Background: Scleroderma is a fibrotic disorder of unknown etiology that is characterized by excessive collagen synthesis and its deposition in the skin and various internal organs. Objective: To examine whether an overproduction of extracellular matrix molecules is a result of either increased fibroblast proliferation or increased collagen synthesis. As results of clinical trials with 1,25-dihydroxyvitamin D3 (calcitriol) have suggested beneficial effect in the treatment of scleroderma patients, the effects of calcitriol on fibroblasts derived from scleroderma and normal skin has been examined as well. Methods: Cultures of fibroblasts were established from biopsies from involved and uninvolved skin of scleroderma patients and from skin of healthy subjects, and compared with respect to proliferation, collagen synthesis and collagen lattice contraction. Results: No significant differences in cell proliferation and in the extent of fibroblast-induced collagen lattice contraction have been found between scleroderma and normal fibroblasts. Morphologically, fibroblasts derived from scleroderma patients exhibited a disorganized growth pattern in a monolayer culture in contrast to normal fibroblasts. Collagen synthesis tends to be higher in scleroderma fibroblasts as compared with controls. Calcitriol exerted an antiproliferative and antisynthetic effect on fibroblasts, which, however, did not discriminate healthy fibroblasts from fibroblasts derived from involved or uninvolved scleroderma plaques. Conclusions: Our findings suggest that collagen accumulation may not result from increased proliferation or altered dynamic properties of fibroblasts in a scleroderma lesion but from increased collagen biosynthesis. We additionally found that calcitriol does not selectively affect scleroderma fibroblasts.
The composition of free and covalently bound lipids in reconstructed epithelia generated with normal human keratinocytes, HaCaT cells and squamous carcinoma cells was investigated and compared with native skin. Stratum corneum isolated from native human and reconstructed epidermis was subjected to extensive extraction with chloroform-methanol mixtures followed by alkaline hydrolysis to release covalently bound lipids. High-performance thin layer chromatography was used for analysis of solvent-extractable and non-extractable lipids and gas liquid chromatography was performed to assess the fatty acid profile in extractable lipids. In both native and reconstructed tissue covalently bound lipids consisted of omega-hydroxyceramides, omega-hydroxyacids and free fatty acids. Small amounts of omega-hydroxyacids could already be detected in solvent-extractable fractions. omega-Hydroxyceramides consisted of Ceramide A, Ceramide B and a small fraction of unknown ceramides with intermediate polarity. The relative proportions of individual omega-hydroxyceramides were similar in both native and reconstructed stratum corneum. In contrast, differences were found in profiles of both solvent-extractable and non-extractable lipids isolated from epithelia reconstructed with transformed cell lines (HaCaT, SCC-12F2 and SCC-13 cells). Compared with native or reconstructed epidermis, in epithelia reconstructed with transformed cell lines the ceramide content was low, the most polar ceramides were missing and the content of free fatty acids was low. The same holds true for covalently bound lipids that were virtually absent in these epithelia. Marked similarities were demonstrated in the overall lipid composition of free and bound stratum corneum lipids in native epidermis and in epidermis reconstructed with normal human keratinocytes. The observed imbalance in fatty acid profile may account for differences in phase behaviour of stratum corneum lipids.
One of the prerequisites for the use of human skin equivalents for scientific and screening purposes is that their barrier function is similar to that of native skin. Using human epidermis reconstructed on de-epidermized dermis we demonstrated that the formation of the stratum corneum (SC) barrier in vitro proceeds similarly as in vivo as judged from the extensive production of lamellar bodies, their complete extrusion at the stratum granulosum/SC interface, and the formation of multiple broad lamellar structures in the intercorneocyte space. The presence of well-ordered lipid lamellar phases was confirmed by small-angle X-ray diffraction. Although the long periodicity lamellar phase was present in both the native and the reconstructed epidermis, the short periodicity lamellar phase was present only in native tissue. In addition, the SC lipids predominantly formed the hexagonal sublattice. Analysis of lipid composition revealed that all SC lipids are synthesized in vitro. Differences in SC lipid organization in reconstructed epidermis may be ascribed to the differences in fatty acid content and profile indicating that further improvement in culture conditions is required for generation of in vitro reconstructed epidermis with stratum barrier properties of the native tissue.
