Patterns of mitosis in hamster epidermis.

Alignment of the flattened keratinizing cells of the upper strata of mammalian epidermis leads to the formation of columnar units of structure. In mouse epidermis, mitoses have been found to occur relatively infrequently in the region beneath the center of each cell column where a non-keratinocyte dendritic cell, usually with freatures typical of an epidermal Langerhans cell, is situated. The observed pattern of mitosis could therefore be due either to displacement of central keratinocytes by Langerhans cells or indicate some control of keratinocyte proliferation related either to the Langerhans cells or to the over-lying cell columns. No relationship exists between the position of Langerhans cells and epidermal cell columns in hamster epidermis but measurement of the position of mitosis has shown a reduced frequency of occurrence of mitosis beneath the central region. This pattern of mitosis is therefore unrelated to Langerhans cells and appears to reflect differences in the mitotic potential of basal keratinocytes which could be associated with feedback from the overlying cell columns or with an intrinsic pattern of basal cell activity.     

Changes in Soybean Agglutinin (SBA) and Peanut Agglutinin (PNA) Binding Pattern in the Epidermis of the Developing Chick Embryo

Lectin binding pattern in the developing chick embryonic epidermis was studied using peroxidase labeling method. The epidermis of the 13-day-old embryo is in an undifferentiated state. Little binding of soybean agglutinin (SBA), specific for N-acetyl-D-galactosamine, and peanut agglutinin (PNA), specific for β-D-galactose, was seen in such epidermal cells. As the epidermis developed toward keratinization, the cell membrane of the differentiating flattened cells was positively stained with SBA and PNA. The positive staining was also seen in the supranuclear region of the cells located between the flattened cells and the basal cells. The basal cells remained unstained in all the stages of development. Similar staining pattern with SBA and PNA was seen in the cultured skin explants during the epidermal differentiation in vitro. These observations show that the SBA- and PNA-reactive glycoconjugates accumulate during the epidermal cell differentiation, suggesting their important roles in the maintenance of the ordered structure of the epidermis.     

DNA synthesis and content in the nuclei of epidermal cells of mice during their differentiation and specialization

Synthesis and content of DNA in the nuclei of differentiating cells of mouse skin epidermis was studied by using cytomorphometric, autoradiographic and cytophotometric methods. It has been shown that the cells of the keratinoid series divide only in the basal layer and contain 2-4c DNA. Keratinocytes of the thorny layer are mostly tetraploid, 2c cells are lacking. H4c and 8c cells comprise 12% of the population. In the keratinocytes of the granular layer DNA content is somewhat lower due to nuclei break down and conversion of cells into anucleate scale. Part of the melanocytes of the basal layer also contain 4c DNA. Highly specialized element of the basal layer Merkel and Langerhans cells are polyploid. Conclusion is drawn that DNA hyper-replication by multiplication of the whole genome is part of the development program of the population.     

KINETICS OF CELL RENEWAL, CELL MIGRATION AND CELL LOSS IN THE HAIRLESS MOUSE DORSAL EPIDERMIS

Forty hairless mice were given injections of tritiated thymidine every 4th hour during 10 days. At 24 hr intervals groups of four mice were killed. The numbers of labelled basal and differentiating cells were determined by autoradiography with a stripping film technique. To determine the background activity skin sections from uninjected control mice were subjected to the same stripping film procedure. Another group of hairless mice was given one single pulse labelling with tritiated thymidine. The number of labelled mitoses was scored for 12 hr after the injection. At 10, 12 and 15 hr after the injection, the numbers of labelled basal and differentiating cells were also determined. A mathematical model of cell population kinetics in the epidermis has been suggested. The results of different simulations on this model were compared with the observed results. The curve of mean grain counts under continuous labelling increased from day to day with two well-defined plateaux. The percentage of all labelled cells increased rapidly up to the 3rd day, and thereafter the curves gradually flattened off. When basal cells and differentiated cells were considered separately the labelling index of the basal cells increased rapidly for the first 3 days and then flattened off at the 100% level on the 5th day. The labelling index of the differentiating cells was low during the first 3–4 days. Then a steep increase in the percentage of labelled differentiating cells was seen, but the curve flattened off again close to the 100 % level after the 7th day. The labelled mitosis curve had its maximum 5 hr after the thymidine injection. The curve fell again to almost zero at 12 hr. Ten, 12 and 15 hr after the injection, 6, 7 and 7% respectively of the labelled cells were found in the spinous layer. It was concluded that three grains over each nucleus could be used as lower limit for considering a cell as labelled. On this basis, tritiated thymidine injections every 4th hour can be considered as continuous labelling.     

The assessment of post mortem structural changes in the human epidermis

The structure of epidermis and appearance of keratinocytes is described in intact skin specimens from human corpses stored after death under refrigeration. Two groups of alterations can be identified depending on the epidermal layer. In the spinous layer, the cells are characterized by crescent-shaped nuclei surrounded by a hollow area. The number of such cells increases significantly each day during the first 8 days post mortem (dpm), and their frequencies follow respective regression equations, so as to enable the post mortem time estimation with one day accuracy. In the basal layer, distorted, balloon-shaped cells with pycnotic nuclei appear, which with the lapse of time are forming groups, and eventually the epidermis in those places separates from the dermis. The presence of both described changes seems to indicate whether the skin sample was obtained from the living organism or after the death.     

Ultrastructure of the epidermis of the lizard (Lacerta vivipara) at the resting stage of the sloughing cycle

The ultrastructure of the epidermis of the lizard ( Lacerta vivipara ) one day after sloughing is described. The non-keratinized layers of the epidermis are essentially similar in structure to those of amphibians and mammals. The cells of the basal layer are not however separated from each other by the large spaces described in the amphibian (Farquhar & Palade, 1965). The middle layers of the epidermis at this stage of the sloughing cycle produce neither the characteristic mucous granules found in amphibians nor the keratohyalin granules of mammals. A small number of granules corresponding in size and location to the "Odland bodies" of both mammalian and amphibian epidermis are, however, present. The intermediate layer cells also contain a number of bodies similar in appearance to those described by Farquhar & Palade as lysosomes in amphibian skin. These structures are both osmium iodide and acid phosphatase positive. Unlike the condition in amphibians and mammals, the cytoplasm of cells in the layer immediately beneath the keratinized strata is honeycombed with small vesicles, and contains large irregular vacuoles of uncertain content. Certain nonkeratinizing elements within the epidermis are tentatively interpreted as nerve terminations. Two morphologically distinct keratinized strata can be distinguished, the inner stratum consisting of flattened cells similar to those of the stratum corneum of mammalian epidermis; individual cell outlines cannot be distinguished in the outer stratum, which has a structure similar to that of avian feather keratin. A shallow surface zone of the outer keratinized stratum has been identified as the Oberhautchen. This consists of longitudinally disposed leaflets or laminae which are responsible for the sculptured pattern of the epidermal surface. The observations reported here provide a basis for analysis of changes occurring at other stages of the sloughing cycle.     

Analysis of the cellular heterogeneity in the basal layer of mouse ear epidermis: an approach from partial decomposition in vitro and retroviral cell marking in vivo

In the thin epidermis, the existence of epidermal proliferation units was hypothesized. Each unit is supposed to be partitioned into each column of polygonal-shaped cornified plates, estimated to contain a central stem cell in its basal layer. We attempted to verify this hypothesis in vitro by analyzing the partially decomposed fragment of mouse ear epidermis and in vivo using retroviral cell marking. Partially decomposed fragments of the mouse ear epidermis, mostly composed of cytokeratin 14-expressing basal keratinocytes, formed multicellular colonies in vitro. They were composed of heterogeneously shaped cells, morphologically resembling the cells in each single cell-derived colony, including potential stem cells with great proliferative potency in vitro. The estimated frequency of the candidates of stem cells in the fragments was much lower than the prediction from the representative hypothesis. Retroviral cell marking with nuclear localizing LacZ protein in vivo suggested the existence of a large clonal cellular unit for epidermal renewal. From these in vitro and in vivo observations, we propose a new model for the epidermal proliferation unit.     

Fine structure of taste buds in the barbel of the catfish,Ictalurus punctatus

Summary Taste buds occur in the epithelium of the catfish barbel along its entire length. Two major cell types, light and dark cells, occupy the upper two-thirds of the taste bud. A third cell type, the basal cell, lies on the basal lamina and is essentially separated from the light and dark cells by a plexus of unmyelinated nerve fibers. The dark cells have branching processes, both apically and basally whereas the light cells have a single apical process and many basal processes. The apical processes of dark cells contain secretory granules, while the apical processes of light cells contain an abundant agranular endoplasmic reticulum. Light cell nuclei contain bundles of 10 nm filaments, often arranged in the shape of a cup or ring, but nucleoli are rarely seen. It is suggested that this morphology indicates a low degree of RNA synthesis by light cells. The basal cells contain large numbers of vesicles, about 60 nm in diameter, which are sometimes seen in clumps in relation to an adjacent nerve fiber in a configuration resembling a synapse. Curiously, although basal cells present a large surface to the basal lamina, there are no hemidesmosomes. This suggests that the basal cell does not originate from the epidermis.Supported by grant#NS-06181 from the National Institute of Neurological Diseases and Stroke, U.S. Public Health Service     

Epidermal Growth Factor and EGF Receptors are mainly expressed in the wound epidermis and proliferating ependyma of the regenerating tail of lizards

The presence of EGF and its receptor during tail regeneration in lizard has been assessed by immunoblotting and immunofluorescence to test whether this growth factor may be involved in the process. Immunolabelled bands at 8 and 42–46 kDa for EGF are detected in the regenerating tail. A main band at 45–50 kDa and other weaker bands at lower or higher molecular weight for the EGF receptor are also present. The results indicate that degraded forms of the protein are present although the specific nature of the different bands could not be determined. Immunofluorescence indicates that EGF-labelled cells and EGF receptor are especially seen in the wound epidermis and in the cytoplasm of ependymal cells. Numerous basal keratinocytes of the wound epidermis and apical epidermal peg contain labelled nuclei for EGFR, suggesting that activated receptor stimulates intense cell proliferation of the wound epidermis. Blastema and labelled myoblasts are occasionally detected in early differentiating muscles, but almost no labelled chondroblasts are present in the differentiating cartilaginous tube. The study indicates that EGF and its receptor are mainly present in epithelial cells in a form that allows them to regulate proliferation during tail regeneration.     

T-2 toxin-induced acute skin lesions in Wistar-derived hypotrichotic WBN/ILA-Ht rats

Acute lesions in the dorsal skin topically applied with T-2 toxin (10 microliters of 0.5 mg/ml-solution to 1 cm2) were examined in Wistar-derived hypotrichotic WBN/ILA-Ht rats up to 24 hours after treatment (24HAT). In the epidermis, depression of basal cell proliferating activity was detected at 3HAT by immunostaining for proliferating cell nuclear antigen (PCNA), and the percentage of PCNA-positive basal cells decreased thereafter. At 12HAT, in addition to intracytoplasmic edema of spinous cells, acidophilic degeneration of basal cells characterized by shrinkage of cell body with acidophilic cytoplasm and pyknotic or karyorrhectic nuclei became prominent. Most of these nuclei were positive for TUNEL which is a widely used immunostaining for the in situ detection of fragmented DNA, i.e. apoptosis, and the percentage of TUNEL-positive basal cells increased thereafter. The nuclei of these basal cells also showed ultrastructural changes characteristic for apoptosis. On the other hand, in the dermis, infiltration of inflammatory cells including mast cells started at 3HAT and increased thereafter. In addition, capillary and small vessel endothelial degeneration developed at 6HAT and progressed thereafter. These results suggest that T-2 toxin directly affects the epidermis and produces apoptosis in basal cells.     

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.     

ELECTRON MICROSCOPE STUDIES OF EPIDERMAL MELANOCYTES, AND THE FINE STRUCTURE OF MELANIN GRANULES

Melanocytes and melanin granules have been studied by electron microscopy in normal human and cat skin, and in hyperplastic human skin lesions. The melanocytes have always been found as free cells within the epidermis,i.e., on the epidermal side of the dermal membrane. Melanocytes frequently rest on the dermal membrane or bulge towards the dermis. In such cases the uninterrupted dermal membrane is uniformly thin and smooth in appearance, in contrast with the regions alongside Malpighian cells, where it appears appreciably thicker and seemingly anchored to the basal cell layer. Two types of melanin granules have been distinguished according to their location in the melanocytes and to morphological characteristics which may only express different stages in the maturation of the granules: (a) light melanin granules in which a structure resembling a fine network is apparent; (b) dense melanin granules which, in osmium-fixed preparations, appear as uniformly dense masses surrounded by a coarsely granular, intensely osmiophilic shell. Treatment of sections of osmium-fixed tissues with potassium permanganate has revealed within the dense granules the existence of an organized framework in the form of a regular, crystalline-like lattice. It is suggested that this basic structure is protein in nature and may include the enzymatic system capable of producing melanin. The existence is reported of fine filaments located in the cytoplasm of melanocytes and morphologically distinct from the tonofilaments found in Malpighian cells.     

Relationship between Endopolyploidy and Cell Size in Epidermal Tissue of Arabidopsis

Relative quantities of DNA in individual nuclei of stem and leaf epidermal cells of Arabidopsis were measured microspectrofluorometrically using epidermal peels. The relative ploidy level in each nucleus was assessed by comparison to root tip mitotic nuclei. A clear pattern of regular endopolyploidy is evident in epidermal cells. Guard cell nuclei contain levels of DNA comparable to dividing root cells, the 2C level (i.e., one unreplicated copy of the nuclear DNA). Leaf trichome nuclei had elevated ploidy levels of 4C, 8C, 16C, 32C, and 64C, and their cytology suggested that the polyploidy represents a form of polyteny. The nuclei of epidermal pavement cells were 2C, 4C, and 8C in stem epidermis, and 2C, 4C, 8C, and 16C in leaf epidermis. Morphometry of epidermal pavement cells revealed a direct proportionality between nuclear DNA level and cell size. A consideration of the development process suggests that the cells of highest ploidy level are developmentally oldest; consequently, the developmental pattern of epidermal tissues can be read from the ploidy pattern of the cells. This observation is relevant to theories of stomate spacing and offers opportunities for genetic analysis of the endopolyploidy/polyteny phenomenon.     

A computer simulation of cell stacking for even thickness in mammalian epidermis

The method of even stacking of epidermal cells in mammalian skin was studied by computer simulation. The epidermis consists of neat vertical columns of stacked, flattened, tetrakaidecahedral cells. Cells which have been proliferated in a basal layer migrate upwards, occupy the bottom regions of vertical columns, and become members constituting columns. Computer simulations demonstrated that the column height becomes considerably varied if the cells are randomly supplied from the basal layer. In contrast, if the cells are assumed to have an ability to find the uppermost region among the column's bases consisting of one base where the cell has reached and its neighbouring bases, the cells stack into columns whose heights are remarkably uniform even if the cells are randomly supplied. The results indicated that an epidermal structure consisting of the flattened polyhedral cells could itself function as a control mechanism of the epidermal thickness.     

The skin of primates. XXXIX. The skin of the white-browed capuchin (Cebus albifrons)

The skin of the white-browed capuchin (Cebus albifrons), although basically similar to that of the squirrel monkey (Saimiri sciureus), contains several outstanding peculiarities: (1) both the epidermis and dermis of the general body surface are devoid of melanotic melanocytes; (2) the skin of the prehensile tail has no modified, glabrous friction surface; (3) the prehensile surface of the tail has no specialized nerve end-organs; (4) cholinesterase-positive, papillary nerve end-organs rest beneath the epidermal ridges of volar skin; and (5) both the clear cells and dark cells of the eccrine glands contain glycogen but neither shows phosphorylase activity.     

miRNAs, 'stemness' and skin

The epidermis and its appendages provide organisms with protection from the environment, keeping pathogens out and preventing the loss of essential body fluids. To perform both functions, the skin has elaborated a complex differentiation process known as cornification. The renewal capacity of the skin, which is responsible for maintaining tissue homeostasis, regenerating hair and repairing the epidermis after injury, resides in the basal proliferating compartment in which epidermal stem cells are located. These cells possess the remarkable capacity to both self-perpetuate and give rise to the differentiating cells that form mature tissues. Recent findings indicate that microRNAs have an essential role in orchestrating the formation of epidermis and skin appendages, in particular, at the interface between stemness and differentiation.     

A STUDY OF THE FINE STRUCTURE OF THE EPIDERMIS OF RANA PIPIENS

The epidermis of adult Rana pipiens has been studied by electron microscopy and histological and histochemical methods. It was found that the epidermis is engaged in the production of both keratin and mucus. The basal cells are mainly filled with tonofilaments, whereas the cells located in the mid-portion of the epidermis contain both tonofilaments and mucous granules. Golgi vesicles and endoplasmic reticulum are found in relative abundance in the mucus-producing cells and seem to be involved in the production of mucous granules. The mucus seen was partly retained within the cells and partly secreted into the intercellular spaces. The outermost keratinized cells contain mainly filaments and a few remnants of cell constituents.     

EARLY AND LATE INCORPORATION OF TRITIATED THYMIDINE INTO SKIN CELLS AND THE PRESENCE OF A LONG-LIVED G0-SPECIFIC PRECURSOR POOL

40 min after a single injection of 50 µCi of tritiated thymidine a 3 mm punch of DBA-1 mouse skin contains about 1000 dpm. This value remains constant for at least 48 hr after injection. 50 hair follicles contain about 40 dpm, and from these values the activity calculated to reside in the basal layer of a 3 mm punch of skin is 760 dpm. These values also remain constant with time after injection. Fresh punches of skin contain much more activity. The fixative-soluble fraction (the difference between fresh and fixed values) decays slowly with time. The values for DBA-2 mice are similar. Plucking the hair from the follicles appears immediately to increase the size of the fixative-soluble fraction and decrease the fixed tissue values to about 500 dpm per punch for whole skin and about 1 dpm per 50 follicles for DBA-1. Thus almost all the activity is restricted to the epidermis. The fixative-soluble fraction returns approximately to the unplucked value between 24 and 48 hr after plucking. However, during this period the fixed tissue values are rising rapidly as stimulated cells enter S. It appears that in both strains labeled material remains available for incorporation into stimulated cells for at least 48 hr after a single injection. The amount persisting appears to decrease with time. The whole-fixed skin, the hair follicles, and the epidermis all contain cells that are capable of becoming labeled after stimulation 8–48 hr after an injection. The label in question does not become incorporated into normal cycling skin or hair follicle cells. It is concluded that the DNA precursor pool is possibly connected with G₀ cells and that both the hair follicle and the basal layer of the epidermis contain these resting cells.     

Dolichos biflorus agglutinin (DBA) reveals a similar basal cell differentiation in normal and psoriatic epidermis

Binding of N-acetyl galactosamine (GalNAc)-specific Dolichos biflorus agglutinin (DBA) conjugates to frozen sections of normal epidermis and of psoriatic uninvolved and lesional skin was studied in fluorescence microscopy. The DBA conjugates bound only to single basal cell layer in normal and uninvolved psoriatic epidermis from patients with different blood group status. In the lesional area of psoriatic skin a similar reaction with a single basal cell layer was revealed. Other lectin-conjugates applied, presenting also GalNAc specificity, reacted with most cell layers of normal and both uninvolved and lesional psoriatic epidermis and gave an attenuated reaction with the middle epidermal layers. The results show that the basal cell characteristics are confined only to the cells along the basal membrane also in psoriatic epidermis, although cells in three lowest layers may be able to proliferate.     

Emigration of bilayered epidermal cell sheets from tadpole tails (Xenopus laevis)

Summary Migration of bilayered epidermal cell sheets out of explants of tadpole tails (Xenopus laevis) were investigated with time-lapse cinemicrography using reflection-contrast optics. Cell-sheet formation begins beneath the explant in a region where it is closely attached to the coverslip. A single basal cell extends a lamellipodium through the outer (surface) epidermal layer and starts moving in a direction free of attached cells. This cell remains connected to the following basal cell, which the also extends a lamellipodium onto the glass. The cell sheet develops as increasingly more adjacent basal cells start to migrate. Surface cells do not actively locomote but they remain attached to the basal cells and to adjacent surface cells. Thus, they are transported as an intact cell layer, and consequently the in situ arrangement of the tadpole epidermis is largely preserved in the cell sheet, i.e., basal cells adhere to the substratum and are covered by outer cells (surface cells) which face the culture medium. Basal cells extend lamellae beneath the rear end of the preceding cell, which is slightly fifted off the substratum. The direction of locomotion is determined by the frontal cells. Cell-sheet enlargement and locomotion cease when all the epidermal cells facing the coverslip have left the explant, and the cell sheet and epidermis covering the explant form a continuous layer.