Several million people are exposed to dioxin and dioxin-like compounds, primarily through food consumption. Skin lesions historically called "chloracne" are the most specific sign of abnormal dioxin exposure and classically used as a key marker in humans. We followed for 5 years a man who had been exposed to the most toxic dioxin, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), at a single oral dose of 5 million-fold more than the accepted daily exposure in the general population. We adopted a molecular medicine approach, aimed at identifying appropriate therapy. Skin lesions, which progressively covered up to 40% of the body surface, were found to be hamartomas, which developed parallel to a complete and sustained involution of sebaceous glands, with concurrent transcriptomic alterations pointing to the inhibition of lipid metabolism and the involvement of bone morphogenetic proteins signaling. Hamartomas created a new compartment that concentrated TCDD up to 10-fold compared with serum and strongly expressed the TCDD-metabolizing enzyme cytochrome P450 1A1, thus representing a potentially significant source of enzymatic activity, which may add to the xenobiotic metabolism potential of the classical organs such as the liver. This historical case provides a unique set of data on the human tissue response to dioxin for the identification of new markers of exposure in human populations. The herein discovered adaptive cutaneous response to TCDD also points to the potential role of the skin in the metabolism of food xenobiotics.
BackgroundSkin atrophy is a common manifestation of aging and is frequently accompanied by ulceration and delayed wound healing. With an increasingly aging patient population, management of skin atrophy is becoming a major challenge in the clinic, particularly in light of the fact that there are no effective therapeutic options at present.Methods and FindingsAtrophic skin displays a decreased hyaluronate (HA) content and expression of the major cell-surface hyaluronate receptor, CD44. In an effort to develop a therapeutic strategy for skin atrophy, we addressed the effect of topical administration of defined-size HA fragments (HAF) on skin trophicity. Treatment of primary keratinocyte cultures with intermediate-size HAF (HAFi; 50,000–400,000 Da) but not with small-size HAF (HAFs; <50,000 Da) or large-size HAF (HAFl; >400,000 Da) induced wild-type (wt) but not CD44-deficient (CD44−/−) keratinocyte proliferation. Topical application of HAFi caused marked epidermal hyperplasia in wt but not in CD44−/− mice, and significant skin thickening in patients with age- or corticosteroid-related skin atrophy. The effect of HAFi on keratinocyte proliferation was abrogated by antibodies against heparin-binding epidermal growth factor (HB-EGF) and its receptor, erbB1, which form a complex with a particular isoform of CD44 (CD44v3), and by tissue inhibitor of metalloproteinase-3 (TIMP-3).ConclusionsOur observations provide a novel CD44-dependent mechanism for HA oligosaccharide-induced keratinocyte proliferation and suggest that topical HAFi application may provide an attractive therapeutic option in human skin atrophy.
Background: Hyaluronic acid (HA) formulations are used for aesthetic applications. Different cross-linking technologies result in HA dermal fillers with specific characteristic visco-elastic properties. Objective: Bio-integration of three CE-marked HA dermal fillers, a cohesive (monophasic) polydensified, a cohesive (monophasic) monodensified and a non-cohesive (biphasic) filler, was analysed with a follow-up of 114 days after injection. Our aim was to study the tolerability and inflammatory response of these fillers, their patterns of distribution in the dermis, and influence on tissue integrity. Methods: Three HA formulations were injected intradermally into the iliac crest region in 15 subjects. Tissue samples were analysed after 8 and 114 days by histology and immunohistochemistry, and visualized using optical and transmission electron microscopy. Results: Histological results demonstrated that the tested HA fillers showed specific characteristic bio-integration patterns in the reticular dermis. Observations under the optical and electron microscopes revealed morphological conservation of cutaneous structures. Immunohistochemical results confirmed absence of inflammation, immune response and granuloma. Conclusion: The three tested dermal fillers show an excellent tolerability and preservation of the dermal cells and matrix components. Their tissue integration was dependent on their visco-elastic properties. The cohesive polydensified filler showed the most homogeneous integration with an optimal spreading within the reticular dermis, which is achieved by filling even the smallest spaces between collagen bundles and elastin fibrils, while preserving the structural integrity of the latter. Absence of adverse reactions confirms safety of the tested HA dermal fillers.
Background: UV irradiation can deplete epidermal vitamin A, thus the hypothesis that UV-induced depletion of vitamin A in sun-exposed skin is involved in the pathogenesis of skin cancers and skin ageing. Objectives: In this study we addressed two questions: (1) Are retinol (ROL) and retinyl esters (RE) – the two predominant forms of vitamin A – equally sensitive to the action of UVB, and (2) could the depletion be prevented by anti-oxidants? Methods: Hairless mice were irradiated with a single UVB dose, corresponding to the maximum of ROL and RE absorption. Retinoid content, enzyme activities catalysing the esterification of ROL (ARAT and LRAT) and the hydrolysis of RE (REH), as well as retinol-binding protein (CRBP-1) expression were determined in the epidermis. Results: A single UVB dose induced a rapid, dose-dependent decrease in both ROL and RE in the epidermis of hairless mice, with partial replenishment after 24 h. The dose-response curve for ROL showed a high sensitivity to UV at doses not exceeding 200 mJ/cm2, followed by a plateau, whereas RE underwent a continuous dose-dependent decrease at UVB doses up to 1 J/cm2. A topical anti-oxidant mixture containing 0.5% ascorbate, 0.25% tocopherol and 0.25% melatonin failed to protect epidermal RE from UVB-induced depletion, whereas it did prevent ROL depletion. ARAT and REH, as well as CRBP-1, were not affected by UVB in these conditions. Conclusion: Vitamin A storage in the epidermis comprises two forms, ROL and RE, that do not show similar sensitivity to acute UVB exposure. ROL stores comprise a UVB-resistant (possibly by CRBP) portion and a UVB-sensitive portion that can be protected by anti-oxidants. RE stores do not show such a pattern.
Retinaldehyde, a natural metabolite of beta-carotene and retinol, has been proposed recently for topical use in humans. Because retinaldehyde does not bind to retinoid nuclear receptors, its biologic activity should result from enzymatic transformation by epidermal keratinocytes into ligands for these receptors, such as all-trans retinoic acid and 9-cis-retinoic acid. In this study, we analyzed by high performance liquid chromatography the type and amounts of tissue retinoids as well as several biologic activities resulting from topical application of either retinaldehyde or all-trans retinoic acid on mouse tail skin. Biologic activities of all-trans retinoic acid and retinaldehyde were qualitatively identical in metaplastic parameters (induction of orthokeratosis, reduction of keratin 65-kDa mRNA, increase in filaggrin and loricrin mRNAs) and hyperplastic parameters (increase in epidermal thickness, increase in bromodeoxyuridine (BrdU)-positive cells, increase in keratin 50-kDa mRNA, and reduction in keratin 70-kDa mRNA). Some quantitative differences, not all in favor of all-trans retinoic acid, were found in several indices. Cellular retinoic acid-binding protein II and cellular retinol-binding protein I mRNAs were increased by both topical retinaldehyde and all-trans retinoic acid. Whereas all-trans retinoic acid, 9-cis-retinoic acid, and 13-cis-retinoic acid were not detectable (limit 5 ng/g) in vehicle-treated skin, 0.05% retinaldehyde-treated skin contained 13 +/- 6.9 ng/g wet tissue of all-trans retinoic acid (mean +/- SD), 12.6 +/- 5.9 ng/g 13-cis-retinoic acid, and no 9-cis-retinoic acid. In contrast, 9-cis-retinoic acid was detectable in 0.05% of all-trans retinoic acid-treated skin, which also contained 25-fold more all-trans retinoic acid and 5-fold more 13-cis-retinoic acid than retinaldehyde-treated skin. Our results show that topical retinaldehyde is transformed in vivo into all-trans retinoic acid by mouse epidermis. The small amounts of ligand for retinoic acid nuclear receptors thus produced are sufficient to induce biologic effects similar to those resulting from the topical application of the ligand itself in much higher concentration.
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