Variations in lipids in different layers of porcine epidermis

The Pseudomonas aeruginosa sphBC genes are important for growth in the presence of sphingosine by promoting sphingosine metabolism

Sphingoid bases, including sphingosine, are important components of the antimicrobial barrier at epithelial surfaces where they can cause growth inhibition and killing of susceptible bacteria. Pseudomonas aeruginosa is a common opportunistic pathogen that is less susceptible to sphingosine than many Gram-negative bacteria. Here, we determined that deletion of the sphBCD operon reduced growth in the presence of sphingosine. Using deletion mutants, complementation, and growth assays in P. aeruginosa PAO1, we determined that the sphC and sphB genes, encoding a periplasmic oxidase and periplasmic cytochrome c, respectively, were important for growth on sphingosine, while sphD was dispensable under these conditions. Deletion of sphBCD in P. aeruginosa PA14, P. protegens Pf-5, and P. fluorescens Pf01 also showed reduced growth in the presence of sphingosine. The P. aeruginosa sphBC genes were also important for growth in the presence of two other sphingoid bases, phytosphingosine and sphinganine. In wild-type P. aeruginosa, sphingosine is metabolized to an unknown non-inhibitory product, as sphingosine concentrations drop in the culture. However, in the absence of sphBC, sphingosine accumulates, pointing to SphC and SphB as having a role in sphingosine metabolism. Finally, metabolism of sphingosine by wild-type P. aeruginosa protected susceptible cells from full growth inhibition by sphingosine, pointing to a role for sphingosine metabolism as a public good. This work shows that metabolism of sphingosine by P. aeruginosa presents a novel pathway by which bacteria can alter host-derived sphingolipids, but it remains an open question whether SphB and SphC act directly on sphingosine.

The skin barrier: An extraordinary interface with an exceptional lipid organization

The barrier function of the skin is primarily located in the stratum corneum (SC), the outermost layer of the skin. The SC is composed of dead cells with highly organized lipid lamellae in the intercellular space. As the lipid matrix forms the only continuous pathway, the lipids play an important role in the permeation of compounds through the SC. The main lipid classes are ceramides (CERs), cholesterol (CHOL) and free fatty acids (FFAs). Analysis of the SC lipid matrix is of crucial importance in understanding the skin barrier function, not only in healthy skin, but also in inflammatory skin diseases with an impaired skin barrier. In this review we provide i) a historical overview of the steps undertaken to obtain information on the lipid composition and organization in SC of healthy skin and inflammatory skin diseases, ii) information on the role CERs, CHOL and FFAs play in the lipid phase behavior of very complex lipid model systems and how this knowledge can be used to understand the deviation in lipid phase behavior in inflammatory skin diseases, iii) knowledge on the role of both, CER subclasses and chain length distribution, on lipid organization and lipid membrane permeability in complex and simple model systems with synthetic CERs, CHOL and FFAs, iv) similarity in lipid phase behavior in SC of different species and complex model systems, and vi) future directions in modulating lipid composition that is expected to improve the skin barrier in inflammatory skin diseases.

Elucidating the molecular landscape of the stratum corneum

Skin is recognized as an intricate assembly of molecular components, which facilitate cell signaling, metabolism, and protein synthesis mechanisms in order to offer protection, regulation, and sensation to the body. Our study takes significant steps to characterize in more detail the complex chemistry of the skin, in particular by generating a better understanding of the uppermost layer, the stratum corneum. Using a state-of-the-art 3D OrbiSIMS technique, we were able to observe the depth distribution, in situ, for a wide range of molecular species. This unprecedented molecular characterization of skin provides information that has the potential to benefit research into fundamental processes, such as those associated with skin aging and disease, and the development and delivery of effective topical formulations.

Characterization of the molecular structure of skin, especially the barrier layer, the stratum corneum, is a key research priority for generating understanding to improve diagnostics, aid pharmaceutical delivery, and prevent environmental damage. Our study uses the recently developed 3D OrbiSIMS technique to conduct in situ analysis of ex vivo human skin tissue and reveals the molecular chemistry of skin in unprecedented detail, as a result of the step change in high mass resolving power compared with previous studies. This characterization exposes the nonhomogeneity of the stratum corneum, both laterally and as a function of depth. Chemical variations relating to fundamental biological processes, such as the epidermal cholesterol sulfate cycle, are visualized using in situ analysis. We are able to resolve the debate around the chemical gradients present within the epidermis, for example, whether palmitic acid is of sebaceous origin or a true component of the stratum corneum. Through in situ depth analysis of cryogenically preserved samples, we are able to propose that it is actually a component of both surface sebum and the intrinsic lipid matrix. This approach also suggests similarity between the epidermis compounds found in human and porcine skin as a function of depth. Since porcine skin is a widely used model for permeation testing this result has clinical relevance. In addition to using this technique for endogenous species, we have used it to demonstrate the permeation of a commercially important antiaging peptide into the human stratum corneum. Due to its chemical similarity to native skin components and exceptionally low effective concentration, this information was previously unattainable.

Glucocerebrosidase: Functions in and Beyond the Lysosome

Glucocerebrosidase (GCase) is a retaining β-glucosidase with acid pH optimum metabolizing the glycosphingolipid glucosylceramide (GlcCer) to ceramide and glucose. Inherited deficiency of GCase causes the lysosomal storage disorder named Gaucher disease (GD). In GCase-deficient GD patients the accumulation of GlcCer in lysosomes of tissue macrophages is prominent. Based on the above, the key function of GCase as lysosomal hydrolase is well recognized, however it has become apparent that GCase fulfills in the human body at least one other key function beyond lysosomes. Crucially, GCase generates ceramides from GlcCer molecules in the outer part of the skin, a process essential for optimal skin barrier property and survival. This review covers the functions of GCase in and beyond lysosomes and also pays attention to the increasing insight in hitherto unexpected catalytic versatility of the enzyme.

Structural Transitions in Ceramide Cubic Phases during Formation of the Human Skin Barrier

The stratum corneum is the outermost layer of human skin and the primary barrier toward the environment. The barrier function is maintained by stacked layers of saturated long-chain ceramides, free fatty acids, and cholesterol. This structure is formed through a reorganization of glycosylceramide-based bilayers with cubic-like symmetry into ceramide-based bilayers with stacked lamellar symmetry. The process is accompanied by deglycosylation of glycosylceramides and dehydration of the skin barrier lipid structure. Using coarse-grained molecular dynamics simulation, we show the effects of deglycosylation and dehydration on bilayers of human skin glycosylceramides and ceramides, folded in three dimensions with cubic (gyroid) symmetry. Deglycosylation of glycosylceramides destabilizes the cubic lipid bilayer phase and triggers a cubic-to-lamellar phase transition. Furthermore, subsequent dehydration of the deglycosylated lamellar ceramide system closes the remaining pores between adjacent lipid layers and locally induces a ceramide chain transformation from a hairpin-like to a splayed conformation.

Epidermal sphingolipids: Metabolism, function, and roles in skin disorders

Mammalian epidermis produces and delivers large quantities of glucosylceramide and sphingomyelin precursors to stratum corneum extracellular domains, where they are hydrolyzed to corresponding ceramide species. This cycle of lipid precursor formation and subsequent hydrolysis represents a mechanism that protects the epidermis against potentially harmful effects of ceramide accumulation within nucleated cell layers. Prominent skin disorders, such as psoriasis and atopic dermatitis, have diminished epidermal ceramide levels, reflecting altered sphingolipid metabolism, that may contribute to disease severity/progression. Enzymatic processes in the hydrolysis of glucosylceramide and sphingomyelin, and the roles of sphingolipids in skin diseases, are the focus of this review.

Analyse biochimique des lipides épidermiques

According to the knowledge acquired some 15 years ago, the cutaneous lipids may be classified into 2 families: the "neutral" lipids, represented by cholesterol, cholesterol esters, cholesterol sulphate, triglycerides, free fatty acids, squalen and alcanes, and the "polar" lipids including phospholipids (phosphatidylcholine, phosphatidylserine, phosphatidylethanolamine, sphingomyeline) and sphingolipids (ceramides I-VII, monohexosylceramides). From the functional point of view, free fatty acids, cholesterol, and ceramides organised in layers are the most important components of intercellular spaces of the stratum corneum. Analytic methods have been recently developed to help understand the structural organisation of these various molecules within the horny layer and their influence on the epidermal barrier function. Raman microspectroscopy or X-ray diffraction are most frequently used. Differential calorimetry and fluorescence or infrared spectroscopy provide complementary information. The principal findings are: lamellar structure depends on the presence of ceramides supplemented by adequate quantities of free fatty acids and cholesterol; ceramide chains interact to provide the ordered structure and ceramide-1 is necessary for stabilisation of lipid layers; cholesterol may regulate the molecular mobility of hydrocarbon chains within the bi-layers. Knowledge of the molecular structure of the barrier lipids finds several applications, e.g.: in pharmacology--conception of new formulations adapted for percutaneous and topical application of drugs; in dermatology--comprehension of physiopathologic mechanisms of various dermatoses; in biotechnology--development of skin substitutes with valid stratum corneum barrier; in cosmetics--choice of best formulations suited for reconstruction of the intercellular lipid substance.

Skin barrier formation: the membrane folding model

We propose that skin barrier morphogenesis may take place via a continuous and highly dynamic process of intersection-free membrane unfolding with a concomitant crystallization of the emerging multilamellar lipid structure representing the developing skin barrier. This implies that the trans-Golgi network and lamellar bodies of the uppermost stratum granulosum cells as well as the multilamellar lipid matrix of the intercellular space at the border zone between stratum granulosum and stratum corneum could be representations of one and the same continuous membrane structure. The profound difference between the earlier Landmann model and the membrane folding model presented here is that the Landmann model includes changes in membrane topology, whereas topology is kept constant during skin barrier formation according to the membrane folding model. The main advantages of the membrane folding model with respect to the Landmann model are the following: (i) smaller energy cost (involves no budding or fusion); (ii) conserves membrane continuity (preserves water compartmentalization and allows control hereof; membrane continuity essential for barrier function); (iii) allows meticulous control (the thermodynamics of the unfolding procedure are related to curvature energy); (iv) faster (milliseconds, as membrane unfolding basically represents a phase transition from cubic-like to lamellar morphology; involves no budding or fusion); (v) membrane folding between lamellar and cubic-like morphologies has been identified in numerous biologic systems; (vi) there is experimental evidence for an "extensive intracellular tubulo-reticular cisternal membrane system within the apical cytosol of the outermost stratum granulosum"; and (vii) may explain the reported plethora of forms, numbers, sizes and general appearances of "lamellar bodies" in transmission electron microscopy micrographs.

Effect of selective lipid extraction from different body regions on epidermal barrier function

PURPOSE

To assess the effects of selective lipid extraction and tape stripping on transepidermal water loss (TEWL) at three body regions in the pig.

METHODS

Lipids were extracted from the abdominal, inguinal. and back regions using three different solvent extraction procedures or cellophane tape stripping (15x) on Yorkshire pigs. Three solvent extraction stages were I, cyclohexane (5 ml for three, 1-min extractions): II, cyclohexane/ethanol (4:1) (5 ml for three, 1-min extractions): and III, cyclohexane/ethanol (1:4) (5 ml for three, 3-min extractions) extracted as follows: Site A, Stage I: Site B, Stage I and II; Site C, Stage I, II and III. Erythema, edema, and TEWL were assessed in control, tape-stripped, and extracted sites at 0, 6, and 24 h. The extracted lipids were analyzed by thin layer chromatography and quantified by densitometry for ceramide, cholesterol, cholesterol esters, fatty acids, and triglycerides.

RESULTS

The change in TEWL (delta TEWL) in 14 of the 15 sites was the highest at 24 h and generally increased with each additional extraction. The greatest changes were present in the back. Each extraction stage removed specific lipids in reproducible quantities that caused the delta TEWL to increase from 0 to 24 h. Lipid removal was verified by transmission electron microscopy. The mean total lipid concentration depended on extraction solvents and body region, and was reproducible across sites and regions at equivalent stages of lipid extraction. Relative proportions of individual lipids extracted were similar across all body regions. Higher concentrations of total lipids were extracted from the back. CONCLUSIONS. These studies demonstrate that extraction of lipids increased the delta TEWL to a level similar to repeated tape stripping at all body sites in the pig. This study suggested that strategies that could biochemically alter epidermal lipid composition may increase absorption of simultaneously administered topical compounds and may be useful to enhance drug delivery.

In vitro characterization of anti-glucosylceramide rabbit antisera

Glucosylceramides (GlcCer) are biosynthetic precursors of glycosphingolipids. They are widely distributed in biological systems where they exhibit numerous biological functions. Studies on the localization of glucosylceramides in different tissues have used biochemical methods only since specific antibodies against GlcCer were not previously available. We have characterized two commercially available rabbit antisera which were prepared against GlcCer of plant origin (1-O-(beta-D-glucopyranosyl)-N-acyl-4-hydroxysphinganine; GlcCer-3) or human origin (1-O-(beta-D-glucopyranosyl)-N-acyl-sphingosine; GlcCer-2) and claimed to be specific for GlcCer. The antisera were also able to detect specifically GlcCer species in crude lipid extracts from human epidermis after separation by thin-layer chromatography. The reagents are sensitive since both antisera reacted at dilutions higher than 1:500 with their homologous antigen in the nanogram range in thin layer immunostaining or dot-blot assays. The antisera are specific for GlcCer although they did not differentiate between GlcCer-2 and GlcCer-3 containing sphingosine or 4-hydroxysphinganine. The antisera also reacted with N-stearoyl-DL-dihydroglucocere-broside indicating that the naturally occurring structural variations in the amino alcohol moiety are not determining the specificity. No crossreactivity was observed with other mono- or diglycosylceramides (galactosylceramides, lactosyl-ceramide), free ceramides or structurally unrelated lipids (cholesterol, sphingomyelin, or phospholipids). Therefore, the glycosylmoiety seems to represent the major antigenic determinant. Finally, the antisera also proved to be useful for the immunohistochemical localization of GlcCer in human epidermis by which earlier biochemical data on the distribution of GlcCer in the various epidermal layers were confirmed.

Identification of two secreted phospholipases A2 in human epidermis

Phospholipases A2 are enzymes that catalyze the release of fatty acids from the sn-2 position of phospholipids. Fatty acids have been suggested to play a key role in the barrier function of the epidermis. The aim of this study was to identify and characterize the type of secretory phospholipase A2 expressed in human epidermis. We report the molecular cloning of two secretory phospholipase A2 in the human epidermis. The first enzyme is identical to human pancreatic type IB phospholipase A2. Western blots revealed a 14 kDa protein localized in the soluble fraction. The second phospholipase A2 is identical to human synovial type IIA enzyme and is localized in the membrane fraction. By semiquantitative reverse transcription-polymerase chain reaction performed on horizontal sections of the epidermis, we found that the mRNAs of both phospholipases A2 were expressed mainly in the basal layers of the epidermis. Our data thus provide evidence for the expression of two secretory phospholipases A2 in human epidermis. The different localization of these two secretory proteins strongly suggests that each enzyme might have a specific role in skin physiology and probably in the barrier function. Taken together, these data validate the reverse transcription-polymerase chain reaction technique performed on thin sections as a first approach to detect gene expression in different layers of the epidermis.

Oral mucosal permeability and stability of transforming growth factor beta-3 in vitro

PURPOSE

To investigate the permeability and localization of topically applied 125I-TGF-beta3 in porcine floor-of-mouth mucosa as a function of concentration and exposure.

METHODS

The 125I-TGF-beta3 diluted in three different vehicles was applied to the tissue samples mounted in perfusion cells maintained at 37 degrees C. Flux and Kp values were calculated from the perfusate collected over a 24 hour period. The quantity of 125I-TGF-beta3 present in the tissue was determined by horizontal sectioning and subsequent counting. The stability of 125I-TGF-beta3 in saliva and in the tissue was analyzed by SDS polyacrylamide gradient gel electrophoresis.

RESULTS

125I-TGF-beta3 was relatively stable in saliva and in the epithelium; approximately 50% of the total counts in the deeper epithelium were resident in the 25kDa TGF-beta3 homodimer. A steady-state flux was reached approximately 6 hours post application and Kp value was 4.0+/-0.6 x 10(-6) (mean +/- sem). Penetration of 125I-TGF-beta3 to the basal cell layer was concentration dependent but reached nanomolar concentrations even after extensive surface rinsing, representing over one-thousand fold the IC50 for epithelial cell cycle arrest.

CONCLUSIONS

The data suggest that topical application of TGF-beta3 to the oral mucosa in an appropriate vehicle can provide effective therapeutic delivery to the tissue.

Electron diffraction provides new information on human stratum corneum lipid organization studied in relation to depth and temperature

The outermost layer of mammalian skin, the stratum corneum, provides the body with a barrier against transepidermal water loss and penetration of agents from outside. The lipid-rich extracellular matrix surrounding the corneocytes in the stratum corneum is mainly responsible for this barrier function. In this study (cryo-) electron diffraction was applied to obtain information about the local lateral lipid organization in the extracellular matrix in relation to depth in human stratum corneum. For this purpose, stratum corneum grid-strips were prepared from native skin in vivo and ex vivo. It was found that the lipid packing in samples prepared at room temperature is predominantly orthorhombic. In samples prepared at 32 degrees C the presence of a hexagonal packing is more pronounced in the outer layers of the stratum corneum. Gradually increasing the specimen temperature from 30 to 40 degrees C induced a further transition from an orthorhombic to a hexagonal sublattice. At 90 degrees C all lipids were present in a fluid phase. These results are in good agreement with previously reported wide angle X-ray diffraction and Fourier transformed infrared spectroscopy studies. We conclude that the lipids in human stratum corneum are highly ordered throughout the stratum corneum and that electron diffraction allows monitoring of the local lipid organization, which contributes to the understanding of stratum corneum barrier function.

Cholesterol sulfate inhibits proteases that are involved in desquamation of stratum corneum

We previously reported that desmosomes play a key role in the adhesion of corneocytes, and their digestion by two types of serine proteases leads to desquamation. Patients with recessive X-linked ichthyosis show hyperkeratosis attributable to desmosomes, associated with an increased content of cholesterol sulfate (CS) and an increased thickness of stratum corneum. In this study, therefore, we examined the possibility that CS provokes the abnormal desquamation, acting as a protease inhibitor. Scaling was induced on mice after topical application of chymostatin and leupeptin. Visible scale was also observed on mice after topical application of CS. We found that the stratum corneum thickness of CS-treated mice was increased in comparison with that of vehicle-treated mice. The thickness of the epidermis and the labeling index with proliferating cell nuclear antigen from CS-treated mice was almost the same as that from vehicle-treated mice. Moreover, in the stratum corneum of CS-treated mice, the content of desmosomes was higher than that in vehicle-treated mice. CS also inhibited the protease-induced cell dissociation of human stratum corneum sheets. In vitro, CS competitively inhibited both types of serine protease: the Ki for trypsin was 5.5 x 10(-6) M and that for chymotrypsin was 2.1 x 10(-6) M. These results indicate that CS retards desquamation by acting as a protease inhibitor. Thus, accumulation of stratum corneum in recessive X-linked ichthyosis may be a result of the inhibition by excessive CS of proteases involved in the dissolution of desmosomes, required for desquamation of the stratum corneum.

Consequences of beta-glucocerebrosidase deficiency in epidermis. Ultrastructure and permeability barrier alterations in Gaucher disease

Hydrolysis of glucosylceramide by beta-glucocerebrosidase results in ceramide, a critical component of the intercellular lamellae that mediate the epidermal permeability barrier. A subset of type 2 Gaucher patients displays ichthyosiform skin abnormalities, as do transgenic Gaucher mice homozygous for a null allele. To investigate the relationship between glucocerebrosidase deficiency and epidermal permeability barrier function, we compared the stratum corneum (SC) ultrastructure, lipid content, and barrier function of Gaucher mice to carrier and normal mice, and to hairless mice treated topically with bromoconduritol B epoxide (BrCBE), an irreversible inhibitor of glucocerebrosidase. Both Gaucher mice and BrCBE-treated mice revealed abnormal, incompletely processed, lamellar body-derived sheets throughout the SC interstices, while transgenic carrier mice displayed normal bilayers. The SC of a severely affected type 2 Gaucher's disease infant revealed similarly abnormal ultrastructure. Furthermore, the Gaucher mice demonstrated markedly elevated transepidermal water loss (4.2 +/- 0.6 vs < 0.10 g/m2 per h). The electron-dense tracer, colloidal lanthanum, percolated between the incompletely processed lamellar body-derived sheets in the SC interstices of Gaucher mice only, demonstrating altered permeability barrier function. Gaucher and BrCBE-treated mice showed < 1% and < 5% of normal epidermal glucocerebrosidase activity, respectively, and the epidermis/SC of Gaucher mice demonstrated elevated glucosylceramide (5- to 10-fold), with diminished ceramide content. Thus, the skin changes observed in Gaucher mice and infants may result from the formation of incompetent intercellular lamellar bilayers due to a decreased hydrolysis of glucosylceramide to ceramide. Glucocerebrosidase therefore appears necessary for the generation of membranes of sufficient functional competence for epidermal barrier function.

Localization of beta-glucosidase activity within keratinizing epithelia

1. Serial frozen sections (10 microns thick) were cut parallel to the plane of the epithelium from skin, hard palate and gingiva of the pig (Sus scrofa), and beta-glucosidase activity was measured in each section. 2. In each of these tissues, there was a low constitutive level of beta-glucosidase activity in the inner portion of the epithelium, and a several-fold increase in activity was observed in the region of the stratum granulosum-stratum corneum interface. 3. The maximum specific activity of beta-glucosidase was significantly lower in gingiva (8 nmol substrate/hr/slice) than in epidermis and palate (15-18 nmol/hr/slice). 4. The increase in expression of beta-glucosidase activity near the stratum granulosum-stratum corneum boundary appears to be intimately involved in the conversion of glucosylceramides to ceramides in the final stages of differentiation. This conversion may be a major determinant of the barrier properties of the stratum corneum.

Sphingolipids are required for mammalian epidermal barrier function. Inhibition of sphingolipid synthesis delays barrier recovery after acute perturbation

Stratum corneum lipids comprise an approximately equimolar mixture of sphingolipids, cholesterol, and free fatty acids, arranged as intercellular membrane bilayers that are presumed to mediate the epidermal permeability barrier. Prior studies have shown that alterations in epidermal barrier function lead to a rapid increase in cholesterol and fatty acid synthesis which parallels the early stages of the repair process. Despite an abundance of indirect evidence for their role in the barrier, the importance of sphingolipids has yet to be demonstrated directly. Whereas sphingolipid synthesis also increases during barrier repair, this response is delayed in comparison to cholesterol and fatty acid synthesis (Holleran, W.M., et al. 1991. J. Lipid Res. 32:1151-1158). To further delineate the role of sphingolipids in barrier homeostasis, we assessed the impact of inhibition of sphingolipid synthesis on epidermal barrier recovery. A single topical application of beta-chloro-L-alanine (beta-CA), an irreversible inhibitor of serine-palmitoyl transferase (SPT), applied to acetone-treated skin of hairless mice resulted in: (a) greater than 75% inhibition of SPT activity at 30 min (P less than 0.001); (b) a global decrease in sphingolipid synthesis between 1 and 3 h (P less than 0.02); (c) reduction of epidermal sphingolipid content at 18 h (P less than 0.01); (d) delayed reaccumulation of histochemical staining for sphingolipids in the stratum corneum; and (e) reduced numbers and contents of lamellar bodies in the stratum granulosum. Finally, despite its immediate, marked diminution of sphingolipid synthesis, beta-CA slowed barrier recovery only at late time points (greater than 6 h) after acetone treatment. This inhibition was overridden by coapplications of ceramides (the distal SPT product), indicating that the delay in repair was not due to non-specific toxicity. These studies demonstrate a distinctive role for epidermal sphingolipids in permeability barrier homeostasis.

Lipids, proteins and corneocyte adhesion

Three factors were examined for their relative contribution to corneocyte cohesion in normal adult pig ear: (1) extracellular lipids derived from membrane-coating granules (MCG); (2) corneosomes (modified stratum corneum desmosomes); and (3) corneocyte covalently bound lipid envelopes. Cohesion strength of the outer stratum corneum was measured directly by cohesometry, then altered by removing MCG lipids with solvents of varying potency. Cohesion changes were related to degree of lipid removal and ultrastructural alterations. Trypsin was also used to see if proteolysis of corneosomes promoted squame shedding. Potent solvents increased cohesion in relation to the amount of MCG lipid extracted. Tighter cohesion was due to fusion of the outer leaflets from covalently bound lipid envelopes on adjacent corneocytes. However, lipid envelopes are unlikely to mediate normal stratum corneum cohesion since MCG lipids play a significant anti-cohesive role preventing their apposition. Mild solvents partially removed MCG lipids causing a slight decrease in cohesion compared with untreated samples. This suggests a minor cohesive role for MCG lipids, consistent with maintaining their barrier function. We believe that corneosomes are the major determinant of stratum corneum cohesiveness because, in untreated skin, both cohesion and the number of corneosomes increased from the surface towards the granular layer. Furthermore, corneosome digestion with trypsin induced superficial squame shedding.

Thin-layer chromatographic analyses of lipids in different layers of porcine epidermis and oral epithelium

Frozen cryosections were cut parallel to the surface of porcine skin and palatal, buccal and floor-of-mouth mucosa so as to provide separate samples representing various epithelial layers. The samples were dried, extracted with chloroform:methanol, and the lipids were chromatographed on silica gel plates in various solvent systems. After charring, lipids were quantified with a scanning densitometer. Overall, greater differences in proportions and distributions of lipid components were evident between keratinized and non-keratinized epithelia than between epidermis and keratinized oral epithelium. For epidermis and palate there was an increase in neutral lipids, including ceramides, from the deeper layers to the surface; ceramides were most abundant in surface layers. In buccal epithelium there was a distinct increase in glycosylceramides toward the surface, and in both non-keratinized regions ceramides were present in only very small amounts. The results suggest that although neutral lipids may be associated with a superficial barrier layer in skin and oral mucosa, there are differences in the composition of this barrier between keratinized and non-keratinized epithelia.

The permeability of oral mucosa

In discussing permeability, we are describing one of the fundamental barrier functions of oral mucosa. Despite assumptions to the contrary, the oral mucosa is not a uniformly, highly permeable tissue like gut, but shows regional variation. The keratinized areas, such as gingiva and hard palate, are least permeable and nonkeratinized lining areas are most permeable. This variation appears to reflect differences in the types of lipid making up the intercellular permeability barrier in the superficial layers of the epithelium. Differences in permeability may be related to regional differences in the prevalence of certain mucosal diseases and can be utilized to advantage for local and systemic drug delivery.

Structural and lipid biochemical correlates of the epidermal permeability barrier

As reviewed in this article, the stratum corneum must now be accorded the respect due to a structurally heterogeneous tissue possessing a selected array of enzymatic activity. The sequestration of lipids to intercellular domains and their organization into a unique multilamellar system have broad implications for permeability barrier function, water retention, desquamation, and percutaneous drug delivery. Yet, the functions and organization of specific lipid species in this membrane system are still unknown. Certain novel insights have resulted from comparative studies in avians and marine mammals. Further elucidation of the molecular architecture and interactions of lipid and nonlipid components of the stratum corneum intercellular domains will be a prerequisite for a comprehensive understanding of stratum corneum function.

Comparison of glycosidase activities in epidermis, palatal epithelium and buccal epithelium

1. beta-Glucosidase, alpha-glucosidase, beta-galactosidase and alpha-mannosidase were measured in epidermis, palatal and buccal epithelium of the pig (Sus scrofa). 2. All three epithelia contained similar alpha-mannosidase activity (1.7-3.2 nmol mg tissue-1 hr-1 at pH 4), and none contained significant alpha-glucosidase. 3. Specific activity of beta-glucosidase was high (9-13 nmol mg tissue-1 hr-1 at pH 4) in epidermis and palate, but activity was low (less than 2 nmol mg tissue-1 hr-1) in buccal epithelium. 4. Only epidermis contained a high level of beta-galactosidase (5.8 nmol mg tissue-1 hr-1). 5. Differences in glycosidase profiles may underlie differences in permeability barrier properties in these epithelia.

Lipid content and water permeability of skin and oral mucosa

It has been claimed that total lipid content may be the critical factor determining the water permeability of skin. The present study examined this relationship in various oral epithelia and epidermis. Epithelia was heat separated from specimens of porcine skin, gingiva, buccal mucosa, palate, and floor of mouth. Lipids were solvent extracted and separated by thin layer chromatography with appropriate standards. The plates were sprayed with sulfuric acid and charred, and the concentration of lipids was determined by densitometry as mg lipid/gm tissue dry weight. Permeability constants were determined for each tissue by using tritiated water in perfusion chambers. When these values were compared over all regions, total lipid did not appear to be related to the permeability of these tissues. However, in the keratinized regions (epidermis, gingiva, and palate) a lower water permeability was related to a greater content of total lipid, nonpolar lipid, ceramide, and glucosylceramide. In non-keratinized tissues, a lower permeability corresponded to increased amounts of an unidentified glycosylceramide. The role of lipid in the permeability barrier of these tissues was further demonstrated by extracting specimens of skin and oral mucosa with chloroform/methanol and then determining Kp values; in both tissue regions, there was a significant increase in water permeability. Thus, although lipid is a component of the water permeability barrier in both skin and oral mucosa, different lipid components subserve this function in keratinized and non-keratinized tissues.

Desmosomes, corneosomes and desquamation. An ultrastructural study of adult pig epidermis

We recently developed a pig skin model to determine the role of corneosomes (modified desmosomes in the stratum corneum) and extracellular lipids in desquamation. The present study provides control morphometric data on the morphological changes in desmosomes and corneosomes leading to desquamation in adult pig epidermis in vivo. The extracellular space within desmosomes gradually widened from the basal to the granular layer, and decreased slightly in the stratum corneum. Mid-dense line broadening, and increased electron density of the distal light layers, coincided with membrane-coating granule extrusion in the outer granular layer. Corneocyte attachment correlated with corneosome distribution. Compactum packing was relatively tight and corneosomes were numerous. Cohesion was mainly peripheral in the disjunctum, and corneosomes were restricted to corneocyte edges. Adhesion had a tongue-and-groove appearance with corneosomes riveting corneocyte peripheries into a lipped groove on adjoining cells. Cells shed by peeling radially towards the lipped groove, and corneosomes decreased from lower to upper disjunctum. Corneosome breakdown commenced with an electron lucent band forming between the plug and lipid envelope. The plug was then unzipped from the lipid envelope and degraded. Corneosomes did not form squamosomes.

Membrane structural alterations in murine stratum corneum: relationship to the localization of polar lipids and phospholipases

During the formation of the mammalian epidermal permeability barrier, lipids are sequestered in the stratum corneum intercellular spaces, transforming from a relatively polar lipid mixture to predominantly nonpolar species. Certain lipid catabolic enzymes, which co-localize with these lipids, may regulate this process. In order to localize the sites within the outer epidermis where polar lipids are catabolized, and their relationship to the alterations in membrane structure that occur in these layers, we compared the biochemical localization of polar lipids, the ultrastructure, and freeze-fracture morphology, as well as the localization of phospholipases within the outer epidermis. Both histochemical staining of frozen sections and biochemical studies of protease- and tape-stripped whole stratum corneum demonstrated small amounts of polar lipids in the stratum compactum, while in contrast, the stratum disjunctum was devoid of both phospholipids and glycosphingolipids. Phospholipase activity was present within lamellar bodies, among secreted lamellar body disks at the granular-cornified layer interface, and within the intercellular spaces of the stratum compactum. Both the depletion of polar lipids from the stratum compactum and deletion of these substances from the stratum disjunctum correlated with sequential changes in membrane structure observed by transmission electron microscopy and freeze-fracture. Thus, a phospholipase-mediated attack on phospholipids (with a parallel assault by other lipid catabolic enzymes on other polar species), may induce both the initial fusion and elongation of lamellar body disks and the subsequent formation of the hydrophobic membrane bilayers found in the mid-to-outer stratum corneum. These studies also may require modification of traditional views of the stratum corneum as a metabolically inert tissue, revealing its intercellular lipid domains to be partially in an active state of flux.

The epidermal permeability barrier

The permeability barrier of the skin which prevents transcutaneous water loss and penetration of harmful drugs from the environment is localized in the horny layer of the epidermis. Multiple lipid bilayers obstructing the intercellular space of the stratum corneum fulfill this function. In contrast to cellular membranes consisting predominantly of phospholipids, these lamellae contain mostly ceramides, cholesterol and free fatty acids. The lamellae are derived from the contents of lamellar granules (LGs) which are synthesized in the viable epidermal layers by the keratinocytes. LGs display stacks of small disks each of which represents a flattened vesicle or liposome. Prior to terminal differentiation, the disks are exocytosed into the intercellular space and fused to form uninterrupted sheetlike lamellae. The singular lipid composition of LG-disks and of stratum corneum-lamellae reflects the multistage process of barrier formation. It also renders these structures well suited to provide for a barrier function.

Effects of essential fatty acid deficiency on epidermal O-acylsphingolipids and transepidermal water loss in young pigs

Linoleate-rich O-acylglucosylceramides and acylceramides are thought to be of major significance for the physical structure and function of the epidermal permeability barrier. In the present investigation, the effects of a linoleate-free diet on O-acylsphingolipids and their associated functions were investigated. Starting at 5 days of age, male pigs were fed diets containing 12% of either lard or hydrogenated coconut oil. Transepidermal water loss was measured with an electrolytic water analyzer at weekly intervals. Pigs were killed at intervals, and epidermal lipids were isolated and analyzed. Fatty acid compositions were determined by gas-liquid chromatography (GLC). Within 2-3 weeks, pigs on the diet containing coconut oil began to display biochemical and physiological symptoms of essential fatty acid deficiency. Within 2 months, this group had extremely scaly skin and transepidermal water loss was elevated to five times that of controls. The progressive increase in transepidermal water loss correlated with replacement of linoleate by oleate in both acylceramide and acylglucosylceramide. The formation of lamellar granules and intercellular lipid sheets in the stratum corneum was not impaired in essential fatty acid deficiency as judged by electron microscopy. These results suggest that the linoleic acid normally found in the O-acylsphingolipids is not essential for formation of the epidermal membrane system. Rather, it appears that the nature of the ester-linked fatty acid in the O-acylsphingolipids regulates the permeability of this membrane system.