Secretion of pigment epithelium-derived factor. Mutagenic study.

Pigment epithelium-derived factor (PEDF), a neurotrophic and antiangiogenic protein, is an extracellular component of the retinal interphotoreceptor matrix which has been shown to be secreted by human fetal retinal pigment epithelial cells. It belongs to the serpin superfamily and contains the typical exposed reactive center loop. The function of this loop is still unknown. In this study we used site-directed mutagenesis of the cDNA encoding PEDF to show that (a) truncation of the C-terminal tail (Pro415-Pro418) of PEDF, (b) deletion of the Pro373-Ala380 segment that resides within the reactive center loop of the protein, and (c) alanine substitution of amino-acid residues Asn391-Thr403 located within its hydrophobic core inhibit PEDF secretion, but not its transcription, by cells transfected with the various PEDF cDNAs. On the basis of the crystal structure of PEDF, these mutations are presumed to alter the protein conformation, suggesting that conservation of the 3D structure of PEDF is essential for its secretion. In addition, we show that replacement of Gly376 and Leu377 with alanine prevents PEDF secretion. As these two residues are located within the highly exposed segment of the reactive center loop, we propose a novel function for this loop in PEDF. Our results imply that the reactive center loop, specifically Gly376 and Leu377, is involved in the interaction of PEDF with components of the quality control system in the endoplasmic reticulum, thus ensuring its efficient secretion.

The PKA phosphorylation of vitronectin: effect on conformation and function.

Vitronectin (Vn) stabilizes the inhibitory form of plasminogen activator inhibitor-1 (PAI-1), an important modulator of fibrinolysis. We have previously reported that Vn is specifically phosphorylated by PKA (at Ser378), a kinase we have shown to be released from platelets upon their physiological activation. Here we describe the molecular consequences of this phosphorylation and show (by circular dichroism, and by phosphorylation with casein kinase II) that it acts by modulating the conformation of Vn. The PKA phosphorylation of Vn is enhanced in the presence of either PAI-1, or heparin, or both. This enhanced phosphorylation occurs exclusively on Ser378 as shown with the Vn mutants Ser378Ala and Ser378Glu. The binding of PKA phosphorylated Vn to immobilized PAI-1 and to immobilized plasminogen is shown to be lower than that of Vn. The evidence compiled here suggests that this phosphorylation of Vn can modulate plasminogen activation and consequently control fibrinolysis.

Truncated vitronectins: binding to immobilized fibrin and to fibrin clots, and their subsequent interaction with cells.

The plasminogen activator inhibitor-1 (PAI-1) is stabilized in its inhibitory conformation by binding to Vitronectin (Vn). The anchorage of PAI-1 to the fibrin fibers was recently shown to be mediated by Vn, and as such to modulate fibrinolysis. Here we report the mapping of the fibrin binding sites in Vn using truncated recombinant Vns, and show that two segments of Vn are involved: one at its carboxyl terminus (within residues 348-459) and one at its amino terminus (within residues 1-44). This mapping sets the stage for (i) the design of specific inhibitors for the Vn-fibrin interaction; (ii) for studying the role of this interaction in the anchoring of endothelial cells and platelets onto the fibrin clot; and (iii) for getting a deeper insight into the mechanism of the Vn-fibrin interaction in fibrinolysis. (c)2002 Elsevier Science.