Deimination of 70-kD nuclear protein during epidermal apoptotic events in vitro

Peptidylarginine deiminase (PAD) is the enzyme responsible for converting protein-bound arginine residues to citrulline. It has recently been shown that a number of epidermal proteins, including filaggrin, trichohyalin, and keratins, are deiminated by the action of PAD, suggesting a possible role for protein deimination during the final stages of epidermal differentiation. We report here a novel PAD substrate found during the course of identifying deiminated proteins in cultured rat epidermal keratinocytes. We found that a 70-kD protein localized to the periphery of the nucleus was preferentially deiminated after ionomycin treatment in the presence of 2 mM calcium and was associated with apoptotic events in these cells. Furthermore, we discovered that the deimination of nuclear protein could be induced by transfection of a PAD cDNA into rat epidermal keratinocytes. These data suggest that PAD may act on the 70-kD nuclear protein to induce disassembly of the nuclear lamina and promote apoptosis during terminal epidermal differentiation.     

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

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.     

The epitopes targeted by the rheumatoid arthritis-associated antifilaggrin autoantibodies are posttranslationally generated on various sites of (pro)filaggrin by deimination of arginine residues

Antifilaggrin autoantibodies (AFA) are a population of IgG autoantibodies associated to rheumatoid arthritis (RA), which includes the so-called "antikeratin" Abs and antiperinuclear factor. AFA are the most specific serological markers of RA. We previously showed that they recognize human epidermal filaggrin and other profilaggrin-related proteins of various epithelial tissues. Here, we report further characterization of the protein Ags and epitopes targeted by AFA. All the Ags that exhibit numerous neutral/ acidic isoelectric variants were immunochemically demonstrated to be deiminated proteins. In vitro deimination of a recombinant human filaggrin by a peptidylarginine deiminase generated AFA epitopes on the protein. Moreover, two of three filaggrin-derived synthetic peptides with a citrulline in the central position were specifically and widely recognized by AFA affinity-purified from a series of RA sera. These results indicate that citrulline residues are constitutive of the AFA epitopes, but only in the context of specific amino acid sequences of filaggrin. In competition experiments, the two peptides abolished the AFA reactivity of RA sera, showing that they present major AFA epitopes. These data should help in the identification of a putative deiminated AFA-inducing or cross-reactive articular autoantigen and provide new insights into the pathogenesis of RA. They could also open the way toward specific immunosuppressive and/or preventive therapy of RA.     

Ligands and activators of nuclear hormone receptors regulate epidermal differentiation during fetal rat skin development

Because a protective barrier is essential for life, the development of the epidermis and stratum corneum must be completed prior to birth. The epidermal permeability barrier is comprised of corneocytes embedded in a lipid enriched matrix. Recent studies from our laboratory, using an explant model of fetal rat skin development that closely parallels in utero development, have shown that hormones and other activators of members of the nuclear receptor family regulate permeability barrier ontogenesis by stimulating lipid metabolism and the formation of the extracellular lipid lamellae. Using this model we sought to determine whether these hormones and nuclear activators also regulate keratinocyte differentiation during fetal development. Profilaggrin/filaggrin and loricrin expression, assessed by in situ hybridization and by immunohistochemistry, were progressively increased during epidermal ontogenesis. Whereas profilaggrin/filaggrin and loricrin were not expressed at day 17 of gestation, by day 19 both were present in the upper layers of the epidermis and both became still more abundant by day 21. These developmental changes also occurred in fetal skin explants cultured in vitro for 4 d, although the expression levels did not appear as robust as in utero. Whereas neither profilaggrin/filaggrin nor loricrin were expressed in control explants cultured for 2 d, they were seen in explants treated with either thyroid hormone, glucocorticoids, or estrogens. In contrast, dihydrotestosterone treatment delayed the expression of profilaggrin/filaggrin and loricrin. Moreover, both clofibrate, a peroxisome proliferator-activated receptor-alpha ligand, and juvenile hormone III, a farnesoid X-activated receptor activator, markedly accelerated fetal epidermal differentiation, stimulating both profilaggrin/filaggrin and loricrin expression. Our results demonstrate that several hormones and activators of nuclear hormone receptors regulate epidermal differentiation during fetal development, affecting key constituents of both keratohyalin granules and the cornified envelope. Thus, a variety of ligands/activators of nuclear receptors accelerate not only permeability barrier ontogenesis, but also the expression of structural proteins essential for stratum corneum formation.     

Assembly of hair keratins in transfected epithelial cells

To define the interactions required for the filament assembly of differentiation-specific keratins, active copies of mouse hair keratin mHa1 and mHb4 genes were introduced into a rat kangaroo kidney epithelial cell line (PtK2) and a rat stratified squamous epithelial cell line (rat epidermal keratinocyte). In PtK2 transient transfectants, when introduced individually or in combination, mHa1 and mHb4 formed aggregates of ring-like structures of various sizes at the perinuclear region with no evidence of organization into a keratin network. These aggregates altered the distribution of the endogenous keratins and vimentin. In most of the cells carrying the ring-like structures of mHa1 and mHb4 around the nucleus, the endogenous keratin network collapsed and localized around the nucleus. Furthermore, the densely accumulated endogenous keratin surrounded the ring-like aggregates with partial co-localization. However, when transfected into the rat epidermal keratinocytes, mHa1 and mHb4 were able to co-localize with the well-developed cytoskeleton of endogenous keratins. These results showed that, in contrast to keratin pairs K5/K14 and K8/K18, the mHa1/mHb4 pair is unable to develop an extensive keratin network on its own and that there are possible differential abilities among these hair keratins and other keratins to form well-developed cytoplasmic networks.     

Calcipotriol (MC 903), a synthetic derivative of vitamin D3 stimulates differentiation of squamous carcinoma cell line in the raft culture

We investigated whether calcipotriol, a synthetic derivative of vitamin D3 has the ability to correct defects in the control of proliferation and differentiation of human squamous carcinoma cells using the raft culture of SCC 13 cell line. Calcipotriol treatment at concentrations of 10(-8)-10(-6) M considerably enhanced terminal differentiation of SCC 13 cells, as shown by the appearance of enucleated-eosinophilic cells as well as granular cells in their upper cell layers. Immunohistochemical staining showed marked increases in the differentiation of marker proteins such as keratin 1, involucrin, or filaggrin expressing cells in their upper layers. The elevated expression at protein level was confirmed by immunoblotting analysis. Furthermore, calcipotriol also stimulated basal cell marker proteins such as keratin 14 and EGF receptor. However, the numbers of basal marker expressing cells within the architecture of SCC 13 raft culture were markedly reduced upon calcipotriol treatment, and their localization was mainly restricted in the innermost cell layer. In addition, calcipotriol stimulated EGF receptor biosynthesis for the first 16 hours post treatment and subsequently inhibited [3H]-thymidine incorporation of SCC 13 cells at 24 hours. In this study, we have clearly demonstrated that the long term application of calcipotriol considerably improves the complex defects in the regulation of proliferation and differentiation of SCC 13 cells, as supported by morphological and biochemical observations. This provides an evidence that calcipotriol can be applied clinically as a potent differentiation inducer in the treatment of human squamous cell carcinoma.     

Making a connection: direct binding between keratin intermediate filaments and desmosomal proteins

In epidermal cells, keratin intermediate filaments connect with desmosomes to form extensive cadherin-mediated cytoskeletal architectures. Desmoplakin (DPI), a desmosomal component lacking a transmembrane domain, has been implicated in this interaction, although most studies have been conducted with cells that contain few or no desmosomes, and efforts to demonstrate direct interactions between desmoplakin and intermediate filaments have not been successful. In this report, we explore the biochemical nature of the connections between keratin filaments and desmosomes in epidermal keratinocytes. We show that the carboxy terminal "tail" of DPI associates directly with the amino terminal "head" of type II epidermal keratins, including K1, K2, K5, and K6. We have engineered and purified recombinant K5 head and DPI tail, and we demonstrate direct interaction in vitro by solution-binding assays and by ligand blot assays. This marked association is not seen with simple epithelial type II keratins, vimentin, or with type I keratins, providing a possible explanation for the greater stability of the epidermal keratin filament architecture over that of other cell types. We have identified an 18-amino acid residue stretch in the K5 head that is conserved only among type II epidermal keratins and that appears to play some role in DPI tail binding. This finding might have important implications for understanding a recent point mutation found within this binding site in a family with a blistering skin disorder.     

Dietary factors influence the recovery rates of Helicobacter pylori in a BALB/cA mouse model

We have identified a number of type I and type II keratins in the zebrafish Danio rerio by two-dimensional polyacrylamide gel electrophoresis, complementary keratin blot-binding assay and immunoblotting. These keratins range from 56 kDa to 46 kDa in molecular mass and from pH 6.6 to pH 5.2 in isoelectric point. Type II zebrafish keratins exhibit significantly higher molecular masses (56-52 kDa) compared with the type I keratins (50-48 kDa), but the isoelectric points show no significant difference between the two keratin subclasses (type II: pH 6.0-5.5; type I: pH 6.1-5.2). According to their occurrence in various zebrafish tissues, the identified keratins can be classified into "E" (epidermal) and "S" (simple epithelial) proteins. A panel of monoclonal anti-keratin antibodies has been used for immunoblotting of zebrafish cytoskeletal preparations and immunofluorescence microscopy of frozen tissue sections. These antibodies have revealed differential cytoplasmic expression of keratins; this not only includes epithelia, but also a variety of mesenchymally derived cells and tissues. Thus, previously detected fundamental differences in keratin expression patterns between higher vertebrates and a salmonid, the rainbow trout Oncorhynchus mykiss, also apply between vertebrates and the zebrafish, a cyprinid. However, in spite of notable similarities, trout and zebrafish keratins differ from each other in many details. The present data provide a firm basis from which the application of keratins as cell differentiation markers in the well-established genetic model organism, the zebrafish, can be developed.     

An atypical form of bullous congenital ichthyosiform erythroderma is caused by a mutation in the L12 linker region of keratin 1

Defective keratins are the cause of a number of hereditary disorders of the epidermis and other epithelia. The disease-causing mutations in keratins are clustered in the rod domain, and mutations in the helix boundary peptides cause the most severe forms of epidermal fragility syndromes. Siemens described a family with an atypical, mild form of bullous congenital ichthyosiform erythroderma. Linkage analysis in this family indicated that a defective type II keratin might be the underlying cause, keratins K1 and K2e being the best candidates. A substitution of valine for aspartic acid was detected at position 340 (D340V) in the L12 region of the K1 polypeptide. The mutation was found to cosegregate with the disorder in the family. Herewith, a genotype-phenotype correlation is shown for bullous congenital ichthyosiform erythroderma comparable with that described for epidermolysis bullosa simplex.     

Monoclonal antibody specific to bovine lens epithelial cell membrane: preparation of a lens epithelial cell-selective immunotoxin

Dithranol has been used successfully in the treatment of psoriasis for more than 75 years, and much in vitro and in vivo research has been done on the elucidation of the mode of action of this potent and safe antipsoriatic therapy. In vivo research has revealed major effects of dithranol on epidermal proliferation and inflammation. Information on the in vivo effects on epidermal differentiation is limited. Therefore, the dynamics of a set of differentiation markers (keratin 16, filaggrin, keratinocyte transglutaminase, involucrin) and markers for proliferation and inflammation (Ki-67, T lymphocytes, polymorphonuclear leucocytes) were studied in skin biopsies of six patients with psoriasis during 4 weeks of dithranol therapy. The treatment regimen involved a short contact protocol at our out-patient day treatment centre with an easily washed off cream. Treatment resulted in a decrease of the PASI score of 48% in 4 weeks. Immunohistochemically, a major decrease of keratin 16 content and virtually complete restoration of the filaggrin positive cell layer were seen. These changes proved to be significant by comparison of the markers over the group of six patients. Although many other topical treatments for psoriasis (occlusive therapy and vitamin D3 analogues) result in a prominent reduction in the amount of transglutaminase and involucrin positive cell layers, the effect of dithranol on these markers is minimal.     

Effect of physical activity as a caddie on ultrasound measurements of the Os calcis: a cross-sectional comparison

Human epidermal keratinocytes synthesize, secrete, and degrade acetylcholine and use their cell-surface nicotinic and muscarinic cholinergic receptors to mediate the autocrine and paracrine effects of acetyl-choline. Because acetylcholine modulates transmembrane Ca2+ transport and intracellular metabolism in several types of cells, we hypothesized that cholinergic agents might have similar effects on keratinocytes. Nicotine increased in a concentration-dependent manner the amount of 45Ca2+ taken up by keratinocytes isolated from human neonatal fore-skins. This effect was abolished in the presence of the specific nicotinic antagonist mecamylamine, indicating that it was mediated by keratinocyte nicotinic acetylcholine receptor(s). The sequences encoding the alpha 5 and alpha 7 nicotinic receptor subunits were amplified from cDNA isolated from cultured keratinocytes. These subunits, as well as the alpha 3, beta 2, and beta 4 subunits previously found in keratinocytes, can be components of Ca(2+)-permeable nicotinic receptor channels. To learn how activation of keratinocyte nicotinic receptors affected the rate of cell differentiation, we measured the nicotinic cholinergic effects on the expression of differentiation markers by cultured keratinocytes. Long-term incubations with micromolar concentrations of nicotine markedly increased the number of cells forming cornified envelopes and the number of cells staining with antibodies to suprabasal keratin 10, transglutaminase type I, involucrin, and filaggrin. The increased production of these differentiation-associated proteins was verified by Western blotting. Because nicotinic cholinergic stimulation causes transmembrane Ca2+ transport into keratinocytes, and because changes in concentrations of intracellular Ca2+ are known to alter various keratinocyte functions, including differentiation, the subcellular mechanisms mediating the autocrine and paracrine actions of epidermal acetylcholine on keratinocytes may involve Ca2+ as a second messenger.     

The scientific venture of Battista Grassi and the discovery of Anopheles in malaria

Harlequin ichthyosis (HI) is a severe congenital ichthyosis in which newborn infants are covered with a thick plate of stratum corneum. We examined skin specimens from a variety of regions of the body including the scalp, face, tongue, trunk, upper and lower extremities, digits, palms, and soles of three fetuses affected with HI that were diagnosed prenatally. In all the skin regions, characteristic morphological abnormalities (absent or abnormal lamellar granules and intercellular lamellae, lipid inclusions in the cornified cells) were expressed in the late second trimester of the fetal period. The cornified cells in hair canals showed morphological abnormalities of HI more strongly than the interfollicular epidermis. Immunoblot study of epidermal extracts revealed that profilaggrin was much more prominent than filaggrin in all the hairy skin regions where the hair canals were extensively keratinized, but filaggrin was prominent in the palm. These observations support the idea that, in the hairy skin, HI phenotype expression is associated with keratinization and abnormal filaggrin metabolism in hair. In addition, the prenatal diagnosis or prenatal exclusion of HI is thought to be possible from whichever site of the fetal body the skin biopsy is taken in the late second trimester of the fetal period.     

Epidermolysis bullosa herpetiformis (Dowling-Meara type) exhibits ultrastructural derangement of tonofilaments and desmosomes

Ultrastructural and immunohistochemical studies of clinically intact skin obtained from three severe neonatal cases of epidermolysis bullosa herpetiformis (Dowling-Meara type) demonstrated disorders in the assembly of keratin intermediate filaments and desmosomes of the keratinocytes. During mitosis, K5- and K14-positive and K1- and K10-negative tonofilaments were disrupted and formed spherical bodies associated with intracytoplasmic desmosomes by invagination of the desmosomes and the adjacent plasma membrane. During the invagination process, destructive changes in the internalized membrane were noted. These were accompanied by gradual loss of reactivity with a monoclonal antibody ZK31, which detected plasma membrane adjacent to the attachment plaques of desmosomes. However, the reactivity of the attachment plaques of the internalized desmosomes for desmoplakins and desmoglein did not decline during the process of internalization. In the suprabasal layers of the epidermis, filamentous substructures and K1 and K10 appeared at the periphery of the spherical bodies. Simultaneously, the desmosomes that were sparsely located in the lower epidermis, increased in number as cell differentiation progressed. Thus, the keratinocytes attained an almost normal appearance with respect to tonofilaments and desmosomes by the time they reached the upper layer of the epidermis. These findings may be relevant to the mechanism responsible for the clinical appearance of the herpetiform blisters in epidermolysis bullosa herpetiformis, which are also characterized by spontaneous involution during childhood or when exposed to high ambient temperatures.     

The genetic basis of epidermolysis bullosa simplex with mottled pigmentation

Epidermolysis bullosa simplex (EBS) is a group of autosomal dominant skin diseases characterized by blistering, due to mechanical stress-induced degeneration of basal epidermal cells. It is now well-established that the three major subtypes of EBS are genetic disorders of the basal epidermal keratins, keratin 5 (K5) and keratin 14 (K14). Here we show that a rare subtype, referred to as EBS with mottled pigmentation (MP), is also a disorder of these keratins. Affected members of two seemingly unrelated families with EBS-MP had a C to T point mutation in the second base position of codon 24 of one of two K5 alleles, leading to a Pro: Leu mutation. This mutation was not present in unaffected members nor in 100 alleles from normal individuals. Linkage analyses mapped the defect to this type II keratin gene (peak logarithm of odds score at phi = 0 of 3.9), which is located on chromosome 12q11-q13. This provides strong evidence that this mutation is responsible for the EBS-MP phenotype. Only conserved between K5 and K6, and not among any of the other type II keratins, Pro-24 is in the nonhelical head domain of K5, and only mildly perturbs the length of 10-nm keratin filaments assembled in vitro. However, this part of the K5 head domain is likely to protrude on the filament surface, perhaps leading to additional aberrations in intermediate filament architecture and/or in melanosome distribution that are seen ultrastructurally in patients with the mutation.     

Refeeding varying fatty acid and cholesterol diets alters phospholipids in rat intestinal brush border membrane

The epidermis is an attractive site for therapeutic gene delivery because it is accessible and capable of delivering polypeptides to the systemic circulation. A number of difficulties, however, have emerged in attempts at cutaneous gene delivery, and central among these is an inability to sustain therapeutic gene production. We have examined two major potential contributing factors, viral vector stamina and involvement of long-lived epidermal progenitor cells. Human keratinocytes were either untreated or transduced with a retroviral vector for beta-galactosidase (beta-Gal) at > 99% efficiency and then grafted onto immunodeficient mice to regenerate human epidermis. Human epidermis was monitored in vivo after grafting for clinical and histologic appearance as well as for gene expression. Although integrated vector sequences persisted unchanged in engineered epidermis at 10 weeks post-grafting, retroviral long terminal repeat (LTR)-driven beta-Gal expression ceased in vivo after approximately 4 weeks. Endogenous cellular promoters, however, maintained consistently normal gene expression levels without evidence of time-dependent decline, as determined by immunostaining with species-specific antibodies for human involucrin, filaggrin, keratinocyte transglutaminase, keratin 10, type VII collagen, and Laminin 5 proteins out to week 14 post-grafting. Transduced human keratinocytes generated multilayer epidermis sustained through multiple epidermal turnover cycles; this epidermis demonstrated retention of a spatially appropriate pattern of basal and suprabasal epidermal marker gene expression. These results confirm previous findings suggesting that viral promoter-driven gene expression is not durable and demonstrate that keratinocytes passaged in vitro can regenerate and sustain normal epidermis for prolonged periods.     

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Expression of keratin K5 (and K14) in multilayered epithelia occurs predominantly in the basal layer of proliferating keratinocytes. When a keratinocyte becomes committed to terminal differentiation, it moves out of the basal layer towards the epithelial surface. As part of this program of terminal differentiation, the expression of K5 (and K14) is downregulated in suprabasal cells, and new pairs of differentiation-specific keratins are expressed. To define the cis-acting DNA sequences required for K5 cell-type- and differentiation-specific expression, chimeric gene fusions between portions of the bovine keratin K5 locus and the Escherichia coli lacZ gene were used to generate transgenic mice. In the genomic fragment consisting of 5.3 kb of 5' flanking sequences, 6.1 kb corresponding to the body of the gene and 4.5 kb of 3' flanking sequences, the subfragment extending from -5300 bp to +138 bp was the smaller region that directed lacZ expression to stratified epithelia in a manner analogous to the endogenous keratin K5. Proximal sequences from -1300 bp to +138 bp were inactive. We also determined the expression pattern of keratin K5 during mouse development using an antiserum specific for mouse keratin K5. Expression was first detected in ectodermal cells of 11.5 days postcoitum embryos, and from day 13.5 postcoitum onwards K5 was detected in the precursors of most epithelia and organs which express K5 at adult stages. This pattern was reproduced, with few differences, by the construct with sequences from -5300 bp to +138 bp fused to the lacZ gene. These findings identify sequences between -5.3 kb and -1.3 kb of the bovine K5 gene as being important for cell-type- and differentiation-specific gene expression both during mouse development and in the adult.     

EGF-receptor tyrosine kinase inhibition induces keratinocyte growth arrest and terminal differentiation

Epidermal keratinocyte growth and differentiation are regulated by specific families of growth factors and receptors. Peptide growth factors of the epidermal growth factor family stimulate proliferation of clonal density human keratinocytes and suppress markers of terminal differentiation in confluent cultures of human keratinocytes. We present evidence that selected inhibitors of activation of the type I human epidermal growth factor receptor (EGFR or HER-1), namely, neutralizing monoclonal antibody to HER-1/EGFR and the specific tyrosine kinase inhibitor PD 153035, potently inhibit proliferation of human keratinocytes in autonomously replicating subconfluent cultures. Coupled to growth arrest is the suppression of HER-1 tyrosine autophosphorylation in inhibitor-treated human keratinocytes. Proliferation and tyrosine autophosphorylation are initially reversible following removal of the inhibitor and restimulation of cells with epidermal growth factor. Sustained inactivation of HER-1 in autonomously replicating cultures of human keratinocytes induces expression of keratin 1 and keratin 10 genes, early markers of terminal differentiation. Reversal of growth inhibition by epidermal growth factor suppresses keratin 1 and keratin 10 expression. These results demonstrate that human keratinocyte terminal differentiation as well as proliferation are mediated by HER-1. Co-expression of autocrine epidermal growth factor-related ligands as well as HER-1 by human keratinocyte may function as part of the signal transduction network in epidermis to regulate cell number, replication rate, and terminal differentiation.