Lamellar body-enriched fractions from neonatal mice: preparative techniques and partial characterization

Lamellar bodies as delivery systems of hydrolytic enzymes: implications for normal and abnormal desquamation

Lamellar body secretion results in the delivery of a selected array of hydrolytic enzymes to the extracellular domains of stratum corneum (SC). Deposition and activation of these enzymes in the interstices presumably is associated with the transformation of lamellar body-derived lipids from a relatively polar to a non-polar mixture, as well as the degradation of other non-lipid intercellular substrates. To determine whether abnormal desquamation might result from failure of hydrolytic enzyme delivery to the SC interstices, we localized one catabolic enzyme, acid lipase, previously shown to be a reproducible marker for the lamellar body secretory system, by cytochemical methods within the epidermis of selected human (congenital ichthyosiform erythroderma, CIE) and animal (essential fatty-acid deficient (EFAD) mouse epidermis and mouse tail epidermis) models associated with abnormal scaling or unusual SC retention. In addition, we compared the persistence of desmosomes within normal SC vs. the various models. Normal human and murine epidermis displayed abundant lipase activity both in lamellar bodies (LB) and in association with secreted lamellar body contents in the SC interstices. Despite normal quantities of LB in CIE, EFAD, and mouse tail epidermis, lipase activity was markedly deficient both in LB and in the SC intercellular domains. These studies support the hypothesis that normal desquamation is mediated by enzymatic modulations in lipid and/or protein content of the SC interstices, and that some forms of pathological or excessive scaling may be due to desmosomal persistence that results from defective or limited delivery of lamellar body-derived, hydrolytic enzymes to the SC intercellular domains.

Lamellar body secretory response to barrier disruption

Abundant evidence points to an important role for epidermal lamellar body secretion in permeability-barrier maintenance. However, the response of the lamellar body secretory system to barrier disruption has not been examined. Hence, we examined the lamellar body secretory response at various points after acetone-induced barrier abrogation in hairless mice in air-exposed animals and those occluded with impermeable versus vapor-permeable membranes. Tape-stripped animals served as a control for chemical toxicity. Barrier perturbation with either acetone or tape stripping was followed by rapid secretion of lamellar body contents from the uppermost granular cell layer, leaving the cytosol largely devoid of lamellar bodies. The newly secreted lamellar body contents comprised pleated sheets (not "discs," as previously thought), which unfurled in the intercellular spaces at the granular-cornified cell interface. At this time (15-30 min), the basic unit structure of the lamellar bilayers in the mid-to-upper stratum corneum appeared disorganized and interspersed with large lacunae, reflecting solvent extraction. Nascent lamellar bodies began to reappear in the granular cell cytosol by 30 min and by 360 min the cells displayed a full complement of normal-appearing lamellar bodies. Between 60 and 360 min, the density of lamellar body sheets at the granular-cornified cell interface increased, whereas the membrane bilayers of the outer stratum corneum remained disorganized. New lamellar bilayer units first appeared in the lower stratum corneum between 60 and 180 min, as a result of the transformation of secreted lamellar body sheets and over time these lamellae appeared at more apical locations. Occlusion with a water vapor-impermeable but not a vapor-permeable membrane resulted in a) decreased quantities of lamellar bodies and lamellar body-derived intercellular products; b) formation of lamellar bodies with abnormal internal contents; c) inhibition of lamellar body secretion; and d) inhibition of transformation of lamellar body-derived sheets into lamellar bilayer units. These results demonstrate the central role of the lamellar body-secretory system in barrier repair and homeostasis.

Structural basis for the barrier abnormality following inhibition of HMG CoA reductase in murine epidermis

Recent studies have shown that increased epidermal 3-hydroxy-3-methyl-glutaryl coenzyme A (HMG CoA) reductase activity is crucial for the barrier recovery response that follows solvent-induced barrier perturbation. Upregulation of this enzyme leads to increased cholesterologenesis, formation and secretion of cholesterol-enriched lamellar bodies, and barrier repair. Topical lovastatin-induced inhibition of HMG CoA reductase activity both delays the acute barrier-repair response, as well as leading to a chronic barrier abnormality when applied repeatedly to intact skin. Presently, we assessed the effects of repeated topical applications of two different specific inhibitors of HMG CoA reductase on barrier function, the lamellar body-secretory system, and stratum corneum intercellular domains, with functional and morphologic parameters. Once-daily applications of lovastatin or fluindostatin (XU62-320; Sandoz) for 4-8 d to intact hairless mouse epidermis produced a progressive abnormality in barrier function (transepidermal water loss greater than 2.0-5.0 in treated versus less than 0.25 mg/cm2/h for weakly active analogues or vehicle controls). The barrier defect was preceded by alterations in lamellar body internal structure and a partial failure of lamellar body secretion into the stratum corneum interstices, further confirmed by enzyme cytochemistry. Moreover, the deposition of abnormal lamellar body contents resulted in the formation of clefts in the intercellular spaces at the stratum granulosum-stratum corneum interface, resulting in increased permeability through these domains shown by lanthanum perfusion. Applications of irritants, even when producing a barrier abnormality, did not alter the lamellar body secretory system. Co-applications of cholesterol with the inhibitors reversed both the barrier abnormality and the abnormalities in the lamellar body secretory system that occur with the inhibitor alone. Finally, membrane bilayer structures in the mid-to-outer stratum corneum of inhibitor-treated specimens appeared normal, but the intercellular domains displayed enormously expanded lacunae. However, because similar dilatations also occurred in vehicle-treated samples, they can be attributed to the vehicle alone. These studies provide further evidence that the inhibitor-induced defect in barrier function a) is initiated by inhibition of HMG CoA reductase; b) can be attributed to defects in both lamellar body structure and deposition with resultant abnormalities in intercellular membrane domains in the lower stratum corneum; and c) is further enhanced by permissive effects of the vehicle on the permeability of the outer stratum corneum.

Drug delivery via the mucous membranes of the oral cavity

The delivery of drugs via the mucous membranes lining the oral cavity (i.e., sublingual and buccal), with consideration of both systemic delivery and local therapy, is reviewed in this paper. The structure and composition of the mucosae at different sites in the oral cavity, factors affecting mucosal permeability, penetration enhancement, selection of appropriate experimental systems for studying mucosal permeability, and formulation factors relevant to the design of systems for oral mucosal delivery are discussed. Sublingual delivery gives rapid absorption and good bioavailability for some small permeants, although this site is not well suited to sustained-delivery systems. The buccal mucosa, by comparison, is considerably less permeable, but is probably better suited to the development of sustained-delivery systems. For these reasons, the buccal mucosa may have potential for delivering some of the growing number of peptide drugs, particularly those of low molecular weight, high potency, and/or long biological half-life. Development of safe and effective penetration enhancers will further expand the utility of this route. Local delivery is a relatively poorly studied area; in general, it is governed by many of the same considerations that apply to systemic delivery.

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.

Inhibitors of 3-hydroxy-3-methylglutaryl coenzyme A reductase induce reductase accumulation and altered lamellar bodies in rat forestomach keratinocytes

Lovastatin, an inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase and a potent hypocholesterolemic agent, induces a hyperplastic thickening of the rat forestomach mucosa after oral administration of its active form, a hydroxyacid. We studied the effects of lovastatin on the intracellular accumulation of HMG-CoA reductase immunostaining and the accompanying morphological changes in rat forestomach keratinocytes by immunofluorescence microscopy and transmission electron microscopy (TEM). Administration of lovastatin hydroxyacid induced increases in HMG-CoA reductase levels within forestomach keratinocytes that were dose and time dependent and reversible. The adjacent glandular stomach epithelium did not exhibit induction of reductase. A pharmacologically inactive epimer of lovastatin hydroxyacid did not increase keratinocyte reductase accumulation, and lovastatin lactone induced minimal forestomach reductase. TEM of forestomachs from rats given lovastatin hydroxyacid demonstrated profound alterations in epidermal lamellar bodies (organelles that transport lipids and steroids to the intercellular spaces of the stratum corneum). Treated cells lacked internal lipid lamellae and failed to secrete sheets of lipid material into the intercellular spaces of the stratum corneum. We hypothesize that sustained inhibition of HMG-CoA reductase in rat forestomach keratinocytes induces accumulation of HMG-CoA reductase and hyperplasia by inhibiting sterol synthesis, assembly of lamellar bodies, and formation of intercellular lipid sheets.

Morphogenesis of the cornoid lamella: histochemical, immunohistochemical, and ultrastructural study of porokeratosis

To elucidate the morphogenesis of cornoid lamellae (CL) in porokeratosis, skin lesions of three cases of disseminated superficial actinic porokeratosis and a case of linear porokeratosis were examined. By N-(7-dimethylamino-4-methyl-3-coumarinyl)maleimide staining, SH groups were present in the living layer of the epidermis beneath CL and irregularly disappeared at the bottom of CL, whereas SS linkages appeared in dyskeratotic cells in the living layer and in the irregularly shaped cell membranes of the horny cells. Epidermis beneath CL showed an increased and irregular involucrin expression. Ultrastructurally, the living keratinocytes contained many cytoplasmic vacuoles and had a smaller number of lamellar bodies than normal. Intercellular lamellar sheets were incompletely formed. The dyskeratotic cells and the lower horny cells contained many small vacuoles but formed a marginal band. The horny cells of CL also formed a marginal band and, further, a keratin pattern. CL may be formed by hyperproliferative atypical kertatinocytes which keratinize rapidly and irregularly and show defective desquamation due to the paucity of intercellular lamellar sheets.

Ultrastructural study of the skin in Sjögren-Larsson syndrome

The ichthyosiform skin and the uninvolved skin of a 5-year-old Japanese female with Sjögren-Larsson syndrome were examined by light and electron microscopy to elucidate the keratinization disorder. Light microscopically, the epidermis of the ichthyosiform skin showed acanthosis, papillomatosis and hyperkeratosis. The horny cells had a basket-weave appearance. The granular cell layer was slightly thickened. Slight round cell infiltration and vascular dilatation were seen in the upper dermis. The uninvolved skin was histologically normal. Electron microscopically, in both ichthyosiform and uninvolved skin, abnormal lamellar or membranous inclusions were present in the cytoplasm of horny cells of the epidermis. These inclusions appeared to be derived from some of the lamellar bodies and/or abnormal membranous structures found in the cytoplasm of spinous and granular cells. Mitochondria in the epidermal basal cells were more numerous in the ichthyosiform skin than in the uninvolved skin. These findings indicate that, whether the skin is involved or not, the epidermis of the patient with this disorder may always have a structural abnormality, which may be genetically determined. Local environmental factors may play a role in inducing the acanthosis and papillomatosis of the epidermis.

Sugars protect desmosome and corneosome glycoproteins from proteolysis

Adhesional glycoproteins of desmosomes possess asparagine-linked, complex oligosaccharide side chains. We investigated the potential of these sugars to protect the core proteins of desmosomes and corneosomes (modified stratum corneum desmosomes) against proteolysis. Isolated pig ear epidermis was exposed sequentially to individual hydrolases, and their effect monitored ultrastructurally. Two major steps were employed: (1) glycosidases, to remove stepwise the sugars in a typical complex oligosaccharide chain; and (2) proteolysis using both endopeptidases and an exopeptidase. Controls were exposed to the same sequence of buffers, but without enzymes. Proteases alone induced no major changes in desmosomes or corneosomes compared with controls. Glycosidases alone, or proteases followed by glycosidases, caused mild fragmentation of the desmosomal interspace, but no widening. However, dramatic changes occurred when glycosidase treatment was followed by proteolysis. The interspace of both desmosomes and corneosomes was extensively digested, and consequently widened, causing loose packing of the epidermis. These findings indicate that sugars are potentially anti-proteolytic in both desmosomes and corneosomes. Sugars may, therefore, be a factor in preventing premature desquamation, by protecting desmosomes and corneosomes against extracellular proteases derived from membrane-coating granules.

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.

The lovastatin-treated rodent: a new model of barrier disruption and epidermal hyperplasia

Recent studies have linked epidermal cholesterol synthesis with maintenance of the permeability barrier. To assess directly the importance of cholesterol synthesis, we applied lovastatin, a potent inhibitor of cholesterol synthesis, to hairless mouse skin. Transepidermal water loss (TEWL) began to increase after four to six daily applications. Co-application of cholesterol blocked the expected increase in TEWL, demonstrating the importance of cholesterol for development of the lesion. The histology of lovastatin-treated skin revealed epidermal hyperplasia, accompanied by accelerated DNA synthesis. Whereas cholesterol synthesis initially was reduced in lovastatin-treated epidermis, with further treatment cholesterol synthesis normalized, while fatty acid synthesis accelerated greatly. Although the total free sterol content of lovastatin-treated epidermis remained normal, the fatty acid content increased coincident with barrier disruption. Finally, morphologic abnormalities of both lamellar body structure and their deposited, intercellular contents occurred coincident with the emerging biochemical abnormalities. Thus, the abnormal barrier function in this model can be ascribed to an initial inhibition of epidermal sterol synthesis followed by an alteration in cholesterol and fatty acid synthesis, leading to an imbalance in stratum corneum lipid composition and abnormal membrane bilayer structure.

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.

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.

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.

Enzymatic distinction between two subgroups of autosomal recessive lamellar ichthyosis

It has been proposed that the autosomal recessive lamellar ichthyoses may be divided into two subgroups, the erythrodermic (EARLI) and non-erythrodermic (NEARLI) forms. We report measurements of the enzymes beta-glucosidase, a recently described phosholipase, a short-chain carboxylesterase ("butyrase"), and a long-chain carboxylesterase ("palmitase") in aqueous extracts of scales from patients diagnosed according to clinical and micromorphologic criteria, and show that beta-glucosidase and phospholipase tend to be lower in the EARLI group, whereas butyrase is relatively low in the NEARLI group. The internal ratio of either butyrase/glucosidase or butyrase/phospholipase yields a clear separation of the two subgroups, supporting the concept of heterogeneity in this group of diseases.

Change in sphingomyelinase activity in human epidermis during aging

We have investigated the change in activity of sphingomyelinase in human whole epidermis during aging. The sphingomyelinase activity gradually decreased with the aging process; that of people aged eighty decreased to one fourth of that of people aged twenty in same area. This result indicates that the lipid metabolism may be altered in the epidermis during aging.

Association of a basic 25K protein with membrane coating granules of human epidermis

Keratinocytes of the upper granular layers contain unique round-to-oval granules, 100-500 nm in diameter, in their peripheral cytoplasm. These granules (known as membrane coating granules [MCG], or lamellar granules) fuse with the apical cell surface of uppermost granular cells and discharge their contents into the intercellular space, where they are believed to play a role in establishing the permeability barrier of the epidermis and possibly in regulating the orderly desquamation of terminally differentiated keratinocytes. Using two monoclonal antibodies originally prepared against hair follicle antigens, we have identified a 25K epidermal protein in association with both MCG-like granules in the peripheral cytoplasm of granular cells as well as MCG-derived intercellular material. This protein is relatively basic (pI greater than 8), largely aqueous soluble, methionine deficient, and is relatively abundant in epidermis (comprising up to approximately 0.1% of soluble proteins). Its distribution is restricted to the granular layer of keratinized (cornified) stratified squamous epithelia. The identification of this protein component opens new avenues for studying the molecular mechanisms underlying the establishment of permeability barrier and/or regulation of desquamation.

Membrane-coating granules are acidic organelles which possess proton pumps

Lysosomes are by definition organelles that maintain an internal acidic pH and contain hydrolytic enzymes. Membrane-coating granules contain a battery of hydrolytic enzymes, in addition to their lamellar discs, and are therefore commonly assumed to be lamellate lysosomes. Although there are data confirming the existence of enzymes in membrane-coating granules, there is no direct evidence to suggest that their internal pH is acidic. As part of a wider program on their role in desquamation, our aim was to determine whether membrane-coating granules are indeed acidic and possess proton pumps. Chloroquine and monensin were selected as the pH markers because both induce swelling of acidic organelles. In four repeat experiments dermatome slices of pig ear skin (2 mm2 x 0.5 mm) were incubated as organ cultures either alone (control) or with 1 mM chloroquine or 25 microM monensin. Ultrastructural observations revealed no swelling in control specimens. In contrast, the inclusion of chloroquine or monensin caused swelling of specific organelles including membrane-coating granules, lysosomes, and trans elements of Golgi stacks, but not mitochondria, rough endoplasmic reticulum, or nuclear envelopes. Swelling of membrane-coating granules and the other organelles was prevented by pretreatment with N,N'-dicyclohexylcarbodiimide, a known inhibitor of lysosomal H+ ATPase activity. These findings suggest that membrane-coating granules actively maintain an acidic interior with the aid of proton pumps. Furthermore, membrane-coating granules are heterogeneous because swelling of the whole population did not commence simultaneously. However, it remains to be determined whether this heterogeneity reflects variations in membrane-coating granule pH, leakiness of their membranes to cations, or the number or activity of their proton pumps.

A light and electron microscopy study of normal human stratum corneum with particular reference to the intercellular space

Intercellular and skin-surface substances, and exfoliating corneocytes, were clearly visualized by both light and electron microscopy. The intercellular space constituted an essential part of the normal human stratum corneum, in the basal and middle zones of which this space was filled with substances producing a compact appearance. The intercellular constituents were a nonhomogeneous substance, intact, single and "compound" lamellar granules and an intensely stained, membrane-like material that in some parts, but not in others, had a lamellar pattern. The artifacts produced by ultrathin sectioning for electron microscopy were too small to provide sufficient explanation for the porous appearance of the superficial zone. More important factors seemed to be enlargement of the intercellular space with decrease in the number of desmosomes and alterations of the intercellular substances, with decrease in the amount of nonhomogeneous substance and transformation of the single and "compound" lamellar granules into single and "compound" vesicular bodies. The hypothesis is advanced that the single and "compound" vesicular bodies together with the decreased amount of nonhomogeneous substance may contribute to maintain the patency of the intercellular space in the superficial zone (stratum disjunctum), thereby facilitating absorption of surface-applied agents into the stratum corneum by some shunt mechanism, while the content of the intercellular space in the basal and middle zones (stratum compactum) forms the principal barrier to free diffusion.

Skin lipid content during early fetal development

Although little is known about changes in the lipid composition of the skin during fetal development, information regarding the developmental sequence of fetal skin lipid content could be important for understanding the emergence of epidermal barrier function, as well as providing baseline criteria for prenatal diagnosis of certain inherited disorders of cornification. In these studies, epidermis was separated from dermis in fetal skin samples ranging from 50 to 140 d, estimated gestational ages (EGA), and its lipid composition was analyzed by quartz rod microchromatography/flame-ionization and thin layer chromatography. Lipid biochemical data were correlated with developmental milestones observed by electron microscopy (morphologic studies). The lipid composition of epidermal and dermal fractions from skin samples between 50 and 110 d EGA was similar, with both tissues exhibiting a predominance of free sterols and phospholipids. After 110 d EGA dermis became enriched in triglycerides, corresponding to the progressive development of adipocytes after this time. EGA epidermis after 110 d was enriched not only in triglycerides, but also sterol esters. Moreover, ceramides and glycosphingolipids also became increasingly prominent, changes that were greatest in epidermis from older fetuses and from cephalad regions. These changes in epidermal lipid composition corresponded morphologically to the progressive emergence of both folliculocentric epidermal cornification and sebaceous gland development.

Density-dependent variations in the lipid content and metabolism of cultured human keratinocytes

Cultured human foreskin keratinocytes have been utilized extensively to study modulations in protein content during epidermal differentiation. In this study we examined their usefulness as a model system for differentiation-linked changes in lipid content and metabolism. First-to-third passage keratinocytes were grown in 10% fetal calf serum on a mitomycin-treated 3T3 feeder layer and harvested at intervals before, during, and after reaching confluence for determination of lipid, protein, and DNA content. Lipid synthesis, determined as acetate incorporation into lipid, was most active in pre-confluent cultures and at all times closely paralleled the growth activity of the cultures. Post-confluent cultures were characterized by an increase in total lipid content and by increased triglyceride content and synthesis. Pulse-chase studies demonstrated that labeling of the triglyceride pool was labile and suggested that even in post-confluent cultures, triglycerides provide a fatty acid reservoir for phospholipid biosynthesis. A novel band, which co-migrated with monoalkyldiacylglycerol in two solvents systems was present in confluent and post-confluent cultures, but absent in pre-confluent cultures. Sphingolipids constituted less than 10% of total lipid at all stages of growth, and cholesterol sulfate was present only in small quantities. These studies illustrate the relationship of lipid synthesis to growth and demonstrate that human foreskin keratinocytes, cultured under standard conditions, reproduce incompletely the lipid composition of epidermis in vivo.

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.

A unique phospholipase A2 in human epidermis: its physiologic function and its level in certain dermatoses

It is now well established that epidermis, like many other tissues, contains a phospholipase A2 that is responsible for the initiation of the arachidonic acid cascade. Here we report that human epidermis also contains a second, quite distinct enzyme of the phospholipase A2 group, which is unique in its extreme activity against phospholipids in true solution. It also differs from the classic cutaneous enzyme in that (a) its activity is not reduced by pretreatment of the skin with corticosteroids in vivo nor by treatment of the epidermal homogenate with alkaline phosphatase in vitro, and (b) its activity is reduced, rather than increased, in the lesions of inflammatory diseases such as psoriasis. The enzyme seems to occur mainly in fully differentiated keratinocytes, its level being low in the basal cell layer of epidermis and in keratinocytes cultured in vitro. On the basis of these observations, we suggest that this new phospholipase A2 is responsible for the degradation of phospholipids that accompanies the terminal keratinization process.

Low density lipoprotein receptor expression on keratinocytes in normal and psoriatic epidermis

Biochemical and morphologic studies on the interaction of low density lipoprotein (LDL) with cultured normal keratinocytes and squamous carcinoma cells have shown a negative correlation between LDL receptor activity and terminal differentiation of the epidermal cells [Ponec M et al, J Invest Dermatol 83:436-440, 1984 and Vermeer, BJ et al, J Invest Dermatol 86:195-200, 1986]. Whether such in vitro studies pertain to the epidermis in vivo is not known. To obtain information on the distribution of LDL receptors in the epidermis in situ, morphologic studies were performed using LDL-gold as an ultrastructural marker. When freshly isolated mouse and human epidermal cells were incubated with LDL-gold complexes, only keratinocytes with the morphologic characteristics of basal cells showed binding and uptake of LDL-gold. No LDL receptor activity was found on Langerhans cells, melanocytes or highly differentiated keratinocytes. Since cell separation techniques can destroy receptors, the staphylococcal epidermolytic toxin was utilized to produce intercellular and intra-epithelial splitting of the epidermis. In preparations of both normal mouse and human epidermis, LDL-gold binding was restricted to basal cells and a few suprabasal keratinocytes. In contrast, in psoriatic epidermis, and to a lesser extent, essential fatty acid-deficient mouse epidermis, cells in the stratum spinosum showed abundant LDL-gold binding. Thus LDL-gold may be a useful marker for epidermal differentiation.

Avian sebokeratocytes and marine mammal lipokeratinocytes: structural, lipid biochemical, and functional considerations

In terrestrial mammals, stratum corneum lipids derive from two sources: deposition of lamellar body lipids in stratum corneum interstices and excretion of sebaceous lipids onto the skin surface, resulting in a two-compartment ("bricks and mortar") system of lipid-depleted cells surrounded by lipid-enriched intercellular spaces. In contrast, intracellular lipid droplets, normally not present in the epidermis of terrestrial mammals, are prominent in avian and marine mammal epidermis (cetaceans, manatees). We compared the transepidermal water loss, ultrastructure, and lipid biochemistry of the viable epidermis and stratum corneum of pigeon apterium, fledgling (featherless) zebra finches, painted storks, cetaceans, and manatees to those of humans and mice. Marine mammals possess an even more extensive lamellar-body secretory system than do terrestrial mammals; and lamellar-body contents, as in terrestrials, are secreted into the stratum corneum interstices. In cetaceans, however, glycolipids, but not ceramides, persist into the stratum corneum; whereas in manatees, glycolipids are replaced by ceramides, as in terrestrial mammals. Acylglucosylceramides, thought to be critical for lamellar-body deposition and barrier function in terrestrial mammals, are present in manatees but virtually absent in cetaceans, a finding that indicates that they are not obligate constituents of lamellar-body-derived membrane structures. Moreover, cetaceans do not elaborate the very long-chain, saturated N-acyl fatty acids that abound in terrestrial mammalian acylglucosylceramides. Furthermore, cold-water marine mammals generate large, intracellular neutral lipid droplets not found in terrestrial and warm-water marine mammals; these lipid droplets persist into the stratum corneum, suggesting thermogenesis, flotation, and/or cryoprotectant functions. Avians generate distinctive multigranular bodies that may be secreted into the intercellular spaces under xerotic conditions, as in zebra fledglings; ordinarily, however, the internal lamellae and limiting membranes deteriorate, generating intracellular neutral lipid droplets. The sphingolipid composition of avian stratum corneum is intermediate between terrestrials and cetaceans (approximately equal to 50% glycolipids), with triglycerides present in abundance. In the midstratum corneum of avians, neutral lipid droplets are released into the interstices, forming a large extracellular, lipid-enriched compartment, surrounding wafer-thin corneocytes, with a paucity of both lipid and keratin ("plates-and-mortar" rather than the "bricks-and-mortar" of mammals).(ABSTRACT TRUNCATED AT 400 WORDS)

Variations in lipids in different layers of porcine epidermis

Frozen cryosections, 8 microns thick, were cut parallel to the surface of porcine skin so as to provide separate samples representing various epidermal layers. These samples were dried, extracted with chloroform-methanol mixtures, and the lipids chromatographed on silica gel plates in different solvent systems. After spraying with sulfuric acid and charring, lipids were quantified using a scanning densitometer. It was thus possible to determine lipid concentrations in 12 consecutive epidermal layers, extending 96 microns into the skin. The phospholipids that were characterized all decreased in concentration toward the surface, whereas the neutral lipids and ceramides all increased. Glucosylceramide and acylglucosylceramide reached a peak concentration in the stratum granulosum and then decreased in the surface layers. Cholesterol sulfate reached a maximum concentration in the deeper stratum corneum and then abruptly decreased in the surface layer. These changes in patterns of lipid concentration are consistent with current theories regarding the formation of a water barrier in the stratum corneum that is composed mainly of neutral lipids, and with a possible function of cholesterol sulfate in cellular adhesion in the stratum corneum.

Epidermal permeability barrier: transformation of lamellar granule-disks into intercellular sheets by a membrane-fusion process, a freeze-fracture study

Freeze-fracture replication of lamellar granules and intercellular sheets of the horny layer in mouse, chicken, and snake epidermis reveals a pattern of serial fracture faces which is highly suggestive of polar lipids in a bilayer configuration. The occurrence of alternating wide and narrow fracture faces separated by intervening steps supports the view that epidermal barrier bilayers display lipid asymmetry similar to membranes. Within the lamellar granules, bilayers arrange to form disks which in fact are equivalent to flattened unilamellar liposomes. Stacking of the disks in turn gives rise to the lamellar pattern. After exocytosis into the intercellular space, the disks are arranged parallel to the cell membranes. In tangentially fractured specimens, the cleavage plane jumps back and forth from the plasma membrane to a disk-bilayer, thereby giving rise to the known phenomenon of EF-ridges (on the extracellular fracture face) and PF-grooves (in the plasmatic fracture face) which both represent the level of the plasma membrane sur- or subjacent to the aisles between disks. Concomitantly with the upward movement of the keratinocytes, the ridges and grooves become narrower until they fade away by the second or third cell layer of the stratum corneum. This phenomenon is explained by the fusion of adjacent disks at their highly curved brims due to a mechanism similar to the process of membrane fusion which causes the formation of wide, uninterrupted sheets.

Cytochemical and biochemical localization of lipase and sphingomyelinase activity in mammalian epidermis

Despite a wealth of new information on epidermal lipids and their role in permeability barrier function and desquamation, little is known about the location of the enzymes that regulate their catabolism. In this study we have localized lipase (triacylglycerol hydrolase) and sphingomyelinase in the outer epidermis simultaneously by cytochemical and cell fractionation techniques. Aldehyde-fixed tissues (100-microns slices) incubated in either Tween 85 or triolein plus taurocholate/calcium chloride-containing buffer, pH 7.2 or 4.5, were then exposed to lead to form insoluble soaps, and processed for electron microscopy. Simultaneously, cell homogenates and isolated lamellar body fractions were incubated with methylumbelliferyl oleate under similar conditions, with released, free methylumbelliferone serving as an index of lipase activity. On electron microscopy and cell fractionation, both lipase and sphingomyelinase were localized primarily to intercellular domains in the stratum corneum. In the stratum granulosum lipases were found, both ultrastructurally and biochemically, in lamellar bodies and ultrastructurally in both the perinuclear cistern and mitochondria. In summary, these studies: by demonstrating lipid-catabolic enzymes in the intercellular domains of the stratum corneum, lend further support to the 2-compartment model of the stratum corneum; provide new information about the location of lipid-catabolic enzymes in differentiating epidermis; and provide insights about how lipids are processed during permeability barrier formation and desquamation.

Avian epidermal differentiation: role of lipids in permeability barrier formation

Though avian skin is known to possess a highly lipogenic epidermis, little is known about its permeability barrier function. We correlated epidermal barrier function, fine structure and lipid biochemistry in the pigeon, Columbia livia, and compared these features with terrestrial mammalian systems. Whereas barrier function, as assessed by transepidermal water loss was not as efficient as in mammals, both groups shared certain morphological features including substantial compartmentalization of lipids in stratum corneum intercellular domains. Avian intercellular lipids derive from extrusion of intracellular non-membrane-bound droplets from lowermost corneocytes, rather than by secretion of lamellar discs from multigranular bodies, as previously reported in some avians, and in mammals. Instead, both the internal lamellae and the limiting membranes of multigranular bodies appear to degenerate, leading to the formation of non-membrane-bound droplets. The lipid content of avian epidermis and stratum corneum demonstrates important similarities to terrestrial mammals, i.e. abundant sphingolipids, a paucity of phospholipids, and abundant neutral lipids, but also certain striking differences, i.e. persistence of glycosphingolipids and triglycerides into the stratum corneum. Thus, avian stratum corneum forms a two-compartment system of lipid-depleted cells embedded in non-polar-lipid enriched intercellular domains, analogous to mammals. But, in contrast to mammals, the highly attenuated corneocytes of avians, which results from a paucity of keratin filaments, produce a 'straws-and-mortar' tissue, rather than the 'bricks-and-mortar' tissue of mammals.