Subunit structure of the mouse epidermal keratin filament

Autoantibodies in scurfy mice and IPEX patients recognize keratin 14

Scurfy mice have a deletion in the Foxp3 gene, resulting in a failure to generate Foxp3(+) regulatory T cells, and they subsequently develop severe CD4(+) T-cell-mediated autoimmune inflammation. Multiple organs are involved, but the skin is one of the main organs affected. During the course of disease, Scurfy mice develop autoantibodies; however, the targeted antigens are unknown. In this study, we show that Scurfy mice develop autoantibodies directed against skin antigens. Using western blot analysis, we found that Scurfy serum reacted with proteins in total skin lysate, as well as in a keratinocyte lysate. Most of the Scurfy sera tested identified a major band at 50 kDa. Transfer of Scurfy CD4(+) T cells into nu/nu mice yielded autoantibodies with similar reactivity. Further analysis using 2D western blots, followed by peptide mass fingerprinting, identified several keratins as targets. To confirm this observation, we chose one of the identified targets, keratin 14, and prepared recombinant proteins encompassing the N-terminal, middle, and C-terminal portions of the keratin 14 protein. Scurfy serum predominantly recognized the C-terminal fragment. Sera from patients with immunodysregulation, polyendocrinopathy, enteropathy, X-linked (IPEX) syndrome, the human disease resulting from FOXP3 mutations, also recognized skin antigens, including keratin 14. Thus, the results of our study indicate that autoantibodies in Scurfy mice and patients with IPEX target keratins.

Analysis of v-Ha-ras and v-fos oncogene transduction into a mouse epidermal cell line with "initiated" phenotype in culture but normal skin phenotype in vivo

Cell line SCR722 was derived from adult SENCAR mouse epidermal cells initiated in culture by treatment with the carcinogen N-methyl-N'-nitro-N-nitrosoguanidine and selection for foci proliferating in medium with calcium levels that induce terminal differentiation in normal cells. Expansion of one of these foci and two additional cell clonings produced cell line SCR722, which was near-tetraploid and formed normal skin when grafted to athymic nude mouse hosts. However, unlike normal keratinocytes, SCR722 cells fail to suppress papilloma formation when grafted along with papilloma cell line SP-1. For optimum growth in culture, SCR722 cells required fibroblast-conditioned medium and 0.5 mM Ca2+. SCR722 cells had a wild-type c-Ha-ras gene but had lost their requirement for conditioned medium in culture and produced dysplastic papillomas in grafts when transduced with the v-Ha-ras gene. SCR722 cells stably expressing the v-fos gene produced normal epidermis in grafts, but when these cells were transduced with the v-Ha-ras gene, they produced carcinomas. Clones with greater expression of the transfected v-fos gene had a more invasive phenotype in vivo. These results indicate that carcinogen treatment of epithelial cells can result in an altered but nontumorigenic phenotype that may be at risk for becoming a more advanced neoplastic state with additional genetic alterations.

Patterns of mRNA for epidermal growth factor receptor and keratin B-2 in normal cervical epithelium and in cervical intraepithelial neoplasia

Patterns of epidermal growth factor receptor (EGFR) and keratin B-2 (KB2) mRNA localization were studied in samples of normal cervical squamous epithelium and in samples of cervical intraepithelial neoplasia (CIN). 35S-Labeled EGFR and KB2 DNA probes were used for in situ hybridization on formalin-fixed tissue sections. Normal cervical squamous epithelium showed predominantly basal and parabasal expression of EGFR mRNA and suprabasal and midepithelial localization of KB2 mRNA. CIN lesions with moderate to severe dysplasia were generally characterized by continued expression of EGFR mRNA and decreased KB2 mRNA in midepithelial locations. Ratios of KB2 mRNA levels at the basal layer to KB2 mRNA levels at the midepithelial location were increased in moderate and severe dysplasia (CIN II and III) compared with normal epithelium (P less than .01). Ratios of EGFR mRNA levels at the midepithelial level to those of EGFR mRNA at the basal layer were increased in moderate to severe dysplasia compared with normal epithelium. These findings indicate a possible in vivo role of EGFR gene expression in normal and neoplastic proliferation and in prevention of differentiation of the cervical epithelium.

Comparative properties of untreated and N-nitrosobenzylmethyl-amine-transformed rat esophageal epithelial cell lines

A culture system utilizing rat esophageal epithelial cells has been developed. Four normal and eight N-nitrosobenzylmethylamine-treated lines were compared with respect to chromosome number, anchorage-independent growth in agarose, and tumorigenic potential in syngeneic rats. All cell lines were aneuploid with nine in the near-tetraploid range and three in the near-diploid range. No relation between tumorigenic potential and chromosome number or structure was apparent. Similarly, anchorage-independent growth in agarose did not correlate with tumorigenic potential. Three of the 12 immortalized lines (two carcinogen-treated and 1 untreated) induced well-differentiated squamous cell carcinomas in syngeneic rats. These tumors had weak metastatic potentials suggesting that tumorigenic potential and metastatic ability are separately controlled. These cell lines will be useful for the investigation of factors involved in the conversion of immortalized rat esophageal epithelial cell lines to lines of high metastatic potential.

Antikeratin autoantibodies in the amyloid deposits of lichen amyloidosus and macular amyloidosis

In order to characterize immunoglobulins found on amyloid deposits of lichen amyloidosus and macular amyloidosis, and elution from cryostat sections was performed with citrate buffer, glycine buffer, NaCl, and PBS. Resulting eluates (mainly IgG) were examined with dot immunoblotting and SDS-PAGE immunoblotting and were found to react with the human epidermal keratin of 50 and 67 kD. Antikeratin autoantibody activities in normal murine and human sera were examined using a dot immunoblotting assay. In murine sera, titers of IgG and IgM autoantibodies were higher in older mice. The human cord blood showed significantly lower IgM autoantibody titers, whereas IgG antibody titers showed no significant differences from adults' sera, probably due to the permeability of IgG through the placental barrier. A stronger antibody activity in older individuals was thought to be due to the repeated exposures to keratin proteins derived from apoptotic keratinocytes. Sera from lichen amyloidosus and macular amyloidosis patients did not show any difference from normal controls in their antikeratin titers. It was concluded that the patients with lichenoid or macular amyloidosis are capable of producing a normal level of antikeratin autoantibodies. However, the removal of opsonized keratin-type amyloid from the skin is slow or deficient due to as yet unknown factors.

Establishment and characterization of an epithelial cell line from the rat submandibular gland

An epithelial cell line, RSMTx, has been established from the submandibular gland of weanling Fisher 344 rats by treatment of explanted tissue clumps with 3-methylcholanthrene. These cells exhibit a polygonal shape on light microscopy and a polar appearance, with desmosomes, terminal bar-like structures, surface microvilli and cytoplasmic interdigitations, when examined by electron microscopy. The cells react positively with an antiserum to cytoskeletal keratin, and a commercial monoclonal antibody to an "epithelial membrane antigen." An antiserum, prepared against early passage cells in hamsters, reacts primarily with ductal elements in tissue sections of submandibular gland, as does an antiserum prepared in mice with late passage cells. The cells are easily passaged and have been maintained for more than two years in continuous culture.

Effect of retinoid deficiency on keratin expression in mouse bladder

Twelve to sixteen weeks following treatment of CF-1 mice with a vitamin A-deficient diet, characteristic signs of retinoid deficiency including body wasting, poor hair coat, altered gait, decreased mobility, and xerophthalmia were observed. Histological examination of tissue sections from these mice revealed dramatic changes in the urinary tract epithelium. The normal transitional epithelium was replaced by a stratified squamous epithelium that resembled hyperproliferative epidermis. Using two-dimensional gel electrophoresis, a number of new proteins were found to be synthesized in vitamin A-deficient bladder when compared to tissue from control bladders. Using antikeratin antibodies in immunoblot experiments, we found that at least some of the newly synthesized proteins were keratins. These proteins, which comprise the intermediate filaments of the cytoskeleton, are known to be specific markers of epithelial differentiation. Of particular interest was the appearance of a Mr 67,000 basic and Mr 61,000 acidic keratin pair, characteristic of terminally differentiating murine epidermal cells. Unexpectedly, several other keratins, previously associated only with hyperproliferative epidermis, were also expressed in the tissue. These results demonstrate that vitamin A deficiency in the mouse leads to the appearance of a squamous metaplasia in the urinary tract epithelium that is characterized by the expression of distinct epidermal keratins.

Vitamin A deficiency and keratin biosynthesis in cultured hamster trachea

Tracheas from vitamin A-deficient hamsters in organ culture in vitamin A-free medium developed squamous metaplasia. Addition of retinyl acetate to the medium prevented squamous metaplasia and a mucociliary epithelium was maintained. Indirect immunofluorescent staining with antikeratin antibodies AE1 and AE3 indicated positive reactions with epithelium of tracheas either cultured in vitamin A-free or retinyl acetate (RAc)-containing medium. The "stratum corneum"-like squames in metaplastic tracheas were strongly stained by AE3. Immunoprecipitation of cytoskeletal extracts from [35S]methionine labeled tracheas with a multivalent keratin antiserum indicated that the concentration of keratins synthesized in tracheas cultured in vitamin A-free medium was greater than that observed in tracheas cultured in the presence of RAc. In addition, new species of keratin were expressed in tracheas cultured in RAc-free medium. Alterations in the program of keratin synthesis were clearly detectable after 1 d in vitamin A-free medium, even though squamous metaplasia was not yet obvious. Squamous tracheas were shown by immunoblot analysis to contain keratins of 50, 48, 46.5, and 45 kilodalton (kd) detected with AE1; and 58, 56, and 52 kd detected with AE3. Immunoblot analysis with monospecific antimouse keratin sera also demonstrated the presence of 60, 55, and 50 kd keratins in the metaplastic tracheas. All these various species of keratins were either absent or present in much reduced quantity in mucociliary tracheas in RAc-containing medium. Interestingly, the induction of squamous metaplasia in tracheal epithelium did not result in the expression of the 59 and 67 kd keratins which are characteristically expressed in the differentiated layers of the epidermis. Therefore, this study shows that squamous metaplasia of tracheas due to vitamin A-free cultivation is accompanied by an increase in keratin synthesis as well as by the appearance of keratin species not normally present in mucociliary tracheal epithelium.

Pair formation and promiscuity of cytokeratins: formation in vitro of heterotypic complexes and intermediate-sized filaments by homologous and heterologous recombinations of purified polypeptides

Cytokeratins are expressed in different types of epithelial cells in certain combinations of polypeptides of the acidic (type I) and basic (type II) subfamilies, showing "expression pairs." We have examined in vitro the ability of purified and denatured cytokeratin polypeptides of human, bovine, and rat origin to form the characteristic heterotypic subunit complexes, as determined by various electrophoretic techniques and chemical cross-linking, and, subsequently, intermediate-sized filaments (IFs), as shown by electron microscopy. We have found that all of the diverse type I cytokeratin polypeptides examined can form complexes and IFs when allowed to react with equimolar amounts of any of the type II polypeptides. Examples of successful subunit complex and IF formation in vitro include combinations of polypeptides that have never been found to occur in the same cell type in vivo, such as between epidermal cytokeratins and those from simple epithelia, and also heterologous combinations between cytokeratins from different species. The reconstituted complexes and IFs show stability properties, as determined by gradual "melting" and reassociation, that are similar to those of comparable native combinations or characteristic for the specific new pair combination. The results show that cytokeratin complex and IF formation in vitro requires the pairing of one representative of each the type I and type II subfamilies into the heterotypic tetramer but that there is no structural incompatibility between any of the members of the two subfamilies. These findings suggest that the co-expression of specific pair combinations observed in vivo has other reasons than general structural requirements for IF formation and probably rather reflects the selection of certain regulatory programs of expression during cell differentiation. Moreover, the fact that certain cytokeratin polypeptide pairs that readily form complexes in vitro and coexist in the same cells in vivo nevertheless show preferential, if not exclusive, partner relationships in the living cell points to the importance of differences of stabilities among cytokeratin complexes and/or the existence of extracytokeratinous factors involved in the specific formation of certain cytokeratin pairs.

Amino acid sequence microheterogeneities of basic (type II) cytokeratins of Xenopus laevis epidermis and evolutionary conservativity of helical and non-helical domains

Three clones coding for carboxy-terminal portions of type II cytokeratins have been isolated from a cDNA library constructed from the epidermis of the frog Xenopus laevis. These clones have been identified by hybridization-selection-translation and Northern blot analysis, and contain sequences complementary to mRNAs of similar size that code for three different polypeptides of the Mr 64,000 group, Ia-c, i.e. the only major type II cytokeratins expressed in this tissue. A comparison of the corresponding nucleotide sequences and the amino acid sequences deduced therefrom shows only minor differences in these polypeptides, most of which occur as isolated point mutations. This indicates that coding sequences of the different type II cytokeratin genes in epidermis of Xenopus are very similar, in contrast to the more extended differences of type II cytokeratin genes expressed in mammalian epidermis, which probably reflects a lower degree of evolutionary divergence of members of this protein family in amphibia. A comparison of the Xenopus sequences with those of mammalian type II cytokeratins reveals the same characteristic features, i.e. an alpha-helical domain ending with the familiar consensus sequence T Y R (X Y) L E G E, followed by a non-helical domain Cl enriched in hydroxyamino acids. Both domains are remarkably conserved in sequence between Xenopus and mammals. The following glycine-rich domain (C2) displays similar oligopeptide repeats (mostly of the type G G G M in the frog keratins), and the terminal C3 domain is characterized by a region exceptionally rich in hydroxyamino acids, which immediately precedes a cluster of basic amino acids at the carboxy terminus. Our results show that the typical features of the domain of type II cytokeratins are already established in amphibia and that these homologies are not restricted to the alpha-helical rod of these proteins but, in principle, extend to the other domains located in the so-called hypervariable tail portion. This suggests that the hypervariable regions are not subject to random variability but contain functionally important domains that have been well conserved during evolution.

The characterization of two monoclonal anti-keratin antibodies and their use in the study of epithelial disorders

The present paper describes the production and characterization of two monoclonal antibodies, K20 and K92. Immunohistological staining showed these two antibodies to be specific for keratinizing epithelium. However, whereas K20 stained all layers of the epidermis K92 reacted with only the suprabasal epidermal layers. Immunoblotting studies with preparations of keratins from both the non-cornified (i.e. the basal, spinous and granular layers) and cornified (stratum corneum) layers of epidermis showed that K20 recognized the 46, 48, 50, 55, 56, 56.5, 59, 61, 62, 64, 65, 66 and 67 kd bands, of which the 50 and 46 kd bands appeared to be masked in tissue sections. In contrast, antibody K92 was more restricted in its activity, recognizing only the 55 and 56 kd bands strongly. These antibodies were used in the study of various epithelial disorders and revealed alterations in the epithelial intermediate filament expression in both benign and malignant disease processes.

Differential post-translational modification of human type I keratins synthesized in a rabbit reticulocyte cell-free system

The translation products synthesized in a rabbit reticulocyte lysate system, from total cellular mRNA from the human epithelial cell-line ME-180, have been examined. Keratin proteins are prominent among these translation products, and they precisely coelectrophorese in sodium dodecyl sulfate-polyacrylamide gels with keratins purified from the cells. Type-I, acidic, keratins which are acetylated in vivo, are also acetylated by the reticulocyte lysate. Examination by two-dimensional electrophoresis, of two acidic keratins known to be phosphorylated in vivo reveals that only one of these proteins is phosphorylated in the lysate system. Phosphorylation of this protein occurs after release of the completed polypeptide chain from the ribosome. The protein phosphorylated by the lysate is known to be the only ME-180 phosphokeratin modulated by cyclic AMP, reflecting in vitro the differential modification of ME-180 keratins in vivo.

The complete cDNA and deduced amino acid sequence of a type II mouse epidermal keratin of 60,000 Da: analysis of sequence differences between type I and type II keratins

We present the complete nucleotide and deduced amino acid sequences of a mouse epidermal keratin subunit of 60,000 Da. The keratin possesses a central alpha-helical domain of four tracts (termed 1A, 1B, 2A, and 2B) that can form coiled-coils, interspersed by short linker sequences, and has non-alpha-helical terminal domains. This pattern of secondary structure is emerging as common to all intermediate filament subunits. The alpha-helical sequences conform to the type II class of keratins. Accordingly, this is the first type II keratin for which complete sequence information is available, and thus it facilitates elucidation of the fundamental distinctions between type I and type II keratins. It has been observed that type I keratins are acidic and type II keratins are neutral--basic in charge. We suggest that the basis for this empirical correlation between type and charge resides in the respective net charges of the 1A and 2B tracts. Calculations on interchain interactions between charged residues in the alpha-helical domains indicate that this keratin prefers to participate in dimers according to an in-register parallel arrangement. The terminal domains of this keratin possess characteristic glycine-rich sequences, and the carboxyl-terminal domain is highly homologous to that of a human epidermal keratin of 56,000 Da. According to the hypothesis that end-domains are located on the periphery of keratin filaments, we conclude that the corresponding mouse and human keratins are closely related, both structurally and functionally.

Isolation and characterization of keratin-like proteins from cultured cells with fibroblastic morphology

Intermediate filaments (IF) isolated from a variety of cultured cells, conventionally described as fibroblasts, are composed predominantely of proteins of molecular weights of 54,000 and/or 55,000. Less than 15% of the protein found in native IF preparations from these cells is composed of three to four polypeptides of molecular weights 60,000-70,000. We have investigated some biochemical and immunological properties of these proteins isolated from BHK-21 and mouse 3T3 cells. They are capable of forming paracrystals that exhibit a light/dark banding pattern when negatively stained with uranyl acetate. The dark bands are composed of longitudinally aligned approximately 2-nm-diam filaments. The center-to-center spacing between either dark or light bands is 37-40 nm. These dimensions are consistent with the secondary structure of IF polypeptides and suggest that the dark bands represent lateral alignment of alpha-helical coiled-coil domains. Immunoblotting, secondary structure, as well as amino acid composition data indicate that the 60,000-70,000-mol-wt paracrystal polypeptides are similar to keratin. Thus, polypeptides with biochemical and immunological properties of epidermal keratin are present in cells normally considered to be fibroblasts.

In vitro cultivation of nonlymphoid thymic cells: morphological and immunological characterization

Nonlymphoid thymic elements play an important role in T-lymphocyte development, especially in the development of recognition of transplantation antigens (H-2 in the mouse). Understanding this process will require the isolation and characterization of these cells. A simple technique for the culture of an enriched population of murine thymic epithelium is described. The epithelial nature of these cells is evidenced by their morphology, electron microscopy, and keratin content. Readily distinguishable macrophages comprise a secondary population within these cultures. Antigens encoded in the I-A region of H-2 were found on 70% of thymic epithelial cells and H-2K on 30% of thymic epithelial cells. These antigens were generally present on distinct populations but doubly positive cells were observed. Thymic macrophages were found to have conventional receptors for the Fc fragment of immunoglobulin on their surface and could ingest antibody-coated sheep erythrocytes. Thymic epithelial cells did not have such Fc receptors. A striking observation was that thymic epithelial cells could bind and internalize autologous thymocytes. This selective thymocyte ingestion by thymic epithelium may have important implications in regard to processing of T-lymphocyte precursors.

Epidermal keratin filaments assembled in vitro have masses-per-unit-length that scale according to average subunit mass: structural basis for homologous packing of subunits in intermediate filaments

We have used scanning transmission electron microscopy to elucidate the question of how intermediate filament (IF) subunits of widely differing mass can all form morphologically similar IF. From scanning transmission electron micrographs, the distributions of mass were determined for three types of epidermal keratin IF reassembled in vitro from mixtures of subunits with substantially different masses, viz., "light" and "heavy" human keratins with [Mr] = 50,000 and 56,000, respectively, and mouse keratins of [Mr] = 63,000. Their principal assembly products were found to average 22, 25, and 29 kdalton/nm, respectively. These densities, which correspond to immature "minimal form" IF (Steven, A. C., J. Wall, J. Hainfeld, and P. M. Steinert, 1982, Proc. Natl. Acad. Sci. USA., 79:3101-3105), are directly proportional to the average subunit masses. The human keratin IF (but not those of mouse) also contained minor amounts (15-20%) of more massive polymers averaging 33 and 35 kdalton/nm, respectively, which probably represent mature IF. Taken together with earlier results on IF of other subclasses, these results indicate that the average linear density of IF scales according to the average mass of their constituent subunits, both for "minimal form" and for mature IF. As underlying mechanism for this homology, we propose that the fundamental building-blocks of all these IF contain a common structural element whose packing within the various IF is likewise conserved and which specifies the overall structure. The variable amounts of mass in the nonconserved moieties account for the observed proportionality. This scheme fits with amino acid sequence data for several IF subunits that have revealed, as a likely candidate for the common element, an essentially conserved alpha-helical domain, contrasting with the highly variable sequences of their non-alpha-helical terminal domains.

Recent advances in oral mucosal research

Major progress in investigation of the normal structure and function of the oral mucosa has been made within the last ten years and has come principally from the application of various techniques developed in basic science disciplines to specific mucosal problems. However, it is apparent that many gaps still exist in our knowledge of the oral mucosa and, although it is to be expected that different workers will have distinct views on which of these are the most significant, some basic areas for further investigation can clearly be identified. For example, little is known about epithelial control systems and their disturbance by epithelial disease processes, about the nature of the interactions occurring during development and maintenance of the oral mucosal epithelia, or about the epithelial cell surface and its role in normal function. The specific properties and behavior of the cell populations of the subepithelial connective tissues appears to be poorly understood and the existence and significance of functional changes in mucosa with age and malnutrition are uncertain. It is increasingly apparent that successful progress in such investigations involves approaches using diverse methodologies. For example, epithelial-mesenchymal interactions are likely to involve multiple mesenchymal factors acting in concert to establish and maintain epithelial form and, because of this complexity, the nature of the inductive influences is not likely to be elucidated in model systems unless individual variables can be rigidly controlled. Defining the cellular and acellular elements in mesenchyme and reconstructing a functional mesenchyme from purified components may not be a simple task, but with current methods for cultivating mucosal keratinocytes and fibroblasts, as well as for purifying various components of the ground substance, it should be possible to initiate such a program of study. Some of the most dramatic advances made over the past 5-6 years in epidermal research have come about through the utilization of newly developed biochemical investigative techniques, examples of which include the use of gene cloning to study the organization of the keratin gene family, and the use of immuno-fluorescence with monoclonal antibodies to discern when various keratin proteins appear during differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)

Histidine-rich proteins (filaggrins): structural and functional heterogeneity during epidermal differentiation

The urea-soluble protein profiles of guinea pig, rat, mouse and human epidermis have been compared by non-equilibrium pH gradient/sodium dodecyl sulphate two-dimensional gel electrophoresis. The histidine-rich proteins (filaggrins) were identified firstly by their characteristic specificity and kinetics of labelling with [3H]histidine and [32P]phosphate, and secondly by their ability in vitro to aggregate keratin filaments specifically into bundles. In all species the phosphorylated filaggrin precursor, profilaggrin, is resolved as a single or doublet band with an apparent molecular weight greater than 300,000 and a neutral or slightly acidic iso-electric point. In striking contrast, the strongly basic filaggrins produced from similar profilaggrins form molecular weight families that are clearly species specific. In rat and man there is a single, principal molecular weight form of filaggrin (Mr 45,000 and 38,000, respectively), while mouse and guinea pig have heterogeneous families, including high molecular weight variants (Mr greater than 200,000). Even filaggrins of a particular molecular weight are not homogeneous proteins, but consist of a number of iso-electric variants, some of which are considerably less basic than the bulk of the filaggrins. Incorporation studies using [3H]arginine and [32P]phosphate indicate that the iso-electric variance is not due to residual phosphate, following profilaggrin breakdown, but rather to a conversion of basic arginine residues into neutral citrulline residues. Filaggrins of all the molecular weights from all the species studied share the ability to aggregate keratin filaments into large, insoluble macrofibrils. However, the more acidic iso-electric variants have lower affinities for keratin, particularly in man and guinea pig where the most acidic filaggrins have completely lost the ability to aggregate keratins. We discuss the possibility that a loss of keratin binding ability, resulting in a loosening of the keratin fibre/filaggrin matrix is necessary before the normal complete proteolysis of the filaggrins can occur.

Expression of keratin genes in mouse epidermis and normal and malignantly transformed epidermal cells in culture

Complementary DNA (cDNA) clones constructed to the 55, 59 and 67 kilodalton (K) keratins, the major keratins synthesized in newborn mouse epidermis, were used as molecular hybridization probes to examine the expression of these genes in newborn epidermis and normal and malignantly transformed epidermal cells in culture. Transcripts of these three keratin genes are abundant in newborn epidermis. However, primary cultures of epidermal cells contain very low levels of these RNAs. The decreased expression of these keratin genes in primary cells appears to be due to factors within the culture system. Unlike primary-cell cultures, the malignantly transformed cell line Pam 212 synthesizes keratin proteins and mRNAs similar to newborn epidermis, including the 67 K keratin. However, synthesis of the 67 K keratin in Pam 212 cells is modulated by culture factors. Keratin gene expression in another Pam line, 321, differs from that of Pam 212 cells in that decreased expression of these three keratin genes occurs. These results indicate that keratin genes that are normally expressed in vivo in epidermis may be expressed in malignant epidermal cells under conditions that do not permit expression of these genes in nonmalignant primary epidermal cells.

Structural features of epidermal keratin filaments reassembled in vitro

We have studied the structure of epidermal keratin filaments polymerized in vitro, addressing two different levels of organization. First, we have determined the amino acid sequence of a mouse epidermal keratin subunit from the nucleotide sequence of a cDNA clone. The subunit contains a large central region, representing about 50 percent, whose sequence strongly suggests that it assumes a coiled-coil alpha-helical conformation. This is flanked on the amino and carboxyl terminals by long glycine-rich sequences. Second, we have used scanning transmission electron microscopy to study the structure of frozen, unstained filaments. Analyses of such images provides information on the mass per unit length and on the distribution of mass within the filament. These data impose rigorous constraints on possible models for the packing of protofilaments within the filament. Epidermal keratin filaments assembled in vitro are polymorphic; however, the majority of bovine filaments weigh about 37 kD/nm, but most human filaments have masses of only about 27 kD/nm. The filament width is at least 15 nm, substantially more than the generally accepted value of 8 to 10 nm, owing to the existence of low-density mass at the periphery that has not been visualized by conventional microscopic methods. We currently postulate that the alpha-helical regions of the subunits comprise the structural core or backbone of the filament from which at least some of the glycine-rich sequences protrude.

Intermediate filaments of the vimentin and prekeratin type in human epidermis

Monospecific antibodies to intermediate filaments of mesenchymally derived vimentin, applied to frozen sections of human skin, specifically stained dendritic basal and suprabasal cells. Cellular morphology, distribution, reaction pattern with anti-HLA-DR in serial sections, and OKT6 in double-staining procedures identified these cells as melanocytes and Langerhans cells. As shown previously in animals keratinocytes stained with antiprekeratin exclusively. Thus, vimentin is an intracellular marker for Langerhans cells and melanocytes, differentiating them from keratinocytes.

Clonal growth and serial propagation of rat esophageal epithelial cells

The clonal growth and serial propagation of rat esophageal epithelial cells in low serum-containing medium has been achieved without feeder layers or conditioned medium. To date, a total of four lines have been developed and maintained for as many as 40 passages in culture. Growth of the cells was possible only after modifying the culture medium (PFMR-4) by reducing the calcium concentration from 1 to 0.1 mM, and by adding low levels of dialyzed fetal bovine serum and seven growth factors; i.e. epidermal growth factor, hydrocortisone, ethanolamine, phosphoethanolamine, insulin, transferrin, and cholera toxin. Cell lines have been developed from both explant outgrowths and enzyme dissociated esophagi. The epithelial nature of the cells was confirmed by electron microscopy and immunological methods. Clonal growth studies revealed that optimal cell growth occurred in medium containing 2.4% dialyzed fetal bovine serum and 0.1 mM calcium. Calcium levels of 0.3 mM or higher caused the cells to stratify and undergo terminal differentiation. Coating the culture dishes with collagen, or a combination of collagen, fibronectin, and bovine serum albumin, increased both the cell growth rate and the colony forming efficiency. The successful long term culture of rat esophageal epithelial cells permits their use as models in studies concerned with esophageal differentiation and carcinogenesis.

Complete amino acid sequence of a mouse epidermal keratin subunit and implications for the structure of intermediate filaments

We have determined the complete primary structure of an intermediate filament subunit, the 59,000 molecular weight subunit of mouse epidermal keratin, from the nucleotide sequence of cDNA clones. The central portion of the sequence forms extended tracts of a coiled-coil alpha-helical conformation. This is flanked at both termini by similar non-alpha-helical sequences that are extremely rich in glycine residues, frequently configured in tandem peptide repeats. Limited chymotryptic digestion of keratin filaments containing this protein suggests a structural organization whereby the terminal glycine-rich sequences protrude from a conserved core structure into which the coiled-coil alpha-helical segments are packed.

Keratin gene expression in mouse epidermis and cultured epidermal cells

The major differentiation products of mouse epidermis are keratins of 40-70 kilodaltons (kDal). We have prepared a library of cDNA clones from total poly(A)+ RNA from newborn mouse epidermis. Clones corresponding to the major in vivo keratins of 55, 59, and 67 kDal have been isolated and characterized. By RNA blot analysis of poly(A)+ RNA from newborn mouse epidermis, we have identified RNA species that are approximately 1,600, 2,000, and 2,400 nucleotides in length and are complementary to the cDNAs for the 55-, 59-, and 67-kDal keratins, respectively. Analysis of RNA from primary cultures of newborn mouse epidermis by this same technique shows greatly reduced levels of these RNAs. Transcripts complementary to all three cloned cDNAs are abundant in 14- to 16-day embryonic and adult mouse skin. Thus, altered expression in culture does not appear to be due to induction of a developmentally programmed switch by placing the cells in culture but instead is due to factors modulating expression within the culture system. Because the 55-, 59-, and 67-kDal keratins are the major proteins in epidermis they probably represent keratin associated with terminal differentiation. The expression data suggest that cultured cells are blocked in expression of differentiation keratins but instead synthesize other keratin family members probably related to cytoskeletal functions.

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.

Immunolocalization of keratin polypeptides in human epidermis using monoclonal antibodies

Three monoclonal antibodies (AE1, AE2, and AE3) were prepared against human epidermal keratins and used to study keratin expression during normal epidermal differentiation. Immunofluorescence staining data suggested that the antibodies were specific for keratin-type intermediate filaments. The reactivity of these antibodies to individual human epidermal keratin polypeptides (65-67, 58, 56, and 50 kdaltons) was determined by the immunoblot technique. AE1 reacted with 56 and 50 kdalton keratins, AE2 with 65-67 and 56-kdalton keratins, and AE3 with 65-67 and 58 kdalton keratins. Thus all major epidermal keratins were recognized by at least one of the monoclonal antibodies. Moreover, common antigenic determinants were present in subsets of epidermal keratins. To correlate the expression of specific keratins with different stages of in vivo epidermal differentiation, the antibodies were used for immunohistochemical staining of frozen skin sections. AE1 reacted with epidermal basal cells, AE2 with cells above the basal layer, and AE3 with the entire epidermis. The observation that AE1 and AE2 antibodies (which recognized a common 56 kdalton keratin) stained mutually exclusive parts of the epidermis suggested that certain keratin antigens must be masked in situ. This was shown to be the case by direct analysis of keratins extracted from serial, horizontal skin sections using the immunoblot technique. The results from these immunohistochemical and biochemical approaches suggested that: (a) the 65- to 67-kdalton keratins were present only in cells above the basal layer, (b) the 58-kdalton keratin was detected throughout the entire epidermis including the basal layer, (c) the 56-kdalton keratin was absent in the basal layer and first appeared probably in the upper spinous layer, and (d) the 50-kdalton keratin was the only other major keratin detected in the basal layer and was normally eliminated during s. corneum formation. The 56 and 65-67-kdalton keratins, which are characteristic of epidermal cells undergoing terminal differentiation, may be regarded as molecular markers for keratinization.

A simplified method for studying fibrous proteins in psoriatic scales obtained by tape stripping

Polyacrylamide gel electrophoretic investigations were carried out on solubilized proteins from psoriatic and normal stratum corneum obtained by adhesive tape stripping. The proteins in the scales adhering to the tape were solubilized by incubating the tape in 1% sodium dodecyl sulphate (SDS) solution. The electrophoretic behaviour of these solubilized proteins on SDS-polyacrylamide gel was compared with the alpha-fibrous proteins (keratin) of callus. The proteins isolated from callus of normal human heel showed six main bands which were similar to those of the keratin isolated by the 8 M urea-mercaptoethanol method. The lesional skin of forty-five psoriatic patients consistently showed nine main bands on polyacrylamide gels, but only two main bands were observed in the non-lesional, non-heel skin. Six of these nine bands had mobilities and relative intensities almost identical with those of alpha-keratin extracted by the mercaptoethanol method, but the other three bands had greater mobilities on the gels. These results suggest that this technique may have considerable potential for studying changes in alpha-keratin in patients with psoriasis and other disorders of keratinization.

O-phosphoserine content of intermediate filament subunits

Purified subunits of intermediate filaments obtained from a variety of tissues and cell types contain O-phosphoserine and, in some cases, smaller amounts of O-phosphothreonine. The O-phosphoserine content was estimated by reaction of performic acid oxidized subunits with methylamine in NaOH. Decamin of BHK-21 and CHO fibroblasts contained about 1 mol/mol. Avian and mammalian desmin consists of two subunits, an acidic (alpha) subunit which contained 2 mol/mol and a more basic (beta) nonphosphorylated subunit. The principal (Mr approximately 60 000) subunit of squid brain neurofilaments contained 5 mol/mol. Most mouse and bovine keratin subunits contained 3--6 mol/mol, although certain bovine subunits of higher molecular weight contained none. The O-phosphoserine contents of keratin subunits purified from the viable and stratum corneum layers were the same. The O-phosphoserine was located in non-alpha-helical regions of the subunits which presumably project out from the alpha-helical wall of the intermediate filaments. Most subunits could be partially dephosphorylated in vitro with alkaline phosphatase. It was found that the capacity of such partially dephosphorylated subunits for assembly into native-type filaments in vitro was independent of their phosphate content.

Dynamic aspects of the supramolecular organization of intermediate filament networks in cultured epidermal cells

We have shown, by indirect immunofluorescence microscopy using an antiserum against the mouse keratin subunit K2 and by electron microscopy, that transformed (PAM) and primary (PME) mouse epidermal cells possess extensive networks of IF bundles. Following trypsinization and replating of PAM cells, IF bundles are seen to move as a continuous network from a perinuclear zone into the peripheral cytoplasmic regions. In PAM cells lysed in high-ionic-strength solutions containing Triton X-100 and DNAase-1, IF bundles appear to be closely associated with nuclear envelope remnants and, in some cases, appear to be attached to nuclear pore complexes. PME cells cultivated in low Ca2+-containing medium possess perinuclear birefringent arrays of IF bundles. Within 2 hours of switching the cells to normal Ca2+ levels, the PME IF bundle network moves towards and establishes contact with the cell surface as desmosomes form. Live cells observed by phase contrast and fixed cells observed by immunofluorescence microscopy demonstrate that desmosomes can be distinguished as dark bands separating neighboring cells. There is little difference between the major proteins seen in SDS-polyacrylamide gel profiles of isolated IF bundle networks from PME cells before and after the Ca2+ switch. Therefore, a reorganization of relatively insoluble membrane-associated protein following the Ca2+ switch may be involved in desmosome formation. The isolated IF networks from PAM cells differ in protein composition compared to the PME IF networks. This may be related to the greatly reduced number of desmosomes in PAM cells. The IF bundle system in epidermal cells appears to be involved in shape formation, shape maintenance, the establishment of desmosomes, nuclear centration, and cell-cell contact.

Characterization of a class of cationic proteins that specifically interact with intermediate filaments

We describe a class of cationic structural proteins that associate specifically with intermediate filaments (IF) but not with other types of cytoskeletal proteins. These proteins, for which the term filaggrin is introduced, are isolated from the stratum corneum of mammalian epidermis. They are species-distinct proteins; for example, rat and mouse filaggrin have different molecular weights and amino acid compositions, but are nevertheless chemically and functionally ver similar. They interact in vitro with the IF several different types of cells to form large fibers or macrofibrils in which many IF are highly aligned in parallel arrays. Stoichiometric analyses suggest that two molecules of filaggrin bind to each three-chain building block of the IF, possibly by ionic interactions with the coiled-coil alpha-helical regions of the IF.

Cultured human bronchial epithelial cells: blood group antigens, keratin, collagens, and fibronectin

Immunofluorescence and immunoperoxidase methods were used to identify constituents and products of cultured human bronchial epithelial cells and fibroblasts. Epithelial cells, but not fibroblasts, from patients with blood Types A or B reacted to the respective antisera to either the A or B blood group antigens. However, neither the epithelial cells nor the fibroblasts from patients with blood type O[H] reacted with the anti-H antisera. Epithelial cells in primary culture reacted with antibody to prekeratin proteins from human stratum corneum and fibroblasts did not react. Moreover, keratin filaments were assembled in vitro from proteins isolated from the epithelial cells. These immunological and biochemical data support previous morphological observations that human bronchial epithelial cells in primary culture shift progressively from a mucociliary epithelium to a keratinizing epithelium. Epithelial cells and fibroblasts could also be identified by their reactivity to anti-collagen antibodies. Fibroblasts reacted strongly with antibodies to Types I and III collagens and epithelial cells did not. On the other hand, epithelial cells reacted weakly with antibodies to Type IV collagen and fibroblasts were completely negative. Both epithelial cells and fibroblasts reacted with antibody to fibronectin; however, the distribution of fibronectin differed in the two cell types. In epithelial cells, fibronectin was restricted to the cell surface, whereas in fibroblasts it was found on the cell surface and in the extracellular matrix where fibrils of fibronectin were both cell associated and deposited on the surface of the dish where the fibroblasts had migrated.

Immunohistochemical localization of the 150K neurofilament protein in the rat and the rabbit

Antisera to the 150K-dalton polypeptide of the bovine neurofilament triplet and chicken neurofilament antisera reacting with the 70K protein in isolated bovine brain filaments stained the same structures in rat cerebellum by immunofluorescence and peroxidase-antiperoxidase methods, that is Purkinje cell baskets, thin nerve fibers in the lower half of the molecular layer and myelinated axons. The 150K bovine neurofilament antisera did not stain large motor neurons in the anterior horns of the spinal cord in rat and rabbit, nor aluminum-induced neurofibrillary tangles in the rabbit. All these structures were demonstrated by the chicken neurofilament antisera and by silver neurofibrillary methods. IDPN-induced axonal balloons containing accumulations of neurofilaments were equally well stained by bovine 150K and chicken neurofilament antisera. These data suggest that the 150K polypeptide of the neurofilament triplet is not a subunit of the neurofilament core and probably plays a role in axonal transport.

Characterization of the keratin filament subunits unique to bovine snout epidermis

Steinert [Biochem. J. (1975) 149, 39-48] reported that the alpha-keratin polypeptides (the subunits of the intracellular keratin filaments) of bovine hoof and snout epidermis are the same. We now demonstrate that this is not so: in addition to the seven polypeptides previously identified in hoof epidermis, snout epidermis also contains at least three other polypeptides of higher molecular weight. These unique polypeptides were isolated, purified and characterized. They are chemically and structurally very similar to the other polypeptides of bovine epidermis and readily polymerize in vitro with them to form native-type epidermal keratin filaments.

Specific quantification of mouse and human keratin proteins by radioimmunoassay

Mouse epidermal keratin proteins were purified and labelled with 125I by chemical techniques. A radioimmunoassay method was established with a rabbit antibody elicited against the mouse keratin. This assay method was utilized to quantify keratin proteins of mouse and human epidermal extracts, both from intact tissues and cells in culture. As little as 30 ng of mouse keratin (0.5 pmol) was quantifiable.

Calcium regulation of growth and differentiation of mouse epidermal cells in culture

Modification of the ionic calcium concentration in the culture medium markedly alters the pattern of proliferation and differentiation in cultured mouse epidermal cells. When medium calcium is lowered to 0.05--0.1 mM, keratinocytes proliferate rapidly with a high growth fraction and do not stratify, but continue to synthesize keratin. The cells grow as a monolayer for several months and can be subcultured and cloned in low Ca++ medium. Ultrastructural examination of cells cultured under low Ca++ conditions reveals widened intercellular spaces, abundant microvilli and perinuclear organization of tonofilaments and cellular organelles. Desmosomes are absent. Epidermal cells growing as a monolayer in low Ca++ can be induced to terminally differentiate by adding calcium to the level normally found in the culture medium (1.2 mM). Cell-to-cell contact occurs rapidly and desmosomes form within 2 hr. The cells stratify by 1--2 days and terminally differentiate with cell sloughing by 3--4 days. After Ca++ addition, DNA synthesis decreases with a lag of 5--10 hr and is totally inhibited within 34 hr. In contrast, RNA and protein synthesis continue at 40--50% of the low Ca++ level at day 3, a time when many cells are detaching from the culture dish. Keratin synthesis is unaffected by the Ca++ switch.