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.     

Deep-etch views of clathrin assemblies

Clathrin assemblies were adsorbed to mica and freeze-dried by a new procedure that yields 3-D images with much topological detail. These permitted renewed inquiry into how clathrin trimers (i.e. "triskelions") assemble into polygonal coats or baskets. Freeze-drying revealed unsuspected differences in the relative shapes and dimensions of individual trimer building blocks, as compared with the completed polygonal networks, which indicate that the assembly scheme first proposed by Crowther and Peare (1) requires modification. Specifically, the freeze-etch images display the following new features: (1) Trimer arms possess terminal scroll-shaped hooks that can open or close and thus determine their lengths. (2) When extended, trimer arms are sufficiently long to pass around three sides of the final polygonal facet. Since current views hold that the arms pass around only two sides, the remaining length, including the terminal hook, must point into the basket interior. (3) Freeze-dried trimers display bends in their arms at specific loci that determine their final distribution in the completed baskets. (4) The completed struts of the final assemblies are uniformed in the calibre, cylindrical in profile, and travel directly between the vertices of each polygon, without any sign of the slew or width-variation that is predicted by the Crowther and Pearse model. Based on this direct comparison of promoter vs product, by a single technique that can image both, we offer a modified scheme for clathrin coat assembly, in which we predict that the individual arms in each clathrin triskelion emanate from its center in a slewed manner, but the final assembled struts of the basket need not be slewed. Attempts were made to capture assembly intermediates on mica to obtain support for the scheme, but these unfortunately yielded ambiguous images of incomplete polygons with blunt projections, rather than the expected "halo" of uncommitted trimer arms. These we interpret to be "dead ends" that failed to polymerize further because they included proteolyzed components. Further assembly experiments, avoiding such hazards, are indicated.     

Deep-etch visualization of the Sertoli cell (blood-testis) barrier in the boar.

The Sertoli cell (blood-testis) barrier in the boar was visualized by the freeze-fracture, deep-etch, rotary-replication technique. Three kinds of cross-bridging structures were clearly recognized in the following three ectoplasmic specialization (ES) regions; (1) cross-bridges in the intercellular space between adjacent Sertoli cell membranes; (2) cross-bridges in the space between the Sertoli cell membrane and microfilament bundles; and (3) cross-bridges in the space between microfilament bundles and subsurface cisternae. Results from immunolocalization, vinculin and alpha-actinin were recognized in the Sertoli cell barrier. Our findings show that these structural elements of the Sertoli cell barrier are held together by these cross-bridging structures, and provide important morphological evidence that implicates the ES in the dynamic function of the microfilament bundles of the Sertoli cell barrier.     

AFM visualization of clathrin triskelia under fluid and in air

Atomic force microscopy (AFM) is used to characterize the structure and interactions of clathrin triskelia. Time sequence images of individual, wet triskelia resting on mica surfaces clearly demonstrate conformational fluctuations of the triskelia. AFM of dried samples yields images having nanometric resolution comparable to that obtainable by electron microscopy of shadowed samples. Increased numbers of triskelion dimers and assembly intermediates, as well as structures having dimensions similar to those of clathrin cages, are observed when the triskelia were immersed in a low salt, low pH buffer. These entities have been quantified by AFM protein volume computation.

Structured summary

MINT-7299119, MINT-7299136:Clathrin (uniprotkb:P49951) and Clathrin (uniprotkb:P49951) bind (MI:0407) by atomic force microscopy (MI:0872)     

Life of a clathrin coat: insights from clathrin and AP structures

Membrane sorting between secretory and endocytic organelles is predominantly controlled by small carrier vesicles or tubules that have specific protein coats on their cytoplasmic surfaces. Clathrin-clathrin-adaptor coats function in many steps of intracellular transport and are the most extensively studied of all transport-vesicle coats. In recent years, the determination of structures of clathrin assemblies by electron microscopy, of domains of clathrin and of its adaptors has improved our understanding of the molecular mechanisms of clathrin-coated-vesicle assembly and disassembly.     

Human S100b protein: formation of a tetramer from synthetic calcium-binding site peptides.

Human brain S100b protein is a unique calcium-binding protein comprised of two identical 91-amino acid polypeptide chains that each contain two proposed helix-loop-helix (EF-hand) calcium-binding sites. In order to probe the assembly of the four calcium-binding sites in S100b, a peptide comprised of the N-terminal 46 residues of S100b protein was synthesized and studied by CD and 1H NMR spectroscopies as a function of concentration and temperature. At relatively high peptide concentrations and in the absence of calcium, the peptide exhibited a significant proportion of alpha-helix (45%). Decreasing the peptide concentration led to a loss of alpha-helix as monitored by CD spectroscopy and coincident changes in the 1H NMR spectrum. These changes were also observed by 1H NMR spectroscopy as a function of temperature where it was observed that the Tm of the peptide was lowered approximately 14 degrees C with a 17-fold decrease in peptide concentration. Sedimentation equilibrium studies were used to determine that the peptide formed a tetramer in solution in the absence of calcium. It is proposed that this tetrameric fold also occurs in S100b and is a result of the interaction of portions of all four calcium-binding sites.     

Identification of a distinct 9S form of soluble clathrin in cultured cells and tissues

We have used a monoclonal antibody (CHC5.9) to identify clathrin (Mr 180,000; 'heavy chain') in coated vesicles, triskelion structures prepared in vitro and in high-speed supernatants (HSS) of cell homogenates from a variety of tissues and species (e.g., brain and liver from rat, cow and man; Xenopus ovaries). HSS proteins were subjected to sucrose density gradient centrifugation and gel filtration, and the fractions obtained were assayed for clathrin by enzyme-linked immunosorbent assay (ELISA) and polyacrylamide gel electrophoresis (PAGE), followed by immunoblotting. The native soluble clathrin identified in such fractions was indistinguishable from triskelions produced in vitro from purified bovine brain clathrin by several criteria, e.g. by its sedimentation coefficient (9S) and elution profile on gel filtration using Sephacryl S 300. No other major forms of soluble clathrin were detected. The results indicate that cells contain a soluble pool of clathrin and that the predominant molecular form of this soluble clathrin has properties similar to those of the triskelion obtained by dissociation studies in vitro. We hypothesize that this distinct 9S form represents a major oligomeric subunit involved in assembly and disassembly of clathrin polyhedron coats in the living cell.     

Creating a chimeric clathrin heavy chain that functions independently of yeast clathrin light chain

Clathrin facilitates vesicle formation during endocytosis and sorting in the trans‐Golgi network (TGN)/endosomal system. Unlike in mammals, yeast clathrin function requires both the clathrin heavy (CHC) and clathrin light (CLC) chain, since Chc1 does not form stable trimers without Clc1. To further delineate clathrin subunit functions, we constructed a chimeric CHC protein (Chc‐YR) , which fused the N‐terminus of yeast CHC (1–1312) to the rat CHC residues 1318–1675, including the CHC trimerization region. The novel CHC‐YR allele encoded a stable protein that fractionated as a trimer. CHC‐YR also complemented chc1Δ slow growth and clathrin TGN/endosomal sorting defects. In strains depleted for Clc1 (either clc1Δ or chc1Δ clc1Δ), CHC‐YR, but not CHC1, suppressed TGN/endosomal sorting and growth phenotypes. Chc‐YR‐GFP (green fluorescent protein) localized to the TGN and cortical patches on the plasma membrane, like Chc1 and Clc1. However, Clc1‐GFP was primarily cytoplasmic in chc1Δ cells harboring pCHC‐YR, indicating that Chc‐YR does not bind yeast CLC. Still, some partial phenotypes persisted in cells with Chc‐YR, which are likely due either to loss of CLC recruitment or chimeric HC lattice instability. Ultimately, these studies have created a tool to examine non‐trimerization roles for the clathrin LC.     

Conformation of a clathrin triskelion in solution

A principal component in the protein coats of certain post-golgi and endocytic vesicles is clathrin, which appears as a three-legged heteropolymer (known as a triskelion) that assembles into polyhedral cages principally made up of pentagonal and hexagonal faces. In vitro, this assembly depends upon the pH, with cages forming more readily at low pH and less readily at high pH. We have developed procedures, on the basis of static and dynamic light scattering, to determine the radius of gyration, R(g), and hydrodynamic radius, R(H), of isolated triskelia, under conditions where cage assembly occurs. Calculations based on rigid molecular bead models of a triskelion show that the measured values can be accounted for by bending the legs and a puckering at the vertex. We also show that the values of R(g) and R(H) measured for clathrin triskelia in solution are qualitatively consistent with the conformation of a triskelion in a "D6 barrel" cage assembly measured by cryoelectron microscopy.     

Location of auxilin within a clathrin cage

The Dna J homologue, auxilin, acts as a co-chaperone for Hsc70 in the uncoating of clathrin-coated vesicles during endocytosis. Biochemical studies have aided understanding of the uncoating mechanism but until now there was no structural information on how auxilin interacts with the clathrin cage. Here we have determined the three-dimensional structure of a complex of auxilin with clathrin cages by cryo-electron microscopy and single particle analysis. We show that auxilin forms a discrete shell of density on the inside of the clathrin cage. Peptide competition assays confirm that a candidate clathrin box motif in auxilin, LLGLE, can bind to a clathrin construct containing the beta-propeller domain and also displace the well-characterised LLNLD clathrin box motif derived from the beta-adaptin hinge region. The means by which auxilin could both aid clathrin coat assembly and displace clathrin from AP2 during uncoating is discussed.     

Mapping subunit contacts in the regulatory complex of the 26 S proteasome. S2 and S5b form a tetramer with ATPase subunits S4 and S7

The 19 S regulatory complex (RC) of the 26 S proteasome is composed of at least 18 different subunits, including six ATPases that form specific pairs S4-S7, S6-S8, and S6'-S10b in vitro. One of the largest regulatory complex subunits, S2, was translated in reticulocyte lysate containing [(35)S]methionine and used to probe membranes containing SDS-polyacrylamide gel electrophoresis separated RC subunits. S2 bound to two ATPases, S4 and S7. Association of S2 with regulatory complex subunits was also assayed by co-translation and sedimentation. S2 formed an immunoprecipitable heterotrimer upon co-translation with S4 and S7. The non-ATPase S5b also formed a ternary complex with S4 and S7 and the three proteins assembled into a tetramer with S2. Neither S2 nor S5b formed complexes with S6'-S10b dimers or with S6-S8 oligomers. The use of chimeric ATPases demonstrated that S2 binds the NH(2)-terminal region of S4 and the COOH-terminal two-thirds of S7. Conversely, S5b binds the COOH-terminal two-thirds of S4 and to S7's NH(2)-terminal region. The demonstrated association of S2 with ATPases in the mammalian 19 S regulatory complex is consistent with and extends the recent finding that the yeast RC is composed of two subcomplexes, the lid and the base (Glickman, M. H., Rubin, D. M., Coux, O., Wefes, I., Pfeifer, G., Cejka, Z., Baumeister, W., Fried, V. A., and Finley, D. (1998) Cell 94, 615-623).     

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.     

Simultaneous visualization of LDL receptor distribution and clathrin lattices on membranes torn from the upper surface of cultured cells

We have developed a method for simultaneous visualization by electron microscopy of both the distribution of cell surface receptors and architectural features of the inner membrane surface, such as clathrin-coated pits. Electron microscope grids were covered with formvar and coated with poly-L-lysine. These grids were then placed on a piece of buffer-impregnated cellulose acetate membrane filter maintained at 4 degrees C on an ice bath. Cells of interest were grown on glass coverslips and incubated with either a ligand-gold or an antibody-gold conjugate specific for the membrane determinant of interest. The coverslip with gold-labeled cells was then overlaid on the grids and pressure was applied. When the grid was removed, large areas of the upper cell surface, which had labeled determinants, remained adherent to the formvar support. With the proper staining, both the gold particles and internal membrane features could be seen at the same time in the electron microscope. This method is rapid, does not require extensive experience with electron microscopic technique, and permits viewing of membrane samples that are large enough to perform quantitative analysis of gold distribution in relation to membrane specializations.     

Calcium-dependent tetramer formation of S100A8 and S100A9 is essential for biological activity

S100 proteins comprise the largest family of calcium-binding proteins. Members of this family usually form homo- or heterodimers, which may associate to higher-order oligomers in a calcium-dependent manner. The heterodimers of S100A8 and S100A9 represent the major calcium-binding proteins in phagocytes. Both proteins regulate migration of these cells via modulation of tubulin polymerization. Calcium binding induces formation of (S100A8/S100A9)2 tetramers. The functional relevance of these higher-order oligomers of S100 proteins, however, is not yet clear. To investigate the importance of higher-order oligomerization for S100 proteins, we created a set of mutations within S100A9 (N69A, E78A, N69A+E78A) destroying the high-affinity C-terminal calcium-binding site (EF-hand II). Mutations in EF-hand II did not interfere with formation of the S100A8/S100A9 heterodimer as demonstrated by yeast two-hybrid experiments and pull-down assays. In contrast, mass spectrometric analysis and density gradient centrifugation revealed that calcium-induced association of (S100A8/S100A9)2 tetramers was strictly dependent on a functional EF-hand II in S100A9. Failure of tetramer formation was associated with a lack of functional activity of S100A8/S100A9 complexes in promoting the formation of microtubules. Thus, our data demonstrate that calcium-dependent formation of (S100A8/S100A9)2 tetramers is an essential prerequisite for biological function. This is the first report showing a functional relevance of calcium-induced higher-order oligomerization in the S100 family.     

Osprey: a network visualization system

We have developed a software platform called Osprey for visualization and manipulation of complex interaction networks. Osprey builds data-rich graphical representations that are color-coded for gene function and experimental interaction data. Mouse-over functions allow rapid elaboration and organization of network diagrams in a spoke model format. User-defined large-scale datasets can be readily combined with Osprey for comparison of different methods.     

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.     

Osprey: a network visualization system

We have developed a software platform called Osprey for visualization and manipulation of complex interaction networks. Osprey builds data-rich graphical representations that are color-coded for gene function and experimental interaction data. Mouse-over functions allow rapid elaboration and organization of network diagrams in a spoke model format. User-defined large-scale data sets can be readily combined with Osprey for comparison of different methods.