Platelets do not express the oxidized or reduced forms of tissue factor.

BACKGROUND: Expression of tissue factor (TF) antigen and activity in platelets is controversial and dependent upon the laboratory and reagents used. Two forms of TF were described: an oxidized functional form and a reduced nonfunctional form that is converted to the active form through the formation of an allosteric disulfide. This study tests the hypothesis that the discrepancies regarding platelet TF expression are due to differential expression of the two forms. METHODS: Specific reagents that recognize both oxidized and reduced TF were used in flow cytometry of unactivated and activated platelets and western blotting of whole platelet lysates. TF-dependent activity measurements were used to confirm the results. RESULTS: Western blotting analyses of placental TF demonstrated that, in contrast to anti-TF#5, which is directed against the oxidized form of TF, a sheep anti-human TF polyclonal antibody recognizes both the reduced and oxidized forms. Flow cytometric analyses demonstrated that the sheep antibody did not react with the surface of unactivated platelets or platelets activated with thrombin receptor agonist peptide, PAR-1. This observation was confirmed using biotinylated active site-blocked factor (F)VIIa: no binding was observed. Likewise, neither form of TF was detected by western blotting of whole platelet lysates with sheep anti-hTF. Consistent with these observations, no FXa or FIXa generation by FVIIa was detected at the surface of these platelets. Similarly, no TF-related activity was observed in whole blood using thromboelastography. CONCLUSION AND SIGNIFICANCE: Platelets from healthy donors do not express either oxidized (functional) or reduced (nonfunctional) forms of TF.

Factor XIa and tissue factor activity in patients with coronary artery disease.

It has been established that inflammation and enhanced pro-coagulant activity are associated with the pathogenesis of atherosclerotic vascular disease. We evaluated and compared the contributions of the factor (F)XIa and tissue factor (TF) activity in plasma of patients with coronary artery disease (CAD). Citrate plasma was obtained prior to therapy from 53 patients with stable angina (29 with a history of previous myocardial infarction; CAD-MI) and 30 with acute coronary syndrome (ACS) within 12 hours from pain onset. Four ACS patients treated with heparin were excluded. FXIa and TF activity were determined in clotting assays based upon the prolongation of clotting time by inhibitory monoclonal antibodies. Twenty-five of 26ACS patients (96%) and 22 of 29 CAD-MI patients (76%) had quantifiable FXIa (50 +/- 33 and 42 +/- 45pM, respectively). Ten of 26 (38%) ACS patients and only three of 53 (6%) stable CAD patients showed TF activity (<0.4pM). No FXIa or TF activity was observed in age-matched healthy controls (n = 12). For both CAD-MI and ACS patients, there were correlations (p < 0.05) between FXIa and interleukin-6 (R(2) = 0.59 and 0.39, respectively) and between FXIa and TAT (R(2) = 0.64 and 0.63, respectively). In conclusion, the majority of ACS and CAD-MI patients have circulating FXIa that correlates with markers of coagulation and inflammation.

The significance of circulating factor IXa in blood.

The presence of activation peptides (AP) of the vitamin K-dependent proteins in the phlebotomy blood of human subjects suggests that active serine proteases may circulate in blood as well. The goal of the current study was to evaluate the influence of trace amounts of key coagulation proteases on tissue factor-independent thrombin generation using three models of coagulation. With procoagulants and select coagulation inhibitors at mean physiological concentrations, concentrations of factor IXa, factor Xa, and thrombin were set either equal to those of their AP or to values that would result based upon the rates of AP/enzyme generation and steady state enzyme inhibition. In the latter case, numerical simulation predicts that sufficient thrombin to produce a solid clot would be generated in approximately 2 min. Empirical data from the synthetic plasma suggest clotting times of 3-5 min, which are similar to that observed in contact pathway-inhibited whole blood (4.3 min) initiated with the same concentrations of factors IXa and Xa and thrombin. Numerical simulations performed with the concentrations of two of the enzymes held constant and one varied suggest that the presence of any pair of enzymes is sufficient to yield rapid clot formation. Modeling of states (numerical simulation and whole blood) where only one circulating protease is present at steady state concentration shows significant thrombin generation only for factor IXa. The addition of factor Xa and thrombin has little effect (if any) on thrombin generation induced by factor IXa alone. These data indicate that 1) concentrations of active coagulation enzymes circulating in vivo are significantly lower than can be predicted from the concentrations of their AP, and 2) expected trace amounts of factor IXa can trigger thrombin generation in the absence of tissue factor.