uncoated vesicles, tryptic digestion released most of the proteins remaining after coat removal.     

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

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

An enzyme that removes clathrin coats: purification of an uncoating ATPase

Uncoating ATPase, an abundant 70,000-mol-wt polypeptide mediating the ATP-dependent dissociation of clathrin from coated vesicles and empty clathrin cages, has been purified to virtual homogeneity from calf brain cytosol. Uncoating protein is present in cells in amounts roughly stoichiometric with clathrin. This enzyme is isolated as a mixture of monomers and dimers, both forms being active. ATP can support protein-facilitated dissociation of clathrin at micromolar levels; all other ribotriphosphates as well as deoxy-ATP are inactive. The clathrin that is released from cages consists of trimers (triskelions) in a stoichiometric complex with uncoating ATPase. These complexes with clathrin have little tendency to self-associate at neutral pH, and at acidic pH they interfere with the assembly of free clathrin. The possible existence and function of these complexes as clathrin carriers in cells would explain why uncoating protein is made in quantities equivalent to clathrin.     

Antibodies to brain clathrin recognise plant coated vesicles

Coated vesicles isolated from carrot suspension culture cells were immune-blotted against four antibodies to porcine brain clathrin. Positive cross-reaction was obtained with three antibodies. Two of these cross-reacted with both the heavy clathrin chain and the putative light chains. Three out of five antibodies immunofluorescently stained permeabilised carrot suspension culture cells.     

The 70-kd mammalian heat shock proteins are structurally and functionally related to the uncoating protein that releases clathrin triskelia from coated vesicles.

It is shown that in immunological, structural and functional terms the uncoating protein, which catalyses ATP-dependent dissociation of clathrin triskelia from clathrin-coated vesicles is intimately related to two major stress proteins of mammalian cells. These proteins of hitherto unknown functions have polypeptide mol. wts. of 73 kd and 72 kd, respectively. They are normal cell constituents which are synthesized in increased abundance under adverse environmental circumstances, such as non-physiological temperatures or treatment with amino acid analogues.     

Interaction of glycolytic enzymes with purified clathrin coated vesicles

Glycolytic enzymes were found to bind to isolated coated vesicles. From a preparation of rabbit muscle myogen mixed with clathrin coated vesicles greater than 75% of four enzymes, aldolase. glyceraldehydephosphate dehydrogenase, pyruvate kinase, and lactate dehydrogenase were found to pellet with isolated coated vesicles upon centrifugation at 60.000 g for 1 h. The binding of purified aldolase, glyceraldehydephosphate dehydrogenase, pyruvate kinase, the muscle form and the heart form of lactate dehydrogenase was characterized further. Substrates were found to elute three of the enzymes and binding was determined to be a function of ionic strength.     

Trimeric binding of the 70-kD uncoating ATPase to the vertices of clathrin triskelia: a candidate intermediate in the vesicle uncoating reaction

Clathrin-coated vesicles were uncoated with the 70-kD "uncoating ATPase" from bovine brain, and the molecular products were visualized by freeze-etch electron microscopy. This yielded images of released clathrin triskelia with up to three 70-kD uncoating ATPase molecules bound to their vertices. Likewise, incubation of soluble clathrin triskelia with purified uncoating ATPase also led to trimeric binding of the ATPase to the vertices of clathrin triskelia. However, this occurred only when either EDTA or nonhydrolyzable analogues of ATP were present, in which case the ATPase also appeared to self-associate. When ATP was present instead, no 70-kD ATPases could be found on clathrin triskelia and all ATPases remained monomeric. These observations support the notion that ATP controls an allosteric conversion of the 70- kD uncoating ATPase between two different molecular conformations, an ATP-charged state in which the molecule has relatively low affinity for itself as well as low affinity for clathrin, and an ATP-discharged state in which both of these affinities are high. We presume that in vivo, the latter condition is brought about by ATP hydrolysis and product release, at which point the ATPase will bind tightly to clathrin and/or self-associate. We further propose that these reactions, when occurring in concert within a clathrin lattice, will tend to destabilize it by a mechanism we call "protein polymer competition". We stress the analogies between such a mechanism of uncoating and the ATP-driven events in muscle contraction. Finally, we show that under experimental conditions in which the uncoating ATPase fully removes the coats from brain coated vesicles, identical aliquots of the enzyme do not affect plasmalemmal coated pits in situ. This remarkable selectivity, the mechanism of which remains a complete mystery, is at least consistent with the idea that the 70-kD ATPase indeed plays a role in uncoating coated vesicles after they have formed in vivo.     

Phosphorylation/dephosphorylation of the beta light chain of clathrin from rat liver coated vesicles

The phosphorylation in vitro, on serine residues by endogenous casein kinase 2, of the clathrin beta light chain (33 kDa) of rat liver coated vesicles requires the presence of poly(L-lysine) which acts through binding to the beta light chain. The phosphorylation of other proteins is also increased in the presence of poly(L-lysine) and casein kinase 2. In contrast, the phosphorylation of the upper band of the 50-kDa protein doublet from rat liver coated vesicles is inhibited. Rat liver coated vesicles display a protein phosphatase activity which preferentially dephosphorylates clathrin beta light chain. This activity is different from the protein phosphatase which dephosphorylates the 50-kDa protein. This enzyme seems to be unrelated to the ATP/Mg-dependent protein phosphatase, or the polycation-stimulated protein phosphatases, which dephosphorylate the 50-kDa protein and beta light chain very efficiently, but with a different specificity. After dissociation of coated vesicles the beta-light-chain phosphatase activity is recovered in the membrane fraction. This phosphatase activity is inhibited by 50 microM orthovanadate and 5 mM p-nitrophenyl phosphate but not by 10 mM EDTA.     

Visualization of the binding of Hsc70 ATPase to clathrin baskets: implications for an uncoating mechanism

Clathrin assembly into coated pits and vesicles is promoted by accessory proteins such as auxilin and AP180, and disassembly is effected by the Hsc70 ATPase. These interactions may be mimicked in vitro by the assembly and disassembly of clathrin "baskets." The chimera C58J is a minimal construct capable of supporting both reactions; it consists of the C58 moiety of AP180, which facilitates clathrin assembly, fused with the J domain of auxilin, which recruits Hsc70 to baskets. We studied the process of disassembly by using cryo-electron microscopy to identify the initial binding site of Hsc70 on clathrin-C58J baskets at pH 6, under which conditions disassembly does not proceed further. Hsc70 interactions involve two sites: (i) its major interaction is with the sides of spars of the clathrin lattice, close to the triskelion hubs and (ii) there is another interaction at a site at the N-terminal hooks of the clathrin heavy chains, presumably via the J domain of C58J. We propose that individual triskelions may be extricated from the clathrin lattice by the concerted action of up to six Hsc70 molecules, which intercalate between clathrin leg segments, prying them apart. Three Hsc70s remain bound to the dissociated triskelion, close to its trimerization hub.     

Incorporation of spin-labeled fatty acids into bovine brain clathrin coated vesicles

Stearic acids with a nitroxide radical at selected positions have been incorporated in the phospholipid bilayers of clathrin coated vesicles, uncoated vesicles and sonicated liposomes made from the lipids extracted from the uncoated vesicles. The extent of incorporation was found minimum for stearic acids labeled on C-12 and for bilayers of uncoated vesicles. The ESR spectra of the spin-labeled fatty acids incorporated in the bilayers showed a pronounced temperature dependence (without discontinuity) and a decrease in the hyperfine splitting as the nitroxide group was inserted deeper in the hydrophobic core of the membranes. An abrupt phospholipid phase transition or a phase separation could be excluded. The presence of the external proteins (the clathrin coat) on the membranes was not found to noticeably influence the gradient of flexibility of the fatty acid chains of the phospholipids. The influence of the internal proteins embedded in the bilayers was evidenced by a detailed analysis of the ESR spectra of (7,8)SA in terms of two components: one component arising from the labels surrounded exclusively by phospholipids, the other component arising from labels of reduced mobility perturbed by the vicinity of the proteins. These results support the persistence of lipidic domains in the endocytic vesicles despite the accumulation of receptors which follows their formation.     

Release of clathrin from coated vesicles dependent upon a nucleoside triphosphate and a cytosol fraction

Calf-brain coated vesicles were incubated with ATP and a cytosol fraction. As much as 90% of the clathrin was selectively released within 10 min at 37 degrees C without detectable proteolysis. This uncoating process required the presence of both ATP and cytosol. Empty cages of clathrin could also be dissociated in a similar manner. A nonhydrolyzable analogue, 5'-adenylylimidodiphosphate (AMP-PNP), would not substitute for ATP. Clathrin was dissociated from coats in a form unable to reassemble into cages under standard conditions. These reactions may reflect a segment of a clathrin-coated vesicle cycle in which coats are removed from vesicles after budding.