Acute Acidification of Stratum Corneum Membrane Domains Using Polyhydroxyl Acids Improves Lipid Processing and Inhibits Degradation of Corneodesmosomes

Acute Acidification of Stratum Corneum Membrane Domains Using Polyhydroxyl Acids Improves Lipid Processing and Inhibits Degradation of Corneodesmosomes

Neutralization of the normally acidic stratum corneum (SC) has deleterious consequences for permeability barrier homeostasis and SC integrity/cohesion attributable to serine proteases (SPs) activation leading to deactivation/degradation of lipid-processing enzymes and corneodesmosomes (CD). As an el...

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Published in:Journal of investigative dermatology Vol. 130; no. 2; pp. 500 - 510
Main Authors: Hachem, Jean-Pierre, Roelandt, Truus, Schürer, Nanna, Pu, Xu, Fluhr, Joachim, Giddelo, Christina, Man, Mao-Qiang, Crumrine, Debra, Roseeuw, Diane, Feingold, Kenneth R., Mauro, Theodora, Elias, Peter M.
Format: Journal Article
Language:English
Published: New York, NY Elsevier Inc 01-02-2010
Nature Publishing Group
Elsevier Limited
Subjects:
Animals
Biological and medical sciences
Biopsy
Cell Membrane - metabolism
Dermatology
Desmosomes - metabolism
Disaccharides - pharmacology
Epidermis - drug effects
Epidermis - metabolism
Gluconates - pharmacology
Hydrogen-Ion Concentration
Lactones
Lipids - chemistry
Male
Medical sciences
Membrane Microdomains - metabolism
Mice
Mice, Hairless
Microscopy, Fluorescence - methods
Skin - metabolism
Lipids
Stratum corneum
Dermatology
Acute
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Summary:Neutralization of the normally acidic stratum corneum (SC) has deleterious consequences for permeability barrier homeostasis and SC integrity/cohesion attributable to serine proteases (SPs) activation leading to deactivation/degradation of lipid-processing enzymes and corneodesmosomes (CD). As an elevated pH compromises SC structure and function, we asked here whether SC hyperacidification would improve the structure and function. We lowered the pH of mouse SC using two polyhydroxyl acids (PHA), lactobionic acid (LBA), or gluconolactone (GL). Applications of the PHA reduced the pH at all levels of SC of hairless mouse, with further selective acidification of SC membrane domains, as shown by fluorescence lifetime imaging. Hyperacidification improved permeability barrier homeostasis, attributable to increased activities of two key membrane-localized, ceramide-generating hydrolytic enzymes (β-glucocerebrosidase and acidic sphingomyelinase), which correlated with accelerated extracellular maturation of SC lamellar membranes. Hyperacidification generated “supernormal” SC integrity/cohesion, attributable to an SP-dependent decreased degradation of desmoglein-1 (DSG1) and the induction of DSG3 expression in lower SC. As SC hyperacidification improves the structure and function, even of normal epidermis, these studies lay the groundwork for an assessment of the potential utility of SC acidification as a therapeutic strategy for inflammatory dermatoses, characterized by abnormalities in barrier function, cohesion, and surface pH.
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ISSN:0022-202X
1523-1747
DOI:10.1038/jid.2009.249