Determination of epidermal G2-chalone in epidermal-type tissues

By means of monospecific immune serum, using the indirect method by Coons, the epidermal G2-chalone was revealed in the corneal epithelium, in the transitory epithelium of the urinary bladder, renal pelvis, as well as in stromal epithelial cells of the cortical substance and in thymic bodies, the facts that suggest epithelial nature of these tissues. In tracheal epithelium the method mentioned failed to reveal G2-chalone. Analysing localization of the epidermal G2-chalone in various tissues of the epidermal origin, it has been stated that in the non-cornified multistratified flat epithelium it is present in cellular cytoplasm of all layers, while in the cornified epithelium - it is predominantly detected in basal and scupular cells. A suggestion is made that distribution of the intratissue epidermal G2-chalone depends on the process of cornification. A possibility to use G2-chalone as a marker for tissues of the epidermal type is discussed.     

Inhibition by epidermal extracts of the 12-O-tetradecanoylphorbol-13-acetate induced peak of ornithine decarboxylase activity in the mouse epidermis

The time course of induction of epidermal ornithine decarboxylase (E.C. 4.1.117) (ODC) activity following a single topical application of 17 nmoles of 12-O-tetradecanoylphorbol-13-acetate (TPA) on hairless mouse skin was established. Prior intraperitoneal (i.p.) administration of a crude epidermal extract prepared from hairless mouse epidermis led to a time-dependent, 50% inhibition of the peak level of TAP-induced ODC activity. Maximum inhibition was observed when the extract was injected 1.5 h before TPA treatment. The crude epidermal extract did not affect ODC activity in vitro. Following the administration of epidermal extracts, the inhibition of the TPA-induced ODC-response correlated positively with the presence of epidermal G2-chalone activity (determined by a stathmokinetic method) whereas myocardial, skeletal muscle, or heat-inactivated epidermal extracts with no epidermal G2-chalone activity, had no effect on TPA-induced ODC activity. These results indicate a possible relationship between ODC-activity and the control of mitotic rate by G2-chalone.     

Changes in the level of epidermal G2-chalone and mitotic activity in the rat vaginal epithelium]

The content of tissue-specific inhibitor of mitosis in epidermal epithelium (G2-chalone) was estimated by a single radial immunodiffusion test in the rat vagina during various stages of the estrous cycle. The level of chalone was found to correlate with the mitotic index (MI) of vaginal epithelium. The lowest level of G2-chalone is detected in proestrus and the highest one in estrus. The level of G2-chalone in vaginal epithelium was shown to be significantly decreased in aging rats (14--16 month-old) with regular cycles as compared to that in young normal cycle rats (3--4 month-old). The single injection of estradiol benzoate (1 microgram/100 g) into ovariectomized rats led to an increase in the MI following 18 hours. The increased MI is preceeded by a substantial drop of the G2-chalone level 12 hours after estrogen injection.     

Immunomorphologic analysis of G2-chalone localization in epidermal-type tissues

Localization of the epidermal G2-chalone in tissues has been established by means of indirect method of Coons using a monospecific immune serum. It has been found in dermal epithelia of the back, external ear, tongue, esophagus, forestomach, vagina, hairy follicles, but it has not been found in the sebaceous glands and derma. These findings are fully in agreement with the results obtained by the method of double diffusion after Ouchterlony. Tissue specificity of G2-chalone is proved by the fact that at places where epithelia differing histogenetically join with each other, it is found only in the epithelia of the epidermal type. Within the epithelial layer G2-chalone is mainly localized in the spinous and partly in the basal cells. Possible mechanisms on regulation of the mitotic activity are discussed in connection with the data obtained.     

Cell cycle specificity and reversibility of the inhibitory effect of epidermal G1-chalone on DNA synthesis in partially synchronized RTE-2 keratinocytes in vitro

The specific action of a pig skin fraction enriched in epidermal G1-chalone, a tissue-specific inhibitor of epidermal DNA synthesis, was investigated by means of flow cytofluorometry. The results indicate that G1-chalone inhibits progression of partially synchronized rat tongue epithelial cells (line RTE-2) through the cell cycle at a point 2 h prior to the beginning of the S-phase. Approximately 8 h after chalone addition, the cells can overcome the inhibition and begin to enter the S-phase. The duration of this delay is concentration-independent, but the fraction of cells affected is proportional to the chalone concentration. The progression of cells which already have entered S-phase is not affected. In contrast to the G1-chalone preparation, aphidicolin, a potent inhibitor of DNA polymerase alpha, clearly shows S-phase-specific inhibition. These results indicate that the epidermal G1-chalone inhibits epidermal cell proliferation in a fully reversible manner by a highly specific effect on cell cycle traverse.     

Purification and characterization of epidermal G2- and G1-chalones]

Highly purified epidermal G1- and G2-chalones from rat skin inhibit the entering of epidermocytes to S and M phases of cell cycle respectively. Their biological activity is characterized by tissue-specificity and not by species-specificity. Both of them are tissue-specific glycoproteins as for their antigenic properties. Molecular weight of G1-chlone is 21 000, G2-chalone--34 000, isoelectric point (pH) 5.55 and 5.85 respectively. G2-chalone is the fastest as compared to G1-chalone in 5% acrylamide gel electrophoresis, pH 8.3. When injected in rabbits, G2-chalone produced monospecific antibodies which have no cross-reactivity with G1-chalone. The amino acid composition of both chalones and immunofluorescent localization of G2-chalone in epidermal tisues are given.     

A system for the study of epidermal G1-chalone in cell culture. The rat tongue epithelial cell line RTE2

A pig-skin preparation enriched in epidermal G1-chalone when administered to cells of the rat tongue epithelial line RTE2 at concentrations of 3-300 micrograms/ml (dry mass) caused a 60% reduction in cell number. Three other cell lines showed essentially no growth inhibition during chalone treatment. The kinetics of chalone inhibition were similar to those observed in mouse epidermis in vivo. Five hours after the addition of chalone preparation in fresh medium a decrease in the rate of DNA synthesis was observed. Maximum inhibition at 12 h was followed by a subsequent increase in DNA synthesis, reaching control values again after 30 h. The inhibitory effect was dose-dependent up to 3 micrograms/ml. At higher concentrations the degree of inhibition remained constant at about 50% of the control up to 300 micrograms/ml. Removal of added chalone by changing the medium at the time of maximum inhibition gave rise to a complete recovery within 9 h. These results indicate a cell-line specific, non-toxic and reversible inhibitory effect of the chalone preparation which resembles that observed in the living animal. The RTE2 cell line may thus be considered to provide a highly sensitive experimental system suitable for more detailed studies on the mechanism of action of epidermal G1-chalone.     

Effect of rat liver chalones on liver cell proliferation at different times after partial hepatectomy]

The action of rat's liver ethanol extract (72--81 per cent saturation) on cell proliferation of this organ at various periods after a partial hepatectomy has been studied. The most sensitive periods of the action of G1- and G2-chalone were, resp., the time of cell transformation, and the middle of the premitotic period of cell cycle. The action of G2-chalone used is organ-specific, since the drug decreased the mitotic activity of both hepatocytes and stromal cells. At the same time, the proliferation of ear, tongue and small bowel epithelial cells remained unchanged.     

Expression of the HB9 homeobox gene concomitant with proliferation accompanying epidermal stratification during development of chick embryonic tarsometatarsal skin

A homeobox gene, HB9, has been isolated from the tarsometatarsal skin of 13-day-old chick embryos using a degenerate RT-PCR-based screening method. In situ hybridization analysis revealed that, during development of chick embryonic skin, the HB9 gene was expressed in epidermal basal cells of the placodes, but not in those of interplacodes, and in the dermal cells under the placodes at 9 days before addition of an intermediate layer by proliferation of the basal cells in the placodes. With the onset of epidermal stratification, the direction of the basal cell mitosis changed, with the axis becoming vertical to the epidermal surface. Placodes and interplacodes form outer and inner scales, respectively, after they have elongated distally (Tanaka S, Kato Y (1983b) J Exp Zool 225: 271–283). During scale ridge elongation at 12–15 days, HB9 was strongly expressed in the epidermis of the outer scale face, where the cell proliferation is more active than in the epidermis of the inner scale face; hence, stratification of the outer scale face is more prominent than that of the inner scale face. After 16 days, when mitotic activity in the epidermal basal cells decreases and the thickness of the epidermis is maintained at a constant level, the HB9 expression decreases with the onset of epidermal keratinization. These results suggest that HB9 may be involved in the proliferation of the epidermal basal cells that accompanies epidermal stratification.     

Changes in Soybean Agglutinin (SBA) and Peanut Agglutinin (PNA) Binding Pattern in the Epidermis of the Developing Chick Embryo

Lectin binding pattern in the developing chick embryonic epidermis was studied using peroxidase labeling method. The epidermis of the 13-day-old embryo is in an undifferentiated state. Little binding of soybean agglutinin (SBA), specific for N-acetyl-D-galactosamine, and peanut agglutinin (PNA), specific for β-D-galactose, was seen in such epidermal cells. As the epidermis developed toward keratinization, the cell membrane of the differentiating flattened cells was positively stained with SBA and PNA. The positive staining was also seen in the supranuclear region of the cells located between the flattened cells and the basal cells. The basal cells remained unstained in all the stages of development. Similar staining pattern with SBA and PNA was seen in the cultured skin explants during the epidermal differentiation in vitro. These observations show that the SBA- and PNA-reactive glycoconjugates accumulate during the epidermal cell differentiation, suggesting their important roles in the maintenance of the ordered structure of the epidermis.     

Basal Keratinocytes Contribute to All Strata of the Adult Zebrafish Epidermis

The epidermis of terrestrial vertebrates is a stratified epithelium and forms an essential protective barrier. It is continually renewed, with dead corneocytes shed from the surface and replaced from a basal keratinocyte stem cell population. Whilst mouse is the prime model system used for epidermal studies, there is increasing employment of the zebrafish to analyse epidermis development and homeostasis, however the architecture and ontogeny of the epidermis in this system are incompletely described. In particular, it is unclear if adult zebrafish epidermis is derived entirely from the basal epidermal stem cell layer, as in the mouse, or if the most superficial keratinocyte layer is a remnant of the embryonic periderm. Furthermore, a relative paucity of cellular markers and genetic reagents to label and manipulate the basal epidermal stem cell compartment has hampered research. Here we show that the type I keratin, krtt1c19e, is a suitable marker of the basal epidermal layer and identify a krtt1c19e promoter fragment able to drive strong and specific expression in this cell type. Use of this promoter to express an inducible Cre recombinase allowed permanent labelling of basal cells during embryogenesis, and demonstrated that these cells do indeed generate keratinocytes of all strata in the adult epidermis. Further deployment of the Cre-Lox system highlighted the transient nature of the embryonic periderm. We thus show that the epidermis of adult zebrafish, as in the mouse, derives from basal stem cells, further expanding the similarities of epidermal ontogeny across vertebrates. Future use of this promoter will assist genetic analysis of basal keratinocyte biology in zebrafish.     

Cell cycle specificity and reversibility of the inhibitory effect of epidermal G1-chalone on DNA synthesis in partially synchronized RTE-2 keratinocytes in vitro

The specific action of a pig skin fraction enriched in epidermal G₁-chalone, a tissuespecific inhibitor of epidermal DNA synthesis, was investigated by means of flow cytofluorometry. The results indicate that G₁-chalone inhibits progression of partially synchronized rat tongue epithelial cells (line RTE-2) through the cell cycle at a point 2 h prior to the beginning of the S-phase. Approximately 8 h after chalone addition, the cells can overcome the inhibition and begin to enter the S-phase. The duration of this delay is concentrationindependent, but the fraction of cells affected is proportional to the chalone concentration. The progression of cells which already have entered S-phase is not affected. In contrast to the G₁-chalone preparation, aphidicolin, a potent inhibitor of DNA polymerase α, clearly shows S-phase-specific inhibition. These results indicate that the epidermal G₁-chalone inhibits epidermal cell proliferation in a fully reversible manner by a highly specific effect on cell cycle traverse.     

Body-specific proliferation of adult precursor cells in Xenopus larval epidermis

Cell proliferation was examined in the back and tail epidermis of larval Xenopus laevis using bromodeoxyuridine (BrdU). The BrdU labeling index of the back epidermis increased temporally at stage 59, followed by a rapid decrease to the same level as at stage 51. The temporal increase in cell proliferation of the back epidermis produced a new epidermal layer composed of basal cells. In vitro analysis showed that tri-iodothyronine (T₃) promotes cell proliferation of basal cells but suppresses that of skein cells. Immunohistochemical studies showed that the newly formed basal cell layer functions as adult precursor cells which produce the adult epidermal cells. In contrast to the back epidermis, the labeling index of the tail epidermis decreased from stage 57. However, when the tail skin was transplanted to the back area, cell proliferation in the tail epidermis increased to the same level as that of the normal back epidermis. Cell proliferation of the back epidermis was not suppressed by transplanting the skin to the tail area. These results suggest that some promoting factors are produced in the body region and regulate the number of adult precursor cells, which determine the developmental fate of the larval skin.     

Autolysis and heterolysis of the epidermal cells in anuran tadpole tail regression

Autolysis and heterolysis of the degenerating epidermis of the tail fin of Rana japonica tadpoles during spontaneous metamorphosis were observed by transmission and scanning electron microscopy. In the early climactic stages of metamorphosis (st. 19–20), the outermost epidermal cells developed vacuoles that were acid phosphatase positive and showed apparent breakdown of the cell membrane. The cells shrunk, perhaps due to the rupture of the cell membrane, and sloughed off without typical cornification. As tail resorption proceeded, autolysis of the epidermal cells spread towards the inner layers, in which some epidermal cells lost desmosomal junctions. They also displayed atrophic figures with condensed cytoplasm, breakdown of the cell membrane, and pycnotic nuclei. Lymphocytes, neutrophils and macrophages were already present in the basal layers of the premetamorphic epidermis (st. 10). Based on ultrastructural observation, blood cells could be distinguished from autolysing epidermal cells. Only a few blood cells were found in the early climactic stages of metamorphosis (st. 19–20), but the number of the blood cells, especially macrophages, greatly increased during the final stages of metamorphosis (st. 23–24). During the final stages, many macrophages were observed to phagocytose the autolysing epidermal cells by projecting slender pseudopodia into the inner epidermis. Macrophages also were observed to pass through the degraded basal lamella. These results suggest that not only autophagy but also heterophagy of the epidermal cells by the macrophages is a major process in the regression of the tail fin epidermis.     

The ACR4 receptor-like kinase is required for surface formation of epidermis-related tissues in Arabidopsis thaliana

In higher plants, an outer layer of meristematic cells, the protoderm, forms early in embryogenesis and this layer gives rise to the epidermis in differentiating tissues. We proposed previously that an Arabidopsis thaliana homolog of crinkly4 (ACR4), a gene for a receptor-like protein kinase, would be involved in differentiation and/or maintenance of epidermis-related tissues. In the present study, we isolated loss-of-function acr4 mutants by a reverse genetic approach. Our extensive analyses using the transmission electron microscopy and the toluidine blue test -- a method that has recently been developed for the rapid visualization of defects in the leaf cuticle -- showed that the acr4 mutations significantly affected the differentiation of leaf epidermal cells, suggesting similar roles for ACR4 and CR4 in the differentiation of leaf epidermis. Our acr4 mutants also had various abnormalities related to epidermal differentiation, which included disorganized cell layers in the integument and endothelium of ovules. In addition, the green fluorescent protein fused to ACR4 was localized preferentially on the lateral and basal plasma membranes in the epidermis of the leaf primordia, suggesting a role for ACR4 in epidermal differentiation at cell surfaces that make contact with adjacent cells. Furthermore, the loss-of-function mutations in the ACR4 and ABNORMAL LEAF SHAPE1 (ALE1) genes, which encode a putative subtilisin-like serine protease, synergistically affected the function of the epidermis such that most leaves fused. Thus, ACR4 seems to play an essential role in the differentiation of proper epidermal cells in both vegetative and reproductive tissues.     

Dolichos biflorus agglutinin (DBA) reveals a similar basal cell differentiation in normal and psoriatic epidermis

Binding of N-acetyl galactosamine (GalNAc)-specific Dolichos biflorus agglutinin (DBA) conjugates to frozen sections of normal epidermis and of psoriatic uninvolved and lesional skin was studied in fluorescence microscopy. The DBA conjugates bound only to single basal cell layer in normal and uninvolved psoriatic epidermis from patients with different blood group status. In the lesional area of psoriatic skin a similar reaction with a single basal cell layer was revealed. Other lectin-conjugates applied, presenting also GalNAc specificity, reacted with most cell layers of normal and both uninvolved and lesional psoriatic epidermis and gave an attenuated reaction with the middle epidermal layers. The results show that the basal cell characteristics are confined only to the cells along the basal membrane also in psoriatic epidermis, although cells in three lowest layers may be able to proliferate.     

The fine structure of epidermal papillae of Travisia forbesii (Annelida)

The structure of the epidermis of Travisia forbesii was described using light and electron microscopy. The epidermis is a highly modified variant of the normal one-layer polychaete epithelium. It consists of basal epidermal cells and an external layer of closely sited papillae consisting of glandular and supportive epidermal cells, and extensive electron-transparent intercellular spaces. The papillae are embedded in the thick cuticle. Each papilla has a peduncle, which is formed by one cell that penetrates the inner cuticle layer to the basal epidermal cells. A fold of basement membrane forms the core of the peduncle and ends in the base of a papilla. All epidermal cells are connected to each other with apical cell junctions and to the basement membrane with hemidesmosomes, so the epithelium is continuous and uninterrupted. The epidermis has an intra-epidermal neuron plexus. The structure of the papillae is compared with papillae and tubercles of other polychaetes, and the possible functional significance and phylogenetic implications of these structures are discussed.     

Dolichos biflorus agglutinin (DBA) reveals a similar basal cell differentiation in normal and psoriatic epidermis

Summary Binding of N-acetyl galactosamine (GalNAc)-specific Dolichos biflorus agglutinin (DBA) conjugates to frozen sections of normal epidermis and of psoriatic uninvolved and lesional skin was studied in fluorescence microscopy. The DBA conjugates bound only to single basal cell layer in normal and uninvolved psoriatic epidermis from patients with different blood group status. In the lesional area of psoriatic skin a similar reaction with a single basal cell layer was revealed. Other lectin-conjugates applied, presenting also GalNAc specificity, reacted with most cell layers of normal and both uninvolved and lesional psoriatic epidermis and gave an attenuated reaction with the middle epidermal layers. The results show that the basal cell characteristics are confined only to the cells along the basal membrane also in psoriatic epidermis, although cells in three lowest layers may be able to proliferate.     

Expression of the helix-loop-helix protein ID1 in keratinocytes is upregulated by loss of cell-matrix contact

To analyze the inhibitor of DNA-binding type 1 (ID1) in the human epidermis and in cultured keratinocytes we generated and characterized ID1-specific monoclonal antibodies. Immunohistological studies on human skin biopsies revealed that ID1 is not detectable in normal human epidermis but in lesional epidermis of bullous pemphigoid. In the latter case we found ID1 in the cytoplasm of basal and proximal suprabasal keratinocytes. Cultured normal human epidermal keratinocytes displayed ID1 in the cytoplasm; upon differentiation into a multilayered keratinocyte sheet, ID1 was no longer detectable. It was reexpressed after dispase-mediated detachment of the keratinocyte cultures from the growth substratum. In this case ID1 was localized to the cytoplasm and the nucleus. Our data indicate that after epidermal injury-in our case loss of cell-matrix contact-ID1 is upregulated in affected keratinocytes. In view of the ID1 function in other cell types, we speculate that ID1 facilitates the transition from the resting to the migrating and proliferating keratinocyte required for efficient repair of epidermal lesions by reepithelialization. Taken together we suggest that ID1 is an important player in epidermal (patho-)physiology.     

Differential expression of CD44s and CD4v10 proteins and syndecan in normal and irradiated mouse epidermis

 The role of the CD44s adhesion molecule, its epithelial isoforms and its relationship to epidermal proteoglycans such as syndecan was studied in normal and irradiated mouse skin. In normal mouse skin, only 10% of basal cells are strongly CD44s-immunopositive, with a cytoplasmic expression pattern. Double-label experiments with the basal cell marker keratin 14 confirmed the epithelial nature of the strongly CD44s-positive cell type in the basal layer. Some spinous keratinocytes and the majority of the remaining basal cells exhibited a weak membranous staining pattern. In contrast, the epithelial isoform, CD44v10, was strongly present in all basal and suprabasal epithelial cells of the epidermis, with a membranous staining pattern. Syndecan was found in the granular layer of the normal epidermis only. After 1 week of daily irradiation, the entire basal cell layer of the epidermis expressed CD44s in the membrane, but with a varying degree of staining intensity. This reactivity spread to the upper spinous layer after 3 weeks of treatment. In hyperproliferative epidermis, there was no difference in the staining patterns between CD44s and CD44v10. The expression of syndecan switched from the granular layer to the basal and lower spinous layers after 2 weeks of daily irradiation. Immunoreactivity for syndecan was also strongly enhanced in the dermis of irradiated samples. The results suggest an important role for syndecan and CD44 in proliferative processes during radiation-induced accelerated repopulation. Accepted: 30 September 1996