Collagen XVII and TIMP-1 in epithelial cell migration

Parikka, M. (Mataleena)

28 November 2003

Abstract Collagen XVII (BP180) is a transmembrane component of hemidesmosomes, which connect basal keratinocytes to the basement membrane. The extracellular domain of collagen XVII is proteolytically shed from the cell surface and released to the extracellular matrix. Apart from its function in epithelial cell adhesion, collagen XVII has been suggested to participate in keratinocyte motility. The collagen XVII expression pattern was studied in wounds of oral mucosa and in epithelial tumors. During re-epithelialization, collagen XVII was expressed in the keratinocytes distal to the wound edge, but not in the leading cells of the epithelial tip. Collagen XVII upregulation was observed in moderate/severe dysplasias of oral mucosa. In follicular ameloblastomas and basal cell carcinomas, collagen XVII expression was reduced in peripheral cells, whereas cytoplasmic staining was detected in central tumor cells. Tongue squamous cell carcinomas showed increased collagen XVII expression in grade II/III tumors, particularly in areas of invasive growth. The results suggest a correlation between overexpression of collagen XVII and the invasive potential of the tumor. For the first time, the role of collagen XVII in the regulation of malignant migration was explored. The presence of COL15, the cell adhesion domain of collagen XVII, induced migration of tongue squamous cell carcinoma cells in transmigration assays. Experiments with specific function-blocking integrin antibodies revealed that the promigratory function of COL15 is mediated by αv and α5 integrins. The role of the matrix metalloproteinase (MMP) family of proteolytic enzymes in wound re-epithelialization was studied in a transgenic mouse model. In these mice, a specific inhibitor of MMPs, TIMP-1, was overexpressed in cells that normally produce MMP-9. The healing of cutaneous wounds was found to be significantly delayed, but not prevented, due to the impaired ability of keratinocytes to migrate to the wound area. These results suggest that collagen XVII may participate in epithelial tumor progression and invasion by promoting migration of tumor cells. Based on the present study, epithelial cell-derived MMPs play a significant role in the migration of wound keratinocytes during re-epithelialization.

carcinoma

collagen XVII

epithelial migration

matrix metalloproteinases

neoplasm invasiveness

odontogenic tumors

re-epithelialization

tissue inhibitor of metalloproteinase-1

wound healing

Skin regeneration in deep second-degree scald injuries either by infusion pumping or topical application of recombinant human erythropoietin gel

Giri, Priya, Ebert, Sabine, Braumann, Ulf-Dietrich, Kremer, Mathias, Giri, Shibashish, Machens, Hans-Günther, Bader, Augustinus

January 2015

Large doses of recombinant growth factors formulated in solution form directly injected into the body is usual clinical practice in treating second-degree scald injuries, with promising results, but this approach creates side effects; furthermore, it may not allow appropriate levels of the factor to be sensed by the target injured tissue/organ in the specific time frame, owing to complications arising from regeneration. In this research, two delivery methods (infusion pumping and local topical application) were applied to deliver recombinant human erythropoietin (rHuEPO) for skin regeneration. First, rHuEPO was given in deep second-degree scald injury sites in mice by infusion pump. Vascularization was remarkably higher in the rHuEPO pumping group than in controls. Second, local topical application of rHuEPO gel was given in deep second-degree scald injury sites in rats. Histological analysis showed that epithelialization rate was significantly higher in the rHuEPO gel-treated group than in controls. Immunohistochemical studies showed that the rHuEPO gel-treated group showed remarkably higher expression of skin regeneration makers than the control group. An accurate method for visualization and quantification of blood vessel networks in target areas has still not been developed up to this point, because of technical difficulties in detecting such thin blood vessels. A method which utilizes a series of steps to enhance the image, removes noise from image background, and tracks the vessels edges for vessel segmentation and quantification has been used in this study. Using image analysis methods, we were able to detect the microvascular networks of newly formed blood vessels (less than 500 μm thickness), which participate in the healing process, providing not only nutrition and oxygen to grow tissues but also necessary growth factors to grow tissue cells for complete skin regeneration. The rHuEPO-treated group showed higher expression of stem cell markers (CD 31, CD 90, CD 71, and nestin), which actively contribute to in-wound-healing processes for new hair follicle generation as well as skin regeneration. Collectively, both rHuEPO group pumping into the systemic circulation system, and injection into the local injury area, prompted mice and rats to form new blood vessel networks in scald injury sites, which significantly participate in the scald healing process. These results may lead to the development of novel treatments for scald wounds.

info:eu-repo/classification/ddc/610

ddc:610