Keratin alterations during embryonic epidermal differentiation: a presage of adult epidermal maturation

Chromosomal mapping of human keratin genes: evidence of non-linkage

We have determined the chromosomal location of the genes for the human keratin intermediate filament proteins K1 (type II; 67 kDa) and K10 (type I; 57 kDa) by the use of specific cDNA clones in conjunction with somatic cell hybrid analysis and in situ hybridization. The K1 keratin gene maps to chromosome region 12q11----q13; the K10 keratin gene maps to chromosome region 17q12----q21. Each gene has been mapped relative to other genes known to be localized on chromosomes 12 and 17, respectively. In somatic cell hybrid analysis, the K1 gene segregates concordantly with the Hox-3 homeo box gene cluster at chromosome region 12p12----q13. The K10 gene localizes to a region proximal to a breakpoint at 17q21 which is involved in a t(17;21)(q21;q22) translocation associated with an acute leukemia. K10 appears to be distal (telomeric) to the gene loci for G-CSF, erb-A, and Her-2, which map to chromosome region 17q12----q21. The NGFR gene and Hox-2 homeo box locus are localized distal to the 17q21 break point and thus distal to the K10 gene. These data demonstrate that keratin genes K1 and K10, which are coexpressed in terminally differentiated epidermis, are not linked in the human genome, implying the existence of trans-acting factors involved in the regulation of expression of these genes.

Monoclonal antibody labeling for cytokeratins and filaggrin in the human pilosebaceous unit of normal, seborrhoeic and acne skin

The distribution of cytokeratins and filaggrin in human pilosebaceous unit was investigated in specimens obtained from normal (n = 15), seborrhoeic (n = 6), and acne skin (n = 6), using the monoclonal antibodies CK8.12, CK8.13, CK4.62, CK8.60, KL1, PKK2, RPN 1160, and an antibody for filaggrin. The type and amount of cytokeratin content was correlated with the stage of cell differentiation in these three skin types. In all specimens studied the sebocytes. The sebaceous duct cells, and the infundibular cells contained cytokeratins, no clear differences were found between normal, seborrhoeic, and acne skin. During sebocytic maturation the amount and type of cytokeratin content changed gradually and the labeling pattern was partly different compared to the interfollicular epidermal pattern. In the sebaceous duct and the infundibulum, the labeling pattern using KL1, CK8.12, and CK8.13 was similar to that seen in interfollicular epidermis, whereas labeling with CK8.60 and PKK2 was different. These findings indicate that sebaceous duct and infundibular cells express transitional patterns of differentiation between epidermal keratinocytes and sebocytes. Filaggrin was expressed only in some sebaceous duct cells and in infundibular cells. In seborrhoeic and in acne skin, however, the reactivity of antibody to filaggrin was more intense and was already observed in the lower parts of the sebaceous duct and the infundibulum. Although no filaggrin was found in the intermediate cells of the sebaceous duct and the infundibulum in normal skin, these cell types clearly contained filaggrin in seborrhoeic and acne skin.

Expression of simple epithelial type cytokeratins in stratified epithelia as detected by immunolocalization and hybridization in situ

Multi-layered ("stratified") epithelia differ from one-layered ("simple") polar epithelia by various architectural and functional properties as well as by their cytoskeletal complements, notably a set of cytokeratins characteristic of stratified tissue. The simple epithelial cytokeratins 8 and 18 have so far not been detected in any stratified epithelium. Using specific monoclonal antibodies we have noted, in several but not all samples of stratified epithelia, including esophagus, tongue, exocervix, and vagina, positive immunocytochemical reactions for cytokeratins 8, 18, and 19 which in some regions were selective for the basal cell layer(s) but extended into suprabasal layers in others. In situ hybridization with different probes (riboprobes, synthetic oligonucleotides) for mRNAs of cytokeratin 8 on esophageal epithelium has shown, in extended regions, relatively strong reactivity for cytokeratin 8 mRNA in the basal cell layer. In contrast, probes to cytokeratin 18 have shown much weaker hybridization which, however, was rather evenly spread over basal and suprabasal strata. These results, which emphasize the importance of in situ hybridization in studies of gene expression in complex tissues, show that the genes encoding simple epithelial cytokeratins can be expressed in stratified epithelia. This suggests that continual expression of genes coding for simple epithelial cytokeratins is compatible with the formation of squamous stratified tissues and can occur, at least in basal cell layers, simultaneously with the synthesis of certain stratification-related cytokeratins. We also emphasize differences of expression and immunoreactivity of these cytokeratins between different samples and in different regions of the same stratified epithelium and discuss the results in relation to changes of cytokeratin expression during fetal development of stratified epithelia, in response to environmental factors and during the formation of squamous cell carcinomas.

Patterns of expression of trichocytic and epithelial cytokeratins in mammalian tissues. II. Concomitant and mutually exclusive synthesis of trichocytic and epithelial cytokeratins in diverse human and bovine tissues (hair follicle, nail bed and matrix, lingual papilla, thymic reticulum)

The hair-forming cells (trichocytes) and the mature hair contain four major trichocytic cytokeratins from each of the subfamilies, basic (Hb1-4) and acidic (Ha1-4); these are related - but not identical - to the epithelial cytokeratins. Here we show, by biochemical methods and immunofluorescence microscopy using antibodies specific for either epithelial or trichocyte cytokeratins, that the same set of hair-type cytokeratins, including two newly identified minor components, designated Hax (type I) and Hbx (type II), are also expressed in cells forming nails, in the filiform papillae of the dorsal surface of human and bovine tongue, and, most surprisingly, in some cells of the epithelial reticulum of bovine and human thymus. By double-label immunofluorescence microscopy, we also show that the expression of the two subsets of cytokeratins, i.e., the epithelial and the trichocytic ones, is not necessarily mutually exclusive, but that certain cells of hair follicles, nail matrix and bed, lingual papillae, and the nonlymphoid cell system of the thymus contain both trichocytic and certain epithelial cytokeratins. This indicates that these cells coexpress representatives of both kinds of cytokeratin. Implications of these findings with respect to problems of regulatory control of cytokeratin synthesis in tissue development and differentiation, and the possible functional meaning of the occurrence of trichocytic cytokeratins in such histologically diverse tissues, are discussed.

Molecular characterization and expression of the stratification-related cytokeratins 4 and 15

A number of human cytokeratins are expressed during the development of stratified epithelia from one-layered polar epithelia and continue to be expressed in several adult epithelial tissues. For studies of the regulation of the synthesis of stratification-related cytokeratins in internal tissues, we have prepared cDNA and genomic clones encoding cytokeratin 4, as a representative of the basic (type II) cytokeratin subfamily and cytokeratin 15, as representative of the acidic (type I) subfamily, and determined their nucleotide sequences. The specific expression of mRNAs encoding these two polypeptides in certain stratified tissues and cultured cell lines is demonstrated by Northern blot hybridization. Hybridization in situ with antisense riboprobes and/or synthetic oligonucleotides shows the presence of cytokeratin 15 mRNA in all layers of esophagus, whereas cytokeratin 4 mRNA tends to be suprabasally enriched, although to degrees varying in different regions. We conclude that the expression of the genes encoding these stratification-related cytokeratins starts already in the basal cell layer and does not depend on vertical differentiation and detachment from the basal lamina. Our results also show that simple epithelial and stratification-related cytokeratins can be coexpressed in basal cell layers of certain stratified epithelia such as esophagus. Implications of these findings for epithelial differentiation and the formation of squamous cell carcinomas are discussed.

3,3',5-Triiodothyronine-induced differences in water-insoluble protein synthesis in primary epidermal cell cultures from the hind limb of premetamorphic Rana catesbeiana tadpoles

Epidermal cells from the hind limb of premetamorphic tadpoles of the American bullfrog Rana catesbeiana (stages IX-XI) were maintained in primary culture for 120 hr. Cultures, maintained for 36 hr in medium supplemented with L-triiodothyronine (T3; 3 x 10(-10) mol T3/ml medium), synthesize water-insoluble proteins with Mrs of 59, 50, 48, and 43. The 59 and 48 kDa proteins synthesized by T3-supplemented cultures are not detectably synthesized by 36-hr-old cell cultures without added T3, but they are synthesized by both hormone-supplemented and unsupplemented cultures after 120 hr. These two proteins have Mrs and pIs which correspond with keratins detected in stratifying mammalian epidermis and are immunoprecipitated by antibodies prepared against human keratins. These observations indicate that T3 induces epidermal cell cultures from the hind limb of premetamorphic tadpoles to precociously synthesize water-insoluble proteins which (1) have Mrs and pIs similar to keratins from differentiating amphibian epidermal tissue and (2) are biochemically and immunologically similar to keratins associated with the differentiation of mammalian epidermal tissue.

Developmental-specific expression and immunoreactivity of keratins during odontogenesis in rat embryos

The enamel organ of the mammalian dental primordium undergoes a precise sequence of differentiation. To correlate this differentiation with tissue-specific markers we analysed the keratin protein composition and immunoreactivity of incisor primordia from the earliest stage of odontogenesis to the neonatal period. Throughout the enamel organ synthesized a characteristic subset of keratin proteins, and the expression of one specific keratin marked the onset of the cap stage. Interestingly, the immunoreactivity of the ameloblastic keratins against polyclonal antibodies increased with progressive odontogenesis, suggesting that cytokeratin filaments may undergo post-translational or conformational alterations during assembly within differentiating enamel-organ cells.

Patterns of cytokeratin and vimentin expression in the human eye

We studied the expression of the various cytokeratin (CK) polypeptides and vimentin in tissues of the human eye by applying immunocytochemical procedures using a panel of monoclonal antibodies as well as by performing biochemical analyses of microdissected tissues. Adult corneal epithelium was found to contain significant amounts of the cornea-specific CKs nos. 3 and 12 as well as CK no. 5, and several additional minor CK components. Among these last CKs, no. 19 was found to exhibit an irregular mosaic-like staining pattern in the peripheral zone of the corneal epithelium, while having a predominantly basal distribution in the limbal epithelium. Both the fetal corneal epithelium and the conjunctival epithelium were uniformly positive for CK no. 19. In the ciliary epithelium, co-expression of CKs nos. 8 and 18 and vimentin was detected, whereas in the retinal pigment epithelium, CKs nos. 8 and 18 were dominant. The present data illustrate the remarkable diversity and complexity of CK-polypeptide expression in the human eye, whose significance with respect to histogenetic and functional aspects is, as yet, only partially clear. The unusual distribution of CK no. 19 in different zones of the corneal epithelium may be related to the specific topography of corneal stem cells. The occurrence of the expression of simple-epithelium CKs in the ciliary and pigment epithelium demonstrates that, despite their neuroectodermal derivation, these are true epithelia.

Keratins of the human hair follicle: "hyperproliferative" keratins consistently expressed in outer root sheath cells in vivo and in vitro

Keratins produced by morphologically distinct compartments of the human hair folicle (hHF) were analysed and compared to those produced by cultured hHF and interfollicular keratinocytes. Five of the major keratins, the basic keratins nos. 5 and 6 (apparent mol. mass 60 and 58 kDa) and the acidic keratins nos. 14, 16, and 17 (51, 49 and 48 kDa), could be labelled in intact hHF and were found in all fractions of the outer root sheath (ORS). The other major keratins, which were not labelled under these conditions (basic-neutral hHbI and -II; 60-62 kDa and acidic hHaI and -II; 40-42 kDa) were associated with hair shaft (hHS) both in the follicle and, virtually unchanged, in the distal part of the hair. Another, previously undescribed, group of proteins with keratin-like properties exhibiting a broad pI-spectrum (basic to slightly acidic: hIC-I, -II, -III, 64-67 kDa; distinctly acidic: hIC-IV, about 54 kDa) was detected in isolated inner root sheath (IRS), in the cuticular material shed from denuded hHS, and also in nail plates. In our experiments only ORS cells grew readily in culture irrespective of their origin from peripheral (mesenchyme-adjacent) or more central ORS-cell layers. In contrast to keratinocytes from interfollicular epidermis (IFE) the cultured ORS cells expressed a keratin set virtually identical to that expressed in vivo. This set also closely resembled that expressed by IFE keratinocyte cultures. The identity of the respective keratins (nos. 5, 6, 14, 16, and 17) present in all these cells in vivo and in vitro was confirmed by tryptic peptide mapping. The data indicated that the microenvironment (in situ) directs the differentiation of ORS cells in a manner comparable to the way it is directed by conventional culture conditions, with consistent expression of the "basal" and "hyperproliferative" set of keratins. This, however, does not exclude the possibility that other types of environmentally induced response may occur, as seen for example during the reepithelialization of superficial skin wounds by ORS cells.

Abnormal expression and processing of keratins in pupoid fetus (pf/pf) and repeated epilation (Er/Er) mutant mice

The pupoid fetus (pf) and repeated epilation (Er) mutations of mice result in a failure of epidermal differentiation in homozygotes. Expression of the epidermal keratins has been followed in pf/pf and Er/Er mice by two-dimensional gel electrophoresis, and by immunohistochemistry and Western blotting using polyclonal antibodies that are monospecific for individual keratin polypeptides. Our results show that expression of the differentiation-specific keratins (K1 and K10) is delayed in both the pf/pf and Er/Er mutants and that, when these keratins do appear later in development, they are localized in the deeper layers of the thickened mutant epidermis. Conversely, K6 and K16, two keratins found in low abundance in normal epidermis, are abundant in mutant epidermis. In newborn mutant epidermis, K6 and K16 are found to be most abundant in the outermost epidermal cells, a distribution opposite to that of K1 and K10. These findings suggest that the expression of these hyperplastic keratins in mutant mice may occur to the exclusion of the differentiation-specific keratins both during development and in newborn animals. Differentiation, and an apparently normal pattern of keratin expression, occur when whole pf/pf or Er/Er skin is grafted to normal mice. These results suggest that the pf and Er genes may be expressed systemically and that transfer of the mutant skin to a "normal" environment results in the recovery of a normal phenotype.

Differentiation-related changes of cytokeratin expression in cultured keratinocytes and in fetal, newborn, and adult epidermis

Cytokeratin expression in differentiating cultured foreskin keratinocytes was studied using chain-specific anti-cytokeratin monoclonal antibodies directed against cytokeratins 4, 8, 10, 13, 18, and 19, respectively. Keratinocytes were cultured at low Ca2+ concentration (0.06 mM) to repress differentiation. At confluency, the cells were switched to high Ca2+ concentration (1.6 mM) to induce differentiation. Cells were harvested 0, 3, 8, 16, 24, 48, and 72 h after the switch. Keratinocytes cultured throughout at high Ca2+ concentration were also harvested. Immunoblots of cytokeratin preparations isolated from these cultures showed that cytokeratins 4, 13, and 19 were not present in nondifferentiating keratinocytes but could be detected from about 16 h after the Ca2+ switch. Immunohistochemical studies were performed on frozen sections of cell sheets incubated with anti-cytokeratin and anti-vimentin. Expression of cytokeratins 4, 13, and 19 was seen in superficial cells. Cytokeratin 10 was locally present in suprabasal and superficial cells. Vimentin was present in 40-70% of the basal cells and in only a few differentiating keratinocytes. Expression of cytokeratins 8 and 18 could not be detected. The same antibodies were also used to stain sections from fetal (15, 20, and 29 weeks), newborn (40 weeks), and mature (5 and 75 years) epidermis. In the 15-week-old epidermis, basal cells were positive for cytokeratins 8 and 19 and locally for cytokeratin 4; intermediate cells expressed cytokeratins 4, 10, 13, and 19; and the periderm contained cytokeratins 4, 8, 13, 18, and 19. In the 20-week-old epidermis, cytokeratin 4 had disappeared from the basal cell layer and cytokeratin 19 was present only locally; in the intermediate cell layer, cytokeratins 4 and 19 had disappeared; and in the periderm, the expression of the cytokeratins studied was the same as that in the 15-week-old epidermis. The basal cells of the 29-week-old fetal epidermis, the newborn epidermis, and the mature epidermis are negative with all antibodies tested, except for some scattered cells in the fetal and newborn skin, presumably Merkel cells, that were positive for cytokeratins 8, 18, and 19. Suprabasal cells in all specimens were positive only for cytokeratin 10. With respect to the cytokeratins studied, our results show that cultured differentiating keratinocytes resemble the suprabasal cells of early fetal epidermis. Basal cells of cultured keratinocytes resemble the basal cells of late fetal, newborn, and adult epidermis and therefore support previous observations.

Isolation, characterization, and in vitro cultivation of keratinocyte subfractions from adult NMRI mouse epidermis: epidermal target cells for phorbol esters

Adult dorsal mouse epidermis (strain NMRI) was separated from dermis in thin-split sections by cold trypsinization. From the isolated keratinocytes four cell fractions (F1-F4) were obtained using discontinuous Percoll density gradient centrifugation. The fractions were characterized by light microscopy, by indirect immunofluorescence using specific lectins (Bandeirea simplicifolia and Ulex europaeus) and an antibody against the spinous 67-kDa keratin polypeptides, and by electrophoretic analysis of the keratin polypeptide patterns. The heavy fractions, F3 and F4, were identified as being derived from the basal cell layer, whereas the light fractions, F1 and F2, consisted mainly of suprabasal cells. The basal cells (F3 and F4) could be cultivated on plastic substratum coated with rat-tail collagen (4 X MEM, 10% FCS at 34 degrees C; plating efficiency 70-85%). Labeling of DNA with [3H]thymidine indicated that during the first 5 days of cultivation, basal cells ran through two cell cycles, after which the proliferative activity ceased due to terminal differentiation. The addition of the tumor promoter TPA led to a stimulation of DNA synthesis in confluent cultures of both F3 and F4 cells.

Characterization of a monoclonal antibody (BG3C8) that reacts with basal cells of stratified epithelia

Monoclonal antibodies were produced against a suspension of formaldehyde fixed human epidermal cells. The supernatant fluid of one clone (BG3C8) yielded a bright immunofluorescent staining of basal cells both in cryostat sections of human split skin and in preparations of purified basal cells. As determined by one- and two-dimensional gel immunoblotting of epidermal basal cell proteins the antibody recognized a minor basic polypeptide of 55,000 apparent molecular weight that was not present in extracts of cultured cell lines of epithelial, fibroblast and lymphoid origin. The distribution of the 55,000 molecular weight protein in normal human tissue was determined by immunohistological staining of cryostat tissue sections that included: central nervous, endocrine, female and male reproductive, alimentary, lymphatic-haemopoietic, respiratory and urinary systems, skin and its appendages, mesenchymal tissue (bone, cartilage, muscle, connective tissue, blood vessels, nerves and synovia) as well as placenta and umbilical cord. The results showed a restricted distribution of this antigen which was found only in basal cells of most stratified or pseudostratified epithelia and in myoepithelial cells. This antibody may be useful in the study of normal and pathological differentiation in various epithelial disorders.

Expression of keratin proteins in deeply invasive basal and squamous cell carcinoma: an immunohistochemical study

The expression of certain classes of keratin is associated with cell maturation and differentiation. During cell transformation and tumor development, the cell specificity of intermediate filament, keratin, is largely conserved. Taking advantage of this, we utilized monoclonal antikeratin immunohistochemical techniques to examine basal and squamous cell carcinomas as they became deeply invasive. Dyskeratotic keratinocytes and keratin pearls in squamous cell carcinomas (SCCs) stain with antikeratin antisera to larger keratins (65-67 Kd). At the deep tumor margins, SCCs no longer express larger keratins but retain expression of 50, 58 Kd, which are markers of keratinocytes derived from stratified squamous epithelial cells. This selective loss of expression of keratin polypeptide markers of differentiation in SCC is associated with progressively more aggressive biologic behavior as the tumor invades deeper structures such as muscle and bone. Recurrent basal cell carcinoma (BCC) which was of the nodular type when first excised, shows features of morphea-like BCC and of aggressive growth patterns at the deep invasive margin. At these deep margins, some tumors express markers of keratinization (65-67 Kd). While tumor cells retain the specificity of the intermediate filament, keratin, the individual cells express products of differentiation as measured by keratin expression independently of their cytologic atypia. At the deeper invasive margin of the tumor, the neoplastic cells synthesize keratin proteins in an unpredictable fashion.

Histological evaluation of three new monoclonal anti-cytokeratin antibodies. 1. Normal tissues

Three new monoclonal anti-cytokeratin antibodies (mabs) potentially useful in cancer research and clinical diagnosis have been evaluated in immuno-histochemistry on cryostat sections of a broad variety of normal human tissues. A45-B/B3 reacts with all cells containing cytokeratins (epithelia and mesothelia). This mab positively identifies epithelial cells of any kind, and it may serve in differentiating carcinomas from tumours of mesenchymal origin. A53-B/A2 recognizes an individual cytokeratin, No. 19, and stains preferably mesothelia, urothelium, and bile duct epithelium. This antibody is suited to discriminate between different epithelial lineages. A51-B/H4 reacts with a subgroup of cytokeratins (probably including Nos. 14, 8 and/or 18). It is positive with most epithelia but negative with keratanized stratified epithelium. This antibody shows an interesting, but up to now unexplained, cross-reactivity with nuclei of certain nonepithelial cells. All three mabs also react with epithelial cells from at least three animal species.

Differential localization of distinct keratin mRNA-species in mouse tongue epithelium by in situ hybridization with specific cDNA probes

The tongue of the adult mouse is covered by a multilayered squamous epithelium which is continuous on the ventral surface, however interrupted on the dorsal surface by many filiform and few fungiform papillae. The filiform papillae themselves are subdivided into an anterior and posterior unit exhibiting different forms of keratinization. Thus, the entire epithelium shows a pronounced morphological diversity of well recognizable tissue units. We have used a highly sensitive in situ hybridization technique to investigate the differential expression of keratin mRNAs in the tongue epithelium. The hybridization probes used were cDNA restriction fragments complementary to the most specific 3'-regions of any given keratin mRNA. We could show that independent of the morphologically different tongue regions, all basal cells uniformly express the mRNA of a type I 52-kD keratin, typical also for basal cells of the epidermis. Immediately above the homogenous basal layer a vertically oriented specialization of the keratin expression occurs within the morphological tissue units. Thus the dorsal interpapillary and ventral epithelium express the mRNAs of a type II 57-kD and a type I 47-kD keratin pair. In contrast, in the anterior unit of the filiform papillae, only the 47-kD mRNA is present, indicating that this keratin may be coexpressed in tongue epithelium with different type II partners. In suprabasal cells of both, the fungiform papillae and the posterior unit of the filiform papillae, a mRNA of a type I 59-kD keratin could be detected; however, its type II 67-kD epidermal counterpart seems not to be present in these cells. Most surprisingly, in distinct cells of both types of papillae, a type I 50-kD keratin mRNA could be localized which usually is associated with epidermal hyperproliferation. In conclusion, the in situ hybridization technique applied has been proved to be a powerful method for detailed studies of differentiation processes, especially in morphologically complex epithelia.

Concurrent expression of basal and luminal epithelial markers in cultures of normal human breast analyzed using monoclonal antibodies

The aim of this study was to investigate the retention in culture of the antigens characteristic of the two mammary epithelial subclasses, basal and luminal epithelium. Primary and secondary cultures of normal human mammary-gland cells were used for immunolocalization experiments with monoclonal antibodies to luminal and basal epithelium. In contrast to the in vivo situation, in which reactivity was only seen in basal cells that were negative for the luminal antigen, we found the homogeneous expression of the basal marker by all of the cultured cells at second passage, and the simultaneous expression of the luminal marker by some of these cells. Characterization of the basal antigen expressed in culture using sodium-dodecyl-sulfate/polyacrylamide gel electrophoresis and immunoblotting techniques showed it to be a 51-kilodalton keratin peptide with an isoelectric pH of 5.4, and confirmed its similarity to the antigen expressed in vivo. Our findings thus demonstrated the coordinate expression of the basal and luminal antigens in cells cultured on solid substrates. The availability of monoclonal antibodies to epithelial-subclass-specific markers of the human mammary gland now makes it feasible to search for culture conditions that would allow the maintenance and manipulation of cell differentiation in vitro.

Developmentally regulated cytokeratin gene in Xenopus laevis

We have determined the sequence of cloned cDNAs derived from a 1,665-nucleotide mRNA which transiently accumulates during Xenopus laevis embryogenesis. Computer analysis of the deduced amino acid sequence revealed that this mRNA encodes a 47-kilodalton type I intermediate filament subunit, i.e., a cytokeratin. As is common to all intermediate filament subunits so far examined, the predicted polypeptide, named XK70, contains N- and C-terminal domains flanking a central alpha-helical rod domain. The overall amino acid homology between XK70 and a human 50-kilodalton type I keratin is 47%; homology within the alpha-helical domain is 57%. The N-terminal domain, which is not completely contained in our cDNAs, is basic, contains 42% serine plus alanine, and includes five copies of a six-amino-acid repeating unit. The C-terminal domain has a high alpha-helical content and contains a region with sequence homology to the C-terminal domains of other type I and type III intermediate filament proteins. We suggest that different keratin filament subtypes may have different functional roles during amphibian oogenesis and embryogenesis.

Cytokeratin No. 9, an epidermal type I keratin characteristic of a special program of keratinocyte differentiation displaying body site specificity

Plantar epidermis of the bovine heel pad as well as human plantar and palmar epidermis contain large amounts of an acidic (type I) keratin polypeptide (No. 9) of Mr 64,000 which so far has not been found in epidermis of other sites of the body. We present evidence for the keratinous nature of this protein, including its ability to form cytokeratin complexes and intermediate-sized filaments in vitro. We have isolated RNA from plantar epidermis of both species and show, using translation in vitro, that these polypeptides are genuine products of distinct mRNAs. Using immunofluorescence microscopy with specific antibodies against this protein, we demonstrate its location in most cells of suprabasal layers of plantar epidermis as well as in sparse keratinocytes which occur, individually or in small clusters, in upper layers of epidermis of other body locations. We conclude that cytokeratin No. 9 is characteristic of a special program of keratinocyte differentiation which during morphogenesis is expressed in most epidermal keratinocytes of soles and palms but only in a few keratinocytes at other body sites. This example of cell type-specific expression of a member of a multigene family in relation to a body site-related program of tissue differentiation raises important biological questions concerning the regulation of keratinocyte differentiation and morphogenesis as well as the function of such topological heterogeneity within a given type of tissue.

Structural and histochemical aspects of epidermis development of fetal porcine skin

Epidermal development of fetal porcine skin was studied in fetuses from 41 days of gestation until birth with scanning and electron microscopy techniques as well as histochemical methods, including immunohistochemistry. The porcine fetus develops a relatively thick and solid multilayered cover of epidermal cells, which is not lost before birth. It consists of tightly packed cells of the periderm and the stratum intermedium. The periderm cells are totally filled with filamentous proteins; in the intermediate cells, the filamentous proteins are concentrated in the cell periphery, forming a thick marginal zone. Immunohistochemically, the cytofilaments could be identified as cytokeratins of lower and higher molecular weights. The first thin stratum corneum lamellae are formed below the stratum intermedium at about 80-85 days of gestation.

Epithelial cell heterogeneity in the guinea pig thymus: immunohistochemical characterization of four thymic epithelial subsets defined by monoclonal anti-keratin antibodies

Keratins are a family of related polypeptides constitutive of the cytoskeleton of epithelial cells and are never found in nonepithelial tissues. Thymic epithelial cells (TEC), known to induce T cell differentiation, are the keratin-containing cells within the thymus. Using four monoclonal anti-keratin antibodies (KL1, KL4, AE2, AE3) directed against keratins of different molecular weight, we have investigated the guinea pig thymic epithelium. The immunohistochemical analysis of thymic cryostatic sections revealed that the keratin expression of TEC varied according to their location in the thymic lobula; the thymic cortex was specifically stained by AE3 whereas the thymic medulla and the subcapsular cortex were recognized by KL4. In addition, KL1 and AE2 exclusively labeled Hassall's corpuscles. The biochemical analysis of keratins extracted from the thymus showed that each TEC subset was characterized by an unique pattern of keratin polypeptides. This study extends the concept of thymic epithelium heterogeneity and suggests that anti-keratin antibodies which allow the typing of TEC subsets may be valuable tools for studying the differentiation of thymic epithelium and its in vitro function on T lymphocytes.

Distribution profiles of keratin proteins during rat amelogenesis

We examined rat cells undergoing amelogenesis for the presence of three types of keratin proteins using a polyclonal antibody to keratin (against total keratins (TK) with molecular masses ranging from 41 to 65 kilodaltons (kd) and monoclonal antibodies keratins to KL1 and PKK1 (reactive with keratins with molecular masses of 55-57 and 41-56 kd, respectively). In normal oral epithelia from young rats, the TK, KL1, and PKK1 antibodies bound to all of the epithelial strata. The epithelial cap on the top of incisors and the dental lamina of molar teeth exhibited strong TK staining, moderate staining KL1, and little or no PKK1 staining. In developing molar enamel organs, both the outer and inner enamel epithelia, the stratum intermedium, and stellate reticulum cells were all positively stained by the TK immunoreagent. In developing incisors, TK only bound strongly to stratum-intermedium cells, and no KL1 and PKK1 staining antibodies was observed in ameloblasts or the stratum intermedium.

Differentiation-dependent expression of keratins in human oral epithelia

The polypeptide composition of epithelial keratins varies with the state of differentiation. The epithelia lining the human oral cavity show regional variations in their histology. In the present study, paired samples of nonkeratinized buccal epithelium and keratinized hard palate epithelium were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by immunoblots with monoclonal antibodies AE1, AE2, and AE3, and results were correlated with immunofluorescence staining of tissue sections of the same samples. Keratins from hard palate (Mr 67K, 63-65K, 58K, 56.5K, 56K, 50K, 48K) and epidermis (Mr 67K, 63-65K, 58K, 56.5K, 50K) were similar to each other but distinctly different from those of buccal epithelium (major bands of Mr 52K and 59K, minor bands of 50K and 58K). The immunoblot analysis further indicated the similarity of hard palate and epidermal keratins, in contrast to those of buccal epithelium. Each oral tissue expressed keratins of the type I (AE1, acidic) subfamily and type II (AE3, basic) subfamily. In tissue sections, the predominant staining pattern for nonkeratinized buccal epithelium was: AE1, positive in the basal layer; AE2, negative; AE3, positive in all layers. In contrast, the staining pattern for keratinized palatal epithelium was: AE1 and AE2, positive in the suprabasal layers; AE3, positive in all layers. Strong suprabasal AE1 staining in palate may be related to the presence of the 48K keratin. Some buccal samples showed an alternate staining pattern of spotty suprabasal staining with AE1 and AE2 which was correlated with the expression of the 56.5K and 63-67K keratins, as well as filaggrin. These results suggest differentiation-specific expression of the keratins and show immunologically detectable variation in the apparently normal differentiation pattern of nonkeratinized buccal epithelium.

Differential expression of keratin genes during mouse development

Suprabasal layers of the newborn mouse epidermis contain two mRNAs of 2.0 and 2.4 kb which are translated into keratins of 59 and 67 kDa, respectively. To study their expression during development, cDNA sequences corresponding to the 2.0- and the 2.4-kb mRNAs were cloned, characterized by hybridization selection assay, and used as probes to detect keratin sequences in polyadenylated RNA from Day 11, 13, 15, and 17 embryos. In RNA from Day 11 of gestation, two RNAs of 2.8 and 1.8 kb were identified. They were found to have homologies with both epidermal RNAs, suggesting that they are coding for proteins of the keratin family. These two sequences were not detected in sample of later stages. RNAs comigrating with the two epidermal keratin RNAs were identified only in Day 15 and 17 embryos indicating that their expression was induced between Day 13 and 15. Finally, the localization of the 59-kDa keratin mRNA was examined by in situ hybridization. The spinous and granulous cell layers were found to be heavily covered with grains while other regions of the tissue sections were unlabeled. All these results support the hypothesis of a sequential expression of keratins during differentiation of epidermal cells and suggest that proteins related to the keratins expressed specifically in keratinizing cells are expressed earlier during development.

Intermediate filaments of the midgestation rat trophoblast giant cell

Trophectoderm (TE) of the rodent blastocyst, the preimplantation precursor of the trophoblast giant cell (TGC), is the first embryonic cell to exhibit intermediate filaments (IF). The two IF proteins of TE (54K and 46K) have been variously described as trophectoderm specific, noncytokeratin, or cytokeratin and have been identified with Endo A and Endo B, IF proteins extracted from extraembryonic endodermal cells. IF proteins of midgestation rat TGC, the postimplantation descendant of TE, were compared to IF proteins of various rat simple epithelial cells by two-dimensional gel electrophoresis, partial proteolytic digest, antibody recognition on electrophoretic transfer, and antibody recognition by indirect immunofluorescence. The two TE IF proteins at 54K and 46K were identified in TGC IF and recognized by anti-Endo A, anti-Endo B, respectively, and anticytokeratins. TGC were found to possess additional cytokeratins at 52K, 45K, 43K, and 40K. The profile of TGC cytokeratins was qualitatively identical to that of various rat simple epithelial cells. The results suggest that (a) TE and TGC IF proteins are cytokeratins, (b) TE and TGC cytokeratins are characteristic of a simple epithelial cell, and (c) the morphologic and functional differentiation of TE to TGC is accompanied by elaboration of the cytokeratin profile.

Keratin proteins in human oral mucosa

We have examined the keratin proteins in normal human oral mucosa from 6 different regions including hard palate, buccal mucosa, tongue, gingiva and floor of the mouth. Urea-dithiothreitol extracts of EDTA separated epithelia were analysed by SDS-PAGE and immunoblotting. Eight samples from each region were investigated and showed very little individual variation in the keratin profile on Coomasie Blue-stained gels. The keratinizing hard palate and gingiva expressed identical patterns and resembled the pattern of epidermis from the flank region. The normally non-keratinizing buccal mucosa and the mucosa of the floor of the mouth expressed polypeptides distinctly different from those of the keratinizing epithelia and lacked the high molecular weight keratins. The dorsal surface of the tongue and the commissure region showed a pattern intermediate between keratinizing and non-keratinizing epithelia. The greater sensitivity of the immunoblotting technique revealed that the non-keratinizing epithelia synthesized one of the high molecular polypeptides and that the tongue produced all the bands found in keratinizing epithelia, but in very small quantities. There are, thus, distinct differences in the keratin expression of oral epithelia which are related to the pattern of keratinization assessed histologically.

Variation and frequency of cytokeratin polypeptide patterns in human squamous non-keratinizing epithelium

The squamous non-keratinizing epithelium of the human upper digestive tract was analyzed for keratin-like cytoskeletal proteins (cytokeratins) by both high resolution one- and two-dimensional gel electrophoresis. The Triton/high salt-insoluble portion of pure epithelial homogenates contains a number of SDS- and urea-extractable polypeptides, whose two-dimensional gel pattern (NEpHG/SDS) typically represents a defined subset of human cytokeratins. The cytoskeletal preparations of epithelial tissue samples obtained from different individuals were found to be uniform with respect to their content of cytokeratin polypeptides 55.0 kD/basic, 52.0 kD/acidic, and 49.0 kD/acidic. However, we have observed that four basic members of apparent molecular weight 60.0, 59.0, 56.5, and 56.0 kD occur at an inconstant rate. Consequently, the cytokeratin polypeptide patterns appeared highly variable as a result of the presence of constant plus compositionally different subsets of inconstant members. From the analysis of cytoskeletal portions of more than 300 individual tissue samples we demonstrate eight different keratin-like polypeptide patterns including their frequencies and propose the existence of no more than nine. These, most probably, encompass all the possible inter-individual variations to which the cytokeratins of this type of epithelium will combine for forming intermediate-sized filaments in vivo. We furthermore hypothesize that the observed variation of cytokeratin patterns may reflect a polymorphism of genes coding for the variable keratin-like polypeptide members.

Developmental changes in keratin patterns during epidermal maturation

The biochemical maturation of the epidermis of Xenopus laevis was examined through an identification of the keratins expressed at selected stages of development. The keratin patterns obtained were compared to those observed in the adult epidermis and two Xenopus non-epidermal, epithelial cell lines. The keratins expressed during development can be grouped into three classes: (1) keratins which are restricted to the embryonic epidermis (58 and 59 kDa); (2) keratins which are prominent during development, but become minor components of the adult epidermis (47, 48, and 60 kDa); and (3) keratins which accumulate during development to become the major keratins of the adult epidermis (49, 53, 56, and 63 kDa). The embryo-specific keratins are present at all developmental stages prior to metamorphosis which we have investigated, but disappear when the epidermis keratinizes during metamorphosis. Both class 1 and 2 keratins, while undetectable or minor components of the adult skin, are present in the two non-epidermal cell lines. In contrast, the class 3 keratins show little overlap with the keratins of these cell lines. All of the class 3 keratins appear after hatching with the exception of the 53-kDa keratin which is present at the earliest developmental stage which we have examined. All of the major keratins of the adult epidermis accumulate as metamorphosis proceeds, while the embryo-restricted keratins are gradually lost.

Expression of epidermal keratins and filaggrin during human fetal skin development

The major structural proteins of epithelia, the keratins, and the keratin filament-associated protein, filaggrin, were analyzed in more than 50 samples of human embryonic and fetal skin by one-dimensional SDS PAGE and immunoblotting with monoclonal and polyclonal antibodies. Companion samples were examined by immunohistochemistry and electron microscopy. Based on structural characteristics of the epidermis, four periods of human epidermal development were identified. The first is the embryonic period (before 9 wk estimated gestational age), and the others are within the fetal period: stratification (9-14 wk), follicular keratinization (14-24 wk), and interfollicular keratinization (beginning at approximately 24 wk). Keratin proteins of both the acidic (AE1-reactive, type I) and the basic (AE3-reactive, type II) subfamilies were present throughout development. Keratin intermediate filaments were recognized in the tissue by electron microscopy and immunohistochemical staining. Keratins of 50 and 58 kD were present in the epidermis at all ages studied (8 wk to birth), and those of 56.5 and 67 kD were expressed at the time of stratification and increased in abundance as development proceeded. 40- and 52-kD keratins were present early in development but disappeared with keratinization. Immunohistochemical staining suggested the presence of keratins of 50 and 58 kD in basal cells, 56.5 and 67 kD in intermediate cells, and 40 and 52 kD in the periderm as well as in the basal cells between the time of stratification and birth. Filaggrin was first detected biochemically at approximately 15 wk and was localized immunohistochemically in the keratinizing cells that surround hair follicles. It was identified 8-10 wk later in the granular and cornified cell layers of keratinized interfollicular epidermis. These results demonstrate the following. An intimate relationship exists between expression of structural proteins and morphologic changes during development of the epidermis. The order of expression of individual keratins is consistent with the known expression of keratins in simple vs. stratified vs. keratinized epithelia. Expression of keratins typical of stratified epithelia (50 and 58 kD) precedes stratification, and expression of keratins typical of keratinization (56.5 and 67 kD) precedes keratinization, which suggests that their expression marks the tissue commitment to those processes. Because only keratins that have been demonstrated in various adult tissues are expressed during fetal development, we conclude that there are no "fetal" keratins per se.(ABSTRACT TRUNCATED AT 400 WORDS)

Developmentally regulated cytokeratin gene in Xenopus laevis

We have determined the sequence of cloned cDNAs derived from a 1,665-nucleotide mRNA which transiently accumulates during Xenopus laevis embryogenesis. Computer analysis of the deduced amino acid sequence revealed that this mRNA encodes a 47-kilodalton type I intermediate filament subunit, i.e., a cytokeratin. As is common to all intermediate filament subunits so far examined, the predicted polypeptide, named XK70, contains N- and C-terminal domains flanking a central alpha-helical rod domain. The overall amino acid homology between XK70 and a human 50-kilodalton type I keratin is 47%; homology within the alpha-helical domain is 57%. The N-terminal domain, which is not completely contained in our cDNAs, is basic, contains 42% serine plus alanine, and includes five copies of a six-amino-acid repeating unit. The C-terminal domain has a high alpha-helical content and contains a region with sequence homology to the C-terminal domains of other type I and type III intermediate filament proteins. We suggest that different keratin filament subtypes may have different functional roles during amphibian oogenesis and embryogenesis.

Epidermal keratin gene expressed in embryos of Xenopus laevis

DG81 is a cDNA clone derived from a subtracted library containing those RNA molecules that are present in gastrulae but absent from eggs of the frog Xenopus laevis. DG RNAs (where DG indicates differentially expressed in gastrula) represent the products of new transcription activated in the embryo at the midblastula transition or shortly thereafter. DG81 RNA is first detected in middle to late gastrulae, peaks in abundance in early tadpoles, and declines to background levels by the end of metamorphosis. Sequence analysis of an almost full-length cDNA clone homologous to DG81 allows deduction of a protein sequence that shows extensive homology to known intermediate filament proteins, most notably to epidermal type I cytokeratins. Consequently, the protein encoded by DG81 has been named XK81, for Xenopus keratin 81. In concert with keratins analyzed previously, XK81 has a central coiled-coil alpha-helical domain of 312 amino acids, which accounts for most of the homology to other keratins. This rod-like region is flanked by more divergent domains of 73 amino acids at the NH2 terminus and 44 amino acids at the COOH terminus. XK81 provides an example of a cytokeratin whose expression is limited to pre-adult developmental stages. We suggest that XK81 functions specifically in the differentiation of the tadpole epidermis.

Altered patterns of keratin synthesis in human epidermal keratinocytes transformed by SV40

Transformation of human epidermal keratinocytes by the oncogenic virus SV40 is a stage-specific process in which normal patterns of differentiation are progressively altered over time following infection. Within the context of this scheme, we examined the keratins produced by the infected cells. Immunofluorescence studies indicated that viral infection led to the formation of variant cells visibly lacking the normal keratin cytoskeleton after about 10-15 serial passages (60-90 cell generations) post infection. Analyses of variant cell formation in clonal populations grown on palladium islands revealed that the variants were derived within 2-3 cell divisions from cells containing an apparently normal keratin cytoskeleton, but that variant formation depended upon cell density. Immunoprecipitation of 35S-methionine labelled keratins from the infected keratinocytes revealed a gradual loss of the normal 46, 50, 56 and 58Kd keratin species over a period of many months after infection. The loss of the normal keratins was accompanied by the appearance of at least two species in the 48-52Kd size range not present in uninfected cells and the enhancement of a third, 40Kd, protein quite early after infection. Analysis of the altered keratin patterns on two-dimensional acrylamide gels using either isoelectric focusing (IEF) or non-equilibrium pH gradient electrophoresis (NEPHG) along the first dimension showed that the infected cells produced basic keratins which increased in relative abundance as cells became more transformed with serial passage including at least five isoelectric forms not seen in uninfected cells. Translation of poly A+ RNAs from the infected cells indicated that the altered keratin synthesis probably reflects changes in the translatable mRNA pool.

Intermediate filament cytoskeleton of amnion epithelium and cultured amnion epithelial cells: expression of epidermal cytokeratins in cells of a simple epithelium

Using immunofluorescence microscopy and two-dimensional gel electrophoresis, we compared the cytoskeletal proteins expressed by human amnion epithelium in situ, obtained from pregnancies of from 10-wk to birth, with the corresponding proteins from cultured amnion epithelial cells and cultures of cells from the amniotic fluid of 16 week pregnancies. Epithelia of week 16 fetuses already display tissue-specific patterns of cytokeratin polypeptides which are similar, although not identical, to those of the corresponding adult tissues. In the case of the simple amnion epithelium, a complex and characteristic complement of cytokeratin polypeptides of Mr 58,000 (No. 5), 56,000 (No. 6), 54,000 (No. 7), 52,500 (No. 8), 50,000 (No. 14), 46,000 (No. 17), 45,000 (No. 18), and 40,000 (No. 19) is present by week 10 of pregnancy and is essentially maintained until birth, with the addition of cytokeratin No. 4 (Mr 59,000) and the disappearance of No. 7 (Mr 54,000) at week 16 of pregnancy. In full-term placentae, the amnion epithelium displays two morphologically distinct regions, i.e., a simple and a stratified epithelium, both of which express the typical amnion cytokeratin polypeptides. However, in addition the stratified epithelium also synthesizes large amounts of special epidermal cytokeratins such as No. 1 (Mr 68,000), 10 (Mr 56,500), and 11 (Mr 56,000). In culture amnion epithelial cells obtained from either 16-wk pregnancies or full-term placentae will continue to synthesize the amnion-typical cytokeratin pattern, except for a loss of detection of component No. 4. This pattern is considerably different from the cytokeratins synthesized by cultures of cells from amniotic fluids (cytokeratins No. 7, 8, 18, and 19, sometimes with trace amounts of No. 17) and from several so-called "amnion epithelial cell lines." In addition, amnion epithelial cells in situ as well as amnion epithelial cell cultures appear to be heterogeneous in that they possess some cells that co-express cytokeratins and vimentin. These observations lead to several important conclusions: In contrast to the general concept of recent literature, positively charged cytokeratins of the group No. 4-6 can be synthesized in a simple, i.e., one-layered epithelium. The change from simple to stratified amnion epithelium does not require a cessation of synthesis of cytokeratins of the simple epithelium type, but in this case keratins characteristic of the terminally differentiated epidermis (No. 1, 10, and 11) are also synthesized.(ABSTRACT TRUNCATED AT 400 WORDS)

Monoclonal antibodies specific for subsets of epidermal keratins: biochemical and immunocytochemical characterization--applications in pathology and cell culture

Keratin composition has been widely used as a biochemical marker of differentiation in normal epithelia, cell culture systems and tumours of epithelial tissues. We have been developing a model system for the study of human squamous epithelial cell differentiation, and among a panel of monoclonal antibodies we have generated for analysing this system are two antibodies recognizing subsets of epidermal keratins. The two antibodies, designated LICR-LON-16a and LICR-LON-29b, were raised to the human squamous carcinoma cell line LICR-LON-HN-5, and we describe here their biochemical and immunocytochemical characterization. Antibody 16a reacts with only epidermal basal cells in normal human skin and shows specificity for the 45 and 46 kdalton keratins. Antibody 29b stains all living layers of the epidermis, and reacts with a broad range of ketain polypeptides, (45-56 kdaltons) in immunoblotting analyses. We have investigated the alterations of cellular staining that occur in chronic hyperproliferative skin diseases and carcinomas and compared this with the staining of multilayered cultures of normal keratinocytes and the HN-5 cell line. We show that in squamous cell carcinomas and in HN-5 cell xenografts 16a and 29b stain only the well-differentiated cell types. Furthermore we found that the basal cell specificity of 16a was lost in all of the hyperproliferative skin lesions examined including psoriasis and eczema. This transition to suprabasal staining pattern was also seen in the cultures of normal keratinocytes and HN-5 cells. We conclude that aberrant keratin synthesis or abnormal post-translational processing of keratins associated with an increased rate of cell turnover could account for the altered expression of the epitope recognized by antibody 16a.

Expression of keratins and other cytoskeletal proteins in mouse mammary epithelium during the normal developmental cycle and primary culture

Mammary epithelium is composed of ductal, alveolar, and myoepithelial cells, and undergoes dramatic responses in growth, differentiation, and function to hormonal stimuli during the four stages of the mammary developmental cycle represented in virgin, pregnant, lactating, and involuting animals. To determine if progression of the epithelium through the cycle is accompanied by changes in cytoskeletal composition, particularly the keratins, the polypeptides in cytoskeletal extracts from BALB/c mouse mammary tissues were analyzed by one- and two-dimensional gel electrophoresis combined with immunoblots using polyclonal and monoclonal antikeratin antibodies. The major polypeptides in cytoskeletal fractions enriched in intermediate filaments included seven acidic and three basic components ranging in molecular weight from 40,000 to 90,000. Two major polypeptides of Mr 50,000 and 40,000, along with two minor components of Mr 57,000 and 55,000 were identified as keratins. The polypeptide profiles of mammary glands from virgin, pregnant, lactating, and involuting mice were very similar, indicating a remarkable stability of cytoskeletal composition during hormonal shifts and periods of minimal or maximal cell growth and differentiated function. The data also suggest that ductal and alveolar cells express the same set of cytoskeletal polypeptides, including keratins. Mammary cells grown in primary culture exhibited a loss or reduction in most of the basic polypeptides, a large increase in an acidic Mr 55,000 keratin, and the appearance of a prominent acidic polypeptide of Mr 46,000. The latter results demonstrate that keratin expression in mouse mammary epithelial cells is subject to regulation by certain environmental factors.

Changes in the expression of blood-group carbohydrates during oral mucosal development in human fetuses

The distribution of the blood-group antigens A, B, H type 2 (A and B precursor), and N-acetyllactosamine (H-type-2 precursor) was studied in human fetal oral mucosa from 30 fetuses. Epithelium was examined from the lip, the alveolar ridge and the hard palate in fetuses representing development from week 10-20 in utero. The blood-group carbohydrate chains were examined in tissue sections by immunofluorescence microscopy. The A- and B-blood group antigens were detected by human blood-group sera, and antigen-H type-2 chains and N-acetyllactosamine were detected by murine monoclonal antibodies. Regional differences in the expression of oral epithelial blood-group carbohydrates occurred during the fetal period. In the labial epithelium that remained unkeratinized, blood-group antigens A and B were present throughout the entire period of fetal development on the cell surface of the spinous and superficial cells, antigen H type 2 was present on parabasal cells, and N-acetyllactosamine was present on basal cells. In the epithelia of the alveolar ridge and the hard palate, the initial uniform staining for blood-group antigens A and B only occurred in the upper cell layers and changed to include a patchy reaction of single cells in the spinous cell layer. The distribution of antigen H type 2 changed simultaneously to include parabasal cells and the entire spinous cell layer.(ABSTRACT TRUNCATED AT 250 WORDS)

Distribution of epidermal growth factor receptors in rat tissues during embryonic skin development, hair formation, and the adult hair growth cycle

In a previous study on neonatal rat skin (Green MR, Basketter DA, Couchman JR, Rees DA: Dev Biol 100:506-512, 1983) a close positive correlation was found between epidermal growth factor (EGF) receptor tissue distribution and areas of potential epithelial cell proliferation. We now report on the binding distribution of [125I]EGF, representing the tissue localization of available EGF receptors, during embryonic rat skin development including hair follicle formation and the adult hair growth cycle. At 16 days embryonic development a relatively low receptor density is seen over all the epidermal cell layers but by 17 days, with the onset of very rapid epidermal proliferation, labeling increases and becomes restricted to the basal epidermal cells. Between 17 and 20 days embryonic development, available receptors for EGF are consistently absent from epidermal basal cells overlaying the dermal condensates marking the first stage of hair follicle development. This restricted and temporary loss of EGF receptors above these specialized mesenchymal condensates implies a role for the EGF receptor and possibly EGF or an EGF-like ligand in stimulating the epithelial downgrowth required for hair follicle development. In the anagen hair bulb, receptors for EGF are detected over the outer root sheath and the epithelial cell layers at the base of the follicle and show a correlation with the areas of epithelial proliferation in the hair bulb. During the catagen and telogen phases of the hair cycle, receptors are observed in high numbers on all the undifferentiated or dedifferentiating cells of the degenerating epithelial strand and secondary hair germ. Dermal cells are, in general, less heavily labeled than the basal epithelial cells of skin except for the developing striated muscle (panniculus carnosus) in embryonic skin which is more heavily labeled. The data are discussed in terms of a possible role for the EGF receptor and associated EGF or EGF-like ligands in specific areas of epithelial tissue morphogenesis during embryonic skin maturation, hair follicle development, and hair cycling.

The keratin polypeptide patterns in heterotypically recombined epithelia of skin and mucosa of adult mouse

Epithelial-mesenchymal interactions were investigated considering both morphologic criteria and keratin polypeptide expression in homotypic and heterotypic recombinants of adult mouse skin and oral mucosa. Two series of cross-recombinants of epithelia with different morphology and keratin patterns were chosen: (a) footpad epidermis/ear dermis and ear epidermis/footpad dermis; (b) palate epithelium/cheek connective tissue and cheek epithelium/palate connective tissue. Homotypic and heterotypic recombinants were prepared after EDTA-separation of the original tissues and then grown on syngeneic mice in subcutaneously prepared protected graft chambers. EDTA-separation is especially suited to completely separate the epidermal-dermal union, and the transplantation procedure used strictly prevents contamination with host epithelium. Five weeks after implantation keratins were analyzed by one and two-dimensional gel electrophoresis and peptide mapping. In both series, homotypic recombination of the tissues did not alter the original morphology and keratin polypeptide composition of the individual epithelial components. Ear epidermis displayed no significant changes in structure or keratin pattern in heterotypic recombinants. Recombined with ear dermis, footpad epidermis showed acquisition of some morphologic features typical for ear epidermis and slight changes in keratin composition which were, however, difficult to interpret due to the normal similarities of footpad keratin with that of ear. In contrast, the heterorecombinants of the palate/cheek series exhibited considerable alterations in their keratin patterns. Either epithelium showed suppression of distinct keratin subunits and de novo expression of subunits characteristic of the epithelium normally associated with the connective tissue component. The keratin patterns of both matches closely resembled each other and represented patterns intermediate between the normal patterns. This partial, however, significant modulation in the expression of differentiation markers was paralleled by similarly directed changes in the architecture of the heterotransplanted tissues, thus indicating that both morphogenesis and cytodifferentiation of certain adult epithelia can be influenced by extrinsic mesenchymal factors.

Expression of the transformation-sensitive protein "cyclin" in normal human epidermal basal cells and simian virus 40-transformed keratinocytes

A cell population highly enriched in human epidermal basal cells has been obtained and characterized by using antibodies specific for various cell types in the epidermis. Quantitative two-dimensional gel electrophoretic analysis (isoelectric focusing) of [35S]methionine-labeled polypeptides from basal cells and simian virus 40-transformed keratinocytes showed that the basal cells synthesize very low amounts (less than 0.02% of the total protein) of the nuclear, transformation-sensitive protein cyclin as compared to the transformed cells, which synthesize this protein constitutively (0.15% of the total protein). Very low levels of cyclin were observed in total human epidermis, and preliminary studies of two basaliomas have shown a significant synthesis of this protein in these tumors. Immunofluorescence studies using antibodies to proliferating cell nuclear antigen that immunoprecipitate cyclin confirmed the above observations at least in the case of the cultured cells. Taken together, these results support the notion that cyclin may be a central component of the pathway(s) that controls cell proliferation.