BACKGROUND/ PURPOSE: In a multi-project research line, we are currently testing whether a morphologically and functionally near normal epidermis can be cultured from human sweat gland (SG) cells and be used as a skin substitute. The present study focuses on the stratum corneum of the epidermis that assumes a vital barrier function for the skin. The main process in the formation of the cornified cell envelope in human epidermis, i.e. crosslinking of proteins and lipids, is catalyzed by several transglutaminases (TG). Therefore, we compared the expression patterns of various TG and their substrates in SG-derived versus keratinocyte-derived epidermal substitutes. METHODS: Sweat gland cells, keratinocytes, and fibroblasts were isolated from human skin samples and cultivated separately to generate epidermal substitutes. These were transplanted onto the back of athymic rats. After 2 weeks, the transplants were excised and analyzed histologically as well as by indirect immunofluorescence. We looked at the expression of TG1, 3, 5, and their substrates involucrin and loricrin (=markers of epidermal differentiation) in SG-derived and keratinocyte-derived skin substitutes as well as in normal skin. RESULTS: The SG cell-derived epidermis was near normal anatomically, formed a cornified cell envelope and demonstrated TG1, 3, and 5 as well as involucrin and loricrin expression patterns similar to those found in keratinocyte-derived epidermis and normal control skin. CONCLUSION: These findings support the thesis that SG cells have the potential to form a near normal stratified epidermal analog that might be used as a skin substitute. The expression of TG1 and 3, not normally expressed in human SG, suggests the presence of re-programmed SG cells and/or stem cells capable of both de novo generating and maintaining an epidermis.
BACKGROUND/ PURPOSE: In a multi-project research line, we are currently testing whether a morphologically and functionally near normal epidermis can be cultured from human sweat gland (SG) cells and be used as a skin substitute. The present study focuses on the stratum corneum of the epidermis that assumes a vital barrier function for the skin. The main process in the formation of the cornified cell envelope in human epidermis, i.e. crosslinking of proteins and lipids, is catalyzed by several transglutaminases (TG). Therefore, we compared the expression patterns of various TG and their substrates in SG-derived versus keratinocyte-derived epidermal substitutes. METHODS: Sweat gland cells, keratinocytes, and fibroblasts were isolated from human skin samples and cultivated separately to generate epidermal substitutes. These were transplanted onto the back of athymic rats. After 2 weeks, the transplants were excised and analyzed histologically as well as by indirect immunofluorescence. We looked at the expression of TG1, 3, 5, and their substrates involucrin and loricrin (=markers of epidermal differentiation) in SG-derived and keratinocyte-derived skin substitutes as well as in normal skin. RESULTS: The SG cell-derived epidermis was near normal anatomically, formed a cornified cell envelope and demonstrated TG1, 3, and 5 as well as involucrin and loricrin expression patterns similar to those found in keratinocyte-derived epidermis and normal control skin. CONCLUSION: These findings support the thesis that SG cells have the potential to form a near normal stratified epidermal analog that might be used as a skin substitute. The expression of TG1 and 3, not normally expressed in human SG, suggests the presence of re-programmed SG cells and/or stem cells capable of both de novo generating and maintaining an epidermis.
Authors: Luca Pontiggia; Thomas Biedermann; Martin Meuli; Daniel Widmer; Sophie Böttcher-Haberzeth; Clemens Schiestl; Jörg Schneider; Erik Braziulis; Irene Montaño; Claudia Meuli-Simmen; Ernst Reichmann Journal: J Invest Dermatol Date: 2008-08-21 Impact factor: 8.551
Authors: Erik Braziulis; Thomas Biedermann; Fabienne Hartmann-Fritsch; Clemens Schiestl; Luca Pontiggia; Sophie Böttcher-Haberzeth; Ernst Reichmann; Martin Meuli Journal: Pediatr Surg Int Date: 2011-03 Impact factor: 1.827
Authors: Andreas Daniel Weber; Luca Pontiggia; Thomas Biedermann; Clemens Schiestl; Martin Meuli; Ernst Reichmann Journal: Pediatr Surg Int Date: 2011-03 Impact factor: 1.827
Authors: Clemens Schiestl; Thomas Biedermann; Erik Braziulis; Fabienne Hartmann-Fritsch; Sophie Böttcher-Haberzeth; Margarete Arras; Nikola Cesarovic; Flora Nicolls; Carsten Linti; Ernst Reichmann; Martin Meuli Journal: Pediatr Surg Int Date: 2011-03 Impact factor: 1.827