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.     

Formation of the corneous layer in the epidermis of the tuatara (Sphenodon punctatus, Sphenodontida, Lepidosauria, Reptilia)

The formation of the stratum corneum in the epidermis of the reptile Sphenodon punctatus has been studied by histochemical, immunohistochemical, and ultrastructural methods. Sulfhydryl groups are present in the mesos and pre-alpha-layer but disappear in the keratinized beta-layer and in most of the mature alpha-layer. This suggests a complete cross-linking of keratin filaments. Tyrosine increases in keratinized layers, especially in the beta-layer. Arginine is present in living epidermal layers, in the presumptive alpha-layer, but decreases in keratinized layers. Histidine is present in corneous layers, especially in the intermediate region between the alpha- and a new beta-layer, but disappears in living layers. It is unknown whether histidine-rich proteins are produced in the intermediate region. Small keratohyalin-like granules are incorporated in the intermediate region. The plane of shedding, as confirmed from the study on molts, is located along the basalmost part of the alpha-layer and may involve the degradation of whole cells or cell junctions of the intermediate region. A specific shedding complex, like that of lizards and snakes, is not formed in tuatara epidermis. AE1-, AE2-, or AE3-positive alpha-keratins are present in different epidermal layers with a pattern similar to that previously described in reptiles. The AE1 antibody stains the basal and, less intensely, the first suprabasal layers. Pre-keratinized, alpha- and beta-layers, and the intermediate region remain unlabeled. The AE2 antibody stains suprabasal and forming alpha- and beta-layers, but does not stain the basal and suprabasal layers. In the mature beta-layer the immunostaining disappears. The AE3 antibody stains all epidermal layers but disappears in alpha- and beta-layers. Immunolocalization for chick scale beta-keratins labels the forming and mature beta-layer, but disappears in the mesos and alpha-layer. This suggests the presence of common epitopes in avian and reptilian beta-keratins. Low molecular weight alpha-keratins present in the basal layer are probably replaced by keratins of higher molecular weight in keratinizing layers (AE2-positive). This keratin pattern was probably established since the beginning of land adaptation in amniotes.     

Presence of putative histidine-rich proteins in the amphibian epidermis

In amphibian epidermis mucus is thought to constitute the matrix material that links keratin filaments present in cells of the corneous layer. As contrast in mammals, and perhaps in all amniotes, histidine-rich proteins form the matrix material. In order to address the study of matrix molecules in the epidermis of the first tetrapods, the amphibians, an autoradiographic and electrophoretic study has been done after administration of tritiated histidine. Histological analysis of amphibian epidermis shows that histidine is taken up in the upper intermediate and replacement layers beneath the corneous layer. Ultrastructural autoradiographic analysis reveals that electron-dense interkeratin material is labeled after administration of tritiated histidine. Electrophoretic analysis of the epidermis shows labeled proteic bands at 58-61, 50-55, 40-45, and some only weakly labeled at 30 and 24-25 kDa at 4-48 hours after injection of tritiated histidine. Keratin markers show that bands at 40-61 kDa contain keratins. Most histidine is probably converted into other amino acids such as glutamate and glutamine that are incorporated into newly synthetized keratins. However, non-keratin histidine-incorporating proteins within the keratin range could also be formed. The bands at 30 and 24-25 kDa suggest that these putative histidine-rich proteins are not keratins. In fact, their molecular weigh is below the range of that for keratins. In contrast with the mammalian condition, but resembling reports for lizard epidermis, putative histidine-rich proteins in amphibians have no high molecular weight precursor. Although filaggrin is not detectable by immunofluorescence in sections of amphibian epidermis, protein extraction, electrophoresis and immunoblotting are more sensitive. In the epidermis of toad and frog, but only occasionally in that of newt, filaggrin cross-reactive proteic bands are seen at 50-55, 40-45, and sometimes at 25 kDa. This suggests that after extraction and unmasking of reactive sites in the epidermis of more terrestrial amphians (anurans), some HRPs with filaggrin-like cross-reactivity are present. The overlap that exists at 50-55 kDa between filaggrin-positive and AE2-positive keratins, but not that at 40-45 kDa further indicate that non-keratin, filaggrin-like proteins may be present in anuran epidermis. The present study suggests for the first time that very small amounts of histidine-rich proteins are produced among keratin filaments in upper intermediate, replacement and corneous layers of amphibian epidermis. Although the molecular composition of these proteins is unknown, precluding understanding of their relationship to those of mammals and reptiles, these cationic proteins might have originated in conjunction with the formation of a horny layer during the adaptation to land during the Carboniferous and were possibly refined later in the epidermis of amniotes.     

Immunocytochemical and electrophoretic distribution of cytokeratins in the resting stage epidermis of the lizard Podarcis sicula

The distribution of three anti-cytokeratin (alpha-keratin) antibodies (AE1, AE2, AE3) in the epidermis of a lizard has been studied by immunocytochemistry at light and electron microscope and by immunoblot analysis. This study shows the expression of different keratins in the resting stage epidermis of the lizard Podarcis sicula. In this stage the epidermis has an external beta-layer, an underlying alpha-layer, some layers of living suprabasal cells and a basal stratum germinativum. The AE1 antibody is localized in the basal and suprabasal cells only in the outer scale surface, but is absent from the inner surface, the hinge region and from the keratinized beta- and alpha-layers. The AE2 antibody is mainly localized at the level of the hinge region and of the alpha-layer and gives a lower reaction in the beta-layer. The AE3 antibody is mainly localized in basal and suprabasal cells, lower in the alpha-layer, and absent from the beta-layer. The electron microscope shows that all the three antibodies immunolabel cytoplasmic fibrillar structures in the deep alpha-layers and that AE2 and AE3 antibodies label small electron-dense areas in the external dense beta-layer within the electron-lucid matrix. Immunoblot analysis of the keratins extracted and separated by gel electrophoresis demonstrates the presence of a band of high molecular weight (67-68 kDa) positive to all three antibodies. In addition AE1 antibody recognizes a 44-45 kDa band and a 57-58 kDa band, AE2 recognizes a 60-61 kDa band, and AE3 recognizes a 47 kDa and a 56-57 kDa band. The localization of the keratins identified by immunoblot analysis in the epithelial layers is discussed taking in account the immunolabeling at light and electron microscope. The present study suggests that also in the normal epidermis of this reptiles, in both the alpha- and the beta-layer, the molecular masses of keratins increase from the basal to the keratinized layers, a phenomenon which is generalized to adult and embryonic amniotes epidermis.     

Ultrastructural localization of alpha-keratins in the regenerating epidermis of the lizard Podarcis muralis during formation of the shedding layer

In the epidermis of lizards, alpha- and beta-keratins are sequentially produced during a shedding cycle. Using pre- and post-embedding immunocytochemistry this study shows the ultrastructural distribution of 3 alpha-keratin antibodies (AE1, AE2, AE3) in the renewing epidermis and in the shedding complex of the regenerating tail of the lizard Podarcis muralis. The AE1 antibody that recognizes acidic low MW keratins is confined to tonofilament bundles in basal and suprabasal cells but is not present in keratinizing beta- and alpha-cells. The AE2 antibody that recognises higher MW keratins weakly stains pre-keratinized cells and intensely keratinized alpha-layers. A weak labeling is present in small electrondense areas within the beta-layer. The AE3 antibody, that recognizes low and high MW basic keratins, immunolabels tonofilament bundles in all epidermal layers but intensely the alpha-keratinizing and keratinized layers (mesos, alpha-, lacunar and clear). Keratohyalin-like granules, present in the clear cells of the shedding layer, are negative to these antibodies so that the cornified clear layer contains keratins mixed with non-keratin material. The AE3 antibody shows that the mature beta-layer and the spinulated folds of the oberhautchen are labeled only in small dense areas among the prevalent electron-pale beta-keratin material. Therefore, some alpha-keratin is still present in the beta-layer, and supports the idea that alpha-keratins (basic) function as scaffold for beta-keratin deposition.     

Immunocytochemical and electrophoretic distribution of cytokeratins in the regenerating epidermis of the lizard Podarcis muralis

Using immunocytochemistry at light- and electron-microscope levels, we studied the distribution of three monoclonal antibodies (AE1, AE2, AE3) specific for mammalian alpha-keratins in regenerating lizard epidermis. We also characterized the keratins expressed during this process by immunoblotting after electrophoretic separation. The AE1 antibody is localized in the basal and suprabasal layers of prescaling and scaling epidermis. During the first stages of scale neogenesis, the AE1 antibody also marks the differentiating oberhautchen and beta-layer, but it disappears from these layers as they mature. This antibody does not stain the prekeratinized and keratinized outermost layers in the hinge region. The AE2 antibody labels the superficial wound epidermis, prekeratinizing and keratinized beta- and alpha-layers, but not basal and suprabasal cells. The AE3 antibody labels all living and keratinized epidermal layers, although AE3 immunoreactivity decreases and disappears as the beta-layer matures. The ultrastructural study shows that the AE2 and AE3, but not the AE1, antibodies specifically label small electron-dense areas within the beta-layer, suggesting retention of alpha-keratins. In the stages of tail regeneration examined, immunoblotting with the three antibodies used for the immunolocalization gives a pattern similar to that of the normal epidermis, except distally, where the process of scale differentiation begins. In this region, in addition to the keratin forms discovered in the normal and in proximal regenerating epidermis, an intense low molecular weight band at 40-41 kDa, positive to all three antibodies, is clearly detectable. Furthermore, in the distal region AE1 and AE3 antibodies, but not the AE2, recognize a weak band at 77-78 kDa not present in the normal and proximal epidermis. The localization and the possible role of the different keratins in the regenerating epidermis is discussed.     

Histidine uptake in the epidermis of lizards and snakes in relation to the formation of the shedding complex

Mammalian epidermis utilizes histidine-rich proteins (filaggrins) to aggregate keratin filaments and form the stratum corneum. Little is known about the involvement of histidine-rich proteins during reptilian keratinization. The formation of the shedding complex in the epidermis of snakes and lizards, made of the clear and the oberhautchen layers, determines the cyclical epidermal sloughing. Differently from snakes, keratohyalin-like granules are present in the clear layer of lizards. The uptake of tritiated histidine into the epidermis of two lizards and one snake has been studied by autoradiography in sections at progressive post-injection periods. At 40 min and 1 hr post-injection keratohyalin-like granules were not or poorly labeled. At 3-22 hr post-injection most of the labeling was present over suprabasal cells destined to form the shedding complex, in keratohyalin-like granules of the clear layer, and in the forming a-layer but was low in the forming b-layer, and in superficial keratinized layers. The analysis of the shedding complex in the pad lamellae (a specialized scale used for climbing) of a gecko showed that the setae and the cytoplasm of clear cells among them are main sites of histidine uptake at 4 hr post-injection. In the snake most of the labeling at 4 hr post-injection was localized in the shedding complex along the boundary between the clear and oberhautchen layers. The present study suggests that, in the epidermis of lepidosaurian reptiles, the synthesis of a histidine-rich protein is involved in the formation of the shedding layer and, as in mammals, in a-keratinization.     

Differentiation of snake epidermis, with emphasis on the shedding layer

Little is known about specific proteins involved in keratinization of the epidermis of snakes. The presence of histidine-rich molecules, sulfur, keratins, loricrin, transglutaminase, and isopeptide-bonds have been studied by ultrastructural autoradiography, X-ray microanalysis, and immunohistochemistry in the epidermis of snakes. Shedding takes place along a shedding complex, which is composed of two layers, the clear and the oberhautchen layers. The remaining epidermis comprises different layers, some of which contain beta-keratins and others alpha-keratins. Weak loricrin, transglutaminase, and sometimes also iso-peptide-bond immunoreactivities are seen in some cells, lacunar cells, of the alpha-layer. Tritiated histidine is mainly incorporated in the shedding complex, especially in dense beta-keratin filaments in cells of the oberhautchen layer and to a small amount in cells of the clear layer. This suggests the presence of histidine-rich, matrix proteins among beta-keratin bundles. The latter contain sulfur and are weakly immunolabeled for beta-keratin at the beginning of differentiation of oberhautchen cells. After merging with beta cells, the dense beta-keratin filaments of oberhautchen cells become immunopositive for beta-keratin. The uptake of histidine decreases in beta cells, where little dense matrix material is present, while pale beta-keratin filaments increase. During maturation, little histidine labeling remains in electron-dense areas of the beta layer and in those of oberhautchen spinulae. Some roundish dense granules of oberhautchen cells rich in sulfur are negative to antibodies for alpha-keratin, beta-keratin, and loricrin. The granules eventually merge with beta-keratin, and probably contribute to the formation of the resistant matrix of oberhautchen cells. In conclusion, beta-keratin, histidine-rich, and sulfur-rich proteins contribute to form snake microornamentations.     

Immuno-cross reactivity of transglutaminase and cornification marker proteins in the epidermis of vertebrates suggests common processes of soft cornification across species

In differentiating mammalian keratinocytes proteins are linked to the plasma membrane by epidermal transglutaminases through N-epsilon-(gamma-glutamyl)-lysine isopeptide bonds to form the cornified cell envelope. The presence of transglutaminases and their protein substrates in the epidermis of nonmammalian vertebrates is not known. The present study analyses the presence and localization of the above proteins in the epidermis using immuno-cross reactivity across different classes of amniotes. After immunoblotting, some protein bands appear labelled for loricrin, sciellin, and transglutaminase in most species. These proteins are scarce to absent in the epidermis of aquatic species (goldfish and newt) where a stratum corneum is absent or very thin. The molecular weight of transglutaminase immunoreactive bands generally varies between 40 to 62 kDa, with the most represented bands at 52-57 kDa in most species. The more intense loricrin- and sciellin-immunoreactive bands are seen at 50-55-62 kDa, but are weak or absent in aquatic vertebrates. Loricrine-like immunoreactivity is present in the epidermis where alpha-(soft)-keratinization occurs. Isopeptide bonds are mainly associated to bands in the range of 50-62 kDa. In vertebrates where hard-keratin is expressed (the beta-keratin corneous layer of sauropsids and in feathers) or in hair cortex of mammals, no loricrin-like, transglutaminase-, and isopeptide-bond-immunoreactivities are seen. Immunoblotting however shows loricrin-, sciellin-, and trasnsglutaminase-positive bands in the corneous layers containing beta-keratin. Histologically, the epidermis of most amniotes shows variable transglutaminase immunoreactivity, but isopeptide-bond and sciellin immunoreactivities are weak or undetactable in most species. The limitations of immunohistochemical methods are discussed and compared with results from immunoblotting. In reptilian epidermis transglutaminase is mainly localized in 0.15-0.3 microm dense granules or diffuse in transitional alpha-keratogenic cells. In beta-keratogenic cells few small dense granules show a weak immunolabeling. Transglutaminase is present in nuclei of terminal differentiating alpha- and beta-keratinocytes, as in those of mature inner and outer root sheath. The present study suggests that keratinization based on loricrin, sciellin and transglutaminase was probably present in the stratum corneoum of basic amniotes in the Carboniferous. These proteins were mainly maintained in alpha-keratogenic layers of amniotes but decreased in beta-keratogenic layers of sauropsids (reptiles and birds). The study suggests that similar proteins for the formation of the cornified cell envelope are present in alpha-keratinocytes across vertebrates but not in beta-keratinocytes.     

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.     

Ultrastructure of the embryonic snake skin and putative role of histidine in the differentiation of the shedding complex.

The morphogenesis and ultrastructure of the epidermis of snake embryos were studied at progressive stages of development through hatching to determine the time and modality of differentiation of the shedding complex. Scales form as symmetric epidermal bumps that become slanted and eventually very overlapped. During the asymmetrization of the bumps, the basal cells of the forming outer surface of the scale become columnar, as in an epidermal placode, and accumulate glycogen. Small dermal condensations are sometimes seen and probably represent primordia of the axial dense dermis of the growing tip of scales. Deep, dense, and superficial loose dermal regions are formed when the epidermis is bilayered (periderm and basal epidermis) and undifferentiated. Glycogen and lipids decrease from basal cells to differentiating suprabasal cells. On the outer scale surface, beneath the peridermis, a layer containing dense granules and sparse 25-30-nm thick coarse filaments is formed. The underlying clear layer does not contain keratohyalin-like granules but has a rich cytoskeleton of intermediate filaments. Small denticles are formed and they interdigitate with the oberhautchen spinulae formed underneath. On the inner scale surface the clear layer contains dense granules, coarse filaments, and does not form denticles with the aspinulated oberhautchen. On the inner side surface the oberhautchen only forms occasional spinulae. The sloughing of the periderm and embryonic epidermis takes place in ovo 5-6 days before hatching. There follow beta-, mesos-, and alpha-layers, not yet mature before hatching. No resting period is present but a new generation is immediately produced so that at 6-10 h posthatching an inner generation and a new shedding complex are forming beneath the outer generation. The first shedding complex differentiates 10-11 days before hatching. In hatchlings 6-10 h old, tritiated histidine is taken up in the epidermis 4 h after injection and is found mainly in the shedding complex, especially in the apposed membranes of the clear layer and oberhautchen cells. This indicates that a histidine-rich protein is produced in preparation for shedding, as previously seen in lizard epidermis. The second shedding (first posthatching) takes place at 7-9 days posthatching. It is suggested that the shedding complex in lepidosaurian reptiles has evolved after the production of a histidine-rich protein and of a beta-keratin layer beneath the former alpha-layer.     

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.     

Expression of specific keratin markers by rabbit corneal, conjunctival, and esophageal epithelia during vitamin A deficiency

Using an in vivo rabbit model system, we have studied the morphological and biochemical changes in corneal, conjunctival, and esophageal epithelia during vitamin A deficiency. Light and electron microscopy showed that the three epithelia undergo different degrees of morphological keratinization. Corneal and conjunctival epithelia became heavily keratinized, forming multiple layers of superficial, anucleated cornified cells. In contrast, esophageal epithelium underwent only minor morphological changes. To correlate morphological alterations with the expression of specific keratin molecules, we have analyzed the keratins from these epithelia by the immunoblot technique using the subfamily-specific AE1 and AE3 monoclonal antikeratin antibodies. The results indicate that during vitamin A deficiency, all three epithelia express an AE1-reactive, acidic 56.5-kd keratin and an AE3-reactive, basic 65-67-kd keratin. Furthermore, the expression of these two keratins correlated roughly with the degree of morphological keratinization. AE2 antibody (specific for the 56.5- and 65-67-kd keratins) stained keratinized corneal epithelial sections suprabasally, as in the epidermis, suggesting that these two keratins are expressed mainly during advanced stages of keratinization. These two keratins have previously been suggested to represent markers for epidermal keratinization. Our present data indicate that they can also be expressed by other stratified epithelia during vitamin A deficiency-induced keratinization, and suggest the possibility that they may play a role in the formation of the densely packed tonofilament bundles in cornified cells of keratinized tissues.     

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.     

Immunocytochemistry indicates that glycine‐rich beta‐proteins are present in the beta‐layer,while cysteine‐rich beta‐proteins are present in beta‐ and alpha‐layers of snake epidermis

Immunolocalization of glycine‐rich and cysteine–glycine‐medium‐rich beta‐proteins (Beta‐keratins) in snake epidermis indicates a different distribution between beta‐ and alpha‐layers. Acta Zoologica, Stockholm. The epidermis of snakes consists of hard beta‐keratin layers alternated with softer and pliable alpha‐keratin layers. Using Western blot, light and ultrastructural immunolocalization, we have analyzed the distribution of two specific beta‐proteins (formerly beta‐keratins) in the epidermis of snakes. The study indicates that the antibody HgG5, recognizing glycine‐rich beta‐proteins of 12–15 kDa, is poorly or not reactive with the beta‐layer of snake epidermis. This suggests that glycine‐rich proteins similar to those present in lizards are altered during maturation of the beta‐layer. Conversely, a glycine–cysteine‐medium‐rich beta‐protein (HgGC10) of 10–12 kDa is present in beta‐ and alpha‐layers, but it is reduced or disappears in precorneous and suprabasal cells destined to give rise to beta‐ and alpha‐cells. Together with the previous studies on reptilian epidermis, the present results suggest that beta‐proteins rich in glycine mainly accumulate on a scaffold of alpha‐keratin producing a resistant and hydrophobic beta‐layer. Conversely, beta‐proteins lower in glycine but higher in cysteine accumulate on alpha‐keratin filaments present in beta‐ and alpha‐layers producing resistant but more pliable layers.     

Abnormal Epidermal Keratinization in the repeated epilation mutant mouse

Repeated epilation (Er) is a radiation-induced, autosomal, incomplete dominant mutation in mice which is expressed in heterozygotes but is lethal in the homozygous condition. Many effects of the mutation occur in skin: the epidermis in Er/Er mice is adhesive (oral and nasal orifices fuse, limbs adhere to the body wall), hyperplastic, and fails to undergo terminal differentiation. Skin from fetal +/+, Er/+ and Er/Er mice at ages pre- and postkeratinization examined by light, scanning, and transmission electron microscopy showed marked abnormalities in tissue architecture, differentiation, and cell structure; light and dark basal epidermal cells were separated by wide intercellular spaces, joined by few desmosomes, and contained phagolysomes. The numbers of spinous, granular, and superficial layers were highly variable within any given region and among various regions of the body. In some areas, 2-8 layers of granular cells, containing large or diminutive keratohyalin granules, extended to the epidermal surface; in others, the granular layers were covered by several layers of partially keratinized or nonkeratinized cells. In rare instances, a single or small group of cornified cells was present among the granular layers but was not associated with the epidermal surface. Both the granular and nonkeratinized/partially keratinized upper epidermal layers Er/Er skin gave positive immunofluorescence with antiserum to the histidine-rich, basic protein, filaggrin. Proteins in epidermal extracts from +/+, Er/+ and Er/Er mice were separated and identified by radio- and immunolabeling techniques. The Er/Er extract was missing a 26.5- kdalton protein and had an altered ratio of bands in the keratin region. The 26.5-kdalton band was histidine-rich and cross-reacted with the antiserum to rat filaggrin. Several high molecular weight bands present in both Er/Er and +/+ extracts also reacted with the antiserum. These are presumed to be the precursors of filaggrin and to account for the immunofluorescence om Er/Er epidermis even though the product protein is absent. The morphologic and biochemical data indicated that the genetic defect has a general and profound influence on epidermal differentiation, including alteration of two proteins (filaggrin and keratin) important in normal terminal differentiation, tissue architecture, and cytology. Identification of epidermal abnormalities at early stages of development (prekeratinization) and defective structure of other tissues and gross anatomy suggest that the mutation is responsible for a defect in same regulatory step important in many processes of differentiation and development.     

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.     

Expression of epidermal keratins and filaggrin during human fetal skin development

The major structural proteins of epithelia, the keratins, and the keratin filament-associated protein, filaggrin, were analyzed in more than 50 samples of human embryonic and fetal skin by one-dimensional SDS PAGE and immunoblotting with monoclonal and polyclonal antibodies. Companion samples were examined by immunohistochemistry and electron microscopy. Based on structural characteristics of the epidermis, four periods of human epidermal development were identified. The first is the embryonic period (before 9 wk estimated gestational age), and the others are within the fetal period: stratification (9-14 wk), follicular keratinization (14-24 wk), and interfollicular keratinization (beginning at approximately 24 wk). Keratin proteins of both the acidic (AE1-reactive, type I) and the basic (AE3-reactive, type II) subfamilies were present throughout development. Keratin intermediate filaments were recognized in the tissue by electron microscopy and immunohistochemical staining. Keratins of 50 and 58 kD were present in the epidermis at all ages studied (8 wk to birth), and those of 56.5 and 67 kD were expressed at the time of stratification and increased in abundance as development proceeded. 40- and 52-kD keratins were present early in development but disappeared with keratinization. Immunohistochemical staining suggested the presence of keratins of 50 and 58 kD in basal cells, 56.5 and 67 kD in intermediate cells, and 40 and 52 kD in the periderm as well as in the basal cells between the time of stratification and birth. Filaggrin was first detected biochemically at approximately 15 wk and was localized immunohistochemically in the keratinizing cells that surround hair follicles. It was identified 8-10 wk later in the granular and cornified cell layers of keratinized interfollicular epidermis. These results demonstrate the following. An intimate relationship exists between expression of structural proteins and morphologic changes during development of the epidermis. The order of expression of individual keratins is consistent with the known expression of keratins in simple vs. stratified vs. keratinized epithelia. Expression of keratins typical of stratified epithelia (50 and 58 kD) precedes stratification, and expression of keratins typical of keratinization (56.5 and 67 kD) precedes keratinization, which suggests that their expression marks the tissue commitment to those processes. Because only keratins that have been demonstrated in various adult tissues are expressed during fetal development, we conclude that there are no "fetal" keratins per se.(ABSTRACT TRUNCATED AT 400 WORDS)     

Putative histidin-rich proteins in the epidermis of lizards

In the stratum granulosum of mammalian epidermis, histidin-rich proteins (filaggrins) determine keratin clumping and matrix formation into terminal keratinocytes of the stratum corneum. The nature of matrix, interkeratin proteins in the epidermis of nonmammalian vertebrates, and in particular in that of reptilian, mammalian progenitors are unknown. The present biochemical study is the first to address this problem. During a specific period of the renewal phase of the epidermis of lizards and during epidermal regeneration, keratohyalin-like granules are formed, at which time they take up tritiated histidine. The latter also accumulate in cells of the alpha-keratin layer (soft keratin). This pattern of histidine incorporation resembles that seen in keratohyalin granules of the stratum granulosum of mammalian epidermis. After injection of tritiated histidine, we have analysed the distribution of the radioactivity by histoautoradiography and electrophoretic gel autoradiography of epidermal proteins. Extraction and electrophoretic separation of interfilamentous matrix proteins from regenerating epidermis 3-48 hours post-injection reveals the appearance of protein bands at 65-70, 55-58, 40-43, 30-33, 25-27, and 20-22 kDa. Much weaker bands were seen at 100, 140-160, and 200 kDa. A weak band at 20-22 kDa or no bands at all are seen in the normal epidermis in resting phase and in the dermis. In regenerating epidermis at 22 and 48 hours post-injection, little variation in bands is detectable, but low molecular weight bands tend to increase slightly, suggesting metabolic turnover. Using anti-filaggrin antibodies against rat, human, or mouse filaggrins, some cross-reactivity was seen with more reactive bands at 40-42 and 33 kDa, but it was reduced or absent at 140, 95-100, 65-70, 50-55, and 25 kDa. This suggests that different intermediate degradative proteins of lizard epidermis may share some epitopes with mammalian filaggrins and are different from keratins with molecular weight ranging from 40 to 65-68 kDa. The immunocytochemical observation confirms that a weak filaggrin-like immunoreactivity characterizes differentiating alpha-keratogenic layers in normal and regenerating tail. A weak filaggrin labeling is discernable in small keratohyalin-like granules but is absent from the larger granules and from mature keratinocytes. The present results indicate, for the first time, that histidine-rich proteins are involved in the process of alpha-keratinization in reptilian epidermis. The cationic, interkeratin matrix proteins implicated may be fundamentally similar in both theropsid-derived and sauropsid amniotes.     

Immunocytochemical localization of cysteine‐rich beta‐proteins in the extensible epidermis of the dewlap in the lizard Anolis carolinensis

The dewlap in the lizard Anolis carolinensis is made of scales separated by large interscale regions capable of broad stretching during fan extension. This indicates that the skin contains proteins that allow extension of interscale regions. The immunocytochemical analysis of the epidermis indicates that HgG5, a glycine‐rich hydrophobic beta‐protein poor in cysteine is localized only in the stiff beta‐layer of the outer scale surface, but is completely absent in mesos and alpha‐layers and in hinge regions. HgGC10, a cysteine‐medium‐rich beta‐protein is present in beta‐layers but especially in alpha‐layers of interscale epidermis that presents folds and lacks a beta‐layer. HgGC3 is weakly localized in the alpha‐layer, but is mainly found in hinge regions. HgGC8 and HgG13 are low to absent in the alpha‐ and beta‐layer. The immunolocalization of cysteine‐rich beta‐proteins such as HgGC10/3 in alpha‐layers and interscale epidermis suggests that these small proteins are involved in the formation of a corneous material compatible with dewlap extension. The basement membrane underneath scales is joined to bundles of collagen fibrils in the dermis through anchoring fibrils that likely determine flattening of the epidermis during the extension of the throat fan.