Origin of feathers: Feather beta (beta) keratins are expressed in discrete epidermal cell populations of embryonic scutate scales

The feathers of birds develop from embryonic epidermal lineages that differentiate during outgrowth of the feather germ. Independent cell populations also form an embryonic epidermis on scutate scales, which consists of peridermal layers, a subperiderm, and an alpha stratum. Using an antiserum (anti-FbetaK) developed to react specifically with the beta (beta) keratins of feathers, we find that the feather-type beta keratins are expressed in the subperiderm cells of embryonic scutate scales, as well as the barb ridge lineages of the feather. However, unlike the subperiderm of scales, which is lost at hatching, the cells of barb ridges, in conjunction with adjacent cell populations, give rise to the structural elements of the feather. The observation that an embryonic epidermis, consisting of peridermal and subperidermal layers, also characterizes alligator scales (Thompson, 2001. J Anat 198:265-282) suggests that the epidermal populations of the scales and feathers of avian embryos are homologous with those forming the embryonic epidermis of alligators. While the embryonic epidermal populations of archosaurian scales are discarded at hatching, those of the feather germ differentiate into the periderm, sheath, barb ridges, axial plates, barbules, and marginal plates of the embryonic feather filament. We propose that the development of the embryonic feather filament provides a model for the evolution of the first protofeather. Furthermore, we hypothesize that invagination of the epidermal lineages of the feather filament, namely the barb ridges, initiated the formation of the follicle, which then allowed continuous renewal of the feather epidermal lineages, and the evolution of diverse feather forms.     

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.     

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.     

How and when the regional competence of chick epidermis is established: feathers vs. scutate and reticulate scales, a problem en route to a solution

Most of the chick body is covered with feathers, while the tarsometatarsus and the dorsal face of the digits form oblong overlapping scales (scuta) and the plantar face rounded nonoverlapping scales (reticula). Feathers and scuta are made of beta-keratins, while the epidermis of reticula and inter-appendage or apteria (nude regions) express a-keratins. These regional characteristics are determined in skin precursors and require an epidermal FGF-like signal to be expressed. Both the initiation of appendages, their outline and pattern depend on signals from the dermis, while their asymmetry and outgrowth depend on epidermal competence. For example, the plantar dermis of the central foot pad induces reticula in a plantar or feathers in an apteric epidermis, in a hexagonal pattern starting from the medial point. By manipulating Shh levels in the epidermis, the regional appendage type can be changed from scuta or reticula to feather, whereas the inhibition of Wnt7a, together with a downregulation of Shh gives rise to reticula and in extreme cases, apteria. During morphogenesis of plantar skin, the epidermal expression of En-1, acting as a repressor both of Wnt7a and Shh, is linked to the formation of reticula. Finally, in birds, the complex formation of feathers, which can be easily triggered, even in the extra-embryonic somatopleure, may result from a basic genetic program, whereas the simple formation of scales appears secondarily derived, as requiring a partial (scuta) or total (reticula) inhibition of epidermal outgrowth and beta-keratin gene expression, an inhibition lost for the scuta in the case of feathered feet breeds.     

Synthesis of interkeratin matrix in differentiating lizard epidermis: an ultrastructural autoradiographic study after injection of tritiated proline and histidine

During epidermal differentiation in mammals, keratins and keratin-associated matrix proteins rich in histidine are synthesized to produce a corneous layer. Little is known about interkeratin proteins in nonmammalian vertebrates, especially in reptiles. Using ultrastructural autoradiography after injection of tritiated proline or histidine, the cytological process of synthesis of beta-keratin and interkeratin material was studied during differentiation of the epidermis of lizards. Proline is mainly incorporated in newly synthesized beta-keratin in beta-cells, and less in oberhautchen cells. Labeling is mainly seen among ribosomes within 30 min postinjection and appears in beta-keratin packets or long filaments 1-3 h later. Beta-keratin appears as an electron-pale matrix material that completely replaces alpha-keratin filaments in cells of the beta-layer. Tritiated histidine is mainly incorporated into keratohyalin-like granules of the clear layer, in dense keratin bundles of the oberhautchen layer, and also in dense keratin filaments of the alpha and lacunar layer. The detailed ultrastructural study shows that histidine-labeling is localized over a dense amorphous material associated with keratin filaments or in keratohyalin-like granules. Large keratohyalin-like granules take up labeled material at 5-22 h postinjection of tritiated histidine. This suggests that histidine is utilized for the synthesis of keratins and keratin-associated matrix material in alpha-keratinizing cells and in oberhautchen cells. As oberhautchen cells fuse with subjacent beta-cells to form a syncytium, two changes occur : incorporation of tritiated histidine, but uptake of proline increases. The incorporation of tritiated histidine in oberhautchen cells lowers after merging with cells of the beta-layer, whereas instead proline uptake increases. In beta-cells histidine-labeling is lower and randomly distributed over the cytoplasm and beta-keratin filaments. Thus, change in histidine uptake somehow indicates the transition from alpha- to beta-keratogenesis. This study indicates that a functional stratum corneum in the epidermis of amniotes originates only after the association of matrix and corneous cell envelope proteins with the original keratin scaffold of keratinocytes.     

An ultrastructural study of periderm granules in the regenerating feather of the jungle fowl

Summary Periderm granules in the support cells of regenerating feathers of mature male Jungle Fowls were studied ultrastructurally and histochemically. Histochemical results showed the absence of carbohydrate and lipid, and the presence of protein in the periderm granules. The periderm granules were measured at successive levels of feather regeneration. The mean size of the periderm granules increased significantly as the regenerating feather matured, and this observation was suggestive of a storage function, perhaps of surplus or waste protein. The cells in which the periderm granules are found also contain glycogen. There are numerous desmosomal junctions on their interdigitating plasma membranes. These transient cells may collect waste, provide nutrition, and serve as a protective barrier for the definitive cells of the regenerating feather.     

Analysis of morphogenesis and keratinization in transfilter recombinants of feather-forming skin

The relationships between feather morphogenesis, histogenesis, and biochemical differentiation were examined by recombining backskin epidermis and dermis, from chick embryos (Hamburger-Hamilton stages 27-31), with an intervening Nucleopore filter (pore size of 0.4 micron). The filter inhibited normal feather morphogenesis and histogenesis of barb ridges, yet feather-like filaments, which were free of dermal cells, formed from the epidermal cells. Using indirect immunofluorescence, with antiserum against alpha- and beta-keratins, the biochemical differentiation of the feather-like filaments was compared to normal feathers. In the feather-like filaments resulting from tissues of stages 27-29, cells containing beta keratins were occasionally seen at the periphery of the filaments, yet cells containing alpha-keratins were inappropriately located throughout the filaments. In a few feather-like filaments on recombinants resulting from tissues of stages 29.5-31, cells positive for beta-keratins were found in the center of the filament, but again alpha-keratins were also found. Surrounding these cells there were several layers of cells, arranged circumferentially, resembling sheath cells. Some sheath-like cells contained beta-keratins. We conclude that although feather epidermal cells, which are separated from their dermis by a Nuclepore filter, can undergo limited morphogenesis and the production of alpha- and beta-keratins, normal feather morphogenesis, histogenesis, and biochemical differentiation require the intimate associations of epidermis and dermis.     

Cell junctions during morphogenesis of feathers: general ultrastructure with emphasis on adherens junctions

Alibardi, L. 2011. Cell junctions during morphogenesis of feathers: general ultrastructure with emphasis on adherens junctions. —Acta Zoologica (Stockholm) 92 : 89–100. The present ultrastructural and immunocytochemical study analyzes the cell junctions joining barb/barbule cells versus cell junctions connecting supportive cells in forming feathers. Differently from the epidermis or the sheath, desmosomes are not the prevalent junctions among feather cells. Numerous adherens junctions, some gap junctions and fewer tight junctions are present among differentiating barb/barbule cells during early stages of their differentiation. Adherens junctions are frequent also among differentiating supportive cells and show weak immunolabeling for both N‐cadherin and neural‐cell adhesion molecule (N‐CAM). Differentiating barb and barbule cells do not show labeled junctions for N‐cadherin and N‐CAM. The labeling occurs at patches in the cytoplasm of supportive cells but is more frequently seen in the external cytoplasm and along the extra‐cellular space (glycocalix) covering the plasma membrane of supportive cells. Labeling for N‐cadherin is also found in medium‐dense 0.1‐ to 0.3‐μm granules present in supportive cells and sometimes is associated with coarse filaments or periderm granules. The study indicates that adherens junctions form most of the transitional connections among supportive cells before their degeneration. Keratinizing barb and barbule cells loose the labeling for adherens junctions (N‐CAM and N‐chaderin) while their adhesion is strengthened by the incorporation of cell junctions in the corneous mass forming the barbules.     

Immunological characterization and fine localization of a lizard beta-keratin

Scales of lizards contain beta-keratin of poorly known composition. In the present study, a rat polyclonal serum against a lizard beta-keratin of 14-15 kDa has been produced and the relative protein has been immunolocalized in the epidermis. The observations for the first time show that the isolated protein band derives from the extraction of a protein component of the beta-keratin filaments of lizard epidermis. In immunoblots and immunocytochemistry, the antiserum recognizes most lizard beta-keratins, but produces a variable cross-reactivity with snake beta-keratins, and weak or no reactivity with beta-keratins isolated from tuatara, turtles, alligator and birds. In bidimensional immunoblots of lizard epidermis, three main spots at 15-16 kDa with isoelectric point at 7.0, 7.6 and 8.0, and an unresolved large spot at 29-30 kDa and with pI at 7.5-8.0, are obtained, may be derived from the aggregation of smaller beta-keratin proteins. The ultrastructural immunolocalization with the antibody against lizard beta-keratin shows that only small and large beta-keratin filaments of beta-cells of lizard epidermis are labeled. Keratin bundles in oberhautchen cells are less immunolabeled. Beta-keratin is rapidly polymerized into beta-packets that merge into larger beta-keratin filaments. No labeling is present over other cell organelles or cell layers of lizard epidermis, and is absent in non-epidermal cells. The antiserum recognizes epitope(s) characteristics for lizard beta-keratins, partially recognized in snakes and absent in non-lepidosaurian species. This result indicates that beta-keratins among different reptilian groups posses different immunoreactive regions.     

Proliferation of human embryonic and fetal epidermal cells in organ culture

The morphology of human embryonic and fetal skin growth in organ culture at the air-medium interface was examined, and the labeling indices of the epidermal cells in such cultures were determined. The two-layered epidermis of embryonic specimens increased to five or six cell layers after 21 days in culture, and the periderm in such cultures changed from a flat cell type to one with many blebs. The organelles in the epidermal cells remained unchanged. Fetal epidermis, however, differentiated when grown in this organ culture system from three layers (basal, intermediate, and periderm) to an adult-type epidermis with basal, spinous, granular, and cornified cell layers. Keratohyalin granules, lamellar granules, and bundles of keratin filaments, organelles associated with epidermal cell differentiation, were observed in the suprabasal cells of such cultures. The periderm in these fetal cultures formed blebs early but was sloughed with the stratum corneum in older cultures. The rate of differentiation of the fetal epidermis in organ culture was related to the initial age of the specimen cultured, with the older specimens differentiating at a faster rate than the younger specimens. Labeling indices (LIs) of embryonic and fetal epidermis and periderm were determined. The LI for embryonic basal cells was 8.5% and for periderm was 8%. The fetal LIs were 7% for basal cells, 1% for intermediate cells, and 3% for periderm. The ability to maintain viable pieces of skin in organ culture affords a model for studying normal and abnormal human epidermal differentiation from fetal biopsies and for investigating proliferative diseases.     

Distribution and characterization of proteins associated with cornification in the epidermis of gecko lizard

The distribution and molecular weight of epidermal proteins of gecko lizards have been studied by ultrastructural, autoradiographic, and immunological methods. Setae of the climbing digital pads are cross-reactive to antibodies directed against a chick scutate scale beta-keratin but not against feather beta-keratin. Cross-reactivity for mammalian loricrin, sciellin, filaggrin, and transglutaminase are present in alpha-keratogenic layers of gecko epidermis. Alpha-keratins have a molecular weight in the range 40-58 kDa. Loricrin cross-reactive bands have molecular weights of 42, 50, and 58 kDa. Bands for filaggrin-like protein are found at 35 and 42 kDa, bands for sciellin are found at 40-45 and 50-55 kDa, and bands for transglutaminase are seen at 48-50 and 60 kDa. The specific role of these proteins remains to be elucidated. After injection of tritiated histidine, the tracer is incorporated into keratin and in setae. Tritiated proline labels the developing setae of the oberhautchen and beta layers, and proline-labeled proteins (beta-keratins) of 10-14, 16-18, 22-24 and 32-35 kDa are extracted from the epidermis. In whole epidermal extract (that includes the epidermis with corneous layer and the setae of digital pads), beta-keratins of low-molecular weight (10, 14-16, and 18-19 kDa) are prevalent over those at higher molecular weight (34 and 38 kDa). In contrast, in shed epidermis of body scales (made of corneous layer only while setae were not collected), higher molecular weight beta-keratins are present (25-27 and 30-34 kDa). This suggests that a proportion of the small beta-keratins present in the epidermis of geckos derive from the differentiating beta layer of scales and from the setae of digital pads. Neither small nor large beta-keratins of gecko epidermis cross-react with an antibody specifically directed against the feather beta-keratin of 10-12 kDa. This result shows that the 10 and 14-16 kDa beta-keratins of gecko (lepidosaurian) have a different composition than the 10-12 kDa beta-keratin of feather (archosaurian). It is suggested that the smaller beta-keratins in both lineages of sauropsids were selected during evolution in order to build elongated bundles of keratin filaments to make elongated cells. Larger beta-keratins in reptilian scales produce keratin aggregations with no orientation, used for mechanical protection.     

Characterization of beta-keratins and associated proteins in adult and regenerating epidermis of lizards

Reptilian epidermis contains two types of keratin, soft (alpha) and hard (beta). The biosynthesis and molecular weight of beta-keratin during differentiation of lizard epidermis have been studied by autoradiography, immunocytochemistry and immunoblotting. Tritiated proline is mainly incorporated into differentiating and maturing beta-keratin cells with a pattern similar to that observed after immunostaining with a chicken beta-keratin antibody. While the antibody labels a mature form of beta-keratin incorporated in large filaments, the autoradiographic analysis shows that beta-keratin is produced within the first 30 min in ribosomes, and is later packed into large filaments. Also the dermis incorporates high amount of proline for the synthesis of collagen. The skin was separated into epidermis and dermis, which were analyzed separately by protein extraction and electrophoresis. In the epidermal extract proline-labeled proteic bands at 10, 15, 18-20, 42-45, 52-56, 85-90 and 120 kDa appear at 1, 3 and 5 h post-injection. The comparison with the dermal extract shows only the 85-90 and 120 kDa bands, which correspond to collagen. Probably the glycine-rich sequences of collagen present also in beta-keratins are weakly recognized by the beta-1 antibody. Immunoblotting with the beta-keratin antibody identifies proteic bands according to the isolation method. After-saline or urea-thiol extraction bands at 10-15, 18-20, 40, 55 and 62 kDa appear. After extraction and carboxymethylation, weak bands at 10-15, 18-20 and 30-32 kDa are present in some preparations, while in others also bands at 55 and 62 kDa are present. It appears that the lowermost bands at 10-20 kDa are simple beta-keratins, while those at 42-56 kDa are complex or polymeric forms of beta-keratins. The smallest beta-keratins (10-20 kDa) may be early synthesized proteins that are polymerized into larger beta-keratins which are then packed to form larger filaments. Some proline-labeled bands differ from those produced after injection of tritiated histidine. The latter treatment does not show 10-20 kDa labeled proteins, but tends to show bands at 27, 30-33, 40-42 and 50-62 kDa. Histidine-labeled proteins mainly localize in keratohyalin-like granules and dark keratin bundles of clear-oberhautchen layers of lizard epidermis, and their composition is probably different from that of beta-keratin.     

The Integumentary Morphology of Modern Birds--An Overview

Avian integument is thin, elastic, and loosely attached to thebody, giving birds the freedom of movement needed for flight.Its epidermis is both keratinized and lipogenic, and the skinas a whole acts as a sebaceous secretory organ. The skin iscovered by feathers over most of the body, but many birds showcolored bare skin or integumentary outgrowths on the head andneck. Heavily cornified epidermis covers the beak, claws, spurs,and the scales on the legs and feet. These structures (exceptthe back of the leg and underside of the foot) contain beta-keratinlike that in reptilian scales. Most birds have sebaceous secretoryglands at the base of the tail and in the ear canals. Feathersare the most numerous, elaborate, and diverse of avian integumentaryderivatives. Their diversity is due to the possibilities inherentin their basic plan of a shaft with two orders of branches andthe use of modified beta-keratin as a strong, light, and plasticbuilding material. The evolution of feathers in birds has beenaccompanied by the development of complex systems for producingcolors and patterns, the innovations of feather arrangementand follicles with their musculature and innervation, and theprocess and control of molting.     

Cell organization of barb ridges in regenerating feathers of the quail: implications of the elongation of barb ridges for the evolution and diversification of feathers

This ultrastructural study on the regenerating feathers of quail describes the cellular organization of the barb ridges responsible for the ramification of adult feathers. Bilateral symmetry of the barb ridges determines the organization of feather cells into feather branching. The length of the barb ridges, derived from the number of cells associated to form the barbule plates, determines the length of the barbule branching. Long chains of barb cells form long barbs that branch from the rachis with an increase of feather size. Supportive cells function as spacers between the barbule cells. New cells derive from stem cells localized in the collar region of the feather follicle, as indicated from the re‐organization of collar cells into barb ridges (a morphogenetic process inherited from that of embryonic feathers), production of an embryonic type of keratin (feather keratin), permanence of periderm granules (typical embryonic organelles) in barb vane ridge cells. Variations in the process of barb ridge morphogenesis allow the fusion of ridges into a rachis. The differentiation of hooklets contributes to the origin of planar feathers. Separation between rachis and merging barb ridges is by supportive cells, derived from the marginal plates of the barb ridges. Speculations on the evolution and diversification of feathers are presented.     

Ultrastructural autoradiographic and immunocytochemical analysis of setae formation and keratinization in the digital pads of the gecko Hemidactylus turcicus (Gekkonidae,Reptilia)

The modified subdigital scales of some lizards allow them to climb vertical surfaces. This is due to the action of millions of tiny setae present in the digital pads. Setae are mainly composed of beta-keratin which may have some modality of aggregation similar to that of barbs and barbules of feathers. Keratins and associated proteins are involved in the organization of setae. The formation of setae in the climbing pad lamellae of the gecko Hemidactylus turcicus has been analyzed under the electron microscope after injection of tritiated histidine and immunocytochemistry for a chick scale beta-keratin. Setae are made up of dense and pale filaments, both oriented along the longer axis of setae. Beta-keratin is present in the oberhautchen layer and in the growing setae which are highly modified oberhautchen cells. Most of the immunolabeling concentrated in the central part of setae. This cross-reactivity suggests that some epitopes in chick beta-keratin are also present in gecko setae. Four hours after injection of tritiated histidine, the labeling is localized over setae, in particular in the dense filaments and less in the pale filaments. Some labeling is also seen in the keratinaceous material present in the cytoplasm of clear cells, which are believed to mold setae. The present observations suggest that both beta-keratin and denser matrix proteins, possibly incorporating histidine, are packed into growing setae. These proteins may be mixed to form pale and dense filaments oriented along the longer axis of setae, a pattern resembling that of barb and barbule cells of feathers. The role of matrix material in the orientation of the deposited beta-keratin during setal outgrowth is discussed with the problem of barb and barbule differentiation in avian feathers.     

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.     

The epidermis of scales in gecko lizards contains multiple forms of beta-keratins including basic glycine-proline-serine-rich proteins

The epidermis of scales of gecko lizards comprises alpha- and beta-keratins. Using bidimensional electrophoresis and immunoblotting, we have characterized keratins of corneous layers of scales in geckos, especially beta-keratins in digit pad lamellae. In the latter, the formation of thin bristles (setae) allow for the adhesion and climbing vertical or inverted surfaces. alpha-Keratins of 55-66 kDa remain in the acidic and neutral range of pI, while beta-keratins of 13-18 kDa show a broader variation of pI (4-10). Some protein spots for beta-keratins correspond to previously sequenced, basic glycine-proline-serine-rich beta-keratins of 169-191 amino acids. The predicted secondary structure shows that a large part of the molecule has a random-coiled conformation, small alpha helix regions, and a central region with 2-3 strands (beta-folding). The latter, termed core-box, shows homology with feather-scale-claw keratins of birds and is involved in the formation of beta-keratin filaments. Immunolocalization of beta-keratins indicates that these proteins are mainly present in the beta-layer and oberhautchen layer, including setae. The sequenced proteins of setae form bundles of keratins that determine their elongation. This process resembles that of feather-keratin on the elongation of barbule cells in feathers. It is suggested that small proteins rich in glycine, serine, and proline evolved in reptiles and birds to reinforce the mechanical resistance of the cytokeratin cytoskeleton initially present in the epidermis of scales and feathers.     

The proteins of the embryonic chick epidermis : I. During the normal development in ovo

As a preliminary to a study of the proteins of the embryonic chick epidermis when grown in vitro under various culture conditions, the proteins of the anterior metatarsal epidermis, from 11 days of embryonic life up to 9 days posthatching, have been studied. Carboxymethylated derivatives of the proteins extracted by a thiol reduction procedure have been analyzed by polyacrylamide gel electrophoresis. The results have shown that the differentiation of the epidermis is characterized by the appearance between days 14 and 17 of at least 11 major protein bands in the electrophoretic pattern. Two of these bands are of relatively high molecular weight protein and appear earlier than the remaining bands which form a group of closely related, low molecular weight protein species. The differentiation of the tissue also involves the disappearance from the electrophoretic pattern of all but one of the five major bands present in extracts of the 11/12-day epidermis. A study of the proteins derived from the isolated periderm of the 14-day chick embryo beak has suggested that one of the major bands in the 11/12-day metatarsal epidermal extracts may be a peridermal protein.     

Fine structure and immunocytochemistry of monotreme hairs, with emphasis on the inner root sheath and trichohyalin-based cornification during hair evolution

The fine structure of hairs in the most ancient extant mammals, the monotremes, is not known. The present study analyzes the ultrastructure and immunocytochemistry for keratins, trichohyalin, and transglutaminase in monotreme hairs and compares their distribution with that present in hairs of the other mammals. The overall ultrastructure of the hair and the distribution of keratins is similar to that of marsupial and placental hairs. Acidic and basic keratins mostly localize in the outer root sheath. The inner root sheath (IRS) comprises 4-8 cell layers in most hairs and forms a tile-like sheath around the hair shaft. No cytological distinction between the Henle and Huxley layers is seen as cells become cornified about at the same time. Externally to the last cornified IRS cells (homologous to the Henle layer), the companion layer contains numerous bundles of keratin. Occasionally, some granules in the companion layer show immunoreactivity for the trichohyalin antibody. This further suggests that the IRS in monotremes is ill-defined, as the companion layer of placental hairs studied so far does not express trichohyalin. A cross-reactivity with an antibody against sheep trichohyalin is present in the IRS of monotremes, suggesting conserved epitopes across mammalian trichohyalin. Trichohyalin granules in the IRS consist of a framework of immunolabeled coarse filaments of 10-12 nm. The latter assume a parallel orientation and lose the immunoreactivity in fully cornified cells. Transglutaminase immunolabeling is diffuse among trichohyalin granules and among the parallel 10-12 nm filaments of maturing inner root cells. Transglutaminase is present where its substrate, trichohyalin, is modified as matrix protein. Cornification of IRS is different from that of hair fiber cuticle and from that of the cornified layer of the epidermis above the follicle. The different consistency among cuticle, IRS, and corneous layer of the epidermis determines separation between hair fiber, IRS, and epidermis. This allows the hair to exit on the epidermal surface after shedding from the IRS and epidermis. Based on comparative studies of reptilian and mammalian skin, a speculative hypothesis on the evolution of the IRS and hairs from the skin of synapsid reptiles is presented.     

Review: cornification,morphogenesis and evolution of feathers

Feathers are corneous microramifications of variable complexity derived from the morphogenesis of barb ridges. Histological and ultrastructural analyses on developing and regenerating feathers clarify the three-dimensional organization of cells in barb ridges. Feather cells derive from folds of the embryonic epithelium of feather germs from which barb/barbule cells and supportive cells organize in a branching structure. The following degeneration of supportive cells allows the separation of barbule cells which are made of corneous beta-proteins and of lower amounts of intermediate filament (IF)(alpha) keratins, histidine-rich proteins, and corneous proteins of the epidermal differentiation complex. The specific protein association gives rise to a corneous material with specific biomechanic properties in barbules, rami, rachis, or calamus. During the evolution of different feather types, a large expansion of the genome coding for corneous feather beta-proteins occurred and formed 3–4-nm-thick filaments through a different mechanism from that of 8–10 nm IF keratins. In the chick, over 130 genes mainly localized in chromosomes 27 and 25 encode feather corneous beta-proteins of 10–12 kDa containing 97–105 amino acids. About 35 genes localized in chromosome 25 code for scale proteins (14–16 kDa made of 122–146 amino acids), claws and beak proteins (14–17 kDa proteins of 134–164 amino acids). Feather morphogenesis is periodically re-activated to produce replacement feathers, and multiple feather types can result from the interactions of epidermal and dermal tissues. The review shows schematic models explaining the translation of the morphogenesis of barb ridges present in the follicle into the three-dimensional shape of the main types of branched or un-branched feathers such as plumulaceous, pennaceous, filoplumes, and bristles. The temporal pattern of formation of barb ridges in different feather types and the molecular control from the dermal papilla through signaling molecules are poorly known. The evolution and diversification of the process of morphogenesis of barb ridges and patterns of their formation within feathers follicle allowed the origin and diversification of numerous types of feathers, including the asymmetric planar feathers for flight.