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

The Importance of Nanocarrier Design and Composition for an Efficient Nanoparticle-Mediated Transdermal Vaccination

The World Health Organization estimates that the pandemic caused by the SARS-CoV-2 virus claimed more than 3 million lives in 2020 alone. This situation has highlighted the importance of vaccination programs and the urgency of working on new technologies that allow an efficient, safe, and effective immunization. From this perspective, nanomedicine has provided novel tools for the design of the new generation of vaccines. Among the challenges of the new vaccine generations is the search for alternative routes of antigen delivery due to costs, risks, need for trained personnel, and low acceptance in the population associated with the parenteral route. Along these lines, transdermal immunization has been raised as a promising alternative for antigen delivery and vaccination based on a large absorption surface and an abundance of immune system cells. These features contribute to a high barrier capacity and high immunological efficiency for transdermal immunization. However, the stratum corneum barrier constitutes a significant challenge for generating new pharmaceutical forms for transdermal antigen delivery. This review addresses the biological bases for transdermal immunomodulation and the technological advances in the field of nanomedicine, from the passage of antigens facilitated by devices to cross the stratum corneum, to the design of nanosystems, with an emphasis on the importance of design and composition towards the new generation of needle-free nanometric transdermal systems.

Biomarkers of Alzheimer's disease risk in peripheral tissues; focus on buccal cells

Alzheimer's disease (AD) is a progressive degenerative disorder of the brain and is the most common form of dementia. To-date no simple, inexpensive and minimally invasive procedure is available to confirm with certainty the early diagnosis of AD prior to the manifestations of symptoms characteristic of the disease. Therefore, if population screening of individuals is to be performed, more suitable, easily accessible tissues would need to be used for a diagnostic test that would identify those who exhibit cellular pathology indicative of mild cognitive impairment (MCI) and AD risk so that they can be prioritized for primary prevention. This need for minimally invasive tests could be achieved by targeting surrogate tissues, since it is now well recognized that AD is not only a disorder restricted to pathology and biomarkers within the brain. Human buccal cells for instance are accessible in a minimally invasive manner, and exhibit cytological and nuclear morphologies that may be indicative of accelerated ageing or neurodegenerative disorders such as AD. However, to our knowledge there is no review available in the literature covering the biology of buccal cells and their applications in AD biomarker research. Therefore, the aim of this review is to summarize some of the main findings of biomarkers reported for AD in peripheral tissues, with a further focus on the rationale for the use of the buccal mucosa (BM) for biomarkers of AD and the evidence to date of changes exhibited in buccal cells with AD.

Characterization of the expression of cytokeratins 5, 8, and 14 in mouse thymic epithelial cells during thymus regeneration following acute thymic involution

The thymus is a central lymphoid organ for T cell development. Thymic epithelial cells (TECs) constitute a major component of the thymic stroma, which provides a specialized microenvironment for survival, proliferation, and differentiation of immature T cells. In this study, subsets of TECs were examined immunohistochemically to investigate their cytokeratin (CK) expression patterns during thymus regeneration following thymic involution induced by cyclophosphamide treatment. The results demonstrated that both normal and regenerating mouse thymuses showed a similar CK expression pattern. The major medullary TECs (mTEC) subset, which is stellate in appearance, exhibited CK5 and CK14 staining, and the minor mTEC subset, which is globular in appearance, exhibited CK8 staining, whereas the vast majority of cortical TECs (cTECs) expressed CK8 during thymus regeneration. Remarkably, the levels of CK5 and CK14 expression were enhanced in mTECs, and CK8 expression was upregulated in cTECs during mouse thymus regeneration after cyclophosphamide-induced acute thymic involution. Of special interest, a relatively high number of CK5⁺CK8⁺ TEC progenitors occurred in the thymic cortex during thymus regeneration. Taken together, these findings shed more light on the role of CK5, CK8, and CK14 in the physiology of TECs during mouse thymus regeneration, and on the characterization of TEC progenitors for restoration of the epithelial network and for concomitant regeneration of the adult thymus.

Structure and functions of keratin proteins in simple, stratified, keratinized and cornified epithelia

Historically, the term 'keratin' stood for all of the proteins extracted from skin modifications, such as horns, claws and hooves. Subsequently, it was realized that this keratin is actually a mixture of keratins, keratin filament-associated proteins and other proteins, such as enzymes. Keratins were then defined as certain filament-forming proteins with specific physicochemical properties and extracted from the cornified layer of the epidermis, whereas those filament-forming proteins that were extracted from the living layers of the epidermis were grouped as 'prekeratins' or 'cytokeratins'. Currently, the term 'keratin' covers all intermediate filament-forming proteins with specific physicochemical properties and produced in any vertebrate epithelia. Similarly, the nomenclature of epithelia as cornified, keratinized or non-keratinized is based historically on the notion that only the epidermis of skin modifications such as horns, claws and hooves is cornified, that the non-modified epidermis is a keratinized stratified epithelium, and that all other stratified and non-stratified epithelia are non-keratinized epithelia. At this point in time, the concepts of keratins and of keratinized or cornified epithelia need clarification and revision concerning the structure and function of keratin and keratin filaments in various epithelia of different species, as well as of keratin genes and their modifications, in view of recent research, such as the sequencing of keratin proteins and their genes, cell culture, transfection of epithelial cells, immunohistochemistry and immunoblotting. Recently, new functions of keratins and keratin filaments in cell signaling and intracellular vesicle transport have been discovered. It is currently understood that all stratified epithelia are keratinized and that some of these keratinized stratified epithelia cornify by forming a Stratum corneum. The processes of keratinization and cornification in skin modifications are different especially with respect to the keratins that are produced. Future research in keratins will provide a better understanding of the processes of keratinization and cornification of stratified epithelia, including those of skin modifications, of the adaptability of epithelia in general, of skin diseases, and of the changes in structure and function of epithelia in the course of evolution. This review focuses on keratins and keratin filaments in mammalian tissue but keratins in the tissues of some other vertebrates are also considered.

Cytoskeletal proteins in thymic epithelial cells of the Australian lungfish Neoceratodus forsteri

The vertebrate thymus consists of distinctive subpopulations of epithelial cells that contain a diverse repertoire of cytoskeletal proteins. In this study of the thymus in the Australian lungfish, Neoceratodus forsteri, immunohistochemistry was used to distinguish the cytoskeletal proteins present in each class of thymic epithelial cell. A panel of antibodies (Abs), each specific for a different cytoskeletal polypeptide (keratins, vimentin, desmin, actin and tubulins), was used on paraffin and ultrathin resin sections of thymus. Ab AE I (reactive against human type I cytokeratins (CK) 14, 16 and 19) selectively stained the cytoplasm of capsular, trabecular and the outermost epithelial cells of Hassall's corpuscles. Anti-CK 10 Abs strongly labelled the capsular epithelial cells and less than 20% of cortical and medullary epithelial cells. The anti-50-kDa desmin Ab did not react with any thymic cells, whereas the anti-53-kDa desmin Ab labelled some capsular, cortical and medullary thymic epithelial cells. The anti-vimentin Ab stained most of the capsular and ~60% of the cortical epithelium. Thymic nurse cells and Hassall's corpuscles were found to be devoid of actin, which was strongly detected in medullary and perivascular epithelium. Both alpha and beta tubulins were detected in all thymic cells. This study extends the concept of thymic epithelial heterogeneity. The complexity of thymic epithelium in N. forsteri may indicate a relationship between thymic epithelial subpopulations and the thymic microenvironment. These data identify anti-keratin Abs as a valuable tool for studying differentiation and ontogeny of the thymic epithelium in N. forsteri.

Relationship of adhesion molecules expression with epithelial differentiation markers during fetal skin development

BACKGROUND

Cadherins and integrins are important for maintenance of tissue integrity and in signal transduction during skin development. Distribution of these molecules in human skin development was investigated and associated with markers of differentiation, cytokeratins (CK) and involucrin (INV).

METHODS

Using immunohistochemistry expression of E- and P-cadherins, integrins beta-1 and -4, CK10, CK14 and INV was assessed in skin fragments of 10 human fetuses (gestational weeks ranged from 4 to 24, all weighing up to 500 g).

RESULTS

At initial phases of development, integrins beta-1 and -4 and E- and P-cadherins were present on epithelial cell membranes in all layers. CK14 and CK10 were expressed in all epithelial layers and INV weakly detected in the superficial layer. In more advanced stages, integrins were detected in all layers, but a marked polarized expression was seen in basal layer. E-cadherin was detected in all layers, but the cornified stratum and P-cadherin were observed in the lower layers. CK14 was expressed in basal layer, CK10 in suprabasal stratum and INV was observed in cornified layer.

CONCLUSIONS

Cadherins and integrins are essential for skin development, being spatially and temporally regulated. Their expression is related with the expression of maturation markers of the epidermis.

Formation of the corneous layer in the epidermis of the tuatara (Sphenodon punctatus, Sphenodontida, Lepidosauria, Reptilia)

The formation of the stratum corneum in the epidermis of the reptile Sphenodon punctatus has been studied by histochemical, immunohistochemical, and ultrastructural methods. Sulfhydryl groups are present in the mesos and pre-alpha-layer but disappear in the keratinized beta-layer and in most of the mature alpha-layer. This suggests a complete cross-linking of keratin filaments. Tyrosine increases in keratinized layers, especially in the beta-layer. Arginine is present in living epidermal layers, in the presumptive alpha-layer, but decreases in keratinized layers. Histidine is present in corneous layers, especially in the intermediate region between the alpha- and a new beta-layer, but disappears in living layers. It is unknown whether histidine-rich proteins are produced in the intermediate region. Small keratohyalin-like granules are incorporated in the intermediate region. The plane of shedding, as confirmed from the study on molts, is located along the basalmost part of the alpha-layer and may involve the degradation of whole cells or cell junctions of the intermediate region. A specific shedding complex, like that of lizards and snakes, is not formed in tuatara epidermis. AE1-, AE2-, or AE3-positive alpha-keratins are present in different epidermal layers with a pattern similar to that previously described in reptiles. The AE1 antibody stains the basal and, less intensely, the first suprabasal layers. Pre-keratinized, alpha- and beta-layers, and the intermediate region remain unlabeled. The AE2 antibody stains suprabasal and forming alpha- and beta-layers, but does not stain the basal and suprabasal layers. In the mature beta-layer the immunostaining disappears. The AE3 antibody stains all epidermal layers but disappears in alpha- and beta-layers. Immunolocalization for chick scale beta-keratins labels the forming and mature beta-layer, but disappears in the mesos and alpha-layer. This suggests the presence of common epitopes in avian and reptilian beta-keratins. Low molecular weight alpha-keratins present in the basal layer are probably replaced by keratins of higher molecular weight in keratinizing layers (AE2-positive). This keratin pattern was probably established since the beginning of land adaptation in amniotes.

Expression of cytoskeletal proteins in developing human minor salivary glands

The presence of an epithelium at different stages of proliferation and differentiation raises interesting questions concerning the histogenesis, cell turnover and differentiation of normal salivary glands. In order to expand knowledge of these aspects, we investigated the expression of cytokeratins (CKs) 7,8,10,13,14,16,18 and 19, vimentin (VIM), and smooth muscle actin (SMA) in developing human minor salivary glands using monoclonal antibodies. Labial, buccal, palatine, and lingual salivary glands and those from the floor of the mouth were obtained from human fetuses (forensic postmortem) ranging in age from gestational weeks 10 to 29. Serial sections, 3 microm thick, were immunostained using a strepto-avidin-biotin technique. Reactivity for all antibodies was negative in the salivary gland epithelium during the developmental stages of bud formation, cord growth, and branching of cord. During canalization and cytodifferentiation, the glandular epithelial cells showed a positive reaction to some CKs and SMA. Cytokeratins 7, 8, 18, and 19 showed strong labeling in luminal duct cells that exhibited some degree of morphological differentiation. Myoepithelial cellc were recognized by antibodies to SMA. Cytoskeletal protein expression changes according to the cell type, degree of differentiation, and stage of morphological development of the glandular structure. These changes occur independently of the localization of the gland.

Interferons mediate terminal differentiation of human cortical thymic epithelial cells

In the thymus, epithelial cells comprise a heterogeneous population required for the generation of functional T lymphocytes, suggesting that thymic epithelium disruption by viruses may compromise T-cell lymphopoiesis in this organ. In a previous report, we demonstrated that in vitro, measles virus induced differentiation of cortical thymic epithelial cells as characterized by (i) cell growth arrest, (ii) morphological and phenotypic changes, and (iii) apoptotis as a final step of this process. In the present report, we have analyzed the mechanisms involved. First, measles virus-induced differentiation of thymic epithelial cells is shown to be strictly dependent on beta interferon (IFN-beta) secretion. In addition, transfection with double-stranded RNA, a common intermediate of replication for a broad spectrum of viruses, is reported to similarly mediate thymic epithelial cell differentiation through IFN-beta induction. Finally, we demonstrated that recombinant IFN-alpha, IFN-beta, or IFN-gamma was sufficient to induce differentiation and apoptosis of uninfected thymic epithelial cells. These observations suggested that interferon secretion by either infected cells or activated leukocytes, such as plasmacytoid dendritic cells or lymphocytes, may induce thymic epithelium disruption in a pathological context. Thus, we have identified a new mechanism that may contribute to thymic atrophy and altered T-cell lymphopoiesis associated with many infections.

Ultrastructure of the embryonic snake skin and putative role of histidine in the differentiation of the shedding complex

The morphogenesis and ultrastructure of the epidermis of snake embryos were studied at progressive stages of development through hatching to determine the time and modality of differentiation of the shedding complex. Scales form as symmetric epidermal bumps that become slanted and eventually very overlapped. During the asymmetrization of the bumps, the basal cells of the forming outer surface of the scale become columnar, as in an epidermal placode, and accumulate glycogen. Small dermal condensations are sometimes seen and probably represent primordia of the axial dense dermis of the growing tip of scales. Deep, dense, and superficial loose dermal regions are formed when the epidermis is bilayered (periderm and basal epidermis) and undifferentiated. Glycogen and lipids decrease from basal cells to differentiating suprabasal cells. On the outer scale surface, beneath the peridermis, a layer containing dense granules and sparse 25-30-nm thick coarse filaments is formed. The underlying clear layer does not contain keratohyalin-like granules but has a rich cytoskeleton of intermediate filaments. Small denticles are formed and they interdigitate with the oberhautchen spinulae formed underneath. On the inner scale surface the clear layer contains dense granules, coarse filaments, and does not form denticles with the aspinulated oberhautchen. On the inner side surface the oberhautchen only forms occasional spinulae. The sloughing of the periderm and embryonic epidermis takes place in ovo 5-6 days before hatching. There follow beta-, mesos-, and alpha-layers, not yet mature before hatching. No resting period is present but a new generation is immediately produced so that at 6-10 h posthatching an inner generation and a new shedding complex are forming beneath the outer generation. The first shedding complex differentiates 10-11 days before hatching. In hatchlings 6-10 h old, tritiated histidine is taken up in the epidermis 4 h after injection and is found mainly in the shedding complex, especially in the apposed membranes of the clear layer and oberhautchen cells. This indicates that a histidine-rich protein is produced in preparation for shedding, as previously seen in lizard epidermis. The second shedding (first posthatching) takes place at 7-9 days posthatching. It is suggested that the shedding complex in lepidosaurian reptiles has evolved after the production of a histidine-rich protein and of a beta-keratin layer beneath the former alpha-layer.

Keratinization in the epidermis of amphibians and the lungfish: comparison with amniote keratinization

Keratinization in the epidermis of amphibians and the lungfish has been studied by electron microscopy, autoradiography and immunocytochemistry to determine whether histidine-rich proteins, filaggrin and loricrin are present. In the lungfish and amphibian tadpoles, anti-keratin antibodies (AE1 and AE3) stain the whole epidermis but not the AE2 antibody, a marker for keratinization. In adult epidermis, the AE2 antibody mainly stains keratinized layers, AE1 mainly stained basal cells, less suprabasal cells and no pre-keratinized and keratinized layers, and AE3 stains all epidermal layers. This staining pattern resembles that of amniote epidermis. Little tritiated histidine is taken up in toad epidermis at 4-6 h post-injection but 24 h after injection the radioactivity is most concentrated in the replacement layer beneath the corneus. This indicates that protein synthesis takes place in the epidermis but, due to the metabolic conversion that takes place in 24 h, it is unlikely that histidine-rich proteins are formed. Neither filaggrin-like nor loricrine-like immunoreactivities are present in amphibian and lungfish epidermis. This indicates absence of histidine-rich matrix proteins and corneous cell envelope proteins and only mucus is present among keratin filaments. Filaggrine-like and loricrin-like proteins are characteristic of amniotes epidermis and might have originated in basic amniotes (cotylosaurs).

Immunocytochemical and electrophoretic distribution of cytokeratins in the regenerating epidermis of the lizard Podarcis muralis

Using immunocytochemistry at light- and electron-microscope levels, we studied the distribution of three monoclonal antibodies (AE1, AE2, AE3) specific for mammalian alpha-keratins in regenerating lizard epidermis. We also characterized the keratins expressed during this process by immunoblotting after electrophoretic separation. The AE1 antibody is localized in the basal and suprabasal layers of prescaling and scaling epidermis. During the first stages of scale neogenesis, the AE1 antibody also marks the differentiating oberhautchen and beta-layer, but it disappears from these layers as they mature. This antibody does not stain the prekeratinized and keratinized outermost layers in the hinge region. The AE2 antibody labels the superficial wound epidermis, prekeratinizing and keratinized beta- and alpha-layers, but not basal and suprabasal cells. The AE3 antibody labels all living and keratinized epidermal layers, although AE3 immunoreactivity decreases and disappears as the beta-layer matures. The ultrastructural study shows that the AE2 and AE3, but not the AE1, antibodies specifically label small electron-dense areas within the beta-layer, suggesting retention of alpha-keratins. In the stages of tail regeneration examined, immunoblotting with the three antibodies used for the immunolocalization gives a pattern similar to that of the normal epidermis, except distally, where the process of scale differentiation begins. In this region, in addition to the keratin forms discovered in the normal and in proximal regenerating epidermis, an intense low molecular weight band at 40-41 kDa, positive to all three antibodies, is clearly detectable. Furthermore, in the distal region AE1 and AE3 antibodies, but not the AE2, recognize a weak band at 77-78 kDa not present in the normal and proximal epidermis. The localization and the possible role of the different keratins in the regenerating epidermis is discussed.

Kdap, a novel gene associated with the stratification of the epithelium

The skin develops and differentiates during embryogenesis, which is concertedly regulated by a variety of genes. The present study isolated from the rat embryonic skin a novel differentiation-associated gene named Kdap (keratinocyte differentiation-associated protein) by suppression subtractive hybridization between the skin of 14day postcoitus (dpc) embryo (the prehair-germ stage) and that of 17dpc embryo (the hair-germ stage). Its mRNA contained four spliced forms in these tissues. The gene encoded a protein of total 98 amino acids with a calculated molecular mass of 11kDa and an isoelectric point of 6.1 as an unspliced form. The two splicing zones were well conserved among rat, mouse, and human. This protein had a high hydrophobic N-terminal region, a possible signal sequence, and contained two putative N-myristoylation sites and two casein kinase II phosphorylation sites. In situ hybridization experiments detected Kdap transcripts exclusively in the suprabasal cell layers of the embryonic epidermis. Intense expression was also seen in suprabasal cells in regions of infundibulum of the hair follicle. These results indicated that Kdap provides a new insight into the mechanism of differentiation and the maintenance of stratified epithelia.

Cytokeratin expression in human fetal tongue and buccal mucosa

Expression of cytokeratins (CK), a subset of intermediate filament (IF) proteins in epithelia, is developmentally regulated. CK expression may also change after malignant transformation. Our earlier studies on CK expression in human oral tumours and pre-cancerous lesions have shown specific changes in CK expression. We analysed CK expression in human tongue and buccal mucosa (BM) in fetuses in the embryonic age group of 16 to 27 weeks using biochemical and immunohistochemical techniques to find out whether there is any similarity in CK expression in human oral squamous cell carcinomas (SCC) and fetal oral tissues. CK 1, 8 and 18 were detected in a majority of samples using both techniques. Our earlier studies had shown aberrant expression of CK 1 and 18 in many of the oral SCC and leukoplakias. Studies by immunohistochemistry showed that these different CK antigens were expressed in different cell layers. CK 1(2) were present in the stratified epithelial layers whereas CK 8 and 18 were restricted to glandular epithelium. Till 27 weeks of gestation, both tongue and BM expressed CK 1, 8 and 18 along with CK 6 and 16. Thus, fetal tissues showed some similarities in CK pattern with their respective SCC.

Effects of retinoic acid exposure in utero on mouse vibrissal follicle development

It is known that topical all-trans-retinoic acid (RA) modulates growth and differentiation of skin and its cutaneous appendages. To examine whether a pre-natal exposure to a potentially non-teratogenic dosage of all-trans-RA had any effect on vibrissal follicle development, the histologic and immunohistochemical responses to RA during its morphogenesis in NMRI mouse were investigated. After a single oral dose of 30 mg/kg body weight of all-trans-RA on day 11.5 of gestation, no fetal malformations were detected and the histological features and the distribution of keratin (K) proteins in comparable stages of vibrissal development were similar for the untreated, vehicle-treated and RA-treated mice. The absence of teratogenic response and of adverse effects on the vibrissae under the experimental conditions indicates that this protocol may be useful for investigation of the effects of pre-natal exposure to RA on the post-natal development of experimental tumours in the mouse skin.

In situ hybridization study of cytokeratin 4, 13, 16 and 19 mRNAs in human developing junctional epithelium

Cytokeratins (CKs) are now considered to be reliable markers for following the development and differentiation of epithelial tissue. We have investigated the pathway of differentiation in human developing junctional epithelium using monoclonal antibodies and two-dimensional gel electrophoresis of microdissected tissue to identify CK 19, CK 16, CK 14, CK 13, CK 6, CK 5, CK 4 in the junctional epithelium (JE) over partially erupted human teeth. The CK profile was similar to that of developing oral epithelia, suggesting that the junctional epithelium in teeth during eruption is of odontogenic origin. The present study used in situ hybridization to determine the distribution of the mRNAs of CKs 19, 16, 13 and 4 in human developing junctional epithelium and to examine the correlation between mRNAs and their encoded proteins. CK 19 mRNA was abundant in the basal cell layers of the primary junctional epithelium (PJE) but less concentrated in the suprabasal layers. CK16, 13 and 4 mRNAs were abundant in the basal cell layers of the PJE. The parabasal cell layers reacted intensely to the cRNA probe complementary to CK16 mRNA, as were the reactions in the suprabasal cell layers of the PJE for the CK 13 and 4 probes. Our results demonstrate that the PJE express the genes encoding for CKs 16 and 4 that have been revealed previously only by electrophoresis. They therefore confirm that the PJE is a well-differentiated stratified epithelium with a complex unique phenotype that produces CKs specific for basal cells (CK 19), CKs associated with hyperproliferation (CK 16), and finally those associated with stratification (CKs 4 and 13). Only synthesis of CK 19 protein and mRNA are strictly parallel. CKs 4 and 13 mRNAs are present in basal and suprasal cells, while their encoded proteins were not, except for CK 13 in suprabasal cell layers of PJE, where the amount of its mRNAs was coincident with the expression of the protein.

A set of novel tadpole specific genes expressed only in the epidermis are down-regulated by thyroid hormone during Xenopus laevis metamorphosis

Four genes were identified in a screen for thyroid hormone-induced down-regulation of gene expression in Xenopus laevis tadpole tails. All four encode extracellular glycoproteins that are expressed exclusively in the apical cell layer of the entire tadpole epidermis, which is the equivalent of the mammalian fetal periderm. The onset of the four novel genes' expression late in embryogenesis, their activity throughout the life of the tadpole, their repression by exogenously added thyroid hormone, and the spontaneous cessation of their expression at the end of tadpole life are closely coordinated. These facts suggest that the protein products of these genes form a novel albeit temporary barrier or other structure in the tadpole epidermis that functions in lieu of the cornified, stratified epithelium of the adult epidermis. We have exploited the cloning of these genes for use as cell-specific markers to follow the appearance and loss of apical cells during development. We were able to demonstrate directly that the apical cells are derived from a stratification of the embryonic ectoderm at the onset of the formation of a true epidermis. The apical cells uniformly cover the surface of the tadpole until metamorphosis, when the expression of the four larval epidermis-specific genes is lost coordinately over the entire tadpole. In contrast, the adult epidermis develops with a distinct regional specificity: adult keratin is first expressed up to a line separating the body and tail epidermis and finally appears in the tail only at metamorphic climax. Finally, our analysis reveals that the TH-induced down-regulated gene expression program during metamorphosis is very different from the previously described up-regulated program which involves multiple cell types and several waves of gene expression changes. The down-regulated program only consists of the repression of a small number of genes which are expressed in larval cells preprogrammed to die during the larval to adult transition at metamorphosis.

Gene targeting at the mouse cytokeratin 10 locus: severe skin fragility and changes of cytokeratin expression in the epidermis

Bullous congenital ichthyosiform erythroderma (BCIE) is a dominantly inherited blistering skin disorder caused by point mutations in the suprabasal cytokeratins 1 or 10. Targeting the murine cytokeratin 10 gene in ES cells resulted in mice with different phenotypes in the homozygotes and heterozygotes; both of which exhibit similarities to specific clinical characteristics of BCIE. Homozygotes suffered from severe skin fragility and died shortly after birth. Heterozygotes were apparently unaffected at birth, but developed hyperkeratosis with age. In both genotypes, aggregation of cytokeratin intermediate filaments, changes in cytokeratin expression, and alterations in the program of epidermal differentiation were observed. In addition we demonstrate, for the first time, the existence of the murine equivalent of human cytokeratin 16.

Cytokeratin expression in the developing vagina of the postnatal gerbil (Meriones unguiculatus)

During postnatal development the vaginal epithelium of the Mongolian gerbil is transformed from two to three layers into a stratified, first mucified subsequently keratinized squamous epithelium. Changes in the expression of cytokeratins were studied and the immunohistochemical results compared with the ultrastructural findings at the corresponding stage. The first 10 postnatal days (days pn) were characterized by a moderate, positive immunoreaction for pancytokeratin in all vaginal cell layers. A faint reaction was caused by mAB CK 18.01 against CK 1, 5, 6 and 8. The appearance of mucous granules in the luminal cells after 15 pn seemed to coincide with an increase in cytokeratins. The immunoresponse for pancytokeratin in these cells was very intense compared with the reaction in the basal cell layers. Mucocytes during development and at proestrus were the only cells which reacted faintly positive with mAB against CK 18 alone. The keratinizing epithelium, which differentiates after day 40 pn, reacted strongly positive for pancytokeratin in the keratinizing layers, desquamating, fully keratinized cells, however, showed a negative reaction. The data indicate that mucocytes are not transformed squamous keratinized cells, but represent a cell category with its individual differentiation potential. Vimentin was not expressed. Neither the epithelium of the sinus vagina nor of the Müllerian vagina displayed any response.

Loricrin expression is coordinated with other epidermal proteins and the appearance of lipid lamellar granules in development

In mouse, epidermal development proceeds from a single basal cell layer covered by a specialized single cell layer called the periderm at E14 to a fully differentiated stratified squamous epithelium at E18. To determine when loricrin, a major cell envelope component, is expressed during development, we examined fetal skin from mice of gestational ages E13 through E19 and compared the temporal pattern of loricrin expression with that of other differentiation markers. We found that loricrin mRNA and protein were expressed by E16, following the expression of keratins K1 and K10 and preceding the expression of profilaggrin. Interestingly, both loricrin and profilaggrin were initially expressed focally in areas corresponding to more advanced morphologic stages of maturation. Because the cornified envelope is a composite structure consisting of both protein and lipid components, we also monitored the appearance of lipid lamellar granules during epidermal development. These granules were first evident at E16 and the extrusion of lipids from the granules into the intercellular space occurred at E17, prior to the cross linking of loricrin into the cell envelope. Our results document that loricrin is expressed and accumulates at the cell periphery subsequent to the extrusion of lipids, but prior to processing of profilaggrin. We suggest that the sequential regulation of these events is critical for formation of epidermal barrier function during development.

Altered cytokeratin expression in carcinogenesis inhibition by antioxidant nutrients

Epidermoid carcinomas were induced in hamster buccal pouches with use of 7.12 dimethylbenz[a]anthracene (DMBA). In five animals that served as tumor controls (Group 1), right buccal pouches were painted with DMBA (0.5% solution in mineral oil) thrice weekly for 14 weeks. In five animals (Group 2), right buccal pouches were painted with DMBA and reduced glutathione (GSH) was administered systemically by mouth. Five animals (Group 3) received vitamin E instead of glutathione. An additional 20 animals (Groups 4, 5, 6, and 7) were untreated, vehicle, glutathione, and vitamin E controls, respectively. Glutathione and vitamin E were given in doses of 10 mg/kg in 0.5 ml of mineral oil thrice weekly on days alternate to DMBA painting. Treatment by GSH and vitamin E reduced the number and size of tumors that were formed. Histopathologically, there were also fewer sites of dysplasia, carcinoma in situ, and early invasive epidermoid carcinoma than in the tumor control animals. The formalin-fixed and paraffin-embedded buccal pouch sections were stained immunohistochemically with use of monoclonal antibodies for cytokeratins. These included high-molecular-weight keratins (50,000-68,000 mol wt) 10, 13, and 8 (k10, k13, and k8, respectively). Oral carcinomas and dysplastic sites exhibited basal and suprabasal (spinous layer) high levels of k10, k13, and k8 staining. Treatment with GSH or vitamin E increased the suprabasal staining for high-molecular-weight keratins and reduced the protein expression for k10, k13, or k8. This pattern of staining was observed in dysplastic as well as in carcinoma sites. These results indicate that cytokeratin protein expression could contribute to a common biomarker analysis for chemoprevention.

Programming gene expression in developing epidermis

As the major proteins of adult keratinocytes, keratins provide biochemical markers for exploring mouse epidermal embryogenesis. Here, we used a modified method of whole-mount in situ hybridization to track skin-specific expression of endogenous keratin mRNAs throughout embryogenesis. To monitor transcriptional regulation, we coupled this with beta-galactosidase expression of a human epidermal keratin promoter-driven transgene. These studies have radically changed our perception of how the program of gene expression becomes established during epidermal development. Specifically, we have discovered that (1) basal keratin (K5 and K14) genes are first detected at E9.5 in a highly regional fashion, and surprisingly as early as the single layered ectodermal stage; (2) the early patterns do not correlate with morphogenesis per se, but rather with regional variations in the embryonic origin of underlying mesenchyme, supporting morphogenetic criteria that early inductive cues are mesenchymal; (3) epidermal keratin genes are expressed in periderm, supporting the notion that this layer arises from ectodermal stratification, even though it is simple epithelial-like in morphology and is subsequently sloughed during development; (4) later embryonic patterns of K5 and K14 gene expression parallel proliferative capacity and not stratification; and (5) K1 and K10 mRNAs are first detected as early as E13.5, and their patterns correlate with differentiation and not stratification. These patterns of epidermal gene expression led us to explore whether potential transcriptional regulators of these genes are expressed similarly. We show that AP2 (but not Sp1) cRNAs hybridize in a pattern similar to, but preceding that of basal keratin cRNAs. Finally, using gene expression in cultured cells, we demonstrate that AP2 has a strong inductive effect on basal keratin expression in a cellular environment that does not normally possess AP2 activity.

Cytokeratin profile of the junctional epithelium in partially erupted teeth

This study uses cytokeratins (CK) as markers to investigate the phenotype of the junctional epithelium (JE) in partially erupted human teeth. The gingival samples, which were clinically healthy, were carefully dissected from the teeth. Cryostat sections were cut for histological staining, immunofluorescence microscopy and gel electrophoresis. Cytokeratins were extracted after microdissection. The basal and suprabasal epithelial cell markers, cytokeratins 4, 5, 13, 14 and 19 were detected with specific monoclonal antibodies. They showed that the junctional epithelium in erupting teeth has a complex topography. The cytokeratin immunohistochemical profile distinguished between the primary junctional epithelium (CK 5, 14 and 19 in basal and suprabasal cells and CK 13 faintly stained throughout the suprabasal layers) and the adjacent epithelium that had the same cytokeratin profile as the sulcular epithelium (CK 5, 14 and 19 in basal cells and CK 4 and 13 intensively stained in the suprabasal cells). Extraction, two-dimensional electrophoresis and western blotting showed that this transitional JE during eruption also contained CK 6, 16 and perhaps CK 4. Thus, the JE in erupting teeth shows patterns of CK distribution that are very similar to that of developing oral epithelia.

Dynamic expression patterns of tenascin, proteoglycans, and cell adhesion molecules during human hair follicle morphogenesis

The development of skin appendages such as hair, feathers, and teeth is brought about by reciprocal interactions between epidermal and mesenchymal tissues and is thought to be influenced in part by cell adhesion molecules and components of the extracellular matrix. The developmental distributions of tenascin, neural cell adhesion molecule (NCAM), E-cadherin, intercellular adhesion molecule 1 (ICAM-1), chondroitin sulfate proteoglycan (CSPG), and the heparan sulfate proteoglycan perlecan were studied in relation to hair follicle morphogenesis in fetal human skin. Tenascin first appeared in developing skin in focal concentrations at the epidermal-mesenchymal interface, just prior to, and presumably correlated with, hair follicle initiation. Tenascin immunostaining remained prominent in the basement membrane zone and extracellular matrix of the follicle sheath during subsequent morphogenetic stages. Two forms of tenascin (M(r) 250 x 10(3) and 280-300 x 10(3)), were revealed by Western blots of skin extracts. NCAM immunolabeling was initially present throughout the dermis, and became progressively restricted to the dermal condensation and the follicle sheath. Western blot analysis revealed an isoform of NCAM (M(r) 160 x 10(3)) which lacked polysialic acid. At all stages, E-cadherin staining was diminished on follicle cells situated adjacent to the basement membrane, relative to cells in the follicle interior. Follicle-specific immunostaining for ICAM-1 was transient, appearing only at the pre-germ and hair germ stages of development. Antibodies to three distinct CSPG determinants revealed unique immunolabeling patterns following follicle initiation: One CSPG epitope co-distributed with tenascin in the follicle basement membrane and follicle sheath extracellular matrix; one CSPG epitope was similarly expressed, and was also found on follicle epithelial cells; and the third CSPG determinant was noticeably absent from the follicle sheath during elongation of the developing appendage. Perlecan was concentrated in the dermal papilla, in addition to its distribution in all skin basement membranes. A model for how these diverse molecules may interact to influence human hair follicle morphogenesis is presented.

Multiple gap junction genes are utilized during rat skin and hair development

The expression of four different gap junction gene products (alpha 1, beta 1, beta 2, and beta 3) has been analysed during rat skin development and the hair growth cycle. Both alpha 1 (Cx43) and beta 2 (Cx26) connexins were coexpressed in the undifferentiated epidermis. A specific, developmentally regulated elimination of beta 2 expression was observed in the periderm at E16. Coinciding with the differentiation of the epidermis, differential expression of alpha 1 and beta 2 connexins was observed in the newly formed epidermal layers. alpha 1 connexin was expressed in the basal and spinous layers, while beta 2 was confined to the differentiated spinous and granular layers. Large gap junctions were present in the basal layer, while small gap junctions, associated with many desmosomes, were typical for the differentiated layers. Although the distribution pattern for alpha 1 and beta 2 expression remained the same in the neonatal and postnatal epidermis, the RNA and protein levels decreased markedly following birth. Hair follicle development was marked by expression of alpha 1 connexin in hair germs at E16. Following beta 2 detection at E20, the expression increased for both alpha 1 and beta 2 in developing follicles. A cell-type-specific expression was detected in the outer root sheath, in the matrix, in the matrix-derived cells (inner root sheath, cortex and medulla) and in the dermal papilla. In addition, alpha 1 was specifically expressed in the arrector pili muscle, while sebocytes expressed both alpha 1 and beta 3 (Cx31) connexin. beta 1 connexin (Cx32) was not detected at any stage analysed. The results indicate that multiple gap junction genes contribute to epidermal and follicular morphogenesis. Moreover, based on the utilization of gap junctions in all living cells of the surface epidermis, it appears that the epidermis may behave as a large communication compartment that may be coupled functionally to epidermal appendages (hair follicles and sebaceous glands) via gap junctional pathways.

Changes in cytokeratin expression during the development of the human oral mucosa

The changes in cytokeratin expression by the developing oral mucosa of 10 to 23-week-old human fetuses were studied by indirect immunofluorescence using a panel of 15 monoclonal antibodies. The lining and masticatory mucosae were incompletely differentiated in 10-wk fetuses, since they expressed identical patterns of cytokeratins (CK 4, 5, 8, 13, 18, 19 and probably CK 14, 16, 17) very similar to that of adult alveolar mucosa. The main difference was the presence of cytokeratins 8, 18 and 19 in embryonic tissues. Cytokeratins 1, 2, 10 and 11 began to appear in gingival and hard palate epithelium from wk 11, predicting the differentiation of the masticatory mucosa by wk 16. The patterns of cytokeratin expression in the 23-wk fetus in the lining and masticatory mucosae appear to be different. In lining mucosa, the only difference from the 10th wk is a decrease in cytokeratins 8, 18 and 19, whereas the pattern of cytokeratin expression in masticatory mucosa (CK 1, 2, 4, 5, 8, 10, 11, 13, 18, 19 and probably CK 14, 16 and 17) is now very near that of adult gingiva. This pattern appears, as in the adult, to be similar to that of the epidermis in the same period.

Simple epithelial cytokeratin-expression in seborrheic keratosis

The cytokeratin expression of seborrheic keratosis was studied by means of immunohistochemistry and compared with that of normal human skin. The following findings were obtained in seborrheic keratosis: (1) a partial lack of high molecular weight cytokeratin (#1/68 kD, #10/56.6 kD) in all ten cases examined; (2) the detection of cytokeratin typical for simple epithelia (#8/52.5 kD, #18/45 kD, #19/40 kD) in eight of ten cases; and (3) the detection of cytokeratin #5/58 kD in suprabasal cells in 5 of 10 cases. An immunoelectron-microscopic investigation, using an anti-keratin antibody against cytokeratin #19/40 kD, revealed a whirl-like arrangement of keratin filaments within immunoreactive cells, in contrast to a linear, parallel arrangement in non-immunoreactive cells. Cells known to express cytokeratin typical for simple epithelia, such as sweat gland cells or Merkel cells, were not observed. The altered cytokeratin gene-expression in seborrheic keratosis may be attributable to de-differentiation of tumor cells or potential re-differentiation towards embryonic keratinocytes.

Marjolin's ulcer: immunohistochemical study of 17 cases and comparison with common squamous cell carcinoma and basal cell carcinoma

Formalin-fixed, paraffin-embedded biopsy specimens of 17 cases of squamous cell carcinoma of Marjolin's ulcer (SCC-MU), 6 cases of common SCC (SCC), and 5 cases of basal cell carcinoma (BCC) were stained with three monoclonal antikeratin antibodies (CAM 5.2, MAK-6, and MA-903), a monoclonal antivimentin antibody (V9), and a polyclonal anticarcinoembryonic antigen antiserum (A115). Neoplastic cells of SCC-MU, SCC, and BCC showed consistently negative staining for CAM 5.2. A wide range of reactivity, from negative to diffuse strong positivity, among neoplastic cells of SCC-MU and SCC was noted with MAK-6. Alternatively, neoplastic cells of SCC-MU, SCC, and BCC consistently showed diffuse moderate to strong reactivity with MA-903. These findings imply that SCC-MU has largely high-molecular-weight keratins. They also showed a wide range of reactivity with V9. However, neoplastic cells of five of the six SCC and five cases of BCC were negative for V9. These findings suggest that neoplastic cells of SCC-MU contain vimentin in higher frequency than in the more usual SCC.

Spatial, temporal, and hormonal regulation of epidermal keratin expression during development of the frog, Xenopus laevis

To study the mechanism of hormone-induced keratin expression in the epidermis during Xenopus metamorphosis, a monospecific antibody was raised against a unique carboxy-terminal peptide of the 63-kDa keratin. Immunohistological analysis demonstrated that the onset of 63-kDa keratin expression showed distinct regional and temporal differences. The expression started at stage 54 in the hindlimb epidermis, at stage 57 in the head, and over 1 month later at stage 63 in the tail. The amount of 63-kDa keratin was further regulated during epidermal stratification and differentiation. The 63-kDa keratin was expressed first in basal epidermal cells before stratification began. The outer layer of the larval epidermis (periderm) did not express the 63-kDa keratin. As the cells moved out of basal layer, they stained more intensely with the anti-keratin antibody indicating that 63-kDa keratin synthesis is up-regulated during differentiation. Similar results were obtained with cultures of purified epidermal cells grown in high calcium conditions. Since we have shown that thyroid hormone (T3) induces 63-kDa keratin gene expression and hydrocortisone (HC) modulates T3 action we examined the effects of T3 and HC at the single cell level with the anti-keratin antibody. Immunostaining demonstrated that T3 alone and T3 plus HC increased the number of 63-kDa keratin-positive cells as well as the amount of 63-kDa keratin per cell. Unexpectedly these hormones had the same effects on head and tail epidermal cells even though the latter cells degenerate during metamorphosis. The major difference between tail and head cells was that the percentage 63-kDa keratin-producing cells was much greater in the head than in the tail.

Growth of sebaceous cells in monolayer culture

Rat preputial cells were grown in an epithelial cell primary monolayer culture system identical to that used for culturing epidermal cells, which were studied for comparison. Despite similar appearance when observed by phase contrast microscopy, other features identified the preputial cells as a unique epithelial cell population. Preputial cells grew as a relatively small number of large colonies, formed domes before confluence, and expressed a specific acinar keratin, K4, which had previously been found in human sebaceous glands. In addition, preputial cells formed fewer cornified envelopes than epidermal cells, too few to discern the reduction of envelope formation by retinoic acid treatment in vitro which was found in epidermal cells. Rat preputial cells in monolayer culture, therefore, are a promising model for studying the effects of hormones on sebaceous cell growth and differentiation.

Cytokeratin expression in adrenocortical neoplasia: An immunohistochemical and biochemical study with implications for the differential diagnosis of adrenocortical, hepatocellular, and renal cell carcinoma

The immunostaining patterns of adrenocortical tumors are not clearly defined, primarily due to their inconsistent expression of cytokeratins (CK). To address this issue and to investigate whether adrenocortical tumors can be immunohistochemically differentiated from histologically similar tumors arising from the kidney and liver, we studied four normal adrenal glands, two adrenocortical adenomas (ACAs), 31 adrenocortical carcinomas (ACCs), 37 renal cell carcinomas (RCCs), and 33 hepatocellular carcinomas (HCCs) with anti-CK antibodies AE1, CAM 5.2, UCD/PR10.11, 35BH11, PKK1, and Ks19.1, as well as antibodies to vimentin (VIM), epithelial membrane antigen (EMA), and HMFG-2. Normal adrenal cortical cells showed variable staining with all anti-CK antibodies on fixed and frozen sections. In contrast, only one of two fixed ACAs stained with a single anti-CK, although both neoplasms reacted with multiple anti-CK antibodies on frozen sections. Similarly, 20 of 31 fixed ACCs contained VIM, but only one tumor stained for CK; frozen sections of this and another, previously negative tumor, however, stained with most of the anti-CK antibodies tested. One-dimensional Western immunoblot analysis confirmed the presence of CKs 18 and 19 in two examples of normal adrenal cortex, one ACA, and the ACC immunohistochemically positive on fixed and frozen sections, with CK 19 identified in the ACC that was positive on frozen section alone. All fixed HCCs and most RCCs stained with multiple anti-CK antibodies (33 and 34 cases, respectively), with a proportion of tumors positive for VIM (six and 22 cases, respectively), EMA (seven and 30 cases, respectively), and HMFG-2 (15 and 28 cases, respectively). The results suggest that CK expression is diminished in most adrenocortical tumors to levels too low to be recognized following the deleterious effects of fixation. While the immunohistochemical absence of CK, EMA, and HMFG-2 in fixed sections in the majority of ACCs is distinctive, sufficient phenotypic overlap exists such that differentiation between RCC and HCC may not be possible in an individual case.

Altered expression of proliferation and differentiation markers in human papillomavirus 16 and 18 immortalized epithelial cells grown in organotypic culture

The patterns of expression of keratins K1 and K8, filaggrin, and the proliferation-associated protein, proliferating cell nuclear antigen (PCNA), were studied in normal and human papillomavirus (HPV) 16 or 18 immortalized keratinocyte cell lines grown on organotypic raft cultures. Normal keratinocytes produced an epithelial sheet that closely resembled epidermis in vivo, characterized by lack of K8 expression, PCNA expression restricted to the basal layer, and K1 and filaggrin expression in the suprabasal layers. Although morphologically abnormal in many respects, some HPV-immortalized cell lines produced cornified epithelial layers and approximated the normals in their patterns of expression of keratins and filaggrin. Other HPV-immortalized cell lines produced poorly differentiated epithelial layers that were characterized by loss of filaggrin expression, and the single tumorigenic cell line, 18-11, was distinguished by abundant K8 expression. All of the HPV-immortalized cell lines were distinguished from normal keratinocytes by a common pattern of full-thickness PCNA expression in the epithelial layers they produced, suggesting that maintenance of the proliferative state may be an important contribution made by HPV 16 or 18 sequences toward the production of a malignant phenotype.

Expression of cytokeratin polypeptides during development of the rat inner ear

The expression of cytokeratin polypeptides in the different epithelia of the developing inner ear of the rat from 12 days post conception to 20 days after birth was analysed immunohistochemically, using a panel of monoclonal antibodies. Throughout the development of the complex epithelial lining of the inner ear originating from the otocyst epithelium, only cytokeratins which are typical of simple epithelia were expressed. Cytokeratins 8, 18, and 19 were detectable shortly after the formation of the otocyst from the ectoderm (12 dpc), whereas cytokeratin 7 expression was delayed and first appeared in the vestibular portion and subsequently in the developing cochlear duct. During the development of the different types of specialized cells, differentiation-dependent modulation of the cytokeratin expression patterns was observed. In the mature inner ear, the specialized cell types displayed a function-related cytokeratin expression profile, both in the cochlear and vestibular portion. Cytokeratin expression in the flat epithelium of the vestibular portion suggests a more complex composition of this epithelium than has been established from routine morphology. Remarkably, the cochlear sensory cells were apparently devoid of cytokeratins, but no final conclusion could be drawn on the presence of cytokeratins in the sensory cells of the vestibular portion, because of the difficulty to delineate the cell borders between sensory cells and supporting cells.

Keratins in the developing olfactory epithelia

At embryonic day 14, the supporting cells of the olfactory epithelium already contained tonofilaments which terminated in the desmosomes, and were stained by antikeratin antibodies of RGE53 and MA902, indicating the presence of 45 and 52.5 kDa keratins. The basal cells were identified at postnatal day 1 by the appearance of a few filaments, and stained by PKK2 antikeratin antibody which reacts with 40, 46, 48, and 54 kDa keratins, and by CKB1 antikeratin antibody which reacts with 50 kDa keratin. At postnatal day 14, the basal cells possessed densely aggregated bundles of filaments and reacted with KL1 and MA902 antikeratin antibodies, indicating the appearance of 56 and 52.5 kDa keratins. The basal cells showed a columnar or pyramidal shape changing into a flat shape during postnatal development. The olfactory cells remained unstained by antikeratin antibodies throughout their development.

Immunohistochemical demonstration of keratin in ameloblastoma as an indication of tumor differentiation

Keratin expression was studied immunohistochemically in 27 ameloblastomas using polyclonal antibody against wide-spectrum keratins (TTL) and monoclonal antibodies against lower- and higher-molecular-weight keratins (PKK1 and KL1), respectively, to clarify the tumor differentiation. Reactions with TTL and KL1 antibodies were generally positive in the stellate cells of the follicular or acanthomatous ameloblastomas. Cell nests of the basal cell type were positive for PKK1. On the other hand, the reactions with TTL or KL1 in the plexiform type were generally weak or absent. From these facts, it was concluded that the follicular, as well as acanthomatous, ameloblastoma is liable to undergo squamous differentiation, whereas the plexiform ameloblastoma remains in primitive stage of tumor differentiation.

Expression of low molecular mass cytokeratins in oocytes of Schistosoma mansoni

We studied the distribution of acidic 45 kDa keratin 18 and 40/42 kDa keratin 19 in Schistosoma mansoni, a trematode of medical importance in many tropical regions. The monoclonal antibodies which were produced against the cytoskeleton of mammary carcinoma cell line BT-20 recognized cytokeratins preferentially in parasite oocytes. As has been described in mammalian oocytes, the acidic cytokeratins were present in a nonfibrillar form. The two monoclonal antibodies also recognized testicular cells. No keratin immunoreactivity could be demonstrated by immunofluorescence microscopy at the larval stage, the miracidium. In immunoblotting, the molecular mass as determined by SDS-polyacrylamide gel electrophoresis of schistosome cytokeratins was about 15 kDa higher than that of the corresponding cytokeratins recognized by the monoclonal antibodies in BT-20 cells. The results suggest that acidic low molecular mass cytokeratins in trematodes have a phylogenetically conserved major function in oocytes which is unrelated to the documented cytoskeletal role in differentiated mammalian epithelial cells.

Monoclonal antibodies to two different epitopes in a 30-kD CNBr peptide of the K1 and K2 keratins

Two anti-keratin monoclonal antibodies, Kab-2 and Kab-3, with specificities for different epitopes of type II (basic) human epidermal keratins, were produced. These antibodies had different immunofluorescent staining patterns on human fetal epidermis. Western blots and solid phase RIA showed both antibodies bound to 65-67-kD basic keratins (K1 and K2) extracted from foreskin epidermis. Competitive binding studies with the two Kab antibodies and other anti-keratin monoclonal antibodies showed that Kab-2 and Kab-3 recognized related epitopes, distinct from the epitopes recognized by other anti-keratin antibodies AE-1, 2, and 3. Kab-2 and Kab-3 epitopes were distinguished by differences in their reactivity with peptides generated by Staphylococcus aureus V8 protease digestion of the K1 keratin; the antibodies recognized both common and unique peptides. Western blots of cyanogen bromide digests of the K1 keratin showed that both Kab antibodies reacted with a 30-kD fragment of the molecule presumed to be the N-terminal CNBr peptide. We interpret these data to indicate that in tissues, portions of the N-terminal region of the K1 keratin are differentially available for reaction with these monoclonal antibodies and that morphologic differences in staining with monoclonal antibodies to the same molecule can reflect epitope specificity or epitope availability related to supramolecular organization.

Three distinct keratinocyte subtypes identified in human oral epithelium by their patterns of keratin expression in culture and in xenografts

We have characterized the cells that form the human oral epithelia by analyzing their patterns of keratin expression in culture and in transplants. Keratinocytes of all oral regions synthesized high levels of keratins K5/K14 and K6/K16,K17, as expressed by cells of all stratified squamous epithelia in culture. However, cells from different regions varied in their expression in culture of retinoid-inducible (K19 and K13) and simple epithelial (K7, K8 and K18) keratins. By these criteria, all oral cells could be classified as belonging to one of three intrinsically distinct subtypes: "keratinizing" (gingiva, hard palate), "typical nonkeratinizing" (inner cheek, floor of mouth, ventral tongue) and "special non-keratinizing" (soft palate), all of which differed from the epidermal keratinocyte subtype. Cells from fetal floor of mouth expressed a pattern of keratins in culture markedly different from that of adult floor of mouth cells but identical to that of the adult "special nonkeratinizing" subtype and similar to that of several oral squamous cell carcinoma lines. When cultures of oral keratinocytes were grafted to the dermis of nude mice, they formed stratified epithelial structures after 10 days. In some areas of the stratified structures, the basal layer recapitulated the K19 expression pattern of the oral region from which they had originated. Thus, regional differentiation of the oral epithelium is based on an intrinsic specialization of regional keratinocyte stem cells. Additionally, oral cell transformation either frequently involves reversion to the fetal keratin program or else oral cells that express this keratin program are especially susceptible to transformation.

An immunocytochemical study of keratin reactivity during rat odontogenesis

The cytokeratin distribution in the developing rat enamel organ from day 15 of gestation through to 11 days post partum was examined immunohistochemically using a panel of monoclonal antibodies. A temporo-spatial programme of keratin expression was observed during odontogenesis and positive reactivity of the enamel organ was seen with the pan keratin antibodies CK1 (clone LP34 - reacts with a number of keratins including 6 and 18) and AE1-3 (reacts with most acidic and basic keratins). No reactivity was observed in the enamel organ with the other antibodies examined (Ks 8.12 [reacts with keratins 13 and 16], Ks 8.60 [reacts with keratins 10 and 11) and MCA157 [reacts with rat liver antigen]), although these antibodies did stain other epithelial tissues. This study supports the view that the epithelial cells of the enamel organ synthesize a tissue-specific subset of keratins which are related to the differentiation of the cells.

Alveolar epithelial cell keratin expression during lung development

Defining the expression and organization of keratins has provided insight into epithelial cell differentiation during tissue development and remodeling. We have used monoclonal antibodies to examine keratin distribution in lung epithelial cells in the rat from the preglandular phase of gestation to the adult. Of particular interest were the distributions of keratin No. 18 and keratin No. 19, since previous results have suggested these keratins may be important in alveolar epithelial cell transitions occurring in adult remodeling lung and in cultured type II cells. The epithelial tubes at 15 days of gestation do not react with 24A3 monoclonal antibody to keratin No. 18, nor is this antigen apparent by gel or immunoblot analysis. Staining is apparent at day 16, however, showing a light punctate pattern at the basal edge of the cells, and becomes prominent by day 17, with intensity greatest in the larger airway tubes. The intensity and number of cells in the parenchyma staining with 24A3 peaks at postnatal days 5 to 10, when proliferation and cytodifferentiation of type I and type II cells is most active. In the adult, staining of type II cells is present mainly at the cell periphery, and occasional reactive attenuated type I-like cells can be observed. Keratin No. 19 immunoreactivity is not present in the primitive epithelial tube until 19 days' gestation but predominantly stains type II pneumocytes in the adult rat lung throughout the entire cell. AE3 antibody to basic keratins stains similarly to keratin No. 19. We conclude that keratin No. 18 is expressed at high levels in type II cells during development in periods of intense proliferation and alveolarization. This correlates with our previous observations on keratin expression following bleomycin lung injury.

Human oral epithelial cell culture. II. Keratin expression in fetal and adult gingival cells

Epithelial cells from human fetal and adult gingiva were cultured in keratinocyte growth medium (KGM), a serum-free medium. The expression of keratin proteins in these cells was evaluated using immunohistochemistry and SDS-PAGE-immunoblot analysis and compared with expression in the tissue. Keratins 5, 6, 14, 16, and 19 were identified in cells cultured from both fetal and adult tissues. K19 was localized in basal cells of fetal oral tissue but was not seen in adult gingiva (except for scattered Merkel cells). K1 and K10 were expressed in tissue, but not in cultured cells. The keratin profiles of cultured epithelial cells from several adult donors were similar and were identical in cultures from primary through Passage 5. K13, a differentiation-specific keratin, was expressed in all suprabasal cells of fetal oral epithelium, but shows only spotty expression in adult gingival tissue. K13 was expressed in cultures of fetal cells, but very weakly or not at all in cultures of adult cells. K13 expression was greater in cultures grown with physiologic calcium concentrations (1.2 mM) than in those grown at 0.15 mM or less. Our findings are consistent with basal-like characters of these cells in 0.15 mM calcium growth conditions. Differentiation of fetal oral cells in culture to the suprabasal basal cell stage in 1.2 mM Ca2+ is shown by the expression of K13.

Expression of the 43 kDa papain inhibitor during human fetal skin development

The presence of the 43 kDa papain inhibitor protein in the skin of 40 fetuses with the gestational age varying from 9 to 40 weeks was studied. Immunohistochemistry showed the first evidence of the 43 kDa papain inhibitor in the acral parts, mostly in the nail bed, at the 14th week when the epidermis in all other sites was not stained. Staining of the follicular infundibulum as well as some parts of the uppermost epidermis and keratin layer was observed from 17 to 40 weeks. The staining was most intensive at 20-30 weeks gestational age, and later the intensity gradually decreased so that in the full-term newborn the 43 kDa papain inhibitor was hardly detectable or absent. It was concluded that the 43 kDa papain inhibitor is present in fetal skin at the stage of stratification (9-14 weeks) only in the nail region and its volar surroundings. It appears at the stage of interfollicular keratinization (14-24 weeks) in the uppermost epidermis, especially in the appendical openings and its amount seems the decrease during the stage of interfollicular keratinization (24 weeks--full-term). The expression of 43 kDa inhibitor protein is temporally related to that of filaggrin.

Keratin filaments of epithelial and taste-bud cells in the circumvallate papillae of adult and developing mice

Keratin filaments of epithelial- and taste-bud cells in the circumvallate papillae of adult and developing mice were studied by immunocytochemistry using monoclonal antikeratin antibodies (PKK2 and PKK3) and by conventional electron microscopy. Elongated cells (type-I, -II, and -III cells) of the taste buds were stained by PKK3 antibody, which reacts with 45-kdalton keratin, whereas basal cells of the taste buds and surrounding epithelial cells showed negative staining with PKK3. Such PKK3-reactive cells occurred at 0 day after birth, when taste-buds first appeared in the dorsal surface epithelium of the papillae. Thus 45-kdalton keratin seems to be an excellent immunocytochemical marker for identifying taste-bud cells. Epithelial cells in all layers of the trench wall and basal layer cells of the dorsal surface contained densely aggregated bundles of keratin filaments that reacted with PKK2 antibody, but not with PKK3. In contrast, taste-bud cells and spinous and granular layer cells of the dorsal surface possessed loose aggregated bundles of filaments that reacted with PKK3, but not with PKK2. These results suggest that the aggregation and distribution pattern of keratin filaments may reflect differences in the keratin subtypes that comprise these filaments.

Cytogenetic studies of esophageal carcinoma cell lines

Although the incidence of cancer of the esophagus is low in the United States, the prognosis of patients with this malignancy is poor, especially when metastases exist. More research concerning the biological characteristics of this tumor is necessary to permit more effective treatment and to determine the etiology. We successfully studied cytogenetically 14 short- and long-term cell lines derived from esophageal carcinoma to determine whether these tumors have nonrandom, unique chromosomal abnormalities. Our results showed that the tumor cells had chromosome numbers clustering around a modal number that varied according to the cell line. The presence in the primary explant of extensive numerical and structural abnormalities involving every chromosome including the sex chromosomes indicate that these abnormalities occur early in the malignant cells. The chromosomes most frequently involved in the structural abnormalities were 1, 9, and 11, each occurring in 13 of the 14 lines, and of three found in 12 of the 14 lines. The major aberrations resulted in deletions of portions of these chromosomes. The most frequent breakpoints for these abnormalities occurred at 3p14, 11q11q12; and 9q11q12 as well as in the centromeric regions of all the acrocentric chromosomes. Another unusual chromosomal marker found in three lines (HCE-1, HCE-3, and HCE-5) was a homogeneously staining region (HSR) that occurred as an extension on 11q12.

Cytokeratin patterns in the epidermis of human ovarian mature cystic teratomas

Using a battery of monoclonal antibodies, we investigated the cytokeratin pattern in the epidermides of 12 human ovarian mature cystic teratomas (MCTs) and compared them with those of infant, adult, and fetal skin. Histologically, two types of epidermal layers were identified in the MCTs, a mature layer and an immature layer. The mature layer was similar to the epidermis of infants and adults, while the immature layer resembled stratified nonkeratinizing and metaplastic squamous epithelium. The cytokeratin pattern of the histologically mature epidermis in MCT was either similar to that in infants and adults or was of the fetal type. The cytokeratin expression of the histologically immature epidermis in MCT also showed many similarities to the fetal cytokeratin pattern. We conclude that histologic maturity of the epidermis in MCT is not necessarily expressed by the cytokeratin pattern, which reflects the state of molecular rather than histologic differentiation. Since prognosis in germ cell tumors is usually related to the degree of tissue maturation, our observations raise the possibility that the cytokeratin profile may eventually prove to be a valuable prognostic tool in some of the neoplasms that contain epithelial elements.

A monoclonal antibody that defines basal cells of stratified epithelia in various human and rabbit tissues

Monoclonal antibodies were produced against monkey lung lavage fluid by using a mouse hybridoma technique. One monoclonal antibody, KP8D4, specifically reacted with basal cells in human bronchial epithelia by immunohistological staining of acetone-fixed, frozen sections and it recognized a protein with an apparent molecular weight of 84000, as determined by gel immunoblotting. The distribution of this protein was immunohistochemically examined in various human tissues (lung, tongue, esophagus, stomach, intestine, liver, pancreas, salivary gland, spleen, thymus, heart, aorta, vena cava, prostate, breast, kidney, urinary bladder, thyroid, brain, skin, striated muscle) and various tissues of rats, rabbits and pigs. The results showed a specific affinity of KP8D4 to basal cells of stratified epithelia in the various human and rabbit tissues. This antibody may be a useful tool for studies of normal development and diverse pathological disorders.

A new look into an old problem: keratins as tools to investigate determination, morphogenesis, and differentiation in skin

We have investigated keratin and keratin mRNA expression during (1) differentiation of stem cells into epidermis and hair follicles and (2) morphogenesis of follicles. Our results indicate that a type I keratin K14 is expressed early in embryonal basal cells. Subsequently, its expression is elevated in the basal layer of developing epidermis but suppressed in developing matrix cells. This difference represents an early and major biochemical distinction between the two diverging cell types. Moreover, because expression of this keratin is not readily influenced by extracellular regulators or cell culture, it suggests a well-defined and narrow window of development during which an irreversible divergence in basal and matrix cells may take place. In contrast to K14, which is expressed very early in development and coincident with basal epidermal differentiation, a hair-specific type I keratin and its mRNA is expressed late in hair matrix development and well after follicle morphogenesis. Besides providing an additional developmental difference between epidermal and hair matrix cells, the hair-specific keratins provide the first demonstration that keratin expression may be a consequence rather than a cause of cell organization and differentiation.

Patterns of expression of trichocytic and epithelial cytokeratins in mammalian tissues. III. Hair and nail formation during human fetal development

Cells forming hair and nail material are characterized by the synthesis of members of a particular group of alpha-keratin polypeptides (trichocytic cytokeratins. "T cytokeratins") different from epithelial cytokeratins ("E cytokeratins"). As the precursor cells to trichocytes are derived from fetal epidermal keratinocytes expressing only E cytokeratins, we have studied the patterns of expression of both T and E cytokeratins in developing human hair-and nail-forming tissues of different fetal stages, by immunocytochemistry using antibodies specific for certain T or E cytokeratins and by two-dimensional gel electrophoresis and immunoblotting. In developing hair follicles up to the early bulbous-peg stage (weeks 12-15 of gestational age), only certain E but no T cytokeratins were identified. T cytokeratins were first detected in the late bulbous-peg stage (in week-14 scalp skin) in certain cells of the central part of the hair cone. In hair-producing follicles (weeks 18-25), the lower hair matrix cells were positive for certain E cytokeratins, whereas T cytokeratins appeared in the uppermost portion of the matrix and, most prominently, in the maturing trichocytes. From the late bulbous-peg stage on. E cytokeratin antibody Ks13.1 selectively decorated the inner root sheath. In finger nail "anlagen", T cytokeratins were detected first in week 12 and 13 fetuses, specifically in cells of the lunula region. In more-advanced stages of nail formation, expression of T cytokeratins extended not only to the upper layers of the ventral nail matrix but was also found, albeit more sparsely, in cells of the whole nail-bed epithelium. Throughout these developmental stages, coexpression of T and E cytokeratins was noted in certain cells, including E cytokeratin 19. While in earlier stages E cytokeratins 10/11, characteristic of epidermal-type cornification, were noted in different regions, including the superficial stratum of the nail bed epithelium, they were later restricted to the epithelium of the proximal nail fold. The results show that terminal trichocytic differentiation starts, both in ontogeny and during the steady growth of hairs and nails, in cells expressing E cytokeratins and that coexpression of E and T polypeptides occurs in both kinds of appendages. While in the hair follicle, the change to the exclusive synthesis of T cytokeratins appears to take place relatively abruptly and simply, the development of nail structures from the ventral nail matrix seems to be more gradual and is characterized by more-complex patterns of coexpression of both kinds of cytokeratins.