The Effects of Human Beta-Defensins on Skin Cells in vitro.

BACKGROUND: Defensins are antimicrobial peptides that exert immunomodulatory and chemotactic functions. Based on these properties and their high expression levels in the skin, they are likely to affect skin inflammation, infection, and wound healing. This may lead to therapeutic applications in (burn) wound healing. OBJECTIVE: We aimed to investigate the effects of human ß-defensins (hBDs) on keratinocytes and fibroblasts, 2 major skin cell types involved in skin regeneration. METHODS: Monolayer keratinocyte and fibroblast cultures were exposed to recombinant hBDs, and we overexpressed hBD2 and hBD3 in keratinocytes of reconstructed epidermal equivalents by lentiviral transduction. The effects were measured by immunohistochemistry, quantitative real-time PCR, and migration assays. Kinome analyses were performed on cultured keratinocytes to investigate the signal transduction events elicited by hBD stimulation. RESULTS: We found that hBD3 induced the expression of cytokines and chemokines in keratinocytes, which was not observed in fibroblasts. hBD2, however, stimulated cell migration only in fibroblasts, which was not found for hBD3. Both defensins are likely to exert receptor-mediated effects in keratinocytes, as witnessed by changes in protein kinase activation following stimulation by hBD2 and hBD3. Kinome analysis suggested that protein kinase C activation was a common event for both defensins. We observed, however, considerable differences in keratinocyte responses between stimulation by exogenous recombinant defensins and endogenous defensins expressed following lentiviral transduction. CONCLUSION: Defensins exert modest biological effects on skin cells that are potentially beneficial in wound healing, but many questions regarding the biological mechanisms of action and relevance for the in vivo situation are still remaining.

An in vitro wound healing model for evaluation of dermal substitutes.

Reepithelialization of skin wounds is essential to restore barrier function and prevent infection. This process requires coordination of keratinocyte proliferation, migration, and differentiation, which may be impeded by various extrinsic and host-dependent factors. Deep, full-thickness wounds, e.g., burns, are often grafted with dermal matrices before transplantation of split-skin grafts. These dermal matrices need to be integrated in the host skin and serve as a substrate for neoepidermis formation. Systematic preclinical analysis of keratinocyte migration on established and experimental matrices has been hampered by the lack of suitable in vitro model systems. Here, we developed an in vitro full-thickness wound healing model in tissue-engineered human skin that allowed analysis of the reepithelialization process across different grafted dermal substitutes. We observed strong differences between porous and nonporous matrices, the latter being superior for reepithelialization. This finding was corroborated in rodent wound healing models. The model was optimized using lentivirus-transduced keratinocytes expressing enhanced green fluorescent protein and by the addition of human blood, which accelerated keratinocyte migration underneath the clot. Our model shows great potential for preclinical evaluation of tissue-engineered dermal substitutes in a medium-throughput format, thereby obviating the use of large numbers of experimental animals.

Modulation of activated leukocyte cell adhesion molecule-mediated invasion triggers an innate immune gene response in melanoma.

Activated leukocyte cell adhesion molecule (ALCAM/CD166) is a progression marker of a variety of cancers, including melanoma, and is a marker for mesenchymal stem cells. ALCAM expression triggers matrix metalloproteinase activity and correlates with the transition between superficial melanoma growth and deep dermal invasion in vivo. We previously showed that manipulating ALCAM functionality could both decrease and increase melanoma invasion, depending on the manner by which ALCAM function was altered. How ALCAM exerts these opposing invasive phenotypes remained elusive. In the present study, we analyzed differences in melanoma cell gene expression in two- and three-dimensional cultures as function of ALCAM-mediated adhesion. We identified a cluster of genes highly responsive to ALCAM functionality and relevant for melanoma invasion. This cluster is characterized by known invasion-related genes similar to L1 neuronal cell adhesion molecule and showed a remarkable induction of several innate immune genes. Unexpectedly, we identified major variations in the expression of genes related to an immunological response when modulating ALCAM function, including complement factors C1r and C1s. The expression and function of these proteinases were confirmed in protein assays and in vivo. Together, our results demonstrate a link between ALCAM functionality and the immune transcriptome, and support the assumption that ALCAM-ALCAM interactions could function as a cell signaling complex to promote melanoma tumor invasion.

Keratinocytes drive melanoma invasion in a reconstructed skin model.

Melanoma progression is a multistep progression from a common melanocytic nevus through the radial growth phase, the invasive vertical growth phase finally leading to metastatic spread into distant organs. Migration and invasion of tumor cells requires secretion of proteases to facilitate remodeling of the extracellular matrix including basement membranes. Here we used a reconstructed skin model to investigate melanoma growth and invasion in vitro. Using this model we show that the dermoepidermal basement membrane prevents the invasion of metastatic melanoma BLM and MV3 cells in the absence of a stratified epidermis. In the reconstructed skin model, matrix metalloproteinase-9, a protease activated early in melanoma development, is secreted by the keratinocytes and subsequently activated by an unknown soluble factor secreted by the melanoma cells. The dynamic interplay between keratinocytes and melanoma cells is further shown by an altered growth pattern of melanoma cells and the finding that a reconstructed epidermis induces invasion. Overall, our findings show that the invasive behavior of melanoma cells is determined by the melanoma cells themselves, but that the interplay between surrounding keratinocytes and the melanoma cells plays an important role in melanoma invasion.

Soluble adhesion molecules in human cancers: sources and fates.

Adhesion molecules endow tumor cells with the necessary cell-cell contacts and cell-matrix interactions. As such, adhesion molecules are involved in cell signalling, proliferation and tumor growth. Rearrangements in the adhesion repertoire allow tumor cells to migrate, invade and form metastases. Besides these membrane-bound adhesion molecules several soluble adhesion molecules are detected in the supernatant of tumor cell lines and patient body fluids. Truncated soluble adhesion molecules can be generated by several conventional mechanisms, including alternative splicing of mRNA transcripts, chromosomal translocation, and extracellular proteolytic ectodomain shedding. Secretion of vesicles (ectosomes and exosomes) is an alternative mechanism mediating the release of full-length adhesion molecules. Soluble adhesion molecules function as modulators of cell adhesion, induce proteolytic activity and facilitate cell signalling. Additionally, adhesion molecules present on secreted vesicles might be involved in the vesicle-target cell interaction. Based on currently available data, released soluble adhesion molecules contribute to cancer progression and therefore should not be regarded as unrelated and non-functional side products of tumor progression.

Tumor marker nucleoporin 88 kDa regulates nucleocytoplasmic transport of NF-kappaB.

Nucleoporin 88 kDa (Nup88) is a tumor marker, overexpressed in various types of cancer. In Drosophila Nup88 (mbo) was reported to selectively mediate the nucleocytoplasmic transport of NF-kappaB, an ubiquitous transcription factor involved in immune responses, apoptosis, and cancer. We addressed the function of Nup88 in mammalian cells. Selective depletion of Nup88 by small interfering RNA (siRNA) inhibited NF-kappaB-dependent reporter gene activation and the nuclear translocation of NF-kappaB without affecting the upstream activation pathway in NIH3T3 cells. In contrast, nuclear translocation of glucocorticoid receptor was not reduced by the depletion of Nup88. In metastatic melanoma cells overexpressing Nup88, constitutive activation of NF-kappaB was found both in nucleus and cytoplasm. Nup88 depletion in these cells reduced TNF-induced nuclear accumulation of NF-kappaB subunits. We conclude that Nup88 regulates the activity of NF-kappaB at the level of nucleocytoplasmic transport. Overexpression of Nup88 in tumor cells may, thus be involved in the constitutive NF-kappaB activation.

Attenuation of melanoma invasion by a secreted variant of activated leukocyte cell adhesion molecule.

Activated leukocyte cell adhesion molecule (ALCAM/CD166/MEMD), a marker of various cancers and mesenchymal stem cells, is involved in melanoma metastasis. We have exploited a secreted NH(2)-terminal fragment, sALCAM, to test the hypothesis that ALCAM coordinates tissue growth and cell migration. Overexpression of sALCAM in metastatic melanoma cells disturbed clustering of endogenous ALCAM and inhibited activation of matrix metalloproteinase-2 (MMP-2). Exposure of HT1080 fibrosarcoma cells to sALCAM similarly inhibited MMP-2, suggesting a broader effect on ALCAM-positive tumor cells. In contrast to the previously reported, promotive effects of an NH(2)-terminally truncated, transmembrane variant (DeltaN-ALCAM), sALCAM impaired the migratory capacity of transfected cells in vitro, reduced basement membrane penetration in reconstituted human skin equivalents, and diminished metastatic capacity in nude mice. Remarkably, L1 neuronal cell adhesion molecule (L1CAM/CD171), another progression marker of several cancers including melanoma, was suppressed upon sALCAM overexpression but was up-regulated by DeltaN-ALCAM. The partially overlapping and opposite effects induced by alternative strategies targeting ALCAM functions collectively attribute an integrative role to ALCAM in orchestrating cell adhesion, growth, invasion, and proteolysis in the tumor tissue microenvironment and disclose a therapeutic potential for sALCAM.

Activated leukocyte cell adhesion molecule (ALCAM/CD166/MEMD), a novel actor in invasive growth, controls matrix metalloproteinase activity.

Activated leukocyte cell adhesion molecule (ALCAM/CD166/MEMD) could function as a cell surface sensor for cell density, controlling the transition between local cell proliferation and tissue invasion in melanoma progression. We have tested the hypothesis that progressive cell clustering controls the proteolytic cascade for activation of gelatinase A/matrix metalloproteinase-2 (MMP-2), which involves formation of an intermediate ternary complex of membrane type 1 MMP (MT1-MMP/MMP-14), tissue inhibitor of metalloproteinase-2 (TIMP-2), and pro-MMP-2 at the cell surface. Surprisingly, truncation of ALCAM severely impaired MMP-2 activation in a nude mouse xenograft model, in which we previously observed diminished primary tumor growth and enhanced melanoma metastasis. Comparative studies of two-dimensional monolayer and three-dimensional collagen-gel cultures revealed that extensive cell-to-cell contacts, wild-type ALCAM, and cell-to-matrix interactions were all indispensable for efficient conversion of pro-MMP-2 to its active form in metastatic melanoma cells. Truncated, dominant-negative ALCAM diminished MMP-2 activation via reduced transcript levels and decreased processing of MT1-MMP. Failure of the proteolytic cascade after selective ALCAM depletion by RNA interference was mainly due to incomplete MT1-MMP processing, which was otherwise promoted by extensive cell-to-cell contacts. These data attribute a novel signaling role to ALCAM in regulation of proteolysis and support its previously postulated sensor function in invasive growth.