The three-dimensional molecular structure of the desmosomal plaque

The cytoplasmic surface of intercellular junctions is a complex network of molecular interactions that link the extracellular region of the desmosomal cadherins with the cytoskeletal intermediate filaments. Although 3D structures of the major plaque components are known, the overall architecture remains unknown. We used cryoelectron tomography of vitreous sections from human epidermis to record 3D images of desmosomes in vivo and in situ at molecular resolution. Our results show that the architecture of the cytoplasmic surface of the desmosome is a 2D interconnected quasiperiodic lattice, with a similar spatial organization to the extracellular side. Subtomogram averaging of the plaque region reveals two distinct layers of the desmosomal plaque: a low-density layer closer to the membrane and a high-density layer further away from the membrane. When combined with a heuristic, allowing simultaneous constrained fitting of the high-resolution structures of the major plaque proteins (desmoplakin, plakophilin, and plakoglobin), it reveals their mutual molecular interactions and explains their stoichiometry. The arrangement suggests that alternate plakoglobin-desmoplakin complexes create a template on which desmosomal cadherins cluster before they stabilize extracellularly by binding at their N-terminal tips. Plakophilins are added as a molecular reinforcement to fill the gap between the formed plaque complexes and the plasma membrane.     

Immunocytochemical identification of epithelium-derived human tumors with antibodies to desmosomal plaque proteins.

Epithelial cells contain desmosomes, special intercellular junctions providing sites of membrane attachment for intermediate-sized filaments of the cytokeratin type (tonofilaments). Such sites of anchorage of tonofilaments appear as dense plaques on the cytoplasmic side of the desmosomal membrane. We have isolated desmosome-enriched fractions from bovine snout epidermis and tongue mucosa and have characterized the major protein associated with the desmosomal plaque. This protein occurs in equimolar amounts of two polypeptides of Mr 250,000 (desmoplakin I) and Mr 215,000 (desmoplakin II) which are chemically and immunologically related. Antibodies raised against desmoplakins allow the identification and localization of this protein in epithelial cells grown in tissues or in vitro and show crossreaction in species as diverse as man, mouse, and chicken. Using immunolocalization at the light and electron microscope levels, we show that these antibodies bind specifically to desmosomal plaques. Antibodies to desmoplakins have been used successfully for detection of desmosomal proteins in a broad variety of epithelium-derived human tumors, including primary carcinomas and their metastases, irrespective of the morphology of the specific tumor. Nonepithelial tumors examined have been negative. We propose to use antibodies to desmoplakins and to cytokeratins in pathological diagnosis as two independent markers for the positive immunocytochemical identification and classification of epithelium derived tumors.     

Molecular structure of the human desmoplakin I and II amino terminus.

Desmoplakins (DPs) I and II are closely related proteins found in the innermost region of the desmosomal plaque, which serves as a cell surface attachment site for cytoplasmic intermediate filaments. Overlapping cDNA clones comprising 9.2 kilobases of DP-I, predicted to encode a full-length 310-kDa polypeptide (2677 amino acid residues), have now been identified. Here we report the predicted protein sequence and structural analysis of the N terminus of DP, extending our previous study of the rod and carboxyl domains. The N terminus contains groups of heptad repeats that are predicted to form at least two major alpha-helical-rich bundles. Unlike the rod and carboxyl domains, the N terminus did not display a periodic distribution of charged residues. Northern blot mapping and genomic sequence analysis were also undertaken to examine the organization of the DP mRNAs. A 1-kilobase intron was located at the 3' boundary of a DP-I-specific region; however, instead of an intron at the 5' junction, a possible splice donor site was observed within a potential coding sequence, suggesting alternative RNA splicing from an internal donor site.     

A cell surface desmosome-associated component: identification of tissue-specific cell adhesion molecule.

Autoantibodies in the serum of patients suffering the blistering skin disease pemphigus vulgaris recognize a 140-kDa glycoprotein (GP) present in enriched fractions of bovine tongue epidermal desmosomes. Immunofluorescence observations of cryostat sections of bovine tongue epidermis reveal that affinity-purified rabbit antibodies to the 140-kDa GP generate a punctate intercellular stain that is similar to that generated by antibodies directed against a desmosome plaque component (desmoplakin). In cultured mouse keratinocytes, the antibodies against 140-kDa GP recognize desmosomes along areas of cell-cell contact. Double immunofluorescence of cultured keratinocytes with these antibodies and a desmoplakin antiserum reveals that the antibodies against the 140-kDa GP stain a single fluorescent line along areas of cell-cell contact. This single fluorescent line lies between double fluorescent lines generated by the desmoplakin antiserum. Immunogold ultrastructural localization reveals that the 140-kDa antigen is localized not only along the intercellular area of the desmosome but also is found along the whole epidermal cell surface. The antibodies to the 140-kDa GP are able to induce a disruption of cell-cell contact in cultured keratinocytes that possess desmosomes. We propose that the 140-kDa GP is a cell adhesion molecule (CAM). Furthermore we discuss the heterogeneity of desmosomes in the light of our findings that antibodies against the 140-kDa GP recognize specific stratified squamous epithelial tissues.     

Identification of amino acid sequence motifs in desmocollin, a desmosomal glycoprotein, that are required for plakoglobin binding and plaque formation.

By transfecting epithelial cells with gene constructs encoding chimeric proteins of the transmembrane part of the gap junction protein connexin 32 in combination with various segments of the cytoplasmic part of the desmosomal cadherin desmocollin 1a, we have determined that a relatively short sequence element is necessary for the formation of desmosome-like plaques and for the specific anchorage of bundles of intermediate-sized filaments (IFs). Deletion of as little as the carboxyl-terminal 37 aa resulted in a lack of IF anchorage and binding of the plaque protein plakoglobin, as shown by immunolocalization and immunoprecipitation experiments. In addition, we show that the sequence requirements for the recruitment of desmoplakin, another desmosomal plaque protein, differ and that a short (10 aa) segment of the desmocollin 1a tail, located close to the plasma membrane, is also required for the binding of plakoglobin, as well as of desmoplakin, and also for IF anchorage. The importance of the carboxyl-terminal domain, homologous in diverse types of cadherins, is emphasized, as it must harbor, in a mutually exclusive pattern, the information for assembly of the IF-anchoring desmosomal plaque in desmocollins and for formation of the alpha-/beta-catenin- and vinculin-containing, actin filament-anchoring plaque in E- and N-cadherin.     

Molecular genetics of arrhythmogenic right ventricular cardiomyopathy: emerging horizon?

PURPOSE OF REVIEW: Recent developments in the elucidation of genes underlying arrhythmogenic right ventricular cardiomyopathy and possible pathogenic mechanisms will be highlighted. RECENT FINDINGS: The cardiac desmosome is a multiprotein structure involved in cell-cell interactions. Mutations in genes encoding desmosomal proteins such as PKP2, DSP, JUP, DSC2 and DSG2 underlie arrhythmogenic right ventricular cardiomyopathy, which can therefore be considered a desmosome cardiomyopathy. Mutations in the plakophilin-2 gene are most prevalent. Current pathophysiological insights suggest a final common pathway in which plakoglobin release from the desmosome, independent of the primarily affected desmosomal protein, results in desmosome impairment, intercalated disc remodeling and Wnt/beta-catenin pathway signaling defects. The recognition of left ventricular involvement associated with mutations in desmosomal protein genes and low penetrance suggests that formal criteria should not be followed too closely in selecting patients for DNA analysis, because finding a mutation may have important implications for clinical practice. SUMMARY: Recent developments have demonstrated that arrhythmogenic right ventricular cardiomyopathy can be considered a desmosome cardiomyopathy. Left ventricular involvement is not uncommon in this type of cardiomyopathy. Such findings are important for diagnostics and family screening and form a starting-point for the elucidation of other (non)-genetic factors influencing disease progression and outcome.     

A 45-kDa protein antigenically related to band 3 is selectively expressed in kidney mitochondria.

Anion exchange similar to that catalyzed by erythrocyte band 3 occurs across many nonerythroid cell membranes. To identify anion-exchange proteins structurally related to band 3, we immunoblotted rabbit kidney medullary membrane fractions with anti-band 3 antibodies. Immunoblots using antibodies to the cytoplasmic domain of band 3 revealed cross-reactive proteins in the plasma membrane fraction only. In contrast, two monoclonal antibodies against band 3 membrane domain labeled a 45-kDa protein; further immunoblotting and immunogold studies of membrane fractions and kidney sections using one of the anti-membrane domain antibodies showed that labeling was strongest in mitochondria of H(+)-secreting collecting duct cells. Tissue-to-tissue expression of the 45-kDa mitochondrial protein was variable: kidney medulla greater than heart greater than kidney cortex much greater than liver. We conclude that a 45-kDa protein with immunological cross-reactivity to the erythrocyte band 3 membrane domain is expressed in mitochondria in a highly cell-specific fashion and speculate that the protein may play a role in mitochondrial anion transport.     

Ca2+-ATPase of the sarcoplasmic reticulum shares a common domain with a membrane glycoprotein associated with the cytoskeleton of microvilli.

On the basis of structural observations, it has been proposed that cytoskeletal organization of the intestinal microvilli could be related to striated muscle structure. We have prepared antibodies against an amphipathic membrane glycoprotein (140 kilodaltons) associated with microvillar cytoskeleton and investigated its occurrence in striated muscle. Frozen sections of striated muscle were prepared according to the technique of Tokuyasu and visualized by indirect immunofluorescence with antibodies to the 140-kilodalton protein. In longitudinal sections the labeling was concentrated mainly in the area of the I band. In cross sections a honeycomb pattern was observed, suggesting that the recognized antigen was probably associated with the periphery of the myofibrils. Ultrathin frozen sections prepared for electron microscopy revealed that this antigen is closely associated with the membrane of the sarcoplasmic reticulum. In muscle extracts, the antibodies to the intestinal microvillar 140-kilodalton protein recognized a protein of 100 kilodaltons that comigrates with the Ca2+-ATPase of the sarcoplasmic reticulum. They recognized a purified preparation of the Ca2+-ATPase and, more specifically, the trypsin-generated fragment A2, the NH2-terminal part of the molecule that is exposed on the cytoplasmic face of the sarcoplasmic reticulum. Although these two proteins, expressed in unrelated cells, have a different molecular size and are inserted in different types of membranes, they share a common structural domain responsible for their crossreactivity. We propose that this domain could also be responsible for a common function--namely, the bridging of actin filaments to membranes.     

Distinct desmocollin isoforms occur in the same desmosomes and show reciprocally graded distributions in bovine nasal epidermis.

The adhesive core of the desmosome is composed of cadherin-like glycoproteins of two families, desmocollins and desmogleins. Three isoforms of each are expressed in a tissue-specific and developmentally regulated pattern. In bovine nasal epidermis, the three desmocollin (Dsc) isoforms are expressed in overlapping domains; Dsc3 expression is strongest in the basal layer, while Dsc2 and Dsc1 are strongly expressed in the suprabasal layers. Herein we have investigated whether different isoforms are assembled into the same or distinct desmosomes by performing double immunogold labeling using isoform-specific antibodies directed against Dsc1 and Dsc3. The results show that individual desmosomes harbor both isoforms in regions where their expression territories overlap. Quantification showed that the ratio of the proteins in each desmosome altered gradually from basal to immediately suprabasal and upper suprabasal layers, labeling for Dsc1 increasing and Dsc3 decreasing. Thus desmosomes are constantly modified as cells move up the epidermis, with continuing turnover of the desmosomal glycoproteins. Statistical analysis of the quantitative data showed a possible relationship between the distributions of the two isoforms. This gradual change in desmosomal composition may constitute a vertical adhesive gradient within the epidermis, having important consequences for cell positioning and differentiation.     

Moesin: a member of the protein 4.1-talin-ezrin family of proteins.

Moesin (membrane-organizing extension spike protein, pronounced mó ez in) has previously been isolated from bovine uterus and characterized as a possible receptor protein for heparan sulfate. We now have cloned and sequenced its complete cDNA, which represents a single 4.2-kilobase mRNA encoding a protein of 577 amino acids. It contains no apparent signal peptide or transmembrane domain. In addition, the protein shows significant sequence identity (72%) to ezrin (cytovillin, p81), as well as similarity to protein 4.1 and talin. All of the latter proteins have been postulated to serve as structural links between the plasma membrane and the cytoskeleton. A similar role for moesin is implied by structure and domain predictions derived from the cDNA-deduced peptide sequence. Furthermore, our data indicate that moesin is identical to the 77-kDa band that copurifies with ezrin in its isolation from human placenta [Bretscher, A. (1989) J. Cell Biol. 108, 921-930].     

Connexin43 remodeling caused by inhibition of plakophilin-2 expression in cardiac cells

Desmosomes and gap junctions are distinct structural components of the cardiac intercalated disc. Here, we asked whether the presence of plakophilin (PKP)2, a component of the desmosome, is essential for the proper function and distribution of the gap junction protein connexin (Cx)43. We used RNA silencing technology to decrease the expression of PKP2 in cardiac cells (ventricular myocytes, as well as epicardium-derived cells) obtained from neonatal rat hearts. We evaluated the content, distribution, and function of Cx43 gap junctions. Our results show that loss of PKP2 expression led to a decrease in total Cx43 content, a significant redistribution of Cx43 to the intracellular space, and a decrease in dye coupling between cells. Separate experiments showed that Cx43 and PKP2 can coexist in the same macromolecular complex. Our results support the notion of a molecular crosstalk between desmosomal and gap junction proteins. The results are discussed in the context of arrhythmogenic right ventricular cardiomyopathy, an inherited disease involving mutations in desmosomal proteins, including PKP2.     

Arrhythmogenic right ventricular dysplasia, a cell adhesion cardiomyopathy: insights into disease pathogenesis from preliminary genotype--phenotype assessment

Arrhythmogenic right ventricular dysplasia/cardiomyopathy (ARVC) is a genetically determined heart muscle disorder presenting clinically with even lethal ventricular arrhythmias, particularly in the young and athletes. It is reported familial with recessive and most commonly dominant inheritance. Disease-causing genes are increasingly recognised among desmosomal proteins plakoglobin, desmoplakin, plakophilin2, and desmoglein2 displaying phenotypic heterogeneity. Mutations in the plakoglobin and desmoplakin genes have been identified to underlie recessive ARVC associated with woolly hair and palmoplantar keratoderma (Naxos disease), while mutations in plakophilin2, desmoglein2 as well as desmoplakin have been identified to underlie the dominant non-syndromic form. Preliminary genotype-phenotype assessment indicates that mutations affecting the outer dense plaque of desmosome (desmoglein2, plakoglobin, plakophilin2 and the N-terminal of desmoplakin) result in ARVC with the ordinary described phenotype. However, mutations at the inner dense plaque, particularly affecting the desmin-binding site of desmoplakin, may result in ARVC with predominantly left ventricular involvement and clinical overlapping with dilated cardiomyopathy. The interesting finding of abnormal distribution of plakoglobin, independently of the primarily affected protein, might suggest a common pathway for plakoglobin in ARVC pathogenesis.     

Monoclonal antibody analysis of keratin expression in the central nervous system

A monoclonal antibody directed against a 65-kDa brain protein demonstrates an epitope found in keratin from human epidermis. By indirect immunofluorescence, the antibody decorates intracytoplasmic filaments in a subclass of astrocytes and Purkinje cells of adult hamster brain. Double-label immunofluorescence study using antibody to glial fibrillary acidic protein and this antibody reveals the 65-kDa protein to be closely associated with glial filaments in astrocytes of fetal mouse brain cultures. Immunoblot analysis of purified human epidermal keratin and hamster brain homogenate confirms the reactivity of this antibody to epidermal keratin polypeptides. All the major epidermal keratins were recognized by this antibody. It did not bind to the remaining major intermediate filament proteins. These findings suggest that monoclonal antibody 34C9 recognizes a cytoskeletal structure connected with intermediate filaments. In addition, the monoclonal antibody demonstrates that epidermal keratins share an epitope not only among themselves but also with a "neural keratin."     

Identification of a 160-kDa polypeptide that binds to the tight junction protein ZO-1.

ZO-1 is a 210- to 220-kDa peripheral membrane protein associated with the cytoplasmic surface of the epithelial tight junction. Because ZO-1 may interact with other unidentified tight junction proteins, we have looked for other polypeptides that bind to ZO-1. A 160-kDa polypeptide was identified that coimmunoprecipitates with ZO-1 from detergent extracts of metabolically labeled Madin-Darby canine kidney (MDCK) cells. This polypeptide appears to be distinct from ZO-1, rather than a degradation product, by several criteria. It lacks ZO-1 epitopes recognized by both monoclonal antibodies and a polyclonal serum to ZO-1, since it is not detectable in immunoblots of either whole cell extracts or ZO-1 immunoprecipitates. Also, it exhibits a peptide map different from that of ZO-1 on one-dimensional "Cleveland gels." Moreover, because the kinetics of appearance of newly synthesized 160-kDa polypeptide in anti-ZO-1 immunoprecipitates is much slower than that of ZO-1, its presence in immunoprecipitates cannot be simply explained by degradation of ZO-1 during cell lysis. Like ZO-1, the 160-kDa polypeptide seems to be a cytoplasmic peripheral membrane protein. It cannot be labeled by two different cell surface labeling reagents. It can be extracted from the membrane by high salt concentration in the absence of detergents. As expected for a protein complex, the 160-kDa polypeptide and ZO-1 turn over with similar kinetics. We propose that the 160-kDa polypeptide is a component of the tight junction.     

Thyroid hormone-induced differential synthesis of water-insoluble proteins in epidermal cell cultures from the hind limb of Rana catesbeiana tadpoles in stages XII-XV and XVI-XIX.

Hind limb epidermal cell cultures from stage XII-XV and XVI-XIX tadpoles of the American bullfrog Rana catesbeiana were maintained for 36 and 120 hr in medium containing either fetal calf serum or thyroid hormone (3,3',5-triiodothyronine, T3; 3 x 10(-10) mol/ml). T3 induces the precocious synthesis (within the first 36 hr) of a 59-kDa keratin associated with epidermal stratification in cultures from stages XII-XV. In epidermal cell cultures from stages XVI-XIX, T3 produces an overall pattern of water-insoluble proteins, including keratins, which is strikingly similar to temporally differentiated cultures (120 hr). A 73-kDa protein is among the water-insoluble proteins precociously synthesized by 36-hr-old cultures from stages XVI-XIX treated with T3. This protein, which is not immunoprecipitated by antibodies raised against keratins, corresponds in Mr and pI to a mammalian differentiation-specific desmosomal plaque protein. Immunoprecipitation of keratins from 120-hr-old cultures shows that many of the water-insoluble proteins synthesized are, indeed, keratins. Further, quantitation, by laser densitometry, of immunoprecipitated keratins from 120-hr cultures demonstrates that greater amounts of keratins, particularly the 65 and 59 kDa which are associated with a differentiated epidermis, are present in stages XVI-XIX. This study indicates that epidermal cell cultures from stages XVI-XIX respond more quickly to the differentiating effects of T3.     

Purification and characterization of a bovine acetyl low density lipoprotein receptor.

The acetyl low density lipoprotein (LDL) receptor is expressed on macrophages and some endothelial cells and mediates macrophage-foam cell formation in culture. A 220-kDa acetyl LDL binding protein was partially purified from bovine liver membranes and was used to make a specific monoclonal antibody. The 220-kDa protein immunoprecipitated by this antibody retained binding activity, and the antibody was used to detect this protein in cells lining bovine liver sinusoids and on the surface of cultured bovine alveolar macrophages. In the human monocytic cell line THP-1, the expression of both acetyl LDL receptor activity and a 220-kDa acetyl LDL binding protein were dramatically induced in parallel after differentiation to a macrophage-like state induced by phorbol ester. The ligand specificity, tissue and cell-type specificity, and coinduction data indicated that this 220-kDa cell-surface binding protein is probably a receptor that mediates acetyl LDL endocytosis. The 220-kDa protein, which was purified 238,000-fold from bovine lung membranes to near homogeneity using monoclonal antibody affinity chromatography, is a trimer of 77-kDa subunits that contain asparagine-linked carbohydrate chains.     

Antibodies against the carboxyl-terminal 5-kDa peptide of the alpha subunit of transducin crossreact with the 40-kDa but not the 39-kDa guanine nucleotide binding protein from brain.

We tested 18 antisera showing reactivity against the alpha subunit of transducin, the guanine nucleotide binding protein from rod outer segment, for crossreactivity against the 40- and 39-kDa guanine nucleotide binding proteins purified from bovine brain. A single antiserum, CW6, showed crossreactivity, and this was predominantly against the 40-kDa protein. Immunoblots of the tryptic fragments of transducin alpha subunit with multiple antisera raised against that subunit showed that only CW6 recognizes a COOH-terminal 5-kDa peptide that includes the site of pertussis toxin ADP-ribosylation. Antibodies against the 5-kDa peptide, affinity-purified from CW6, specifically react with the 40-kDa brain protein on immunoblots. The results show that the 39- and 40-kDa guanine nucleotide binding proteins from brain differ immunochemically and that the COOH-terminal 5-kDa peptide of transducin alpha subunit is homologous to a region in the 40-kDa brain protein. We speculate that this homologous region may be in a domain that confers specificity for receptor interactions of guanine nucleotide binding proteins.     

Adaptive diversification within a large family of recently duplicated, placentally expressed genes

The pregnancy-associated glycoproteins (PAG) are putative peptide-binding proteins and products of a large family of genes whose expression is localized to the placental surface epithelium of artiodactyl species. We have tested the hypothesis that natural selection has favored diversification of these genes by examining patterns of nucleotide substitution in a sample of 28 closely related bovine, caprine, and ovine family members that are expressed only in trophoblast binucleate cells. Three observations were made. First, in codons encoding highly variable domains of the proteins, there was a greater accumulation of both synonymous and nonsynonymous mutations than in the more conserved regions of the genes. Second, in the variable regions, the mean number of nonsynonymous nucleotide substitutions per site was significantly greater than the mean number of synonymous substitutions per site. Third, nonsynonymous changes affecting amino acid charge occurred more frequently than expected under random substitution. This unusual pattern of nucleotide substitution implies that natural selection has acted to diversify these PAG molecules at the amino acid level, which in turn suggests that these molecules have undergone functional diversification. We estimate that the binucleate cell-expressed PAG originated 52 +/- 6 million years ago, soon after the divergence of the ruminant lineage. Thus, rapid functional diversification of PAG expressed in trophoblast binucleate cells seems to have been associated with the origin of this unique placental adaptation.     

Functional reconstitution of skeletal muscle Ca2+ channels: separation of regulatory and channel components.

Regulatory properties of a partially purified Ca2+ -channel preparation from isolated rabbit skeletal muscle triads were examined in proteoliposomes. These properties included (i) inhibition by phenylalkylamine antagonists, such as verapamil, (ii) inhibition by the GTP-binding protein Go in the presence of guanosine 5'-[gamma-thio]triphosphate, and (iii) regulation of phenylalkylamine inhibition as a result of phosphorylation by a polypeptide-dependent protein kinase (PK-P). By selective reconstitution of protein fractions obtained by wheat germ lectin and ion-exchange chromatography, a separation of Ca2+-channel activity (fraction C) from regulatory component(s) (fraction R) responsible for verapamil sensitivity was achieved. Reconstitution of fraction C alone yielded vesicles that exhibited channel-mediated 45Ca2+ uptake that could be directly inhibited by coreconstitution of Go in the presence of guanosine 5'-[gamma-thio]triphosphate. However, the 45Ca2+ uptake obtained with fraction C was not inhibited by verapamil. Coreconstitution of fractions C and R yielded vesicles in which the sensitivity of 45Ca2+ uptake to verapamil was restored. The verapamil sensitivity of this preparation could be inhibited by PK-P. Fraction C, obtained by wheat germ agglutinin-Sepharose chromatography followed by DEAE-Sephacel chromatography, included a 180-kDa protein that was phosphorylated by cAMP-dependent protein kinase (PK-A) but not by PK-P and a 145-kDa protein (180 kDa under nonreducing conditions) that was not phosphorylated by either kinase. Fraction R contained proteins that did not adsorb to wheat germ lectin and included 165-kDa and 55-kDa proteins that were phosphorylated by PK-P but not by PK-A. These results suggest a complex model for Ca2+-channel regulation in skeletal muscle involving a number of distinct, separable protein components.