Identification of citrulline residues in the V subdomains of keratin K1 derived from the cornified layer of newborn mouse epidermis

Citrulline residues are detected in keratins and filaggrin in the cornified layers of mammalian epidermis. Such citrulline residues are formed by the enzymatic deimination of arginine residues by peptidylarginine deiminase (EC 3.5.3.15). Major deiminated keratins are thought to be partially degraded/disulfide-cross-linked keratin K1 based on the immunoblotting profiles. In order to obtain more definitive evidence of the deimination of keratin K1 and also to investigate its functional significance, we attempted to identify its preferred acting sites of peptidylarginine deiminase. A partially degraded keratin K1 fraction obtained from the cornified layer of newborn mouse epidermis was subjected to limited proteolytic cleavages, and the resulting deiminated peptides were fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis or reverse-phase high-performance liquid chromatography for N-terminal sequencing and/or amino acid analysis. At least two sites were identified, one in the V1 and the other in the V2 subdomains of keratin K1. An undecapeptide sequence covering the latter shows about 70% homology with an undecapeptide sequence in the V2 subdomain of human K1, a presumptive site of deimination. We speculated that the deimination of arginine residues in these subdomains might modulate their interactions with epidermal proteins other than keratins and filaggrin during the terminal stage of epidermal differentiation.     

Studies on specificity of peptidylarginine deiminase reactions using an immunochemical probe that recognizes an enzymatically deiminated partial sequence of mouse keratin K1.

Citrulline residues are detected in keratins and filaggrin in the cornified layers of mammalian epidermis. Such citrulline residues are formed by the enzymatic deimination of arginine residues by peptidylarginine deiminases (EC 3.5.3.15). Major deiminated keratins are derived from keratin K1. Two arginine residues identified as preferred deimination sites in mouse K1 are located in its V subdomains. To develop an immunochemical probe which recognizes the deiminated peptide sequence specifically, we enzymatically deiminated an undecapeptide corresponding to the deiminated peptide sequence identified in the V2 subdomain for immunizing rabbits. An IgG fraction obtained from the antiserum was affinity-purified using an immobilized peptide column. The affinity-purified IgG showed high specificity towards partially degraded keratin K1 obtained from the cornified layer of 3-day-old mouse epidermis. It also yielded intense signals of unidentified minor components localized in the cornified layers of late embryonic and early postnatal mouse epidermis. Comparative studies using different types of the enzymes suggested that peptidylarginine deiminase type I acted on the arginine residue in the V2 subdomain of keratin K1 more readily than peptidylarginine deiminase type II. The data are discussed in conjunction with possible factors influencing the specificity of the enzyme reaction.     

Sequential reorganization of cornified cell keratin filaments involving filaggrin-mediated compaction and keratin 1 deimination

The final step of keratinocyte differentiation, transition from the granular cells to the cornified cells, involves various post-translational modifications that include deimination of arginine residues. Major deiminated epidermal proteins are derived from K1. Two preferred deimination sites were identified in mouse K1, one in the V1 and the other in the V2 subdomains. An antibody against the deiminated peptide sequence in the V2 subdomain recognized not only deiminated mouse K1 but also deiminated human K1. In this study we analyzed distribution of deiminated K1 in normal human skin and in bullous congenital ichthyosiform erythroderma at light and electron microscopic levels. In normal skin the first few (1-3) cornified cell layers were positive for filaggrin and negative for the antibody against deiminated mouse K1 peptide, whereas the more superficial cells were negative for filaggrin and strongly positive for the antibody against deiminated mouse K1 peptide, indicating slightly delayed onset of K1 deimination at the initial stage of cornification. The clumped keratin in bullous congenital ichthyosiform erythroderma that was not properly compacted with filaggrin was poorly positive to the antibody against deiminated mouse K1 peptide. In addition, K1 derivatives in bullous congenital ichthyosiform erythroderma reacted poorly with the antibody against deiminated mouse K1 peptide compared with the normal control in immunoblot analyses. Our results suggest sequential reorganization of cornified cell keratin filaments involving filaggrin-mediated compaction and K1 deimination. Abnormal keratin aggregation in bullous congenital ichthyosiform erythroderma is likely to disturb the normal deimination of K1.     

Prediction of a coding sequence for a novel type II keratin from N-terminal sequences of mouse epidermal proteins site-specifically deiminated in embryonic development

BACKGROUND: Epidermal keratinization involves various post-translational modifications including the deimination of arginine residues. Major deiminated proteins are derived from keratin K1. Two preferred deimination sites were identified in the V subdomain of mouse K1. An antibody against one of the deiminated peptide sequences (ACP) recognized deiminated mouse and human K1, and stained the cornified layers of human and infant mouse epidermis. ACP also stained the outermost layer of mouse embryonic epidermis. Western blotting revealed minor proteins showing strong ACP-positive signals in the mouse embryonic epidermal extract in which deiminated K1 derivatives were hardly detected. OBJECTIVE: To characterize ACP-positive proteins expressed in mouse embryonic epidermis. METHODS: ACP-positive proteins were isolated by preparative gel electrophoresis for N-terminal sequencing followed by blast searches for matching sequences in the protein and nucleotide database. RESULTS: We obtained N-terminal sequences of two ACP-positive proteins. A cDNA clone in the est_mouse database has an open reading frame for 202 amino acid residues containing both sequenced peptides. The deduced sequence shows typical features of the N-terminal portion of type II keratins. A virtually identical sequence to this reading frame is present in a genomic contig of chromosome 15 on which keratin type II genes are clustered. Sequential searches for overlapping cDNA clones in the est_mouse database along with similar searches in the genomic contig formulated a hypothetical cDNA sequence encoding a putative protein of 572 amino acid residues tentatively called K1-emb. CONCLUSION: We predicted a sequence of novel type II keratin site-specifically deiminated in embryonic mouse epidermis.     

Decreased deiminated keratin K1 in psoriatic hyperproliferative epidermis

Citrulline-containing proteins, mainly originating from keratin K1 and formed by enzymatic deimination of arginine residues, have been identified in the cornified layers of human epidermis. We analyzed the localization and nature of the deiminated proteins in psoriatic epidermis. Immunostaining based on chemical modification of citrulline residues showed that the normal and psoriatic uninvolved epidermis contained deiminated proteins diffusely in the cornified cell layer, whereas the involved epidermis had no detectable or markedly reduced levels of deiminated proteins. Immunolabeling with polyclonal antibodies against a synthetic citrulline-containing peptide corresponding to a deiminated sequence of mouse K1 also suggested markedly decreased deiminated K1 in psoriatic involved lesions. Keratin analyses indicated that deiminated K1 present in normal and psoriatic uninvolved epidermis was not detected in the psoriatic involved epidermis. Double staining with a monoclonal antibody, 34betaB4, and the polyclonal antibodies demonstrated that epidermis with low suprabasal keratin expression was negative for deiminated K1. In contrast, intralesional acrosyringia showing decreased suprabasal keratin immunoreactivity like that of the surrounding psoriatic epidermis showed strong deiminated K1 staining. This suggests that abnormal keratin deimination is restricted to the psoriatic hyperproliferative epidermis, without affecting sweat ductal epithelia.     

Peptidylarginine deiminase isoforms 1-3 are expressed in the epidermis and involved in the deimination of K1 and filaggrin

Post-translational conversion of arginine to citrulline residues is catalyzed by peptidylarginine deiminases (PAD). Although the existence of five isoforms of PAD has been reported in rodents and humans, their tissue distribution, substrate specificity, and physiological function have yet to be explored. In the epidermis, deimination of filaggrin and keratins is involved in maintaining hydration of the stratum corneum (SC), and hence the cutaneous barrier function. Here, RT-PCR, western blotting, and confocal microscopy analyses with anti-peptide antibodies highly specific for each of the PAD1-4 demonstrated that only PAD1-3 are expressed in mouse and human epidermis. PAD1 was detected in all layers, including the SC, and PAD2 in all the living layers, whereas PAD3 expression was shown to be restricted to the granular layer and lower SC. Moreover, PAD1 and 3 were observed to co-localize with (pro)filaggrin, and PAD2 to be located at the keratinocyte periphery in the stratum granulosum. We also detected PAD1 in extracts of superficial SC, where K1 is deiminated. Moreover, we showed that PAD1 and 3 are able to modify filaggrin in vitro. These data strongly suggest that each enzyme exerts a specific role in the course of epidermis differentiation.     

Changing pattern of deiminated proteins in developing human epidermis

Peptidylarginine deiminases are widely distributed, calcium-ion-dependent enzymes that convert arginine residues of proteins into citrulline residues. This reaction, deimination, is thought to be an important event during the final stage of epidermal differentiation, possibly associated with integration and disintegration of keratin filaments. To elucidate the possible roles of protein deimination during human epidermal development we investigated localization of deiminated proteins using anti-citrulline peptide antibody, which preferentially recognizes citrulline residues in the V subdomains of keratin 1, and anti-chemically modified citrulline antibody, which enables detection of citrulline residues independent of amino acid sequences. Anti-chemically modified citrulline antibody, but not anti-citrulline peptide antibody stained the periderm in two-layered epidermis of 49 d and 57 d estimated gestational age. In the stratified epidermis of 88 d, 96 d, and 108 d estimated gestational age fetal skin, anti-citrulline peptide antibody and anti-chemically modified citrulline antibody staining was seen in the periderm and intermediate cell layers. After periderm cells regressed and keratinization began in the interfollicular epidermis, anti-citrulline peptide antibody and anti-chemically modified citrulline antibody were restricted to the cornified cell layers of the interfollicular epidermis, similar to the distribution patterns of that in adult epidermis. Postembedding immunoelectron microscopy showed anti-citrulline peptide antibody immunogold labeling over the cytoplasmic intermediate filament network in the periderm and the intermediate cell layers. These results demonstrate an orderly formation of deiminated proteins in different layers of embryonic epidermis and suggest important roles for peptidylarginine deiminases in human epidermal morphogenesis.     

Collateral occurrence of deimination of keratins with differentiation of an immortalized newborn rat keratinocyte cell line cultured at air–liquid interface

We devised a simple method to maintain an immortalized newbown rat keratinocyte cell line at the air–liquid interface using a tissue culture insert fitted with a microporous membrane. The cells formed stratified layers of flattened and anucleated cells resembling stratum corneum of the epidermis. Deiminated proteins, which are localized in the cornified layer of epidermis as the reaction products of peptidylarginine deiminase were detected immunohistochemically in the differentiated cells. Western blot analyses revealed that major deiminated proteins were type I keratins K10 and K14. Deiminated products of type II keratin K5 were found as minor components. Our observations show that deimination of keratins might be correlated with terminal differentiation of the immortalized keratinocyte cell line.     

Effects of topical retinoids on cytoskeletal proteins: implications for retinoid effects on epidermal differentiation.

In vivo effects of retinoids on epidermal differentiation were investigated by analyzing cytoskeletal proteins in rhino mice treated topically with all-trans-retinoic acid (RA) and other retinoids (13-cis-retinoic acid, etretinate, TTNPB). Non-disulfide-linked cytoskeletal proteins, including keratins from the epidermal "living layers," were first selectively extracted using 9.5 M urea; subsequently, keratins of the stratum corneum were isolated using 9.5 M urea plus a reducing agent. Gel electrophoresis and immunoblot analysis showed that urea extracts of epidermis from vehicle-treated skin were composed predominantly of four major keratins (analogous to human epidermal keratins K1, K5, K10, and K14), and the keratin filament-associated protein filaggrin. In contrast, extracts of epidermis from retinoid-treated skin contained additional keratins (K6, K16, and K17) and almost no detectable filaggrin. Furthermore, similar analysis of stratum corneum keratins demonstrated that extracts from RA-treated skin did not contain the partially proteolyzed keratins typically observed in stratum corneum extracts of control animals. Hyperplasia-inducing agents (salicylic acid, croton oil) caused an increase in keratins K6, K16, and K17, but they did not effect filaggrin or alter proteolysis of stratum corneum keratins. The result that RA induced expression of keratins K6, K16, and K17, as commonly expressed in hyperproliferative epidermis, is consistent with the notion that retinoids increase epidermal cell proliferation in the basal and/or lower spinous layers. The findings that topical RA decreased filaggrin expression and reduced proteolysis of stratum corneum keratins, despite increased size and number of granular cells and the presence of an anucleate stratum corneum, suggest that topical RA may also modulate a later stage of epidermal differentiation involved in stratum corneum formation.     

Cornified cell envelope proteins and keratins are normally distributed in harlequin ichthyosis

Long-term survivors of harlequin ichthyosis (HI) have raised a controversy over the differences between HI and lamellar ichthyosis (LI). Abnormal lamellar granules and the failure of conversion from profilaggrin to filaggrin have been reported in HI. On the other hand, malformation of the cornified cell envelope as a result of mutation of keratinocyte transglutaminase has been found in LI. In the present study, we analyzed the distribution of keratins, filaggrin/profilaggrin and cornified cell envelope proteins in the epidermis in HI. We studied a newborn Japanese male with typical clinical features of HI. Electron microscopic observation of a skin biopsy specimen taken from the trunk revealed the presence of lipid inclusions within the cornified cells, the absence of lamellar granules in the granular layer keratinocytes, and a lack of extracellular lamellar structures between the first cornified cell and the granular cell. Immunohistochemical labeling showed a normal distribution of keratins (keratins 1,5, 10, and 14), filaggrin/profilaggrin and cornified cell envelope proteins (involucrin, small proline-rich proteins, and loricrin) in the epidermis of lesional skin. The present observations of the patient's skin verified that keratins and cornified cell envelope proteins are normally expressed in HI, thus demonstrating a different pathogenesis between HI and LI.     

Deimination and expression of peptidylarginine deiminases during cutaneous wound healing in mice

Deimination, the conversion of protein-bound arginines into citrullines, is a post-translational modification catalyzed by a peptidylarginine deiminase (Pad). In the epidermis, three Pads are expressed, namely Pad1, 2 and 3, and the major deiminated protein is filaggrin. Deimination of fibrin has been observed in various pathological inflammatory conditions. Here, we analyzed the expression of Pads and citrullination of proteins during cutaneous wound healing, i.e. in a physiological inflammatory condition. Full-thickness punches were performed on adult mouse back skin, and wound recovery was analyzed over 10 days by immunohistology and western blotting. Pad1 was immunodetected in all the neo-epidermis. Pad3, normally expressed in the stratum granulosum, was not detected in the hyperproliferative tongue of the neo-epidermis, but was shown to be co-localized with (pro)filaggrin in a large number of keratinocyte layers in its differentiating part. Deiminated proteins were detected in the stratum corneum of the neo-epidermis in the late phase of re-epithelialization, and in the clot and the clot-derived scab. In the clot where we only detected Pad4, one of the deiminated proteins was shown to be fibrin. Deimination of the clot proteins, and more generally wound healing and keratinocyte differentiation, seemed to be Pad2-independent, as shown using Padi2(-/-) mice.     

DHCR24 gene knockout mice demonstrate lethal dermopathy with differentiation and maturation defects in the epidermis

Desmosterolosis is an autosomal recessive disorder due to mutations in the 3beta-hydroxysterol-Delta24 reductase (DHCR24) gene that encodes an enzyme catalyzing the conversion of desmosterol to cholesterol. To date, only two patients have been reported with severe developmental defects including craniofacial abnormalities and limb malformations. We employed mice with targeted disruption of DHCR24 to understand the pathophysiology of desmosterolosis. All DHCR24-/- mice died within a few hours after birth. Their skin was wrinkleless and less pliant, leading to restricted movement and inability to suck (empty stomach). DHCR24 gene was expressed abundantly in the epidermis of control but not of DHCR24-/- mice. Accordingly, cholesterol was not detected whereas desmosterol was abundant in the epidermis of DHCR24-/- mice. Skin histology revealed thickened epidermis with few and smaller keratohyaline granules. Aberrant expression of keratins such as keratins 6 and 14 suggested hyperproliferative hyperkeratosis with undifferentiated keratinocytes throughout the epidermis. Altered expression of filaggrin, loricrin, and involcrin were also observed in the epidermis of DHCR24-/-. These findings suggested impaired skin barrier function. Indeed, increased trans-epidermal water loss and permeability of Lucifer yellow were observed in DHCR24-/- mice. DHCR24 thus plays crucial role for skin development and its proper function.     

Peptidylarginine deiminases and deimination in biology and pathology: relevance to skin homeostasis

Deimination corresponds to the transformation of arginine residues within a peptide sequence into citrulline residues. Catalyzed by peptidylarginine deiminases, it decreases the net positive charge of proteins, alters intra and intermolecular ionic interactions and probably the folding of target proteins. Deimination has recently been implicated in several physiological and pathological processes. Here, we describe the enzymes involved in this post-translational modification, focusing on their expression, location and roles in skin, as well as their known protein substrates in the epidermis and hair follicles. We discuss also the potential involvement of deimination in human diseases including cutaneous disorders.     

Abnormalities of basal cell keratin in epidermolysis bullosa simplex do not affect the expression patterns of suprabasal keratins and cornified cell envelope proteins

Abstract Basal keratins, suprabasal keratins, filaggrin, and cornified cell envelope (CCE) precursor proteins are expressed during the differentiation of epidermal keratinocytes. These molecules are coordinately expressed during epidermal differentiation. The present study investigated the expression patterns of keratins and CCE precursor proteins in 15 patients with epidermolysis bullosa simplex (EBS), which is caused by mutations in the genes that encode for the basal keratins, keratins 5 and 14. The patterns of expression of keratins 5, 14, 1 and 10, filaggrin, and of the three major CCE precursor proteins, involucrin, loricrin and small proline-rich proteins 1 and 2 (SPRs), were studied immunohistochemically and by electron microscopy. In 14 of the 15 patients with EBS, the distribution pattern of keratins was not altered. In one neonate with EBS, basal cell keratins were expressed in the suprabasal layers. Ultrastructurally, numerous clumped tonofilaments were observed in the basal and suprabasal cells. In all cases, findings were positive for filaggrin in the granular cells, with positivity for involucrin in the upper spinous and granular cells. The upper spinous cells and granular cells were positive for SPRs 1 and 2, and loricrin was expressed in granular cells. Ultrastructurally, no marked abnormality was observed in the suprabasal layers such as a decrease in, or agglutination of, keratin filaments, except in one neonate. A CCE about 15 nm thick was formed normally in the cell membrane of cornified cells. The patterns of distributions of basal cell keratins, suprabasal keratins, filaggrin, and CCE precursor proteins, as well as the ultrastructural findings, resembled those of normal skin. Thus, the abnormality in basal cell keratins in patients with EBS did not appear to alter the patterns of expression of the keratins and CCE precursor proteins. Received: 8 April 1998 / Received after revision: 17 July 1998 / Accepted: 30 July 1998     

Barrier function, epidermal differentiation, and human beta-defensin 2 expression in tinea corporis

Tinea corporis is a superficial mycotic infection resulting in substantial epidermal changes. We determined skin barrier function, epidermal differentiation, and human-beta-defensin 2 (hBD-2) protein expression in 10 patients with tinea corporis caused by Trichophyton rubrum (T. rubrum). We found disturbed skin barrier function as shown by a significant increase in transepidermal water loss (TEWL) and specific ultrastructural changes including disturbed formation of extracellular lipid bilayers, lamellar body extrusion, and deposit of clotted material at the stratum granulosum/stratum corneum interface. Epidermal proliferation in tinea increased several fold and accordingly, proliferation and inflammation-associated keratins K6, K16, and K17 were expressed. Expression of basal keratins K5 and K14 increased, whereas differentiation-associated K10 was reduced. Reduction of the cornified envelope proteins involucrin, loricrin, and the S100 protein filaggrin was also seen. Reduced filaggrin expression correlated with reduced skin hydration; protein breakdown products of filaggrin have been shown to be important for water binding. Surprisingly, we found pronounced epidermal protein expression of hBD-2, which may be related to disturbed epidermal differentiation and inflammation. hBD-2 showed a weak, although significant, antifungal activity against T. rubrum in the turbidimetric assay and the immunohistological staining was somewhat less pronounced in areas directly underneath fungal hyphae in the stratum corneum. Together, we describe profound changes in skin barrier structure and function, epidermal proliferation, and differentiation including pronounced protein expression of hBD-2 in tinea corporis.     

Loss of normal profilaggrin and filaggrin in flaky tail (ft/ft) mice: an animal model for the filaggrin-deficient skin disease ichthyosis vulgaris

Flaky tail (gene symbol ft) is an autosomal recessive mutation in mice that results in a dry, flaky skin, and annular tail and paw constrictions in the neonatal period. Previous studies demonstrated that the ft mutation maps to the central region of mouse chromosome 3, in the vicinity of the epidermal differentiation complex, a gene locus that includes many nonkeratin genes expressed in epidermis. In this study we report a detailed characterization of the flaky tail mouse. Affected homozygous ft/ft mice exhibit large, disorganized scales on tail and paw skin, marked attenuation of the epidermal granular layer, mild acanthosis, and orthokeratotic hyperkeratosis. Biochemical analysis demonstrated that ft/ft mice lacked normal high molecular profilaggrin (approximately 500 kDa), and instead expressed a lower molecular weight form of profilaggrin (220 kDa) that is not proteolytically processed to profilaggrin intermediates or filaggrin. Mutant mice lacked the large, irregular F-type keratohyalin granules that contain profilaggrin, and filaggrin was absent from the cornified layers of ft/ft epidermis. The expression of epidermal keratins was unchanged, whereas the cornified envelope proteins involucrin and loricrin were increased in ft/ft epidermis. Cultured ft/ft keratinocytes also synthesized reduced amounts of profilaggrin mRNA and protein, demonstrating that the defect in profilaggrin expression is intrinsic to epidermal cells. These findings demonstrate that flaky tail mice express an abnormal profilaggrin polypeptide that does not form normal keratohyalin F-granules and is not proteolytically processed to filaggrin. We propose that the absence of filaggrin, and in particular the hygroscopic, filaggrin-derived amino acids that are thought to function in epidermal hydration, underlies the dry, scaly skin characteristic of ft/ft mice. This animal model provides a tool for understanding the role of filaggrin in normal epidermal function and may provide insight into the molecular basis of the filaggrin-deficient human skin disorder ichthyosis vulgaris. J Invest Dermatol 115:1072-1081 2000     

Targeting gene expression to the epidermis of transgenic mice: potential applications to genetic skin disorders

The ability to specifically target gene expression to the epidermis of transgenic mice offers the exciting possibility of creating animal models of certain skin disorders that are inherited in man. It may be possible to produce mouse models of dominantly inherited keratinization disorders by targeting the expression of mutant genes encoding the major differentiation products of the epidermis, such as the differentiation specific keratins, filaggrin and cell envelope proteins. Mouse models for other skin disorders associated with abnormal regulation of growth, such as psoriasis, may be generated by targeting the overexpression of cytokines and growth factors, which are thought to play important roles in the pathogenesis of this disease. The development of currently unavailable animal models for certain inherited human skin diseases would not only contribute to our understanding of the pathogenesis of these diseases at the molecular level, but also provide interesting models for therapeutic intervention.     

Induction of selected lipid metabolic enzymes and differentiation-linked structural proteins by air exposure in fetal rat skin explants

The epidermal permeability barrier of premature infants matures rapidly following birth. Previous studies suggest that air exposure could contribute to this acceleration, because: (i) development of a structurally and functionally mature barrier accelerates when fetal rat skin explants are incubated at an air-medium interface, and (ii) occlusion with a water-impermeable membrane prevents this acceleration. To investigate further the effects of air exposure on epidermal barrier ontogenesis, we compared the activities of several key enzymes of lipid metabolism and gene expression of protein markers of epidermal differentiation in fetal rat skin explants grown immersed versus air exposed. The rate-limiting enzymes of cholesterol (HMG CoA reductase) and ceramide (serine palmitoyl transferase) synthesis were not affected. In contrast, the normal developmental increases in activities of glucosylceramide synthase and cholesterol sulfotransferase, responsible for the synthesis of glucosylceramides and cholesterol sulfate, respectively, were accelerated further by air exposure. Additionally, two enzymes required for the final stages of barrier maturation and essential for normal stratum corneum function, beta-glucocerebrosidase, which converts glucosylceramide to ceramide, and steroid sulfatase, which desulfates cholesterol sulfate, also increased with air exposure. Furthermore, filaggrin and loricrin mRNA levels, and filaggrin, loricrin, and involucrin protein levels all increased with air exposure. Finally, occlusion with a water-impermeable membrane prevented both the air-exposure-induced increase in lipid enzyme activity, and the expression of loricrin, filaggrin, and involucrin. Thus, air exposure stimulates selected lipid metabolic enzymes and the gene expression of key structural proteins in fetal epidermis, providing a biochemical basis for air-induced acceleration of permeability barrier maturation in premature infants.     

The growth of ichthyotic epidermal cells in a 3-dimensional reconstruction of human skin, the skin equivalent

We have studied the differentiation of ichthyotic epidermis in vitro using the skin equivalent model. The morphology of these ichthyotic cultures has been investigated using histopathological and histometric techniques including epidermal and stratum corneum thickness measurements. The skin equivalents have also been investigated for the presence of markers of differentiation using immunolocalization techniques. These markers include the 65·5 and 67 kDa keratins, desmoplakin, involuerin, laminin and filaggrin. It has been shown that the ichthyotic epidermis develops a fully differentiated epidermis and stratum corneum, equivalent to those seen in normal skin equivalents.     

EXPRESSION OF KERATOHYALIN-TRICHOHYALIN HYBRID GRANULES IN MOLLUSCUM CONTAGIOSUM

Background. Recently, in the filiform papillae epithelium of mouse dorsal tongue, we showed the presence of hybrid granules in which filaggrin and trichohyalin were both present, but physically segregated. Further, trichohyalin was also detected in scattered granular cells of a number of hyperplastic skin diseases. Methods. The epidermis infected with molluscum contagiosum virus (MCV) was studied by conventional electron microscopy in conjunction with light and electron-microscopic immunohistochemistry, using both antifilaggrin and antitrichohyalin antibodies as probes. Results. We found that the granular cells of MCV-infected epidermis contained both filaggrin and trichohyalin. Subsequent electron-microscopic examination showed that the granular cells contained morphologically heterogeneous granules that appeared to be composed of discrete areas of distinct electron densities. Double-labeling, using antibodies to filaggrin and trichohyalin, clearly indicated that filaggrin and trichohyalin were both present in the hybrid granules and that the electron-dense regions contained trichohyalin while the more electron-lucent regions contained filaggrin. Conclusions. The expression of trichohyalin was a common feature observed in the epidermis from a heterogenous group of hyperplastic conditions, including MCV Infection. This finding has led us to speculate that trichohyalin may be specifically or preferentially involved in interacting with the hyperproliferation-related keratin pair (K6/K16), whereas the function of filaggrin is more closely linked to the skin-type keratin pair (K1/K10) that are normal keratins found in the differentiated epidermis.