A thrombin receptor (TR) demonstrating a unique activation mechanism has recently been isolated from a megakaryocytic (Dami) cell line. To further study determinants of peptide ligand-mediated activation phenomenon, we have isolated, cloned, and stably expressed the identical receptor from a human umbilical vein endothelial cell (HUVEC) library. Chinese hamster ovary (CHO) cells expressing a functional TR (CHO-TR), platelets, and HUVECs were then used to specifically characterize a-thrombin-and peptide ligand-induced activation responses using two different antibodies: anti-TR"52 directed against a 20-amino acid peptide spanning the thrombin cleavage site, and anti-TR'" generated against the NH2-terminal 160 amino acids of the TR expressed as a chimeric protein in Escherichia coli. Activation-dependent responses to both athrombin (10 nM) and peptide ligand (20 MM) were studied using fura 2-loaded cells and microspectrofluorimetry.
Thrombin receptor (TR) activation by alpha-thrombin requires proteolytic cleavage, although synthetic peptides modeled after the new N-terminus directly effect receptor activation without cleavage, presumably by interacting with an unidentified region of the receptor. To further define critical residues responsible for receptor activation, we performed epitope mapping of anti-TR1–160, a previously described polyclonal antibody that inhibits peptide ligand-induced receptor activation in various cell types expressing a functional TR. An enzyme-linked immunosorbent assay (ELISA) using overlapping decapeptides derived from the TR extracellular domains identified four immunodominant peaks within the long N-terminal extension centered between amino acids 34–44, 48–67, 65–79, and 87–94. Soluble peptides derived from regions 83–94, but not those from other regions of the receptor, neutralized the ability of anti-TR1–160 to inhibit peptide ligand-induced platelet aggregation, suggesting that antibodies directed against this region of the TR are important in ligand-mediated activation. Thrombin receptor mutants lacking discrete regions of the TR were subsequently evaluated using microinjected Xenopus oocytes. Whereas a TR mutant lacking amino acid residues Thr67-Lys82 (TR delta 67–82) showed normal to exaggerated responses to either alpha-thrombin or synthetic peptide ligands, only TR mutants with limited deletions spanning the residues Gln83-Ser93 exhibited dysfunctional responses to either agonist (200 nmol/L alpha-thrombin or 200 mumol/L TR42–47). These data provide a model for receptor activation that implicates a discrete and previously uncharacterized sequence within the TR N- terminal extension that is necessary for initiation of signal transduction events independent of the initiating agonist.
The integrin VLA-2 (alpha 2 beta 1), generally considered to represent the specific collagen receptor on human endothelial cells, contains an alpha 2-subunit inserted I domain with structural similarity to the type A domains found within the recently described superfamily of receptor-ligand recognition proteins. This region of the cDNA has now been isolated and used for molecular and functional characterization of this heterodimeric receptor complex. Comparative sequence analysis with the porcine homologue revealed 93% amino acid sequence identity, suggestive of a developmentally conserved function. To complete structure/function studies, this region of the human cDNA was expressed as a chimeric protein in Escherichia coli, and a rabbit polyclonal antibody (anti-I domain) was used to study determinants of endothelial cell attachment and spreading in vitro. Quantifiable and visual disruption of endothelial cell attachment to gelatin, type I collagen, and laminin was evident using the specific anti-I domain antibody, with minimal inhibitory effects demonstrable using fibronectin or fibrinogen matrices. Therefore, these data would suggest that the alpha 2 beta 1 I domain confers ligand-binding specificity for both known alpha 2 beta 1 substrates (laminin and collagen), and that this region subserves a regulatory function in the molecular processes controlling endothelial cell attachment and spreading in vitro.
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