Pigment cell localizations in anuran ventral skin at climactic metamorphosis.

In anuran amphibians, the specific color pattern of the skin is expressed after metamorphosis, and its formation involves pigment cell migrations. Pigment cells are differently distributed in the tadpole, larval, and froglet skin. To learn more about their fate during metamorphic climax and in the young froglet, we focused our attention on the different localizations of larval melanophores and iridophores in the ventral skin of Rana esculenta before and during skin homing. Localizations of melanophores and iridophores can be elucidated at the developmental stages suggested by Taylor and Kollros (TK stages). At TK stage II (during early premetamorphosis), large melanophores beneath the larval skin are detected. At TK stage X, dispersed melanophores lie under bundles of muscular striated fibrils near the larval skin; they are also observed at the vascular level. At TK stage XVII (prometamorphosis), melanophores are extended on the inner side of the basement lamellar collagen. At the end of prometamorphosis, iridophores are located with melanophores in the separating space between attached basement collagen and derived basement collagen. At TK stage XX (earlier climax), melanophores and iridophores are detected inside the upper extremities of fractures opened in the derived basement collagen. At TK stage XXIV (later climax), both types of larval pigment cells are observed in the inner extremities of breaks derived from the fractures. During climax, these pigment cells occupy the well-formed breaks. At TK stage XXV in young froglet, the pigment cells remain alone in the breaks formed in the derived basement collagen. Briefly, breaks in the basement lamellar collagen are opened by invading cell processes of mesenchymal cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reconstitution of human epidermis in vitro is accompanied by transient activation of basal keratinocyte spreading

Frozen human cadaver skin obtained from the skin bank was thawed and incubated in serum-free medium for 1–2 days, after which the original epidermis could be removed mechanically. Transmission electron microscopic observations showed that the dermal matrix remaining behind contained intact bundles of collagen fibrils but no live cells and that a continuous lamina densa persisted in the basement membrane region. Indirect immunofluorescence analyses demonstrated linear staining of the basement membrane region by antibodies against laminin and type IV collagen and discontinuous staining with antibodies against fibronectin. Scanning electron microscopic observations revealed a normal topographical arrangement of dermal matrix papilla and interspersed crypts on the surface of the matrix. Epidermal cells placed on the dermal matrix attached in 1–2 h and spread by 24 h. After 1 week of culture the epidermis was reconstituted, at which time approximately 30% of the epidermal cells were basal keratinocytes and the remainder were more differentiated keratinocytes. A high degree of differentiation of the reconstituted epidermis was shown by the formation of hemidesmosomes along the basement membrane, the formation of desmosomes characterized by intercellular dense lines, and the presence of a cell layer containing keratohyalin granules. At various times during epidermal reconstitution, cells were harvested and tested in short-term assays for adhesion to fibronectin substrata. During the first several days there was a transient activation of basal keratinocyte spreading analogous to the modulation of keratinocyte spreading that we have observed during epidermal reconstitution in vivo.     

Expression of basement membrane components through morphological changes in the hair growth cycle

The amount and distribution of fibronectin associated with hair follicles was found to vary during the hair growth cycle in the rat. Immunocytochemical staining of follicles in mid-late anagen (the growth stage) revealed the presence of fibronectin in the dermal papilla matrix, in the basement membrane separating this from the epithelial cells of the hair bulb, and in the basement membrane and connective tissue sheath which underly the cells of the outer root sheath. Early in catagen, the transitional stage, staining of the dermal papilla matrix disappeared. Fibronectin persisted in the basement membrane and connective tissue sheath, which undergo corrugation and apparent thickening in catagen. After follicle shortening, the telogen (resting) stage is reached, at which point fibronectin staining was found to be minimal, being restricted to the basement membrane around the secondary germ. The onset of anagen, involving cell division and follicle elongation, was associated with a great increase in the amount of fibronectin in this zone and in and around the dermal papilla. Analysis of entry into anagen by [3H]thymidine incorporation and autoradiography revealed that growth could be detected before the increase in fibronectin expression. However, growing cells, even in a suprabasal position, always had some fibronectin at their surface. Immunoelectron microscopy of early anagen follicles confirmed the light microscopic findings and also showed that fibronectin was present in small vesicles close to the surface of dermal papilla and some epithelial cells. Increased deposition of laminin and type IV collagen in early anagen follicles was also noted, emphasizing the importance of basement membrane components during morphogenetic events in vivo.     

Dermal fibroblasts from Down''s syndrome patients share a cycloheximide-induced deficiency in collagen adhesion responses with normal aging cells

Human skin fibroblasts from three different Down's syndrome patients (trisomy 21) of very different ages have been tested for their adhesion responses on tissue culture substrata coated with type I collagen, fibronectin (FN), and their combination after or during treatment of cells with cycloheximide to evaluate limitations in specific responses. It was shown previously that in vitro-aged papillary and reticular dermal fibroblasts from normal individuals do not generate F-actin stress fibers when pretreated with cycloheximide on collagen substrata but do so on FN substrata, a deficiency linked to limiting amounts/function of collagen-specific receptors in aging cells. In these studies, all three Down's fibroblast populations demonstrated a similar deficiency in stress fiber formation, evaluated by rhodamine-phalloidin staining, upon cycloheximide treatment at all passage levels. They remained competent for stress fiber formation on FN substrata and for reorganization of microtubule and intermediate filament networks on all substrata, demonstrating the specificity for the collagen matrix and for the F-actin cytoskeleton in this deficiency. The cycloheximide-induced deficiency could be readily reversed in all three cell populations by further incubation of cells in drug-free medium and, in some cases, by prior growth of cells in ascorbate-supplemented medium to stimulate collagen and possibly collagen receptor production. However, several pieces of evidence indicate that reduced amounts of FN and collagen synthesized by fibroblasts do not contribute to the cycloheximide-induced deficiency, including the inability to reverse the effect by treatment of cells with TGF beta. Several conclusions are suggested from these studies: (a) Down's dermal fibroblasts become deficient in collagen-specific receptor(s) upon cycloheximide treatment, which leads to altered transmembrane signaling and inability to reorganize F-actin into stress fibers; (b) Down's dermal fibroblasts at all passage levels have matrix adhesive phenotypes similar to those of aging fibroblasts from normal individuals; and (c) these studies provide further support for cells from Down's patients as a genetic model of aging in normal populations.     

Human alveolar macrophage fibronectin: synthesis, secretion, and ultrastructural localization during gelatin-coated latex particle binding

Human pulmonary alveolar macrophages synthesized and secreted several characteristic high molecular weight proteins for at least 7 d in vitro. Immunoprecipitates of medium and cell lysates from metabolically labeled cultures with specific anti-human plasma fibronectin IgG contained one major labeled polypeptide of molecular weight 440,000 (unreduced) or 220,000 (reduced). An identical polypeptide in conditioned medium from radiolabeled macrophages bound specifically to gelatin-Sepharose, demonstrating that alveolar macrophages synthesized and secreted a molecule immunologically and functionally similar to fibronectin. Fibronectin was the major newly synthesized and secreted polypeptide of freshly harvested alveolar macrophages. Pulse-chase experiments revealed that newly synthesized fibronectin was rapidly secreted into medium, approximately 50 percent appearing by 1 h and 80 percent by 8 h. Immunoperoxidase staining using antifibronectin F(ab’)(2)-peroxidase conjugates revealed the majority of immunoreactive fibronectin to be intracellular, localized to endoplasmic reticulum and Golgi apparatus. No extracellular matrix fibronectin was visualized, and cell surface staining was rarely seen, usually appearing only at sites where cells were closely apposed and not at sites of macrophage-substrate attachment. Similar immunostaining of fibroblast cultures revealed cell surface-associated fibrillar fibronectin. Ultrastructural localization of fibronectin during binding and phagocytosis of gelatin-coated and plain latex particles revealed fibronectin only on gelatin-latex beads and at their cell binding sites. Neigher plain latex beads nor their cell membrane binding sites stained for fibronectin. These results demonstrate that fibronectin is a major product of human alveolar macrophages, is rapidly secreted, and is localized at cell membrane binding sites for gelatin-coated particles. In view of the known binding properties of fibronectin, it may serve as an endogenous opsonic factor promoting the binding of staphylococcus, denatured collagen, fibrin, or other macromolecules to macrophages in the lower respiratory tract.     

Culture and characterization of dental follicle cells from rat molars

Summary Because the dental follicle is necessary for the eruption of teeth of limited eruption, it was the objective of this study to determine if the cells of the follicle could be cultured in vitro. To achieve this, dental follicles and associated enamel organs were dissected from the first and second mandibular molars of 6–7-day-old rats (secretory stage of amelogenesis), and then cultured in a medium that promotes fibroblast growth — the predominant cell type of the dental follicle. The cultured cells grew to confluency and were kept through 3 passages before experimentation. The cultured cells were fibroblastic in shape, elongate with processes, and transmission electron microscopy revealed that they contained an abundant rough endoplasmic reticulum, but did not form desmosomes. Immunofluorescent staining for anti-vimentin showed that all the cells stained and electron-microscopic immunogold labeling indicated that the antibody was associated with intermediate filaments. As revealed by SDS-polyacrylamide gel electrophoresis and Western blotting, the cultured cells synthesized and secreted the extracellular matrix molecules fibronectin and procollagens. Subsequent immunofluorescence staining of permeabilized and non-permeabilized cells confirmed the presence of fibronectin and type I collagen both intra- and extracellularly. Thus, based on all the above characteristics, the cultured cells appeared to be fibroblasts derived from the dental follicle, although a few of the fibroblasts may be derived from undifferentiated mesenchymal cells interposed between the alveolar bone and follicle. Experiments now can be conducted to determine how these cultured cells respond directly to growth factors that alter the rates of tooth eruption.     

Immunofluorescent localization of collagen types I,III and IV,fibronectin, laminin,and basement membrane proteoglycan in developing mouse skin

Summary The distribution of various extracellular matrix components was studied in frozen sections of embryonic (14–18 days) and early postnatal (birth and 4 days post parturn) dorsal mouse skin using monospecific antibodies and indirect immunofluorescence. Basement membrane zone components — type IV collagen, laminin and heparan sulphate proteoglycan — were found to be uniformly and unchangingly distributed along the dermal-epidermal junction. In contrast, the distribution of interstitial matrix components — types I and III collagen, and fibronectin — was heterogeneous and varied with the stages of hair development. Collagens became sparse and were eventually completely removed from the prospective dermal papilla and from a one-cell-thick sheath of dermal cells around hair buds. They remained absent from the dermal papilla throughout hair organogenesis. Fibronectin was always present around dermal papilla cells and was particularly abundant along the dermal-epidermal junction of hair rudiments, as well as underneath hair buds. In contrast, in interfollicular skin, collagens accumulated in increasing density, while fibronectin became progressively sparser. It thus appears that interstitial collagens and fibronectin are distributed in a manner which is related to hair morphogenesis. In morphogenetically active regions, collagen density is low, while that of fibronectin is high. Conversely, in histologically stabilized zones, collagen is abundant and fibronectin is sparse. This microheterogeneous distribution of interstitial collagens and of fibronectin might thus constitute part of the morphogenetic message that the dermis is known to transmit to the epidermis during the development of skin and of cutaneous appendages.     

Localization and synthesis of type III collagen and fibronectin in human reparative dentine

Summary The injury of dental pulp tissue, following caries, is accompanied by the deposit of a typical hard scar tissue known as reparative dentine which should be regarded as the mineralization of a new organic matrix. Highly purified antibodies were used in combination with immunoperoxidase or immunogold technique at the ultrastructural level to reveal the distribution and synthesis of types I and III collagen and fibronectin elaborated by typical matrix-forming cells in the new tissue.Specific immunoperoxidase labelling, on demineralized teeth, clearly demonstrated that type I collagen represents the main type of collagen (88%). It is associated with bundles of fine striated fibrils of type III collagen and in close vicinity with fibronectin and constituted, at least, the new organic matrix of reparative dentine.Immunogold staining gave precise localization mainly over Golgi apparatus for the 3 components, thus suggesting that the cells concerned should not be considered as new odontoblasts but rather as pulpal cells in the process of differentiation participating in the formation of new dentine. Moreover, these events are very similar to those observed during wound healing in other tissues.     

Localization and synthesis of type III collagen and fibronectin in human reparative dentine. Immunoperoxidase and immunogold staining

The injury of dental pulp tissue, following caries, is accompanied by the deposit of a typical hard scar tissue known as reparative dentine which should be regarded as the mineralization of a new organic matrix. Highly purified antibodies were used in combination with immunoperoxidase or immunogold technique at the ultrastructural level to reveal the distribution and synthesis of types I and III collagen and fibronectin elaborated by typical matrix-forming cells in the new tissue. Specific immunoperoxidase labelling, on demineralized teeth, clearly demonstrated that type I collagen represents the main type of collagen (88%). It is associated with bundles of fine striated fibrils of type III collagen and in close vicinity with fibronectin and constituted, at least, the new organic matrix of reparative dentine. Immunogold staining gave precise localization mainly over Golgi apparatus for the 3 components, thus suggesting that the cells concerned should not be considered as new odontoblasts but rather as pulpal cells in the process of differentiation participating in the formation of new dentine. Moreover, these events are very similar to those observed during wound healing in other tissues.     

Extracellular matrix components and testicular peritubular cells influence the rate and pattern of Sertoli cell migration in vitro

We report the patterns of migration of Sertoli cells plated on specific substrata, and the influences of testicular peritubular cells on these processes. Data presented indicate that while peritubular cells readily spread when explanted onto Type I collagen, Sertoli cells do not. A delay of 4 to 6 days occurs after Sertoli cells are plated before they begin to migrate randomly to form plaque-like monolayers on Type I collagen. These processes are dependent upon the synthesis and subsequent deposition of laminin and/or Type IV collagen by Sertoli cells, and are independent of fibronectin. A different behavior occurs when reconstituted mixtures of purified Sertoli cells and pertiubular cells are sparsely plated onto Type I collagen. Peritubular cells rapidly spread to form chains of cells between Sertoli cell aggregates. Sertoli cells then migrate on the surfaces of the peritubular cells, culminating in the formation of cable-like structures between aggregates. Evidence is presented that the Sertoli cell migration to form "cables" under these conditions is dependent upon fibronectin synthesized by peritubular cells, and is independent of the presence of laminin or Type IV collagen. We discuss the possible relevance of these data to the role which precursors of peritubular cells may play in determining the behavior of Sertoli cell precursors in vivo during tubulogenesis, or in the remodelling of the seminiferous tubule which occurs during different stages of the cycle of the seminiferous epithelium in spermatogenesis.     

Aging-related changes and topology of adhesion responses sensitive to cycloheximide on collagen substrata by human dermal fibroblasts

Human dermal fibroblasts (both papillary and reticular) were tested during in vivo or in vitro aging for their responses on collagen and/or fibronectin (FN) substrata, as well as on topologically mixed substrata. Cycloheximide treatments were used to evaluate whether receptors to these matrix molecules, mediating F-actin reorganization into stress fibers, are altered during aging processes. Late-passage (but not mid-passage) papillary and reticular cells from both an elderly male and a newborn infant spread effectively on collagen +/- FN but failed to generate stress fibers after lengthy pretreatment of cells with cycloheximide. In contrast, treatment with cycloheximide only when cells were reattaching was not inhibitory. None of the treatments had any effect on stress fiber formation of cells on FN-only substrata, demonstrating that drug sensitivity was specific for collagen responses. The inhibition could be reversed by rinsing cycloheximide out of cultures and could be prevented by prior growth of cells in ascorbate-supplemented medium to stimulate production/maturation of collagen and possibly collagen-specific receptors. Adjacent regions of coverslips were adsorbed with collagen and a proteolytic fragment of plasma FN lacking the collagen-binding domain but retaining other binding domains; cells bridging the interface were of special interest. When fragment F155 containing both the RGDS cell-binding and the heparin II-binding domains was tested in this paradigm, cells generated stress fibers continuous from the collagen-facing side into the F155-facing side of the same cell, consistent with the compatability of both collagen and FN receptors in generating the same stress fiber. However, F110 lacking the heparin II domain was incapable of facilitating stress fiber formation; fibers formed effectively on the collagen side and terminated abruptly at the collagen:F110 interface. These experiments demonstrate stringent regulation of where stress fibers begin, span, and terminate in the cytoplasm by matrix receptors at the cell's undersurface and establish that there are alterations of collagen-specific receptors as a consequence of in vitro aging, but not of in vivo aging, in both papillary and reticular human dermal fibroblasts.     

Fibronectin binding site in type I collagen regulates fibronectin fibril formation

Mov13 fibroblasts, which do not express endogenous alpha 1(I) collagen chains due to a retroviral insertion, were used to study the role of type I collagen in the process of fibronectin fibrillogenesis. While Mov13 cells produced a sparse matrix containing short fibronectin fibrils, transfection with a wild type pro alpha 1(I) collagen gene resulted in the production of an extensive matrix containing fibronectin fibrils of normal length. To study the amino acids involved in the fibronectin-collagen interaction, mutations were introduced into the known fibronectin binding region of the pro alpha 1(I) collagen gene. Substitution of Gln and Ala at positions 774 and 777 of the alpha 1(I) chain for Pro resulted in the formation of short fibronectin fibrils similar to what was observed in untransfected Mov13 cells. Type I collagen carrying these substitutions bound weakly to fibronectin- sepharose and could be eluted off with 1 M urea. The effect of this mutation on fibronectin fibrillogenesis could be rescued by adding either type I collagen or a peptide fragment (CB.7) which contained the wild type fibronectin binding region of the alpha 1(I) chain to the cell culture. These results suggest that fibronectin fibrillogenesis in tissue culture is dependent on type I collagen synthesis, and define an important role for the fibronectin binding site in this process.     

Collagenolytic cleavage products of collagen type I as chemoattractants for human dermal fibroblasts

The chemoattractive properties of collagen in native (triple-helical) and denatured (random coil) conformation were compared in a Boyden chamber type assay to those of collagen fragments derived from cleavage with mammalian or bacterial collagenase using human embryonic dermal fibroblasts as target cells. Chemotaxis to native collagen required low collagen concentrations because fibril formation at high concentrations and at physiological pH and ionic strength prevented chemoattractiveness. Chemotaxis of denatured collagen was comparable to that of native collagen in solution. Cleavage of native collagen with mammalian collagenase increased, digestion with bacterial collagenase abolished its chemotactic activity. It is thought that these data may reflect the in vivo situation during inflammation and wound repair.     

Studies on vascular smooth muscle cells and dermal fibroblasts in collagen matrices. Effects of heparin

The incorporation of such tissue-cultured mesenchymal cells as bovine vascular smooth muscle cells (SMS) and human dermal fibroblasts (DF) in a collagen matrix results in the reorganization and distortion of that matrix. A 2 ml collagen matrix populated by 55 000 bovine SMC and having a surface area of 800 mm2 will be reduced to 226 mm2 by 48 h. Under identical conditions, a lattice populated by 55 000 DF will achieve an area of 78 mm2 at 48 h. DF are thus more efficient at reducing the size of a collagen lattice by the process of lattice contraction. Bovine SMC proliferate in a collagen matrix; human DF do not. DF in a collagen matrix have a more elongate morphology than SMC. Actin cytoplasmic filaments were studied using the specific F-actin staining reagent, Rhodamine-phalloidin. DF in collagen matrix exhibit diffuse cytoplasmic staining while, in monolayer, they display prominent staining stress fibers. SMC in monolayer and in matrices show stained clumps at the periphery of the cell. The addition of 200 U/ml heparin to SMC eliminates those actin aggregates and causes the formation of stress fibers. It also causes stress fibers to form in dermal fibroblasts in a collagen lattice. However, the elongation and spreading--and the formation of stress fibers brought about by heparin--lead to an inhibition of lattice contraction. Heparin effectively inhibits cell-mediated lattice contraction in SMC and DF, and it also causes the formation of cytoplasmic stress fibers.     

Contraction of fibrillar type I collagen by endothelial cells: A study in vitro

The formation of microvascular sprouts during angiogenesis requires that endothelial cells move through an extracellular matrix. Endothelial cells that migrate in vitro generate forces of traction that compress (i.e., contract) and reorganize vicinial extracellular matrix, a process that might be important for angiogenic invasion and morphogenesis in vivo. To study potential relationships between traction and angiogenesis, we have measured the contraction of fibrillar type I collagen gels by endothelial cells in vitro. We found that the capacity of bovine aortic endothelial (BAE) cells to remodel type I collagen was similar to that of human dermal fibroblasts—a cell type that generates high levels of traction. Contraction of collagen by BAE cells was stimulated by fetal bovine serum, human plasma-derived serum, bovine serum albumin, and the angiogenic factors phorbol myristate acetate and basic fibroblast growth factor (bFGF). In contrast, fibronectin and immunoglobulin from bovine serum, several nonserum proteins, and polyvinyl pyrrolidone (a nonproteinaceous substitute for albumin in artificial plasma) were not stimulatory. Contraction of collagen by BAE cells was diminished by an inhibitor of metalloproteinases (1, 10-phenanthroline) at concentrations that were not obviously cytotoxic. Zymography of proteins secreted by BAE cells that had contracted collagen gels revealed matrix metalloproteinase 2. Subconfluent BAE cells that were migratory and proliferating were more effective contractors of collagen than were quiescent, confluent cells of the same strain. Moreover, bovine capillary endothelial cells contracted collagen gels to a greater degree than was seen with BAE cells. Collectively, our observations indicate that traction-driven reorganization of fibrillar type I collagen by endothelial cells is sensitive to different mediators, some of which, e.g., bFGF, are known regulators of angiogenesis in vivo. © 1996 Wiley-Liss, Inc.     

Dermal tracts in frog skin: fibronectin pathways for cell migration

The dermis of the frog skin (Rana esculenta) displayed a remarkable organization of vertical and horizontal tracts. Vertical thick tracts connected the dermal Stratum spongiosum with the subcutaneous tissue. Horizontal thin tracts were found alongside and contiguous to them. The thick tracts were sheathed by collagen fibrils of the Stratum compactum which were vertically oriented (i.e. parallel to the axes of the tracts) according to the horizontal and orthogonal arrangement of the collagen bundles of the Stratum compactum. The thin tracts devoid of collagenous sheath were formed by clear spaces between superimposed collagen bundles of the dermal Stratum compactum. On vertical sections, the thick tracts were seen to contain fibronectin (FN), detected by indirect immunoperoxidase. Continuous vertical FN lines were centred in these tracts. On horizontal sections, a clear zone around these FN-centred lines was also sheathed by FN. The thick tracts contained flattened pigmentary cells and fibroblasts; these cells were FN-outlined. The thin tracts contained patches of FN and FN-outlined fibroblasts. In culture, in vertical thick tracts, both pigmentary cells and fibroblasts disappeared when antiserum to FN was added to the culture medium. This suggested that thick tracts were pathways allowing pigmentary cells to move upward or downward between their usual upper dermal and lower subcutaneous localizations. Fewer fibroblasts were found in the thin tracts in the presence of antiserum to FN.     

Distribution of extracellular matrix components in the developing ruminant corpus luteum: a wound repair hypothesis for luteinization.

The aim of this study was to investigate corpus luteum development by visualization of extracellular matrix proteins in the tissue at sequential stages of the luteal phase. Corpora lutea were collected from oestrus-synchronized sheep and from bovine material from an abattoir. The distributions of collagen types I and IV, fibronectin and von Willebrand factor were determined using immunohistology and semi-quantitative image analysis. During the post-ovulatory period, a fibronectin- and von Willebrand factor-rich matrix occurred centrally, adjacent to the inner parenchymal surface, whereas during early luteal development a clear border of fibronectin separated the inner parenchyma from the lumen. The inner parenchyma had abundant fibronectin initially, but the amount decreased as the rate of organ growth decreased. Over the same period, the amount of collagen type I first increased and then decreased. Collagen type I and fibronectin were less abundant in other regions of the parenchyma, and the general pattern was of slightly increasing amounts of collagen type I and decreasing amounts of fibronectin as luteal development proceeded. In contrast to earlier studies, only a small percentage of large luteal cells was found to have an associated layer of collagen type IV (presumed basal lamina). It is concluded that luteal growth and maturation require organized sequences of tissue remodelling. The central meshwork of fibronectin and von Willebrand factor and sequential deposition of collagen type I and fibronectin are strongly reminiscent of events in granulation tissue. This indicates that luteinization may be best understood as a wound repair-like process that succeeds the inflammation-like events of ovulation.     

Ultrastructural and immunocytochemical detection of keratins and extracellular matrix proteins in lizard skin cultured in vitro

The present study shows the localization of epidermal and dermal proteins produced in lizard skin cultivated in vitro. Cells from the skin have been cultured for up to one month to detect the expression of keratins, actin, vimentin and extracellular matrix proteins (fibronectin, chondroitin sulphate proteoglycan, elastin and collagen I). Keratinocytes and dermal cells weakly immunoreact for Pan-Cytokeratin but not with the K17-antibody at the beginning of the cell culture when numerous keratin bundles are present in keratinocyte cytoplasm. The dense keratin network disappears after 7-12 days in culture, and K17 becomes detectable in both keratinocytes and mesenchymal cells isolated from the dermis. While most epidermal cells are lost after 2 weeks of in vitro cultivation dermal cells proliferate and form a pellicle of variable thickness made of 3-8 cell layers. The fibroblasts of this dermal equivalent produces an extracellular matrix containing chondroitin sulphate proteoglycan, collagen I, elastic fibers and fibronectin, explaining the attachment of the pellicle to the substratum. The study indicates that after improving keratinocyte survival a skin equivalent for lizard epidermis would be feasible as a useful tool to analyze the influence of the dermis on the process of epidermal differentiation and the control of the shedding cycle in squamates.