Annemie Collen

Role of fibrin matrix in angiogenesis.

Abstract: Angiogenesis, the formation of new blood vessels from existing vessels, plays an important role during development. In the adult, it is limited to the female reproductive system and to tissue repair and pathological conditions. Repair associated angiogenesis is usually accompanied by the presence of inflammatory cells, vascular leakage, and fibrin deposition. The temporary fibrin matrix acts, not only as a sealing matrix, but also as a scaffolding for invading leukocytes and endothelial cells during tissue repair. We have used a three‐dimensional fibrin matrix to study the outgrowth of human microvascular endothelial cells in capillary‐like tubular structures. This process is induced by the simultaneous addition of an angiogenic growth factor (bFGF or VEGF) and the cytokine TNFα, and is enhanced by hypoxia. It involves proteolytic activities, in particular cell bound urokinase/plasmin and matrix metalloproteinase activities. Modulation of the fibrin structure markedly affects the extent and stability of capillary tube formation in vitro. Preparation of fibrin at different pH (7.0–7.8) or crosslinking of the fibrin matrix induces differences in fibrin matrix rigidity and structure. This is accompanied by a change in capillary ingrowth. Heparins, in particular low molecular weight heparins, modulate the fibrin structure and by this action affect angiogenesis in vitro. A mutant fibrinogenNieuwegein, which lacks the terminal part of the Aα chain of fibrin harboring an RGD sequence and the transglutaminase sequence, provided additional evidence that the structure of fibrin is an important determinant for angiogenesis. These findings may have impact on improving wound healing and on influencing angiogenesis in malignancies with a fibrinous stroma.

Role and Localization of Urokinase Receptor in the Formation of New Microvascular Structures in Fibrin Matrices

Fibrin or a fibrinous exudate can facilitate angiogenesis in many pathological conditions. In vitro, the outgrowth of capillary-like structures in fibrin can be mimicked by exposing human microvascular endothelial cells (hMVECs) to an angiogenic growth factor and tumor necrosis factor (TNF)-alpha. Urokinase-type plasminogen activator (u-PA) and plasmin activities are required for this angiogenic process. This study focuses on the role and localization of the u-PA receptor (u-PAR) in newly formed microvascular structures. The u-PAR-blocking monoclonal antibody (MAb) H-2 completely inhibited the formation of capillary-like tubular structures induced by exposure of hMVECs to basic fibroblast growth factor and TNF-alpha. This was accompanied by a several-fold increase in u-PA accumulation in the conditioned medium. The effect of MAb H-2 was not caused by blocking cellular activation by u-PA/u-PAR interaction, as the amino-terminal fragment (ATF) of u-PA, which also activates u-PAR, prevented tube formation. In addition, the inhibition by MAb H-2 was not due to an effect of the antibody on u-PAR-vitronectin binding. These data show that inhibition of tube formation can be caused not only by inhibition of u-PA or plasmin activities but also by unavailability of the u-PAR for cell-bound proteolysis. Immunohistochemical analysis showed that in in vitro angiogenesis u-PAR and u-PA were localized on the invading, tube-forming hMVECs and not on the endothelial cells that are located on top of the fibrin matrix. u-PAR and u-PA were also prominently expressed on endothelial cells of neovessels present in an atherosclerotic plaque. These data may give more insight into the role of u-PAR in repair-associated angiogenesis.

Influence of fibrin structure on the formation and maintenance of capillary-like tubules by human microvascular endothelial cells

Fibrin is a temporary matrix which not only covers a wound, but also provides a structure for invading cells during healing. Changes in the polymerization conditions before gelation of the clot affect the structure of fibrin and thus might influence the interaction with invading cells. Therefore we tested whether changes in the fibrin structure influence the formation of capillary-like tubular structures by human microvascular endothelial cells (hMVEC) in an in vitro angiogenesis model. Opaque [125I]fibrin structures prepared at pH 7.0, fibrin matrices at pH 7.4 and transparent [125I]fibrin structures prepared at pH 7.8 were neutralized (pH 7.4) before seeding hMVEC on top of them in confluent density. Endothelial cells were stimulated with a growth factor [basic fibroblast growth factor (bFGF) and vascular endothelial growth factor (VEGF)165] and a cytokine [tumor necrosis factor (TNF)-α] to induce the u-PA/u-PA receptor-dependent formation of capillary-like tubular structures. The formation of these structures was quantified by determining the length of the invasive structures by image analysis and by measuring the accompanying [125I]fibrin degradation. Ingrowth of tubular structures proceeded at a faster rate in opaque matrices consisting of thick fibrin fibers as compared to transparent gels with fine fibrin fibers. The more rapid ingrowth of tubular structures in opaque fibrin gels induced by bFGF/TNF-α or VEGF165/TNF-α was accompanied by a larger extent of fibrin degradation. Both processes were inhibited by aprotinin and ∈-aminocaproic acid indicating the involvement of plasmin. They were also inhibited by anti-u-PA or anti-u-PA receptor IgG, but not by anti-t-PA IgG, suggesting the involvement of cell-bound u-PA activity. However, in the opaque fibrin gels, the tubular structures dissolved upon prolonged incubation due to excessive fibrin degradation. Simulation of hMVEC with bFGF alone did not induce tubular structures, but ca used a high degree of t-PA- and plasmin-dependent fibrin lysis, and, after several days, a partial detachment of sheets of cells. Gradual inhibition of the excessive fibrin degradation by a series of aprotinin concentrations did not lead to tube formation in bFGF-treated cells. These data indicate that the formation and stability of tubular structures by hMVEC in fibrin is accompanied by controlled fibrinolysis and depends critically not only on cell-bound u-PA-dependent plasminogen activation, but also on the fibrin structure. Because the fibrin structure is largely influenced by the conditions in which fibrin has been polymerized, these conditions may have considerable impact on angiogenesis during wound healing and vascularization of tumour stroma.

The inactivation of single-chain urokinase-type plasminogen activator by thrombin on cultured human endothelial cells

Single-chain urokinase-type plasminogen activator (scu-PA) is cleaved by thrombin, resulting in an inactive molecule called thrombin-cleaved two-chain urokinase-type plasminogen activator (tcu-PA/T). There is no knowledge about cell-mediated inactivation of scu-PA. We have studied whether scu-PA bound to cultured human umbilical vein endothelial cells (HUVEC) could be inactivated by thrombin. High molecular weight scu-PA was bound to HUVEC and incubated with increasing amounts of thrombin for 30 min at 37 degrees C. Cell-bound urokinase-type plasminogen activator (u-PA) was released and levels of scu-PA, tcu-PA/T and active two-chain u-PA were measured using sensitive bioimmunoassays. Cell-bound scu-PA was efficiently inactivated by thrombin. Fifty percent inactivation of scu-PA occurred at about 0.2 nM thrombin. In the presence of monoclonal anti-urokinase receptor IgG, at least 50% of the binding of scu-PA to HUVEC was inhibited. The relative amount of tcu-PA/T that was generated by thrombin was not affected by the monoclonal antibody. These results indicated that scu-PA bound to HUVEC via the urokinase receptor can be inactivated by thrombin. The efficient inactivation of cell-bound scu-PA suggests that a cofactor for thrombin may be involved, like thrombomodulin or glycosaminoglycans. It is concluded that scu-PA bound to the urokinase receptor on a cell surface can be inactivated by thrombin, which may have profound effects on u-PA-mediated local fibrinolysis and extracellular proteolysis during processes in which thrombin is also involved.