Exosite binding drives substrate affinity for the activation of coagulation factor X by the intrinsic Xase complex.

Factor X activation by the intrinsic Xase complex, composed of factor IXa bound to factor VIIIa on membranes, is essential for the amplified blood coagulation response. The biological significance of this step is evident from bleeding arising from deficiencies in factors VIIIa or IXa in hemophilia. Here, we assess the mechanism(s) that enforce the distinctive specificity of intrinsic Xase for its biological substrate. Active-site function of IXa was assessed with a tripeptidyl substrate (PF-3688). The reversible S1 site binder, 4-aminobenzamidine (pAB), acted as a classical competitive inhibitor of PF-3688 cleavage by Xase. In contrast, pAB acted as a noncompetitive inhibitor of factor X activation. This disconnect between peptidyl substrate and protein substrate cleavage indicates a major role for interactions between factor X and extended sites on Xase in determining substrate affinity. Accordingly, an uncleavable factor X variant, not predicted to engage the active site of IXa within Xase, acted as a classical competitive inhibitor of factor X activation. Fluorescence studies confirmed the binding of factor X to Xase assembled with IXa with a covalently blocked active site. Our findings suggest that the recognition of factor X by the intrinsic Xase complex occurs through a multistep "dock-and-lock" pathway in which the initial interaction between factor X and intrinsic Xase occurs at exosites distant from the active site, followed by active-site docking and bond cleavage.

Differential ability of tissue factor antibody clones on detection of tissue factor in blood cells and microparticles.

INTRODUCTION: Tissue factor (TF), the primary initiator of coagulation in vivo, plays a major role in both thrombosis and hemostasis. The expression of TF in monocytes is well documented, but its presence in other blood cells has been disputed, possibly due to methodological variations among different studies. MATERIALS AND METHODS: We studied TF expression on platelets, monocytes, lymphocytes and microparticles (MPs) by flow cytometry (FCM) with five commercially available mouse anti-human TF antibodies (HTF-1, TF9-10H10, CLB/TF-5, VIC7 and VD8). The ability of different TF antibodies to inhibit cell surface TF activity was explored by incubating LPS-stimulated monocytes and MPs derived from LPS-stimulated monocytes (MMPs) with TF antibodies followed by measuring TF activity. RESULTS: HTF-1 detected TF only on LPS-stimulated monocytes, whereas, TF9-10H10 and VD8 detected TF associated with MPs and MMPs in addition to LPS stimulated monocytes. Surprisingly, CLB/TF-5 and VIC7 detected TF on platelets, monocytes even under unstimulated conditions, in addition to MPs and MMPs. CLB/TF-5 also detected TF on unstimulated lymphocytes. Inhibitory studies showed that at a final concentration of 10 µg/mL, HTF-1, CLB/TF-5 and VD8 inhibited monocyte TF activity by 81-84% and MMP TF activity by 92-96%; whereas TF9-10H10 had no inhibitory effect on TF activity in monocytes and MMPs. CONCLUSIONS: Our results suggest non-specific binding by the CLB/TF-5 and VIC7 antibodies in a FCM test system and explain at least some of the reports on TF presence in blood cells, particularly TF associated with platelets and MPs. TF9-10H10 and VD8 are more suitable to detect TF on MPs by FCM.

Circulating monocytes mirror the imbalance in TF and TFPI expression in carotid atherosclerotic plaques with lipid-rich and calcified morphology.

BACKGROUND: Thrombogenicity of atherosclerotic plaque largely depends on plaque morphology and their content of tissue factor (TF) and tissue factor pathway inhibitor (TFPI). The relationship between morphological composition of plaque (lipid-rich or calcified) and expression of TF and TFPI in circulating blood monocytes and within the plaques is not characterized. OBJECTIVE: To investigate whether lipid-rich (echolucent) or calcified (echogenic) morphology of carotid atherosclerotic plaques is associated with differences in TF and TFPI expression in circulating blood monocytes and within carotid atherosclerotic plaques. METHODS: We studied levels of monocyte TF and TFPI mRNA and protein expression and association with traditional risk factors for atherosclerosis in asymptomatic subjects with echolucent (n=20) or echogenic (n=20) carotid plaques, or controls without carotid atherosclerosis (n=20) determined by ultrasonography. Sections of calcified or lipid-rich carotid plaques obtained from symptomatic patients were assessed for TF and TFPI antigen expression. RESULTS: TF and TFPI surface presentation, surface TF/TFPI ratio, and TF activity were higher in monocytes obtained from subjects with echolucent than with echogenic plaques or controls without carotid atherosclerosis. Multiple regression analyses revealed inverse association between serum apoA1 and monocyte surface TF antigen expression (p=0.007), and positive association between serum apoB and monocyte surface TFPI expression (p=0.028). Sections from lipid-rich carotid plaques contained 2.5-fold more TF and 1.5-fold more TFPI antigens relative to calcified lesions, also yielding a higher TF/TFPI ratio. CONCLUSIONS: Our findings indicate that circulating monocytes of asymptomatic individuals with echolucent lipid-rich carotid atherosclerosis express an imbalance between TF and TFPI expression cohering with changes found within advanced carotid atherosclerotic plaques obtained from symptomatic patients.

The role of TFPI in regulation of TF-induced thrombogenicity on the surface of human monocytes.

INTRODUCTION: Although the procoagulant reactivity of monocytes largely depends on expression and cell surface presentation of tissue factor (TF), little is known about the impact of tissue factor pathway inhibitor (TFPI) on regulation of TF function on the monocyte surface. MATERIALS AND METHODS: Peripheral blood mononuclear cells (PBMCs) were isolated from blood of healthy subjects and cryopreserved. We investigated TF and TFPI mRNA expression by reverse transcription-quantitative real-time PCR (RT-qPCR), surface presentation by flow cytometry and confocal microscopy, and TFPI-mediated regulation of TF functional activity on the surface of resting and LPS-stimulated PBMCs by TF activity assay and Calibrated Automated Thrombogram (CAT) assay. RESULTS: Unstimulated PBMCs contained nearly no TF, but detectable TFPI protein levels. TFPI mRNA levels were 2-fold higher than TF, and the TFPIα mRNA isoform expression was higher than TFPIß. LPS stimulation caused a parallel and sustained upregulation of both TFPI isoforms, concomitant with increased surface presentation of TFPI antigen. Stronger, but transient upregulation of TF mRNA and surface antigen was observed at 6hrs of LPS stimulation. After LPS stimulation TF and TFPI were co-localized in the same areas of the monocyte membrane. Pre-incubation of PBMCs with anti-TFPI IgG significantly enhanced TF activity, shortened Lag-time, and increased thrombin generation. TFPI-dependent inhibition of TF was more prominent in resting than in LPS-stimulated cells. CONCLUSIONS: Our results support the concept that surface TFPI is an important regulator of procoagulant reactivity of human monocytes.