Overexpression of a secretory form of FGF-1 promotes MMP-1-mediated endothelial cell migration

Abstract

A coordinated interaction between fibroblast growth factors (FGFs) and matrix metalloproteinases (MMPs) is implicated in migration of microvascular endothelial cells (ECs), an early stage of angiogenesis. Specifically, we investigated microvascular ECs migration in vitro, which can be initiated by the overexpression of a secretory form of the angiogenic fibroblast growth factor-1 (FGF-1) and mediated through the enzymatic activity of matrix metalloproteinase-1 (MMP-1). MMP-1 is a member of the MMP family with a propensity for degradation of interstitial type I collagen. We stably overexpressed a chimeric FGF-1 construct composed of the FGF-4 signal-peptide gene, linked in-frame to the FGF-1 coding frame gene (sp-FGF-1), in cultured postcapillary venular ECs. The presence of the biologically active form of FGF-1 was readily detected in the conditioned medium of ECs transfected with sp-FGF-1 construct as demonstrated by DNA synthesis assay. The sp-FGF-1-, but not the plasmid vector alone-transfected ECs, exhibited an altered morphology as demonstrated by their conversion from a classic cobblestone form to a fibroblastlike shape that featured prominent neuritelike extensions. Addition of the anti-FGF receptor 1 antibody (FGFR1 Ab) reverted the transformed phenotype of sp-FGF-1 transfectants. This suggests that the resulting phenotypic transformation in sp-FGF-1 transfectants requires an uninterrupted interaction between the FGF-1 ligand and its receptor. We studied migration of cells through matrices of either highly pure collagen I or reconstituted basement membrane (matrigel) and found that sp-FGF-1-transfected cells migrated two times and six times faster than the vector control transfectants in the respective matrices. We further demonstrated that the enhanced migration rate of sp-FGF-1-transfected EC coincided with the induction of their MMP-1 mRNA level and increased enzymatic activity. The enhanced migratory activity of sp-FGF-1 could be blocked with a selective inhibitor of MMP-1. These results suggest that the multipotent FGF-1 plays a key role in the early stages of angiogenesis, by mediating MMP-1 proteolytic activity.