Abstract-In atherosclerosis, circulating platelets interact with endothelial cells and monocytes, leading to cell activation and enhanced recruitment of leukocytes into the vascular wall. The invasion of monocytes is accompanied by overexpression of matrix metalloproteinases (MMPs), which are thought to promote atherosclerosis and trigger plaque rupture. Following interaction with itself, the extracellular matrix metalloproteinase inducer (EMMPRIN) induces MMP synthesis via a little-known intracellular pathway. Recently, we showed upregulation of EMMPRIN on monocytes during acute myocardial infarction. EMMPRIN also stimulates secretion of MMP-9 by monocytes and of MMP-2 by smooth muscle cells, indicating that it may be an important regulator of MMP activity. Expression of EMMPRIN on platelets has not been described until now. Here, we demonstrate that resting platelets show low surface expression of EMMPRIN, which is upregulated by various platelet stimulators (flow cytometry). EMMPRIN is located in the open canalicular system and in ␣ granules of platelets (according to electron microscopy and sucrose gradient ultracentrifugation). Platelet stimulation with recombinant EMMPRIN-Fc induced surface expression of CD40L and P-selectin (according to flow cytometry), suggesting that EMMPRIN-EMMPRIN interaction activates platelets. Coincubation of platelets with monocytes induced EMMPRIN-mediated nuclear factor B activation (according to Western blot) in monocytes with increased MMP-9 (zymography), interleukin-6, and tumor necrosis factor-␣ secretion (according to ELISA) by monocytes. In conclusion, EMMPRIN displays a new platelet receptor that is upregulated on activated platelets. Binding of EMMPRIN to platelets fosters platelet degranulation. Platelet-monocyte interactions via EMMPRIN stimulate nuclear factor B-driven inflammatory pathways in monocytes, such as MMP and cytokine induction. Thus, EMMPRIN may represent a novel target to diminish the burden of protease activity and inflammation in atherosclerosis. (Circ Res. 2008;102:302-309.)
Platelet adhesion to the atherosclerotic vascular wall induces thrombosis and boosters vascular inflammation and atheroprogression. In the present study we studied the binding of the platelet collagen receptor glycoprotein (GP) VI to human atherosclerotic plaques (AP) and the role of GPVI-mediated platelet adhesion for atheroprogression. Soluble GPVI-Fc fusion protein bound to immobilized collagen type I, collagen type III, and predominantly to the core region of human carotid atheromatous plaques. The pattern of GPVI-Fc binding was similar to the immunostaining pattern of collagen type III and differed from the immunostaining of collagen type I, which was more intense in the cap than in the core. Plaque-induced platelet aggregation in stirred blood and platelet adhesion/aggregate formation under flow were inhibited by the anti-GPVI monoclonal antibody 5C4 or by pretreatment of plaques with anti-collagen type I and anti-collagen type III antibody, or GPVI-Fc. However, there was no correlation between GPVI-Fc binding and platelet aggregating activity of individual plaques. GPVI bound also to atherosclerotic arteries of ApoE-deficient mice in vivo as assessed by small animal positron emission tomography (PET). Prolonged administration of soluble GPVI attenuated atheroprogression in ApoE-deficient mice. In humans, GPVI binding to collagenous type I and type III structures of the plaque core region mediates plaque-induced platelet adhesion and aggregation, but GPVI binding is not the sole platelet-activating determinant of plaques. In mice, GPVI-mediated platelet adhesion to the atherosclerotic vascular wall is involved in atheroprogression in vivo. Taken together, our data suggests that GPVI is a relevant target to prevent atherothrombotic events and atheroprogression.
Abstract:-The possibility of evaluating the function of transgenes in platelets requires the generation of platelets from nucleated progenitor cells in vitro. In this article, we provide effective culture conditions for generating functional culture-derived (CD) human and mouse platelets from CD34 ϩ progenitor cells that allow expression of any foreign protein of interest. We have evolved an effective cytokine cocktail (thrombopoietin, stem cell factor, interleukin [IL]-1, IL-6) that induces a high yield of CD platelets and optimal shedding from cultivated megakaryocytes generated from CD34 ϩ progenitor cells. CD platelets showed similar functional and morphological characteristics compared with isolated blood platelets, including surface expression of platelet antigens (CD41, CD42, CD62P), aggregation, release of granule constituents (P-selectin, platelet factor 4, serotonin). Moreover, transmission electron microscopy revealed the presence of typical ␣-and dense granules and dense tubular system in CD platelets. Additionally, we showed that stable transgene expression in CD platelets can be performed through infection of CD34 ϩ progenitor cells using adenoviral vectors. Thus, we describe a methodology that enables studying functional consequences of transgenes of interest in the natural environment of platelets that may impose substantial impact on potential future platelet research and therapeutic target evaluation. The full text of this article is available online at http://circres.ahajournals.org.
Cardiac myocyte apoptosis has been demonstrated in end-stage failing human hearts. The therapeutic utility of blocking apoptosis in congestive heart failure (CHF) has not been elucidated. This study investigated the role of caspase activation in cardiac contractility and sarcomere organization in the development of CHF. In a rabbit model of heart failure obtained by rapid ventricular pacing, we demonstrate, using in vivo transcoronary adenovirus-mediated gene delivery of the potent caspase inhibitor p35, that caspase activation is associated with a reduction in contractile force of failing myocytes by destroying sarcomeric structure. In this animal model gene transfer of p35 prevented the rise in caspase 3 activity and DNA-histone formation. Genetically manipulated hearts expressing p35 had a significant improvement in left ventricular pressure rise (+dp/dt), decreased end-diastolic chamber pressure (LVEDP), and the development of heart failure was delayed. To better understand this benefit, we examined the effects of caspase 3 on cardiomyocyte dysfunction in vitro. Microinjection of activated caspase 3 into the cytoplasm of intact myocytes induced sarcomeric disorganization and reduced contractility of the cells. These results demonstrate a direct impact of caspases on cardiac function and may lead to novel therapeutic strategies via antiapoptotic regimens.
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