Cytoarchitectonics and intercellular relations during posttraumatic regeneration of the epidermis

Dynamics of changes of intercellular contacts in the mouse spine epidermis have been studied in 1, 3, 5, 7, 10 days after its traumatic lesion performed up to the upper level of the papillary layer of the derm. In one day a complete desintegration of basal keratinocytes with some signs of reactive changes takes place. A partial desintegration is noted in the exfoliated spinous layer, which participates in the crust formation, as well as in formation of cells in marginal zones of the defect. When there is an intercellular edema, desmosomes manifest themselves as the most highly-adhesive junctions. On the 1st-7th day melanocytes loose their contacts with keratinocytes, but do not display any reactive changes. On the 7th day hyperplasia of the epithelial layer is noted with an increased number of apigmented granular dendrocytes that participate in fagocytosis. The intercellular contacts are reconstructed, however, essential intercellular spaces remain. By the 10th day the contacting surfaces of the cells are completely formed, possessing all specific for epidermis specialized junctions. Columnar organization of the layer is formed.     

The assessment of post mortem structural changes in the human epidermis

The structure of epidermis and appearance of keratinocytes is described in intact skin specimens from human corpses stored after death under refrigeration. Two groups of alterations can be identified depending on the epidermal layer. In the spinous layer, the cells are characterized by crescent-shaped nuclei surrounded by a hollow area. The number of such cells increases significantly each day during the first 8 days post mortem (dpm), and their frequencies follow respective regression equations, so as to enable the post mortem time estimation with one day accuracy. In the basal layer, distorted, balloon-shaped cells with pycnotic nuclei appear, which with the lapse of time are forming groups, and eventually the epidermis in those places separates from the dermis. The presence of both described changes seems to indicate whether the skin sample was obtained from the living organism or after the death.     

Cicatrization of the skin of the 7-day-old chick embryo cultured in vitro

A morphological study of in vitro wound healing has been performed by light, transmission and scanning electron microscopy in dorsal thoraco-lumbar skin of 7-day chick embryos. A circular wound, 750 microns in diameter, was punched out of dorsal skin, removing epidermis and the underlying dense dermis. Wound closure was completed within 96 to 120 hours. Feather bud development was not observed at the wound site. The epidermis began to migrate some 24 h after the wounding; the migration of peridermal cells preceded that of basal epidermal cells by some 12 hours. Mechanisms of the epidermal migration were similar to those observed in situ during wound healing of the integument in 5-day chick embryos (THEVENET, 1981), Superficial epithelization of bare dermis occurred as soon as 12 h after the injury. Cytoplasm of dermal cells exhibited many microtubules and a dilated rough endoplasmic reticulum. During the first 48 h, the epidermal cells established direct contacts and zones of close parallel apposition with epithelized dermal cell processes. The basement membrane lamina densa was maintained at the edges of the wound without retraction or ruffling. It was reconstituted concomitantly with the epidermal migration within 72 h. Cytoplasm of migratory epidermal and epithelized dermal cells exhibited many cytoskeleton structures.     

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     

Fluorochrome-coupled lectins reveal distinct cellular domains in human epidermis

The distribution of saccharide moieties in human interfollicular epidermis was studied with fluorochrome-coupled lectins. In frozen sections Concanavalin A (Con A), Lens culinaris agglutinin (LCA), Ricinus communis agglutinin I (RCAI), and wheat germ agglutinin (WGA) stained intensively both dermis and viable epidermal cell layers, whereas peanut agglutinin (PNA) bound only to living epidermal cell layers. Ulex europaeus agglutinin I (UEAI) bound to dermal endothelial cells and upper cell layers of the epidermis but left the basal cell layer unstained. Dolichos biflorus agglutinin (DBA) bound only to basal epidermal cells, whereas both soybean agglutinin (SBA) and Helix pomatia agglutinin (HPA) showed strong binding to the spinous and granular cell layers. On routinely processed paraffin sections, a distinctly different staining pattern was seen with many lectins, and to reveal the binding of some lectins a pretreatment with protease was required. All keratin-positive cells in human epidermal cell suspensions, obtained with the suction blister method, bound PNA, whereas only a fraction of the keratinocytes bound either DBA or UEAI. Such a difference in lectin binding pattern was also seen in epidermal cell cultures both immediately after attachment and in organized cell colonies. This suggests that in addition to basal cells, more differentiated epidermal cells from the spinous cell layer are also able to adhere and spread in culture conditions. Gel electrophoretic analysis of the lectin-binding glycoproteins in detergent extracts of metabolically labeled primary keratinocyte cultures revealed that the lectins recognized both distinct and shared glycoproteins. A much different lectin binding pattern was seen in embryonic human skin: fetal epidermis did not show any binding of DBA, whereas UEAI showed diffuse binding to all cell layers but gave a bright staining of dermal endothelial cells. This was in contrast to staining results obtained with a monoclonal cytokeratin antibody, which showed the presence of a distinct basal cell layer in fetal epidermis also. The results indicate that expression of saccharide moieties in human epidermal keratinocytes is related to the stage of cellular differentiation, different cell layers expressing different terminal saccharide moieties. The results also suggest that the emergence of a mature cell surface glycoconjugate pattern in human epidermis is preceded by the acquisition of cell layer-specific, differential keratin expression.     

Keratinization in the epidermis of amphibians and the lungfish: comparison with amniote keratinization

Keratinization in the epidermis of amphibians and the lungfish has been studied by electron microscopy, autoradiography and immunocytochemistry to determine whether histidine-rich proteins, filaggrin and loricrin are present. In the lungfish and amphibian tadpoles, anti-keratin antibodies (AE1 and AE3) stain the whole epidermis but not the AE2 antibody, a marker for keratinization. In adult epidermis, the AE2 antibody mainly stains keratinized layers, AE1 mainly stained basal cells, less suprabasal cells and no pre-keratinized and keratinized layers, and AE3 stains all epidermal layers. This staining pattern resembles that of amniote epidermis. Little tritiated histidine is taken up in toad epidermis at 4-6 h post-injection but 24 h after injection the radioactivity is most concentrated in the replacement layer beneath the corneus. This indicates that protein synthesis takes place in the epidermis but, due to the metabolic conversion that takes place in 24 h, it is unlikely that histidine-rich proteins are formed. Neither filaggrin-like nor loricrine-like immunoreactivities are present in amphibian and lungfish epidermis. This indicates absence of histidine-rich matrix proteins and corneous cell envelope proteins and only mucus is present among keratin filaments. Filaggrine-like and loricrin-like proteins are characteristic of amniotes epidermis and might have originated in basic amniotes (cotylosaurs).     

Immunomorphological analysis of G2-chalone localization during the process of rat epidermis histogenesis

The appearance of G2-chalone in the cytoplasm of the intermediate cell layer and partly in the periderm of 17-day-old rat embryo epidermis has been demonstrated by the indirect method of Coons using a monospecific antiserum. G2-chalone was absent from the basal cell layer of 17--21-day-old embryos and of the newborn rats. It was found in all the epidermal layers in 2--5-day-old postnatal rats, while in 6--9-day-old animals it was primarily detected in the cytoplasm of spinous and basal cells. Thus the localization of epidermal G2-chalone typical for defined tissue becomes stabilized at the end of epidermis histogenesis.     

A preformed basal lamina alters the metabolism and distribution of hyaluronan in epidermal keratinocyte "organotypic" cultures grown on collagen matrices

A rat epidermal keratinocyte (REK) line which exhibits histodifferentiation nearly identical to the native epidermis when cultured at an air-liquid interface was used to study the metabolism of hyaluronan, the major intercellular macromolecule present in basal and spinous cell layers. Two different support matrices were used: reconstituted collagen fibrils with and without a covering basal lamina previously deposited by canine kidney cells. REKs formed a stratified squamous, keratinized epithelium on both support matrices. Hyaluronan and its receptor, CD44, colocalized in the basal and spinous layers similar to their distribution in the native epidermis. Most (approximately 75%) of the hyaluronan was retained in the epithelium when a basal lamina was present while most (approximately 80%) diffused out of the epithelium in its absence. While REKs on the two matrices synthesized hyaluronan at essentially the same rate, catabolism of this macromolecule was much higher in the epithelium on the basal lamina (half-life approximately 1 day, similar to its half-life in native human epidermis). The formation of a true epidermal compartment in culture bounded by the cornified layer on the surface and the basal lamina subjacent to the basal cells provides a good model within which to study epidermal metabolism.     

Keratin Polypeptide Analysis in Fetal and in Terminally Differentiating Newborn Mouse Epidermis

The keratin polypeptide pattern of neonatal mouse epidermis consists of eight individual polypeptides having molecular weights of between 46,000 and 67,000. Unlike the keratin patterns in adult mouse epidermis, this pattern is not subject to body site-specific alterations regarding the specific content of distinct polypeptides or the absolute number of keratin constituents.
At day 16 of fetal development the neonatal keratin pattern is only partially expressed, it being fully completed just prior to birth at day 19 of gestation. A comparative analysis of the sequential changes in epidermal morphology and keratin pattern during the last third of embryonic development confirms the view that, independent of the species, keratin polypeptides below 60,000 mol. wt. are generated by basal cells, whereas the biosynthesis of high molecular weight keratin members take place in the suprabasal cell compartments of keratinizing epithelia. The site of origin of five polypeptides (60,000, 58,000, 52,000, 49,000, 46,000) could therefore be attributed to the basal cell layer, the remaining three polypeptides (67,000, 64,000, 62,000) being synthesized in the outer metabolically active epidermal layers. Similar conclusions could be drawn after subfractionation of neonatal epidermis into living (basal, spinous, and granular) and dead cell layers (stratum corneum), and investigation of the corresponding keratin patterns.
During their progression through the epidermis, two proteins (60,000, 58,000) undergo a hitherto undescribed type of posttranslational modification characterized by a slight increase in size and a change in electrical charge. The mechanism underlying this modification is unknown and it is unclear whether the modification if functional or trivial. The largest keratin polypeptide (67,000) of the protein family - probably a product of spinous cells - disappears from the cornified layer without any evidence that it serves as a precursor for smaller keratin subunits.     

Conservation of somatic tissue derived from collared peccaries (<Emphasis Type="Italic">Pecari tajacu</Emphasis> Linnaeus, 1758) using direct or solid-surface vitrification techniques

Cryopreservation of somatic tissue can be applied in biodiversity conservation, especially for wild species as collared peccary. We aimed to evaluate the effect of vitrification techniques of ear tissue of collared peccary [direct vitrification in cryovials (DVC) or solid-surface vitrification (SSV)] on the layers of epidermis and dermis by conventional histology and cell ability during the in vitro culture. Thus, both the vitrification methods were able to maintain normal patterns of the epidermis as the cornea and granular layers, furthermore the intercellular space and dermal–epidermal junction of the spinous layer when compared to fresh control. Nevertheless, DVC and SSV percentage of normality decreased in the morphological integrity of cytoplasm (37.5 and 25.0%) of spinous layer, respectively, as compared to the fresh fragments (100%, p < 0.05). Moreover, other differences between the fresh control (100%) and DVC tissues were verified in the intra-epidermal cleavage of the spinous (37.5%) and basal (37.5%) layers. In general, DVC and SSV techniques were efficient for the recovery of the somatic cells according to most of the evaluated parameters for the in vitro culture (p > 0.05). In addition, only at time of 72 h (D3), in the growth curve, DVC fragments showed a reduced cell concentration than fresh control. In conclusion, SSV was found to be a more efficient method for vitrifying collared peccary skin tissue when compared to DVC. These results are relevant for the tissue cryopreservation from collared peccary and could also be useful for mammals with phylogenetic relationships.     

Healing of skin wounds in the African catfish Clarias gariepinus

The African catfish Clarias gariepinus was used as a model for wound healing and tissue regeneration in a scale-less fish. A temporal framework of histological and cell proliferation markers was established after wound induction in the dorsolateral cranial region, by removing the epidermal and dermal layers, including stratum adiposum (SA). Wound closure and epidermis formation was initiated within 3 h post-procedure (hpp) with migration and concomitant proliferation of epidermal cells from the wound borders. The wound was covered by this primary epidermal front 12 hpp and fusion of the opposing epidermal fronts occurred within 24 hpp. Attachment of the newly formed epidermal layer to the underlying dermis was observed 48 hpp concomitant with a second wave of cell proliferation at the wound edge. Normal epidermal thickness within the wound was achieved 72 hpp. Formation of a basement membrane occurred by 120 hpp with concomitant emergence of the SA from the wound borders. Wound healing in C. gariepinus skin involved closure of the wound and re-epithelization through cell migration with a single wave of early cell proliferation not documented in other species. Furthermore, covering of the wound by epithelium as well as the reappearance of the basement membrane and SA occurred sooner than in other fish species.     

Ultraviolet B irradiation induces epidermal regeneration with rapidly cycling cells

The left flank of hairless mouse skin was irradiated with a minimal erythema dose of ultraviolet B (UVB) light at 297 nm (25 mJcm-2), while the right flank served as untreated control. The alterations in epidermal growth kinetics induced by this UVB dose were studied with the percentage of labelled mitoses (PLM) technique during the period of increased proliferation. Thirty hours after irradiation, when a large cohort of cells appears in S phase, each animal was injected intra-peritoneally with 50 microCi tritiated thymidine [( 3H]-TdR). The number of labelled basal and suprabasal cells, as well as their localization in epidermis were registered in histological sections at short intervals up to 48 h after the [3H]-TdR pulse. Labelled mitoses were also counted in the same specimens. The results showed a four-fold increase of the high initial number of labelled cells in UVB-exposed epidermis within 18 h of the pulse injection, and a six-fold increase after 36 h. In control epidermis, where the starting value of the labelling index was much lower, there was only a three to four-fold increase in the number of labelled cells during the period studied. The PLM and the labelling index data were consistent with an average cell cycle time of approximately 10-12 h for UVB-exposed cells, in contrast to about 30 h for the fastest cycling population in control epidermis. The PLM curve also indicated a prolonged S phase duration in UVB-exposed epidermis compared with controls. In addition, labelled cells were seen in the suprabasal layer as early as 6 h after the [3H]-TdR injection and within 36 h labelled cells had reached the outermost layer of nucleated cells, indicating a reduced transit time through epidermis. The present study shows that a minimal erythema dose of UVB light at 297 nm induced a period of increased transit time through the S phase, combined with rapid cell proliferation, leading to an overall shortening of the epidermal cell cycle time. The cohort of cells labelled with [3H]-TdR 30 h after irradiation seemed to proceed as a wave of partially synchronized cells through the cell cycle for more than two rounds, which is comparable with the cell kinetic perturbations observed in regenerating mouse epidermis.     

Presence in human epidermal cells of a soluble protein precursor of the cross-linked envelope: activation of the cross-linking by calcium ions.

Late in the terminal differentiation of epidermis and cultured epidermal cells, a protein envelope located beneath the plasma membrane becomes cross-linked by cellular transglutaminase. The process of cross-linking can be initiated in cultured epidermal cells by agents affecting cell membrane permeability--nonionic detergents, high salt concentrations and ionophores. These agents initiate the cross-linking process by making calcium ions available to the transglutaminase. A soluble precursor of the cross-linked envelope has been identified in crude extracts of cultured epidermal cells by its ability to incorporate labeled amines through the action of transglutaminase. The protein has been purified to homogeneity by gel filtration and chromatography on columns of DEAE-cellulose and hydroxyapatite. Comprising an estimated 5--10% of the soluble cell proteins, it has a molecular weight of about 92,000, is isoelectric at pH 4.5 +/- 0.3 and has an unusual amino acid composition (46% Glx residues). It is chemically and immunochemically unrelated to keratins. The following evidence confirms that the protein becomes incorporated into cross-linked envelopes: first, washed cross-linked envelopes bind antibody to the purified protein, as shown by indirect immunofluorescence; second, absorption of the antiserum with washed envelopes removes all detectable antibodies to the purified protein; and third, the protein cannot be extracted from keratinocytes after their envelopes have become cross-linked. Examination of sections of epidermis by immunofluorescence, using antiserum to the purified protein, reveals that in addition to the stratum corneum, the living cells of the outer half of the spinous layer react strongly. The envelope precursor is present in the cytoplasm, but becomes concentrated at the cell periphery, where it will be cross-linked later, when the cells have passed through the granular layer. The protein is also concentrated in a peripheral location in cultured epidermal cells.     

Cellular responses of the skin and changes in plasma cortisol levels of trout (Oncorhynchus mykiss) exposed to acidified water

The skin structure and the plasma cortisol levels of trout, Oncorhynchus mykiss, were examined during 7 days of exposure to water of pH 5. By day-4 and-7, the thickness of the epidermis was significantly (P<0.05) less in acid exposed fish than in controls, and degenerative cells were common in the upper epidermal layers. Many epidermal cells exhibited signs of necrosis, and by day-7 many apoptotic cells were also present. Secretory vesicles of high electron density were abundant in the filament cells of the 3–4 outermost layers of epidermis, and intercellular spaces had increased. Mitotic figures occureed throughout the epidermis, with the exception of the outermost cell layer. Mucous cells became elongated after day-1, and later, newly differentiating mucous cells could be seen close to the skin surface, and many mucocytes contained mucosomes of high electron density. Rodlet cells were occasionally seen. Chloride cells appeared similar to those of control fish. Many leucocytes, mainly macrophages and lymphocytes, had penetrated the epidermis via the highly undulating basal lamina, and at day-7, numerous apoptotic lymphocytes were found. In the dermis, melanosomes became dispersed in the cytoplasmic extensions of melanocytes which were present in the epidermis of all acid-exposed fish. Iridocytes were rate after day-4, while fibroblasts were abundant and secreted large amounts of collagen. After 1 day of exposure to acidified water, a significant (P<0.05) elevation of the plasma cortisol level had occurred, but this subsequently declined, and had returned to control values by day-7. The changes in skin structure, however, remained throughout the whole exposure period.     

A strong genotoxic effect in mouse skin of a single painting of coal tar in hairless mice and in MutaMouse

The dorsal skin of C3H/Tif/hr hairless mice was painted with coal tar, pharmacological grade. Epidermal cells and hepatocytes were isolated after 4, 24, 48 and 96 h and DNA strand breaks were determined as tail moment by the alkaline comet assay. The tail moment of epidermal cells was significantly greater at the time points 4, 24, 48 and 96 h after exposure compared to the controls, with the most DNA strand breaks at 24 h. The DNA strand breaks in epidermal cells increased linearly with the dose of coal tar. In hepatocytes, no difference in DNA strand breaks was found between exposed animals and controls. DNA adducts were determined by the 32P-postlabeling assay. For epidermal cells, the mean DNA adduct level was 12-fold greater in coal tar painted mice after 24 h than in controls. Again, a linear dose/response relationship was seen 24 h after painting. For liver DNA, the mean DNA adduct level was 3-fold greater than for controls. The mutation frequency in epidermal and liver cells was examined in lambdalacZ transgenic mice (MutaMouse). Thirty-two days after painting, the mutation frequency in epidermal cells was 16-fold greater in coal tar treated mice compared to controls. No effect was detected in hepatocytes. We found that a single painting of coal tar resulted in strong genotoxic effects in the murine epidermis, evidenced by induction of DNA strand breaks and DNA adducts in hairless mice and lambdalacZ mutations in the MutaMouse. This demonstrates that it is possible to detect genotoxic effects of mixtures with high sensitivity in mouse skin by these end-points.     

Ultraviolet B irradiation induces epidermal regeneration with rapidly cycling cells

Abstract. The left flank of hairless mouse skin was irradiated with a minimal erythema dose of ultraviolet B (UVB) light at 297 nm (25 mJcm^-2), while the right flank served as untreated control. The alterations in epidermal growth kinetics induced by this UVB dose were studied with the percentage of labelled mitoses (PLM) technique during the period of increased proliferation. Thirty hours after irradiation, when a large cohort of cells appears in S phase, each animal was injected intra-peritoneally with 50 /iCi tritiated thymidine ([³H]-TdR). The number of labelled basal and suprabasal cells, as well as their localization in epidermis were registered in histological sections at short intervals up to 48 h after the [³H]-TdR pulse. Labelled mitoses were also counted in the same specimens. The results showed a four-fold increase of the high initial number of labelled cells in UVB-exposed epidermis within 18 h of the pulse injection, and a sixfold increase after 36 h. In control epidermis, where the starting value of the labelling index was much lower, there was only a three to four-fold increase in the number of labelled cells during the period studied. The PLM and the labelling index data were consistent with an average cell cycle time of approximately 10–12 h for UVB-exposed cells, in contrast to about 30 h for the fastest cycling population in control epidermis. The PLM curve also indicated a prolonged S phase duration in UVB-exposed epidermis compared with controls. In addition, labelled cells were seen in the suprabasal layer as early as 6 h after the [³H]-TdR injection and within 36 h labelled cells had reached the outermost layer of nucleated cells, indicating a reduced transit time through epidermis. The present study shows that a minimal erythema dose of UVB light at 297 nm induced a period of increased transit time through the S phase, combined with rapid cell proliferation, leading to an overall shortening of the epidermal cell cycle time. The cohort of cells labelled with [³H]-TdR 30 h after irradiation seemed to proceed as a wave of partially synchronized cells through the cell cycle for more than two rounds, which is comparable with the cell kinetic perturbations observed in regenerating mouse epidermis.     

Mouse epidermal cell cultures : II. Isolation, characterization and cultivation of epidermal cells from perinatal mouse skin

In order to initiate studies on chemical carcinogenesis in an in vitro system analogous to mouse epidermis, primary epidermal cell cultures from perinatal mouse skin were established. A standardized method for the large-scale isolation of epidermal cells from late embryonic or newborn mouse dorsal skin has been developed. The epidermal cells were separated from fibroblasts by two series of discontinuous Ficoll density gradients. Using 80 to 100 animals/experiment, an average yield of 3×10⁶ viable epidermal cells/animal was obtained. The viability of the purified cell suspension exceeded 85%, and the plating efficiency, representing the growing cell fraction 24 h after plating, was about 43%.The cultures started as epithelial monolayers without fibroblast contamination. Their epidermal nature and origin was proved immunologically by an in vivo absorbed rabbit anti-mouse epidermis antiserum. The purity of the epidermal cells was quantitatively determined in trypsinized suspensions by the indirect immunofluorescence test yielding more than 95% epidermal antigen-positive cells. About half of the remaining antigen-negative cells could be identified as melanocytes. These highly purified epidermal cells grew in vitro for 2–3 weeks without dermal constituents or diffusible mesenchymal factors. The monolayers differentiated in culture giving rise to keratinizing cell sheets on top of the proliferating basal layer. By morphological, histochemical and physical methods, it could be evidenced that the differentiation processes in vitro are quite similar to keratinization in vivo.     

Differential chromosomal fluorescence with 33258 Hoechst

In order to initiate studies on chemical carcinogenesis in an in vitro system analogous to mouse epidermis, primary epidermal cell cultures from perinatal mouse skin were established. A standardized method for the large-scale isolation of epidermal cells from late embryonic or newborn mouse dorsal skin has been developed. The epidermal cells were separated from fibroblasts by two series of discontinuous Ficoll density gradients. Using 80 to 100 animals/experiment, an average yield of 3×10⁶ viable epidermal cells/animal was obtained. The viability of the purified cell suspension exceeded 85%, and the plating efficiency, representing the growing cell fraction 24 h after plating, was about 43%.The cultures started as epithelial monolayers without fibroblast contamination. Their epidermal nature and origin was proved immunologically by an in vivo absorbed rabbit anti-mouse epidermis antiserum. The purity of the epidermal cells was quantitatively determined in trypsinized suspensions by the indirect immunofluorescence test yielding more than 95% epidermal antigen-positive cells. About half of the remaining antigen-negative cells could be identified as melanocytes. These highly purified epidermal cells grew in vitro for 2–3 weeks without dermal constituents or diffusible mesenchymal factors. The monolayers differentiated in culture giving rise to keratinizing cell sheets on top of the proliferating basal layer. By morphological, histochemical and physical methods, it could be evidenced that the differentiation processes in vitro are quite similar to keratinization in vivo.     

Keratin polypeptide analysis in fetal and in terminally differentiating newborn mouse epidermis

The keratin polypeptide pattern of neonatal mouse epidermis consists of eight individual polypeptides having molecular weights of between 46,000 and 67,000. Unlike the keratin patterns in adult mouse epidermis, this pattern is not subjects to body site-specific alterations regarding the specific content of distinct polypeptides or the absolute number of keratin constituents. At day 16 of fetal development the neonatal keratin pattern is only partially expressed, it being fully completed just prior to birth at day 19 of gestation. A comparative analysis of the sequential changes in epidermal morphology and keratin pattern during the last third of embryonic development confirms the view that, independent of the species, keratin polypeptides below 60,000 mol. wt. are generated by basal cells, whereas the biosynthesis of high molecular weight keratin members take place in the suprabasal cell compartments of keratinizing epithelia. The site of origin of five polypeptides (60,000, 58,000, 52,000, 49,000, 46,000) could therefore be attributed to the basal cell layer, the remaining three polypeptides (67,000, 64,000, 62,000) being synthesized in the outer metabolically active epidermal layers. Similar conclusions could be drawn after subfractionation of neonatal epidermis into living (basal, spinous, and granular) and dead cell layers (stratum corneum), and investigation of the corresponding keratin patterns. During their progression through the epidermis, two proteins (60,000, 58,000) undergo a hitherto undescribed type of posttranslational modification characterized by a slight increase in size and a change in electrical charge. The mechanism underlying this modification is unknown and it is unclear whether the modification if functional or trivial. The largest keratin polypeptide (67,000) of the protein family -- probably a product of spinous cells -- disappears from the cornified layer without any evidence that it serves as a precursor for smaller keratin subunits.     

Downregulation of CXCR-2 but not CXCR-1 expression by human keratinocytes by UVB

Interleukin-8 (IL-8) belongs to the CXC chemokine family. IL-8 exerts its biological activities by binding to specific cell surface receptors, CXCR-1 and CXCR-2. Both receptors bind IL-8 with high affinity but they have different affinities for MGSA/Groalpha and NAP-2. It has been shown that the expression of epidermal CXCR-2 is increased in psoriasis, suggesting that activation of KC mediated by CXCR-2 contributes to the characteristic epidermal changes observed in psoriasis. In order to examine the mechanism(s) by which UVB therapy is effective for several dermatoses including psoriasis, we sought to examine if UVB would modulate the expression of CXCR-1 and CXCR-2 in human keratinocytes (KC). Constitutive expression of CXCR-1 and CXCR-2 mRNA was detected by RT-PCR in normal cultured human KC. After 100 or 300 J/m(2) irradiation, a decrease in CXCR-2 mRNA was detectable from 12 h after irradiation; this downregulation was observed until 48 h after irradiation. In contrast, the CXCR-1 mRNA level was unchanged. Immunohistochemical studies and flow cytometry analysis confirmed the suppressive effect of UVB on the expression of CXCR-2 protein in cultured human keratinocytes. Immunohistochemical studies on two minimal erythema doses (2MED)-exposed and 2MED-unexposed skin from healthy volunteers revealed that CXCR-2 staining occurred over the whole layer of the epidermis but at 24 h after 2MED irradiation, the positive staining of CXCR-2 was decreased. A faint CXCR-1 staining was observed in the lower part of the epidermis both in unexposed and exposed skins. Our results indicate that UVB-induced growth inhibition of KC in hyperproliferative skin disorders may, in part, be related to downregulation of CXCR-2.