The extraction and characterization of bovine epidermal alpha-keratin.

1. The alpha-fibrous protein (alpha-keratin) component of bovine epidermis has been extracted and characterized. 2. Prekeratin, a multichain unit of the epidermal tonofilaments, was shown to consist of six different polypeptide chains on polyacrylamide-gel systems containing sodium dodecyl sulphate or sodium decyl sulphate with discontinuous gel buffers, but only three chains were seen when a gel system containing sodium dodecyl sulphate with a continuous gel buffer was used. 3. Extraction of the 'keratinized' stratum corneum and the living part of the epidermis with urea buffers at pH 7.6 or 9.0 released 60% of the total dry weight of the tissues in the form of alpha-helical polypeptides. 4. The numbers, relative amounts and properties of the extracted polypeptides were the same as the subunits of prekeratin and thus are derived from the tonofilaments in situ. 5. The subunits of prekeratin and the polypeptides extracted from the living cell layers contained an average of six cysteine residues, but those from the stratum corneum contained an average of three intrachain disulphide bonds. 6. The polypeptide chains aggregated through non-covalent interactions in vitro into filaments that were similar to the tonofilaments. 7. Since the polypeptides could be released from the stratum corneum without breaking covalent bonds, it is concluded that such bonds do not cross-link the tonofilaments and non-fibrous keratohyalin. It is suggested that the tonofilaments and keratohyalin of bovine epidermis are associated by secondary bonding forces.     

Prekeratin expression of simple epithelia in the cells of long-term cultured epithelial lines of the rat liver

Prekeratin of simple epithelia with m.m. 55 kD (PK55) was found in all the studied tumorigenic and non-tumorigenic liver epithelial cell lines of the IAR series by means of indirect immunofluorescent methods in combination with corresponding monoclonal antibodies. The most prominent expression was observed in some tumorigenic cell lines. Expression of PK55 was reversible--the cells lost prekeratin in low density cultures. It has been found that the synthesis of prekeratins with m.m. 49 kD (PK49) and 40 kD (PK40) began on reaching higher cell densities than those needed for PK55 synthesis in IAR6-7 line. The PK40 appeared in cells spread on the substratum, while the PK49 was observed in upper poorly spread cells of ridges in multilayered dense cultures. Thus, the synthesis of prekeratins is not constitutive at least for some types of epithelial cells. Specific cell-to-cell interactions are presumably needed for each particular prekeratin synthesis induction.     

Characterization of cells of amniotic fluids by immunological identification of intermediate-sized filaments: Presence of cells of different tissue origin

Summary Antibodies against intermediate-sized filaments, of the prekeratin or vimentin type, were used to investigate the presence of these filaments by indirect immunofluorescence microscopy in cultured and non-cultured amniotic fluid cells, in frozen sections of the placenta and in isolated cells of the amniotic epithelium. Two major classes of cells can be cultured from amniotic fluids, namely cells of epithelial origin containing filaments of the prekeratin type and cells of different origin which contain filaments of the vimentin type but are negative when tested with antibodies to epidermal prekeratin. The presence of prekeratin type filaments correlates with the morphology of colonies of amniotic fluid cell cultures in vitro as classified by Hoehn et al. (1974). Cells of E-type colonies are shown to be of epithelial origin. In contrast our data indicate a different origin of almost all cells of F-type colonies and of the large majority of cells of AF-type colonies. Cells of epithelial origin and positively stained with antibodies to epidermal prekeratin are occasionally scattered in F-type colonies and in variable percentages (up to 30%) in AF-type colonies. Surprisingly, cryostat sections of the amniotic epithelium and isolated groups of amniotic cells showed positive reactions with both antibodies to vimentin and prekeratin. The possibility that amniotic cells may be different from other epithelial cells in that they contain both types of filaments simultaneously already in situ is presently under investigation.Part of this work is included in the doctoral thesis of Irmgard Treiss to be submitted to the Faculty of Medicine of the University of Heidelberg     

Expression of vimentin and prekeratins in solid and ascites variants of Zajdela hepatoma

Using indirect immunofluorescence with monoclonal antibodies against prekeratins and vimentin, the contents and intracellular distribution of these proteins have been investigated in Seidel hepatoma cells. In ascitic tumour, cells were organized in multicellular unilayer spheric or ellipsoid complexes with an inner cavity. Such complexes have been found to express intracellular vimentin and chaotically distributed prekeratin filaments. One of the constituents of the normal epithelial basal membrane--laminin was not found on the basal surface of cellular complexes but was localized in their inner lumens only. The expression of vimentin and prekeratin filaments was preserved in metastatic tumour cells found in paratracheal lymph nodes and in the majority of solid tumour cells induced by subcutaneous cell injections. In both cases tumour cells did not form regular morphological structures and laminin was visualized as extracellular granules and short fibrils. In several cases subcutaneous injections of Seidel hepatoma cells gave rise to adenocarcinomas. Prekeratin filaments in these tumours were localized predominantly under cellular membranes. Laminin "membranes" outlined the basal surface of adenomatous structures. Vimentin in these cellular structures was completely absent. It is suggested that vimentin expression in Seidel hepatoma cells was suppressed with morphological normalization of tumour structures manifested in the regular distribution of intercellular contacts and in basal membrane reconstitution.     

The human thymic microenvironment. Phenotypic characterization of Hassall's bodies with the use of monoclonal antibodies

The human thymic microenvironment is important in promotion of T cell maturation, particularly during early stages of thymic ontogeny. Hassall's bodies (HB) are epithelial swirls in the human thymic medulla that are thought to be derived from endocrine medullary thymic epithelium. To study the ontogeny and function of various components of the human thymic microenvironment, we have produced four monoclonal antibodies (TE-8, TE-15, TE-16, and TE-19) that selectively reacted in thymus with HB. Antibodies TE-8 and TE-16 reacted with the cells forming the outer rim of the HB swirl. Antibody TE-19 reacted with the entire cellular portion of HB and with epithelial cells immediately surrounding HB. Granular foci in the cellular swirls of greater than 90% of HB reacted with antibody TE-15. During thymic ontogeny, the antigens defined by antibodies TE-8, TE-15, TE-16, and TE-19 were first detected in fetal thymus on HB beginning at 16 wk gestation, the age when HB morphologically appear in the thymus. Aberrant expression of the antigens corresponding to antibodies TE-8, TE-15, TE-16, and TE-19 was observed on thymic tissue from individuals with severe cellular immunodeficiency disease. In human skin, antibodies TE-8, TE-16, and TE-19 reacted with the stratum granulosum; antibody TE-15 reacted with the stratum corneum. Thus, with the use of antibodies TE-8, TE-15, TE-16, and TE-19, we have identified HB as antigenically distinct regions of endocrine thymic epithelium. Furthermore, we have shown that these anti-HB reagents also selectively react with epidermal keratinocytes in the terminal stages of keratinocyte maturation.     

Identification and Characterization of Epithelial Cells in Mammalian Tissues by Immunofluorescence Microscopy Using Antibodies to Prekeratin

The occurrence of intermediate-sized filaments containing prekeratin-like proteins ('cytokeratins') has been examined in various organs of rat and cow by electron microscopy and by immunofluorescence microscopy on frozen sections using antibodies to defined constitutive proteins of various types of intermediate-sized filaments (prekeratin, vimentin, desmin). Positive cytokeratin reaction and tonofilament-like structures have been observed in the following epithelia: epidermis; ductal, secretory, and myoepithelial cells of sweat glands; mammary gland duct; myoepithelial cells of lactating mammary gland; milk secreting cells of cow; ductal, secretory, and myoepithelial cells of various salivary glands; tongue mucosa; bile duct; excretory duct of pancreas; intestinal mucosa; urothelium; trachea; bronchi; thymus reticulum, including Hassall corpuscles; mesothelium; uterus; and ciliated cells of oviduct. None of the epithelial cells mentioned has shown significant reaction with antibodies to vimentin, the major component of the type of intermediate-sized filaments predominant in mesenchymal cells. The widespread, if not general occurrence of cytokeratin filaments in epithelial cells is emphasized, and it is proposed to use this specific structure as a criterion for true epithelial character or origin.     

Biochemical and immunological identification of cytokeratin proteins present in hepatocytes of mammalian liver tissue

Hepatocytes of mammalian liver are known to contain intermediate-sized filaments of tonofilament morphology. Unlike many other epithelial cells, including cultured hepatocytes and hepatoma cells, hepatocytes present in normal liver tissue have been reported not to react, in significant intensity, with various preparations of antibodies to human and bovine epidermal prekeratin [2,6]. We have therefore examined, by biochemical and immunological methods, the cytoskeletal composition of hepatocytes grown in the body.Cytoskeletal preparations from hepatocytes of mouse and rat liver tissue resistant to high salt buffer and Triton X-100 are enriched in tangles of intermediate filaments and contain, besides some residual microfilamentous actin, a characteristic set of polypeptides. One- and two-dimensional gel electrophoresis reveals the presence of two major cytokeratin components, which appear as ‘pairs’ of isoelectric variants (component A, M_r 55 000, apparent pI values, 6.40 and 6.45; component D, M_r 49000, apparent pI values 5.43 and 5.38), and five minor components (M_r range from 41000 to 53 000), most of them also as ‘pairs’ of polypeptides slightly different in isoelectric pH value. These polypeptide patterns are very similar in mouse and rat liver although some minor but significant differences have been noted between the two species. The polypeptide patterns of liver cytoskeletons are also similar to—but clearly not identical with—the cytoskeletal protein patterns observed in other epithelial tissues and cells, including various lines of cultured rat hepatocytes and hepatoma cells.Guinea pig antibodies raised against individual cytokeratin proteins of mouse liver and against certain prekeratin polypeptides present in desmosome-attached tonofilaments of bovine muzzle are described which differ from previously described prekeratin antibodies. These prekeratin antibodies not only react with filament bundles of the prekeratin type present in many cultured epithelial cells (e.g. murine HEL, human HeLa, rat kangaroo PtK2) and various epithelial tissues, but also allow the detection of the cytokeratin components present in parenchymal cells of liver and pancreas of various species, man included. Immunofluorescence microscopy on frozen sections of liver using these antibodies reveals a novel structure, i.e. a three-dimensional filament meshwork extending throughout the whole cytoplasm of the hepatocyte, with higher intensity of staining in pericanalicular regions.The results show that parenchymal cells of normal liver and pancreas contain filaments of the cytokeratin type that are related to but not identical with epidermal prekeratin. The hepatocyte filaments appear to be different from prekeratin-type filaments present in epidermis and several other epithelial cells, both in some antigenic determinants exposed and in polypeptide composition. Our findings support the concept of the existence of a family of intermediate filament proteins, cytokeratins, containing many different polypeptides that are expressed in different epithelial cells in certain characteristic subsets in a cell type-specific mode.     

The distribution of keratin type intermediate filaments in human breast cancer. An immunohistological study

Antibodies to different intermediate filament proteins can be used to distinguish cells of epithelial, mesenchymal, muscle, glial and neuronal origin. Antibodies to prekeratin which characterize cells of epithelial origin, and antibodies to vimentin which recognize cells of mesenchymal origin have been used to study twenty cases of breast carcinoma (sixteen infiltrating ductal carcinomas and four infiltrating intraductal carcinomas), two cases of cystic breast disease, two fibroadenomas and one case of benign cystosarcoma phylloides. The prekeratin and vimentin were detected using specific antibodies to these proteins by immunofluorescence microscopy using alcohol fixed paraffin-embedded tissues. In eighteen out of the twenty carcinomas the tumor cells were strongly and specifically stained by antibodies to prekeratin. DIfferent tumors gave different patterns of prekeratin staining. In contrast, when the same specimens were tested with the vimentin antibody, the tumor cells were unstained, and instead only the usual strong staining to fibroblasts and blood vessels in the stroma was observed. In cystic breast disease, fibroadenomas, and benign cystosarcoma phylloides, cells of epithelial origin were strongly stained by the prekeratin but not by the vimentin antibody.     

Isolation, characterization and comparison of mammalian epidermal prekeratins

1. The lower living layers of mammalian epidermis contain a cytoplasmic tonofilament protein, prekeratin, believed to be the precursor of the keratin which is found in the outer dead cell layer or stratum corneum. 2. Prekeratin is distinguished by its property of being extractable from epidermis homogenized in the presence of citric acid trisodium citrate buffer pH 2.65. 3. In the present study we have compared the epidermal prekeratins from ten mammalian species and have shown them to be of similar amino acid composition. 4. Conditions have been established for studying the immunology of these insoluble proteins and examination of their immunological properties has shown that they are similar to one another but that their antigenic determinants are different from those of callus keratin. 5. The SDS polyacrylamide gel electrophoretic patterns of these proteins differ widely and we have also demonstrated anatomical site variation by this method.     

Modification of human prekeratin during epidermal differentiation.

The polypeptide-chain components of human epidermal prekeratin and keratin were analysed by high-resolution SDS (sodium dodecyl sulphate)/polyacrylamide-gradient-gel electrophoresis. Size heterogeneity existed amongst prekeratin components and at least ten polypeptides, in the molecular-weight range 46,000-70,000, were observed in 0.1 M-citric acid/sodium citrate buffer (pH 2.65) extracts of scale epidermis. Prekeratin from scalp pilosebaceous ducts was identical with that from the contiguous epidermis, and no prekeratin was found in extracts of scale dermis. Prekeratin from plantar epidermis contained additional polypeptide chains, but only slight anatomical variation existed between the non-callus sites examined. Keratin differed from prekeratin in at least two major respects: (a) many major components did not co-electrophorese on high-resolution SDS/polyacrylamide slab gels, and (b) keratin, but not prekeratin, required denaturing and reducing conditions for extraction. Keratin extracted from scale epidermis after complete removal of prekeratin was identical with forearm stratum-corneum keratin. Palmar and plantar keratin contained additional polypeptide chains and had a different size distribution compared with forearm and scalp keratin components. Modification of prekeratin components to produce the keratin polypeptide profile occurred during epidermal differentiation, and these changes appeared to take place in the granular-layer region of the epidermis.     

Immunofluorescent Localization of Vimentin, Prekeratin and Actin during Odontoblast and Ameloblast Differentiation

The localization of constitutive proteins of different types of cytoskeletal components (prekeratin, vimentin, and actin) was examined in embryonic mouse molars using specific antibodies and immunofluorescence microscopy on frozen sections. Prekeratin and actin were found in the enamel organ. Preameloblasts demonstrated uniform staining, whereas ameloblasts demonstrated an apical accumulation of both prekeratin and actin. Vimentin and actin were observed in the dental papilla. A redistribution of vimentin accompanied the polarization of odontoblasts. A possible transmembranous control of cytoskeletal activities by the extracellular matrix is discussed.     

Immunofluorescent localization of vimentin, prekeratin and actin during odontoblast and ameloblast differentiation

The localization of constitutive proteins of different types of cytoskeletal components (prekeratin, vimentin, and actin) was examined in embryonic mouse molars using specific antibodies and immunofluorescence microscopy on frozen sections. Prekeratin and actin were found in the enamel organ. Preameloblasts demonstrated uniform staining, whereas ameloblasts demonstrated an apical accumulation of both prekeratin and actin. Vimentin and actin were observed in the dental papilla. A redistribution of vimentin accompanied the polarization of odontoblasts. A possible transmembranous control of cytoskeletal activities by the extracellular matrix is discussed.     

Direct visualization of contractile proteins in pertubular cells of the guinea-pig testis using antibodies against highly purified actin and myosin.

Antibodies against actin and myosin from smooth muscle, which may react with contractile elements from both muscular and muscle-like cells, were applied to fresh frozen sections of adult guinea-pig testis. Sections stained with an antibody against pectoralis (striated) muscle myosin or with non-immune globulin were used for controls. Peritubular cells of the lamina propria surrounding seminiferous tubulus contained large amounts of actin and myosin as judged by the intensity of immunofluorescence. Sertoli cells did not stain with the antibodies. Our results support the concept of peritubular cells being the critical force for the contractility of seminiferous tubules.     

Mallory bodies: Lesions of hepatocytes containing proteins of the keratin-myosin-epidermin group

Summary Mallory's alcoholic hyalin in hepatocytes was found also in other diseases and is now referred to as Mallory bodies. Data concerning their histochemical, immuno and electron microscopic properties are partly contradictory. In this study, early stages of Mallory bodies reacted strongly with configurational technics for myosins; affinity tended to decrease when material with the properties of keratohyalin and the matrix of stratum corneum was formed. Thus, many Mallory bodies contained histochemically distinct myoid and keratin-like proteins. Electron microscopists demonstrated thick and thin filaments resembling contractile systems in Mallory bodies; the failure of immunologists to visualize actomyosin may be due to the heterogeneity of these proteins. The currently popular term prekeratin has been applied to a variety of substances extracted from epidermis, hoof and hair under different conditions. The prekeratin of recent immunofluorescence studies seems to contain mainly epidermin and low molecular matrix proteins; both were studied extensively by chemists. Epithelial filaments, including tonofibrils and contractile fibrils regarded as a subgroup of myofibrils, were well known half a century ago, but were banished by electron microscopy. Observations in this study and data on epidermal actomyosin indicate that different proteins of the k-m-e-f group can indeed coexist in epithelial cells. The formation and resolution of Mallory bodies can be regarded as an example of the well known shifts of epithelial cells between secretory and keratinizing states.     

Direct visualization of contractile proteins in peritubular cells of the guinea-pig testis using antibodies against highly purified actin and myosin

Summary Antibodies against actin and myosin from smooth muscle, which may react with contractile elements from both muscular and muscle-like cells, were applied to fresh frozen sections of adult guinea-pig testis. Sections stained with an antibody against pectoralis (striated) muscle myosin or with non-immune globulin were used for controls. Peritubular cells of the lamina propria surrounding seminiferous tubulus contained large amounts of actin and myosin as judged by the intensity of immunofluorescence. Sertoli cells did not stain with the antibodies. Our results support the concept of peritubular cells being the critical force for the contractility of seminiferous tubules.     

Mallory bodies: lesions of hepatocytes containing proteins of the keratin-myosin-epidermin group

Mallory's alcoholic hyalin in hepatocytes was found also in other diseases and is now referred to as Mallory bodies. Data concerning their histochemical, immuno and electron microscopic properties are partly contradictory. In this study, early stages of Mallory bodies reacted strongly with configurational technics for myosins; affinity tended to decrease when material with the properties of keratohyalin and the matrix of stratum corneum was formed. Thus, many Mallory bodies contained histochemically distinct myoid and keratin-like proteins. Electron microscopists demonstrated thick and thin filaments resembling contractile systems in Mallory bodies; the failure of immunologists to visualize actomyosin may be due to the heterogeneity of these proteins. The currently popular term prekeratin has been applied to a variety of substances extracted from epidermis, hoof and hair under different conditions. The prekeratin of recent immunofluorescence studies seems to contain mainly epidermin and low molecular matrix proteins; both were studied extensively by chemists. Epithelial filaments, including tonofibrils and contractile fibrils regarded as a subgroup of myofibrils, were well known half a century ago, but were banished by electron microscopy. Observations in this study and data on epidermal actomyosin indicate that different proteins of the k-m-e-f group can indeed coexist in epithelial cells. The formation and resolution of Mallory bodies can be regarded as an example of the well known shifts of epithelial cells between secretory and keratinizing states.     

Langerhans cells in murine vaginal epithelium affected by oestrogen and topical vitamin A

Langerhans cells vary in their morphology and distribution in the vaginal epithelium of ovariectomized mice stimulated to hyperplasia and keratinization by oestrogen. When the stratum corneum was removed by topical vitamin A application, the shape and distribution of Langerhans cells were unaffected. It was concluded that Langerhans cell morphology and distribution depend on the configuration of the lower strata of the epithelium and not on the presence of a stratum corneum.     

The gastric mucosa of two monotremes: the duck-billed platypus and echidna

The gastric mucosa of both the echidna and platypus is aglandular and the lining epithelium is stratified squamous. The latter exhibits three principle layers: stratum germinativum, stratum spinosum, and stratum corneum. The cytoplasm of cells composing the first two strata of both species shows bundles of tonofibrils and numerous free ribosomes. Cells of the stratum spinosum in the platypus also show numerous dense granules limited to the peripheral cytoplasm. The stratum spinosum of both species is comprised of fusiform-shaped cells whose adjacent cell membranes show extensive interlocking. The stratum spinosum of the echidna in addition shows numerous intercellular bridges. Cells of the stratum corneum become flattened and elongate and in the echidna nuclei near the surface appear to degenerate. Cells comprising the stratum corneum of the platypus exhibit well preserved nuclei and contain scattered large granules of varying electron density. Prior to sloughing, cells near the surface of both species show a separation of adjacent cell membranes. True keratinization is not found in the gastric lining epithelium of either species and the epithelium lining of the stomach of the echidna more closely represents a form of parakeratosis. Delicate papillae containing capillaries extend considerable distances into the overlying epithelium of both species and are thought to contribute to its nutrition.     

Reorganization of arrays of prekeratin filaments during mitosis : Immunofluorescence microscopy with multiclonal and monoclonal prekeratin antibodies

Indirect immunofluorescent labelling of different epithelial cell lines for intermediate filaments of the prekeratin type revealed prominent changes in the organization of prekeratin during mitosis. In three out of four cell lines tested (Henle-407, A-431 and HeLa cells) the filamentous prekeratin networks disappeared at the initiation of mitosis and the immunofluorescent labelling was concentrated in small cytoplasmic bodies. This observation was obtained with both polyspecific rabbit anti-bovine prekeratin antibodies and with monospecific antibodies produced by mouse hybridomas. In a fourth cell line, PtK₂, prekeratin filaments were retained throughout mitosis, mainly in the mitotic poles, whereas the central areas of the cells were apparently devoid of filaments. The addition of colchicine to the different cultured cells induced alterations in the organization of prekeratin filaments which were usually manifested by the formation of thicker filament bundles. It did not induce the formation of the prekeratin-cytoplasmic bodies in interphase cells. However, upon prolonged incubation in the presence of colchicine, there was an increase in the number of mitotically arrested cells and a parallel increase in the number of cells containing prekeratin cytoplasmic bodies. It is thus proposed that the state of organization of prekeratin in these cells is cell-cycle-dependent and may be modulated to permit radical shape changes as those occurring during mitosis.     

Immunomorphological study of the distribution of prekeratin with a molecular weight of 49 kilodaltons in various epithelial cells in rats

Cryostat sections of various tissues of rat were stained using an indirect immunofluorescent method with monoclonal antibody against individual prekeratin with the molecular mass of 49 kilodalton (PK-49). Connective tissue endothelial cells, neurons, glia, haematopoetic tissue and smooth muscles were completely negative in this test. 46 morphological variants of epithelial structures were investigated. PK-49 was absent from all the stratified epithelia (epidermis, hair folliculi, oesophagus) but was expressed in virtually all simple epithelia of endodermal origin (exceptions: squamous lung alveolar epithelium and germinative epithelium of testis). There were negative (kidney tubules) as well as positive (bladder, mammary, glands) cell elements among mesodermal and ectodermal simple epithelia. High specificity of individual PK in respect to morphological variants of epithelia points out to the important role played by prekeratin-type intermediate filaments in morphogenesis.