Although calcium ions have been shown to regulate the differentiation of keratinocytes in vitro, the role of divalent cations in vivo is not known. Prior attempts to localize divalent cations in epithelial tissues have been impeded by a lack of specificity of ultrastructural techniques, as well as translocation of precipitates within tissues. The availability of an improved cytochemical method (oxalate-pyroantimonate technique) has facilitated more precise, reliable localization of calcium. When this technique (+/- 10 mM EGTA) was applied to neonatal mouse epidermis, Ca++-containing precipitates localized primarily within the cytosol, mitochondria, and nuclear chromatin of some basal and spinous cells, suggesting a possible relationship of Ca++ with the cell cycle. In the lower granular layer, progressively more Ca++ precipitates appeared intercellularly, with the only intracellular Ca++ localized within mitochondria and lamellar bodies (limiting membranes and discs). The most apical granular cells always demonstrated dense extracellular deposits, and high intracellular Ca++, free in the cytosol. The extruded contents of lamellar bodies, at the granular-cornified layer interface, also demonstrated significant amounts of Ca++-containing precipitates between the lamellar discs. Although some corneocytes in the lower stratum corneum demonstrated intracellular precipitates, most were deviod of Ca++. The striking intercellular Ca++ accumulation in the mid granular layer, coupled with Ca++ influx in the upper granular layer, supports the view that changes in intracellular Ca++ may regulate epidermal differentiation. Finally, the association of Ca++ with lamellar body disc membranes and contents suggests that divalent cations may contribute to both lamellar body secretion and to the formation of intercorneocyte membrane bilayers.
Epidermal permeability barrier homeostasis requires the postsecretory processing of polar lipid precursors into nonpolar lipid products within the stratum corneum (SC) interstices by a family of lipid hydrolases. A specific requirement for beta-glucocerebrosidase (beta-GlcCer'ase), which exhibits a distinct acidic pH optimum, is particularly well documented. Therefore, we sought to determine whether the recovery of the barrier after acute insults requires acidification of the SC. We examined permeability barrier recovery by assessing changes in transepidermal water loss (TEWL), SC membrane ultrastructure utilizing ruthenium tetroxide (RuO4) postfixation, and beta-GlcCer'ase activity by in situ zymography at an acidic vs neutral pH. Barrier recovery proceeded normally when acetone-treated skin was exposed to solutions buffered to an acidic pH. In contrast, the initiation of barrier recovery was slowed when treated skin was exposed to neutral or alkaline pH, regardless of buffer composition. In addition, enhancement of the alkaline buffer-induced delay in barrier recovery occurred with Ca2+ and K+ inclusion in the buffer. Moreover, the pH-dependent alteration in barrier recovery appeared to occur through a mechanism that was independent of Ca(2+)- or K(+)-controlled lamellar body secretion, since both the formation and secretion of lamellar bodies proceeded comparably at pH 5.5 and pH 7.4. In contrast, exposure to pH 7.4 (but not pH 5.5) resulted in both the persistence of immature, extracellular lamellar membrane structures, and a marked decrease in the in situ activity of beta-GlcCer'ase. These results suggest first that an acidic extracellular pH is necessary for the initiation of barrier recovery, and second that the delay in barrier recovery is a consequence of inhibition of postsecretory lipid processing.
Several problems have frustrated the isolation of lamellar bodies (LB) from mammalian epidermis. We obtained pellets enriched in intact LB by utilizing the staphylococcal epidermolytic toxin to provide intact, outer epidermal sheets, by controlled homogenization in a cell disrupter, and by passage of homogenates through a graded series of nuclepore filters (Science 221:962, 1983). Such preparations contained more intact LB than did fractions prepared by a variety of differential or sucrose/metrizamide discontinuous centrifugation methods. Initial characterization of the enzymatic content of this fraction revealed it to be enriched in certain hydrolytic enzymes (acid phosphatase, carboxypeptidase, cathepsin B, acid lipase, sphingomyelinase, and phospholipase A), but strikingly depleted in all sulfatases, beta-glucuronidase, and the non-lysosomal protease, plasminogen activator. Thus, LB show some properties of lysosomes, although certain characteristic lysosomal enzymes are strikingly absent. Lamellar body fractions contained 2-3 times more lipid per unit weight than did homogenates, and were enriched in phospholipids, free sterols, and glycosphingolipids, but not in other neutral lipids or ceramides. In summary, whereas some of the enzymes in LB could participate in the metabolism of LB lipid precursors to hydrophobic barrier constituents, others may attack intercellular constituents, ultimately resulting in desquamation. The lipid profile of these organelles suggests that they deliver precursors of permeability barrier lipids to intercellular domains.
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