This thesis describes i) the function of an alternatively spliced coagulation factor in hemostasis, ii) the contribution of coagulation factors on cancer progression, and iii) expands our view... Show moreThis thesis describes i) the function of an alternatively spliced coagulation factor in hemostasis, ii) the contribution of coagulation factors on cancer progression, and iii) expands our view on cancer-associated thrombosis. Inhibition of Tissue Factor (TF) signaling with the antibody (Mab-10H10) resulted in decreased tumor initiating capacity and metastasis in a triple negative breast cancer (TNBC) cell line. Since this is a tumor type that is difficult to treat, and has high relapse-rates, it would be of interest to target TF signaling. Dual treatment of TNBC with conventional chemotherapy and Mab-10H10 could result in a positive treatment strategy as both highly proliferative and cancer stem cells are targeted. Furthermore, we provided a proof-of-principle study to search for novel biomarkers in patients with cancer-associated thrombosis in an unbiased manner. Up till now it is challenging to accurately predict those cancer patients with elevated risk of thrombosis. Furthermore, patients with cancer-associated thrombosis have poorer survival. Expansion of this study to validation cohorts and other tumor types will give insights in the underlying molecular mechanism of cancer-associated thrombosis. Eventually, this will aid a better prediction model to select those cancer patients with high risk of thrombosis and those who might benefit from thromboprophylaxis. Show less
This thesis describes the respective contribution of the expression of Tissue factor isoforms full length Tissue Factor (flTF) and alternatively spliced Tissue Factor (asTF) as well as Factor... Show moreThis thesis describes the respective contribution of the expression of Tissue factor isoforms full length Tissue Factor (flTF) and alternatively spliced Tissue Factor (asTF) as well as Factor VII by tumor cells to promote cancer progression. Cohorts of breast, colon, and bone cancer specimens and a multitude of in vitro and in vivo models were used to explore the mechanism behind enhanced cell proliferation and metastasis in in vitro and in vivo models, as well as decreased patient survival associated with TF and FVII expression in cancer patients. Show less
The aim of this thesis is to address how integrin-mediated signaling regulates cellular processes that have profound effects on cell morphology, motility, cancer metastasis, and FN fibrillogenesis,... Show moreThe aim of this thesis is to address how integrin-mediated signaling regulates cellular processes that have profound effects on cell morphology, motility, cancer metastasis, and FN fibrillogenesis, and how these findings can be utilized for relevant medical purposes or advancement of drug discovery. Show less
Tumor cell migration and invasion are essential steps in cancer metastasis. Better understanding of the molecular mechanisms and function of the individual proteins affecting this behaviour is... Show moreTumor cell migration and invasion are essential steps in cancer metastasis. Better understanding of the molecular mechanisms and function of the individual proteins affecting this behaviour is essential to define potential novel drug targets to combat cancer. In general, cells in a normal tissue environment are attached to the extra-cellular matrix (ECM) and to each others. The interactions with the ECM are mediated through integrin adhesion receptors. Matrix adhesions are the physical link between the ECM and the actin cytoskeleton and are important for survival, proliferation, differentiation and migration. These cytoplasmic structures are composed of various signaling (phosphatases and kinases) and structural proteins that form the so-called __integrin-adhesome__. The spatial and temporal regulations of these components determine the type of matrix adhesion, their behaviour and finally the fate of the cell. For instance, resting cells such as renal epithelial cells show enlarged and stable focal adhesions as well as tight cell-cell contacts. In contrast, tumor cells which are able to invade and metastasize, lose their interactions with adjacent cells and show fast, small and highly dynamic matrix adhesions. In this thesis, we set up technologies and investigated the molecular mechanisms of the matrix adhesions dynamics in relation to tumor cell behaviour both in vitro and in vivo situation. Show less
