A novel structural model for regulation of clathrin function.

The distinctive triskelion shape of clathrin allows assembly into polyhedral lattices during the process of clathrin-coated vesicle formation. We have used random and site-directed mutagenesis of the yeast clathrin heavy chain gene (CHC1) to characterize regions which determine Chc trimerization and binding to the clathrin light chain (Clc) subunit. Analysis of the mutants indicates that mutations in the trimerization domain at the triskelion vertex, as well as mutations in the adjacent leg domain, frequently influence Clc binding. Strikingly, one mutation in the trimerization domain enhances the association of Clc with Chc. Additional mutations in the trimerization domain, in combination with mutations in the adjacent leg domain, exhibit severe defects in Clc binding while maintaining near normal trimerization properties. The position of these trimerization domain mutations on one face of a putative alpha-helix defines a region on the trimer surface that interacts directly with Clc. These results suggest that Clc extends into the Chc trimerization domain from the adjacent leg, thereby bridging the two domains. On the basis of this conclusion, we propose a new model for the organization of the triskelion vertex which provides a structural basis for regulatory effects of Clc on clathrin function.     

Folding and trimerization of clathrin subunits at the triskelion hub.

The triskelion shape of the clathrin molecule enables it to form the polyhedral protein network that covers clathrin-coated pits and vesicles. Domains within the clathrin heavy chain that are responsible for maintaining triskelion shape and function were identified and localized. Sequences that mediate trimerization are distal to the carboxyl terminus and are adjacent to a domain that mediates both light chain binding and clathrin assembly. Structural modeling predicts that within this domain, the region of heavy chain-light chain interaction is a bundle of three or four alpha helices. These studies establish a low resolution model of clathrin subunit folding in the central portion (hub) of the triskelion, thus providing a basis for future mutagenesis experiments.     

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.     

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.     

A motif in the clathrin heavy chain required for the Hsc70/auxilin uncoating reaction

The 70-kDa heat-shock cognate protein (Hsc70) chaperone is an ATP-dependent "disassembly enzyme" for many subcellular structures, including clathrin-coated vesicles where it functions as an uncoating ATPase. Hsc70, and its cochaperone auxilin together catalyze coat disassembly. Like other members of the Hsp70 chaperone family, it is thought that ATP-bound Hsc70 recognizes the clathrin triskelion through an unfolded exposed hydrophobic segment. The best candidate is the unstructured C terminus (residues 1631-1675) of the heavy chain at the foot of the tripod below the hub, containing the sequence motif QLMLT, closely related to the sequence bound preferentially by the substrate groove of Hsc70 (Fotin et al., 2004b). To test this hypothesis, we generated in insect cells recombinant mammalian triskelions that in vitro form clathrin cages and clathrin/AP-2 coats exactly like those assembled from native clathrin. We show that coats assembled from recombinant clathrin are good substrates for ATP- and auxilin-dependent, Hsc70-catalyzed uncoating. Finally, we show that this uncoating reaction proceeds normally when the coats contain recombinant heavy chains truncated C-terminal to the QLMLT motif, but very inefficiently when the motif is absent. Thus, the QLMLT motif is required for Hsc-70-facilitated uncoating, consistent with the proposal that this sequence is a specific target of the chaperone.     

Contribution of cysteines to clathrin trimerization domain stability and mapping of light chain binding

The three-legged or triskelion shape of clathrin is critical for the formation of polyhedral lattices around clathrin-coated vesicles. Filamentous legs radiate from a common vertex, with amino acids 1550–1615 contributed by each leg to define the trimerization domain (Liu S-H, Wong ML, Craik CS, Brodsky FM. Cell 1995; 83: 257–267). Within this amino acid stretch there are 3 cysteines at positions 1565, 1569 and 1573 which are completely conserved in higher mammals from humans to C. elegans . The cysteine-to-serine mutation at position 1573 was observed to have the largest impact on clathrin structure and self-assembly. We have also found that Cysteine 1528 located near the boundary between the proximal region and trimerization domain mediated the formation of nonproductive clathrin aggregates when bound light chain subunits were removed. However, when light chains were added back, the ability of this cysteine to form disulfide bridges between individual clathrin molecules was blocked, suggesting bound light chain interacted with Cysteine 1528 to prevent aggregation. This new information serves to map the orientation of the light chain subunit in the vicinity of the trimerization domain and supports previous models that indicate involvement of the trimerization domain in LC binding (Chen C-Y, Reese ML, Hwang PK, Ota N, Agard D, Brodsky FM. EMBO J 2002; 21: 6072–6082; Pishvaee B, Munn A, Payne GS. EMBO J 1997; 16: 2227–2239).     

Enzymatic dissociation of clathrin cages in a two-stage process

Uncoating ATPase catalyzes the ATP-dependent dissociation of clathrin from coated vesicles and empty cages. Following an uncoating reaction, clathrin triskelions are released intact, in a stoichiometric complex with bound uncoating protein. This overall uncoating process was dissected into two partial reactions. In the first, ATP hydrolysis drives the transient displacement of a portion of a triskelion from a cage. Uncoating protein then captures the displaced triskelion, in the second stage, by binding to a newly exposed site on clathrin that had previously been buried in the cage lattice. Triskelion-uncoating protein complexes are released when all points of attachment of the triskelion to the cage have been severed. The uncoating protein interacts with a distinct site on clathrin for each of these reactions.     

Light chain C-terminal region reinforces the stability of clathrin heavy chain trimers

The self-assembly of clathrin into lattices relies on the ability of heavy chain legs to form a three-legged pinwheel structure. We investigated the role of light chains in clathrin trimerization by challenging recombinant hub (plus and minus light chain) with an anionic detergent. The binding of light chain increases the amount of detergent needed to induce detrimerization, suggesting light chains reinforced hub trimers. We also show that light chain C-terminal residues are important for enhancing the in vitro assembly of hub at low pH. We assessed how much the C-terminus of light chain contributed to the stability of the trimerization domain by adding full-length and truncated light chains to trimer-defective hub mutants, C1573S and C1573A. Adding full-length LCb to C1573S caused some retrimerization, but little activity was restored, suggesting the majority of oligomeric C1573S was nonnative. A larger percentage of monomeric C1573A could be retrimerized into an assembly-competent form by adding intact LCb. We also discovered that C-terminally deleted light chains produced a heterogeneous population of hubs that were smaller than native hubs, but were assembly active. We propose a model showing how light chains reinforce the puckered clathrin triskelion. Finally, the ability of light chains to retrimerize C1573A hub suggests that the structural role of light chain may be conserved in yeast and mammals.     

Structure determination of clathrin coats to subnanometer resolution by single particle cryo-electron microscopy

Clathrin triskelions can assemble into lattices of different shapes, sizes and symmetries. For many years, the structures of clathrin lattices have been studied by single particle cryo-electron microscopy, which probed the architecture of the D6 hexagonal barrel clathrin coat at the molecular level. By introducing additional image processing steps we have recently produced a density map for the D6 barrel clathrin coat at subnanometer resolution, enabling us to generate an atomic model for this lattice [Fotin, A., Cheng, Y., Sliz, P., Grigorieff, N., Harrison, S.C., Kirchhausen, T., Walz, T., 2004. Molecular model for a complete clathrin lattice from electron cryomicroscopy. Nature 432, 573-579]. We describe in detail here the image processing steps that we have added to produce a density map at this high resolution. These procedures should be generally applicable and may thus help determine the structures of other large protein assemblies to higher resolution by single particle cryo-electron microscopy.     

Clathrin assembly involves a light chain-binding region

Two regions on the clathrin heavy chain that are involved in triskelion interactions during assembly have been localized on the triskelion structure. These regions were previously identified with anti-heavy chain monoclonal antibodies X19 and X35, which disrupt clathrin assembly (Blank, G. S., and F. M. Brodsky, 1986, EMBO (Eur. Mol. Biol. Organ.) J., 5:2087-2095). Antibody-binding sites were determined based on their reactivity with truncated triskelions, and were mapped to an 8-kD region in the middle of the proximal portion of the triskelion arm (X19) and a 6-kD region at the triskelion elbow (X35). The elbow site implicated in triskelion assembly was also shown to be included within a heavy chain region involved in binding the light chains and to constitute part of the light chain-binding site. We postulate that this region of the heavy chain binds to the interaction site identified on the light chains that has homology to intermediate filament proteins (Brodsky, F. M., C. J. Galloway, G. S. Blank, A. P. Jackson, H.-F. Seow, K. Drickamer, and P. Parham, 1987, Nature (Lond.), 326:203-205). These findings suggest the existence of a heavy chain site, near the triskelion elbow, which is involved in both intramolecular and intermolecular interactions during clathrin assembly.     

Structural insights into the clathrin coat

Clathrin is a cytoplasmic protein best known for its role in endocytosis and intracellular trafficking. The diverse nature of clathrin has recently become apparent, with strong evidence available suggesting roles in both chromosome segregation and reassembly of the Golgi apparatus during mitosis. Clathrin functions as a heterohexamer, adopting a three-legged triskelion structure of three clathrin light chains and three heavy chains. During endocytosis clathrin forms a supportive network about the invaginating membrane, interacting with itself and numerous adapter proteins. Advances in the field of structural biology have led us to a greater understanding of clathrin in its assembled state, the clathrin lattice. Combining techniques such as X-ray crystallography, NMR, and cryo-electron microscopy has allowed us to piece together the intricate nature of clathrin-coated vesicles and the interactions of clathrin with its many binding partners. In this review I outline the roles of clathrin within the cell and the recent structural advances that have improved our understanding of clathrin-clathrin and clathrin-protein interactions.     

Rigidity of triskelion arms and clathrin nets

Statistical analysis is applied to a set of electron micrographic images (Kocsis, E., B. L. Trus, C. J. Steer, M. E. Bisher, and A. C. Steven. 1991. J. Struct. Biol. 107:6-14), from which quantitative measures are obtained to support the notion that the three arms of a triskelion have statistically identical properties and exhibit independent structural fluctuations. Additionally, a study of local contour fluctuations, which indicates that the elastic properties of a triskelion arm are approximately constant over the entire arm length, is used along with a small deformation statistical mechanics theory to derive an effective, average flexural rigidity for the arms. This result is used to estimate the bending energy necessary to deform a clathrin patch, and comparison is made with the deformation energy of an equivalent area of non-clathrin-coated membrane. We estimate that the rigidity of the clathrin lattice is at least comparable to that of a typical membrane. Hence, the natural curvature of a clathrin cage can stabilize, and perhaps propel, the formation of intracellular coated vesicles.     

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.     

Skeletal structure of clathrin triskelion in solution: experimental and theoretical approaches

The physicochemical properties of the clathrin triskelion were determined by dynamic and static light-scattering and sedimentation analyses in Tris and triethanolamine (TEA) buffers of about pH 8, in which the clathrin triskelion has been found to be in different conformational states by electron microscopy [Heuser, J., & Kirchhausen, T. (1985) J. Ultrastruct. Res. 92, 1-27]. Dynamic light-scattering measurements provided diffusion coefficients (D0(20,w)) of 1.22 x 10(-7) and 1.23 x 10(-7) cm2/s, and ultracentrifugal analysis gave sedimentation coefficients (S0(20,w)) of 8.39 and 8.32 S in Tris and TEA buffer, respectively. The average Stokes radius of the protein was determined to be 175 A from its diffusion and sedimentation coefficients and its molecular weight. Static light-scattering analysis provided molecular weights of 6.58 x 10(5) and 6.41 x 10(5) and radii of gyration of 311 and 301 A in the respective buffers. These results indicate that the clathrin triskelion has a similar conformation in the two buffers. For clarification of the skeletal structure of the clathrin triskelion in solution, the physicochemical parameters were calculated by using two models in which the clathrin arms are bent at various angles in a plane, on the basis of the Bloomfield approximation and a formula derived to estimate the radius of gyration of proteins consisting of various structural units. Values for the Stokes radius, diffusion and sedimentation coefficients, and radius of gyration in the ranges of 178-170 A, (1.20-1.26) x 10(-7) cm2/s, 8.26-8.66 S, and 316-266 A, respectively, were obtained with these models with the arms bent in the range of 0-60 degrees.(ABSTRACT TRUNCATED AT 250 WORDS)     

Topological mechanisms involved in the formation of clathrin-coated vesicles.

By examining the basic characteristics of clathrin lattices, we discover that simple topological rules impose strict constraints on clathrin lattice transformations. These constraints require that internal bond rearrangements take place in conjunction with the addition or removal of pairs of clathrin triskelions within the interior of existing clathrin lattice patches. Similar constraints also are relevant to coated-vesicle shape changes and their budding-off from pit lattices. Via specific illustrations, successive vesicles with hexagonal-barrel and other coats are shown to grow out from the interior of a initially flat clathrin-coated pit so long as free triskelions are available from cytoplasm. Concomitantly, we present mathematical derivations of several simple and useful topological equations. These equations govern the numbers of nonhexagonal clathrin lattice facets and their variations during internal shape transformations and justify the proposed mechanisms of triskelion pair insertion and removal.     

Image averaging of flexible fibrous macromolecules: the clathrin triskelion has an elastic proximal segment.

We have developed computational techniques that allow image averaging to be applied to electron micrographs of filamentous molecules that exhibit tight and variable curvature. These techniques, which involve straightening by cubic-spline interpolation, image classification, and statistical analysis of the molecules' curvature properties, have been applied to purified brain clathrin. This trimeric filamentous protein polymerizes, both in vivo and in vitro, into a wide range of polyhedral structures. Contrasted by low-angle rotary shadowing, dissociated clathrin molecules appear as distinctive three-legged structures, called "triskelions" (E. Ungewickell and D. Branton (1981) Nature 289, 420). We find triskelion legs to vary from 35 to 62 nm in total length, according to an approximately bell-shaped distribution (mu = 51.6 nm). Peaks in averaged curvature profiles mark hinges or sites of enhanced flexibility. Such profiles, calculated for each length class, show that triskelion legs are flexible over their entire lengths. However, three curvature peaks are observed in every case: their locations define a proximal segment of systematically increasing length (14.0-19.0 nm), a mid-segment of fixed length (approximately 12 nm), and a rather variable end-segment (11.6-19.5 nm), terminating in a hinge just before the globular terminal domain (approximately 7.3 nm diameter). Thus, two major factors contribute to the overall variability in leg length: (1) stretching of the proximal segment and (2) stretching of the end-segment and/or scrolling of the terminal domain. The observed elasticity of the proximal segment may reflect phosphorylation of the clathrin light chains.     

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.     

Energetics of clathrin basket assembly

A minimal thermodynamic model is used to study the in vitro equilibrium assembly of reconstituted clathrin baskets. The model contains parameters accounting for i) the combined bending and flexing rigidities of triskelion legs and hubs, ii) the intrinsic curvature of an isolated triskelion, and iii) the free energy changes associated with interactions between legs of neighboring triskelions. Analytical expressions for basket size distributions are derived, and published size distribution data (Zaremba S, Keen JH. J Cell Biol 1983;97: 1339–1347) are then used to provide estimates for net total basket assembly energies. Results suggest that energies involved in adding triskelions to partially formed clathrin lattices are small (of the order of kBT), in accord with the notion that lattice remodeling during basket formation occurs as a result of thermodynamic fluctuations. In addition, analysis of data showing the effects of assembly proteins (APs) on basket size indicates that the binding of APs increases the intrinsic curvature of an elemental triskelial subunit, the stabilizing energy of leg interactions, and the effective leg/hub rigidity. Values of effective triskelial rigidity determined in this investigation are similar to those estimated by previous analysis of shape fluctuations of isolated triskelia.     

Clathrin triskelia show evidence of molecular flexibility

The clathrin triskelion, which is a three-legged pinwheel-shaped heteropolymer, is a major component in the protein coats of certain post-Golgi and endocytic vesicles. At low pH, or at physiological pH in the presence of assembly proteins, triskelia will self-assemble to form a closed clathrin cage, or “basket”. Recent static light scattering and dynamic light scattering studies of triskelia in solution showed that an individual triskelion has an intrinsic pucker similar to, but differing from, that inferred from a high resolution cryoEM structure of a triskelion in a clathrin basket. We extend the earlier solution studies by performing small-angle neutron scattering (SANS) experiments on isolated triskelia, allowing us to examine a higher q range than that probed by static light scattering. Results of the SANS measurements are consistent with the light scattering measurements, but show a shoulder in the scattering function at intermediate q values (0.016 Å⁻¹), just beyond the Guinier regime. This feature can be accounted for by Brownian dynamics simulations based on flexible bead-spring models of a triskelion, which generate time-averaged scattering functions. Calculated scattering profiles are in good agreement with the experimental SANS profiles when the persistence length of the assumed semiflexible triskelion is close to that previously estimated from the analysis of electron micrographs.     

Nuclear localization of clathrin involves a labile helix outside the trimerization domain

Clathrin is a trimeric protein involved in receptor-mediated-endocytosis, but can function as a non-trimer outside of endocytosis. We have discovered that the subcellular distribution of a clathrin cysteine mutant we previously studied is altered and a proportion is also localized to nuclear spaces. MALS shows C1573A hub is a mixture of trimer-like and detrimerized molecules. The X-ray structure of the trimerization domain reveals that without light chains, a helix harboring cysteine-1573 is reoriented. We propose clathrin has a detrimerization switch, which suggests clathrin topology can be altered naturally for new functions.