Differentiation of human scalp hair follicle keratinocytes in culture

The morphology of human scalp hair follicle keratinocytes, cultured on the bovine eye lens capsule, is studied by light and electron microscopy. The hair follicle keratinocytes in the stratified cultures are characterized by the presence of numerous tonofilaments, desmosomes and lysosomes and by the presence of glycogen accumulations. The cells in the upper layers develop a cornified envelope. Moreover, an incomplete basal lamina is found between the capsule and the basal cells. However, some features of epidermal keratinocytes in vivo, such as keratohyalin granules and stratum corneum formation, are absent. Analysis of the polypeptides by sodium dodecylsulfate polyacrylamide gel electrophoresis also reveals differences between the cultured hair follicle cells and epidermis, whilst the patterns of cultured cells and hair follicle sheaths are similar. The morphological and protein biosynthetic aspects of terminal differentiation of the keratinocytes in vitro are correlated. These results are discussed in the light of the findings with cultured epidermal keratinocytes, reported in the literature.     

The electron microscopy of normal human oesophageal epithelium.

Oesophageal biopsies were studied with the electron microscope. Three layers were identified, as in the light microscopy of the oesophageal epithelium: basal, prickle and funtional cell layers. A continuous basement membrane separated the lamina propria from the basal cells. The basal cell membrane carried hemidesmosomes, desmosomes and microvillous processes. Their cytoplasm contained the usual organelles plus free ribosomes and tonofirbrils. Prickle cells contained glycogen rosettes and many tonofilaments, and their cell membrane many microvillous and demosomal processes, in places elaborated into desmosome fields. In both these layers there was a wide intercellular space containing some particulate and membranous debris. The flattened cells of the functional layer had fewer desmosomes and microvilli but abundant glycogen and tonofilaments, and a narrow intercellular space. Membrane coating granules first reaching a maximum in the functional cell layer appeared in the upper prickle cell layer and few persisted into the surface cells. The apical cell membrane of the most superficial cells was thickened and had few small microvillous processes, which were covered with a filamentous "fuzzy" coat. No keratohyaline granules were present. Papillae of lamina propria contained capillaries, some with a fenestrated endothelium.     

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

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

Morphological appearance of epidermal cells cultured on fibroblast-reorganized collagen gels

Summary Human foreskin fibroblasts were used to reorganize hydrated collagen gels into a dermal-like matrix, after which freshly isolated keratinocytes isolated from rabbit ear skin were placed on the surfaces of the matrices and cultured for up to 12 days. Transmission electron microscopy revealed 8–12 cell layers of epidermal cells organized in three distinct strata. The basal stratum consisted of cuboidal to columnar cells with typical complement of organelles, oval nuclei, and prominent tonofilaments inserting into desmosomes. Mitotic cells often were found at this level. There was no well-defined basement membrane region; rather, many of the cells appeared to be in close contact with collagen fibrils. The intermediate stratum of suprabasal cells consisted of elongated cells that had reduced organelles, but still were connected to each other by desmosomes. Finally, the superficial stratum of suprabasal cells contained cells that were completely flattened and often appeared to be sloughing off the apical surfaces of the cultures. Indirect immunofluorescence studies carried out on frozen sections revealed bullous pemphigoid antigen associated with basal epidermal cells; pemphigus vulgaris antigen around the epidermal cells of all strata, and keratin present in the epidermal cells of all strata. Filaggrin was observed in punctate and fibrillar arrangements in suprabasal cells. Fibronectin was found in a linear deposit at the dermal-epidermal junction and around the fibroblasts in the reorganized collagen gels. Type-IV collagen and laminin, however, were not detected.     

Biosynthetic pathways of filaggrin and loricrin--two major proteins expressed by terminally differentiated epidermal keratinocytes

We have used immunoelectron microscopy to map the biosynthetic pathways of loricrin and filaggrin in epidermal keratinocytes at successive stages of differentiation in newborn mouse skin. The filaggrin epitope is first detected in large, irregularly shaped, keratohyalin granules (F-granules) in the stratum granulosum, and then distributed throughout the cytoplasms of the innermost layers of stratum corneum cells. We conclude that the poly-protein filaggrin precursor is first accumulated in F-granules, from which it is subsequently released and processed into filaggrin, and becomes associated with the densely packed bundles of keratin filaments inside stratum corneum cells. Its diminished visibility in the outer layers correlates with the known degradation of filaggrin to free amino acids. Loricrin is first detected in small round keratohyalin granules (L-granules), and subsequently at the periphery of cells throughout the stratum corneum. Labeling of purified keratinocyte envelopes establishes that this loricrin epitope is exposed only at their inner (cytoplasmic) surface. Thus loricrin is initially accumulated in L-granules, to be released at a specifically programmed stage of keratinocyte maturation, and incorporated into the covalently cross-linked lining of the cell envelope. Since loricrin is rich in cysteine, L-granules account for the sulfur-rich keratohyalin granules described earlier. Proposals are made to rationalize why, subsequent to synthesis, filaggrin precursor and loricrin should be segregated both from each other and from the rest of the cytoplasm.     

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.     

Ultrastructural localization of caspase-14 in human epidermis.

Caspase-14 has been implicated in the formation of stratum corneum because of its specific expression and activation in terminally differentiating keratinocytes. However, its precise physiological role and its protein substrate are elusive. We studied the ultrastructural localization of caspase-14 in human epidermis to compare its distribution pattern with that of well-characterized differentiation markers. Immunogold cytochemistry confirmed that caspase-14 is nearly absent in basal and spinous layers. In the granular, layer nuclei and keratohyalin granules were labeled with increasing intensity towards the transitional layer. Particularly strong caspase-14 labeling was associated with areas known to be occupied by involucrin and loricrin, whereas F-granules, occupied by profilaggrin/filaggrin, were much less labeled. A high density of gold particles was also present at the forming cornified cell envelope, including desmosomes. In corneocytes, intense labeling was both cytoplasmic and associated with nuclear remnants and corneodesmosomes. These observations will allow focusing efforts of biochemical substrate screening on a subset of proteins localizing to distinct compartments of terminally differentiated keratinocytes.     

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.     

Calcium regulation of cell-cell contact and differentiation of epidermal cells in culture. An ultrastructural study

Calcium modulation of keratinocyte growth in culture was studied by both transmission (TEM) and scanning electron microscopy (SEM). Under standard culture conditions (1.2-1.8 mM calcium), cells were connected by desmosomes and stratified to 4-6 cell layers. Many aspects of in vitro epidermal maturation were analogous to the in vivo process, with formation of keratohyalin granules, loss of nuclei, formation of cornified envelopes and shedding of cornified cells containing keratin filaments. When the medium calcium concentration was lowered to 0.02-0.1 mM, the pattern of keratinocyte growth was strikingly changed. Cells grew as a monolayer with no desmosomal connections and proliferated rapidly, shedding largely non-cornified cells into the medium. Large bundles of keratin filaments were concentrated in the perinuclear cytoplasm. The elevation of extracellular calcium to 1.2 mM induced low calcium keratinocytes to stratify, keratinize and cornify in a manner analogous to that seen when plated in standard calcium medium. The earliest calcium-induced ultrastructural change was the asymmetric formation of desmosomes between adjacent cells. Desmosomal plaques with associated tonofilaments were observed 5 min after calcium addition; symmetric desmosomes were formed within 1-2 h. This system is presented as a useful model for the study of the regulation of desmosome assembly and disassembly.     

Organization of the intercellular spaces of porcine epidermal and palatal stratum corneum: a quantitative study employing ruthenium tetroxide

Previous studies have demonstrated that the intercellular spaces of the stratum corneum contain multilamellar lipid sheets with variable ultrastructure in addition to desmosomes or desmosomal remnants. The intercellular lamellae are thought to provide a permeability barrier whereas the desmosomes are responsible for cell-cell cohesion. In this study, transmission electron microscopy of RuO₄-fixed tissue was used to compare the proportions of the intercellular spaces in epidermal and palatal stratum corneum occupied by desmosomes and by different patterns of lamellae. Desmosomes are more abundant in palatal than in epidermal stratum corneum (46.9 vs 15.0% length of intercellular space). In epidermis the most frequent lamellar arrangements involve 3 (23.5%) or 6 (24.2%) lucent bands with an alternating broad-narrow-broad pattern, whereas the most frequent lamellar arrangements in palatal tissue are 2 (17.2%) or 4 (10.5%) lucent bands of uniform width. Most of the nondesmosomal portion of the intercellular space in palatal stratum corneum was dilated and had elongated lamellae at the periphery and short disorganized lamellae and amorphous electron-dense material in the interior. It is concluded that the multilamellar lipid sheets are less extensive in palatal than in epidermal stratum corneum, which could explain the greater permeability of the palate.     

Ultrastructure of human amnion and amniotic plaques of normal pregnancy

Summary The fine structure of amniotic and amniotic-plaque epithelia has been studied from normal term pregnancies. The columnar/cuboidal amniotic epithelial cells usually have apical or central nuclei, some free ribosomes, patches of granular endoplasmic reticulum, juxtanuclear Golgi complexes, rod-shaped mitochondria, lipid droplets and some glycogen granules. They have short, blunt microvilli which frequently branch and bathe in the amniotic fluid. The lateral plasma membranes enclose tortuous intercellular spaces which are always interrupted by variously folded processes and desmosomes. The epithelial cells rest on a basal lamina and exhibit highly folded basal processes. The amniotic epithelial cells are neither distinctly Golgi and fibrillar types nor light and dark in appearance.Amnion from near the umbilical cord contains many microscopic and several large plaques. Similar structures are not found on the reflected amnion. The microscopic plaques are whitish and translucent, whereas the large ones are opaque. The large plaques vary between 1–3 mm in diameter, and are over 15 cell layers thick. Each large plaque has a main central region and edges continuous with either the microscopic plaque or the simple amniotic epithelium. The main region shows four zones, namely, stratum basale, stratum spinosum, stratum granulosum and stratum corneum. Such zones are not distinct at the edges. The fine structure of basal cells compares with the amniotic epithelial cells, but the cells of spinosum and granulosum layers possess variable amounts of tonofibrils, keratohyalin granules, free ribosomes and other cytoplasmic organelles and inclusions. The corneum cells are keratinized and are frequently separated by intercellular spaces. They slough into the amniotic cavity singly or as a sheet, and contribute towards the composition of the amniotic fluid. The plaques are of amniotic origin, and are not formed by adhesion of either squamous cells or fetal skin cells (masses of keratinized squames). The present observations suggest that the occurrence of amniotic plaques is normal. The presence of plaques may not be necessarily associated with fetal abnormality. However, increase in numbers of plaques may be caused by conditions of fluid imbalance. The homology and significance of plaques in eutherian mammals have been discussed.This research was supported by USPHS Grant AM-11376 and NIH Grant 69-2136.     

The extraction and characterization of bovine epidermal alpha-keratin.

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

Psoriatic hair-follicle cells

Psoriatic human hair-follicle keratinocytes were cultured and then examined using light and electron microscopy. In comparison to control cultures derived from non-psoriatics, there were significant differences: stratification in general was more extensive; suprabasal cells were flat instead of round; there were almost no depositions of basal lamina or of cellular debris on the growth substrate; numerous membrane coating granules and a few keratohyalin granules were present earlier in psoriatic cultures than in control cultures; and the differentiation pattern resulted in an earlier appearance of corneocyte-like cells, and clusters of these corneocyte-like cells appeared to have been shed into the culture medium. As in control cultures, no distinct stratum corneum was found. Whether these differences between psoriatic cultures and control cultures reveal an aberrant differentiation pattern for psoriatic cells in vitro is as yet unknown: due to the faster outgrowth in psoriatic cultures, a multilayered and therefore further-differentiated structure near the hair follicle could be obtained more rapidly in psoriatic than in normal skin.     

Fine structure of the dorsal lingual epithelium of the Japanese monkey Macaca fuscata fuscata.

Filiform papillae, which were densely distributed all over the dorsal surface of the lingual body, were crown-shaped, with a central, circular area that sloped in the anterior direction and several branches that surrounded it in a semicircle from the back of the central area. Dome-shaped, fungiform papillae were scattered among these filiform papillae. At the posterior end of the lingual body, there were four circumvallate papillae. Prominent microridges and elevated intercellular borders were widely distributed in the central area of the filiform papillae and the interpapillar region. On the surface of the branches of the filiform papillae, microridges were rarely seen. On the surface of the fungiform papillae, indistinct microridges were observed. Histologically, the dorsal lingual epithelium revealed three different regions: the epithelium on the anterior side of the filiform papillae, the epithelium on the posterior side of the filiform papillae and the interpapillar epithelium. Whereas the basal and suprabasal cells are similar throughout, differences characterize the intermediate and surface layers. Keratohyalin granules appear predominantly in the intermediate layer in the epithelium on the anterior side of filiform papillae. In the epithelium on the posterior side of the filiform papillae, no keratohyalin granules occur and, instead, tonofibrils are prominent. The cells become significantly flattened. In the interpapillar epithelium, no keratohyalin granules are visible, and the tonofilaments occupy almost the entire cytoplasm of most cells in the intermediate and surface layers. The cells are larger in volume in these layers.     

An ultrastructural study of the prostate gland of megascolicid earthworm Lampito mauritii (Kinberg)

The ultrastructure of prostate gland of Lampito mauritii revealed two types of secretory cells. Type 1 cells with a broad basal region and a long apical region contain electron dense oval secretory granules with an increased density at the core region. Numerous electron lucent granules with fine filamentous and electron dense amorphous materials also occur at the basal region of these cells. Type 2 cells contain electron lucent mucous-like secretory granules. This cell type contains exceptionally large Golgi complexes having 20-23 stacked cisternae. Both cell types open into a common lumen and numerous microtubules are visible at the apical end. Junctional complexes, such as desmosomes and septate junctions, are observed in this glandular tissue.     

Development of chicken epidermis cultured with embryo extract

The epidermis from 11-day-old chick embryo shank skin was cultured with 11-day-old chick embryo extract. The growth and the differentiation of the epidermis in culture were studied histologically, electron microscopically and with polyacrylamide gel electrophoresis of keratin proteins. The epidermis cultured with the chick embryo extract proliferated and stratum structures developed simultaneously with the increase in epidermal cell layers. Finally, a keratinized layer was observed after 10 days in culture. Electron microscopic observations revealed that tonofilaments were produced after 2 days in culture and increased thereafter with culture time, becoming condensed with desmosomes. Keratohyaline granules were observed in 7-day cultures. These keratinization characteristics occurring during culture showed the general characteristics of the alpha stratum observed in the skin of in ovo embryos during the early stages of development. However, the development of peridermal and subperidermal granules was poor and the stratum granulosum, which develops at the late stages between the stratum intermedium and the stratum corneum, was not observed. Polyacrylamide gel electrophoresis of S-carboxymethylated keratin proteins showed that the keratin protein band patterns of the culture differed from those of in ovo skin epidermis.     

Staining of keratin and keratohyalin with the reactive dye levafix red violet E-2BL.

Demonstration of keratin in Zenker-fixed skin and in tissues stored in formalin can be difficult because such material is unsuitable for histochemical studies. A reactive dye, Levafix red violet E-2BL, proved useful for demonstration of keratohyalin and some types of keratin. Formalin-, Zenker- and methacarn-fixed sections were pretreated with alkaline alcohol, stained one hour at 60 C in an aqueous solution containing 0.25% Levafix red violet E-2BL plus 0.25% NaCl, rinsed in buffer solution pH 9, dehydrated and mounted. Keratohyalin granules and stratum corneum were colored red violet; hair and tonofibrils remained unstained. In sections prestained with Mayer's acid hemalum, keratohyalin was dark blue. Sulfonated monoazo dyes without reactive groups colored no tissue structures under the conditions of this technic; apparently, Levafix red violet E-2BL is bound via its reactive group. Polarization microscopic studies suggest binding of Levafix red violet E-2BL by an amorphous matrix of keratin. Correlations with chemical data indicate that the staining patterns parallel the distribution of proteins formed in the stratum granulosum.     

The binding of epidermolytic toxin from Staphylococcus aureus to mouse epidermal tissue

Summary Fluorescein-labelled epidermolytic toxin (FTC-toxin) ofStaphylococcus aureus and ferritin—toxin conjugate have been prepared and purified. FTC-toxin bound selectively to cryostat and resin-impregnated sections of neonatal mouse skin. Binding was localized at the keratohyalin granules and in the stratum corneum. In an epidermal cell (granular, spinous and basal) preparation, only keratohyalin granules of the granular cells bound FTC-toxin. Ferritin—toxin conjugate bound to skin sections at the same two sites as FTC-toxin and was competitive with the binding of free toxin. Keratohyalin granules in unstained sections had a novel patched appearance under the electron microscope, and the ferritin—toxin conjugate bound preferentially to the electron-lucent areas. In the stratum corneum it was shown by quantitative estimation that the target density decreased as the surface of the tissue was approached.     

Staining of Keratin and Keratohyalin with the Reactive Dye Levafix Red Violet E-2BL

Demonstration of keratin in Zenker-fired skin and in tissues stored in formalin can be difficult because such material is unsuitable for histochemical studies. A reactive dye, Levafix red violet E-PBL, proved useful for demonstration of keratohyalin and some types of keratin. Formalin-, Zenker- and methacarn-fired sections were pretreated with alkaline alcohol, stained one hour at 60 C in an aqueous solution containing 0.25% Levafix red violet E-2BL plus 0.25% NaC1, rinsed in buffer solution pH 9, dehydrated and mounted. Keratohyalin granules and stratum corneum were colored red violet; hair and tonofibrils remained unstained. In sections prestained with Mayer's acid hemalum, keratohyalin was dark blue. Sulfonated monoazo dyes without reactive groups colored no tissue structures under the conditions of this technic; apparently, Levafix red violet E-2BL is bound via its reactive group. Polarization microscopic studies suggest binding of Levafix red violet E-2BL by an amorphous matrix of keratin. Correlations with chemical data indicate that the staining patterns parallel the distribution of proteins formed in the stratum granulosum.