Altered lamellar body secretion and stratum corneum membrane structure in Netherton syndrome: differentiation from other infantile erythrodermas and pathogenic implications.

BACKGROUND: The infant with Netherton syndrome (NS) typically displays a generalized erythroderma covered by fine, translucent scales, which can be difficult to distinguish clinically from erythrodermic psoriasis, nonbullous congenital ichthyosiform erythroderma, or other infantile erythrodermas. Some infants with NS develop progressive hypernatremic dehydration, failure to thrive, and enteropathy. Such complications can be fatal. Diagnosis is typically delayed until the appearance of a pathognomonic hair shaft anomaly, trichorrhexis invaginata (bamboo hair). To facilitate the early diagnosis of NS, we obtained biopsy specimens from 7 patients with erythrodermic NS and compared their morphologic findings to those of 3 patients with erythrodermic psoriasis and 2 with congenital ichthyosiform erythroderma. Biopsy specimens were processed for light and electron microscopy using postfixation with osmium tetroxide and ruthenium tetroxide. OBSERVATION: In NS, and often in congenital ichthyosiform erythroderma and erythrodermic psoriasis, the stratum corneum layer was largely replaced by parakeratotic cells. A distinctive feature--premature secretion of lamellar body contents--occurred only in NS. Furthermore, lamellar body-derived extracellular lamellae and stratum corneum lipid membranes were separated extensively by foci of electron-dense material. Finally, transformation of lamellar body-derived lamellae into mature lamellar membrane structures was disturbed in NS. CONCLUSIONS: Premature lamellar body secretion and foci of electron-dense material in the intercellular spaces of stratum corneum, features not observed in other erythrodermic disorders, appear to be frequent and relatively specific markers for NS. These ultrastructural features could permit the early diagnosis of NS before the appearance of the hair shaft abnormality. These abnormalities could explain the impaired permeability barrier in NS, and account for hypernatremia and dehydration in infants with NS.     

Stratum corneum hydration and flexibility are useful parameters to indicate clinical severity of congenital ichthyosis

To determine any correlation between the stratum corneum barrier function and the phenotypic severity of congenital ichthyosis, we studied stratum corneum hydration, flexibility, thickness and transepidermal water loss (TEWL) in patients with congenital ichthyosis. Seven patients with congenital ichthyosis aged 2-46 years and age-matched controls were included in the present study. We divided seven patients into two groups; patients with non-bullous type (non-bullous congenital ichthyosiform erythroderma patients) and patients with the bullous type of congenital ichthyosis (bullous congenital ichthyosiform erythroderma and ichthyosis bullosa of Siemens). Stratum corneum hydration, thickness and flexibility were measured using a Corneometer ASA-M2. The stratum corneum thickness was also examined using a skin biopsy technique. TEWL was measured using Evaporimeter AS-TW1. The clinical severity of ichthyosis phenotype was evaluated using a visual analogue scale (VAS). Stratum corneum hydration and flexibility were significantly reduced in both congenital ichthyosis patient groups. Stratum corneum thickness was significantly increased in both groups. In the patient group with non-bullous congenital ichthyosis, significant negative correlations were confirmed between the VAS score and stratum corneum hydration and between the VAS score and flexibility. A significant, positive correlation was also observed between the VAS score and stratum corneum thickness. There was a positive correlation between the VAS score and TEWL on both the extensor and flexor sides of the forearm and back. We conclude that stratum corneum hydration, flexibility and thickness measured by the corneometer, and TEWL on the arm may be a useful indicator of the severity of ichthyosis phenotype.     

Techniques for Toddlers: Linear Band Incision for Harlequin Ichthyosis with Associated Compartment Syndrome

Harlequin ichthyosis (HI) is a rare autosomal recessive disorder of cornification in which children are born with an extremely thick stratum corneum that becomes a restrictive circumferential encasement around the orifices, limbs, chest, and abdomen, resulting in limb contractures. We present a neonate diagnosed in utero with HI. The infant was born with encasing bands of thickened skin creating strictures that were causing digital and limb cyanosis (compartment syndrome). We treated the child using a new technique of lysis of the encasing bands that we call linear band incision, using a new escharotomy‐like procedure while the infant was undergoing a 3‐week course oral acitretin therapy. The technique involved linear incision and lysis of encasements that resulted in reperfusion of the injured limbs and prevention of further digital necrosis. The child is currently a healthy 8‐year‐old boy with skin manifestations resembling congenital ichthyosiform erythroderma. He has use of all of the limbs that were released in the procedures and is maintained on frequent application of bland emollients. Linear band incision is a potentially life‐ and limb‐saving technique in children with HI.     

Ichthyoses: differential diagnosis and molecular genetics

Ichthyoses are a heterogeneous group of cornification disorders characterized by a generalized scaling of the skin. Common types such as ichthyosis vulgaris and X-linked recessive ichthyosis manifest after birth. In contrast, rare congenital ichthyoses are inherited diseases, which at birth typically present collodion membranes or ichthyosiform erythroderma. Syndromic ichthyoses display a variety of outstanding associated non-cutaneous symptoms. Because of their rarity these disorders often pose a diagnostic challenge for the clinician. This review discusses a broad spectrum of 13 isolated types of ichthyoses, 11 different syndromes with associated ichthyosis and four related cornification disorders. The clinical, ultrastructural and biochemical characteristics are described along with the different molecular causes of ichthyosis. Special attention is given to lamellar ichthyosis and non-bullous congenital ichthyosiform erythroderma. The different pathomechanisms causing ichthyosis provide a fascinating insight into the role of various proteins, enzymes, lipids and metabolic pathways involved in terminal epidermal differentiation/keratinisation.     

Stratum corneum lipid abnormalities in ichthyosis. Detection by a new lipid microanalytical method

Although the biochemical diagnosis of the ichthyoses is still in its infancy, the two recessively inherited types, recessive X-linked ichthyosis (RXLI) and nonbullous congenital ichthyosiform erythroderma (CIE), are accompanied by stratum corneum lipid abnormalities. However, in RXLI, cholesterol sulfate accumulates; in CIE, massive quantities of n-alkanes accumulate. The diagnosis of these disorders has required large quantities of scale for sequential, quantitative thin-layer chromatography (TLC). In this study, we sought to confirm the previously described lipid abnormalities with the use of a rapid, recently developed microchromatographic technique that employs silica gel-coated quartz rods and flame ionization detection (Iatroscan). The cholesterol sulfate content of RXLI (n = 5) scale and the n-alkane content of CIE (n = 8) scale were determined by both TLC and the microchromatographic technique. Less than 10 mg of scale and even single punch biopsy specimens sufficed for the microchromatographic technique, whereas more than 50 mg of scale were required for TLC. Since the microchromatographic technique can rapidly detect diagnostic biochemical abnormalities from readily obtainable, small tissue samples, this method could eventually supplant or supplement standard lipid biochemical techniques for the diagnosis of cutaneous lipidoses.     

SCANNING ELECTRON MICROSCOPY OF THE STRATUM CORNEUM

Summary.— This report describes studies of stratum corneum from normal subjects and from patients with various scaly disorders, with the scanning electron microscope, using the skin surface biopsy technique.
Normnal squamous cells showed essentially the same structure in different parts of the body; individual squames demonstrated irregular surface folds, convolutions and occasionally a more villous appearance. In dominant ichthyosis vulgaris the squamous cells showed predominantly an irregular fine nodular surface pattern. Similar changes were found in non-bullous ichthyosiform erythroderma. Surface depressions (maxitnum diameter approximately 300 nm) were occasionally seen on squames from bullous ichthyosiform erythroderma. Psoriatic squamous cells showed a more pronounced villous pattern than normal squames, the villi being evenly distributed over the surface of the majority of cells examined; some cells had rather flattened villi near their edges.
Possible physiological roles for the structural changes found are discussed.     

Barrier dysfunction and pathogenesis of neutral lipid storage disease with ichthyosis (Chanarin-Dorfman syndrome)

Neutral lipid storage disease with ichthyosis (NLSDI; Chanarin-Dorfman syndrome) is an ichthyosiform syndrome, often associated with mutations in a lipid hydrolase, CGI-58. The presence of oil red O-positive, neutral lipid droplets in tissue biopsies, and/or in leukocytes on blood smears, coupled with a constellation of multisystem abnormalities and a pruritic ichthyosiform erythroderma, are together diagnostic of NLSDI. We investigated the pathogenesis of the ichthyosiform erythroderma in patients from three unrelated kindreds with a clinical diagnosis of NLSDI. Basal permeability barrier function and stratum corneum (SC) integrity were abnormal, but barrier recovery rates were faster than normal, as in atopic dermatitis. The basal barrier abnormality was linked to the secretion of lipid micro-inclusions, first segregated within lamellar bodies (LB), which then form a non-lamellar phase within the SC interstices, shown by combined ruthenium tetroxide post-fixation and lipid-retaining resin-white embedding. With colloidal lanthanum nitrate perfusion, excess water/solute movement was restricted to the SC interstices, and further localized to non-lamellar domains. Phase separation of excess stored lipid provides a unifying pathogenic mechanism not only for NLSDI, but also in several other inherited ichthyosiform disorders of lipid metabolism, such as recessive X-linked ichthyosis and type 2 Gaucher's disease.     

Cutaneous histopathology of Conradi-Hunermann syndrome

The histopathology of the skin in the ichthyosiform erythroderma associated with classical Conradi-Hunermann syndrome has been rarely described. Skin biopsies from 2 infants with the classical features of Conradi-Hunermann syndrome including ichthyosiform erythroderma contained hyperkeratosis, dilated ostia of pilosebaccous structures, and calcium salts in the stratum corneum detectable with special stains. An unusual feature of one case was dilatation of acrosyringeal structures. We hypothesize that dilatation of acrosyringeal structures is analogous to the plugging noted in pilosebaceous units. Taken together, the ichthyosiform erythroderma of Conradi-Hunermann has a distinctive histologic appearance.     

Quantification of stratum corneum ceramides and lipid envelope ceramides in the hereditary ichthyoses

Ceramides (sphingolipids) are the main polar lipids of the stratum corneum and play an important role in skin barrier function, cell adhesion and epidermal differentiation. In view of the function of ceramides in normal skin, this study aimed to assess their levels in patients with various types of hereditary ichthyosis, in which epidermal homeostasis is markedly abnormal. Stratum corneum samples were collected from 80 patients and 23 normal controls, and the intercellular and lipid envelope ceramides were analysed by high-performance thin-layer chromatography. The covalently bound ceramides (ceramides A and B) of the lipid envelope were present in all patients studied, and showed no significant differences from control samples. Total ceramides (ceramides 1–6) were decreased in bullous ichthyosiform erythroderma, which is presumably a secondary phenomenon similar to that seen in patients with atopic dermatitis. Patients with non-erythrodermic lamellar ichthyosis showed a marked decrease in levels of the important acylceramide, ceramide 1, whereas those with other types of autosomal recessive ichthyosis (limited lamellar ichthyosis and non-bullous ichthyosiform erythroderma) had mean levels similar to the controls. Ceramide 1 deficiency may therefore define a subgroup within the autosomal recessive ichthyoses. Sjögren-Larsson syndrome (SLS) shows a deficiency of both acyl-ceramides (ceramides 1 and 6), which would seem likely to disrupt the normal skin barrier function. Furthermore, glucosyl-ceramides (cerebrosides) are known to be deficient in the neural tissue of patients with SLS. The relationship of these ceramide abnormalities to the underlying fatty alcohol oxidoreductase defect remains uncertain, but they may provide an interesting link between the nerve damage and cutaneous abnormalities seen in this rare neurodermatosis.     

Ichthyosis: Mechanisms of Disease

The disorders of cornification (ichthyoses) comprise acquired and inherited disorders characterized clinically by generalized scaling and histologically by hyperkeratosis. They may arise through defects in the production or maintenance of a normal cornified cell compartment, or both. The stratum corneum is composed of protein-enriched and lipid-depleted corneocytes ("bricks") surrounded by an intercellular domain ("mortar") composed of hydrophobic, lipid-enriched membrane bilayers, and containing desmosomes and a limited array of hydrolytic enzymes. Mechanisms whereby a genetic defect involving either the bricks or the mortar may result in abnormal stratum corneum retention are discussed using ichthyosis vulgaris and recessive X-linked ichthyosis as examples. In addition, epidermal hyperproliferation, which floods the cornified cell compartment with incompletely formed units, results in hyperkeratosis. To date, no primary disorders of epidermal hyperproliferation have been defined. Recent work, however, demonstrates that stratum corneum barrier function regulates epidermal DNA synthesis. For example, in essential fatty acid deficiency, barrier dysfunction is responsible at least in part ror the epidermal hyperproliferation. Defective barrier function due to defective lamellar body secretion may also underlie the phenotypic changes after birth in harlequin ichthyosis; that is, from the massive, constrictive hyperkeratosis of the newborn to an exfoliative erythroderma in survivors. The mechanisms whereby specific defects in cornification result in generalized scaling disease are only beginning to be defined. Yet, even at this early stage, the view of the stratum corneum as a tightly organized structure whose function is highly regulated is emerging. Hence, the disorders of cornification should provide important insights into stratum corneum structure and function.     

Ichthyosis

Ichthyoses constitute a large group of cornification disorders that affect the entire integument. The skin is characterized by visible scaling and in many cases by inflammation, for example, in bullous/keratinopathic ichthyosis or Netherton syndrome. From the viewpoint of classification it is useful to distinguish nonsyndromic from syndromic types of ichthyosis. Ichthyosis vulgaris and recessive X-linked ichthyosis are common disorders—often of delayed onset, in contrast to congenital ichthyoses, which belong to the group of rare diseases and present at birth with either the features of collodion membrane or congenital ichthyosiform erythroderma. The diagnostic steps are based on clinical data, analyses such as the steroid sulfatase activity test, skin biopsies, and genetic results. However, the dramatic increase in knowledge about the pathophysiology of these conditions has not led to a curative therapy so far. The therapeutic management is multidisciplinary and involves ichthyosis patient organizations in many countries. The mainstay of treatment remains with moisturizing creams containing, for example, urea, lactic acid and other humectants and keratolytics, regular bathing, and mechanical scale removal. Patients with lamellar ichthyosis or ichthyosiform erythroderma in particular profit from oral therapy with retinoids or retinoic acid metabolism-blocking agents.     

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.     

Harlequin ichthyosis and other autosomal recessive congenital ichthyoses: the underlying genetic defects and pathomechanisms

Autosomal recessive congenital ichthyoses (ARCI) include several severe subtypes including harlequin ichthyosis (HI), lamellar ichthyosis and non-bullous congenital ichthyosiform erythroderma. Patients with these severe types of ichthyoses frequently show severe hyperkeratosis and scales over a large part of the body surface form birth and their quality of life is often severely affected. Recently, research into the pathomechanisms of these severe congenital ichthyoses have advanced dramatically and led to the identification of several causative genes and molecules underlying the genetic defects. To date, seven loci have been identified that are associated with ARCI and, among them, five causative genes and molecules have been detected. The five genes are transglutaminase 1 gene (TGM1), ABCA12, two lipoxygenase genes, ALOXE3 and ALOX12B and ichthyin. One of these components, ABCA12, has recently been shown to be a keratinocyte lipid transporter associated with lipid transport in lamellar granules and loss of ABCA12 function leads to a defective lipid barrier in the stratum corneum, resulting in the HI phenotype. Transglutaminse 1 deficiency was reported to cause a malformed cornified cell envelope leading to a defect in the intercellular lipid layers in the stratum corneum and defective stratum corneum barrier function resulting in an ichthyosis phenotype. Thus, defective intercellular lipid layers are major findings in autosomal recessive congenital ichthyoses. Information concerning ARCI genetic defects and disease pathomechanisms are beneficial for providing better treatments and genetic counseling including prenatal diagnosis for families affect by ichthyoses.     

Expression of stratum corneum chymotryptic enzyme in ichthyoses and squamoproliferative processes

OBJECTIVE: Stratum corneum chymotryptic enzyme (SCCE) is a serine protease, which is thought to play a role in the desquamation of skin via the proteolysis of desmosomes in the stratum corneum. The objective of this study was to investigate the expression of SCCE in ichthyoses and squamoproliferative processes, conditions in which the shedding and replacement of epidermal cells is disrupted. DESIGN: Tissue samples from cases of Netherton's syndrome, congenital ichthyosiform erythroderma, ichthyosis vulgaris, actinic keratosis, squamous cell carcinoma in situ, and invasive squamous cell carcinoma were examined for expression of SCCE using immunohistochemistry. MAIN OUTCOME MEASURES: The slides were qualitatively analyzed for the expression of SCCE by a certified dermatopathologist. RESULTS: In all disease states, we found that the expression of SCCE was absent in areas of parakeratotic stratum corneum of normal thickness. In areas of mixed orthokeratosis and parakeratosis where the stratum corneum was greatly thickened as might correspond clinically to a cutaneous horn, SCCE staining was either absent or focally aggregated without regard to orthokeratosis or parakeratosis. Of note, complete absence of SCCE expression was not observed in any of the cases of ichthyosis examined, nor was there increased expression of SCCE in the atypical cells of the squamoproliferative disorders. CONCLUSIONS: These results suggest that SCCE is abnormally expressed in skin where epidermal cell kinetics are disrupted due to inherited and acquired defects. Further investigation is needed to determine causality between the abnormal expression of SCCE and the altered cell kinetics in these diseases.     

Plasminogen activator inhibitor-2 is expressed in different types of congenital ichthyosis: in vivo evidence for its cross-linking into the cornified cell envelope by transglutaminase-1

BACKGROUND: Plasminogen activator inhibitor-2 (PAI-2), a regulatory serpin of the plasminogen activator (PA) system, has been described as a potential component of the cornified cell envelope (CE). Protease inhibitors are essential for skin homeostasis and in particular for the regulation of the desquamation process. Therefore, an aberrant expression of PAI-2 could be involved in the pathogenesis of certain cornification disorders. OBJECTIVES: Evaluation of the expression of PAI-2 in different types of congenital ichthyosis, especially in lamellar ichthyosis/nonbullous congenital ichthyosiform erythroderma (LI/NCIE) and in Netherton syndrome (NTS). Demonstration of the functional relationship between PAI-2 and transglutaminase (TGase)-1. PATIENTS AND METHODS: Using immunohistochemistry we evaluated cryosections from individuals suffering from LI/NCIE (n=67), NTS (n=6), ichthyosis-follicularis-atrichia-photophobia syndrome (n=2) and Harlequin ichthyosis (n=1) in comparison with psoriasis vulgaris and healthy skin. Moreover, we assessed the respective TGase-1 activity and the presence of TGase-1 protein. A functional assay was developed to elucidate whether PAI-2 is a substrate for TGase-1. RESULTS: PAI-2 is expressed in different types of congenital ichthyosis and there is a strong correlation between TGase-1 activity and PAI-2 protein signal. Double staining revealed a strong colocalization of TGase-1 activity and PAI-2 protein. The epidermal incorporation of the specific PAI-2 peptide containing a TGase binding site revealed a strong pericellular staining in the stratum granulosum in healthy skin. In contrast, TGase-1-deficient skin showed only a lamellar staining in the stratum corneum. CONCLUSIONS: We provide in vivo evidence that PAI-2 is a substrate of TGase-1. The normal expression of PAI-2 in a large group of TGase-1-proficient LI/NCIE patients makes it rather unlikely that PAI-2 alone is a primary molecular cause of LI/NCIE.     

Lipid composition of outer stratum corneum in hereditary palmoplantar keratodermas

BACKGROUND: The analysis of lipid composition of the outer stratum corneum is a promising approach to study the pathophysiology of inherited disorders of keratinization. OBJECTIVE: The purpose of the study was the search for biochemical alterations of stratum corneum lipids in hereditary palmoplantar keratoderma (PPK). METHODS: Using high-performance thin-layer chromatography, we performed an analysis of all major stratum corneum lipid classes in scales of 29 patients with 8 different types of hereditary PPK. RESULTS: In comparison to the controls, slight differences in the lipid pattern were found in all keratodermas. Reduced amounts of total ceramides and increased levels of free fatty acids were noted in nearly all types. CONCLUSIONS: The study indicates that the abnormal composition of stratum corneum lipids in PPK is probably not caused by genetic defects of the epidermal lipid metabolism, but it appears to represent an epiphenomenon of a disturbed cornification.     

Care of the newborn with ichthyosis

Mendelian disorders of cornification (ichthyosis; MeDOC) often present in the neonatal period with little warning to providers or parents. This report reviews the majority of ichthyoses with congenital findings. The neonatal presentation of many MeDOC often differs from the later phenotype because of the changes in the skin that occur with transition from an intrauterine to extrauterine environment. While differentiation of ichthyosis subtypes in the neonatal period is difficult, there are certain phenotypic groups within which these neonates fall, recognition of which can guide initial work up and treatment. For this report, these are categorized as: exuberant vernix; collodion baby/harlequin ichthyosis (HI); ichthyosiform erythroderma; blistering; and normal skin/xerosis phenotypes.     

Ultrastructural features resembling those of harlequin ichthyosis in patients with severe congenital ichthyosiform erythroderma

Congenital ichthyoses are a group of heterogeneous disorders of cornification. Autosomal recessive congenital ichthyosis (ARCI) can be clinically subdivided into congenital ichthyosiform erythroderma and lamellar ichthyosis. Ultrastructurally, ARCI is classified into four groups: ichthyosis congenita (IC) types I-IV. The genetic background of the ARCI disorders is heterogeneous, but only one disease gene, transglutaminase 1, has been detected so far. We describe six patients with severe congenital ichthyosis from six different Scandinavian families. They could not be classified ultrastructurally into the four IC groups because of atypical findings of electron microscopy. These included abnormal lamellar bodies, alterations in keratohyalin, remnant organelles and lipid inclusions in the upper epidermal cells, which resembled the ultrastructural findings of harlequin ichthyosis (HI), although the HI phenotype was not present at birth. Some clinical features, such as thick scales, erythroderma, alopecia and ectropion were common to all patients. Ichthyosis was usually accentuated in the scalp and four patients had clumped fingers and toes. None of the patients carried the transglutaminase 1 mutation. We conclude that ultrastructural findings resembling those detected in previous HI cases (type 1 and 2) can also be found in patients who do not have classic clinical features of that rare ichthyosis. This may be due to lack of specificity of ultrastructural markers for HI or to its clinical heterogeneity.     

Abnormal lamellar granules in a case of CHILD syndrome

BACKGROUND: A 32-year-old female had cutaneous and musculoskeletal changes consistent with congenital hemidysplasia with ichthyosiform erythroderma and limb defects (CHILD) syndrome. She was born with the dysplastic, shortened right-sided arm and leg. Erythematous, hyperkeratotic lesion occurred on the trunk initially and extended to the right-sided arm and leg. Almost all area of her right-side body except the head and neck was covered by the erythematous lesion with yellow waxy scales, and the distal end of the rudimentary leg showed a verrucous appearance. METHODS AND RESULTS: The histology shared many features with verruciform xanthoma. Electron microscopy revealed vesicular structures in the intercellular spaces of the stratum corneum and vacuoles or vesicular structures in upper prickle cell layer. Some of them can be recognized as abnormal lamellar granules. Within the foamy cells in the papillary dermis, large vacuoles were found. CONCLUSION: These findings suggested that abnormal lipid metabolism involving lamellar granules may be responsible to the skin lesion of CHILD syndrome.     

Abnormal fibrous protein isolated from the stratum corneum of a patient with bullous congenital ichthyosiform erythroderma (BCIE)

Summary The fibrous protein of stratum corneum was isolated from a patient with bullous congenital ichthyosiform erythroderma (BCIE), and its properties characterized using electron microscopy, amino acid analysis and SDS gel electophoresis. Results were compared with the characteristics of the fibrous protein isolated from stratum corneum of normal controls.From 900 mg (dry weight) of stratum corneum, 68 mg of fibrous protein was obtained from the patient, while 178 mg was obtained from the normal control. Structural differences were observed with electron microscopy and chemical differences were shown in the ratio of several amino acids. On SDS electrophoresis, the 55,000 dalton constituent of normal fibrous protein could not be identified in the fibrous protein from this patient. These results suggest that an alteration of the polypeptide composition of fibrous protein from this patient with BCIE occurred, and this alteration induced the morphological and clinical features of this dominant genetic keratinization disorder.This study was supported by a research grant for genetic keratinization disorders (H.O.) from the Ministry of Health and Welfare of Japan and by a research grant for biochemical mechanisms of keratinization (H.O.) from Japan Lydia O'Leary Memorial Foundation in 1978