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.     

Plantar epidermis of the guinea pig and characteristics of the stratum corneum.

The guinea pig plantar epidermis was examined by light-microscopical histochemical methods and by transmission electron microscopy. Autolysis of cell structure was much less complete in guinea pig plantar horny layer than in the back, and stainable cytoplasm was retained in keratinized cells but organelles were lost except for some degraded ultrastructural remnants. By light microscopy the whole thickness of the horny layer showed bound phospholipid and bound cysteine, and there was a weak cystine reaction at the peripheries of the keratinized cells. In ultrastructure the keratohyalin contained slightly larger subparticles than in the back skin. The horny layer was not divisible into basal, intermediate and superficial regions as in hairy skin. The stratum lucidum of light microscopy was not defined in electron micrographs. Osmium-stained cytoplasmic material was retained in horny cells about to be desquamated, in contrast to the empty appearance of these cells in hairy skin. Epidermal cells in plantar skin have ultrastructural cytoplasmic processes which are longer than they are broad. In the horny layer these interdigitate with those of neighbouring cells and are held together by lateral demonsomal junctions. Probably this gives mechanical strength against shearing forces experienced by the plantar horny layer.     

A comparison of the epidermis and pigment cells of the crocodile with those in two lizard species

Keratinization and pigmentation in Crocodilus niloticus skin were compared with the conditions in the lizards Lacerta viridis and Anolis carolinensis. The epidermis, both in the crocodile and in lizards, is arranged to form a surface pattern of scales and narrower intervening hinge regions. Similar keratin-bound substances were found in the crocodile and lizard stratum corneum. Nevertheless, the greater uniformity in histological structure and in distribution of chemical substances throughout the depth of the crocodile stratum corneum was in marked contrast to the lizards, which showed morphological differences, and differences in intensities of chemical reactions in the horny cells laid down early and late in each keratinization cycle. In the crocodile, keratin-bound S-S and SH are uniformly distributed in the horny scales, but in the lizards the superficial cells have most S-S and the lowermost keratinized cells most SH. The loosely arranged horny cells in the crocodile are shed in small flakes as in mammals, in contrast to lizards which undergo periodic sloughs of a compact stratum corneum. In the lizards, the intermediate layer between two horny layer generations contains no detectable S-S and is probably unkeratinized, so that when these cells die a fission zone is formed. The crocodile scales each contain a raised pigmented papule in which melanin is introduced into the epidermal cells, and keratinization is also different from the neighbouring area. Guanophores and lipophores are absent in the crocodile, although present in the lizards. All contain prominent dermal melanophores.     

Histochemistry and the structure of the epidermis of a fresh-water teleost Noemacheilus botia (Hamilton-Buchanon) (Cobitidae, Pisces)

Functional organization and the histochemical nature of the various cellular components of the epidermis of Noemacheilus botia are described. The various histochemical techniques reveal the basic proteinaccous nature of the outer free margins of the polygonal cells of the most superficial layer of the epidermis. These cells remain metabolically active as revealed by their healthy nuclei and are not sloughed off at the surface. the lateral cell membranes of these cells are fused together forming a continuous barrier which plays important role in water proofing the skin. In addition the polygonal cells in the most superficial layer also undergo the process of mucogenesis synthesizing sulphated acid mucopolysaccharides which may ultimately form a part of the contents of the protective extracellular cuticular coat.     

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.     

A quantitative histochemical study of sulphydryl and disulphide content during normal epidermal keratinization

Summary A quantitative histochemical study was carried out on the distribution of protein thiol and disulphide groups in normal human plantar epidermal tissue. Histochemical demonstration of reactive groups was achieved by addition ofN-(4-aminophenyl) maleimide, subsequent diazotization and final coupling with a Nitro Red or chromotropic acid label as first described by Sippel. The quantitative reliability of the method was tested by absorption cytophotometry, and evaluated on the basis of the internal consistency of the results reported.Our histological observations and histophotometric data support accepted views on epidermal keratinization. A limited, though reproducible, amount of disulphide bonds was observed near the basement membrane. The free thiol concentration in basal and prickle cells was low and almost constant, but was higher in the granular cells, where deposition of sulphur-containing proteins on cell membranes is initiated. In Malpighian layers, disulphide cross-links only occurred just beneath the transition zone in thickened cell membranes. The staining pattern of the inner stratum corneum resembled a mosaic and was characterized by a sharp rise of the disulphide content, which exceeded the decrease in free thiol groups. The free thiol concentration decreased further throughout the cornified layers whilst the disulphide content remained fairly constant. Staining of thiol and disulphide groups together corresponded, within the limits of the standard error, to the sum of the thiol and disulphide concentrations when they were assayed separately in living and horny cells. These results confirm that living cells are the main site of free thiol groups, while horny cells are the most prominent site of disulphide cross-links.     

THE CHEMICAL NATURE OF KERATOHYALIN GRANULES OF THE EPIDERMIS

Keratohyalin granules were isolated in the native form from the epidermis of newborn rats by the use of citric acid and a detergent. The isolated granules revealed a fine granular substructure in the electron microscope similar to that seen in situ. Analyses of amino acids by automated column-chromatography showed that proline and cystine are present in large proportions whereas histidine is present in a small amount. Accordingly, it was concluded that keratohyalin represents a sulfur-rich amorphous precursor of the horny cell content, rather than a sulfur-poor side product of the keratinization process, or a unique histidine-rich protein as proposed by in situ histochemical and radioautographic studies.     

ε-(γ-Glutamyl)lysine Cross-link in the Terminal Differentiation of Mammalian Epidermis

Purified horny cell membrane of the epidermis of newborn rat was prepared by discontinuous sucrose density gradient ultracentrifugation after 0.1 n sodium hydroxide treatment. ε-(γ-Glutamyl)-lysine cross-link was identified mainly in the horny cell membranes of the epidermis of newborn rat, cow snout, and human stratum corneum. When, [¹⁴C]-lysine was incubated with minced epidermis of newborn rat, [¹⁴C]-lysine labeled ε-(γ-glutamyl)lysine cross-link was identified in purified horny cell membrane. Results indicate that the protein newly synthesized in the granular layer might play a role in the formation of thickened cell membrane in the late stage of the epidermal differentiation.     

Ultrastructural observations on effects of different concentrations of calcium and thyroxine in vitro on larval epidermal cells of Rana catesbeiana tadpoles

Summary During anuran metamorphosis dramatic changes in morphogenesis and differentiation of epidermis occur under the influence of thyroid hormones. Modification of ionic calcium concentration also markedly alters the pattern of proliferation and differentiation in amphibian epidermal cells in vitro. The present study was designed to determine the direct effect of low (0.05 mM) and high (0.5mM) calcium (Ca²⁺) in the absence or presence of thyroxine (10⁻⁷ M) on epidermal cells of the body and tail tissue in vitro. When tail fin and body skin explants were maintained in low (0.05 mM) calcium for 48 h, normal ultrastructural morphology and integrity of the cells was observed in both the tissue types. When tissues were exposed to high levels of calcium (0.5mM) in culture medium, tail epidermis showed stratification, and skein cells exhibited apoptosis, both in the presence or absence of thyroid hormones. Under high calcium conditions, the body epidermis showed keratinization of apical cells, apoptosis of skein cells, and increased desmosome formation. These results suggest that (1) optimal Ca²⁺ concentration for larval epidermal cells is quite low (0.05 mM), (2) high Ca²⁺ leads to keratinization only in body epidermis, and (3) apoptosis occurred in skein cells of both the tissues at high Ca²⁺ concentrations (0.5mM). The present study therefore suggests that the extracellular calcium concentration regulates the process of cell death and differentiation inRana catesbeiana larval epidermis, and this effect may be similar to the effect of calcium on mammalian epidermal cells.     

A histochemical study of keratinization in the domestic fowl (Gallus gallus)

The microanatomy of the epidermis of the domestic fowl is described and related to the distribution of various histochemical constituents involved in keratinization.
The avian horny layer over the back is composed of a loose network of structurally solid horny cells. This is in contrast to most mammalian epidermal horny cells in which structural keratin is found only in the peripheral cytoplasm, and the interior of the keratinocyte contains soluble products of cytolysis with possibly some free keratin filaments dispersed in the fluid material.
The avian tarsal epidermal horny scales show similarities to both the scales of lizards and snakes and to mammalian tail scales which appear to be homologous structures.
It is suggested that a thin layer of cells containing no detectable disulphide bonds, found in the tarsal scale region of the young chick, is probably mechanically weak and may function as a fission plane for sloughing of the horny layer. A specialized epidermis and thickened horny layer is developed in the fowl on the plantar underside of the toes, but this is quite different in structure from the mammalian plantar epidermis.
The overlapping of zones rich in ribonucleic acid (RNA) and bound cysteine (SH) in the growing feather suggests that protein synthesis and the preparatory stages to keratin disulphide bonding normally occur concurrently in feather formation. This is in contrast to the growing hair which has a region rich in RNA followed immediately before it becomes keratinized by a discrete keratogenous zone weak in RNA but rich in bound cysteine.     

The very rapid induction of filopodia in insect cells

Many insect cells, including epidermis, fat body, ocnocytcs and pericardial cells, can very easily be induced to form long fine processes or filopodia. Filopodia contain microfilaments hut differ from epidermal feet in lacking microtubules and in having a much smaller and uniform diameter. Although they may be 10-30 mum long they are less than 0.1 mum wide. They often form straight connections like guy-ropes between their origins and their tips, and when freed from their surface attachments they may contract into helices, as though capable of generating tension. The basal lamina helps to keep the basal surfaces of epidermal cells together. In Rhodnius epidermis, filopodia form only seconds after its removal. They arise at the cell margins and extend to distant part of neighbouring cells where they adhere particularly at their tips. Such filopodia retract and disappear in 20-60 min with the reformation of the basal lamina as though they have functioned to pull neighbouring cells back together. In Calpodes epidermis, filopodia form from the lateral faces as well as the cell margins after trypsin digestion of desmosomes and hemidesmosomes. The observations suggest that filopodia are induced in response to cell separation and function to restore cell to cell continuity. Filopodia also form in the normal course of development where cells separate prior to their rearrangement to make new tissues as in epidermal and fat body metamorphosis. Filopodia are probably ubiquitous agents for the sensing and movement of cells relative to one another in tissue morphogenesis.     

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

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

Morphology of the oral disc of Bufo bufo (Salientia: Bufonidae) tadpoles

The fully developed oral disc of the tadpole of Bufo bufo consists of dorsal and ventral labia bearing, respectively, two and three ridges bearing numerous horny denticles, a horny beak provided with jaw sheath serrations, and large lateral papillae that are borne by two cutaneous plicae. As development progresses toward metamorphosis, these structures gradually regress until they disappear. Each cusped clavate labial denticle adheres, by means of a thin peduncle, to a similar labial denticle fixed in the lip and formed by a group of three or four cells that keratinize gradually and thus present remarkable differences in their morphology. Once all the cells of a group have been converted into horny tissue, the denticle sheds and is replaced by the underlying one. The beak serrations also are horny structures; each consists of a columnar band of cells which undergoes a gradual keratinization. The horny cells that detach themselves at intervals, being replaced by those of the underlying anlagen. The labial denticles and the beak serrations keratinize in two distinct ways. In the former, the desmosomal filaments appear to play an important role whereas, in the latter, the keratin seems to be synthesized “ex novo” by the ribosomes.     

Horny cell formation in the epidermis of Rana pipiens

Well preserved transitional cells were found between differentiated cells and horny cells of the frog epidermis, thus facilitating the study of the sequential events involved in horny cell formation. Autolysosomes appear to play an important role in the formation of horny cells. These structures preferentially digest those cytoplasmic components which are not necessary constituents of the terminal horny cell. The release of the contents of the small mucous granules into the intercellular spaces is one of the initial events in horny cell formation. Filaments and large mucous granules seem to be resistant to the lytic digestion and contribute to the bulk of the horny cell. Loss of fluids through the plasma membrane and consolidation of the remaining constituents, results in a flattened horny cell. The appearance of a thickened membrane around the horny cell signifies the completion of the transformation process.     

Carbohydrate histochemistry of the epidermis of Natrix piscator during its sloughing cycle

Carbohydrate histochemistry of the scale and hinge epidermis of the chequered water snake, Nalrix piscator , throughout the sloughing cycle, has been described. The small amount of mucopolysaccharide present in the Oberhautchen, mesos layer, α-layer and β-Mayer (in its initial stage of differentiation) is comparable with that in amphibian epidermis and the epidermis of certain freshwater fish undergoing keratinization. Moderate amounts of mucopolysaccharide in the lacunar tissue and clear layer may protect against environmental pathogens and retain water to protect the epidermis from desiccation. Mucous cells could not be located in the epidermis throughout the sloughing cycle, contrary to some previous observations that they occur in the hinge region. The general absence of glycogen in the epidermis in most stages of the sloughing cycle suggests that the glycogen metabolized in the epidermis is utilized immediately, in view of the high energy requirements of proliferation and differentiation. Accumulation of glycogen granules in the presumptive α-layer in stage 2 and in the clear layer, presumptive Oberhautchen and presumptive β-Mayer in stage 3 is correlated with low energy requirements, indicating a slowing down of the process of keratinization of cells in these layers.     

Keratinization of fish skin with special reference to the catfish Bagarius bagarius

Summary Histochemical reactions indicating keratinization have previously been demonstrated in parts of the epidermis of Bagarius bagarius. Fluorescence histochemistry and electron microscopy have now confirmed these results. Elevated areas of the epidermis are capped by a layer of dead cells with altered contents. On the outer aspect of these cells a dense layer, 18 nm thick, beneath the plasma membrane corresponds to the resistant envelope found in keratinized cells in tetrapod vertebrates. In Bagarius this layer does not extend to all faces of the keratinized cells, but a similar envelope has been detected in two other sites of piscine keratinized epidermis investigated, namely in the breeding tubercles of Phoxinus phoxinus and in the teeth of Lampetra fluviatilis. In the elevated areas of Bagarius-epidermis, the epithelial cells undergo progressive changes in cytoplasmic organization as they become more superficial. The second tier from the surface is sealed by tight junctions and is separated from the overlying keratinized cells by a sub-corneal space resembling that found in keratinized amphibian epidermis. Histochemical evidence of a high lipid content in the outer layers of the epidermis correlates with the presence of lipid inclusions and lamellated membranous profiles in the material studied by electron microscopy. Histochemical results show that the fin skin of Blennius pholis is not keratinized, but secretes a cuticle, histochemically reactive for both proteins and glycoproteins.     

Adaptation to the land: The skin of reptiles in comparison to that of amphibians and endotherm amniotes

The adaptation to land from amphibians to amniotes was accompanied by drastic changes of the integument, some of which might be reconstructed by studying the formation of the stratum corneum during embryogenesis. As the first amniotes were reptiles, the present review focuses on past and recent information on the evolution of reptilian epidermis and the stratum corneum. We aim to generalize the discussion on the evolution of the skin in amniotes. Corneous cell envelopes were absent in fish, and first appeared in adult amphibian epidermis. Stem reptiles evolved a multilayered stratum corneum based on a programmed cell death, intensified the production of matrix proteins (e.g., HRPs), corneous cell envelope proteins (e.g., loricrine-like, sciellin-like, and transglutaminase), and complex lipids to limit water loss. Other proteins were later produced in association to the soft or hairy epidermis in therapsids (e.g., involucrin, profilaggrin-filaggrin, trichohyalin, trichocytic keratins), or to the hard keratin of hairs, quills, horns, claws (e.g., tyrosine-rich, glycine-rich, sulphur-rich matrix proteins). In sauropsids special proteins associated to hard keratinization in scales (e.g., scale beta-keratins, cytokeratin associated proteins) or feathers (feather beta-keratins and HRPs) were originated. The temporal deposition of beta-keratin in lepidosaurian reptiles originated a vertical stratified epidermis and an intraepidermal shedding layer. The evolutions of the horny layer in Therapsids (mammals) and Saurospids (reptiles and birds) are discussed. The study of the molecules involved in the dermo-epidermal interactions in reptilian skin and the molecular biology of epidermal proteins are among the most urgent future areas of research in the biology of reptilian skin.     

Isolation of plasma membrane from amphibian epidermis: evidence for a basal-to-apical charge and activity gradient

Aqueous two-phase partition and preparative free-flow electrophoresis were used in series to isolate the plasma membranes of amphibian epidermis. Fractions obtained by two-phase partition were 40-fold enriched in a K+-stimulated, ouabain-inhibited, p-nitrophenylphosphatase relative to the total homogenate and based on morphology were representative isolates of all epidermal cells together. Small mucosal granules and mucin aggregates were the primary contaminants. Based on activities of marker enzymes, contents of mitochondria, Golgi apparatus and endoplasmic reticulum were low (0.15 that of total homogenate) or absent. When plasma membranes isolated by aqueous two-phase partition were subjected to preparative free-flow electrophoresis, they were distributed toward the anode in a series of fractions of increasing net negative charge, sialic acid content and specific activity of the K+-stimulated, ouabain-inhibited, p-nitrophenylphosphatase reminiscent of the activity gradient from base to apex for frog epidermis observed from cytochemical investigations. The most electronegative fractions nearest the anode and to the left of the main protein peak were enriched in both sulfate groups and thick membranes of the stratum corneum. A fraction migrating less toward the anode and to the right of the main protein peak contained hemidesmosomes together with the lowest enrichments of sialic acid, sulfate and the phosphatase. The results suggest that the plasma membranes isolated from mixed cell populations, such as those encountered in epidermal homogenates, may be resolved by free-flow electrophoresis according to cell type of origin following activity gradients present in the original tissue. Additionally, the findings provide independent biochemical confirmation of a base-to-apex gradient of transport (ATPase) activity associated with the plasma membranes of cells of the different strata of the amphibian epidermis.     

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.     

Ultrastructural study of the mental body of Hydromantes genei (Amphibia: Plethodontidae)

The mental glands of Hydromantes genei are considered a specialized form of the urodele serous cutaneous glands. Use of a variety of techniques of maceration and digestion as well as transmission electron microscopy (TEM) and scanning electron microscopy (SEM) has shown the three-dimensional morphology of secretory and myoepithelial cells. Secretory cells are pyramidal and rest on an almost continuous layer of myoepithelial cells. The latter have a long ribbon-like body from which branch off transversal and longitudinal processes with swallow-tailed ends. Cytoplasmic processes of secretory cells, containing irregular dense vesicles, squeeze through clefts between myoepithelial cells and may reach, at some points, the basal lamina. The interstices between myoepithelium and secretory cells are extraordinarily rich in nerve endings with clear vesicles. The glandular outlets appear as elliptical stomata in the superficial layer of the epidermis and are lined by horny cells, which invaginate to circumscribe the excretory duct. The morphological results indicate that the myoepithelium of Plethodontidae mental glands differ in some respects from that of amphibian serous cutaneous glands. A double polarity for the secretory cells is also suggested. © 1993 Wiley-Liss, Inc.