Circulating endothelial cell count, plasma vWF and soluble ICAM-1 levels following primary or elective percutaneous coronary intervention.

BACKGROUND: Percutaneous coronary intervention (PCI) is an important therapeutic strategy in patients with ischaemic heart disease. Our aim was to clarify the extent of endothelial injury induced by PCI in stable angina (SA) or in acute ST-elevation myocardial infarction (STEMI). METHODS: Circulating endothelial cell (CEC) count, von Willebrand factor (vWF) and soluble intercellular adhesion molecule-1 (sICAM-1) levels were determined pre-, post-, 24 and 96h after PCI in patients with SA (n=23) and with STEMI (n=28). To provide control data regarding the effect of angiography itself stable angina patients with coronarography only (n=23) were enrolled. RESULTS: PCI and coronarography in stable angina patients caused measurable, but only non-significant elevation of CEC count and plasma vWF (p=NS). In STEMI, significantly higher baseline CEC count (p=0.019) and vWF plasma levels (p=0.046) were found compared to SA with PCI/or coronarography. After PCI, explicit increase in CEC count was observed (significant peak at 24h) (p=0.036). Positive correlation was found between baseline CKMB and CEC count at 24h (r=0.51, p<0.05). CONCLUSION: Both coronary angiography and elective PCI cause only mild endothelial injury. However, in patients with STEMI, not only the procedure itself but myocardial ischemia and the ongoing atherothrombotic process might be responsible for the prolonged and more pronounced endothelial damage.

The platelet ATP and ADP receptors.

Adenine nucleotides, ADP and ATP, are coreleased from dense granules during platelet activation, as well as from endothelial cells and damaged red blood cells following vascular injury. Through autocrine and paracrine mechanisms, these extracellular signaling molecules interact with the platelet P2 receptors to amplify ongoing platelet activation. Two receptors for ADP, the G(q)-protein-coupled P2Y1 and G(i)-protein-coupled P2Y12 and one receptor for ATP, the P2X1 ion channel, have been identified on platelets. Due to distinct pharmacological properties and differential regulation, the P2Y and P2X receptors essentially operate on different scales of time and distance and trigger selective intracellular signaling cascades. Recent advances in the understanding of the P2Y receptor physiology have reinforced the concept of these receptors as useful targets for antithrombotic therapy. The function of P2X1 in platelet activation only recently started to be unraveled. This review focuses on recent findings on the physiology of these platelet ADP and ATP receptors, their distinct downstream intracellular signaling pathways as well as on the available agonists, antagonists and inhibitors that allow their pharmacological discrimination.

ERK2 activation in arteriolar and venular murine thrombosis: platelet receptor GPIb vs. P2X.

The functional significance of extracellular signal-regulated kinase 2 (ERK2) activation was investigated during shear induced human platelet aggregation (SIPA) in vitro and during shear controlled thrombosis in vivo in intestinal arterioles and venules of wild type (WT) and transgenic (TG) mice with platelet-specific overexpression of human P2X(1) (TG). In SIPA, ERK2 was rapidly phosphorylated during GPIb stimulation, its activation contributing to SIPA for 50%, independently of P2X(1) regulation. Thrombotic occlusion of injured arterioles occurred considerably faster in TG (4.3 +/- 2.3 min) than in WT (38 +/- 8 min) arterioles, but occlusion times in TG (19 +/- 12) and WT (48 +/- 4.5 min) venules differed less. Both the alphabeta-meATP triggered desensitization of platelet P2X(1), as well as P2X(1) antagonism by NF279 or NF449 prolonged mean occlusion to about 75 min in WT and 65 min in TG arterioles, but venular occlusion times were less affected. Preventing ERK2 activation by U0126 prolonged occlusion times in TG (41 +/- 10 min) and WT (51 +/- 17) arterioles more than in TG (46 +/- 5 min) and WT (56 +/- 6 min) venules, uncovering a role for ERK2 in shear controlled thrombosis. Antagonism of GPIb by a recombinant murine von Willebrand factor (VWF)-A1 fragment prolonged occlusion times to comparable values, ranging from 55 to 58 min, both in TG and WT arterioles and venules. Further inhibition strategies, combining VWF-A1, U0126 and NF449 in WT and TG mice and resulting in occlusion in various time windows, identified that inhibition by VWF-A1 largely abrogated the ERK2 contribution to thrombosis. In conclusion, P2X(1) and ERK2 both participate in shear stress controlled thrombosis, but ERK2 activation is initiated predominantly via GPIb-VWF interactions.

The ATP-gated P2X1 ion channel acts as a positive regulator of platelet responses to collagen.

ATP is a potent agonist of the P2X1 ion channel, mediating a rapid, quickly desensitized influx of Ca2+. In hirudinized PRP, containing apyrase, the two stable selective P2X1 agonists, alpha,beta-methylene ATP, and L-beta,gamma-methylene ATP induced extracellular Ca2+-dependent fast and reversible platelet shape change, leading to desensitization of the P2X1 ion channel. Preincubation with HPLC-purified ADP potently antagonized the subsequent alpha,beta-methylene ATP- and L-beta,gamma-methylene ATP-evoked platelet shape change. Accordingly, upon heterologous expression of P2X1 in Xenopus oocytes. HPLC-purified ADP acted as an antagonist of the ATP-induced current, but was inactive itself. Since ATP and ADP are co-released from dense granules during platelet activation, we investigated whether the P2X1 ion channel is involved in the response of platelets to collagen. We found that platelet shape change and aggregation induced by low concentrations of collagen were strongly inhibited after selective desensitization of P2X1 with its agonists or by pretreating the platelets with a low concentration of ADP (0.5 microM), that antagonizes the P2X1 channel without desensitizing the P2Y1 receptor. Our data suggest that, during collagen-initiated platelet activation, the early secretion of ATP results in the activation of the P2X1 ion channel, which plays a role as a positive regulator of further platelet responses.

ADP receptors in platelet activation and aggregation.

ADP plays a central role in platelet aggregation. Activation of platelets via ADP proceeds via three membrane receptor proteins, two of which are coupled to a G protein and the third one constituting an ion channel mediating rapid Ca2+-influx. Via Ca2+-mobilization, the Gq-coupled P2Y1 receptor acts in concert with the Gi-coupled P2TAC receptor, which functions by lowering intracellular cAMP levels. The importance of Ca2+-influx via the P2X1 ion channel remains to be elucidated.

A natural dominant negative P2X1 receptor due to deletion of a single amino acid residue.

The P2X1 receptor belongs to a family of oligomeric ATP-gated ion channels with intracellular N and C termini and two transmembrane segments separating a large extracellular domain. Here, we describe a naturally occurring dominant negative P2X1 mutant. This mutant lacks one leucine within a stretch of four leucine residues in its second transmembrane domain (TM2) (amino acids 351-354). Confocal microscopy revealed proper plasma membrane localization of the mutant in stably transfected HEK293 cells. Nevertheless, voltage-clamped HEK293 cells expressing mutated P2X1 channels failed to develop an ATP or ADP-induced current. Furthermore, when co-expressed with the wild type receptor in Xenopus oocytes, the mutated protein exhibited a dose-dependent dominant negative effect on the normal ATP or ADP-induced P2X1 channel activity. These data indicate that deletion of a single apolar amino acid residue at the inner border of the P2X1 TM2 generates a nonfunctional channel. The inactive and dominant negative form of the P2X1 receptor may constitute a new tool for the study of the physiological role of this channel in native cells.