Inhibition of platelet aggregation by CO released by a novel, water-soluble CORM is not mediated by activation of soluble guanylate cyclase. In contrast to NO and PGI(2), CO effectively inhibits platelets even when cells are activated excessively. We suggest that despite the fact that CO is not a potent inhibitor of platelet activation, it may gain importance when NO and PGI(2) alone are insufficient to overcome excessive platelet activation.
SummaryArachidonic acid (AA)-induced platelet aggregation was studied in platelet-rich plasma of 30 male patients who survived myocardial infarction and in 30 healthy men of similar age. Mean platelet aggregation thresholds to A A were 746 ± 62 μM, and 869 ± 57 μM, respectively. Only in 2 healthy subjects, but in 12 patients, irreversible platelet aggregation was induced consistently with low concentrations of AA, under 500 μM. The rate of conversion of AA to thromboxane A2 (TXA2) by platelets of these patients was augmented. Furthermore, less endogenous TXA2 was required to trigger aggregation of their platelets as compared to the controls. We have also shown that in platelet-poor plasma of these patients with “hyperreactive” platelets there exists a transferable factor which makes platelets of healthy subjects more prone to aggregatory action of AA.It is proposed that the assessment of platelet aggregability with AA provides a tool for identifying a subgroup of patients with coronary heart disease who might substantially benefit from the secondary preventive treatment with aspirin and with other antiplatelet drugs which inhibit the generation of TXA2 in platelets.
Two in vitro and one in vivo assay were performed to study the endothelial pleiotropic actions of “tissue type” angiotensin converting enzyme inhibitors (ACE‐Is) such as perindopril and quinapril, their active forms, that is, quinaprilat and peridoprilat, or of statins belonging to natural (lovastatin), semisynthetic (simvastatin), and synthetic enantiomeric (atorvastatin, cerivastatin) classes. Cytoplasmic [Ca2+]i levels in cultured bovine aortic endothelial cells and endothelium‐dependent nitric oxide‐mediated coronary vasodilatation in the Langendorff preparation of guinea pig heart constituted our in vitro assays. The in vivo assay consisted of study of PGI2‐mediated thrombolytic response in arterial blood of rats after intravenous administration of drugs. In this last assay, perindopril and quinapril proved to be, by two orders of magnitude, more potent PGI2‐dependent thrombolytics than the most potent statin (atorvastatin). However, in both in vitro assays we found a higher endothelial efficacy of statins as compared to ACE‐Is. In particular, those statins that contain the lactone ring in their molecules (lovastatin, simvastatin) were the most potent coronary vasodilators. In summary, the in vivo profile of action of ACE‐Is and statins contrasted with their reversed order of potency in vitro. We hypothesize that the endocrine‐like function of the pulmonary circulation [28‐31] may be responsible for the in vivo bradykinin‐triggered, PGI2‐mediated thrombolysis by ACE‐Is, whereas the pleiotropic action of statins, possibly involving inhibition of prenylation [14‐19], is diffused throughout many vascular beds.
Healthy vascular endothelium is a powerful generator of nitric oxide (NO), prostacyclin (PGI2), prostaglandin E2 (PGE2), and plasminogen activator (t-PA). These endothelial products protect vascular wall against aggression from activated blood platelets and leukocytes. In particular they protect against thrombosis, promote thrombolysis, maintain tissue perfusion, and inhibit remodeling of vascular and cardiac walls. Endothelial dysfunction appears on one hand as suppression in the release of the above mediators, and on the other as deleterious discharge of prostaglandin endoperoxides (PGH2, PGG2), superoxide anion O2-, peroxynitrite (ONOO-), and plasminogen activator inhibitor (PAI-1). Our data point to endothelial bradykinin (Bk) as a trigger for protective endothelial mechanisms. In cultured endothelial cells (CEC) Bk through kinin B2 receptors raised in a concentration-dependent manner (1pM-10 nM) free cytoplasmic calcium ions [Ca2+]i. This rise was accompanied by the release of NO as quantified by a porphyrinic sensor. Other endothelial agonists were weaker-stimulators of [Ca2+]i than Bk. In vivo we analyed the effects of exogenous Bk and of amplifiers of endogenous Bk, such as perindopril and quinapril ("tissue type" angiotensin converting enzyme inhibitors, ACE-I) on endothelial function using our original thrombolytic bioassay and EIA assays for 6-keto-PGF1alpha and t-PA antigen. A major difference found between exogenuous Bk and endogenous Bk (that rendered by "tissue ACE-I") was a) prolonged thrombolytic action (> 4h) of quinapril or perindopril. Moreover, only exogenous Bk evoked an immediate and profound hypotensive action. In vivo, Bk-induced thrombolysis was B2 kinin receptor-dependent, PGI2-mediated. The unexpected action of Bk came to light in CEC. Then appeared incubated for 4 h increased expression of mRNAs for haemoxygenase (HO-1), cyclooxygenase 2 (COX-2), prostaglandin E synthase (PGE-S), but hardly for nitric oxide synthase 2(NOS-2). We hypothesize that a network of interactions of Bk-induced enzymes may constitute a delayed phase of Bk effects in the endothelium, whereas the primary phase would be activation by BK of [Ca2+]i-dependent constitutive endothelial enzymes. In blood-perfused rat endotoxemic lungs, NO is the most eminent cytoprotective mediator. Summing up, in peripheral circulation endogenous Bk is the most efficient activator of protective endothelial function. Thrombolytic action of "tissue-type" ACE-Is relies on receptor B-2-mediated, [Ca2+]i-dependent release of PGI2. Bk also may act as a "microcytokine" by inducing mRNAs for HO-1, COX-2, or PGE-S. Activation of HO-1 may lead to a deficiency in intracellular heme required as a cofactor for both COX and NOS. This network of interactions triggered by Bk call for further studies.
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