The calcium-binding site of clathrin light chains

Clathrin light chains are calcium-binding proteins (Mooibroek, M. J., Michiel, D. F., and Wang, J. H. (1987) J. Biol. Chem. 262, 25-28) and clathrin assembly can be modulated by calcium in vitro. Thus, intracellular calcium may play a regulatory role in the function of clathrin-coated vesicles. The structural basis for calcium's influence on clathrin-mediated processes has been defined using recombinant deletion mutants and isolated fragments of the light chains. A single calcium-binding site, formed by residues 85-96, is present in both mammalian light chains (LCa and LCb) and in the single yeast light chain. This sequence has structural similarity to the calcium-binding EF-hand loops of calmodulin and related proteins. In mammalian light chains, the calcium-binding sequence is flanked by domains that regulate clathrin assembly and disassembly.     

Huntingtin-interacting protein 1 (Hip1) and Hip1-related protein (Hip1R) bind the conserved sequence of clathrin light chains and thereby influence clathrin assembly in vitro and actin distribution in vivo

Clathrin heavy and light chains form triskelia, which assemble into polyhedral coats of membrane vesicles that mediate transport for endocytosis and organelle biogenesis. Light chain subunits regulate clathrin assembly in vitro by suppressing spontaneous self-assembly of the heavy chains. The residues that play this regulatory role are at the N terminus of a conserved 22-amino acid sequence that is shared by all vertebrate light chains. Here we show that these regulatory residues and others in the conserved sequence mediate light chain interaction with Hip1 and Hip1R. These related proteins were previously found to be enriched in clathrin-coated vesicles and to promote clathrin assembly in vitro. We demonstrate Hip1R binding preference for light chains associated with clathrin heavy chain and show that Hip1R stimulation of clathrin assembly in vitro is blocked by mutations in the conserved sequence of light chains that abolish interaction with Hip1 and Hip1R. In vivo overexpression of a fragment of clathrin light chain comprising the Hip1R-binding region affected cellular actin distribution. Together these results suggest that the roles of Hip1 and Hip1R in affecting clathrin assembly and actin distribution are mediated by their interaction with the conserved sequence of clathrin light chains.     

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.     

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.     

Compromise of clathrin function and membrane association by clathrin light chain deletion

While clathrin heavy chains from different species are highly conserved in amino acid sequence, clathrin light chains are much more divergent. Thus clathrin light chain may have different functions in different organisms. To investigate clathrin light chain function, we cloned the clathrin light chain, clcA, from Dictyostelium and examined clathrin function in clcA– mutants. Phenotypic deficiencies in development, cytokinesis, and osmoregulation showed that light chain was critical for clathrin function in Dictyostelium . In contrast with budding yeast, we found the light chain did not influence steady-state levels of clathrin, triskelion formation, or contribute to clathrin over-assembly on intracellular membranes. Imaging GFP-CHC in clcA– mutants showed that the heavy chain formed dynamic punctate structures that were remarkably similar to those found in wild-type cells. However, clathrin light chain knockouts showed a decreased association of clathrin with intracellular membranes. Unlike wild-type cells, half of the clathrin in clcA– mutants was cytosolic, suggesting that the absence of light chain compromised the assembly of triskelions onto intracellular membranes. Taken together, these results suggest a role for the Dictyostelium clathrin light chain in regulating the self-assembly of triskelions onto intracellular membranes, and demonstrate a crucial contribution of the light chain to clathrin function in vivo .     

Clathrin self-assembly is regulated by three light-chain residues controlling the formation of critical salt bridges.

Clathrin self-assembly into a polyhedral lattice mediates membrane protein sorting during endocytosis and organelle biogenesis. Lattice formation occurs spontaneously in vitro at low pH and, intracellularly, is triggered by adaptors at physiological pH. To begin to understand the cellular regulation of clathrin polymerization, we analyzed molecular interactions during the spontaneous assembly of recombinant hub fragments of the clathrin heavy chain, which bind clathrin light-chain subunits and mimic the self-assembly of intact clathrin. Reconstitution of hubs using deletion and substitution mutants of the light-chain subunits revealed that the pH dependence of clathrin self-assembly is controlled by only three acidic residues in the clathrin light-chain subunits. Salt inhibition of hub assembly identified two classes of salt bridges which are involved and deletion analysis mapped the clathrin heavy-chain regions participating in their formation. These combined observations indicated that the negatively charged regulatory residues, identified in the light-chain subunits, inhibit the formation of high-affinity salt bridges which would otherwise induce clathrin heavy chains to assemble at physiological pH. In the presence of light chains, clathrin self-assembly depends on salt bridges that form only at low pH, but is exquisitely sensitive to regulation. We propose that cellular clathrin assembly is controlled via the simple biochemical mechanism of reversing the inhibitory effect of the light-chain regulatory sequence, thereby promoting high-affinity salt bridge formation.     

A Comparison of GFP‐Tagged Clathrin Light Chains with Fluorochromated Light Chains In Vivo and In Vitro

Clathrin triskelia consist of three heavy chains and three light chains (LCs). Green fluorescent protein (GFP)‐tagged LCs are widely utilized to follow the dynamics of clathrin in living cells, but whether they reflect faithfully the behavior of clathrin triskelia in cells has not been investigated yet thoroughly. As an alternative approach, we labeled purified LCs either with Alexa 488 or Cy3 dye and compared them with GFP‐tagged LC variants. Cy3‐labeled light chains (Cy3‐LCs) were microinjected into HeLa cells either directly or in association with heavy chains. Within 1–2 min the Cy3‐LC heavy chain complexes entered clathrin‐coated structures, whereas uncomplexed Cy3‐LC did not within 2 h. These findings show that no significant exchange of LCs occurs over the time–course of an endocytic cycle. To explore whether GFP‐tagged LCs behave functionally like endogenous LCs, we characterized them biochemically. Unlike wild‐type LCs, recombinant LCs with a GFP attached to either end did not efficiently inhibit clathrin assembly in vitro, whereas Cy3‐ and Alexa 488‐labeled LC behaved similar to wild‐type LCs in vitro and in vivo. Thus, fluorochromated LCs are a valuable tool for investigating the complex behavior of clathrin in living cells.     

Protein organization in clathrin trimers

We have prepared a homogeneous, soluble 8.6S species (“8.6S clathrin”) from calf-brain coated vesicles. Crosslinking experiments show that this 8.6S clathrin is composed of three heavy chains (molecular weight 180,000) and three light chains (molecular weights 33,000 and 36,000). Each heavy chain is in close contact with a single light chain, and the light chains appear not to be in contact with each other. Intact 8.6S clathrin can reassemble into cages without participation of additional protein species.     

Analysis of clathrin light chain-heavy chain interactions using truncated mutants of rat liver light chain LCB3

Clathrin light chains are extended molecules located along the proximal segment of each of the three heavy chain legs of a clathrin trimer. All mammalian light chains share a central segment with 10 repeated heptad motifs believed to mediate the interaction with clathrin heavy chains. In order to test this model in more detail, we have expressed intact rat liver clathrin light chain LCB3 in Escherichia coli and find that it binds tightly to calf clathrin heavy chains. Using a set of expressed truncated mutants of LCB3, we show that the presence of seven to eight heptads is indeed necessary for a successful interaction. More extensive deletions of the central segment completely abolish the ability to bind to heavy chains. Neither the amino- nor the carboxyl-terminal domain is essential for binding, but competition experiments show that the presence of the carboxyl-terminal domain does enhance the interaction with heavy chains.     

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.     

Clathrin domains involved in recognition by assembly protein AP-2

The domains on clathrin responsible for interaction with the plasma membrane-associated assembly protein AP-2 have been studied using a novel cage binding assay. AP-2 bound to pure clathrin cages but not to coat structures already containing AP that had been prepared by coassembly. Binding to preassembled cages also occurred in the presence of elevated Tris-HCl concentrations (greater than or equal to 200 mM) which block AP-2 interactions with free clathrin. AP-2 interactions with assembled cages could also be distinguished from AP-2 binding to clathrin trimers by sodium tripolyphosphate (NaPPPi), which binds to the alpha subunit of AP-2 (Beck, K., and Keen, J. H. (1991) J. Biol. Chem. 266, 4442-4447). At concentrations of 1-5 mM, NaPPPi blocked clathrin-triskelion binding; in contrast, interactions with cages persisted in the presence of 25 mM NaPPPi. To begin to identify the region(s) of the clathrin molecule important in recognition by AP-2, clathrin cages were proteolyzed to remove heavy chain terminal domains and portions of the distal leg as well as all of the light chains. AP-2 bound to these "clipped cages"; however, unlike the interaction with native cages, binding of AP-2 to clipped cages was sensitive to the lower concentrations of both Tris-HCl and NaPPPi which disrupt interactions of AP-2 with clathrin trimers. Reconstitution of the clipped cages with clathrin light chains did not restore resistance of AP-2 binding to Tris-HCl. We conclude that one binding site for AP-2 resides on the hub and/or proximal part of the clathrin triskelion whereas a second site is likely to involve the terminal domain and/or distal leg; the second site is manifested only in the assembled lattice structure. We suggest that these two distinct binding interactions may be mediated by the two unique large subunits within the AP-2 complex, acting sequentially during assembly.     

Improved Coated Vesicle Isolation Allows Better Characterization of Clathrin Polypeptides

Postmicrosomal pellets from plant sources are grossly contaminatedwith nbosomes. Previous purifications of clathrin coated vesicles(CCV) from such subcellular fractions have therefore often involvedan RNase treatment. Performed at 30°C, this step inherentlycarries with it the dangers of proteolysis. We document herea method for CCV isolation which avoids this. Through the inclusionof suitable antiproteases in the homogenizing and subsequentisolation media, we have also been able to improve the qualityof CCV recovered from plant tissues. As a result we have tentativelybeen able to identify clathrin light chains from zucchini hypocotyland pea cotyledon CCV. Similar to light chains from bovine brainthese polypeptides are heat stable, can be solubilized fromneutralized TCA precipitates, bind calcium and clathrin heavychains. However, in contrast to brain CCV the two light chainsof plant CCV are some 10 kDa heavier. Key words: Antiproteases, Ca²⁺-binding, clathrin coated vesicles, clathrin heavy chains, clathrin light chain(s), heat stability, pea cotyledons, RNase, zucchini hypocotyls     

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.     

Human erythrocyte clathrin and clathrin-uncoating protein

Clathrin, a Mr = 72,000 clathrin-associated protein, and myosin were purified in milligram quantities from the same erythrocyte hemolysate fraction. Erythrocyte clathrin closely resembled brain clathrin in several respects: (a) both are triskelions as visualized by electron microscopy with arms 40 nm in length with globular ends and a flexible hinge region in the middle of each arm, and these triskelions assemble into polyhedral "cages" at appropriate pH and ionic strength; (b) both molecules contain heavy chains of Mr = 170,000 that are indistinguishable by two-dimensional maps of 125I-labeled peptides; and (c) both molecules contain light chains of Mr approximately 40,000 in a 1:1 molar ratio with the heavy chain. Erythrocyte clathrin is not identical to brain clathrin since antibody raised against the erythrocyte protein reacts better with erythrocyte clathrin than with brain clathrin and since brain clathrin contains two light chains resolved on sodium dodecyl sulfate gels while the light chain of erythrocyte clathrin migrates as a single band. The erythrocyte Mr = 72,000 clathrin-associated protein is closely related to a protein in brain that mediates ATP-dependent disassembly of clathrin from coated vesicles and binds tightly to clathrin triskelions (Schlossman, D. M., Schmid, S. L., Braell, W. A., and Rothman, J. E. (1984) J. Cell Biol. 99, 723-733). The erythrocyte and brain proteins have identical Mr on sodium dodecyl sulfate gels and identical maps of 125I-labeled peptides, share antigenic sites, and bind tightly to ATP immobilized on agarose. Clathrin and the uncoating protein are not restricted to reticulocytes since equivalent amounts of these proteins are present in whole erythrocyte populations and reticulocyte-depleted erythrocytes. Clathrin is present at 6,000 triskelions/cells, while the uncoating protein is in substantial excess at 250,000 copies/cell.     

Functional evidence for the identification of an Arabidopsis clathrin light chain polypeptide

Clathrin light chains (CLCs) are regulatory subunits of clathrin triskelia. Based on homology searches in Arabidopsis thaliana data bases we have identified three putative CLC clones, and have focused on the one with the highest homology to mammalian CLC sequences. Analysis of its sequence has revealed coiled-coil structures within a region that corresponds to the clathrin heavy chain-binding site. In addition there is a stretch of acidic amino acids, which is required for the regulatory function of CLC in clathrin assembly. This putative plant CLC ortholog, expressed in bacteria as a glutathione-S-transferase- and myc-tagged fusion protein, was shown to bind to CLC-free recombinantly expressed mammalian clathrin hubs. In contrast, purified native mammalian triskelia with endogeneous CLC did not bind the recombinant putative plant CLC. Based on the conserved sequences between the three Arabidopsis candidates it appears that plants, unlike mammals, may have more than two CLCs.     

Presence of an extensive clathrin coat on the apical plasmalemma of the rat kidney proximal tubule cell

The nature of the cytoplasmic coat present on the apical invaginations of the kidney proximal tubule cell was investigated by immuneoverlay and immunocytochemistry of renal brush borders with anticlathrin antibodies. When kidney cortex was prepared for electron microscopy using methods that enhance visualization of clathrin coats, the apical invaginations at the base of the brush border microvilli were seen to be backed by a nearly continuous coating which resembles but is more extensive than the lattice-like clathrin coats found around brain coated vesicles. When isolated brush border fractions were prepared under conditions that preserve the coats, separated by SDS PAGE, and transferred to nitrocellulose, the presence of clathrin heavy and light chains was detected by immuneoverlay using two different affinity-purified anticlathrin IgGs--one that we prepared, which detects only the clathrin light chains, and the other, prepared by Louvard et al. ( Louvard , D., C. Morris, G. Warren, K. Stanley, F. Winkler , and H. Reggio , 1983, EMBO [Eur. Mol. Biol. Organ.] J., 2:1655-1664), which detects both the heavy and light chains. As viewed by light microscopy (immunofluorescence or immunoperoxidase), staining with both anticlathrins was concentrated at the base of the proximal tubule microvilli. Immunoelectron microscopic localizations carried out on brush border fractions (using peroxidase and gold conjugates) demonstrated specific binding of anticlathrin IgGs to the lattice-like cytoplasmic coat. When brush border fractions were reacted with monoclonal antibodies prepared against gp330 and maltase, proteins that serve as markers for the membrane of the apical invaginations and microvilli, respectively ( Kerjaschki , D., L. Noronha - Blob , B. Sacktor , and M. G. Farquhar , 1984, J. Cell Biol., 98:1505-1513), the two proteins retained their restrictive distribution in the brush border. The findings demonstrate (a) that the cytoplasmic coat of the proximal tubule intermicrovillar apical invaginations is composed of clathrin heavy and light chains, and (b) that the differential distribution of proteins in these two brush border microdomains is maintained in appropriately prepared brush border fractions.     

Clathrin light chain: importance of the conserved carboxy terminal domain to function in living cells

Clathrin triskelions assemble into coats capable of packaging membrane and receptors for transport to intracellular destinations. A triskelion is formed from three heavy chains bound to three light chains. All clathrin light chains (clc) contain an acidic amino terminal domain, a central coiled segment, and a carboxy terminal domain conserved in amino acid sequence. To assess their functional contribution in vivo, we expressed tagged segments of the Dictyostelium clcA in clc-minus Dictyostelium (clc null) cells. We examined the ability of these clcA fragments to rescue clathrin phenotypic deficiencies, to cluster into punctae on membranes, and to bind to the heavy chain. When expressed in clc null cells, a clcA fragment containing the amino terminal domain and the central coiled domain bound heavy chain but was dispensable for clathrin function. Instead, the carboxy terminal domain of clcA was a critical determinant for association with punctae, for clathrin function and for robust binding to the heavy chain. A 70 amino acid carboxy terminal fragment was necessary and sufficient for full function, and for localization into punctae on intracellular membranes. A shorter 49 amino acid carboxy terminal fragment could distribute into punctae but failed to rescue developmental deficiencies. These results reveal the importance of the carboxy terminal domain of the light chain in vivo.     

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.     

Effect of clathrin heavy chain- and alpha-adaptin-specific small inhibitory RNAs on endocytic accessory proteins and receptor trafficking in HeLa cells

To assess the contribution of individual endocytic proteins to the assembly of clathrin coated pits, we depleted the clathrin heavy chain and the alpha-adaptin subunit of AP-2 in HeLa-cells using RNA interference. 48 h after transfection with clathrin heavy chain-specific short interfering RNA both, the heavy and light chains were depleted by more than 80%. Residual clathrin was mainly membrane-associated, and an increase in shallow pits was noted. The membrane-association of adaptors, clathrin assembly lymphoid myeloid leukemia protein (CALM), epsin, dynamin, and Eps15 was only moderately affected by the knockdown and all proteins still displayed a punctate staining distribution. Clathrin depletion inhibited the uptake of transferrin but not that of the epidermal growth factor. However, efficient sorting of the epidermal growth factor into hepatocyte growth factor-regulated tyrosine kinase substrate-positive endosomes was impaired. Depletion of alpha-adaptin abolished almost completely the plasma membrane association of clathrin. Binding of Eps15 to membranes was strongly and that of CALM moderately reduced. Whereas the uptake of transferrin was efficiently blocked in alpha-adaptin knockdown cells, the internalization and sorting of the epidermal growth factor was not significantly impaired. Since neither clathrin nor AP-2 is essential for the internalization of EGF, we conclude that it is taken up by an alternative mechanism.     

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.