Formation of large micro‐ornamentations in developing scales of agamine lizards

The embryonic scales of two Australian agamine lizards (Hypsilurus spinipes and Physignatus lesueuerii) derive from the undulation of the epidermis to form dome‐shaped scale anlage that later become asymmetric and produce keratinized layers. Glycogen is contained in basal and suprabasal cells of the forming outer scale surface that are destined to differentiate into β‐keratin cells. The outer peridermis is very flat, but the second epidermal layer, provisionally identified as an inner peridermis, is composed of large cells that accumulate vesicular bodies and a network of coarse filaments. The sequence of epidermal layers produced beneath the inner peridermis in these agamine lizards corresponds to that of previously studied lizards, but the first subperidermal layer has characteristics of both clear (keratohyalin‐like granules) and oberhautchen (dark β‐keratin packets) cells. This layer is here identified as an oberhautchen since it fuses with the underlying β‐keratinizing cells forming large spinulae as the entire tissue becomes syncytial so that the units appear to increase in size. These spinulae very likely represent sections of honeycomb‐shaped micro‐ornamentations. A mesos layer appears underneath the β‐layer before hatching. J. Morphol. 240:251–266, 1999. © 1999 Wiley‐Liss, Inc.     

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.     

Epidermal differentiation during ontogeny and after hatching in the snake Liasis fuscus (Pythonidae,Serpentes, Reptilia), with emphasis on the formation of the shedding complex

Differentiation and localization of keratin in the epidermis during embryonic development and up to 3 months posthatching in the Australian water python, Liasis fuscus, was studied by ultrastructural and immunocytochemical methods. Scales arise from dome-like folds in the skin that produce tightly imbricating scales. The dermis of these scales is completely differentiated before any epidermal differentiation begins, with a loose dermis made of mesenchymal cells beneath the differentiating outer scale surface. At this stage (33) the embryo is still unpigmented and two layers of suprabasal cells contain abundant glycogen. At Stage 34 (beginning of pigmentation) the first layers of cells beneath the bilayered periderm (presumptive clear and oberhautchen layers) have not yet formed a shedding complex, within which prehatching shedding takes place. At Stage 35 the shedding complex, consisting of the clear and oberhautchen layers, is discernible. The clear layer contains a fine fibrous network that faces the underlying oberhautchen, where the spinulae initially contain a core of fibrous material and small beta-keratin packets. Differentiation continues at Stage 36 when the beta-layer forms and beta-keratin packets are deposited both on the fibrous core of the oberhautchen and within beta-cells. Mesos cells are produced from the germinal layer but remain undifferentiated. At Stage 37, before hatching, the beta-layer is compact, the mesos layer contains mesos granules, and cells of the alpha-layer are present but are not yet keratinized. They are still only partially differentiated a few hours after hatching, when a new shedding complex is forming underneath. Using antibodies against chick scale beta-keratin resolved at high magnification with immunofluorescent or immunogold conjugates, we offer the first molecular confirmation that in snakes only the oberhautchen component of the shedding complex and the underlying beta cells contain beta-keratin. Initially, there is little immunoreactivity in the small beta-packets of the oberhautchen, but it increases after fusion with the underlying cells to produce the syncytial beta layer. The beta-keratin packets coalesce with the tonofilaments, including those attached to desmosomes, which rapidly disappear in both oberhautchen and beta-cells as differentiation progresses. The labeling is low to absent in forming mesos-cells beneath the beta-layer. This study further supports the hypothesis that the shedding complex in lepidosaurian reptiles evolved after there was a segregation between alpha-keratogenic cells from beta-keratogenic cells during epidermal renewal.     

Morphogenesis of the digital pad lamellae in the embryo of the lizard Anolis lineatopus

The present study in the embryo of the lizard Anolis lineatopus describes the modality of cell proliferation responsible for the morphogenesis of the digital pad lamellae and of the epidermal stratification. After tritiated thymidine and 5-bromodeoxy-uridine administration, autoradiographic and immunocytochemical methods have been used. The lamellae originate as long, slightly slanted, undulations of the epidermis of fingers and toes. At an early stage, the epidermis consists of an outer periderm and a basal layer. Cell hypertrophy, and the prevalent cell proliferation in the longer side of the undulation with respect to the shorter side, generate the surface of the outer lamella. Under the peridermis, a shedding complex, composed by clear and oberhautchen layers, is formed and later determines the first intraepidermal shed. The first subperidermal layer derived from the basal layer is a clear layer and the first shed epidermis in the embryo is represented by periderm and clear layer. The heavily granulated clear layer in Anolis lineatopus represents the first epidermal layer produced in the embryonic epidermis, and is connected with the process of shedding. The spinulae of the underlying oberhautchen in the outer scale surface become long setae which grow toward the upper clear layer. Under the shedding complex a β-layer is produced. Autoradiographical study shows that the radioactivity stays in the basal layer for about 4 days before cells move to upper layers. At 6–8 days post-injection labelled cells are visible in the differentiated clear, oberhautchen and β-layers. Under the β-layer differentiating mesos cells are visible before the embryo hatches.     

Glycogen Distribution in Relation to Epidermal Cell Differentiation During Embryonic Scale Morphogenesis in the Lizard Anolis lineatopus

The differentiation of the epidermis during scale morphogenesis in the lizard Anolis lineatopus has been studied by autoradiographic and immunocytochemical techniques and by electron microscopy, in relation to mitotic activity and to the distribution of glycogen. The flat embryonic epidermis of the early embryo is transformed into symmetric epidermal papillae which progressively become asymmetric and eventually form scales with stratified epidermal and peridermal layers. Papilla asymmetrization and epidermal stratification derive from cell hypertrophy and multiplication in the “basal hypertrophic layer of the forming outer side of scales” (BLOS). Glycogen is scarce or absent during early stages of epidermis development. In the dermis no glycogen is found at any stage of scale morphogenesis. Glycogen particles 25–40 nm in size accumulate in hypertrophic basal cells and peridermal cells during scale development. Conversely cells in the forming inner side of scales do not accumulate glycogen, divide less frequently than in the outer side and do not form a β–keratinized layer. It is suggested that an osmotic effect related to glycogen deposition causes increased hydration of the BLOS, whose cells become swollen and contribute to the asymmetrization of the epidermal papillae. Glycogen decreases in suprabasal differentiating cells and disappears from the BLOS at the stage of complete keratinization of the scale, around the period of hatching. Terminal differentiation in the peridermis and suprabasal epidermal layers takes place by cell flattening and condensation of the nucleus and cytoplasm as typical for apoptotic cells.     

Microscopic analysis of lizard claw morphogenesis and hypothesis on its evolution

Morphogenesis of claws in the lizard Lampropholis guichenoti has been studied by light and electron microscopy. Claws originate from a thickening of the epidermis covering the tips of digits under which mesenchymal cells aggregate. Mesenchymal cells are in continuity with perichondrial cells of the last phalange, and are connected to the epidermis through numerous cell bridges that cross an incomplete basement membrane. The dense lamella is completed in non‐apical regions of the digit where also collagen fibrils increase. The dorsal side of the developing claw derives from the growth of the outer scale surface of the last scale of the digit. The corneous layer, made of beta‐keratin cells, curves downward by the tip of the growing claw. The epidermis of the ventral side of the claw contains keratohyaline‐like granules and alpha‐keratinocytes like an inner scale surface. The thickness of the horny layer increases in the elongating unguis while a thinner and softer corneous layer remains in the subunguis. These observations show that lizard claws derive from the modification of the last scale or scales of the digit, probably under the influence of the growing terminal phalanx. Some hypotheses on the evolution of claws in reptiles are presented.     

Comparative immunolocalization of keratin‐associated beta‐proteins (beta‐keratins) supports a new explanation for the cyclical process of keratinocyte differentiation in lizard epidermis

Lizard epidermis is made of beta‐ and alpha‐layers. Using Western blot tested antibodies, the ultrastructural immunolocalization of specific keratin‐associated beta‐proteins in the epidermis of different lizard species reveals that glycine‐rich beta‐proteins (HgG5) localize in the beta‐layer, while glycine–cysteine‐medium‐rich beta‐proteins (HgGC10) are present in oberhautchen and alpha‐layers. This suggests a new explanation for the formation of different epidermal layers during the shedding cycle in lepidosaurian epidermis instead of an alternance between beta‐keratins and alpha‐keratins. It is proposed that different sets of genes coding for specific beta‐proteins are activated in keratinocytes during the renewal phase of the shedding cycle. Initially, glycine–cysteine‐medium‐rich beta‐proteins with hydrophilic and elastic properties accumulate over alpha‐keratins in the oberhautchen but are replaced in the next cell layer with glycine‐rich hydrophobic beta‐proteins forming a resistant, stiff, and hydrophobic beta‐layer. The synthesis of glycine‐rich proteins terminates in mesos and alpha‐cells where these proteins are replaced with glycine–cysteine‐rich beta‐proteins. The pattern of beta‐protein deposition onto a scaffold of intermediate filament keratins is typical for keratin‐associated proteins and the association between alpha‐keratins and specific keratin‐associated beta‐proteins during the renewal phase of the shedding cycle gives rise to epidermal layers possessing different structural, mechanical, and texture properties.     

Differentiation of the epidermis of scutes in embryos and juveniles of the tortoise Testudo hermanni with emphasis on beta-keratinization

The sequence of differentiation of the epidermis of scutes during embryogenesis in the tortoise Testudo hermanni was studied using autoradiography, electron microscopy and immunocytochemistry. The study was mainly conducted on the epidermis of the carapace, plastron and nail. Epidermal differentiation resembles that described for other reptiles, and the embryonic epidermis is composed of numerous cell layers. In the early stages of differentiation of the carapacial ridge, cytoplasmic blebs of epidermal cells are in direct contact with the extracellular matrix and mesenchymal cells. The influence of the dermis on the formation of the beta‐layer is discussed. The dermis becomes rich in collagen bundles at later stages of development. The embryonic epidermis is formed by a flat periderm and four to six layers of subperidermal cells, storing 40–70‐nm‐thick coarse filaments that may represent interkeratin or matrix material. Beta‐keratin is associated with the coarse filaments, suggesting that the protein may be polymerized on their surface. The presence of beta‐keratin in embryonic epidermis suggests that this keratin might have been produced at the beginning of chelonian evolution. The embryonic epidermis of the scutes is lost around hatching and leaves underneath the definitive corneous beta‐layer. Beneath the embryonic epidermis, cells that accumulate typical large bundles of beta‐keratin appear at stage 23 and at hatching a compact beta‐layer is present. The differentiation of these cells shows the progressive replacement of alpha‐keratin bundles with bundles immunolabelled for beta‐keratin. The nucleus is degraded and electron‐dense nuclear material mixes with beta‐keratin. In general, changes in tortoise skin when approaching terrestrial life resemble those of other reptiles. Lepidosaurian reptiles form an embryonic shedding layer and crocodilians have a thin embryonic epidermis that is rapidly lost near hacthing. Chelonians have a thicker embryonic epidermis that accumulates beta‐keratin, a protein later used to make a thick corneous layer.     

Immunolocalization of large corneous beta‐proteins in the green anole lizard (Anolis carolinensis) suggests that they form filaments that associate to the smaller beta‐proteins in the beta‐layer of the epidermis

The distribution of large corneous beta‐proteins of 18–43 kDa (Ac37, 39, and 40) in the epidermis of the lizard Anolis carolinensis is unknown. This study analyses the localization of these beta‐proteins in different body scales during regeneration. Western blot analysis indicates most protein bands at 40–50 kDa suggesting they mix with alpha‐keratin of intermediate filament keratin proteins. Ac37 is present in mature alpha‐layers of most scales and in beta‐cells of the outer scale surface in some scales but is absent in the Oberhäutchen, in the setae and beta‐layer of adhesive pads and in mesos cells. In differentiating beta‐keratinocytes Ac37 is present over 3–4 nm thick filaments located around the amorphous beta‐packets and in alpha‐cells, but is scarce in precorneous and corneous layers of the claw. Ac37 forms long filaments and, therefore, resembles alpha‐keratins to which it probably associates. Ac39 is seen in the beta‐layer of tail and digital scales, in beta‐cells of regenerating scales but not in the Oberhäutchen (and adhesive setae) or in beta‐ and alpha‐layers of the other scales. Ac40 is present in the mature beta‐layer of most scales and dewlap, in differentiating beta‐cells of regenerating scales, but is absent in all the other epidermal layers. The large beta‐proteins are accumulated among forming beta‐packets of beta‐cells and are packed in the beta‐corneous material of mature beta‐layer. Together alpha‐keratins, large beta‐proteins form the denser areas of mature beta‐layer that may have a different consistence that the electron‐paler areas. J. Morphol. 276:1244–1257, 2015. © 2015 Wiley Periodicals, Inc.     

Immunolocalization of keratin‐associated beta‐proteins in developing epidermis of lizard suggests that adhesive setae contain glycine–cysteine‐rich proteins

The localization of specific keratin‐associated beta‐proteins (formerly referred to as beta‐keratins) in the embryonic epidermis of lizards is not known. Two specific keratin‐associated beta‐proteins of the epidermis, one representing the glycine‐rich subfamily (HgG5) and the other the glycine‐cysteine medium‐rich subfamily (HgGC10), have been immunolocalized at the ultrastructural level in the lizard Anolis lineatopus. The periderm and granulated subperiderm are most immunonegative for these proteins. HgG5 is low to absent in theOberhäutchen layer while is present in the forming beta‐layer, and disappears in mesos‐ and alpha‐layers. Instead, HgGC10 is present in the Oberhäutchen, beta‐, and also in the following alpha‐layers, and specifically accumulates in the developing adhesive setae but not in the surrounding cells of the clear layer. Therefore, setae and their terminal spatulae that adhere to surfaces allowing these lizards to walk vertically contain cysteine–glycine rich proteins. The study suggests that, like in adult and regenerating epidermis, the HgGC10 protein is not only accumulated in cells of the beta‐layer but also in those forming the alpha‐layer. This small protein therefore is implicated in resistance, flexibility, and stretching of the epidermal layers. It is also hypothesized that the charges of these proteins may influence adhesion of the setae of pad lamellae. Conversely, glycine‐rich beta‐proteins like HgG5 give rise to the dense, hydrophobic, and chromophobic corneous material of the resistant beta‐layer. This result suggests that the differential accumulation of keratin‐associated beta‐proteins over the alpha‐keratin network determines differences in properties of the stratified layers of the epidermis of lizards. J. Morphol. 2013. © 2012 Wiley Periodicals, Inc.     

The structure and development of the digital lamellae of lizards

The epidermal setae and the spinules of the digital lamellae of anoline and gekkonid lizards are shed periodically along with the rest of the outer layer of the skin. These structures are developed within the lamellae prior to ecdysis. The setae are larger and more complicated than the spinules and begin their development first. The setae of Anolis start as aggregations of tonofibrils beneath the plasma membrane of the presumptive Oberhautchen cells. These cells are arranged in rows parallel to the surface, several cell layers beneath the alpha layer of the skin. The developing setae protrude into the clear layer cells as finger-like projections, with the tonofibrils longitudinally oriented in the direction of growth. About 100 setae are formed by each Oberhautchen cells in Anolis. In late development, the clear layer cells lose their cellular contents and when shed along with all distal cells, retain a template of the new setae or spinules. The spinules and setae are formed before the fibrous and alpha layers of the new skin. The fibrous layer, which occurs only on the ventral (outer) layer of the lamellae, and the Oberhautchen with its setae and spinules, is considered the beta layer. The alpha layer, which occurs adjacent to the fibrous layer on the ventral surface and adjacent to the Oberhautchen on the dorsal (inner) surface, is morphologically identical to that of mammalian α keratin. The shed lizard skin consists of the alpha and beta layers as well as the degenerating cells of the outer epidermal generation, and the clear layer. The clear layer that is shed shows the template of the new setae and spinules developed in the new skin layer. The separation of the new from the old skin occurs along the intercellular space between the clear layer cells and the new Oberhautchen. The alpha layer of the skin is not fully keratinized at shedding. The setae of the digital lamellae of lizards represent unique epidermal structures — intracellular keratinized microstructures.     

Observations on the histochemistry and ultrastructure of regenerating caudal epidermis of the tuatara Sphenodon punctatus (Sphenodontida,Lepidosauria, Reptilia)

Study of the histology, histochemistry, and fine structure of caudal epidermal regeneration in Sphenodon punctatus through restoration of a scaled form reveals that the processes involved resemble those known in lizards. Following establishment of a wound epithelium (WE), subjacent scale neogenesis involves epidermal downgrowths into the dermis. Although the process is extremely slow, and most new scales do not overlap, their epidermal coverings reestablish epidermal generation (EG) formation. As in lizards, the flat, alpha-keratogenic, WE cells contain lipids as revealed by their affinity for Sudan III. A few mucous cells that store large PAS-positive mucus-like granules also occur in WE. During differentiation of WE cells, among the bundles of 70-nm tonofilaments are many lamellar bodies (LBs) and mucous granules (MGs) that discharge their contents into the cytoplasm and extracellular spaces producing a strongly PAS-positive keratinized tissue. Richness of epidermal lipids coexistent with mucus is a primitive characteristic for amniote vertebrates, probably related to functions as a barrier to cutaneous water loss (CWL). As scale neogenesis begins, beneath the superficial WE appear 3-5 layers of irregularly shaped cells. These contain tonofilament bundles surrounded by small, round keratohyalin-like granules (KHLGs) and a keratinized matrix with beta-keratin packets and a 3-5-nm thick keratin granulation. This mixture of alpha- and beta-keratogenic capacities resembles that seen in the innermost cells of a normal tuatara epidermal generation. As in the latter, but in contrast to both normal and regenerating lizard epidermis, no definable shedding complex with interdigitating clear layer and oberhautchen cells occurs (Alibardi and Maderson, 2003). The tortuous boundaries, and merging beta-keratin packets, identify subjacent keratinizing cells as precursors of the typical stratified, squamous beta-layer seen in long-term regenerated caudal skin wherein the entire vertical sequence of epidermal layers resembles that of normal scales. The sequence of events in caudal epidermal regeneration in S. punctatus resembles that documented for lizards. Observed differences between posttrauma scale neogenesis and scale embryogenesis are responses to functional problems involved in, respectively, restoring, or forming, a barrier to CWL while accommodating rapid somatic growth.     

Immunolocalization of specific beta‐proteins in pad lamellae of the digits in the lizard Anolis carolinensis suggests that cysteine‐rich beta‐proteins provides flexibility

Knowledge of beta‐protein (beta‐keratin) sequences in Anolis carolinensis facilitates the localization of specific sites in the skin of this lizard. The epidermal distribution of two new beta‐proteins (beta‐keratins), HgGC8 and HgG13, has been analyzed by Western blotting, light and ultrastructural immunocytochemistry. HgGC8 includes 16 kDa members of the glycine‐cysteine medium‐rich subfamily and is mainly expressed in the beta‐layer of adhesive setae but not in the setae. HgGC8 is absent in other epidermal layers of the setae and is weakly expressed in the beta‐layer of other scales. HgG13 comprises members of 17‐kDa glycine‐rich proteins and is absent in the setae, diffusely distributed in the beta layer of digital scales and barely present in the beta‐layer of other scales. It appears that the specialized glycine‐cysteine medium rich beta‐proteins such as HgGC8 in the beta‐layer, and of HgGC10 and HgGC3 in both alpha‐ and beta‐layers, are key proteins in the formation of the flexible epidermal layers involved in the function of these modified scales in adaptation to contact and adhesion on surfaces. J. Morphol. 275:504–513, 2014. © 2013 Wiley Periodicals, Inc.     

Cell adhesion and junctional proteins in the developing skin of snakes indicate they coordinate the differentiation of the epidermis

The development of scales and the sequence of epidermal layers during snake embryogenesis has been studied by immunofluorescence for the localization of cell adhesion, adherens, and communicating cell junctional proteins. At about 2nd/3rd of embryonic development in snakes the epidermis forms symmetric bumps at the beginning of scale formation, and they rapidly become asymmetric and elongate forming outer and inner surfaces of the very overlapped scales seen at hatching. The dermis separates a superficial loose from a deeper dense part; the latter is joined to segmental muscles and nerves, likely acting on scale orientation during snake movements. N-cam is present in the differentiating epidermis and mesenchyme of forming scales while L-cam is only/mainly detected in the periderm and epidermis. Mesenchymal N-cam is associated with the epidermis of the elongating dorsal scale surface and with the beta-differentiation that occurs in the overlapping outer surface of scales. Beta-catenin and Connexin-43 show a similar distribution, and they are mainly present in the periderm and differentiating suprabasal keratinocytes likely forming an intense connectivity during epidermal differentiation. Beta-catenin also shows nuclear localization in differentiating cells of the shedding and beta-layers at late stages of scale morphogenesis, before hatching. The study suggests that intensification of adhesion and gap junctions allows synchronization of the differentiation of suprabasal cells to produce the ordered sequence of epidermal layers of snake scales, starting from the shedding complex and the beta-layer.

     

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.     

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.     

Immunocytochemical analysis of beta keratins in the epidermis of chelonians,lepidosaurians, and archosaurians

Beta (beta) keratins are present only in the avian and reptilian epidermises. Although much is known about the biochemistry and molecular biology of the beta keratins in birds, little is known for reptiles. In this study we have examined the distribution of beta keratins in the adult epidermis of turtle, lizard, snake, tuatara, and alligator using light and electron immunocytochemistry with a well-characterized antiserum (anti-beta(1) antiserum) made against a known avian scale type beta keratin. In lizard, snake, and tuatara epidermis this antiserum reacts strongly with the beta-layer, more weakly with the oberhautchen before it merges with the beta-layer, and least intensely with the mesos layer. In addition, the anti-beta(1) antiserum reacts specifically with the setae of climbing pads in gekos, the plastron and carapace of turtles, and the stratum corneum of alligator epidermis. Electron microscopic studies confirm that the reaction of the anti-beta(1) antiserum is exclusively with characteristic bundles of the 3-nm beta keratin filaments in the cells of the forming beta-layer, and with the densely packed electron-lucent areas of beta keratin in the mature bet- layer. These immunocytochemical results suggest that the 3-nm beta keratin filaments of the reptilian integument are phylogenetically related to those found in avian epidermal appendages.     

Histochemical and ultrastructural analyses of adhesive setae of lizards indicate that they contain lipids in addition to keratins

We studied the distribution of lipid material and organelles in the epidermal layers of toe pads from two species of lizards representing the two main lizard families in which adhesive scansors are found (gekkonids and polychrotids), the dull day gecko, Phelsuma dubia and the green anole, Anolis carolinensis. Although lipids are a conspicuous component of the mesos layer of squamate reptiles and function in reducing cutaneous water loss, their distribution has not been specifically studied in the highly elaborated epidermal surface of adhesive toe pads. We found that, in addition to the typical cutaneous water loss‐resistant mesos and alpha‐layer lipids, the Oberhäutchen (including the setae) on the most exterior layers of the epidermis in P. dubia and A. carolinensis also contain lipid material. We also present detailed histochemical and ultrastructural analyses of the toe pads of P. dubia, which indicate that lipid material is closely associated spatially with maturing setae as they branch during the renewal phase of epidermal regeneration. This lipid material appears associated with the packing of keratin within setae, possibly affecting permeability to water loss in the pad lamella, where the surface area is from 4–60‐fold greater compared with normal scales. J. Morphol., 2011. © 2011 Wiley‐Liss, Inc.     

Keratinization of the outer surface of the avian scutate scale: Interrelationship of alpha and beta keratin filaments in a cornifying tissue

Summary The outer surface of adult Gallus domesticus scutate scale was studied as a model for epidermal cornification involving accumulation of both alpha and beta keratins. Electron-microscopic analysis demonstrated that the basal cells of the adult epidermis contained abundant lipid droplets and that filament bundles and desmosomes were distributed throughout the cell layers. Indirect immunofluorescence microscopy and double-labeling immunogold-electron microscopy confirmed that the stratum germinativum contained alpha keratin but not beta keratin. Beta keratins were first detected in the stratum intermedium and were always found intermingled with filament bundles of alpha keratin. As the differentiating cells moved into the outer regions of the stratum intermedium and the stratum corneum, the large mixed keratin filament bundles labeled increasingly more with beta keratin antiserum and relatively less so with alpha keratin antiserum. Sodium dodecyl sulfate-polyacrylamide gel analysis of vertical layers of the outer surface of the scutate scale confirmed that cells having reached the outermost layers of stratum corneum had preferentially lost alpha keratin. The mixed bundles of alpha and beta keratin filaments were closely associated with desmosomes in the lower stratum intermedium and with electron-dense aggregates in the cytoplasm of cells in the outer stratum intermedium. Using anti-desmosomal serum it was shown that these cytoplasmic plaques were desmosomes.     

Ultrastructural localization of hair keratin homologs in the claw of the lizard Anolis carolinensis

The claw of lizards is largely composed of beta‐keratins, also referred to as keratin‐associated beta‐proteins. Recently, we have reported that the genome of the lizard Anolis carolinensis contains alpha keratin genes homologous to hair keratins typical of hairs and claws of mammals. Molecular and immunohistochemical studies demonstrated that two hair keratin homologs named hard acid keratin 1 (HA1) and hard basic keratin 1 (HB1) are expressed in keratinocytes forming the claws of A. carolinensis. Here, we extended the immunocytochemical localization of the novel reptilian keratins to the ultrastructural level. After sectioning, claws were subjected to immunogold labeling using antibodies against HA1, HB1, and, for comparison, beta‐keratins. Electron microscopy showed that the randomly organized network of tonofilaments in basal and suprabasal keratinocytes becomes organized in long and parallel bundles of keratin in precorneous layers, resembling cortical cells of hairs. Entering the cornified part of the claw, the elongated corneous cells fuse and accumulate corneous material. HA1 and HB1 are absent in the basal layer and lower spinosus layers of the claw and are expressed in the upper and precorneous layers, including the elongating corneocytes. The labeling for alpha‐keratin was loosely associated with filament structures forming the fibrous framework of the claws. The ultrastructural distribution pattern of hard alpha‐keratins resembled that of beta‐keratins, which is compatible with the hypothesis of an interaction during claw morphogenesis. The data on the ultrastructural localization of hair keratin homologs facilitate a comparison of lizard claws and mammalian hard epidermal appendages containing hair keratins. J. Morphol., 2011. © 2010 Wiley‐Liss, Inc.