A. Koneti Rao

Surface-bound heparin fails to reduce thrombin formation during clinical cardiopulmonary bypass.

The hypothesis that heparin-coated perfusion circuits reduce thrombin formation and activity; fibrinolysis; and platelet, complement, and neutrophil activation was tested in 20 consecutive, randomized adults who had cardiopulmonary bypass. Twenty identical perfusion systems were used; in 10, all blood-contacting surfaces were coated with partially degraded heparin (Carmeda process; Medtronic Cardiopulmonary, Anaheim, Calif.). All patients received a 300 U/kg dose of heparin. Activated clotting times were maintained longer than 400 seconds. Cardiopulmonary bypass lasted 36 to 244 minutes. Blood samples for platelet count, platelet response to adenosine diphosphate, plasma beta-thromboglobulin, inactivated complement 3b, neutrophil elastase, fibrinopeptide A, prothrombin fragment F1.2, thrombin-antithrombin complex, tissue plasminogen activator, plasminogen activator inhibitor-1, plasmin alpha 2-antiplasmin complex, and D-dimer were obtained at these times: after heparin was given, 5 and 30 minutes after cardiopulmonary bypass was started, within 5 minutes after bypass was stopped, and 15 minutes after protamine was given. After cardiopulmonary bypass, tubing segments were analyzed for surface-adsorbed anti-thrombin, fibrinogen, factor XII, and von Willebrand factor by radioimmunoassay. Heparin-coated circuits significantly (p < 0.001) reduced platelet adhesion and maintained platelet sensitivity to adenosine diphosphate (p = 0.015), but did not reduce release of beta-thromboglobulin. There were no significant differences between groups at any time for fibrinopeptide A, prothrombin fragment F1.2, or thrombin-antithrombin complex or in the markers for fibrinolysis: D-dimer, tissue plasminogen activator, plasminogen activator inhibitor-1, and alpha 2-antiplasmin complex. In both groups, concentrations of prothrombin fragment F1.2 and thrombin-antithrombin complex increased progressively and significantly during cardiopulmonary bypass and after protamine was given. Concentrations of D-dimer, alpha 2-antiplasmin complex, and plasminogen activator inhibitor-1 also increased significantly during bypass in both groups. Fibrinopeptide A levels did not increase during bypass but in both groups increased significantly after protamine was given. No significant differences were observed between groups for levels of inactivated complement 3b or neutrophil elastase. Radioimmunoassay showed a significant increase in surface-adsorbed antithrombin on coated circuits but no significant differences between groups for other proteins. We conclude that heparin-coated circuits used with standard doses of systemic heparin reduce platelet adhesion and improve platelet function but do not produce a meaningful anticoagulant effect during clinical cardiopulmonary bypass. The data do not support the practice of reducing systemic heparin doses during cardiac operations with heparin-coated extracorporeal perfusion circuitry.

Platelet and monocyte activation by hyperglycemia and hyperinsulinemia in healthy subjects

Type 2 diabetes mellitus (T2DM) patients have hyperglycemia and hyperinsulinemia and increased risk of atherosclerosis and acute vascular complications. We have reported elevated circulating tissue factor procoagulant activity (TF-PCA) during hyperglycemia (HG) and hyperinsulinemia (HI) in normal subjects. To evaluate the effect of hyperglycemia and hyperinsulinemia on blood cell activation, we assessed platelet CD40L and P-selectin, monocyte tissue factor (TF), and the formation of monocyte–platelet and neutrophil–platelet aggregates. These were assessed in the resting state and following activation with ADP and thrombin (SFLLRN). Healthy individuals were subjected to 24 h of hyperglycemia and hyperinsulinemia, selective hyperglycemia, selective hyperinsulinemia, or normal glucose and insulin. Platelet CD40L expression increased with high glucose/high insulin, selective hyperglycemia and selective hyperinsulinemia. Monocyte–platelet aggregates increased with high glucose/high insulin. Monocyte TF expression increased with high glucose/high insulin and with selective hyperinsulinemia. Upon stimulation with ADP and SFLLRN, monocyte–platelet and neutrophil–platelet aggregates, platelet CD40L and P-selectin, and monocyte TF increased compared to the resting state but was not different between 0 and 24 h, indicating that the responsiveness to those agonists was not altered. Conclusions: Hyperglycemia–hyperinsulinemia in healthy individuals induced platelet activation and monocyte TF expression promoting a procoagulant and proinflammatory state that may contribute to acute vascular events and atherogenesis. Platelet responsiveness to activation with ADP or SFLLRN appears not to be altered by hyperglycemia–hyperinsulinemia.

A prospective study of platelets and plasma proteolytic systems during the early stages of Rocky Mountain spotted fever.

We prospectively examined early changes in platelets and plasma proteolytic systems in 12 vaccinated and 6 unvaccinated volunteers in whom Rocky Mountain spotted fever developed after challenge with Rickettsia rickettsii. The platelet counts declined while the plasma concentration of beta-thromboglobulin and the ratio of beta-thromboglobulin to platelet factor 4 increased, indicating in vivo activation of platelets. Plasma levels of antithrombin III decreased and levels of fibrinopeptide A increased, indicating in vivo activation of the coagulation system. Plasma fibrinogen levels peaked at 24 hours and gradually declined; this is consistent with the behavior of fibrinogen as an acute-phase reactant. Prolongation of the prothrombin time and a decrease in plasma levels of factor VII in the absence of evidence of liver injury suggested possible activation of the extrinsic pathway of coagulation. A decline in plasma prekallikrein levels with an increase in plasma C1-inhibitor-kallikrein complexes suggested activation of kallikrein, probably through the intrinsic coagulation system. Elevations in levels of plasma fibrin-degradation products and alpha 2-antiplasmin-plasmin complexes with declines in plasminogen and alpha 2-antiplasmin levels provided evidence of activation of the fibrinolytic system. Elevated plasma levels of tissue plasminogen activator and von Willebrand factor reflected endothelial stimulation. Thus, even early in the course of Rocky Mountain spotted fever that is treated promptly, there is activation of platelets, coagulation pathways, and the fibrinolytic system. These changes may be related to endothelial perturbation, a major pathogenetic mechanism in the disorder.

Regulation of platelet myosin light chain (MYL9) by RUNX1: implications for thrombocytopenia and platelet dysfunction in RUNX1 haplodeficiency

Mutations in transcription factor RUNX1 are associated with familial platelet disorder, thrombocytopenia, and predisposition to leukemia. We have described a patient with thrombocytopenia and impaired agonist-induced platelet aggregation, secretion, and glycoprotein (GP) IIb-IIIa activation, associated with a RUNX1 mutation. Platelet myosin light chain (MLC) phosphorylation and transcript levels of its gene MYL9 were decreased. Myosin IIA and MLC phosphorylation are important in platelet responses to activation and regulate thrombopoiesis by a negative regulatory effect on premature proplatelet formation. We addressed the hypothesis that MYL9 is a transcriptional target of RUNX1. Chromatin immunoprecipitation (ChIP) using megakaryocytic cells revealed RUNX1 binding to MYL9 promoter region -729/-542 basepairs (bp), which contains 4 RUNX1 sites. Electrophoretic mobility shift assay showed RUNX1 binding to each site. In transient ChIP assay, mutation of these sites abolished binding of RUNX1 to MYL9 promoter construct. In reporter gene assays, deletion of each RUNX1 site reduced activity. MYL9 expression was inhibited by RUNX1 short interfering RNA (siRNA) and enhanced by RUNX1 overexpression. RUNX1 siRNA decreased cell spreading on collagen and fibrinogen. Our results constitute the first evidence that the MYL9 gene is a direct target of RUNX1 and provide a mechanism for decreased platelet MYL9 expression, MLC phosphorylation, thrombocytopenia, and platelet dysfunction associated with RUNX1 mutations.

RUNX1/core binding factor A2 regulates platelet 12-lipoxygenase gene (ALOX12): studies in human RUNX1 haplodeficiency.

Haploinsufficiency of RUNX1 (also known as CBFA2/AML1) is associated with familial thrombocytopenia, platelet dysfunction, and predisposition to acute leukemia. We have reported on a patient with thrombocytopenia and impaired agonist-induced aggregation, secretion, and protein phosphorylation associated with a RUNX1 mutation. Expression profiling of platelets revealed approximately 5-fold decreased expression of 12-lipoxygenase (12-LO, gene ALOX12), which catalyzes 12-hydroxyeicosatetraenoic acid production from arachidonic acid. We hypothesized that ALOX12 is a direct transcriptional target gene of RUNX1. In present studies, agonist-induced platelet 12-HETE production was decreased in the patient. Four RUNX1 consensus sites were identified in the 2-kb promoter region of ALOX12 (at -1498, -1491, -708, -526 from ATG). In luciferase reporter studies in human erythroleukemia cells, mutation of each site decreased activity; overexpression of RUNX1 up-regulated promoter activity, which was abolished by mutation of RUNX1 sites. Gel shift studies, including with recombinant protein, revealed RUNX1 binding to each site. Chromatin immunoprecipitation revealed in vivo RUNX1 binding in the region of interest. siRNA knockdown of RUNX1 decreased RUNX1 and 12-LO proteins. ALOX12 is a direct transcriptional target of RUNX1. Our studies provide further proof of principle that platelet expression profiling can elucidate novel alterations in platelets with inherited dysfunction.

TISSUE FACTOR-POSITIVE MONOCYTES IN CHILDREN WITH SICKLE CELL DISEASE: CORRELATION WITH BIOMARKERS OF HAEMOLYSIS

Tissue Factor (TF) initiates thrombin generation, and whole blood TF (WBTF) is elevated in sickle cell disease (SCD). We sought to identify the presence of TF‐positive monocytes in SCD and their relationship with the other coagulation markers including WBTF, microparticle‐associated TF, thrombin‐antithrombin (TAT) complexes and D‐dimer. Whether major SCD‐related pathobiological processes, including haemolysis, inflammation and endothelial activation, contribute to the coagulation abnormalities was also studied. The cohort comprised children with SCD (18 HbSS, 12 HbSC, mean age 3·6 years). We demonstrated elevated levels of TF‐positive monocytes in HbSS, which correlated with WBTF, TAT and D‐dimer (P = 0·02 to P = 0·0003). While TF‐positive monocytes, WBTF, TAT and D‐dimer correlated with several biomarkers of haemolysis, inflammation and endothelial activation in univariate analyses, in multiple regression models the haemolytic markers (reticulocytes and lactate dehydrogenase) contributed exclusively to the association with all four coagulant markers evaluated. The demonstration that haemolysis is the predominant operative pathology in the associated perturbations of coagulation in HbSS at a young age provides additional evidence for the early use of therapeutic agents, such as hydroxycarbamide to reduce the haemolytic component of this disease.

Contribution of thrombogenic factors to the pathogenesis of atherosclerosis

H UMAN atherosclerosis can be defined as a disease process, caused by multiple pathogenic factors, which starts in childhood and decades later produces occlusive lesions and clinical symptoms. The intima is the cell layer principally involved in atherosclerosis although secondary changes are occasionally found in the media. According to McGill’ the earliest discernible change in human coronary arteries and aortas after birth is a diffuse thickening of the musculoelastic intima. In the later stages of life three different types of lesions can be identified: the fatty streak, the fibrous plaque and the complicated lesions.2,3 The fatty streak consists of a focal accumulation of a small number of intimal smooth muscle cells surrounded by deposits of lipids. The fibrous plaque protrudes into the lumen of the artery. It contains a number of lipid laden smooth muscle cells surrounded by lipid, collagen, elastic fibers and proteoglycans. The complicated lesion appears to be a fibrous plaque that has become altered as a result of hemorrhage, calcification, cell necrosis and mural thrombosis. This type of lesion often becomes associated with occlusive disease. Some pathologists also delineate “gelatinous lesions” or gelatinous thickening or focal intimal edema, which may be the precursors of fibrous plaques.4.” The thrombogenic theory of atherosclerosis was first proposed 130 years ago by Carl von Rokitansky6 who described atheroma as an excessive deposition of blood products, particularly fibrin on the lining membrane of the vessels. von Rokitansky’s views were opposed by Virchow in 1856’ who regarded atheroma as an inflammatory process, and the “thickening as the product of a reactive proliferation on the part of the intimal connective tissue cells.” Virchow’s concept of ceIlular proliferation appears to be very valid today. It is compatible with a theory of smooth muscle proliferation that follows injury to the vessel wall’ and with a “monoclonal hypothesis” of the pathogenesis of atherosclerosis which suggests that each lesion is derived from a single smooth muscle cell that serves as a progenitor for the remaining proliferative cells.8 In the light of modern research demonstrating promotion of cell proliferation by platelet proteins and coagulant factors, the early concepts of atherosclerosis appear to be complimentary rather than contradictory. It is generally accepted that an abnormal metabolism of lipoproteins and lipids contributes significantly to the development of atherosclerosis. At the beginning of this century Ignatowski’ and Anitchkow and Chalatow” produced experimental atherosclerosis in rabbits fed on a cholesterol-enriched diet. On the last two decades a number of models of experimental atherosclerosis in animals fed with a fat-rich diet have been developed.“-‘6 In 1954 Page” proposed a filtration concept of atherosclerosis which was based on the view that atherogenesis is due to the tissue reaction to substances filtered from plasma such as lipoproteins which are deposited in the intima as foreign lipids. Gero et al’* demonstrated by means of immunoelectrophoresis that /3-lipoprotein is indeed present within the human atherosclerotic lesion. This observation was confirmed later by a quantitative immunoelectrophoretic technique developed by Smith et a14,5,‘9-2’ who demonstrated that low density lipoprotein (LDL) is selectively accumulated in the atherosclerotic lesions. It is well established, particularly by the Framingham study,‘3.24 that elevation of LDL and very low density lipoproteins (VLDL) in plasma predisposes to premature atherosclerosis. The occurrence of premature atherosclerosis in familial hyperlipoproteinemias is also well established.‘j Brown et a12h demonstrated the absence of LDL receptors on libroblasts in patients with familial hypercholesteremia. These receptors

Factor VIIa and tissue factor procoagulant activity in diabetes mellitus after acute ischemic stroke: Impact of hyperglycemia

Alterations in blood coagulation may explain the poorer neurological outcome with diabetes mellitus and hyperglycemia after acute ischemic stroke. We studied the relationships between diabetes mellitus, hyperglycemia, whole blood tissue factor procoagulant activity (TF-PCA) and plasma factorVIIa (FVIIa) in ten patients with type 2 diabetes mellitus and 11 non-diabetic patients at baseline and 6, 12, 24, and 48 hours (h) after presentation for acute stroke. In addition, we examined plasma prothrombin fragment 1+2 (F1.2) and thrombin-antithrombin complexes (TAT) as markers of thrombin generation. Stroke severity, assessed by National Institute of Health Stroke Scale (NIHSS), was similar at baseline (p=0.26) but worse in diabetic (8.20+/-4.3) than nondiabetic patients (2.67+/-2.1, p=0.023) at 48 h. At presentation, diabetic patients had higher FVIIa (p=0.004) and lower TF-PCA (p=0.027) than non-diabetic patients but both were higher than in normal control subjects. FVIIa levels remained higher in diabetic patients at 6, 12 and 24 h after stroke. In diabetic patients, FVIIa (r=0.40, p=0.02) and TF-PCA (r=0.50, p=0.02) correlated with blood glucose; and, FVIIa correlated with plasma F1.2 (r=0.34, p=0.002) and TAT levels (r=0.62, p<0.0001). In non-diabetic patients, TF-PCA, but not FVIIa, correlated with F1.2 (r=0.402, p=0.010) and TAT (r=0.39, p=0.011). Combining both groups, NIHSS scores were positively related to FVIIa levels (r=0.50, p=0.021) and inversely related to TF-PCA levels (r=-0.498, p=0.02). Acute ischemic stroke patients with diabetes and hyperglycemia have a more intense procoagulant state compared with nondiabetic patients. This is related to glucose levels and provides a potential mechanism for the observed worse prognosis in such patients after acute stroke.

Platelet microparticles infiltrating solid tumors transfer miRNAs that suppress tumor growth.

Platelet-derived microparticles (PMPs) are associated with enhancement of metastasis and poor cancer outcomes. Circulating PMPs transfer platelet microRNAs (miRNAs) to vascular cells. Solid tumor vasculature is highly permeable, allowing the possibility of PMP-tumor cell interaction. Here, we show that PMPs infiltrate solid tumors in humans and mice and transfer platelet-derived RNA, including miRNAs, to tumor cells in vivo and in vitro, resulting in tumor cell apoptosis. MiR-24 was a major species in this transfer. PMP transfusion inhibited growth of both lung and colon carcinoma ectopic tumors, whereas blockade of miR-24 in tumor cells accelerated tumor growth in vivo, and prevented tumor growth inhibition by PMPs. Conversely, Par4-deleted mice, which had reduced circulating microparticles (MPs), supported accelerated tumor growth which was halted by PMP transfusion. PMP targeting was associated with tumor cell apoptosis in vivo. We identified direct RNA targets of platelet-derived miR-24 in tumor cells, which included mitochondrial mt-Nd2, and Snora75, a noncoding small nucleolar RNA. These RNAs were suppressed in PMP-treated tumor cells, resulting in mitochondrial dysfunction and growth inhibition, in an miR-24-dependent manner. Thus, platelet-derived miRNAs transfer in vivo to tumor cells in solid tumors via infiltrating MPs, regulate tumor cell gene expression, and modulate tumor progression. These findings provide novel insight into mechanisms of horizontal RNA transfer and add multiple layers to the regulatory roles of miRNAs and PMPs in tumor progression. Plasma MP-mediated transfer of regulatory RNAs and modulation of gene expression may be a common feature with important outcomes in contexts of enhanced vascular permeability.

Effect of antiplatelet agents clopidogrel, aspirin, and cilostazol on circulating tissue factor procoagulant activity in patients with peripheral arterial disease

Tissue factor (TF) is the physiological initiating mechanism for blood coagulation. Platelets play an important role in monocyte TF expression, thrombosis and inflammation. Aspirin, clopidogrel and cilostazol, which inhibit platelet responses by different mechanisms, are widely used in patients with arterial diseases. We tested the hypothesis that platelet-inhibiting agents inhibit the levels of circulating TF procoagulant activity (TF-PCA) in patients with peripheral arterial disease (PAD). Twenty-six patients with lower extremity PAD, average age 65.9 +/- 8.4 years (mean +/- SEM), were studied at baseline and following sequential two-week treatment regimens with aspirin (325 mg daily), clopidogrel (75 mg daily) or a phosphodiesterase inhibitor cilostazol (100 mg twice daily) singly, and with each possible combination of these agents. Circulating TF-PCA in whole blood, and plasma factor VIIa, prothrombin fragment F1.2, thrombin-antithrombin complexes (TAT), and P-selectin were measured. Baseline TF-PCA levels in the patients were elevated (131 +/- 19 U/ml) compared to control subjects (23 +/- 2, p < 0.0001). TF-PCA levels declined following treatment with clopidogrel alone, and with combinations of clopidogrel with aspirin or cilostazol, with the lowest levels being with the triple-drug combination. Plasma P-selectin declined in all treatment groups. No changes were noted in plasma factor VIIa, F1.2 or TAT. In conclusion, treatment of PAD patients with antiplatelet agents decreases circulating TF, a molecule with prothrombotic and proinflammatory effects. These findings suggest an unrecognized mechanism, beyond inhibiting aggregation responses, for the efficacy of antiplatelet drugs in patients with arterial diseases.