Induction of the alpha-type keratinization by hydrocortisone in embryonic chick skins grown in a chemically defined medium: An electron microscopic study

Previous biochemical analyses showed the differential accumulation of the epidermal structural protein, which yielded S-carboxymethylated epidermal protein A (SCMEpA), in the hydrocortisone-induced in vitro keratinization of 13-day embryonic chick tarsometatarsal skin growing in a chemically defined medium (Sugimoto et al., 1974). Fine structural features of such an in vitro keratinization process were studied by electron microscopy in the present work.After 2 days of culture with hydrocortisone (0.02 or 0.2 μM), development of the tonofilament bundles occurred to some extent, but the keratinized layer was not formed. Keratinization was observed after 4 days of culture with hydrocortisone (0.02 or 0.2 μM). Desmosomes and tonofilament bundles were prominent in the cytoplasm of the basal and intermediate cell layers of the epidermis. Keratohyalin granules and lipid droplets appeared in the upper layer. Degradation of cellular organelles such as nuclei and mitochondria then proceeded, leaving only filament bundles and electron-dense amorphous masses in the cytoplasm. Thickened cellular envelopes, which are characteristic of keratinized cells, were also observed. These features are characteristic of alpha-type keratinization which is common for other body surfaces. Beta-type keratinization, typical of normal embryonic scales, was not observed even after 6 days of culture with hydrocortisone. Keratinization of embryonic subperiderm of beta-type did not occur either. These ultrastructural observations clearly showed that hydrocortisone induced the alpha-type keratinization. It was also suggested that SCMEpA was closely related to alpha-type keratinization.     

Fine structure of the horny teeth of the lamprey,Entosphenus japonicus

The fine structure of the horny teeth of the lamprey, Entosphenus japonicus, was examined by light- and electron-microscopy. Most of the horny teeth consisted of two horny and two nonhorny layers. The primary horny layer was well keratinized, and the cells were closely packed and intensely interdigitated, being joined together by many modified desmosomes. The plasma membrane of the horny cell, unlike the membranes of other vertebrates, was not thickened. The intercellular spaces were filled with electron-dense material. Microridges were seen on the free surface. Structures resembling microridges were found on the underside of the primary horny layer. The secondary horny layer displayed various stages of keratinization. The keratinization started at the apex and developed toward the base. In the early stage of keratinization, the superficial cells became cylindrical and were arranged in a row forming a dome-shaped line. Their nuclei were situated in the basal part of the cells. The appearance of the nonhorny layers varied according to the degree of keratinization of the horny layers beneath them. The nonhorny cells were joined together by many desmosomes and possessed many tonofilament bundles. The replacement and keratinization of the horny teeth are discussed in the light of these results.     

Ultrastructural determination of gingival Langerhans cells in alloxan-induced diabetic rats

The ultrastructure of Langerhans cells has not been fully investigated in diabetes-associated gingival tissues. The present study was carried out to investigate the ultrastructure of gingival Langerhans cells in alloxan-induced diabetic rats. Gingival biopsies were obtained from 22 diabetic and 18 control rats. Langerhans cells were observed by transmission electron microscopy (TEM) in the basal layers of healthy oral epithelium. On rare occasions, Langerhans cells were found in the suprabasal layers of the oral epithelium. Langerhans cells in the oral epithelium of diabetic rats were seen in the basal and suprabasal layers. Usually, Langerhans cells had clear cytoplasm and convoluted or indented nuclei and few or no specific granules. The clear cytoplasm contained mitochondria, lysosomes and a small number of rough-surfaced endoplasmic reticulum regions, but it lacked tonofilament. Occasionally, centrioles were also observed in the cytoplasm. The membrane of Langerhans cells had no junctional complexes such as desmosomes. In diabetic rats, Langerhans cell precursors were developed into specific granule-bearing cells. Both Langerhans cells and their granules were more frequent in the gingiva of diabetic rats than in the control group. These data suggest that Langerhans cells play an important role in explaining the pathogenesis and development of diabetic gingivitis.     

Proliferation, differentiation and maturation of a mouse epidermal keratinocyte cell line

The spontaneous development of a cell line of neonatal mouse C3H/He epidermal cells is described. The culture has been serially passaged at 29 °C over 18 months in the absence of any dermal support. The cell morphology of the 18th passage is reported. During early growth phase, the morphology of the cell layers was similar to that observed in the basal and differentiating strata of the epidermis: numerous tonofilament bundles and desmosome-filament complexes were observed. During late growth phase, maturation and vertical stratification occurred: demonstrated by the tonofilament accumulation, cell organelle degradation, nuclear pyknosis, presence of keratohyalin granules and horny cell layers with thickened membranes. Hemidesmosome-like structures were shown. No basal lamina or membrane coating granules were detectable. The 18th passage cultured cells did not induce tumors in nude mice. This keratinocyte cell line is not permanent, however: a malignant transformation occurred after 25 subcultures which resulted in an undifferentiated cell population.     

Keratinization of the epidermis of the Australian lungfish Neoceratodus forsteri (dipnoi)

The differentiation of the epidermis in sarcopterigian fish may reveal some trend of keratinization followed by amphibian ancestors to adapt their epidermis to land. Therefore, the process of keratinization of the epidermis of the Australian lungfish Neoceratodus forsteri was studied by histochemistry, electron microscopy, and keratin immunocytochemistry. The epidermis is tri-stratified in a 2-3-month-old tadpole but becomes 6-8 stratified in young adults. Keratin filaments increase from basal to external cells where loose tonofilament bundles are present. This is shown also by the comparison of positivity to sulfhydryl groups and increasing immunoreactivity to alpha-keratins in more external layers of the epidermis. Two broad-spectrum anti alpha-keratin monoclonal antibodies (AE1 and AE3) stain all epidermal layers as they do in actinopterigian fish. In the adult epidermis, but not in that of the larva, the AE2 antibody (a marker of keratinization in mammalian epidermis) often immunolabels more heavily the external keratinized layers where sulfhydryl groups are more abundant. Mucous granules are numerous and concentrate on the external surface of the epidermis to be discharged and contribute to cuticle formation. Keratin is therefore embedded in a mucus matrix, but neither compact keratin masses nor cell corneous envelope were seen in external cells. It is not known whether specific matrix proteins are associated with mucus. There was no immunolocalization of the keratin-associated proteins, filaggrin and loricrin, which suggests that the epidermis of this species lacks the matrix and cell corneus envelope proteins characteristic of that of amniotes. In conclusion, while specific keratins (AE2 positive) are probably produced in the uppermost layers as in amphibian epidermis, no interkeratin, matrix proteins seem to be present in external keratinocytes of the lungfish other than mucus.     

Epidermal growth factor (EGF)-induced morphological changes in the basement membrane of chick embryonic skin

Summary The effect of epidermal growth factor (EGF) on the basement membrane structure of chick embryonic skin cultured in a chemically defined medium (BGJb) containing 20 mM hydrocortisone, and EGF at 10, 50, or 100 ng/ml supplemented with 5% delipidized fetal calf serum, was examined by electron microscopy. During development of the epidermis in vitro, EGF (100 ng/ml) caused striking changes to occur in the basement membrane structure and in the keratinization process. The basement membrane frequently became discontinuous with many gaps apparent in section, and occasionally became folded following detachment from the basal surface of the epidermis and protruded into the underlying dermis. In the basal and intermediate cells of EGF-treated epidermis, tonofilament bundles were decreased in number, while desmosomes and hemidesmosomes revealed no significant changes in morphology.     

Quantitative analysis of epithelial changes during wound healing in palatal mucosa of guinea pigs

Summary The epithelium of wounded guinea pig palate was subjected to stereologic analysis. A total of 18 biopsies (animals) were used. Biopsies were taken at 18, 48, 96 and 120 h after wounding. Point counting procedures were employed to analyse electron micrographs sampled from one (18 h) or two epithelial strata (48, 96 and 120 h). The essential modulations in epithelial structure as wound healing proceeds were as follows: During the early phases characterized by formation and advancement of epithelial lips (18 and 48 h), migrating cells converged towards a cell type which structurally was less differentiated than normal basal cells. This alteration was expressed by a decrease in volume density of cytoplasmic organelles, mainly mitochondria, free ribosomes and tonofilament bundles, coupled with an increase in volume density of lysosomal bodies. Concomitantly, the volume density of cytoplasmic ground substance rose markedly. Subsequent to fusion of contralateral migratory lips (96 and 120 h) reversion to normal epithelial structure was indicated by the increment in magnitude of basal cell parameters. Further structural density gradients from basal towards upper cell layers appeared. This pattern was mainly displayed by mitochondria, free ribosomes, and tonofilament bundles. The magnitude and gradation of most tissue and cell parameters were not yet re-established at 120 h. The density of tonofilament bundles and the density level of cytoplasmic ground substance in particular deviated.This investigation was supported in part by grants No. 512-5958 and No. 512-5151 from the Danish State Medical Research Council     

An ultrastructural study of the regenerating breast feather of the fowl

The developmental morphology of regenerating male breast feathers of the jungle fowl was studied at the ultrastructural level. The process of keratinization was observed in the three types of cells which form feather barbs: barbule cells, cortical cells, and medulla cells. Keratinization first became evident in the barbule cells and resembled the process of keratinization as observed in hair cortical cells and embryonic down feathers. Eventually the whole cytoplasmic area of the barbule cell was occupied by keratin. The barb cortex cells became keratinized in a similar fashion as the barbule cells but not until they were developmentally twice as old as the barbule cells. When keratinization was complete in these cells, the keratin was in the form of large agglomerates scattered in the cytoplasm. The barb medulla cells showed no obvious signs of keratinization until they were developmentally three times as old as the barbule cells. Keratin filament bundles were first seen near the plasma membranes of the medulla cells. Large empty vacuoles appeared in the cytoplasm which also contained moderate amounts of glycogen.     

Absorption of horseradish peroxidase by the small intestinal epithelium in postnatal developing rats.

After an intraluminal injection of horseradish peroxidase into the small intestine, the localization of peroxidase was studied in neonatal developing and adult rats by means of electron microscopy. Until around the 14th day of the neonatal period absorbed peroxidase granules in the duodenal and jejunal epithelium were abundant in the microvillous membrane, the apical tubulo-vacuolar system, and the Golgi apparatus, and on the lateral cell and basal membranes, and the luminal surfaces of the capillary cells. At the weaning period the tubulo-vacuolar system was absent in the duodenal and jejunal epithelial cells, and at that point absorbed peroxidase was observed in the same sites as in the adult rats: the microvillous membrane, the lateral cell and basal membranes, the Golgi apparatus, and the vesicles and vacuoles of the cytoplasm. During the suckling period, in the ileal epithelial cells exogenous peroxidase was found on the microvilli, in the tubulo-vacuolar system, in the supranuclear vacuole, in the Golgi apparatus, on the lateral cell and basal membranes, and also on the luminal surface of the endothelial cells of blood capillaries. When the tubulo-vacuolar system and the supranuclear vacuole were lost from the ileal cells at the weaning period, no exogenous peroxidase uptake was observed in the absorptive cell of the ileal epithelium.     

Immunomorphological analysis of G2-chalone localization during the process of rat epidermis histogenesis

The appearance of G2-chalone in the cytoplasm of the intermediate cell layer and partly in the periderm of 17-day-old rat embryo epidermis has been demonstrated by the indirect method of Coons using a monospecific antiserum. G2-chalone was absent from the basal cell layer of 17--21-day-old embryos and of the newborn rats. It was found in all the epidermal layers in 2--5-day-old postnatal rats, while in 6--9-day-old animals it was primarily detected in the cytoplasm of spinous and basal cells. Thus the localization of epidermal G2-chalone typical for defined tissue becomes stabilized at the end of epidermis histogenesis.     

Uptake of exogenous protein tracer in cells of the rat renal papilla

In order to study the phagocytic potential of different cell types of the rat renal papilla with special emphasis on interstitial cells, horseradish peroxidase (HRP) (8 mg/100 g body weight) was injected intravenously into adult rats. The distribution of peroxidase was studied in animals perfusion-fixed 60 and 180 min after injection and was found to be similar after both time intervals. The epithelial cells of the collecting ducts took up the largest amounts of the tracer. HRP was mainly located in large lysosome-like bodies in the basal part of the cytoplasm, suggesting peritubular uptake from the interstitial space. However, small amounts of the tracer were also seen in apical vesicles close to the luminal plasma membrane. The interstitial cells of peroxidase-injected animals were ultrastructurally altered and had large irregular invaginations of the cell membrane. The cells had taken up only small amounts of the tracer which were located in small round lysosome-like bodies. Thus, the interstitial cells displays no macrophage characteristics, either in the native state or when challenged with an extracellular protein.     

Keratinization of rat vaginal epithelium. II. Immunofluorescence study on keratin filaments in cycling and estrogen primed rats

Rat vaginal epithelial layers from animals in different phases of the estrous cycle showed positive immunofluorescence when treated with either monoclonal antibody to intermediate filaments or immunoglobulin G fraction of antiserum raised against epidermal keratin filaments. During estrus, the intensity of fluorescence observed was maximum in the keratinized cellular layers. In estradiol-primed immature and ovariectomized rats the maximum fluorescence intensity was observed in the layers immediately lining the lumen. However, basal layers in ovariectomized rats also showed some fluorescence. Data presented in this communication indicate that the abundance of keratin filaments in vaginal epithelial cells can be modulated by altering the level of estradiol in the system.     

Keratin incorporation into intermediate filament networks is a rapid process

The properties of keratin-containing intermediate filament (IF) networks in vivo were studied following the microinjection of biotinylated keratin. Keratin-IFs were biotinylated, disassembled, and separated into type I and type II proteins by ion exchange chromatography. Recombination of these derivatized type I and type II keratins resulted in the formation of 10-nm diameter IF. The type I keratins were microinjected into epithelial cells and observed by immunofluorescence microscopy. Biotin-rich spots were found throughout the cytoplasm at 15-20 min after injection. Short biotinylated fibrous structures were seen at 30-45 min after injection, most of which colocalized with the endogenous bundles of IF (tono-filaments). By 1 1/2 to 2 h after microinjection, extensive biotinylated keratin IF-like networks were evident. These were highly coincident with the endogenous tonofilaments throughout the cell, including those at desmosomal junctions. These results suggest the existence of a relatively rapid subunit incorporation mechanism using numerous sites along the length of the endogenous tonofilament bundles. These observations support the idea that keratin-IFs are dynamic cytoskeletal elements.     

Uptake of exogenous protein tracer in cells of the rat renal papilla

Summary In order to study the phagocytic potential of different cell types of the rat renal papilla with special emphasis on interstitial cells, horseradish peroxidase (HRP) (8 mg/100 g body weight) was injected intravenously into adult rats. The distribution of peroxidase was studied in animals perfusion-fixed 60 and 180 min after injection and was found to be similar after both time intervals. The epithelial cells of the collecting ducts took up the largest amounts of the tracer. HRP was mainly located in large lysosome-like bodies in the basal part of the cytoplasm, suggesting peritubular uptake from the interstitial space. However, small amounts of the tracer were also seen in apical vesicles close to the luminal plasma membrane. The interstitial cells of peroxidase-injected animals were ultrastructurally altered and had large irregular invaginations of the cell membrane. The cells had taken up only small amounts of the tracer which were located in small round lysosome-like bodies. Thus, the interstitial cells displays no macrophage characteristics, either in the native state or when challenged with an extracellular protein.Supported by Karolinska Institutet and the Swedish Medical Research Council (proj. no. 05937)     

Distribution and nature of desmosomes in the bovine developing ruminal epithelium.

Desmosomes entirely similar to those of the deeper layers of ruminal epithelium are seen in the luminal layers of the early fetal ruminal epithelium. In the older fetuses, these desmosomes have morphological features that reveal to some extent the occurrence of processes of keratinization. This could indicate that the basis for cell keratinization is already present in the fetus and that postnatal keratinization corresponds mainly to the full development of the prenatally existing pattern of differentiation.     

The terminal web. A reevaluation of its structure and function

The apical cytoplasm of epithelial cells of the small and large intestines has been examined by freeze-etch techniques as well as conventional and high voltage electron microscopy of sectioned material to gain a better understanding of the fine structural organization of the terminal web region. In the small intestine the terminal web exhibits a distinct stratification caused by the association of different sets of filaments with the three members of the junctional complex. Individual filaments of this network are closely associated with the sealing elements of the tight junctions, the surface of the core microfilament bundles, and the intermicrovillar plasma membrane. This region of the terminal web is the apical zone. The adherens zone appears as a band of interwoven filaments of two different diameters extending across the cytoplasm at the level of the intermediate junction. Within this region of the terminal web, individual 60-70 A actin-like filaments separate from the bundles of core microfilaments to interact with one another and with filaments of similar diameter from the zonula adherens. 100 A tonofilaments also contribute to the adherens zone, presumably stabilizing the orientation of the actin-like filaments. The basal zone which underlies the adherens zone consists of closely interwoven bundles of tonofilaments that are anchored to and interconnect the spot desmosomes. Within the large intestine the cytoplasmic microfilaments form a looser and less clearly stratified network which nevertheless retains the same basic organization found in the small intestine. Transmembrane linkers appear to originate within the cytoplasmic plaques of the spot desmosomes, pass through the plasma membranes, and meet in a staggered configuration in the intercellular space; these linkers may thus mediate the actual mechanical coupling between the cytoskeletal networks of tonofilament bundles of adjacent cells. This integrated system of cytoplasmic filaments and intercellular junctions endows the apical cytoplasm with both the flexibility and the stability necessary for the normal functioning of the epithelium.     

Immunocytochemical observations on the cornification of soft and hard epidermis in the turtle Chrysemys picta

The process of cornification in the shell and non-shelled areas of the epidermis of the turtle Chrysemys picta was analyzed by light and ultrastructural immunohistochemistry for keratins, filaggrin and loricrin. Beta-keratin (hard keratin) was only present in the corneus layer of the plastron and carapace. The use of a beta-keratin antibody, developed against a specific chick scale beta-keratin, demonstrated that avian and reptilian hard keratins share common amino acid sequences. In both, shelled and non-shelled epidermis, acidic alpha keratin (AE1 positive) was limited to tonofilament bundles of the basal and suprabasal layer, while basic keratin (AE3 positive) was present in basal, suprabasal, and less intensely, pre-corneus layers, but tended to disappear in the corneus layer. The AE2 antibody, which in mammalian epidermis recognizes specific keratins of cornification, did not stain turtle shell but only the corneus layer of non-shelled (soft) epidermis. Two and four hours after an injection of tritiated histidine, the labelling was evenly distributed over the whole epidermis of both shelled and non-shelled areas, but was absent from the stratum corneum. In the areas of growth at the margin of the scutes of the shell, the labelling increased in precorneus layers. This suggests that histidine uptake is only related to shell growth and not to the production of a histidine-rich protein involved in keratinization. No filaggrin-like and loricrin-like immunoreactivity was seen in the carapace or plastron epidermis. However, in both proteins, some immunoreactivity was found in the transitional layer and in the lower level of the corneus layer of non-shelled areas. Loricrin- and filaggrin-like labelling was seen in small organelles (0.05-0.3 mum) among keratin bundles, identified with mucous-like granules and vesicular bodies. These organelles, present only in non-shelled epidermis, were more frequent along the border with the corneus layer, and labelling was low to absent in mature keratinocytes. This may be due to epitope masking or degradation. The immunolabelling for filaggrin was seen instead in the extracellular space among mature keratinocytes, over a material previously identified as mucus. The possibility that this labelling identified some epitopes derived from degraded portions of a filaggrin-like molecule is discussed. The present study suggests that proteins with some filaggrin- and loricrin-immunoreactivity are present in alpha-keratinocytes but not in beta-keratin cells of the shell.     

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.     

Structure of the perineurium of the peripheral nervous system]

The structure of the perineurium in different parts of the peripheral nervous system of rats, rabbits and cats was studied by light-optical and electron microscopic methods. The structure of the perineurium in all the animals studied is sim8lar and consists of different number of the epithelial type layers of the perineural cells, with bundles of cooagnous fibres between them. The greatest anount of layers is found in the perineurium of the sensory and vegetative ganglia, their amount being less between the nerve trunks and bundles. Solitary sensory mielinated nerve fibres are surrounded with a perineural etui consisting of one or two cellular layers. The thickness of the perineural cells varies from 300 to 1500 A and only in the nucleus field it is equal to 1-2 mu. Every layer of the perineural cells is surrounded by a basal membrane. In their cytoplasm there are many pinocytic vesicles in addition to main organells. Between the perineural cells there exist close contacts. The internal layer of the perineurium is the place of origin of intraganglionic septa and in certain distance surrounds the vessels entering the ganglion. Ultrastructurally the perineural cells are similar to the endothelium of the vessels.     

On the presence of high glycogen concentration and intermediate filaments in the flat cells of the electroreceptive epidermis of mormyrid fish

The cytoplasm of the flat cells of the electroreceptive epidermis of Mormyrids was examined in the light and the electron microscope, in order to reveal the presence of glycogen and to study its distribution. In the electroreceptive epidermis, which consists of three layers, the periodic acid Schiff reaction used to stain polysaccharides is strongly positive in the superficial polyhedral cells and in the flat cells of the intermediate layer. Polysaccharides are absent in the basal polyhedral cells. Pre-incubation with alpha-amylase shows that glycogen is present only in the intermediate cell layer. In the electron microscope, after reaction with periodic acid, thiocarbohydrazide and silver proteinate, glycogen is seen in the form of rosettes of monoparticles. These rosettes occupy both the central region of the cytoplasm of these cells, and the more peripheral parts, where alignments of desmosomes are found. In the cytoplasm of certain flat cells, the rosettes are grouped to form accumulations of glycogen which cover several mu2. Observation in the electron microscope reveals that in addition to glycogen, these cells contain tonofilaments or intermediate filaments, common to epithelial cells, which may group themselves in bundles. Glycogen and the intermediate filaments are thus the principal constituents of the cytoplasm of the flat cells of the electroreceptive epidermis of Mormyrids. The possible role of the filaments, and especially of the glycogen which is a polysaccharide high in energy, in the flat cells which apparently have a low metabolic rate, is discussed.