Protein disulfide isomerase acts as an injury response signal that enhances fibrin generation via tissue factor activation
Christoph Reinhardt, … , Steffen Massberg, Bernd Engelmann
Christoph Reinhardt, … , Steffen Massberg, Bernd Engelmann
Published February 14, 2008
Citation Information: J Clin Invest. 2008;118(3):1110-1122. https://doi.org/10.1172/JCI32376.
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Research Article

Protein disulfide isomerase acts as an injury response signal that enhances fibrin generation via tissue factor activation

Abstract

The activation of initiator protein tissue factor (TF) is likely to be a crucial step in the blood coagulation process, which leads to fibrin formation. The stimuli responsible for inducing TF activation are largely undefined. Here we show that the oxidoreductase protein disulfide isomerase (PDI) directly promotes TF-dependent fibrin production during thrombus formation in vivo. After endothelial denudation of mouse carotid arteries, PDI was released at the injury site from adherent platelets and disrupted vessel wall cells. Inhibition of PDI decreased TF-triggered fibrin formation in different in vivo murine models of thrombus formation, as determined by intravital fluorescence microscopy. PDI infusion increased — and, under conditions of decreased platelet adhesion, PDI inhibition reduced — fibrin generation at the injury site, indicating that PDI can directly initiate blood coagulation. In vitro, human platelet–secreted PDI contributed to the activation of cryptic TF on microvesicles (microparticles). Mass spectrometry analyses indicated that part of the extracellular cysteine 209 of TF was constitutively glutathionylated. Mixed disulfide formation contributed to maintaining TF in a state of low functionality. We propose that reduced PDI activates TF by isomerization of a mixed disulfide and a free thiol to an intramolecular disulfide. Our findings suggest that disulfide isomerases can act as injury response signals that trigger the activation of fibrin formation following vessel injury.

Authors

Christoph Reinhardt, Marie-Luise von Brühl, Davit Manukyan, Lenka Grahl, Michael Lorenz, Berid Altmann, Silke Dlugai, Sonja Hess, Ildiko Konrad, Lena Orschiedt, Nigel Mackman, Lloyd Ruddock, Steffen Massberg, Bernd Engelmann

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Figure 7

Deglutathionylation and TF disulfide bond formation by reduced PDI.

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PDI decreases TF free thiols. (A) PDI lowers TF free thiols. Top panels:...
(A) Incorporation of glutathione into sTF is reverted by GRX and DTT. sTF (1.7 μg/ml) incorporates biotin-labeled glutathione (0.1 mM, in the presence of 0.1 mM diamide; 15 minutes). Where indicated, DTT (1 mM) and GRX (4 μM; in the presence of 1 mM GSH) were added together with biotin-labeled glutathione. The biotinylated proteins were captured by streptavidin-agarose and immunoblotted with anti-TF antibody (GSH-IB). In parallel, sTF was analyzed by western blotting. (B) Deglutathionylation of TF by PDI. Left: sTF was labeled with biotin-labeled glutathione in the absence (control) or presence of native PDI, fully oxidized PDI (PDIox), or fully reduced PDI (PDIred; all at 1.8 μM, 15 minutes). Biotinylated proteins selected by streptavidin-agarose were immunoblotted with anti-TF antibody, and in parallel, sTF was analyzed by western blotting. Right: Quantification of labeling of sTF with biotin-glutathione by densitometry. *P < 0.05 (versus control). n = 4. (C) Reduced forms of PDI promote disulfide bond formation of TF. Left: sTF was exposed to vehicle (control) and native PDI, PDIox, or PDIred (all at 1.8 μM, 15 minutes, room temperature). Then, the samples were incubated with biotin-MPB. The biotinylated proteins were selected with streptavidin-agarose, followed by detection of biotinylated sTF species by immunoblotting with anti-TF antibody. In parallel, western blots were performed. Right: Quantification of free thiols of sTF by densitometry. *P < 0.05 versus control.