Similarities between stratum corneum basic protein and histidine-rich protein II from newborn rat epidermis

The stratum corneum basic protein and histidine-rich protein II were each isolated from newborn rat epidermis and compared by biochemical and immunologic methods. The proteins were indistinguishable by immunodiffusion using antiserum elicited to either protein. The migration of the proteins on SDS-polyacrylamide gel electrophoresis was identical giving a molecular weight of 49 000. These proteins, which have similar but unusual amino acid compositions, give very similar tryptic peptide maps. Both proteins aggregate with keratin filaments to form macrofibrils. These results suggest that histidine-rich protein II and stratum corneum basic protein are the same protein. We suggest that this protein be called histidine-rich basic protein.     

Studies on the synthesis and degradation of a high molecular weight, histidine-rich phosphoprotein from mammalian epidermis

The synthesis and subsequent fate of the histidine-rich proteins, which form a major component of keratohyalin granules in mammalian epidermis, have been studied in the guinea-pig and new-born rat. In both species the protein first synthesised is of very high molecular weight, approximately 340 000. It is short-lived and breaks down to lower molecular weight proteins 1-2 days after its synthesis. These smaller proteins differ in the two species. In the guinea-pig, the high molecular weight protein breaks down to proteins of molecular weight 250 000 and 200 000, which are themselves unstable and break down to low molecular weight species, probably amino acids. The initial breakdown of the high molecular weight protein coincides with the dispersion of the keratohyalin granules and the transition of the granular cell into the stratum corneum. This high molecular weight histidine-rich protein has been purified to homogeneity, despite its instability to several treatments during purification. The protein is highly phosphorylated, containing 6 mol% of phosphoserine, but is otherwise very basic. The possibility that dephosphorylation of the protein produces highly basic matrix proteins in the stratum corneum is discussed.     

Two polypeptide chain constituents of the major protein of the cornified layer of newborn rat epidermis.

The insoluble component of stratum corneum of rat epidermis yields two major bands after extraction with 8 M urea-mercaptoethanol-dithiothreitol. The ratio of these two bands is about 1:1 in terms of protein stain intensity and S-[14C]carboxymethyl label. Both polypeptides were purified to homogeneity by DE-52-cellulose, sodium dodecyl sulfate hydroxylapatite C column chromatography, and preparative DodSO4-polyacrylamide gel electrophoresis. The heavier polypeptide contains 30% alpha helix and the lighter contains 27% alpha helix as determined by circular dichroism studies. Both are sensitive to Pronase and resistant to trypsin, collagenase, and elastase. The lighter chain is stable to pepsin but the heavier can be partially degraded to a smaller polypeptide with a molecular weight similar to that of light chain. Amino acid analysis shows that the light chain contains 12 more tyrosine residues than does the heavy chain, suggesting that the light chain is not generated from the heavy chain. However, the two chains may have a common peptide region. Antiserum prepared against the heavier polypeptide can be completely absorbed by purified lighter polypeptide and vice versa indicating that both chains have some common antigenic determinants. Antibody against either chain can cross-react with the stratum corneum and keratohyalin granules in the epidermis of newborn rat as indicated by fluorescent microscopic observation. Similarly, this antibody also cross-reacts with the cell surface or the contents of spinous and granular cells, and very weakly with basal cells, indicating that the two proteins may be present in the lower strata as well as the stratum corneum.     

Identification of a Rapidly Labelled 350K Histidine-Rich Protein in Neonatal Mouse Epidermis

Abstract. The major histidine-rich protein (HRP) found in the stratum corneum of neonatal mouse epidermis (band 2 protein, molecular weight 27,000) is a relatively late product of epidermal differentiation and incorporates labelled amino acids in vivo only after a 6–9 h lag period. A number of putative precursor HRPs in the 70–300 K molecular weight range were initially identified using short pulse labelling times and our previously described methods for isolation of epidermis and extraction of proteins. However, when steps were taken to minimise proteolysis during preparation, a single species of approximately 350 K molecular weight was the most strongly labelled protein following a 1 h in vivo pulse of [³H]-histidine. This protein was stable in sodium dodecyl sulphate dithiothreitol at 100°C and in 4 M urea, suggesting a single covalently linked polypeptide. The kinetics of labelling and the localisation of the 350 K HRP in the lower granular layers suggest that it is a precursor of the stratum corneum HRP. The processing of the 350 K HRP to the stratum corneum species appears to involve a complex series of specific cleavage steps which give rise to a number of HRPs of intermediate molecular weight.     

Identification of a rapidly labelled 350K histidine-rich protein in neonatal mouse epidermis

The major histidine-rich protein (HRP) found in the stratum corneum of neonatal mouse epidermis (band 2 protein, molecular weight 27,000) is a relatively late product of epidermal differentiation and incorporates labelled amino acids in vivo only after a 6-9 h lag period. A number of putative precursor HRPs in the 70-300 K molecular weight range were initially identified using short pulse labeling times and our previously described methods for isolation of epidermis and extraction of proteins. However, when steps were taken to minimise proteolysis during preparation, a single species of approximately 350 K molecular weight was the most strongly labelled protein following a 1 h in vivo pulse of [3H]-histidine. This protein was stable in sodium dodecyl sulphate dithiothreitol at 100 degrees C and in 4 M urea, suggesting a single covalently linked polypeptide. The kinetics of labelling and the localisation of the 350 K HRP in the lower granular layers suggest that it is a precursor of the stratum corneum HRP. The processing of the 350 K HRP to the stratum corneum species appears to involve a complex series of specific cleavage steps which give rise to a number of HRPs of intermediate molecular weight.     

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

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

beta-Glucocerebrosidase activity in murine epidermis: characterization and localization in relation to differentiation.

The intercellular lipids of the stratum corneum, which are highly enriched in ceramides, are critical for the mammalian epidermal permeability barrier. During the terminal stages of epidermal differentiation, the glucosylceramide content is dramatically reduced, while the content of free ceramides increases. To investigate whether beta-glucocerebrosidase (beta-GlcCer'ase) could be responsible for this change in lipid content, we characterized its activity in murine epidermis, compared enzyme activity to other murine tissues, and localized beta-GlcCer'ase activity within the epidermis. Epidermal extracts demonstrated linear 4-methylumbelliferyl-beta-D-glucose hydrolysis (to 3 h) with protein concentrations between 1 and 250 micrograms/ml. Whole epidermis contained comparable beta-glucosidase activity (9.1 +/- 0.4 nmol/min per mg DNA) to murine brain and liver, and 5-fold higher activity than spleen. Epidermal beta-glucosidase activity was stimulated greater than 15-fold by sodium taurocholate at pH 5.6, and inhibited at acidic pH (3.5-4.0). Bromoconduritol B epoxide (greater than or equal to 1.0 microM), inhibited epidermal enzyme activity by greater than 75%, while activity in brain, liver, and spleen was only inhibited by 6, 17, and 14%, respectively. Moreover, beta-GlcCer'ase mRNA expression in murine epidermis exceeded levels in liver, brain, and spleen. Finally, beta-GlcCer'ase activity was highest in the outer, more differentiated epidermal cell layers including the stratum corneum. In summary, mammalian epidermis contains an usually high percentage (approximately 75%) of beta-glucocerebrosidase activity, and the concentration of activity in the more differentiated cell layers may account for the replacement of glucosylceramide by ceramides in the outer epidermis.     

Subunit structure of the mouse epidermal keratin filament.

The two proteins which are the subunits of mouse epidermal keratin filaments have been isolated from fully differentiated epidermis (stratum corneum), viable differentiating cells and cells grown in culture. The proteins have molecular weights of 68 000 and 60 000, consist of families of very similar species, have common N-terminal (N-acetylserine) and C-terminal (glycine) residues, contain 35--40% alpha-helix and are immunologically cross-reacting. In mixtures, the two proteins polymerize in vitro into native-type keratin filaments that are 70--80 angstrom in diameter, up to 30 micrograms long, possess a characteristic alpha-type X-ray diffraction pattern and contain the subunits in the precise molar ratio of 1 : 2 or 2 : 1.     

AKT-dependent HspB1 (Hsp27) activity in epidermal differentiation

AKT activity has been reported in the epidermis associated with keratinocyte survival and differentiation. We show in developing skin that Akt activity associates first with post-proliferative, para-basal keratinocytes and later with terminally differentiated keratinocytes that are forming the fetal stratum corneum. In adult epidermis the dominant Akt activity is in these highly differentiated granular keratinocytes, involved in stratum corneum assembly. Stratum corneum is crucial for protective barrier activity, and its formation involves complex and poorly understood processes such as nuclear dissolution, keratin filament aggregation, and assembly of a multiprotein cell cornified envelope. A key protein in these processes is filaggrin. We show that one target of Akt in granular keratinocytes is HspB1 (heat shock protein 27). Loss of epidermal HspB1 caused hyperkeratinization and misprocessing of filaggrin. Akt-mediated HspB1 phosphorylation promotes a transient interaction with filaggrin and intracellular redistribution of HspB1. This is the first demonstration of a specific interaction between HspB1 and a stratum corneum protein and indicates that HspB1 has chaperone activity during stratum corneum formation. This work demonstrates a new role for Akt in epidermis.     

Modified distribution of epidermal glycoproteins in the nude mouse

The nude mouse is an athymic mutant whose immunological deficiency has been exploited for transplantation of normal and diseased xenogeneic tissue. Histologically, its skin has no unusual features apart from the absence of hair. We report here a biochemical study of its epidermis, with comparison to the hairless mouse (which is devoid of hair but otherwise functionally normal). The epidermal glycoproteins were probed with the lectin, concanavalin A (Con A). Fluorescein isothiocyanate (FITC)-Con A overlays of cryostat skin sections gave a similar fluorescent pattern for both mouse strains: all the viable epidermal cell layers were labeled but not the stratum corneum. In contrast, when different populations of keratinocytes that were separated on Percoll gradients were analyzed by gel electrophoresis, and the gels then overlaid with iodinated Con A, all the epidermal layers, including the stratum corneum, were labeled. For all the epidermal cell layers there are substantial differences between the two mouse strains. We observe changes in the glycoprotein distribution with the stage of differentiation. Comparison with our earlier data for human epidermis indicates that the discrepancies between the nude mouse and the hairless mouse are much greater than those between the latter and man. The most striking difference is the absence in the stratum corneum of the nude mouse of a 40 K glycoprotein which is the dominant feature for the hairless mouse and for man. The gel patterns point to functional discrepancies in the epidermis of the nude mouse, particularly in the stratum corneum, not evident histologically or with FITC-Con A.     

The characterization of human epidermal filaggrin. A histidine-rich, keratin filament-aggregating protein

Filaggrin is a histidine-rich, cationic protein that aggregates with keratin filaments in vitro and may function as the keratin matrix protein in the terminally differentiated cells of the epidermis. This protein has been previously isolated from rodent epidermis. In this investigation, a similar protein from human skin was identified, isolated and characterized by biochemical and immunologic techniques. Indirect immunofluorescence of human skin using antiserum to rat filaggrin gave positive immunofluorescence of keratohyalin granules and the stratum corneum. This indicated the presence of a human filaggrin in the epidermis in a localization similar to that of the rodent. The protein was isolated from human epidermis and purified by ion-exchange chromatography and preparative gel electrophoresis. The purified protein crossreacts with antibody to rat filaggrin and migrates as a doublet of molecular weight (Mr) approximately 35 000 on SDS-polyacrylamide gels. It is relatively rich in polar amino acids such as histidine, arginine, serine and glycine, but is poor in nonpolar amino acids. Unlike rodent filaggrin, the human protein contains ornithine. This protein aggregates with human keratin filaments, forming compact macrofibrils in a manner analogous to that of rodent filaggrin. Thus, a human epidermal protein has been isolated which has many of the characteristics of rodent filaggrin and may function as the human keratin matrix protein.     

Ultrastructural localization of caspase-14 in human epidermis.

Caspase-14 has been implicated in the formation of stratum corneum because of its specific expression and activation in terminally differentiating keratinocytes. However, its precise physiological role and its protein substrate are elusive. We studied the ultrastructural localization of caspase-14 in human epidermis to compare its distribution pattern with that of well-characterized differentiation markers. Immunogold cytochemistry confirmed that caspase-14 is nearly absent in basal and spinous layers. In the granular, layer nuclei and keratohyalin granules were labeled with increasing intensity towards the transitional layer. Particularly strong caspase-14 labeling was associated with areas known to be occupied by involucrin and loricrin, whereas F-granules, occupied by profilaggrin/filaggrin, were much less labeled. A high density of gold particles was also present at the forming cornified cell envelope, including desmosomes. In corneocytes, intense labeling was both cytoplasmic and associated with nuclear remnants and corneodesmosomes. These observations will allow focusing efforts of biochemical substrate screening on a subset of proteins localizing to distinct compartments of terminally differentiated keratinocytes.     

A new class of soluble basic protein precursors of the cornified envelope of mammalian epidermis

The cornified envelope hs been shown to be formed beneath the plasma membrane as a result of the cross-linking of soluble and membrane-associated precursor proteins by transglutaminase. We have obtained a monoclonal antibody which reacts with the periphery of cells in the upper layers of human epidermis by indirect immunofluorescence (IIF) following immunization of mice with cornified envelopes of cultured human keratinocytes. The antibody also stained the cell peripheries of bovine, rat and mouse epidermis as well as stratified epithelium. Neutral buffer extracts of human cultured keratinocytes and epidermis examined under denaturing conditions contained polypeptides of molecular weight 14 900 and 16 800 which reacted with the antibody, and an additional component of molecular weight 24 800 was found in cultured cells. The polypeptides were shown to have a pI of about 9.0. Under non-denaturing conditions the two lower-molecular-weight polypeptides had an apparent molecular weight of 30 000, while the 24 800 protein had one of 60 000. Incubation of the polypeptides under conditions that activate transglutaminase resulted in a disappearance of the polypeptides or the formation of cross-linked products. Basic polypeptides with somewhat different pI values and molecular weights were identified in neutral buffer extracts of bovine and rat epidermis. The HCE-2 antibody appears to identify a new class of basic protein precursors of mammalian cornified envelope.     

Human epidermal lipids: characterization and modulations during differentiation

Using thin-layer chromatography and glass capillary gas-liquid chromatography, we have quantitated the lipids in the germinative, differentiating, and fully cornified layers in human epidermis. As previously noted in nonhuman species, we found progressive depletion of phospholipids coupled with repletion of sterols and sphingolipids during differentiation. The sphingolipids, present only in small quantities in the lower epidermis, accounted for about 20% of the lipid in the stratum corneum, and were the major repository for the long-chain fatty acids that predominate in the outer epidermis. Although the absolute quantities of sphingolipids increased in the outer epidermis, the glycolipid:ceramide ratio diminished in the stratum corneum, and glycolipids virtually disappeared in the outer stratum corneum. Squalene and n-alkanes were distributed evenly in all epidermal layers, suggesting that these hydrocarbons are not simply of environmental or pilosebaceous origin. Cholesterol sulfate, previously considered only a trace metabolite in epidermis, was found in significant quantities, with peak levels immediately beneath the stratum corneum in the stratum granulosum. These studies: 1) provide new quantitative data about human epidermal lipids; 2) implicate certain classes of lipids for specific functions of the stratum corneum; and, 3) shed light on possible product-precursor relationships of these lipids.     

Measurement of the transit time for cells through the epidermis and stratum corneum of the mouse and guinea-pig

A new approach to determine the transit time through the epidermis is presented, involving a gentle washing of the skin surface to collect the loosely attached surface corneocytes. This, it is believed, will be less likely to stimulate the system than tape-stripping or scraping. Radioactively labelled thymidine and iododeoxyuridine have been used to label cells in the basal layer and various labelled amino acids (glycine, cystine and methionine) have been used to label the metabolically viable cell layers (up to and including the granular layer). The resulting changes in surface radioactivity levels have been interpreted to provide a basal to surface transit time of 8-9.5 days for hairless and haired mouse epidermis and about 13.5 days for guinea-pigs. The basal to granular layer transit time, which probably includes some basal layer residence time, is about 4.5 days in the mouse and 8 days in the guinea-pig. The granular to surface time in mice is about 5 days. The results also suggest that when nuclear and cytoplasmic organelles are degraded in the granular layer, material is released that can diffuse rapidly through the stratum corneum to the surface. Some of this can be shown by chromatography to be thymidine. Hence, the stratum corneum is previous to molecules such as nucleosides. This rapid diffusion outwards through the skin can also be detected shortly after injecting [125I]-iododeoxyuridine.     

Measurement of the transit time for cells through the epidermis and stratum corneum of the mouse and guinea-pig

Abstract A new approach to determine the transit time through the epidermis is presented, involving a gentle washing of the skin surface to collect the loosely attached surface corneocytes. This, it is believed, will be less likely to stimulate the system than tape-stripping or scraping. Radioactively labelled thymidine and iododeoxyuridine have been used to label cells in the basal layer and various labelled amino acids (glycine, cystine and methionine) have been used to label the metabolically viable cell layers (up to and including the granular layer). The resulting changes in surface radioactivity levels have been interpreted to provide a basal to surface transit time of 8–9.5 days for hairless and haired mouse epidermis and about 13.5 days for guinea-pigs. The basal to granular layer transit time, which probably includes some basal layer residence time, is about 4.5 days in the mouse and 8 days in the guinea-pig. The granular to surface time in mice is about 5 days. The results also suggest that when nuclear and cytoplasmic organelles are degraded in the granular layer, material is released that can diffuse rapidly through the stratum corneum to the surface. Some of this can be shown by chromatography to be thymidine. Hence, the stratum corneum is pervious to molecules such as nucleosides. This rapid diffusion outwards through the skin can also be detected shortly after injecting [¹²⁵I]-iododeoxyuridine.     

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.     

Changes in structure of ventral epidermis of Rana ridibunda during metamorphosis

Summary The organisation of the ventral epidermis organisation was followed throughout ontogenesis in Rana ridibunda. Epidermis of tadpoles with 2–3 limbs was organised into two layers: a stratum germinativum consisting of elongated columnar cells, and an outer stratum corneum consisting of two types of cuboid cells. Two types of cells can be distinguished; they are a light (clear) cell and a dark (dense) cell. In the 4-legged tadpoles the stratum corneum cells start to flatten and a replacement layer appeared underneath. A well-defined stratum germinativum is found and within it, epidermal glands. Moulting took place for the first time in tadpoles just before metamorphosis, and a well-organised stratum granulosum was formed still containing the two main types of epidermal glands. The flask cells appear in the juveniles for the first time, greatly increasing in numbers in the adult epidermis.     

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.     

Degenerative and regenerative changes in epidemrmal organ culture: A morphological study wity reference to membrane-coating granules

Summary Membrane-coating granules (MCG) are poorly understood lamellate organelles unique to keratinized epithelia. This study provides data on a skin model for future in vitro investigations of MCG. Porcine ear epidermal, organ cultures were used under standard cell culture conditions. This system was selected because it is easily established and, following a degenerative period in which MCG are lost, regenerates to form a highly differentiated epidermis. The epidermis appeared healthy during the first 2 din vitro and contained MCG but lost keratohyalin granules (KHG). Overt degenerative changes were evident in the upper epidermis on Day 3, and MCG were now bloated. By Day 4 only one to three layers of viable undifferentiated cells remained. In the overlying necrotic epidermis MCG were rare, presumably due to the bursting of bloated MCG. Epidermal regeneration began around Day 5 and by Day 7 there, were 8 to 13 layers, including a, rudimentary parakeratotic stratum corneum (up to 4 layers). The stratum granulosum (two to three layers) now containe immature KHG and poorly lamellate MCG, but only amorphous material extracellularly. By Day 11 there were three to four layers of granular cells as in vivo, and an orthokeratotic stratum corneum (two to four layers). Improved cornification coincided with an increased number of mature KHG and cross-banded MCG, and lamellate MCG contents extracellularly. This model of epidermal regeneration will factiliate studies into the role played by MCG in keratinization because the epithelium initially lacked MCG but later expressed all the major morphologic features of epidermis. Furthermore the mechanisms by which MCG translaction and extrusion are effected may be probed, by the inclusion of such agents as antimicrotubular drugs and calcium ionophores. This work was supported by a grant from Unilever Research, Port Sunlight, England.