Localization of ABCA12 from Golgi apparatus to lamellar granules in human upper epidermal keratinocytes

ABCA12 is an ATP-binding cassette transporter and is thought to act as a transmembrane lipid transporter. We reported that deleterious ABCA12 mutations cause a disturbance in lamellar granule (LG) lipid transport in the epidermal granular layer keratinocytes, resulting in harlequin ichthyosis, a severe genodermatosis. Detailed localization of ABCA12 in comparison with glucosylceramide and Golgi apparatus markers were studied in order to obtain clues to clarify the function(s) of ABCA12 in human skin. We performed double-labelling immunofluorescent staining using antibodies against ABCA12, glucosylceramide and two Golgi apparatus markers (TGN46 and GM130) in normal human skin and cultured keratinocytes. Immunogold electron microscopy for ABCA12 and glucosylceramide was studied on postembedding and cryoultrathin sections of normal human skin. Confocal laser scanning microscopy demonstrated that ABCA12 and glucosylceramide co-localized in the granular layer keratinocytes as well as in keratinocytes cultured in high Ca2+ conditions through the Golgi apparatus to the cell periphery. Postembedding immunogold electron microscopy revealed that both ABCA12 and glucosylceramide labellings were associated with the LG of the uppermost granular layer keratinocytes. Using cryoultramicrotomy, lamellar structures in the LG were more clearly observed, and ultrastructural localization of ABCA12 and glucosylceramide was better demonstrated to LG in the uppermost granular layer cells. These results indicate that ABCA12 plays an important role in lipid transport from the Golgi apparatus to LG in human granular layer keratinocytes.     

板层小体在皮肤渗透屏障形成中的作用

一、板层小体表皮内板层小体（lamellar bodies,LB）是位于棘层上部和颗粒层细胞内的椭圆形囊泡或泡管状分泌性细胞器,直径100 ~ 300 nm。LB在角质形成细胞分化时形成,最早出现于表皮棘层上部,到达颗粒层后数量不断增加,在维持皮肤屏障稳态方面具有重要作用［1］。LB还可以存在于皮肤外器官的细胞中,如肺、胃、支气管、口腔等,具有脂质储存和分泌的功能,又被命名为板层颗粒、多LB、被膜颗粒、Odland小体等［2］……     

Investigation of functions of essential fatty acids in the skin

Essential fatty acid-deficient rats develop scaly skin that has impaired barrier properties and lowered concentrations of linoleic and arachidonic acids in phospholipids. Topical linoleic acid restores impaired barrier function to normal (within 5 days) and increases the amount of linoleic acid in skin lecithin, but has no effect on the low levels of arachidonic acid in this phospholipid, or on skin scaliness, during this time. Topical butyl PGE₁ or butyl PGE₂ for 1 week have no effect on scaliness, impaired barrier function or lipids. Also, the effect of linoleic acid on barrier function is seen even when prostaglandin synthesis has been inhibited by repeated administration of indomethacin. Intraperitoneal linoleic acid also repairs barrier function but has no simultaneous effect on scaliness; and arachidonic acid, similarly administered, rapidly heals skin scaliness, without simultaneously repairing barrier function. Hypophysectomized rats, which grossly resemble essential fatty acid-deficient rats (their skin is scaly), exhibit virtually normal skin fatty acids, and skin permeability is normal, but such animals do not synthesize prostaglandins. These date indicat that of the 2 major essential fatty acids of rat skin, linoleic and arachidonic acids, athe former is found esterified to phospholipids of epidermal membrancs and is also important in the maintenance of the cutanecous barrier to water loss, whereas the latter, although also found in phospholipids, plays no part in barrier function. rather, it is important as a precursor of prostaglandins, which are thought to be involved in the regulation of normal cell division and differantiation of the epidermis, and, consequently, the control of skin scaliness. Hypophysectomized rats and essential fatty acid-deficient rats are similar as neither can synthesize adequate prostagladins, the former probably because the multi-enzyme complex of prostaglandin synthetase in faulty, the latter due ot ethe absence of essential fatty acid precursors.     

Basis for the permeability barrier abnormality in lamellar ichthyosis

The basis for the permeability barrier abnormality in lamellar ichthyosis (LI) is not known. LI is caused by mutations in the gene that encodes the enzyme, transglutaminase 1 (TGI), which is responsible for assembly of the cornified envelope (CE). TG1 also has been suggested recently to catalyze the covalent attachment of omega-hydroxyceramides (omega-OHCer) to the CE, forming the corneocyte-lipid envelope (CLE). We first assessed the barrier function and the permeability pathway of the water-soluble tracer, colloidal lanthanum, across the stratum corneum (SC) in patients with LI with absent (n = 4) or low (n = 2) TG1 activity/protein. Increased movement of tracer through the SC correlated with increased transcutaneous water loss, and tracer remained restricted to the SC interstices. Enhanced extracellular permeability, in turn, was explicable by truncation and fragmentation of extracellular lamellar membrane arrays. The resultant clefts in the SC interstices represent the likely pathway for increased water permeability. Moreover, tracer movement remained restricted to the interstices, despite the demonstration of increased corneocyte fragility associated with widespread variations in CE structure. Regardless of variability in CE structure, however, CLE structure and bound omega-OHCer content were normal. The normal CLE in LI may explain both the restriction of tracer to the SC interstices, as well as the presence of foreshortened membrane arrays with near-normal interlamellar dimensions. Finally, the demonstration of a normal CLE in LI also raises questions about the putative role of TG1 in forming the CLE. These results demonstrate: (1) the extracellular nature of increased permeability in LI; (2) discontinuities in extracellular membrane structures that account for the enhanced permeability in LI; (3) that these membrane abnormalities are both associated with and explained by abnormalities in the subjacent CE scaffold; and (4) an intact CLE is present in LI, despite abnormalities in the CE, which may restrict water movement to the SC interstices in LI.     

A cryotransmission electron microscopy study of skin barrier formation

Direct visualization of the skin barrier formation process by cryotransmission electron microscopy of vitreous epidermal sections has been performed. The results obtained differ in many aspects from those of classical chemical fixation electron microscopy. Here we show that (i) a new "organelle or branched tubular structure" containing nonlamellar or partly lamellar material, and closely corresponding in numbers, dimensions, and localization to lamellar bodies of classical chemical fixation electron micrographs, and (ii) a new "ribosome complex-like structure", not preserved in classical electron micrographs, are omnipresent at apparent active sites of skin barrier formation. Evidence that skin barrier formation may not take place via extensive membrane fusion involving discrete lamellar bodies, but rather by a morphologically continuous membrane folding process are: (i) the often clearly nonlamellar content of structures corresponding to lamellar bodies with concomitant visualization of multilamellar membrane structures of the intercellular space; (ii) the "multifolded" appearance of the lipid matrix of the intercellular space; and (iii) the identification of extended "intracellular" multilamellar continuous structures with an optical density profile closely corresponding to that of the lipid matrix of the intercellular space. Based on the cryo-electron microscopic data presented in this study we propose that a membrane transition from cubic-like to multilamellar may take place already inside the "tubuloreticular cisternal membrane system" of upper granular cells recently reported by Elias et al.     

Negative electric potential induces alteration of ion gradient and lamellar body secretion in the epidermis, and accelerates skin barrier recovery after barrier disruption

Previous reports suggested that ion gradients of ions such as calcium and magnesium in the epidermis play a crucial part in skin barrier homeostasis. We hypothesized that external electric potential affects the ionic gradient and skin barrier homeostasis. We demonstrated here that application of a negative electric potential (0.50 V) on hairless mice skin accelerated the barrier recovery approximately 60.7% of the original level within 1 h compared with control (37.5%) after barrier disruption by acetone treatment. Even after the application of a negative potential, the skin showed accelerated repair for 6 h. On the contrary, the skin that was applied a positive potential for 1 h showed a significant delay in barrier recovery (25.3%) than the control. Ultrastructural studies by electron microscopy suggested that the extent of lamellar body exocytosis into the stratum corneum/stratum granulosum interface increased under a negative potential. Magnesium and calcium ion concentrations in the upper epidermis were relatively higher in the negative portion than in the portion where the positive potential was applied. Topical application of these ions on mice skin also accelerated the barrier recovery. These results suggest that the external electric potential affects the ionic gradients in the epidermis and also influences the skin barrier homeostasis.     

Molecular skin barrier models and some central problems for the understanding of skin barrier structure and function

A better understanding of the structure and function of the human skin barrier is a prerequisite for a more rational design of transdermal drug administration systems. The study of biological structural organisation is, however, confronted with many difficulties, and interpretations of skin barrier-related data should therefore be done with caution. The recently developed 'single gel-phase model' constitutes an attempt to interpret structural and functional skin barrier data from a biophysical standpoint.     

Alterations of immune functions in barrier disrupted skin by UVB irradiation

BACKGROUND: While immunologic events elicited by acute barrier disruption or UVB irradiation have been studied in detail, the biological sequel of multiple insults to the skin is not well understood. OBJECTIVE: Since the skin would receive a variety of simultaneous stimuli in daily life, we tested the effects of sequential treatments with barrier disruption and UVB exposure on skin immunity. METHODS: Earlobes of BALB/c mice received tape-stripping and subsequently low-dose UVB exposure. Control mice were treated with either tape-stripping or UVB. The expression of surface markers and cytokine production in Langerhans cells and keratinocytes and the elicitation response of contact hypersensitivity were compared. RESULTS: By flow cytometry, tape-stripping augmented the expression of MHC class II, CD54, CD80, CD86 and CD40 on Langerhans cells, whereas UVB decreased the expression of some of these molecules. Combination of tape-stripping and UVB induced largely intermediate levels between these two. Upon stimulation with L cells expressing CD40L, Langerhans cells from tape-stripped and UVB-irradiated earlobes strongly transcribed mRNA for interleukin-1beta compared to each treatment. In keratinocytes, tape-stripping or UVB slightly upregulated tumor necrosis factor-alpha and interleukin-1alpha production at both mRNA and protein levels, whereas these two treatments synergistically increased the production of these cytokines. The in vitro hapten-presenting ability of Langerhans cells to trinitrophenyl-immune lymph node T cells ranked first in tape-stripping, second in tape-stripping plus UVB and third in UVB, and so did the intensity of elicitation responses in contact hypersensitivity to a hapten, picryl chloride. CONCLUSION: It is suggested that barrier disruption and UVB antagonize with each other in contact hypersensitivity as a reflection of their effects on Langerhans cell antigen-presenting function, but they synergize in cytokine production by both Langerhans cells and keratinocytes.     

Sphingolipids of the stratum corneum and lamellar granules of fetal rat epidermis

Sphingolipid profiles have been determined for whole epidermis, a subcellular fraction enriched in lamellar granules, and a fraction enriched with stratum corneum derived from fetal rat skin. In each case, 4 groups of glucosylceramides and 6 groups of ceramides have been identified by thin-layer chromatographic comparison with structurally defined sphingolipids from pig epidermis. The relative amounts of the sphingolipids in each preparation have been quantified by photodensitometry of the charred chromatograms. Lamellar granule sphingolipids had elevated proportions, relative to whole epidermis, of acylceramides, acylglucosylceramides, and a glucosylceramide fraction which may be produced by O-deacylation of the acylglucosylceramides. The fetal stratum corneum-enriched samples contain reduced proportions of all glucosylceramides and acylceramides as compared to lamellar granule lipids. The possible functions of these sphingolipids in the assembly and structure of lamellar granules are discussed.     

Ultrastructure of skin from Refsum disease with emphasis on epidermal lamellar bodies and stratum corneum barrier lipid organization

Classic Refsum disease (RD) is a rare, autosomal recessively-inherited disorder of peroxisome metabolism due to a defect in the initial step in the alpha oxidation of phytanic acid (PA), a C16 saturated fatty acid with four methyl side groups, which accumulates in plasma and lipid enriched tissues (please see van den Brink and Wanders, Cell Mol Life Sci 63:1752–1765, 2006). It has been proposed that the disease complex in RD is in part due to the high affinity of phytanic acid for retinoid X receptors and peroxisome proliferator-activated receptors. Structurally, epidermal hyperplasia, increased numbers of cornified cell layers, presence of cells with lipid droplets in stratum basale and reduction of granular layer to a single layer have been reported by Blanchet-Bardon et al. (The ichthyoses, SP Medical & Scientific Books, New York, pp 65–69, 1978). However, lamellar body (LB) density and secretion were reportedly normal. We recently examined biopsies from four unrelated patients, using both OsO₄ and RuO₄ post-fixation to evaluate the barrier lipid structural organization. Although lamellar body density appeared normal, individual organelles often had distorted shape, or had non-lamellar domains interspersed with lamellar structures. Some of the organelles seemed to lack lamellar contents altogether, showing instead uniformly electron-dense contents. In addition, we also observed mitochondrial abnormalities in the nucleated epidermis. Stratum granulosum-stratum corneum junctions also showed co-existence of non-lamellar and lamellar domains, indicative of lipid phase separation. Also, partial detachment or complete absence of corneocyte lipid envelopes (CLE) was seen in the stratum corneum of all RD patients. In conclusion, abnormal LB contents, resulting in defective lamellar bilayers, as well as reduced CLEs, likely lead to impaired barrier function in RD.     

Dietary sphingolipids improve skin barrier functions via the upregulation of ceramide synthases in the epidermis

Sphingolipids are ubiquitous in eukaryotic organisms and are significant components in foods. It has been reported that treatment with sphingolipids prevents colon cancer, improves skin barrier function and suppresses inflammatory responses. However, the mechanisms for those effects of dietary sphingolipids are not well understood. In this study, to investigate the effects of dietary glucosylceramide (GluCer) and sphingomyelin (SM) on skin function, we characterized the recovery of skin barrier function and the change in sphingolipid metabolism‐related enzymes in the epidermis using a special Mg‐deficient diet–induced atopic dermatitis‐like skin and tape‐stripping damaged skin murine models. Our results show that dietary GluCer and SM accelerate the recoveries of damaged skin barrier functions. Correspondingly, dietary sphingolipids significantly upregulated the expression of ceramide synthases 3 and 4 in the epidermis of the atopic dermatitis‐like skin model (P < 0.05). In the case of cultured cells, the expression of ceramide synthases 2‐4 in normal human foreskin keratinocytes was significantly upregulated by treatment with 0.001–0.1 μm sphingoid bases (sphinganine, sphingosine and trans‐4,cis‐8‐sphingadienine) (P < 0.05). These results suggest that the effects of dietary sphingolipids might be due to the activation of ceramide synthesis in the skin, rather than the direct reutilization of dietary sphingolipids. Our findings provide a novel insight into the mechanisms of the skin barrier improving effect and a more comprehensive understanding of dietary sphingolipids.     

Hyaluronan-CD44 interaction stimulates keratinocyte differentiation, lamellar body formation/secretion, and permeability barrier homeostasis

In this study we investigated whether hyaluronan (HA)-CD44 interaction influences epidermal structure and function. Our data show that CD44 deficiency is accompanied by reduction in HA staining in CD44 knockout (k/o) mouse skin leading to a marked thinning of epidermis versus wild-type mouse skin. A significant delay in the early barrier recovery (following acute barrier disruption) occurs in CD44 k/o versus wild-type mouse skin. To assess the basis for these alterations in CD44 k/o mouse epidermis, we determined that differentiation markers are greatly reduced in the epidermis of CD44 k/o versus wild-type mice, while conversely HA binding to CD44 triggers differentiation in cultured human keratinocytes. CD44 downregulation (using CD44 small interfering RNAs) also inhibits HA-mediated keratinocyte differentiation. Slower barrier recovery in CD44 k/o mice could be further attributed to reduced lamellar body formation, loss of apical polarization of LB secretion, and downregulation of cholesterol synthesis. Accordingly, HA-CD44 binding stimulates both LB formation and secretion. Together, these observations demonstrate new roles for HA-CD44 interaction in regulating both epidermal differentiation and lipid synthesis/secretion, which in turn influence permeability barrier homeostasis. HA-CD44 signaling could comprise a novel approach to treat skin disorders characterized by abnormalities in differentiation, lipid synthesis, and/or barrier function.     

Aging of the skin barrier

The skin barrier is mainly present in the stratum corneum (SC), composed of corneocytes surrounded by intercellular lipid lamellae, and attached by corneodesmosome. The tight junction attached to the lateral walls of keratinocytes in the upper part of the stratum granulosum is also included in the skin barrier. During aging, the following structures and functions of the skin barrier are changed or disturbed: (1) skin barrier structure, (2) permeability barrier function, (3) epidermal calcium gradient, (4) epidermal lipid synthesis and SC lipid processing, (5) cytokine production and response after insults, (6) SC acidity, (7) SC hydration, and (8) antimicrobial barrier. Patients with diabetes also show changes in the skin barrier similar to those in aged skin, and the characteristics of the skin barrier are very similar. Understanding the pathogenic mechanisms of the skin barrier in aging will permit us to develop therapeutic strategies for aged or diabetic skin.     

Influx of calcium and chloride ions into epidermal keratinocytes regulates exocytosis of epidermal lamellar bodies and skin permeability barrier homeostasis

In the nervous system, influx of calcium and chloride ions into neurons regulates the signaling system by excitation and inhibition, respectively. In this study, we demonstrated the effects of the ion influx into epidermal keratinocytes in the permeability barrier repair process of the skin after damage. Topical application of the neurotransmitters glutamate and nicotine, which activate the calcium channel in neurons, delayed the barrier repair after tape stripping. In contrast, the neurotransmitters GABA and glycine, which activate the chloride channel in neurons, accelerated barrier repair. Topical application of the calcium ionophore ionomycin delayed barrier recovery and chloride ionophore 1 accelerated barrier repair after barrier disruption by tape stripping and acetone treatment. Ionomycin increased the intracellular calcium concentration in cultured keratinocytes whereas the chloride ionophore 1 increased the intracellular chloride ion concentration. In vivo light microscopy and electron microscopy observation showed acceleration of the exocytosis of lipid-containing lamellar bodies by the chloride ionophore and delay of the exocytosis by the calcium ionophore. These results suggest that, like the nervous system, influx of calcium and chloride ions into epidermal keratinocytes through ionotropic receptors plays a crucial role in cutaneous barrier homeostasis.     

Regional development of Langerhans cells and formation of Birbeck granules in human embryonic and fetal skin.

The regional development of Langerhans cells (LC) and the formation of Birbeck granules (BG) were examined in human embryonic and fetal skin. Samples were obtained from multiple anatomic sites and stained with anti-CD36, anti-CD1a, and anti-HLA-DR antibody as well as Lag antibody specifically reactive to BG and some vacuoles of human LC. In the first trimester, CD36+ dendritic epidermal cells were identified before the appearance of CD1a+ cells and Lag+ cells. Some of the former co-expressed HLA-DR antigens but not CD1a antigens. In the second trimester, regional variations in LC development were observed. Epidermal LC of palms and soles reached a peak in number in the first trimester but were rarely detected after 18 weeks estimated gestation age (EGA), whereas, in other regions, their number increased with age. In the second trimester, CD1a+ cells and Lag+ cells were also identified in the epidermis, although Lag+ cells appeared later than CD1a+ cells. The Lag+ cells until 17 weeks EGA showed a variety of staining intensities and immunoelectron microscopy revealed that they contained various amounts of Lag-reactive BG. Flow cytometric analysis showed that relative amounts of Lag antigens in LC increased during the second trimester and that fetal LC of 18 weeks EGA expressed the same amounts of HLA-DR, CD1a, and Lag antigens as did adult human LC. In the dermis, in the second trimester, numerous CD36+ cells and HLA-DR+ cells were found, whereas CD1a+ cells and Lag+ cells were rarely detected. Taken together, it is suggested that HLA-DR+ dendritic cells acquire CD1a+ antigens first and then form BG after migration to the epidermis and that fetal LC are phenotypically mature in the second trimester.     

Water, salts and skin barrier of normal skin

Background: We recently reported that open application of seawater for 20 min ameliorated experimental irritant contact dermatitis induced by sodium lauryl sulphate (SLS) cumulative irritation. The efficacy was overall contributed by 500 mm of sodium chloride (NaCI) and 10 mm of potassium chloride (KCl), which are consistent with the each concentration in seawater. Although the usefulness of mineral water with 500 mm NaCl and 10 mm KCl to treat atopic dermatitis (AD) or irritated skin was considered, seawater or its components would induce a feel of stinging in patients with AD. Furthermore, 20 min application was thought to be too long to use everyday as a treatment. Objective: We report the effects of 3 types of mineral water with NaCl and KCl to check the further efficacy with lesser stinging by 2 min application. Results: A mineral water with 250 mm NaCl and 50 mm KCl was the most effective water to prevent disruption of skin barrier and stratum corneum water content after cumulating irritation by SLS. Moreover, improvement of skin dryness and pruritus were shown 2 weeks after the application of the mineral water to a 6‐year‐old boy with atopic dermatitis. Conclusion: Our results suggested the possible usefulness of the mineral water with 250 mm NaCl and 50 mm KCl as the therapy of atopic dermatitis of other chronic dermatitis. Although the mineral water would not cure those skin diseases, it could be an adjunctive therapy. Further controlled clinical trials with evaluation by TEWL and capacitance are required to declare the efficacy of the mineral water in the treatment of patients with AD or other chronic dermatitis.     

Lipid composition and acid hydrolase content of lamellar granules of fetal rat epidermis

Lipids and acid hydrolases have been characterized in a subcellular fraction, enriched with lamellar granules (LG), derived from fetal rat epidermis. This fraction contains 23% glycosyl ceramides and ceramides, 15% free sterols, and 34% phospholipids. The lipid/protein ratio is 2.0. The sterols and sphingolipids were present in proportions similar to those previously reported in stratum corneum. These findings provide direct biochemical evidence for the widely accepted hypothesis that stratum corneum lipids are derived from exocytosis of lamellar granules into the intercellular space. The LG fraction was enriched in certain acid hydrolases including glucosidase, acid phosphatase, phospholipases A, and sphingomyelinase; other acid hydrolases, i.e., amino-glycosidases, glactosidase and aryl sulfatase (pH 5.5), and steroid sulfatase were not preferentially localized in this fraction. By modulation of phospholipids, glycolipids, and proteins in the membrane regions of stratum corneum, the acid hydrolases of LG may play a role relevant to the function and desquamation of stratum corneum.     

Studies on skin surface barrier functions:--skin surface lipids and transepidermal water loss in atopic skin during childhood.

The relationship between skin surface lipids and transepidermal water loss (TWL) was investigated in 22 children with atopic skin. TWL values and casual and replacement lipids were measured by electro-hygrometric and gravimetric methods respectively. Free and total cholesterol and squalene were measured by gas chromatography. The inverse correlations between casual lipids, especially total cholesterol, and TWL exhibited in the normal adult and juvenile skin were not found in the atopic skin. In addition, a significant increase in TWL and decrease in sebaceous lipids was characteristic of atopic skin. In conclusion, the inhibitory action of epidermal cholesterol on TWL is considered to exist only when the skin has a normal keratinization process.     

Decreased levels of covalently bound ceramide are associated with ultraviolet B-induced perturbation of the skin barrier

Although ultraviolet B (UVB) irradiation perturbs the skin barrier, little is known about the mechanism(s) with respect to the metabolism of ceramide (Cer). We examined changes in intercellular lipids in murine stratum corneum following UVB irradiation. A single UVB (75 mJ per cm(2)) irradiation caused a significant increase in transepidermal water loss, which plateaued at day 4. In parallel, covalently bound Cer was significantly decreased with the greatest decrease at days 3-4. In contrast, the levels of other free, non-bound lipids (including Cer or acylceramides) were significantly increased for Cer, or remained unchanged at day 4 compared with non-irradiated controls. RT-PCR analysis demonstrated a significant decrease in mRNA encoding transglutaminase-1 (TGase1). The peak occurred 2-4 d after a single UVB irradiation, a time when covalently bound Cer was significantly downregulated in concert with the disruption of the skin barrier. Furthermore, UVB-induced epidermal hyperplasia occurred to the greatest extent between 2 and 4 d following UVB irradiation. These results suggest that decreases in covalently bound Cer in the stratum corneum are mediated via the downregulation of TGase-1 as well as by the rapid induction of epidermal hyperplasia, which is attributable to the perturbation of the skin barrier induced by UVB irradiation.     

Omega-hydroxyceramides are required for corneocyte lipid envelope (CLE) formation and normal epidermal permeability barrier function

Omega-hydroxyceramides (omega-OHCer) are the predominant lipid species of the corneocyte lipid envelope in the epidermis. Moreover, their omega-esterified-derivatives (acylCer) are major components of the stratum corneum extracellular lamellae, which regulate cutaneous permeability barrier function. Because epidermal omega-OHCer appear to be generated by a cytochrome P450-dependent process, we determined the effects of a mechanism-based inhibitor of omega-hydroxylation, aminobenzotriazole (ABT), on epidermal omega-OH Cer formation and barrier function. We first ascertained that ABT, but not hydroxybenzotriazole (OHBT), a chemical relative with no P450 inhibitory activity, inhibited the incorporation of [14C]-acetate into the omega-OH-containing Cer species in cultured human keratinocytes (68.1% +/- 6.9% inhibition versus vehicle-treated controls; p < 0.001), without altering the synthesis of other Cer and fatty acid species. In addition, ABT significantly inhibited the omega-hydroxylation of very long-chain fatty acids in cultured human keratinocytes. Topical application of ABT, but not OHBT, when applied to the skin of hairless mice following acute barrier disruption by tape-stripping, resulted in a significant delay in barrier recovery (e.g., 38.3% delay at 6 h versus vehicle-treated animals), assessed as increased transepidermal water loss. The ABT-induced barrier abnormality was associated with: (i) a significant decrease in the quantities of omega-OHCer in both the unbound and the covalently bound Cer pools; (ii) marked alterations of lamellar body structure and contents; and (iii) abnormal stratum corneum extracellular lamellar membrane structures, with no signs of cellular toxicity. Furthermore, pyridine-extraction of ABT- versus vehicle-treated skin, which removes all of the extracellular lamellae, leaving the covalently attached lipids, showed numerous foci with absent corneocyte lipid envelope in ABT- versus vehicle-treated stratum corneum. These results provide the first direct evidence for the importance of omega-OHCer for epidermal permeability function, and suggest further that acylCer and/or corneocyte lipid envelope are required elements in permeability barrier homeostasis.