Adhesive but not lateral E-cadherin complexes require calcium and catenins for their formation.

We examined intercadherin interactions in epithelial A-431 cells producing endogenous E-cadherin and recombinant forms of E-cadherin tagged either by myc or by flag epitopes. Three distinct E-cadherin complexes were found. The first is a conventional E-cadherin-catenin complex consisting of one E-cadherin molecule linked either to beta-catenin/alpha-catenin or to plakoglobin/alpha-catenin dimers. The second is a lateral E-cadherin complex incorporating two E-cadherin- catenin conventional complexes combined in parallel fashion via dimerization of the NH2-terminal extracellular domain of E-cadherin. The third complex is likely to contain two E-cadherin-catenin conventional complexes derived from two opposing cells and arranged in an antiparallel fashion. Formation of the antiparallel but not lateral complex strictly depends on extracellular calcium and E-cadherin binding to catenins. Double amino acid substitution Trp156Ala/Val157Gly within the extracellular NH2-terminal E-cadherin domain completely abolished both lateral and antiparallel inter-E-cadherin association. These data support an idea that the antiparallel complex has the adhesion function. Furthermore, they allow us to suggest that antiparallel complexes derive from lateral dimers and this complex process requires catenins and calcium ions.

Molecular organization of the desmoglein-plakoglobin complex.

Different epithelial intercellular junctions contain distinct complexes incorporating plakoglobin. In adherens junctions, plakoglobin interacts with two molecules, the transmembrane adhesion protein of the cadherin family (e.g. E-cadherin) and alpha-catenin. The latter is thought to anchor the cadherin-plakoglobin complex to the cortical actin cytoskeleton. In desmosomes, plakoglobin forms a complex with desmosomal cadherins, either desmoglein (Dsg) or desmocollin (Dsc), but not with alpha-catenin. To further understand the structure and assembly of the plakoglobin-cadherin complexes we analyzed amino acid residues involved in plakoglobin-Dsg interactions using alanine scanning mutagenesis. Previously, we have shown that plakoglobin interacts with a 72 amino acid-long cytoplasmic domain (C-domain) that is conserved among desmosomal and classic cadherins. In this paper, we show that a row of the large hydrophobic residues located at the C-terminal portion of the Dsg C-domain is indispensable for interaction with plakoglobin. To study a reciprocal site we expressed plakoglobin (MPg) or its mutants tagged by 6 myc epitope in epithelial A-431 cells. Using sucrose gradient centrifugation and subsequent co-immunoprecipitation, MPg was found to be efficiently incorporated into the same type of complexes as endogenous plakoglobin. A major pool of Dsg-plakoglobin complexes sedimented at 8S and exhibited a 1:1 stoichiometry. Using alanine scanning mutagenesis and the co-immunoprecipitation assay we identified nine hydrophobic amino acids within the arm repeats 1-3 of plakoglobin, that are required for binding to Dsg and Dsc. Eight of these amino acids also participate in the interaction with alpha-catenin. No mutations were found to reduce the affinity of plakoglobin binding to E-cadherin. These data provide direct evidence that the same hydrophobic plakoglobin surface is essential for mutually exclusive interaction with distinct proteins such as alpha-catenin and desmosomal cadherins.

Direct Ca2+-dependent heterophilic interaction between desmosomal cadherins, desmoglein and desmocollin, contributes to cell-cell adhesion.

Human fibrosarcoma cells, HT-1080, feature extensive adherens junctions, lack mature desmosomes, and express a single known desmosomal protein, Desmoglein 2 (Dsg2). Transfection of these cells with bovine Desmocollin 1a (Dsc1a) caused dramatic changes in the subcellular distribution of endogenous Dsg2. Both cadherins clustered in the areas of the adherens junctions, whereas only a minor portion of Dsg2 was seen in these areas in the parental cells. Deletion mapping showed that intact extracellular cadherin-like repeats of Dsc1a (Arg1-Thr170) are required for the translocation of Dsg2. Deletion of the intracellular C-domain that mediates the interaction of Dsc1a with plakoglobin, or the CSI region that is involved in the binding to desmoplakin, had no effect. Coimmunoprecipitation experiments of cell lysates stably expressing Dsc1a with anti-Dsc or -Dsg antibodies demonstrate that the desmosomal cadherins, Dsg2 and Dsc1a, are involved in a direct Ca2+-dependent interaction. This conclusion was further supported by the results of solid phase binding experiments. These showed that the Dsc1a fragment containing cadherin-like repeats 1 and 2 binds directly to the extracellular portion of Dsg in a Ca2+-dependent manner. The contribution of the Dsg/ Dsc interaction to cell-cell adhesion was tested by coculturing HT-1080 cells expressing Dsc1a with HT-1080 cells lacking Dsc but expressing myc-tagged plakoglobin (MPg). In the latter cells, MPg and the endogenous Dsg form stable complexes. The observed specific coimmunoprecipitation of MPg by anti-Dsc antibodies in coculture indicates that an intercellular interaction between Dsc1 and Dsg is involved in cell-cell adhesion.

Cadherin binding sites of plakoglobin: localization, specificity and role in targeting to adhering junctions.

Plakoglobin directly interacts with cadherins and plays an essential role in the assembly of adherens junctions and desmosomes. Recently we have reported that multiple cadherin binding sites are localized along the arm repeat region of plakoglobin. To demonstrate functionally and specificity of these sites in vivo we constructed a set of chimeric proteins containing a plakoglobin sequence fused with the transmembrane vesicular protein synaptophysin. Plakoglobin fused upstream or downstream from synaptophysin (PgSy and SyPg, chimeras, respectively) is exposed on the cytoplasmic surface of synaptic-like vesicles and is able to associate with E-cadherin, and with two desmosomal cadherins, desmoglein and desmocollin. Moreover, plakoglobin targets these vesicles to cell-cell junctions. Insertion of synaptophysin within plakoglobin (PSyG chimeras) can interfere with cadherin binding of the resulting chimeric proteins, dependent on the position of the insertion. Insertion of synaptophysin in the first three arm repeats selectively inactivates plakoglobin binding to desmoglein and desmocollin. An insertion of synaptophysin within the next two repeats inactivates E-cadherin and desmocollin binding but not desmoglein binding. This localization of the desmoglein and E-cadherin binding sites was further confirmed by replacement of plakoglobin arm repeats with the corresponding sequence derived from the plakoglobin homologue, beta-catenin, and by deletion mutagenesis. Insertion of synaptophysin in most sites within arm repeats 6-13 does not change plakoglobin binding to cadherins. It does, however, strongly inhibit association of the resulting vesicles either with desmosomes and adherens junctions or with desmosomes only. Using in vitro binding assays we demonstrate that arm repeats 6-13 contain two cryptic cadherin binding sites that are masked in the intact protein. These observations suggest that the arm repeat region of plakoglobin is comprises two functionally distinct regions: the 1/5 region containing desmoglein and E-cadherin specific binding sites and the 6/13 region implicated in targeting of plakoglobin/cadherin complexes into junctional structures.

The binding of plakoglobin to desmosomal cadherins: patterns of binding sites and topogenic potential.

Plakoglobin is the only protein that occurs in the cytoplasmic plaques of all known adhering junctions and has been shown to be crucially involved in the formation and maintenance of desmosomes anchoring intermediate-sized filaments (IFs) by its interaction with the desmosomal cadherins, desmoglein (Dsg), and desmocollin (Dsc). This topogenic importance of plakoglobin is now directly shown in living cells as well as in binding assays in vitro. We show that, in transfected human A-431 carcinoma cells, a chimeric protein combining the vesicle-forming transmembrane glycoprotein synaptophysin, with the complete human plakoglobin sequence, is sorted to small vesicles many of which associate with desmosomal plaques and their attached IFs. Immunoprecipitation experiments have further revealed that the chimeric plakoglobin-containing transmembrane molecules of these vesicles are tightly bound to Dsg and Dsc but not to endogenous plakoglobin, thus demonstrating that the binding of plakoglobin to desmosomal cadherins does not require its soluble state and is strong enough to attach large structures such as vesicles to desmosomes. To identify the binding domains and the mechanisms involved in the interaction of plakoglobin with desmosomal cadherins, we have developed direct binding assays in vitro in which plakoglobin or parts thereof, produced by recombinant DNA technology in E. coli, are exposed to molecules containing the "C-domains" of several cadherins. These assays have shown that plakoglobin associates most tightly with the C-domain of Dsg, to a lesser degree with that of Dsc and only weakly with the C-domain of E-cadherin. Three separate segments of plakoglobin containing various numbers of the so-called arm repeats exhibit distinct binding to the desmosomal cadherins comparable in strength to that of the entire molecule. The binding pattern of plakoglobin segments in vitro is compared with that in vivo. Paradoxically, in vitro some internal plakoglobin fragments bind even better to the C-domain of E-cadherin than the entire molecule, indicating that elements exist in native plakoglobin that interfere with the interaction of this protein with its various cadherin partners.

Engagement of the CD4 receptor inhibits the interleukin-2-dependent proliferation of human T cells transformed by Herpesvirus saimiri.

Infection with Herpesvirus saimiri, a tumor virus of non-human primates, transformed human CD4+ T cell clones to permanent interleukin (IL)-2-dependent growth without need for restimulation with antigen and accessory cells. The IL-2-dependent proliferation of these cells was dramatically inhibited by soluble anti-CD4 whole antibodies, F(ab')2 and Fab fragments, and also by gp 120 of human immunodeficiency virus. The inhibition was not due to cell death and could be overcome by high concentrations of exogenous IL-2. Cell surface expression of CD4, and to a lesser degree the density of the IL-2 receptor alpha chain, were reduced upon anti-CD4 treatment. After long lasting (> 12 h) incubation with anti-CD4, abundance and activity of CD4-bound p56lck were diminished while the free fraction of p56lck remained unchanged. Since IL-2 binding to its receptor activated only the CD4-bound fraction of p56lck, the IL-2-induced p56lck activity was diminished after long-term CD4 ligation. Taken together, our results suggest a cross talk between CD4- and IL-2 receptor-mediated signaling via p56lck.

Immortalization of human T cell clones by Herpesvirus saimiri. Signal transduction analysis reveals functional CD3, CD4, and IL-2 receptors.

Investigation of human activated T cells has been complicated by the need for periodic restimulation with Ag/mitogen and accessory cells and by the limited life span of most human T cell clones. To overcome these problems, we have transformed established human T cell clones to permanent growth with Herpesvirus saimiri, a lymphoma-inducing virus of nonhuman primates. Three human CD4+ T cell clones were investigated in detail. They have been growing in the presence of exogenous IL-2 but without restimulation with mitogen or feeder cells for more than 11 mo with doubling times between 2 and 4 days. In contrast, their nontransformed parent clones needed to be restimulated with PHA and feeder cells every 14 to 21 days. To compare responses of H. saimiri-transformed clones with those of their parent clones, we stimulated the cells with IL-2 or with anti-CD3 and/or anti-CD4 mAb with and without cross-linking on the cell surface. Transformed and nontransformed T cell clones were strikingly similar in parameters of early signal transduction, namely, tyrosine phosphorylation and mobilization of calcium. Ligation of their TcR/CD3 complexes by mAb or by Ag in the presence of autologous accessory cells increased the proliferation and the secretion of IFN-gamma. Taken together, we have shown that human T cell clones immortalized with H. saimiri express functional CD3, CD4, and IL-2R. They constitute a simple, stable, reproducible and accessory cell-free model system for the investigation of signal transduction events in activated human T cells.