The role of the corneocyte lipid envelopes in cohesion of the stratum corneum.

Treatment of isolated stratum corneum with certain detergents results in complete disaggregation of the corneocytes within hours at 45 degrees C without agitation. This is prevented by prior heating of the tissue to 80 degrees C or by solvent extraction of the intercellular lipids. In the present study, electron microscopy revealed that the heated or solvent-extracted tissue was characterized by cell-to-cell contacts that appeared to involve the chemically bound hydroxyceramides which constitute the corneocyte lipid envelope. It is proposed that the irreversible bonding between corneocytes that results from heating or lipid extraction results from interdigitation of the sphingosine chains belonging to those hydroxyceramides that are bound to the corneocyte protein envelope by the omega-hydroxyl function of the 30- and 32-carbon hydroxyacid moieties. Similar interdigitation of adjacent envelopes might be involved in natural stratum corneum cohesion, limited mostly to the periphery of corneocytes where the absence of intercellular lamellae allows the appropriate cell-to-cell contact.

Molecular models of the intercellular lipid lamellae in mammalian stratum corneum.

Intercellular lipid lamellae in the stratum corneum constitute the barrier to water diffusion and may also play a role in cohesion between corneocytes. The lamellae arise from stacks of lamellar disks that are extruded from the granular cells and then fuse edge-to-edge to form sheets. It has been proposed that each lamellar disk is formed from a flattened vesicle, and therefore consists of two lipid bilayers in close apposition. In the present study, electron microscopic examination of ruthenium-tetroxide-fixed stratum corneum from mouse, pig, and human skin revealed that the double bilayer pattern persists in the intercellular lamellae. In addition, distinctive patterning of the intercellular lamellae has led us to propose novel molecular arrangements of the intercellular lipids. These include interlamellar sharing of lipid chains to produce lipid monolayers between pairs of bilayers. The pattern reflects the provenance of the intercellular lamellae from lamellar granule disks and the nonrandom orientation of the lamellar lipids.

Isolation of corneocyte envelopes from porcine epidermis.

Sheets of porcine stratum corneum were dispersed into individual corneocytes after 4 h in a solution consisting of 8 mM N,N-dimethyldodecylamine oxide and 2 mM sodium dodecylsulfate in phosphate-buffered isotonic saline, at 45 degrees C. With continued detergent treatment and moderate sonication, most of the cells lost their keratin contents and were then separated from the remaining intact cells by centrifugation in cesium chloride solution of density 1.280. Electron microscopy showed that the cell envelopes retained both the crosslinked protein envelope and its attached lipid envelope. The dry weight of envelopes was approximately 7% of the estimated dry weight of the original stratum corneum, while the corneocytes surviving intact also amounted to 7% of the starting weight. Mild alkaline hydrolysis of the corneocyte envelopes allowed the extraction of hydroxyceramides amounting to 10% of the dry weight of the envelopes. The procedure therefore provides isolated corneocyte envelopes suitable for studying both the protein and lipid components of this compound sheath.