Stromal cells as the major source for matrix metalloproteinase-2 in cutaneous melanoma.

Matrix metalloproteinases (MMPs) are essential for tumor progression, invasion and metastases formation. Expression of these proteinases is not only restricted to the tumor cells themselves, but also is found in normal stromal cells. Moreover, immunohistochemistry suggests stromal cells as the major source. To scrutinize this hypothesis we established a slowly growing, syngeneic tumor model using the B16-melanoma cell line B78D14. In vitro analysis demonstrated that B78D14 cells secreted MMP-2, MT1-MMP, and to a lesser degree MMP-9; in addition they expressed both MT1-MMP and EMMPRIN on their surface. In subcutaneous (s.c.) tumors of these cells MMP-2 expression was predominantly present at the tumor-stroma border indicating stromal cells as primary source for this protease in vivo. Indeed, double staining experiments and in situ zymography confirmed that tumor adjacent stromal cells at the invasive front expressed MMP-2 and only at this site activated MMP-2 was detectable. Notably, in an experimental pulmonary metastases model neither tumor nor stromal cells expressed MMP-2, suggesting that the capacity of stromal cells is largely dependent on the surrounding microenvironment.

Expression of matrix metalloproteinases in the microenvironment of spontaneous and experimental melanoma metastases reflects the requirements for tumor formation.

Expression of matrix metalloproteinases (MMPs) and their activation in tumor cells, as well as tumor surrounding stromal cells have been implicated in tumor cell invasion and metastasis. By means of a syngeneic tumor model for either experimental or spontaneous metastases, the differential expression of MMPs and tissue inhibitors of MMPs (TIMPs) in relation to the microenvironment and the way of metastasis induction was characterized. In vitro characterization revealed that increased levels of secreted MMP-2, MMP-9, and TIMP-1 were only detectable in the most aggressive cell line, B16G3.12BM2. Remarkably, active MMP-2 was restricted to this cell line, whereas TIMP-2 and membrane type (MT) 1-MMP expression was comparable in all three of the spontaneously metastasizing melanoma cell lines investigated. In vivo analysis demonstrated that MMP-2, MMP-9, and MT1-MMP were predominantly expressed at the tumor-stroma border of s.c. tumors. Furthermore, functional active MMP-2 was restricted to this invasive front. In spontaneous lymph node or lung metastases, however, MMP-9 was expressed both in the center and the periphery of tumors; these areas were largely negative for MMP-2 and MT1-MMP. Notably, tumor cells of experimental lung metastases did not express MMP-9 at all. These results indicate that expression of MMPs in melanoma metastases is not only influenced by their localization but also the nature of tumor induction, suggesting that individual MMPs serve specific roles during the different stages of metastasis formation.

Analysis of dendritic cell trafficking using EGFP-transgenic mice.

Dendritic cells (DCs) are professional antigen presenting cells, well equipped to initiate an immune response. For effective induction of an immune response, DC should migrate from the periphery to the lymph node to present the antigen to T lymphocytes. Currently, tumor-antigen loaded DCs are used in clinical vaccination trials in cancer patients. To investigate the migratory capacity of DC in vivo, a variety of fluorescent and radioactive labels have been used. Here we introduce a novel tool to study DC migration in vivo: DCs generated from enhanced green fluorescent protein (EGFP)-transgenic mice. DC from EGFP-transgenic mice display typical DC behavior and can be matured without affecting their autofluorescence in vitro. In addition, the continuously produced cytoplasmic EGFP in living cells functions as a viability marker, since EGFP released from dying cells does not stain DC from C57Bl/6 mice upon coculture. In vivo migration studies using EGFP-DC and indium-111-labeled DC were performed to determine the efficiency of i.d. versus s.c. administered DC to reach the draining lymph node. The analysis demonstrates that i.d. injection increases the amount of EGFP-DC/indium-111-labeled DC in the lymph node compared to s.c. injection. Subsequent quantitative, phenotypical and ultrastuctural analysis demonstrate that DC generated from EGFP-transgenic mice are well suited to study the migratory behavior, distribution and phenotype of DC in vivo.

Phenotypical and functional characterization of clinical grade dendritic cells.

Dendritic cells (DC) are the professional antigen presenting cells of the immune system. Therefore, several clinical studies have been initiated in which tumor antigen-loaded DC are used as a vaccine to boost an immune response against malignant tumors in patients with cancer. A prerequisite for DC used in these vaccination studies is not only that they are grown under "Good Manufacturing Practice" but equally important that they retain their functional properties. In an extensive study, various conditions were tested to optimize the maturation and yield of DC grown for clinical use. DC grown in XVIVO-15 medium supplemented with 5% HS yielded the best results, morphologically and phenotypically. Mature DC expressed significant amounts of mature DC markers (CD83) and the costimulatory molecules CD80 and CD86. It was shown that mature and immature DC can be frozen and retain their phenotype and function after thawing. These clinical grade DC secreted high levels of the chemokines dendritic cell chemokine 1 (DC-CK1), interleukin-8 (IL-8), macrophage-derived chemokine (MDC), and thymus and activation-regulated chemokine (TARC). This implicates that these DC can attract naïve T and B cells as well as natural killer cells and memory T cells. Finally, to test their migratory capacity in vivo, (111)In-labeled DC were injected into tumor-free lymph nodes of patients with melanoma. Autoradiographic analysis of the dissected lymph nodes indicated that these DC could migrate into the T cell area of adjacent lymph nodes. In conclusion, a culture procedure was established to generate large numbers of monocyte-derived immature and mature DC that retain their morphologic, phenotypic, and functional characteristics in vitro and can be visualized in situ.