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.     

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.     

Localization of prolactin receptor in the dorsal and ventral skin of the frog (Rana ridibunda)

The dorsal and ventral skin in amphibians plays an important role in osmoregulation. Prolactin hormone is involved in regulation of amphibian skin functions, such as water and electrolyte balance. Therefore, amphibians may be useful as a model for determining the sites of the prolactin receptor. In this study, prolactin receptor was detected in frog dorsal and ventral skin using immunohistochemical staining method. Prolactin receptor immunoreactivity was localized in all epidermal layers except stratum corneum of dorsal skin epidermis, stratum germinativum layer of ventral skin epidermis, myoepithelial cells, secretory epithelium and secretory channel cells of granular glands in both skin regions. The mucous glands and secretory granules of granular glands did not show immunoreactivity for the prolactin receptor. According to our immunohistochemical results, the more widespread detection of prolactin receptor in dorsal skin epidermis indicates that prolactin is more effective in dorsal skin. Presence of prolactin receptors in epidermis points out its possible osmoregulatory effect. Moreover, detection of receptor immunoreactivity in various elements of poison glands in the dermis of both dorsal and ventral skin regions suggests that prolactin has a regulatory effect in gland functions.     

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 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).     

Epidermal keratinization in the salamander and a comparison with other amphibia

In a variety of amphibians examined the stratum corneum was one cell in depth, although in Xenopus it was up to three cells deep. The flattened horny cells were closely fused together along their lateral membranes to form a continuous sheet. Disulphide bonds of keratin were most concentrated in the peripheral cytoplasm, but the interiors of the cornified cells were sufficiently well keratinized to prevent more than slight enzymatic cytolysis of the normal cell components. Characteristically large, weakly stainable, non-shrunken nuclear remnants were found in the salamander and frog horny layers, but the clawed toad had small pyknotic (parakeratotic) nuclei. The mature amphibian keratinocytes contained free fats, bound phospholipids, calcium and sulphydryl groups, together with acid phosphatase and non-specific esterase. Cornification appears to begin by a process of separate individual cell keratinization and lateral membranes of neighbouring cells only later become fused together. This differs from the process in higher vertebrates in which the cells undergoing keratinization form a uniform transitional layer in the epidermis. In the amphibian epidermis neighbouring cells occur in different stages of keratinization.     

Structural organization of the toe pads in the amphibian Philautus annandalii (Boulenger, 1906)

We describe the morphology of toe pads in the Himalayan tree frog Philautus annandalii. These are expanded tips of digits and show modifications of their ventral epidermis for adhesion. The outer cells of toe pad epidermis (TPE) bear surface microstructures (0.7 × 0.2 μm), which are keratinized. Their cytoplasm contains no organelles, but pleomorphic nuclei and mucous granules (0.4–0.5 μm) that glue the keratin filaments. In the intermediate cell layer of TPE, similar keratinized microstructures as in the outer cells are present, so that when the outer layer is shed, it is ready with features for adhesion. These cells contain more keratin than the outer cells. The basal cell layer contains thin keratin bundles and usual cell organelles. The dermis contains mucous‐secreting glands, whose ducts open in the outer epidermal cell layer in channels. The dorsal epidermal cells lack surface microstructures and keratin bundles. Ultrastructural features suggest that toe pads utilize the surface microstructures for adhesion aided by mucus, in which the intermediate cell layer seems to bear the shear stress generated during locomotion. Further, TPE can expand and fit into an increased contact area of the substrate. The long, surface microstructures may also help in mechanical interlocking with rough surfaces on plants.     

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.     

松江鲈鱼皮肤的显微和亚显微结构

采用光学显微镜、扫描电镜和透射电镜,对松江鲈鱼(Trachidermus fasciatus)成体皮肤的显微和亚显微结构进行了观察。结果表明,松江鲈鱼体表不同部位皮肤的厚薄不一,但基本结构相似。皮肤由表皮和真皮层构成。松江鲈鱼的皮肤裸露无鳞,表皮层较薄,由约4～8层细胞构成,主要由复层上皮细胞和黏液细胞及基底细胞组成。表层细胞呈扁平、多边形,细胞之间主要靠桥粒紧密连接,连接处形成增厚的边缘嵴状突起。表皮细胞游离面向内凹陷,表面形成指纹状微嵴。黏液细胞呈圆形或卵圆形,散布在上皮细胞之间。黏液细胞内的黏原颗粒具有椭圆颗粒状、均匀致密的块状和疏松丝状3种不同形态。真皮通过基膜与表皮相连,由稀疏层和致密层构成。真皮结缔组织在腹部较厚而在其他部位较薄。表皮与真皮连接处有色素层,头部、背部、尾柄和体侧皮肤色素细胞分布多,色素层明显,而腹部和颏部皮肤缺少色素。松江鲈鱼黄河群体真皮层中有角质棘状突起,而滦河群体则无。头部、体侧和尾柄处皮肤上还分布有侧线孔和表面神经丘等感觉器官。     

Succinic dehydrogenase activity in the epidermis ofNatrix piscator during its sloughing cycle

Succinic dehydrogenase activity, in the epidermis of Nairix piscutor in different stages of sloughing cycle, has been localized using a nitro-BT technique with appropriate controls. The staining properties of different layers in scale epidermis are similar to the corresponding layers in hinge epidermis.
In the stratum germinativum, the layers of undifferentiated epidermal cells in all stages of the sloughing cycle, and in the lacunar tissue of Stages 3,4 and 5, a positive though weak reaction for SDH activity reflects the active metabolic state of the cells in these layers. Loss of SDH activity in Stage 6 indicates an inactive metabolic state of the lacunar tissue cells, corresponding with their disintegration owing to the cessation of nutrients as a result of keratinization of cells in the underlying layers.
The Oberhautchen, mesos and alpha layers in all Stages, and the clear layer cells in Stages 5 and 6 (outer epidermal generation), the presumptive Oberhautchen, presumptive mesos layer and presumptive alpha layer in all stages of their differentiation, and the presumptive beta layer in Stages 3 and 4 (inner epidermal generation) all stain purple with nitro-BT technique even in sections incubated in the medium without the substrate-succinate. The reaction is inhibited by prior treatment with 0.1 M N-ethyl maleimide blocking protein-bound -SH groups. This suggests that the reaction is due to the presence of protein-bound -SH groups in these sites. The reduced intensity of reaction in the mature beta layer of the outer epidermal generation, and in the presumptive beta layer in Stages 5 and 6 of the inner epidermal generation, is due to simultaneous loss of their content of -SH groups with maturation and keratinization.     

Protein and carbohydrate histochemistry in relation to the keratinization in the epidermis of Barbus sophor (Cyprinidae, Pisces)

The distribution of protein and carbohydrate constituents in the epidermis of Barbus sophor is described in order to give a better understanding of its cellular organization and physiology.
Various cytochemical techniques show the keratinized nature of the outer free margins of the polygonal cells in the most-superficial layer. These contain appreciable amounts of cysteine bound sulphydryl groups, basic proteins, protein bound NH₂ groups, ribonucleic acid and calcium and give a strong Papanicolaou's reaction. Absence of cystine bound disulphide groups suggests that the cornified layer in B. sophor is probably mechanically weak as adjacent keratin chains remain unbonded. The polygonal cells showing keratinization at the outer free margins remain metabolically active and are not sloughed off at the surface. This is in contrast to the keratinized epidermis of other teleosts so far reported in which the keratinized cells are dead and are sloughed off at the surface.
In addition to keratinization the polygonal cells undergo mucogenesis synthesizing sulphated acid mucopolysaccharides.
The presence of eosinophilic granular cells in the epidermis is interesting. The possible role of these cells in the protection of the epidermis has been discussed. The epidermis on the inner surface of the scale is very thin so it may not have much protective significance in these areas.     

CELL JUNCTIONS IN AMPHIBIAN SKIN

Cell junctions have been investigated in the amphibian epidermis, a stratified squamous epithelium, and compared to those described previously in simple columnar epithelia of mammalian cavitary organs. In adult frogs and toads, and in larvae approaching metamorphosis, belts of membrane fusion or zonulae occludentes of considerable depth are regularly found between adjoining cells of the outermost layer of the stratum corneum, binding the cells together into a continuous, uninterrupted sheet. Another set of occluding zonules appears in the second cornified layer (when such a layer is present), and a third set usually occurs in the outermost layer of the stratum granulosum. Specialized elements described as "modified" and "composite" desmosomes are encountered along the lateral and basal aspects, respectively, of the cornified cells; ordinary desmosomes and maculae occludentes (i.e., spots of membrane fusion) are found in all other strata. The usual 200 A intercellular gap is generally maintained between the cells of the stratum germinativum at the basal ends of the intercellular spaces. Hence, the intercellular spaces of the epidermis form a largely continuous network, closed to the external medium and open to the dermal interstitia. The situation is comparable to that found in columnar epithelia, except that the intercellular spaces are much more extensive, and an extracellular subcompartment (or two) apparently exists in the stratum corneum and between the latter and the stratum granulosum. The last subcompartment is usually filled with a dense substance, probably derived from discharged secretory granules. The tripartite junctional complex characteristic of lumen-lining epithelia (i.e., a zonula occludens followed by a zonula adhaerens, and desmosome) is seen only in early larvae; in adults and in larvae approaching metamorphosis, the occluding zonule is followed directly by a series of modified desmosomes. Interpreted in the light of current physiological data, these findings suggest that the diffusion of water, ions, and small, water-soluble molecules is impeded along the intercellular spaces of the epidermis by zonulae occludentes while it is facilitated from cell to cell within the epidermis by zonulae and maculae occludentes.     

Integumentary Effects of Prolactin in the Lower Vertebrates

Prolactin was first known as a stimulator of mammary secretion.It has since been found to induce secretion in the sebaceousglands of the mammal as well. It likewise stimulates secretoryactivity in the avian cropsac and in the mucous glands of fishesand of amphibians when thyroid hormone is also present. Prolactinhas mitogenetic effects on a variety of structures includingthe amphibian stratum corneum and induces growth of the tailfin in larval anurans and in both larval and adult newts. Prolactincauses the regression of cornified tubercles in the skin ofthe newt yetsynergizes with androgen in the presence of thethyroid hormone to induce the formation of keratinized nuptialpads. A similar synergism between prolactin and steroidal hormonesproduces avian incubation patches. There is indication thatprolactin may facilitate the growth of hair in mammals but detailedinformation is lacking. Effects on pigmentation are attributedto prolactin in two fishes.     

Fine structure of the abdominal epidermis of the adult mudpuppy,Necturus maculosus (Rafinesque)

Summary The ventral epidermis of adult Necturus maculosus has been studied using electron and light microscopy. Many larval characteristics of amphibian epidermal structure are retained in adult Necturus. The epidermis is a stratified epithelium consisting of four cell layers and five cell types. Major differences compared with other adult amphibians are: (1) the absence of a well defined moulting cycle together with an apparently diminished synthetic and mitotic activity in the stratum germinativum; (2) an outermost cell layer (stratum mucosum) that is unkeratinized and appears to synthesize a mucous layer; and (3) numerous large club-shaped Leydig cells which span the epidermis between the cells of the stratum germinativum and stratum mucosum. The apical region of the stratum granulosum and stratum mucosum cells shows evidence of extensive synthesis. The stratum mucosum appears to be involved in the secretion of vesicular contents onto the outermost surface of the epithelium. The external surfaces of the stratum mucosum cells possess numerous microridges which are supported by an intricate network of cytofilaments in the apical region of these cells. The significance of these features is discussed in relation to the physiology and ecology of this species.     

Intrinsic organization of the medial cerebral cortex of the lizard Lacerta pityusensis: A golgi study

The morphology of cells and the organization of axons were studied in Golgi-Colonnier and toluidine blue stained preparations from the medial cerebral cortex of the lizard Lacerta pityusensis. In the medial cortex, six strata were distinguished between the superficial glial membrane and the ependyma. Strata I and II formed the outer plexiform layer, stratum III formed the cellular layer, and strata IV go VI the inner plexiform layer. The outer plexiform layer contained smooth bipolar neurons; their dendrites were oriented anteroposteriorly and their axons were directed towards the posterior zone of the brain. Five neuronal types were observed in the cellular layer. The spinous pyramidal neurons had well-developed apical dendrites and poorly developed basal ones. Their axons entered the inner plexiform layer and gave off collaterals oriented anteroposteriorly. The small, sparsely spinous pyramidal neurons had poorly developed dendrites and their axons entered the inner plexiform layer. The spinous bitufted neurons had well-developed apical and basal dendritic tufts. Their axons gave off collaterals that reached the outer and inner plexiform layers of both the dorsomedial and dorsal cortices. The sparsely spinous horizontal neurons had dendrites restricted to the outer plexiform layer. Their axons entered the inner plexiform layer. The sparsely spinous, multipolar neurons had their soma close to stratum IV and their axons entered the outer plexiform layer. In stratum V of the inner plexiform layer were large, spiny polymorphic neurons; they had dendrites with long spines, and their axons reached the cellular layer. On the basis of these results, we have subdivided the medial cortex into two subregions: the superficial region, which contains the neurons of the cellular layer and their dendritic domains, and the deep region, strata V and VI, which contains the large, spiny polymorphic neurons. The neurons in the medial cortex of these lizards resembles those in the area dentata of mammals. On this basis, the superficial region may be compared to the dentate gyrus and the deep region to the hilar region of the hippocampus of mammals.     

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.     

雄性峨眉髭蟾“胡子”的组织结构特征

采用石蜡切片与苏木精-伊红染色及扫描电镜,对雄性峨眉髭蟾Leptobrachium boringii的角质刺及其周边皮肤进行了显微结构和亚显微结构的观察。显微结构观察发现,峨眉髭蟾的角质刺属于皮肤衍生物,突起呈倒"V"形。角质刺由表皮和真皮构成,表皮为复层扁平上皮,可分成4层;最外层细胞角质化,细胞轮廓不清,被染成深红色。真皮由疏松结缔组织构成,分辨不出致密层与疏松层,其内未见皮肤腺,但有少量色素细胞与毛细血管分布。表皮嵴伸入到真皮层,在以往的无尾两栖类研究中未见报道。角质刺基部可见皮肤褶翻起将其包裹在内,皮肤褶向上延伸形成角质刺。扫描电镜观察表明,角质刺顶端呈锥形的"小山丘"状,表面可分辨出表皮细胞轮廓,细胞为呈覆瓦状排列的角质化细胞。角质刺与皮肤交界处为多边形的角质化细胞。角质化上皮细胞的上表面与下表面均具有凹凸不平的花纹结构,细胞之间以镶嵌的方式连接。     

Keratohyalin-like granules in lizard epidermis: evidence from cytochemical, autoradiographic, and microanalytic studies

Epidermal sloughing in lizards is determined by the formation of an intraepithelial shedding complex in which keratohyalin-like granules are formed. The chemical nature of these granules is unknown, as is their role in keratinization. The goal of this study was to test whether they contain some amino acids similar to those found in mammalian keratohyalin. The embryonic and regenerating epidermis of lizards are useful systems to study the formation of these granules. Histochemically keratohyalin-like granules react to histidine and contain some sulfhydryl groups (cysteine). X-ray microanalysis shows that these granules contain sulfur and often phosphorus, two elements also present in the mature clear, oberhautchen, and beta layer. Instead the mesos, alpha, and lacunar layers contain only sulfur. Most sulfur is probably in a disulfide-bonded form, particularly in mature cells of the shedding complex, in large keratohyalin-like granules, and in the beta-keratin layer. Early differentiating beta-keratin cells have the maximal incorporation of tritiated proline, whereas tritiated arginine is slightly more concentrated in the basal layer of the epidermis. A high uptake of tritiated histidine is observed mainly in keratohyalin-like granules of the clear layer, but also in the oberhautchen layer and forming the alpha-lacunar layer. Immunogold electron microscopy shows that keratohyalin-like granules do not localize keratin but are embedded within a keratin network. These results suggest that keratohyalin-like granules of lizards, like mammalian keratohyalin, contain some sulfur-rich and histidine-rich proteins. These granules participate in the process of hardening of the clear layer that molds the spinulae of the deeper oberhautchen to form the superficial microornamentation.     

Calcium regulation of epidermal cell differentiation in the frog Xenopus laevis.

Adult frogs have a stratified epidermis with a keratinized stratum corneum. Since the extracellular calcium concentration is known to regulate differentiation of mammalian epidermal cells in vitro, we studied the effects of calcium on the terminal differentiation of frog epidermal cells. Exposure of the epidermal cells to a high concentration of calcium (greater than 0.2 mM) induced cornification and the synthesis of a 51 Kd acidic keratin. These data are very similar to the results from mammalian epidermal cell cultures, suggesting that the mechanism of terminal differentiation is conserved throughout the evolution of terrestrial vertebrates.     

Fine structure of the epidermis of the mudskipper,Periophthalmus modestus (Gobiidae)

The ultra-structure of the epidermis of the mudskipper,Periophthalmus modestus, was examined by both light and transmission electron microscopies. The epidermis is exceptionally not well endowed with mucous or granular cells. Filament-containing cells occur in three distinct layers of the surface, middle and basal epidermis. The surface layer is further subdivided into two layers, an outermost and less superficial one. Two different cell types were identified in the epidermis. Type I cells are fiat cells in a single stratum. Type II cells are enormous cells, characterized by having a large vacuole in the cytoplasm. The outermost layer is composed of a free surface of Type I cells and numerous microridges covered with a fuzzy, fibrillar substance. The “fuzz” forms a cuticule-like structure, but keratinization as found in terrestrial animals does not occur. The superficial layer contains Type I cells and intraepithelial blood capillaries. When Type I cells become senescent, numerous intercellular spaces are formed in the plasma membranes of adjacent cells, with the senescent cells finally falling off. Just beneath these cells, however, young cells of Type I are always found. The blood capillaries are usually reinforced with young Type I cells. A large volume of oxygen may be absorbed through the skin using the blood capillary network. The middle layer contains several strata of Type II cells. The special corky structure of these cells seems to play an important role in thermal insulation and protection against ultraviolet light in relation to life out of water. However, by comparison with terrestrial animals, the histological design of the epidermis of this goby appears incomplete, so as to reduce desiccation on land, owing to the epidermis lacking a keratinized stratum. The differentiation of the epidermis seems to be an adaptation for a terrestrial habit in this species.