Restoration of the epidermal phenotype by follicular outer root sheath cells in recombinant culture with dermal fibroblasts

In order to better understand how outer root sheath (ORS) cells are able to reepithelialize superficial skin wounds, the level of epidermal differentiation achieved by isolated ORS cells in vitro was determined. Using postmitotic human dermal fibroblasts (HDF) as efficient feeder cells, large numbers of ORS cells from individual follicles were generated. Passaged ORS cells were grown exposed to air on HDF-populated collagen gels in the CRD device (Noser and Limat, In vitro 23, 541-545, 1987) which allows histiotypic tissue organization. In such recombinant organotypic cultures, ORS cells developed distinct epidermal strata comparable to interfollicular keratinocytes (NEK). Ultrastructurally, desmosomes and intermediate filaments increased in number toward the epithelial surface and small keratohyalin (KH) granules (but no large irregular KH granules as in NEK) were abundant, adjacent to an electrondense stratum corneum. Also, synthesis of epidermal suprabasal keratins (K1 and 10;2D gels) was lower in ORS cultures, but clearly visible suprabasally by immunofluorescence along with other epidermal markers (involucrin, filaggrin, surface glycoprotein gp80, pemphigus vulgaris antigen). Basement membrane components (laminin, type IV collagen, bullous pemphigoid antigen) were detectable in both ORS and NEK in these assays. Thus, phenotypic expression was largely comparable, but, whereas terminal differentiation (keratinization) was progressing in NEK cultures limiting their lifespan, this seemed to be better controlled in ORS cultures and viable cell layers persisted resulting in longer survival time.     

Human epidermis reconstructed on synthetic membrane: Influence of experimental conditions on terminal differentiation

Summary Cell suspensions of human keratinocytes seeded onto cell culture inserts may undergo terminal differentiation in the absence of fibroblasts. Among the parameters that control these morphogenic events, exposure to air and the composition of the culture medium were investigated. In the latter case, three media were considered DMEM:Ham’s F12, MCDB 153, and keratinocyte SFM medium at equivalent calcium (1.5 mM) and fetal calf serum (5%) concentrations. Immunochemical methods and transmission electron microscopy show that cells cultured in DMEM:Ham’s F12 medium, and then raised at the air-liquid interface, form a basal layer plus suprabasal cell layers corresponding to thestratum spinosum, stratum granulosum, andstratum corneum. The suprabasal keratinocyte layers show morphologies that resemble intact skin in which cells are connected by desmosomes and contain intermediate filaments and keratohyalin-filaggrin granules. When the cultures are kept submerged, the keratinocytes show occasional keratohyalin granules and are connected by fewer desmosomes. Additionally, no properstratum corneum is formed. In keratinocyte SFM medium and MCDB 153, cultures raised at the air-liquid interface are not able to form an epithelium of normal architecture and do not express terminal differentiation markers. Differentiation is initiated, however, since desmosomes and bundles of keratin filaments appear; on the other hand, filaggrin is not expressed even after 28 d in culture. Membrane-bound transglutaminase is expressed throughout the entire suprabasal compartment in MCDB153 and DMEM:Ham’s F12 media but never appears in keratinocyte SFM medium. These studies show the relative independence of epidermal differentiation program to the composition (including the calcium concentration) of the media contacting the dermis and filling the extracellular space. Conversely, differentiation appears to depend on elements of basal medium and/or components synthesized by keratinocytes under the influence of the culture medium.     

The process of skin healing in experimentally wounded carp

The process of skin healing was studied in thin sections of adult mirror-carp, superficially wounded with a razor blade in a scaleless region. Shortly after wounding, epidermal cells from both sides of the wound moved towards the wound cavity. The cells moved as compact groups, without severing the normal intercellular desmosomes. The moving cells displayed phagocytotic activity of cellular debris during the migration. The phagosomes reacted with diaminobenzidine, revealing strong peroxidase content. The normally abundant pinocytotic vesicles from the basal layer of filament cells vanished during the first hour after wounding, and reappeared after 2 days; 24 h after wounding, desmosomes interconnected the filament cells from both sides of the wound. Due to profuse mucus secretion, the number of mucous cells from the epidermal stratum was markedly reduced. Rodlet cells appeared 1 h after wounding in the external region of the epidermis. There was pronounced increase in alkaline phosphatase content of the pavement cells 10 min after wounding; this enzyme appeared around the ridges of the pavement cells and inside the mucous cells 20 min later.
In the dermis, the region surrounding the wound was darkened, blood cells extravasated, and penetrated partially into the epidermis. After 2 days, dermal fibroblasts displayed intense phagocytosis; after 8 days they were particularly abundant in the region of regenerating tissue and were secreting large quantities of collagen. Marked changes in the relative frequency of the different types of leucocyte occurred during the post-wounding days.     

Human keratinocytes cultured on collagen gels form an epidermis which synthesizes bullous pemphigoid antigens and α2β1 integrins and secretes laminin, type IV collagen, and heparan sulfate proteoglycan at the basal cell surface

Single cell suspensions of human keratinocytes when seeded onto floating three-dimensional gels constructed with type I collagen form a tissue resembling epidermis. These morphogenetic events occur in a serum-free environment in the absence of fibroblasts. Light and transmission electron microscopy show that cells form a basal layer plus suprabasilar cell layers corresponding to the stratum spinosum, stratum granulosum, and stratum corneum. The suprabasilar keratinocyte layers show morphologies which resemble intact skin in which cells are connected by desmosomes and contain intermediate filaments and keratohyalin-fillagrin granules. The basal cell layer differs from skin in vivo in that there is no connection to a basement membrane via hemidesmosomes. Cells in the basal layers are polarized as evidenced by the secretion of type IV collagen, heparan sulfate proteoglycans, and laminin at the cell membrane interface with the collagen gel. These proteins are not organized into a cytological basement membrane. Bullous pemphigoid antigen, a protein component of hemidesmosomes, is synthesized by basal keratinocytes, but like the basement membrane proteins it is not incorporated into a definable cytological structure. Keratinocytes in the basal and suprabasilar layers also synthesize α2β1 integrins. The mechanisms of keratinocyte adhesion to the gel may be through the interactions of this cell surface receptor with laminin and type IV collagen synthesized by the cell and/or direct interactions between the receptor and type I collagen within the gel. This in vitro experimental system is a useful model for defining the molecular events which control the formation and turnover of basement membranes and the mechanisms by which keratinocytes adhere to type I collagen when sheets of keratinocytes are used clinically for wound coverage.     

Human keratinocytes cultured on collagen gels form an epidermis which synthesizes bullous pemphigoid antigens and alpha 2 beta 1 integrins and secretes laminin, type IV collagen, and heparan sulfate proteoglycan at the basal cell surface

Single cell suspensions of human keratinocytes when seeded onto floating three-dimensional gels constructed with type I collagen form a tissue resembling epidermis. These morphogenetic events occur in a serum-free environment in the absence of fibroblasts. Light and transmission electron microscopy show that cells form a basal layer plus suprabasilar cell layers corresponding to the stratum spinosum, stratum granulosum, and stratum corneum. The suprabasilar keratinocyte layers show morphologies which resemble intact skin in which cells are connected by desmosomes and contain intermediate filaments and keratohyalin-fillagrin granules. The basal cell layer differs from skin in vivo in that there is no connection to a basement membrane via hemidesmosomes. Cells in the basal layers are polarized as evidenced by the secretion of type IV collagen, heparan sulfate proteoglycans, and laminin at the cell membrane interface with the collagen gel. These proteins are not organized into a cytological basement membrane. Bullous pemphigoid antigen, a protein component of hemidesmosomes, is synthesized by basal keratinocytes, but like the basement membrane proteins it is not incorporated into a definable cytological structure. Keratinocytes in the basal and suprabasilar layers also synthesize alpha 2 beta 1 integrins. The mechanisms of keratinocyte adhesion to the gel may be through the interactions of this cell surface receptor with laminin and type IV collagen synthesized by the cell and/or direct interactions between the receptor and type I collagen within the gel. This in vitro experimental system is a useful model for defining the molecular events which control the formation and turnover of basement membranes and the mechanisms by which keratinocytes adhere to type I collagen when sheets of keratinocytes are used clinically for wound coverage.     

Structure of the skin of an air-breathing mudskipper, Periophthalmus magnuspinnatus

The epidermis of the mudskipper Periophthalmus magnuspinnatus consisted of three layers: the outermost layer, middle layer and stratum germinativum. Extensive vascular capillary networks were present near the superficial layer of epidermis and outermost layer. The diffusion distance between the vascular capillaries and the surface of epidermis was c . 1.5 ± 0.9μm. The middle layer consisted of small or voluminous cells swollen by epidermal cells. Due to the swollen cells, the thickness of the epidermis increased and the epidermis appeared web-like. The swollen cells contained tonofilaments, lucent contents and desmosomes. Fine blood capillaries were also discernible in this layer. Well-developed lymphatic spaces containing lymphocytes existed in the stratum germinativum. Numerous blood capillaries were present under the basement membrane. The dermis consisted of a stratum laxum and stratum compactum, and there was a definite area with acid mucopolysaccharides and a small scale in the stratum laxum. The skin had an epidermal pigment cell, dendritic melanophores (-cytes) containing melanin granules within their cytoplasm, and two kinds of dermal pigment cells, melanophores and colourless pigments containing reflecting platelets.     

Developmentally and regionally regulated participation of epidermal cells in the formation of collagen lamella of anuran tadpole skin

We investigated the cellular mechanism of formation of subepidermal thick bundles of collagen (collagen lamella) during larval development of the bullfrog, Rana catesbeiana, using cDNA of alpha1(I) collagen as a probe. The originally bilayered larval epidermis contains basal skein cells and apical cells, and the collagen lamella is directly attached to the basement membrane. The basal skein cells above the collagen lamella and fibroblasts beneath it intensively expressed the alpha1(I) gene. As the skin developed, suprabasal skein cells ceased expression of the gene. Concomitantly, the fibroblasts started to outwardly migrate, penetrated into the lamella and formed connective tissue between the epidermis and the lamella. These fibroblasts intensively expressed the gene. As the connective tissue developed, the basal skein cells ceased to express the gene and were replaced by larval basal cells that did not express the gene. These dynamic changes took place first in a lateral region of the body skin and proceeded to all other regions except the tail. Isolated cultured skein cells expressed the gene and extracellularly deposited its protein as the type I collagen fibrils. Thus, it is concluded that anuran larval epidermal cells can autonomously and intrinsically synthesize type I collagen.     

Characterization of metamorphic changes in anuran larval epidermis using lectins as probes

The skin of an adult frog of Xenopus laevis was characterized by the reactivity of 20 lectins. The lectins were classified into six groups in their binding to the epidermal cells: Lycopersicon esculentum lectin (LEL)-type which was positive for all epidermal cells; Pisum sativum agglutinin (PSA)-type for stratum germinativum; succinylated wheat germ agglutinin (sWGA)-type for strata spinosum, granulosum and corneum; Dolichos biflorus agglutinin (DBA)-type for strata germinativum and spinosum; peanut agglutinin (PNA)-type for stratum spinosum; and Ulex europaeus agglutinin (UEA-I)-type for strata granulosum and corneum. PSA and sWGA were utilized as markers of mitotically active germinative cells and the differentiated cells of the epidermis, respectively, to describe the metamorphic conversion of larval epidermal cells to adult type. PSA stained all epidermal cells of tadpoles before metamorphic climax. At the end of metamorphosis, PSA-positive cells were restricted to cells in the basal layer of body epidermis while all the tail epidermis remained PSA-positive. The other cell marker, sWGA, only stained apical cells in tadpole epidermis. During the metamorphic climax, sWGA-positive cells appeared in the cells beneath the stratum corneum of the body region, but not in the tail region. The present study demonstrates that PSA and sWGA are useful to investigate metamorphic changes in tadpole epidermal cells.     

The structure of the integument of the sea cucumber,Thyone briareus

The integument and podia of the sea cucumber Thyone briareus were examined by bright field and electron microscopy. The epidermal surface was found to be covered by an acellular, PAS positive cuticle which appeared to be secreted by the underlying epidermal cells. Although the superficial portion of the cuticle contains numerous fine filaments, their ultrastructure bears no resemblance to collagen fibers. The epidermal cells are widely spaced and have long apical processes that extend along the under surface of the cuticle forming a contiguous epithelium. The apical expansions of the epidermal cells are attached to one another by means of septate desmosomes which may run continuously around all epidermal cells. Special attachment structures within these apical expansions appear to bind the cuticle to the dermis. The epidermal cells and their apical expansions are separated from the dermis by an 800 Å thick basement membrane. Granule containing cells in the upper dermis send processes up to the cuticle where they are bound to the typical epidermal cells by septate desmosomes. The abundant membrane bound granules of the cells enter villous-like processes which pass through the cuticle. The function of these cells may be to produce an adhesive material on the podia or they may be pigment cells. The thick dermis consists of a superficial zone, containing largely ground substance; a middle or laminated zone containing laminae of collagen fibers arranged in an orthogonal fashion; and a hypodermis consisting largely of ground substance and reticular fibers. Fibroblasts are abundant in the superficial dermis and between the collagen laminae. Wandering coelomocytes, or morula cells, accumulate between the collagen laminae and in the hypodermis. They may also become an integral part of the epidermis by forming septate desmosomes with epidermal cells. Morula cells contain highly specialized spherules whose tinctorial properties and electron microscopic appearance suggest that they contain protein and mucopolysaccharide.     

Cellular responses to disruption of the permeability barrier in a three-dimensional organotypic epidermal model

Repeated injury to the stratum corneum of mammalian skin (caused by friction, soaps, or organic solvents) elicits hyperkeratosis and epidermal thickening. Functionally, these changes serve to restore the cutaneous barrier and protect the organism. To better understand the molecular and cellular basis of this response, we have engineered an in vitro model of acetone-induced injury using organotypic epidermal cultures. Rat epidermal keratinocytes (REKs), grown on a collagen raft in the absence of any feeder fibroblasts, developed all the hallmarks of a true epidermis including a well-formed cornified layer. To induce barrier injury, REK cultures were treated with intermittent 30-s exposures to acetone then were fixed and paraffin-sectioned. After two exposures, increased proliferation (Ki67 and BrdU staining) was observed in basal and suprabasal layers. After three exposures, proliferation became confined to localized buds in the basal layer and increased terminal differentiation was observed (compact hyperkeratosis of the stratum corneum, elevated levels of K10 and filaggrin, and heightened transglutaminase activity). Thus, barrier disruption causes epidermal hyperplasia and/or enhances differentiation, depending upon the extent and duration of injury. Given that no fibroblasts are present in the model, the ability to mount a hyperplastic response to barrier injury is an inherent property of keratinocytes.     

Ultrastructural features of Glisson's capsule and the overlying mesothelium in rat, monkey and pike liver

Samples from the liver of a male rat (Sprague-Dawley), a monkey (Macacus rhesus), and a longnose gar pike (Lepisosteus osseus) were studied in a transmission electron microscope to provide cytological and histological information about structures previously poorly documented in the literature. Glisson's capsule consisted of dense, irregular connective tissue of typical Type-I collagen fibrils. The capsule was formed by a single stratum of fibroblasts in the rat and in the pike, but by one or two strata of fibroblasts in the monkey. In the rat, but not in the monkey or pike, fibroblast processes interdigitated with processes from the hepatocytes. In the pike, fibroblast processes extended toward both mesothelium and hepatocytes. In some areas of the rat and pike, mesothelial cells had desmosomal connections and microvillous projections into the peritoneal cavity. Marginated heterochromatin was more abundant in the rat and monkey. The mesothelium was discontinuous in the rat and monkey but, in areas of discontinuity, the capsular surface was covered by a basal lamina, often barely perceptible beneath mesothelial cells of the rat and monkey, but prominent in the pike. In the pike, the mesothelium had numerous pinocytotic vesicles on both peritoneal and capsular surfaces.     

Proliferation of human embryonic and fetal epidermal cells in organ culture

The morphology of human embryonic and fetal skin growth in organ culture at the air-medium interface was examined, and the labeling indices of the epidermal cells in such cultures were determined. The two-layered epidermis of embryonic specimens increased to five or six cell layers after 21 days in culture, and the periderm in such cultures changed from a flat cell type to one with many blebs. The organelles in the epidermal cells remained unchanged. Fetal epidermis, however, differentiated when grown in this organ culture system from three layers (basal, intermediate, and periderm) to an adult-type epidermis with basal, spinous, granular, and cornified cell layers. Keratohyalin granules, lamellar granules, and bundles of keratin filaments, organelles associated with epidermal cell differentiation, were observed in the suprabasal cells of such cultures. The periderm in these fetal cultures formed blebs early but was sloughed with the stratum corneum in older cultures. The rate of differentiation of the fetal epidermis in organ culture was related to the initial age of the specimen cultured, with the older specimens differentiating at a faster rate than the younger specimens. Labeling indices (LIs) of embryonic and fetal epidermis and periderm were determined. The LI for embryonic basal cells was 8.5% and for periderm was 8%. The fetal LIs were 7% for basal cells, 1% for intermediate cells, and 3% for periderm. The ability to maintain viable pieces of skin in organ culture affords a model for studying normal and abnormal human epidermal differentiation from fetal biopsies and for investigating proliferative diseases.     

Regulation of epidermal differentiation by a Distal-less homeodomain gene

The Distal-less-related homeodomain gene Dlx3 is expressed in terminally differentiated murine epidermal cells. Ectopic expression of this gene in the basal cell layer of transgenic skin results in a severely abnormal epidermal phenotype and leads to perinatal lethality. The basal cells of affected mice ceased to proliferate, and expressed the profilaggrin and loricrin genes which are normally transcribed only in the latest stages of epidermal differentiation. All suprabasal cell types were diminished and the stratum corneum was reduced to a single layer. These data indicate that Dlx3 misexpression results in transformation of basal cells into more differentiated keratinocytes, suggesting that this homeoprotein is an important regulator of epidermal differentiation.     

Proliferation in murine epidermis after minor mechanical stimulation. Part 1. Sustained increase in keratinocyte production and migration

It was our objective to obtain an insight into the details and dynamics of the cell proliferative changes following minor barrier disruption, the mechanisms of recovery, and their regulation. Hair of the dorsal area of DBA2-mice was removed and the epidermis was tape stripped. Tritiated thymidine was injected into groups of mice at daily intervals thereafter. Labelling and nuclear densities were measured at several time intervals later in the various epidermal strata to characterize cell production and cell fluxes through the tissue. A dramatic proliferative response was observed at 24 h when the labelling density increased more than sixfold in the basal layer. Labelled cells rapidly appeared in suprabasal layers within a few hours in large quantities while this process took over 2 days in normal skin. Some cycling cells were also found in the suprabasal layer (pulse labelling at 24 h) in contrast with the controls. The cellular flux through the suprabasal layers was drastically (20-fold) increased and the transit time was shortened. Although the nuclear density in the basal layer showed only moderate changes it increased four-fold in the suprabasal layer within 5 days. A kinetic model analysis suggested that the cell cycle time of proliferative cells dropped from a normal value of about 200 h to less than 12 h post tape strip. After 7 days, the proliferative activation still persisted, even though at 3 days post tape strip the stratum corneum had been re-established. Hence, a mild mechanical alteration with removal of some parts of the cornified layer in mouse backskin epidermis triggers a huge proliferative response with massive overproduction of cells that lasts at least 7 days. Our findings suggest that the re-establishment of the cornified layer does not immediately shut down cell proliferation and that more complex, slower (long-term) regulatory processes are involved.     

Keratinization of the outer surface of the avian scutate scale: Interrelationship of alpha and beta keratin filaments in a cornifying tissue

Summary The outer surface of adult Gallus domesticus scutate scale was studied as a model for epidermal cornification involving accumulation of both alpha and beta keratins. Electron-microscopic analysis demonstrated that the basal cells of the adult epidermis contained abundant lipid droplets and that filament bundles and desmosomes were distributed throughout the cell layers. Indirect immunofluorescence microscopy and double-labeling immunogold-electron microscopy confirmed that the stratum germinativum contained alpha keratin but not beta keratin. Beta keratins were first detected in the stratum intermedium and were always found intermingled with filament bundles of alpha keratin. As the differentiating cells moved into the outer regions of the stratum intermedium and the stratum corneum, the large mixed keratin filament bundles labeled increasingly more with beta keratin antiserum and relatively less so with alpha keratin antiserum. Sodium dodecyl sulfate-polyacrylamide gel analysis of vertical layers of the outer surface of the scutate scale confirmed that cells having reached the outermost layers of stratum corneum had preferentially lost alpha keratin. The mixed bundles of alpha and beta keratin filaments were closely associated with desmosomes in the lower stratum intermedium and with electron-dense aggregates in the cytoplasm of cells in the outer stratum intermedium. Using anti-desmosomal serum it was shown that these cytoplasmic plaques were desmosomes.     

The structure of the canary's incubation patch

The gross morphology, histology and ultrastructure of the canary's incubation patch and the ventral apterium from which it arises are described. The apterium is vascularized by pectoral, external mammary, incubation, and prepubic arteries. It is innervated by cutaneous branches of spinal nerves. It has a surface area of 6 cm². Its epidermis is a stratified squamous epithelium with basal, intermediate, transitional and cornified layers. Cells in the stratum germinativum contain a normal array of organelles, but are characterized by tonofilaments, desmosomes and interdigitating surfaces. Cellular organelles disappear in the stratum transitivum and are replaced by large vacuoles and keratohyalin bands. Nonmyelinated nerve fibers are abundant in the stratum germinativum. The dermis consists of (1) an avascular layer of dense collagen subjacent to the epidermis and containing many nonmyelinated nerves, and (2) an underlying layer of areolar connective tissue containing blood vessels, lamellar corpuscles and nerves. A layer of coarse elastic fibers, reinforced by collagen and smooth muscle, separates the dermis from subcutaneous tissue. In contrast to the ventral apterium, the incubation patch is featherless and visibly hypervascular and edematous. Its epidermis is both hypertrophic and hyperplastic. Large spaces separate cells in the stratum germinativum. The visible hypervascularity is due to hyperemia and increased number and size of blood vessels in the dermis. Visible edema is due to the accumulation of fluid interstitially. Although no histological differences exist among various regions of the ventral apterium, such differences are present in the incubation patch.     

An electron microscopic study of the human epidermal keratinocyte

Summary 1. The epidermis of the flexor surface of the upper arm of human subjects was studied with the electron microscope. 2. The cytoplasm of the keratinocytes in the basal layer contained many tonofilaments, ribosomes and other cell organelles. The tonofilaments were arranged singly or in loose bundles and many were attached to the inner membrane of the desmosomes. Along the basal border of the cells pinocytotic vesicles could be seen at different stages of development. 3. The keratinocytes in the stratum spinosum differed from those in the basal layer in two main ways: (a) The tonofilaments were grouped together into large compact bundles known as tonofibrils and it was possible to determine a definite beading or cross banding along the length of some of the filaments. (b) The cells were assuming a flattened shape. 4. The keratinocytes in the stratum granulosum possessed large numbers of irregularly shaped keratohyaline granules. The granules were strongly osmiophilic and were always situated on a meshwork of tonofibrils. The keratohyaline granules had no internal structure. The nuclei and mitochondria showed evidence of degeneration. 5. The keratinocytes in the stratum corneum were long and flattened. The cell walls showed increased electron density and were considerably thickened. The cytoplasm was filled with closely packed fibres separated by a small amount of lucent matrix. The fibres were grouped together in bundles running in different directions within the flattened squames. The fibres had along their entire length alternating areas of high and low electron density. The keratohyalin granules had disappeared and nothing remained of the nuclei or the organelles. In the deepest cells of this region the fibres were sometimes loosely packed leaving large irregular open spaces. This area corresponded to the stratum lucidum. In the most superficial layers of the stratum corneum the fibres appeared to be breaking down so that little remained within the keratinocyte except large lucent spaces. The desmosomes showed distinct structural changes. 6. An attempt was made to correlate the structural changes in the different epidermal layers with the process of keratinization. The possible part that keratohyalin may play in the process of thickening of the cell walls was discussed. The relationship between the desmosome and its dynamic environment was considered.I wish to express my sincere thanks to Dr. David Hilding of the Department of Otolaryngology for the use of an R.C.A. electron microscope and other facilities in his laboratory. This research was supported by the United States Public Health Service and American Cancer Society grants. USPHS CA 04679-07, NB 03995.     

The morphology of the denuded epidermal basal cell layer of the hairless mouse after different preparation methods. A scanning and transmission electron microscopical study

The denuded basal cell layer of the hairless mouse epidermis is described in the present scanning (SEM) and transmission electron microscopical (TEM) study. The suprabasal layers were removed mechanically after trypsinization or by extracellular calcium depletion. Trypsinization before removal of the suprabasal cells caused the basal cells to shrink. Characteristic surface plication and hemi-desmosomal attachment to the basement membrane were generally preserved. SEM revealed partly maintained intercellular bridging, whereas by TEM such contacts were absent because half desmosomes were internalized. Total calcium depletion induced more serious damage to the basal cell surface, which was smooth with apparent perforations. However, cell bridges, and occasional desmosomes were present. The cell interior demonstrated important cellular injury. If the calcium deprived explants were allowed to recover in calcium-containing medium, the cells acquired an activated "regenerative" morphology, without junctions, similar to that observed in wound healing. Epidermal non-keratinocytes were seen only after trypsinization. Control experiments revealed that they adapted poorly to organ culture conditions. By TEM, we observed several interesting aspects of the differences, between dark and clear basal keratinocytes. This was unexpected because fixation studies had shown, that with the present fixation method, typical dark and clear cells do not occur in untreated epidermis. We believe that membrane injury through mechanical stripping of partly adhering epidermal layers induced "clear cells", whereby the neighboring cells appeared darker. This provides additional evidence as to the origin of the two sub-populations, dark and clear basal cells. The clear cells may be injured cells, caused by cell damage, and not by processes of cellular differentiation. The results of the present investigation supports the view that basal keratinocytes have a polygonal shape with numerous free surface extensions and they are anchored to the basement membrane with "foot pads". Our study also shows that SEM of the epidermal basal layer might be feasible. Various artifacts, however, must be considered, depending on the denudation method used. We prefer trypsinization to calcium depletion because it is less time-consuming and results in a cell morphology which in TEM is comparable to that of basal cells in untreated whole epidermis. Extra-cellular calcium depletion, however, might be useful as a method to prepare single cell suspensions for flow cytometry. Restoration of a normal calcium concentration after stripping, provides an opportunity to mimic wound healing in situ, as an alternative t     

Temperature-sensitive regulation of epidermal morphogenesis and the expression of cornified envelope precursors by EGF and TGFα

Epidermis reconstructed on de-epidermized dermis was used to investigate the effects of growth factors and culture temperature on epidermal morphogenesis and the expression of cornified envelope precursors. Cultures grown at 33°C or 37°C in the absence or presence of transforming growth factor alpha (TGFα), keratinocyte growth factor (KGF), basic fibroblast growth factor (bFGF), or insulin-like growth factor (IGF) show a similar morphology to that of native epidermis. Loricrin and SPRR2 are expressed in the stratum granulosum and SPRR3 is absent. Cultures grown in epidermal growth factor (EGF)-supplemented medium at 37°C have a normal morphology, whereas cultures grown at 33°C have a disorganized basal layer, no stratum granulosum, and nuclei are present in the stratum corneum. Loricrin is absent, and SPRR2 and SPRR3 expression extend into the spinous layers. Irrespective of the culture condition used, involucrin is aberrantly expressed in all suprabasal layers. EGF stimulated keratinocyte proliferation and migration to a greater degree than TGFα. Epidermis reconstructed on fibroblast-populated collagen gels at 33°C led to the same disturbances in keratinocyte differentiation as seen in cultures grown on de-epidermized dermis at 33°C in the presence of EGF, whereas parallel cultures grown at 37°C have a similar morphology to that of native epidermis.     

Restricted tissue distribution of a 37-kD possible adherens junction protein

A major polypeptide of M(r) 37,000 was purified from a desmosome-enriched citric acid-insoluble pellet of pig tongue epithelium. The polypeptide was solubilized from the 4-M urea-insoluble pellet with 9 M urea, and extracts were separated by carboxymethyl cellulose and gel filtration chromatography. The 37-kD protein was obtained in milligram quantities as a single band on two-dimensional gels in 30% yield after 21-fold purification from the citric acid-insoluble fraction. The protein is not glycosylated and has a pI of approximately 8.7. Although isolated from a fraction rich in desmosomes, the 37-kD protein is not a desmosomal protein. Indirect immunofluorescence analysis of frozen sections of tongue and other tissues demonstrated that antibodies raised to the 37-kD protein bound only to suprabasal cell layers at punctate regions of the periphery of the cell and was absent from most regions of epidermis, whereas antibodies to desmoplakins I and II, desmosomal proteins, bound similarly but in all epidermal layers. Immunoelectron microscopy localized the 37-kD protein to the cell periphery in regions between, but never in, desmosomes. By immunofluorescence, the 37-kD protein colocalized with actin as well as with vinculin and uvomorulin in oral tissues. Like the 37-kD protein, vinculin and uvomorulin were absent from the basal layer. Based on its appearance, localization, and solubility properties, the 37-kD protein is probably a component of adherens junctions; its restriction to suprabasal cells and exclusion from the epidermis are unique.