alpha-Actinin localization in the junctional complex of intestinal epithelial cells.

We have used antibody to chicken gizzard alpha-actinin to identify and localize this molecule in chicken intestinal epithelium. The antibody binds only to alpha-actinin when tested against a crude extract of chicken gizzard. Extracts of purified epithelial cells contain a molecule which has a subunit molecular weight of 100,000 on sodium dodecyl sulphate gels and which is able to inhibit the interaction of alpha-actinin antibody and 125I-labeled chicken gizzard alpha-actinin. By indirect immunofluorescence, alpha-actinin is localized in the apical portion of chicken intestinal epithelial cells. Ethanol-fixed cryostat sections of intestine taken through the apical portion of the epithelial cells and in a plane perpendicular to the long axis of the cells show that alpha-actinin is organized in a polygonal pattern which corresponds to the outlines of the polygonally packed epithelial cells. We interpret the data as indicating that alpha-actinin is a component of the tight junction (zonula occludens) and/or the belt desmosome (zonula adherens), both of which are membrane structures known to encircle the cell and to be confined to its apical portion.

Kinetics of desmosome assembly in Madin-Darby canine kidney epithelial cells: temporal and spatial regulation of desmoplakin organization and stabilization upon cell-cell contact. II. Morphological analysis.

Biochemical analysis of the kinetics of assembly of two cytoplasmic plaque proteins of the desmosome, desmoplakins I (250,000 Mr) and II (215,000 Mr), in Madin-Darby canine kidney (MDCK) epithelial cells, demonstrated that these proteins exist in a soluble and insoluble pool, as defined by their extract ability in a Triton X-100 high salt buffer (CSK buffer). Upon cell-cell contact, there is a rapid increase in the capacity of the insoluble pool at the expense of the soluble pool; subsequently, the insoluble pool is stabilized, while proteins remaining in the soluble pool continue to be degraded rapidly (Pasdar, M., and W. J. Nelson. 1988. J. Cell Biol. 106:677-685). In this paper, we have sought to determine the spatial distribution of the soluble and insoluble pools of desmoplakins I and II, and their organization in the absence and presence of cell-cell contact by using differential extraction procedures and indirect immunofluorescence microscopy. In the absence of cell-cell contact, two morphologically and spatially distinct patterns of staining of desmoplakins I and II were observed: a pattern of discrete spots in the cytoplasm and perinuclear region, which is insoluble in CSK buffer; and a pattern of diffuse perinuclear staining, which is soluble in CSK buffer, but which is preserved when cells are fixed in 100% methanol at -20 degrees C. Upon cell-cell contact, in the absence or presence of protein synthesis, the punctate staining pattern of desmoplakins I and II is cleared rapidly and efficiently from the cytoplasm to the plasma membrane in areas of cell-cell contact (less than 180 min). The distribution of the diffuse perinuclear staining pattern remains relatively unchanged and becomes the principal form of desmoplakins I and II in the cytoplasm 180 min after induction of cell-cell contact. Thereafter, the relative intensity of staining of the diffuse pattern gradually diminishes and is completely absent 2-3 d after induction of cell-cell contact. Significantly, double immunofluorescence shows that during desmosome assembly on the plasma membrane both staining patterns coincide with a subpopulation of cytokeratin intermediate filaments. Taken together with the preceding biochemical analysis, we suggest that the assembly of desmoplakins I and II in MDCK epithelial cells is regulated at three discrete stages during the formation of desmosomes.

Kinetics of desmosome assembly in Madin-Darby canine kidney epithelial cells: temporal and spatial regulation of desmoplakin organization and stabilization upon cell-cell contact. I. Biochemical analysis.

The functional interaction of cells in the formation of tissues requires the establishment and maintenance of cell-cell contact by the junctional complex. However, little is known biochemically about the mechanism(s) that regulates junctional complex assembly. To address this problem, we have initiated a study of the regulation of assembly of one component of the junctional complex, the desmosome, during induction of cell-cell contact in cultures of Madin-Darby canine kidney epithelial cells. Here we have analyzed two major protein components of the desmosomal plaque, desmoplakins I (Mr of 250,000) and II (Mr of 215,000). Analysis of protein levels of desmoplakins I and II by immunoprecipitation with an antiserum that reacts specifically with an epitope common to both proteins revealed that desmoplakins I and II are synthesized and accumulate at steady state in a ratio of 3-4:1 (in the absence or presence of cell-cell contact). The kinetics of desmoplakins I and II stabilization and assembly were analyzed after partitioning of newly synthesized proteins into a soluble and insoluble protein fraction by extraction of whole cells in a Triton X-100 high salt buffer. In the absence of cell-cell contact, both the soluble and insoluble pools of desmoplakins I and II are unstable and are degraded rapidly (t1/2 approximately 8 h). Upon induction of cell-cell contact, the capacity of the insoluble pool increases approximately three-fold as a proportion of the soluble pool of newly synthesized desmoplakins I and II is titrated into the insoluble pool. The insoluble pool becomes relatively stable (t1/2 greater than 72 h), whereas proteins remaining in the soluble pool (approximately 25-40% of the total) are degraded rapidly (t1/2 approximately 8 h). Furthermore, we show that desmoplakins I and II can be recruited from this unstable soluble pool of protein to the stable insoluble pool upon induction of cell-cell contact 4 h after synthesis; significantly, the stabilization of this population of newly synthesized desmoplakins I and II is blocked by the addition of cycloheximide at the time of cell-cell contact, indicating that the coordinate synthesis of another protein(s) is required for protein stabilization.

The complement of desmosomal plaque proteins in different cell types.

Desmosomal plaque proteins have been identified in immunoblotting and immunolocalization experiments on a wide range of cell types from several species, using a panel of monoclonal murine antibodies to desmoplakins I and II and a guinea pig antiserum to desmosomal band 5 protein. Specifically, we have taken advantage of the fact that certain antibodies react with both desmoplakins I and II, whereas others react only with desmoplakin I, indicating that desmoplakin I contains unique regions not present on the closely related desmoplakin II. While some of these antibodies recognize epitopes conserved between chick and man, others display a narrow species specificity. The results show that proteins whose size, charge, and biochemical behavior are very similar to those of desmoplakin I and band 5 protein of cow snout epidermis are present in all desmosomes examined. These include examples of simple and pseudostratified epithelia and myocardial tissue, in addition to those of stratified epithelia. In contrast, in immunoblotting experiments, we have detected desmoplakin II only among cells of stratified and pseudostratified epithelial tissues. This suggests that the desmosomal plaque structure varies in its complement of polypeptides in a cell-type specific manner. We conclude that the obligatory desmosomal plaque proteins, desmoplakin I and band 5 protein, are expressed in a coordinate fashion but independently from other differentiation programs of expression such as those specific for either epithelial or cardiac cells.

Desmocalmin: a calmodulin-binding high molecular weight protein isolated from desmosomes.

A unique high molecular weight protein (240,000 mol wt) has been purified from isolated desmosomes of bovine muzzle epidermis, using low-salt extraction at pH 9.5-10.5 and gel-filtration followed by calmodulin-affinity column chromatography. This protein was shown to bind to calmodulin in a Ca2+-dependent manner, so we called it desmocalmin here. Desmocalmin also bound to the reconstituted keratin filaments in vitro in the presence of Mg2+, but not to actin filaments. By use of the antibody raised against the purified desmocalmin, desmocalmin was shown by both immunoelectron and immunofluorescence microscopy to be localized at the desmosomal plaque just beneath the plasma membrane. Judging from its isoelectric point and antigenicity, desmocalmin was clearly distinct from desmoplakins I and II, which were identified in the desmosomal plaque by Mueller and Franke (1983, J. Mol. Biol., 163:647-671). In the low-angle, rotary-shadowing electron microscope, the desmocalmin molecules looked like flexible rods approximately 100-nm long consisting of two polypeptide chains lying side by side. The similar rodlike structures were clearly identified in the freeze-etch replica images of desmosomes. Taken together, these findings indicate that desmocalmin could function as a key protein responsible for the formation of desmosomes in a calmodulin-dependent manner (Trinkaus-Randall, V., and I.K. Gipson, 1984, J. Cell Biol., 98:1565-1571).

Structure and biochemical composition of desmosomes and tonofilaments isolated from calf muzzle epidermis.

Complexes of plasma membrane segments with desmosomes and attached tonofilaments were separated from the stratum spinosum cells of calf muzzle by means of moderately alkaline buffers of low ionic strength and mechanical homogenization. These structures were further fractionated by the use of various treatments including sonication, sucrose gradient centrifugation, and extraction with buffers containing high concentrations of salt, urea, citric acid, or detergents. Subfractions enriched in desmosome-tonofilament-complexes and tonofilament fragments were studied in detail. The desmosome structures such as the midline, the trilaminar membrane profile, and the desmosomal plaque appeared well preserved and were notably resistant to the various treatments employed. Fractions containing desmosome-tonofilament complexes were invariably dominated by the nonmembranous proteins of the tonofilaments which appeared as five major polypeptide bands (apparent molecular weights: 48,000; 51,000; 58,000; 60,000; 68,000) present in molar ratios of approx. 2:1:1:2:2. Four of these polypeptide bands showed electrophoretic mobilities similar to those of prekeratin polypeptides from bovine hoof. However, the largest polypeptide (68,000 mol wt) migrated significantly less in polyacrylamide gels than the largest component of the hoof prekeratin (approximately 63,000 mol wt). In addition, a series of minor bands, including carbohydrate-containing proteins, were identified and concluded to represent constituents of the desmosomal membrane. The analysis of protein-bound carbohydrates (total 270 microgram/mg phospholipid in desmosome-enriched subfractions) showed the presence of relatively high amounts of glucosamine, mannose, galactose, and sialic acids. These data as well as the lipid composition (e.g., high ratio of cholesterol to phospholipids, relatively high contents of sphingomyelin and gangliosides, and fatty acid pattern) indicate that the desmosomal membrane is complex in protein and lipid composition and has a typical plasma membrane character. The similarity of the desmosome-associated tonofilaments to prekeratin filaments and other forms of intermediate-sized filaments is discussed.

Isolation of the intercellular glycoproteins of desmosomes.

To characterize the desmosome components that mediate intercellular adhesion and cytoskeletal-plasma membrane attachment, we prepared whole desmosomes and isolated desmosomal intercellular regions (desmosomal "cores") from the living cell layers of bovine muzzle epidermis. The tissue was disrupted in a nonionic detergent at low pH, sonicated, and the insoluble residue fractionated by differential centrifugation and metrizamide gradient centrifugation. Transmission electron microscopic analyses reveal that a fraction obtained after differential centrifugation is greatly enriched in whole desmosomes that possess intracellular plaques. Metrizamide gradient centrifugation removes most of the plaque material, leaving the intercellular components and the adjoining plasma membranes. Sodium dodecyl sulfate polyacrylamide gel electrophoresis coupled with methods that reveal carbohydrate-containing moieties on gels demonstrate that certain proteins present in whole desmosomes are glycosylated. These glycoproteins are specifically and greatly enriched in the desmosome cores of which they are the principal protein constituents, and thus may function as the intercellular adhesive of the desmosome.

Chemical characterization of isolated epidermal desmosomes.

Desmosomes, isolated from cow nose epidermis by a method utilizing citrate buffer pH 2.6 and density gradient centrifugation, have been analyzed and found to contain approximately 76% protein, 17% carbohydrate, and 10% lipid. Nonpolar amino acids predominate in desmosomal protein, representing 456 residues per 1,000. The sialic acid content is 5 nM/mg of protein. The lipid fraction is composed of approximately 40% cholesterol and 60% phospholipids. Desmosomes are completely solubilized by incubation with 2% sodium dodecyl sulphate and 1% beta-mercaptoethanol. Gel electrophoresis of the denatured desmosomal proteins reveals 24 bands, with mobilities corresponding to a molecular weight range of 15,000-230,000 daltons. Seven of these are considered to be major bands, together constituting 81% of the desmosomal protein. Bands 1 and 2, of molecular weights 230,000 and 210,000 daltons, together comprise 28% by weight of the desmosome. It is suggested that these protein chains are located in the desmosomal plaque. Bands 3 and 4 are PAS-positive, constitute 23% of the desmosomal protein, and have apparent molecular weights of 140,000 and 120,000 daltons, respectively. At least part of this material must originate from the carbohydrate-containing layer which is demonstrated, by histochemistry, to be present in the desmosomal interspace. The possible nature and origin of the remaining major bands, of molecular weights 90,000, 75,000, and 60,000 daltons, are discussed.

Identification of a basic protein of Mr 75,000 as an accessory desmosomal plaque protein in stratified and complex epithelia.

Desmosomes are intercellular adhering junctions characterized by a special structure and certain obligatory constituent proteins such as the cytoplasmic protein, desmoglein. Desmosomal fractions from bovine muzzle epidermis contain, in addition, a major polypeptide of Mr approximately 75,000 ("band 6 protein") which differs from all other desmosomal proteins so far identified by its positive charge (isoelectric at pH approximately 8.5 in the denatured state) and its avidity to bind certain type I cytokeratins under stringent conditions. We purified this protein from bovine muzzle epidermis and raised antibodies to it. Using affinity-purified antibodies, we identified a protein of identical SDS-PAGE mobility and isoelectric pH in all epithelia of higher complexity, including representatives of stratified, complex (pseudostratified) and transitional epithelia as well as benign and malignant human tumors derived from such epithelia. Immunolocalization studies revealed the location of this protein along cell boundaries in stratified and complex epithelia, often resolved into punctate arrays. In some epithelia it seemed to be restricted to certain cell types and layers; in rat cornea, for example, it was only detected in upper strata. Electron microscopic immunolocalization showed that this protein is a component of the desmosomal plaque. However, it was not found in the desmosomes of all simple epithelia examined, in the tumors and cultured cells derived thereof, in myocardiac and Purkinje fiber cells, in arachnoideal cells and meningiomas, and in dendritic reticulum cells of lymphoid tissue, i.e., all cells containing typical desmosomes. The protein was also absent in all nondesmosomal adhering junctions. From these results we conclude that this basic protein is not an obligatory desmosomal plaque constituent but an accessory component specific to the desmosomes of certain kinds of epithelial cells with stratified tissue architecture. This suggests that the Mr 75,000 basic protein does not serve general desmosomal functions but rather cell type-specific ones and that the composition of the desmosomal plaque can be different in different cell types. The possible diagnostic value of this protein as a marker in cell typing is discussed.

Organization of desmosomal plaque proteins in cells growing at low calcium concentrations.

Desmosomes are not formed in epithelial cell cultures growing in media with low (less than or equal to 0.1 mM) concentrations of Ca2+ (LCM) but appear rapidly upon shift to media of normal calcium concentrations (NCM). Previous authors using immunolocalization of desmoplakin, a marker protein for the desmosomal plaque, in LCM-grown cells have interpreted positively stained, dense, cytoplasmic aggregates on intermediate filaments (IF) bundles as preformed plaque units which upon NCM shift would move to the plasma membrane and contribute to desmosome formation. Studying various cell cultures, including primary mouse keratinocytes and human A-431 cells, we show that most, probably all, desmoplakin-positive aggregates in LCM-grown cells are associated with membranous structures, mostly vesicles, and also contain other desmosomal markers, including desmoglein, a transmembrane glycoprotein. We interpret such vesicles as residual desmosome-derived domains endocytosed upon cell dissociation. Only keratinocytes grown for long times (2-4 wk) in LCM are practically free from such vesicles. In addition, we demonstrate that certain cells such as A-431 cells, when passaged in LCM and in the absence of stable junctions, are able to continually assemble "half-desmosomes" on the plasma membrane which in turn can be endocytosed as plaque-bearing vesicles. We also show that in LCM the synthesis of several desmosomal proteins (desmoplakins I and II, plakoglobin, desmoglein, "band 6 protein") continues and that most of the plaque protein, desmoplakin, is diffusely spread over the cytoplasm, apparently in a soluble monodisperse form of approximately 9S. From our results we propose that the plaque proteins occur in small, discrete, diffusible entities in the cytoplasm, in concentrations that are relatively high in LCM and low in NCM, from which they assemble directly, i.e., without intermediate precursor aggregates on IFs in the cytoplasm, on certain plasma membrane domains in a Ca2+ dependent process.

Selective extraction of desmosomal proteins by low ionic strength media.

Desmosomes, isolated using an acidic buffer, have been subjected to extraction at low ionic strength. This treatment removes more than 35% of their protein in the form of two polypeptide chains of molecular weight 210 000 and 230 000, but the desmosomes show only subtle changes in ultrastructure. It is concluded that the use of low ionic strength media for desmosome isolation yields residual structures specifically depleted in high molecular weight proteins.

Purification of desmoglein II: a method for the preparation and fractionation of desmosomal components.

We have developed rapid and efficient methods for the isolation of desmosomes and the fractionation of their components. These methods involve the use of 6 M guanidine HCl to isolate the desmosomes from bovine epidermis, followed by hydroxyapatite column chromatography in the presence of SDS to fractionate the desmosomal components. All of the desmoplakins and desmogleins were purified at least partially by these procedures, and desmoglein II was purified to apparent homogeneity. We expect these procedures to facilitate a detailed biochemical analysis of the molecular components of desmosomes. In addition, these methods may be applicable to the purification of other plasma membrane domains involved in cell adhesion.

Biochemical and immunological characterization of desmoplakins I and II, the major polypeptides of the desmosomal plaque.

Epithelial cells contain complexes of cytokeratin filaments (tonofilaments) with specific domains of the plasma membrane that appear as symmetric junctions, i.e. desmosomes, or as asymmetric hemi-desmosomes. These regions of filament-membrane-attachment are characterized by 14 to 20 nm thick dense plaques (desmosomal plaque). In isolated desmosome-tonofilament complexes or other desmosomal fractions from various stratified squamous epithelia (e.g. bovine muzzle epidermis and tongue mucosa) desmosomal plaque structures are recognized and show a relatively high resistance to various extraction buffers and detergents. Such fractions enriched in desmosomal plaque material are also enriched in two prominent polypeptide bands of apparent molecular weights 250,000 (desmoplakin I) and 215,000 (desmoplakin II) which appear, on two-dimensional gel electrophoresis, as two distinct polypeptides isoelectric near neutral pH. These two polypeptides are present in almost equimolar amounts and each of them appears as a series of isoelectric variants, including some labeled by [32P]phosphate in tissue slices. The two desmoplakin polypeptides are closely related as shown by tryptic peptide map analysis and are different from keratin-like proteins and other major polypeptides of desmosome-rich fractions. Guinea pig antibodies raised against desmoplakins and specific for these proteins do not cross-react with other desmosomal antigen(s) or constituents of other types of junctions. Using desmoplakin antibodies we have identified desmoplakins as the major constituents of the desmosomal plaques present in epithelial and myocardiac cells of diverse species. The significance of this group of cell type-specific membrane-associated cytoskeletal proteins and their possible cytoskeletal functions are discussed.

Biochemical characterization of desmosomal proteins isolated from bovine muzzle epidermis: amino acid and carbohydrate composition.

The seven major desmosomal polypeptides from isolated bovine muzzle desmosomes ranging from Mr 75 000 to 250 000 were separated by gel electrophoresis, isolated and characterized with respect to their amino acid composition and sugar content. The two largest polypeptides (bands 1 and 2), i.e. desmoplakins I and II, are similar in their amino acid composition, confirming our previous immunological and biochemical data, and display a relatively high glycine content. In contrast, the other two cytoplasmic components also believed to be associated with the desmosomal plaque, i.e. polypeptides of bands 5 (Mr 83 000) and 6 (Mr 75 000), differ significantly in their amino acid composition from the desmoplakins and from each other. All four candidate polypeptides for plaque association, i.e. bands 1, 2, 5, and 6, show no significant glycosylation. The glycoproteins 4a and 4b (Mr 115 000 and 130 000) are similar in their amino acid composition, peptide analysis and immunological reactivity. Both are relatively rich in mannose and galactose but also contain sialic acid. Our determinations also indicate that the two polypeptides differ significantly in their N-acetylglucosamine and mannose content. Most, if not all, of the sugar residues are associated with a water-soluble fragment of Mr 15 500 obtained after limited digestion with V8 protease. The glycopolypeptides obtained in band 3 (Mr 164 000-175 000) are distinct from the glycopolypeptides 4a and 4b in amino acid composition, sugar content, isoelectric pH values, certain antigenic determinants and in their pattern of cleavage products obtained by treatment with proteases or cyanogen bromide. The results identify polypeptides of bands 3, 4a and 4b as glycosylated with characteristic sugar compositions. It is suggested that the major glycoproteins (bands 3, 4a, 4b) of the desmosome are integral membrane components arranged in a special way conferring resistance to detergent treatment. The possible roles of these glycoproteins in cell recognition and in adhesive functions of the desmosome are discussed.

A constitutive transmembrane glycoprotein of Mr 165,000 (desmoglein) in epidermal and non-epidermal desmosomes. I. Biochemical identification of the polypeptide.

Two murine monoclonal antibodies (DG 3.4 and DG 3.10) raised against a major glycoprotein ("band 3 component") from desmosomes of bovine muzzle epidermis were used in immunoblot experiments following SDS-polyacrylamide gel electrophoresis or two-dimensional gel electrophoresis to identify this or immunologically related proteins in other bovine tissues and cultured cell lines. In all desmosome-bearing cells, i.e. cells also expressing desmoplakins, including representative of stratified, transitional and simple epithelia as well as myocardium, only a single distinct polypeptide of identical Mr value (165,000) and electrical charge was detected. These findings, together with the immunolocalization results reported in the companion paper indicate that this glycoprotein (desmoglein) is a general constituent protein of desmosomes, providing a case of an integral membrane protein co-expressed with non-membranous desmosomal proteins such as the plaque component, desmoplakin I. Our results further suggest that, contrary to previous suggestions, desmoglein is very similar, if not identical in different cells of the same species and does not display significant cell type diversity.

Detection of pemphigus vulgaris and pemphigus foliaceus antigens by immunoblot analysis using different antigen sources.

In an immunoblot analysis with human epidermal extract as a source of antigens, all (28/28) pemphigus vulgaris (Pv) sera showed a specific reactivity with a 130-kD protein. Several, but not all, Pv sera reacted with similar antigens in both a bovine muzzle desmosome preparation and extract of cultured human squamous carcinoma cells. On the other hand, some pemphigus foliaceus (Pf) sera exhibited reactivity with a 150-kD protein, which is most likely desmoglein I, in both the human epidermal extract and the bovine desmosome preparation, but no Pf serum reacted with this antigen in the squamous carcinoma cell extract. Furthermore, 4/16 Pv sera also reacted with a 150-kD protein in the desmosome preparation, which seemed to be the same as Pf antigen. These results show a relationship between antigens of both Pf and Pv and desmosomes, as well as heterogeneities of both Pv and Pf antigens in terms of antigenic molecules or epitopes. Furthermore, this study presents the possibility that immunoblot analysis can be routinely used for differentiation of Pv and Pf antibodies.

Desmosomes, filaments, and keratohyaline granules: their role in the stabilization and keratinization of the epidermis.

Components of desmosomes, filaments, and keratohyaline granules were studied by electron microscope and biochemical methods to clarify their role in the stabilization and keratinization of the epidermis. Isolated desmosomes are composed of 76% protein, 17% carbohydrate, and 10% lipid. The bulk of protein consists of a "spectrin"-like fibrous protein, presumably present in the plaque, and of glycoproteins in the desmosomal interspace. The main component of filaments, prekeratin, is a low-sulfur alpha-protein composed of a pair of three-chain subunits with non-alpha-helical segments separated by 200 A-long alpha-helical regions. The major component of isolated keratohyaline granules, the amorphous particulate material, is formed by a high-sulfur protein with a single-type of polypeptide chain. Polypeptide chains comparable to those found in prekeratin and keratohyaline granules were recovered from extracts of horny cells. Within the living part of the epidermis, filaments hypothetically form a cytoskeletal system which is anchored to desmosomes by a filamentous plaque protein. Glycoproteins are involved in the formation of strong junctions between the cells which enable the living part of the epidermis to respond as a whole to mechanical stress. The stratum corneum is stabilized by a similar system in a consolidated state which is less extensible. Horny cells are enveloped by a thickened membrane and the interfilamentous spaces are filled with various proteins including the sulfur-rich amorphous protein found in keratohyaline granules.

Differentiation of metastatic breast carcinoma from Stewart-Treves angiosarcoma. Use of anti-keratin and anti-desmosome monoclonal antibodies and factor VIII-related antibodies.

A chronic brawny edema developed in the shoulder and arm ipsilateral to the site of a previous mastectomy in a 68-year-old woman. Bluish nodules and telangiectasia admixed with more superficial papules and plaques developed subsequently. Histologically, many of these lesions showed angiocentric clusters of large hyperchromatic tumor cells, often with lumina in the center. It was difficult to differentiate two possibilities, ie, postmastectomy angiosarcoma in lymphedema (Stewart-Treves syndrome) and nodulotelangiectatic metastasis of the original breast carcinoma. Monoclonal anti-keratin antibody and anti-desmosome antibody identified keratin and desmosomes in the tumor cells, whereas staining with factor VIII-related antigen yielded negative results. Electron microscopy revealed, in addition to keratin filaments and desmosomes, typical secretory cells and lumen formation. A combined use of specific monoclonal and polyclonal antibodies is helpful in the determination of tumor origins.

Immunoblot analyses of Brazilian pemphigus foliaceus antigen using different antigen sources.

We investigated the Brazilian pemphigus foliaceus (BPf) antigen applying the immunoblotting method to two different antigen sources using 27 patients' sera. Twelve BPf sera reacted specifically with a 150 kD protein in extract of dispase separated human epidermis, while 18 sera yielded a similar protein band in bovine muzzle desmosomal preparation. The diversity of staining intensities between the two samples suggested the heterogeneity of BPf antigens in terms of epitopes. Japanese sporadic pemphigus foliaceus (Pf) sera showed similar results but Japanese pemphigus vulgaris (Pv) sera recognized different antigens of 130 kD or 135 kD, suggesting that BPf is similar to Japanese Pf but is distinct from Pv in respect to the antigenic substance. Furthermore, the present study showed that immunoblot analysis using different antigen sources should be a valuable tool to determine clinical types of pemphigus.