Mapping two functional domains of clathrin light chains with monoclonal antibodies

The two forms of clathrin light chains (LCA and LCB) or clathrin-associated proteins (CAP1 and CAP2) have presented an immunochemical paradox. Biochemically similar, both possess two known functional parameters: binding the clathrin heavy chain and mediating the action of an uncoating ATPase. All previously reported anti-CAP mAbs, however, react specifically with only CAP1 (Brodsky, F. M., 1985, J. Cell Biol., 101:2047-2054; Kirchhausen, T., S. C. Harrison, P. Parham, and F. M. Brodsky, 1983, Proc. Natl. Acad. Sci. USA, 80:2481-2485). Four new anti-CAP mAbs are reported here: two, C-7H12 and C-6C1, react with both forms; two others, C-10B2 and C-4E5, react only with the lower form. Sandwich ELISAs indicated that C-10B2, C-4E5, C-6C1, and C-7H12 react with distinct epitopes. Monoclonal antibodies C-10B2 and C-4E5 immunoprecipitate clathrin-coated vesicles (CCVs) and react with CAP2 epitopes accessible to chymotrypsin on the vesicle. These mAbs inhibit phosphorylation of CAP2 by endogenous CCV casein kinase II. In contrast, C-6C1 and C-7H12 react with epitopes that are relatively insensitive to chymotrypsin. CAP peptide fragments containing these epitopes remain bound to reassembled cages or CCVs after digestion. Immunoprecipitation and ELISAs demonstrate that C-7H12 and C-6C1 react with unbound CAPs but not with CAPs bound to triskelions or CCVs. The data indicate that the CAPs consist of at least two discernible structural domains: a nonconserved, accessible domain that is relevant to the phosphorylation of CAP2 and a conserved, inaccessible domain that mediates the binding of CAPs to CCVs.     

Bovine brain clathrin light chains impede heavy chain assembly in vitro

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

Class-defining characteristics in the mouse heavy chains of variable domains

Analysis of residue correlation in over 2700 mouse heavy chains of the V(H) domains was carried out on three hierarchical levels. At the 'position' level, statistical analysis revealed 45 positions that conserve similar residues in almost all chains. At the 'fragment' level, the focus of investigation shifted to the study of combinations of amino acids in strands and loops. It was found that no more than 10 patterns were sufficient for describing strands and loops in the chains. At the 'sequence' level, we determined all possible combinations of these patterns and classified the mouse heavy chains. Comparison of the sequences in the eight classes revealed residues at the class-determining positions that were unique to each class. Because a strong correlation of residues was found, one only needs several residues to classify a sequence. It follows that no all residue alignment procedure is necessary to divide sequences into classes. An important corollary of our approach is the possibility of predicting residues in an incomplete sequence from a small sequence fragment. On the basis of our analysis of mouse heavy chains we hypothesize about the presently unknown mouse V(H) germline repertoire.     

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.     

Differential regulation of myosin heavy chains defines new muscle domains in zebrafish

Numerous muscle lineages are formed during myogenesis within both slow- and fast-specific cell groups. In this study, we show that six fast muscle–specific myosin heavy chain genes have unique expression patterns in the zebrafish embryo. The expression of tail-specific myosin heavy chain (fmyhc2.1) requires wnt signaling and is essential for fast muscle organization within the tail. Retinoic acid treatment results in reduced wnt signaling, which leads to loss of the fmyhc2.1 domain. Retinoic acid treatment also results in a shift of muscle identity within two trunk domains defined by expression of fmyhc1.2 and fmyhc1.3 in favor of the anteriormost myosin isoform, fmyhc1.2. In summary, we identify new muscle domains along the anteroposterior axis in the zebrafish that are defined by individual nonoverlapping, differentially regulated expression of myosin heavy chain isoforms.     

Biochemical and immunological studies on clathrin light chains and their binding sites on clathrin triskelions

Clathrin light chains from bovine brain tissue (LC alpha and LC beta) are monomeric proteins with an average mol. wt. of approximately 33,000, as determined by sedimentation equilibrium. Solution studies on purified light chains indicate a large Stokes radius (Re = 3.3 nm) and little defined secondary structure. Both light chains bind specifically and with high affinity (KA approximately 5 x 10(7)/M) to overlapping sites on clathrin heavy chains. These binding sites are contained within a 125,000 dalton heavy chain fragment that forms truncated triskelions with legs, 15 nm shorter than those of intact triskelions. As judged by immuno-electron microscopy, light chain-specific IgG molecules bind mostly to the center of triskelions, but there are also sites that are scattered some 16 nm along the proximal part of triskelion legs. From heterologous binding experiments using human placenta light chains and heavy chain fragments from bovine brain clathrin, it is concluded that the domains of light and heavy chains that are involved in the interaction are conserved across tissue and species boundaries.     

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.     

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.     

Structural evidence for an unblocked VHI sub-subgroup of human heavy chains.

The N-terminal amino acid sequence of an unblocked human heavy chain of an IgGK paraprotein from patient Tho is reported. This unblocked VH sequence belongs to the VHI subgroup and has striking structural homology to an unblocked VHI sequence previously reported for the IgGK paraprotein isolated from the serum of patient Bro. Direct sequence comparison of the Tho and Bro proteins reveals complete structural identity in 25 of the N-terminal 27 residues, with unique amino acid substitutions shared at the N-terminus and positions 16, 18, and 24. This remarkable sequence homology suggests that the two VH sequences represent examples of an unblocked VHI sub-subgroup. The Tho and Bro sequences possess an ala-glu-val basic triplet at positions 9 to 11 in common with the other previously reported VHI proteins which help to further establish this sequence triplet as a recognizable VHI subgroup-specific region. Moreover, in this regard, the unblocked sequences of Tho and Bro emphasize the importance of extending an unblocked VHI sequence beyond positions 9 to 11 before a subgroup assignment can be determined.     

Non-stoichiometric relationship between clathrin heavy and light chains revealed by quantitative comparative proteomics of clathrin-coated vesicles from brain and liver

We used tandem mass spectrometry with peptide counts to identify and to determine the relative levels of expression of abundant protein components of highly enriched clathrin-coated vesicles (CCVs) from rat liver. The stoichiometry of stable protein complexes including clathrin heavy chain and clathrin light chain dimers and adaptor protein (AP) heterotetramers was assessed. We detected a deficit of clathrin light chain compared with clathrin heavy chain in non-brain tissues, suggesting a level of regulation of clathrin cage formation specific to brain. The high ratio of AP-1 to AP-2 in liver CCVs is reversed compared with brain where there is more AP-2 than AP-1. Despite this, general endocytic cargo proteins were readily detected in liver but not in brain CCVs, consistent with the previous demonstration that a major function for brain CCVs is recycling synaptic vesicles. Finally we identified 21 CCV-associated proteins in liver not yet characterized in mammals. Our results further validate the peptide accounting approach, reveal new information on the properties of CCVs, and allow for the use of quantitative proteomics to compare abundant components of organelles under different experimental and pathological conditions.     

Tyrosine phosphorylation of clathrin heavy chain under oxidative stress

In mouse pancreatic insulin-producing betaTC cells, oxidative stress due to H(2)O(2) causes tyrosine phosphorylation in various proteins. To identify proteins bearing phosphotyrosine under stress, the proteins were affinity purified using an anti-phosphotyrosine antibody-conjugated agarose column. A protein of 180kDa was identified as clathrin heavy chain (CHC) by electrophoresis and mass spectrometry. Immunoprecipitated CHC showed tyrosine phosphorylation upon H(2)O(2) treatment and the phosphorylation was suppressed by the Src kinase inhibitor, PP2. The phosphorylation status of CHC affected the intracellular localization of CHC and the clathrin-dependent endocytosis of transferrin under oxidative stress. In conclusion, CHC is a protein that is phosphorylated at tyrosine by H(2)O(2) and this phosphorylation status is implicated in the intracellular localization and functions of CHC under oxidative stress. The present study demonstrates that oxidative stress affects intracellular vesicular trafficking via the alteration of clathrin-dependent vesicular trafficking.     

IL-7 induces tyrosine phosphorylation of clathrin heavy chain

IL-7 induction of protein tyrosine phosphorylation was examined in an IL-7-dependent thymocyte cell line, D1, which was generated from a p53-/- mouse. Anti-phosphotyrosine antibody was used both to immunoprecipitate and Western blot, and showed that IL-7 induced tyrosine phosphorylation of a protein with a molecular weight of approximately 200 kDa. The P200 band was purified by reversed-phase high-performance liquid chromatography. Amino acid sequencing by mass spectrometry revealed three peptides identical to rat clathrin heavy chain (CHC) 1 (192 kDa), and this was confirmed by blotting with an anti-clathrin antibody. Stimulation of normal pro-T cells by IL-7 showed an increased tyrosine phosphorylation of clathrin heavy chain. Tyrosine phosphorylation of clathrin heavy chain was strongly induced by IL-7 and to a lesser extent by IL-4, while no effect could be observed with the cytokines IL-2, IL-9 and IL-15, whose receptors share the gammac chain. Phosphorylation of clathrin heavy chain was found to be sensitive to Jak3 inhibitors but not to Src inhibitors. Clathrin is involved in internalization of many receptors, and its phosphorylation by IL-7 stimulation may affect the internalization of the IL-7 receptor.     

The occurrence of disulphide bonds in purified clathrin light chains.

Three forms of clathrin light chain contain two cysteine residues. These are the predominant brain-specific forms of LCa and LCb and the non-brain form of LCb. After purification in the absence of thiols they contain intramolecular disulphide bonds. The reduced and the oxidized forms show differences in electrophoretic mobility, explaining the variable and heterogeneous patterns observed on electrophoresis. Accessibility of the thiol groups in the free light chains is greater than when they are associated with the heavy chain. In contrast the cysteine residues of the clathrin heavy chain are completely inaccessible in the absence of denaturants and are not found in disulphide bonds. The antigenic properties of the oxidized and the reduced forms of the clathrin light chains are similar, as is their capacity to bind to the clathrin heavy chain. After isolation in the presence of 10 mM-iodoacetamide, the light-chain cysteine residues are fully alkylated. The results are consistent with the reduced form being the native state and the light-chain disulphide bonds an artifact of isolation.     

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.     

Characterization of the clathrin heavy chain from Dictyostelium discoideum.

We report the cloning and analysis of a clathrin heavy-chain cDNA from the eukaryotic microorganism, Dictyostelium discoideum. A single gene, designated chcA, for the clathrin heavy chain encoded a protein of 1,694 amino acids with a molecular mass of 193,618 daltons. Comparison of the amino acid sequence with the rat and with the yeast sequence showed that the highly conserved protein was more similar to the mammalian clathrin heavy chain (57% identity) than to the yeast heavy chain (45% identity). The mRNA for the clathrin heavy chain was regulated during development. mRNA levels were highest during vegetative growth and declined as the cells progressed through the 24-hr developmental cycle. The concentration of clathrin heavy-chain protein was the same in cells grown in liquid media (high rates of pinocytosis) as in cells grown with bacteria (low rates of pinocytosis), which suggests that regulation of pinocytosis in these cells is not achieved by altering the concentration of clathrin.     

A monoclonal antibody to the heavy chain of clathrin.

Monoclonal antibodies have been raised to pig brain triskelions and one clone, DC41, was found to recognize the clathrin heavy chain by immunoblotting. However, both by immunofluorescence and immunoelectron microscopy, and in complete contrast to polyclonal anti-clathrin antibodies, monoclonal DC41 did not label either coated pits or coated vesicles anywhere in the cell. Instead it appeared to label the cell cytoplasm. These data suggest that DC41 recognizes a cytoplasmic form of clathrin, perhaps that form produced by uncoating of coated vesicles which is then ready to re-build another coated pit.     

Sequence of the clathrin heavy chain from Saccharomyces cerevisiae and requirement of the COOH terminus for clathrin function

The sequence of the clathrin heavy chain gene, CHC1, from Saccharomyces cerevisiae is reported. The gene encodes a protein of 1,653 amino acids that is 50% identical to the rat clathrin heavy chain (HC) (Kirchhausen, T., S. C. Harrison, E. P. Chow, R. J. Mattaliano, R. L. Ramachandran, J. Smart, and J. Brosius. 1987. Proc. Natl. Acad. Sci. USA. 84:8805-8809). The alignment extends over the complete length of the two proteins, except for a COOH-terminal extension of the rat HC and a few small gaps, primarily in the globular terminal domain. The yeast HC has four prolines in the region of the rat polypeptide that was proposed to form the binding site for clathrin light chains via an alpha-helical coiled-coil interaction. The yeast protein also lacks the COOH-terminal Pro-Gly rich segment present in the last 45 residues of the rat HC, which were proposed to be involved in the noncovalent association of HCs to form trimers at the triskelion vertex. To examine the importance of the COOH terminus of the HC for clathrin function, a HC containing a COOH-terminal deletion of 57 amino acids (HC delta 57) was expressed in clathrin-deficient yeast (chc1-delta). HC delta 57 rescued some of the phenotypes (slow growth at 30 degrees, genetic instability, and defects in mating and sporulation) associated with the chc1-delta mutation to normal or near normal. Also, truncated HCs were assembled into triskelions. However, cells with HC delta 57 were temperature sensitive for growth and still displayed a major defect in processing of the mating pheromone alpha-factor. Fewer coated vesicles could be isolated from cells with HC delta 57 than cells with the wild-type HC. This suggests that the COOH-terminal region is not required for formation of trimers, but it may be important for normal clathrin-coated vesicle structure and function.     

Tropomyosin-like properties of clathrin light chains allow a rapid, high-yield purification

The light chains (LCa and LCb) of bovine brain clathrin are resistant to heat denaturation by boiling, a property shared by tropomyosin (Bailey, K., 1948, Biochem. J., 43:271-281). Light chains were partially purified by boiling and centrifugation of a Tris-extract of crude membranes prepared from bovine brains (Keen, J. H., M. C. Willingham, and I. H. Pastan, 1979, Cell., 16:303-312). Contaminant polypeptides were then removed by size-exclusion high-pressure liquid chromatography. The purified light chains were separated from each other by using an immunoaffinity column prepared from a monoclonal antibody CVC.7 specific for LCa and not LCb.     

Transformation by Rous sarcoma virus induces clathrin heavy chain phosphorylation

We have shown that the heavy chain of clathrin is phosphorylated in chicken embryo fibroblast cells transformed by Rous sarcoma virus, but not in normal cells. Approximately 1 mol of phosphate is bound for every 5 mol of heavy chain in the maximally phosphorylated transformed cells. Two-thirds of the phosphate is on serine and one-third on tyrosine residues. Clathrin heavy chain is a substrate for pp60v-src in vitro. Cleveland analysis of the in vivo and in vitro clathrin heavy chain phosphopeptides, generated by protease V8 digestion, show labeled proteolytic fragments of similar molecular weight, suggesting that pp60v-src could be directly responsible for the in vivo phosphorylation of clathrin. Phosphate is equally incorporated into clathrin in both the unassembled and the assembled clathrin pools, whereas [35S]methionine is preferentially incorporated into the assembled pool. In normal cells, clathrin visualized by immunofluorescent staining appears in a punctate pattern along the membrane surface and concentrated around the nucleus; in transformed cells the perinuclear staining is completely absent. The phosphorylation of clathrin heavy chain in transformed cells may be linked to previously observed transformation-dependent alterations in receptor-mediated endocytosis of ligands such as EGF and thrombin.     

Structural domains in RNAi

Structural and biochemical studies have begun to elucidate the pathway of RNA silencing that leads to the formation of the RISC complex. The outstanding feature of this pathway is the precise recognition and processing of double-stranded RNA. We present a review of recent structures that illustrate the molecular mechanisms contributing to these two related functions, highlighting models of Drosha, Dicer, and RISC function.