Direct Real Time Visualization of Platelet Calclium Signaling In Vivo: Role of Platelet Activation and Thrombus Formation in a Living Mouse.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 325-325 ◽  
Author(s):  
Christophe Dubois ◽  
Laurence Panicot-Dubois ◽  
Barbara C. Furie ◽  
Bruce Furie
Keyword(s):  
Intracellular Calcium ◽  
Platelet Activation ◽  
Vessel Wall ◽  
High Speed ◽  
Critical Role ◽  
Calcium Mobilization ◽  
Recipient Mouse ◽  
Intracellular Calcium Mobilization ◽  
Platelet Accumulation

Abstract Intracellular calcium mobilization plays a critical role in platelet signaling. Upon platelet activation, an intracellular calcium mobilization leads to the activation of various intracellular and membrane proteins, including integrins involved in both platelet shape change and aggregation. The goal of the present study was to monitor platelet calcium mobilization in vivo in an intact animal and to determine which intracellular pathways are dominant in platelet accumulation into the developing thrombus. Platelets were isolated from mice, washed, loaded with a calcium-sensitive fluorochrome, Fura2-AM and then infused into a recipient mouse. We studied Fura2-AM loaded platelet incorporation during arterial thrombus development following laser injury of the vessel wall in the cremaster microcirculation of living mice using high speed intravital widefield digital microscopy. Fura-2 loaded platelets were monitored by excitation at 380 nm; this fluorescence reports the basal calcium levels in platelets. Calcium mobilization was monitored by excitation at 340 nm where the fluorescence intensity reflects Fura2-calcium complex formation. We observed that platelets bind to the growing thrombus independent of calcium mobilization. However, the stable incorporation of platelets into the thrombus correlated with a significant intracellular calcium increase. Once the thrombus reached maximal size at about 100 seconds, the calcium mobilization also reached maximal intensity. Subsequently, platelets that did not mobilize calcium dissociated from the thrombus. We confirmed these observations by using platelets treated with the calcium chelators, BAPTA-AM or EGTA-AM. We observed a significant inhibition of platelet accumulation into the thrombus, indicating that the intracellular calcium increase is necessary in vivo for the stable accumulation of the platelets into the thrombus. We also evaluated the involvement in vivo of two platelet agonists, ADP and thromboxane A2 (TxA2), on calcium mobilization and platelet incorporation into thrombi. When platelets were treated with aspirin or with the P2Y1 antagonist A3P5P (adenosine 3′-phosphate-5′-phosphate), we observed a partial decrease in both calcium mobilization and platelet accumulation into the thrombus. These results indicate that TxA2 and ADP via the P2Y1 receptor are involved in vivo in platelet activation upon vessel wall injury in this thrombosis model. When platelets were treated with both compounds, we completely inhibited the calcium increase and the incorporation of platelets into the thrombus. Altogether, our results directly show, for the first time in vivo, the importance of the calcium mobilization on platelet accumulation into the developing thrombus. The platelet agonists TxA2 and ADP both play an important and complementary role on platelet activation by acting on the mobilization of the intracellular calcium.

Evidence for Two Distinct G-protein-coupled ADP Receptors Mediating Platelet Activation

1999 ◽  
Vol 81 (01) ◽  
pp. 111-117 ◽  
Author(s):  
Laurent Gousset ◽  
Vinay Bhaskar ◽  
Diana Vincent ◽  
Albert Tai ◽  
Elwood Reynolds ◽  
...  
Keyword(s):  
Platelet Aggregation ◽  
Intracellular Calcium ◽  
G Protein ◽  
Platelet Activation ◽  
Shape Change ◽  
Calcium Mobilization ◽  
Intracellular Calcium Mobilization ◽  
Adp Receptors ◽  
Adp Receptor ◽  
G Protein Coupled

SummaryThe identity of the receptors mediating platelet activation by ADP remains elusive. To distinguish between platelet ADP receptor subtypes, the effects of antagonists on platelet responses and the cloned P2Y1receptor, a putative platelet ADP receptor, have been investigated. 2-methylthio-AMP (2MeSAMP), an inhibitor of ADP-dependent platelet aggregation, antagonized ADP-mediated inhibition of adenylyl cyclase, competed with binding of [3H]2-methylthio-ADP and inhibited the stimulation of [35S]GTP γS binding. 2MeSAMP did not inhibit platelet shape change and was only a weak antagonist of intracellular calcium mobilization in platelets or in cells expressing the cloned human P2Y1receptor. By contrast, the P2Y1receptor antagonist adeno-sine 3’,5’-diphosphate (A3P5P) inhibited ADP-induced platelet aggregation, completely abolished shape change, but did not antagonize ADP effects on cyclic AMP generation or [3H]2-methylthio-ADP binding. However, A3P5P antagonized intracellular calcium mobilization in platelets and cells expressing the cloned P2Y1receptor. Furthermore, using a specific monoclonal antibody and flow cytometry, P2Y1receptor protein was detected on human platelets. These results support the existence of two G protein-coupled ADP receptors mediating platelet aggregation, one of which is coupled to Giproteins and blocked by 2MeSAMP, whereas the second receptor is similar or identical to P2Y1and coupled to Gq.

Dynamics of Calcium Mobilization in Platelets during Thrombus Formation in a Living Mouse.

Blood ◽  
2005 ◽  
Vol 106 (11) ◽  
pp. 649-649
Author(s):  
Christophe Dubois ◽  
Laurence Panicot-Dubois ◽  
Barbara C. Furie ◽  
Bruce Furie
Keyword(s):  
Intracellular Calcium ◽  
Thrombus Formation ◽  
Calcium Mobilization ◽  
Time Interval ◽  
Intracellular Calcium Mobilization ◽  
Living Mouse ◽  
Platelet Thrombus ◽  
The Mean ◽  
Platelet Accumulation ◽  
Relationship Of

Abstract Platelet accumulation at sites of vascular injury arrests bleeding but also plays a critical role in the pathogenesis of thrombosis, leading to ischemia in myocardial infarction or stroke. Intracellular calcium mobilization in platelets is a critical step in the activation of platelets and formation of the platelet thrombus. Here we show the relationship of the dynamics of intracellular calcium mobilization with platelet accumulation into the developing thrombus in a living mouse. Following injection of 100 x 106 fura-2 loaded platelets into a living mouse we used high speed intravital multi-channel digital fluorescence microscopy to monitor calcium status in circulating and thrombus-bound platelets during thrombus development. One population of platelets binds transiently to the developing thrombus but does not mobilize calcium. The mean duration of platelet-thrombus interaction for these platelets is 11 sec. Another population of platelets undergoes calcium mobilization after binding to the developing thrombus. The time interval from attachment to calcium mobilization for individual platelets varied from 1.0 to 12 sec, with a median of 3.5 sec. More than 90% of platelets that undergo calcium mobilization do so with in 5 sec of attachment. The calcium mobilization in the thrombus bound platelets is reversible. About two thirds of the platelets return rapidly to the basal Ca2+ state while the remaining thrombus bound platelets maintain an elevated Ca2+ level for an extended period. The mean duration of platelet-thrombus interaction is 35 sec with a range of 1.5 sec to 284 sec (median duration 39.5 sec) as calculated from multiple independent observations of single platelets. In each platelet studied, only one calcium peak is detected per platelet. There is a close correlation between the duration of calcium mobilization in an individual platelet and the time that the platelet remains attached to the developing thrombus, suggesting a relationship of calcium-dependent events and platelet-thrombus affinity. A population of platelets binds to the thrombus, mobilizes calcium and remains associated with the thrombus. Using widefield deconvolution techniques to obtain planar images and increased numbers of dye-loaded platelets, individual platelets could be observed undergoing sustained calcium elevation within the thrombus. As the platelet thrombus reaches maximal size at about 120 sec, calcium mobilization continues in the stable core of the thrombus for several minutes, then decreases. These studies describe thrombus formation in a living animal under conditions in which the endothelium and vessel wall, blood cells and plasma components, and flowing blood are preserved in the absence of anticoagulants. Our results indicate that stable platelet thrombus formation is dependent upon durable calcium mobilization, and that intracellular calcium regulates thrombus development and maturation in vivo.

Thrombin-Dependent Platelet Activation Is VWF-Independent during Thrombus Formation In Vivo.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 1510-1510
Author(s):  
Christophe Dubois ◽  
Laurence Panicot-Dubois ◽  
Justin F. Gainor ◽  
Barbara C. Furie ◽  
Bruce Furie
Keyword(s):  
Platelet Activation ◽  
Thrombus Formation ◽  
Specific Inhibitor ◽  
Calcium Mobilization ◽  
Wild Type ◽  
Platelet Surface ◽  
Platelet Thrombus ◽  
Platelet Accumulation ◽  
Kinetics Of

Abstract Adhesion to and activation of platelets at an injured vessel wall are critical events in the formation of a thrombus. Calcium mobilization is one marker of platelet activation. Of different agonists capable of activating platelets in vitro, thrombin, collagen and vWF have been described to induce calcium mobilization, leading to the formation of aggregates. Using high speed digital multichannel intravital microscopy, we characterized calcium mobilization during platelet activation and thrombus formation in genetically modified mice. The kinetics of platelet activation and accumulation after laser-induced injury in cremaster muscle arterioles of living mice were analyzed. In wild type mice, platelets adhered and accumulated rapidly at the site of laser-induced injury. Thrombi increased in size, reached a maximum size at 90–120 sec, decreased in size and then stabilized within 3 to 4 min post-injury. In vWF−/− mice, the kinetics of platelet accumulation followed the same pattern as in wild type mice. However, a significant albeit modest reduction in the size of each thrombus was observed in these genetically deficient mice in comparison with wild type mice. By ranking the thrombi by size, we observed that 40% of the thrombi formed in vWF−/− mice were present in the quadrant containing the smallest thrombi versus 18% for the wild type mice. Only 8% of the thrombi formed in vWF−/− mice were distributed in the quadrant containing the largest thrombi versus 32% for the wild type mice. In wild type mice treated with lepirudin, a specific inhibitor of thrombin activity, a small early accumulation of platelets was observed at about 16 sec whereas in untreated wild type mice this early accumulation is often obscured by subsequent thrombin-mediated platelet accumulation and activation. However, at the time of maximal thrombus size in wild-type mice, platelet accumulation in wild type mice was more than ten-fold greater than in wild type mice treated with lepirudin. The kinetics of platelet accumulation were similar in FcRγ−/− mice lacking GPVI, GPVI-depleted mice and wild type mice. Furthermore, depletion of GPVI from the platelet surface of vWF−/− mice or platelets of wild type mice treated with lepirudin did not alter the kinetics of platelet accumulation in those mice. By monitoring calcium mobilization per platelet engaged in the growing thrombus, we observed that elevated calcium levels in each platelet were similar in FcRγ−/−, GPVI depleted, vWF−/− and wild type mice. However in wild type mice treated with lepirudin, platelet calcium mobilization was almost completely inhibited in comparison with those observed in wild type mice. Our results indicate that thrombin is the major agonist leading to platelet activation after laser-induced injury. Collagen, as previously reported (Dubois, Blood.2006;107:3902) does not play a role in platelet thrombus formation after laser injury and, based on data reported here, does not play a role in platelet activation in this model. vWF is important for the growth of the platelet thrombus but is not required for initial platelet accumulation or platelet activation in vivo in this thrombosis model. The platelet agonist or ligand responsible for initial early platelet accumulation after laser-induced injury is unknown, and does not require GPVI, thrombin or vWF.

Protease-Activator Receptor 4 Is Required for Maximal Thrombus Growth, but Not for Fibrin Generation in Thrombi after Laser Injury.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 624-624 ◽  
Author(s):  
Erik R. Vandendries ◽  
Justin R. Hamilton ◽  
Shaun R. Coughlin ◽  
Barbara C. Furie ◽  
Bruce Furie
Keyword(s):  
Platelet Activation ◽  
High Speed ◽  
Thrombin Generation ◽  
Thrombus Formation ◽  
Shape Change ◽  
Fluorescent Antibody ◽  
Fibrin Deposition ◽  
Wild Type ◽  
Platelet Accumulation

Abstract The serine protease, thrombin, is necessary for the conversion of fibrinogen to fibrin and is a potent activator of platelets. Thrombin-induced platelet activation, as measured by shape change, calcium mobilization, and ATP secretion, requires the protease-activator receptor 4 (PAR4). Platelets isolated from PAR4 knock-out mice are unresponsive to thrombin, and PAR4 null mice appear to be protected from thrombosis in a ferric chloride-induced injury model of thrombosis and a thromboplastin model of pulmonary embolism. To examine further the role of thrombin-induced platelet activation in developing thrombi, we have examined the in vivo kinetics of thrombus formation in living mice lacking PAR4 using high-speed widefield digital microscopy. In this study, platelets were labeled using anti-CD41 Fab fragments conjugated to Alexa-488. Thrombi were generated by laser-induced injury of the cremaster arteriolar vessel wall, and the total fluorescent antibody accumulation was monitored and quantitated for 5 minutes after injury. In PAR4 null mice, the thrombi generated were significantly smaller with an early arrest of thrombus growth when compared to thrombi generated in wild-type mice. The maximum thrombus platelet accumulation in PAR4 null mice (median of 30 thrombi in 3 mice) was 75% less than that seen in wild-type mice (median of 33 thrombi in 4 mice)(P<0.001). The time to half-maximal and the time to maximal thrombus formation in PAR4 null mice is approximately 5.5 seconds and 16 seconds, respectively, compared to 45 seconds and 74 seconds in wild-type mice (P<0.001). The shortened time to maximal platelet accumulation appears to be secondary to an early termination of thrombus growth. Fibrin generation was monitored using Alexa-647 conjugated to an anti-fibrin antibody that does not recognize fibrinogen in mice simultaneously infused with anti-CD41 Fab conjugated to Alexa-488. No difference in total fibrin accumulation was seen during the first 4 minutes of thrombus formation in PAR4 null mice (median of 23 thrombi in 3 mice) compared to thrombi generated in wild-type mice (median of 26 thrombi in 4 mice) despite a significant decrease in platelet accumulation in PAR4 null thrombi. Most of the fibrin deposition in both wild-type and PAR4 null thrombi was observed at the vascular wall/thrombus interface. In summary, thrombin-induced platelet activation via PAR4 is required for normal thrombus growth. However, in this model of thrombosis, neither PAR4 nor maximal thrombus growth appears to be necessary for fibrin deposition. This suggests that a platelet-independent mechanism of thrombin generation may exist. Alternatively, the amount of platelet accumulation and activation in PAR4 null mice may be sufficient for normal thrombin generation and subsequent fibrin deposition.

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