Excess of heme induces tissue factor-dependent activation of coagulation in mice

An excess of free heme is present in the blood during many types of hemolytic anemia. This has been linked to organ damage caused by heme-mediated oxidative stress and vascular inflammation. We investigated the mechanism of heme-induced coagulation activation in vivo. Heme caused coagulation activation in wild-type mice that was attenuated by an anti-tissue factor antibody and in mice expressing low levels of tissue factor. In contrast, neither factor XI deletion nor inhibition of factor XIIa-mediated factor XI activation reduced heme-induced coagulation activation, suggesting that the intrinsic coagulation pathway is not involved. We investigated the source of tissue factor in heme-induced coagulation activation. Heme increased the procoagulant activity of mouse macrophages and human PBMCs. Tissue factor-positive staining was observed on leukocytes isolated from the blood of heme-treated mice but not on endothelial cells in the lungs. Furthermore, heme increased vascular permeability in the mouse lungs, kidney and heart. Deletion of tissue factor from either myeloid cells, hematopoietic or endothelial cells, or inhibition of tissue factor expressed by non-hematopoietic cells did not reduce heme-induced coagulation activation. However, heme-induced activation of coagulation was abolished when both non-hematopoietic and hematopoietic cell tissue factor was inhibited. Finally, we demonstrated that coagulation activation was partially attenuated in sickle cell mice treated with recombinant hemopexin to neutralize free heme. Our results indicate that heme promotes tissue factor-dependent coagulation activation and induces tissue factor expression on leukocytes in vivo. We also demonstrated that free heme may contribute to thrombin generation in a mouse model of sickle cell disease

Sulindac Metabolism and Synergy with Tumor Necrosis Factor-α in a Drug-Inflammation Interaction Model of Idiosyncratic Liver Injury

Sulindac (SLD) is a nonsteroidal anti-inflammatory drug (NSAID) that has been associated with a greater incidence of idiosyncratic hepatotoxicity in human patients than other NSAIDs. In previous studies, cotreatment of rats with SLD and a modestly inflammatory dose of lipopolysaccharide (LPS) led to liver injury, whereas neither SLD nor LPS alone caused liver damage. In studies presented here, further investigation of this animal model revealed that the concentration of tumor necrosis factor-α (TNF-α) in plasma was significantly increased by LPS at 1 h, and SLD enhanced this response. Etanercept, a soluble TNF-α receptor, reduced SLD/LPS-induced liver injury, suggesting a role for TNF-α. SLD metabolites in plasma and liver were determined by LC/MS/MS. Cotreatment with LPS did not increase the concentrations of SLD or its metabolites, excluding the possibility that LPS contributed to liver injury through enhanced exposure to SLD or its metabolites. The cytotoxicities of SLD and its sulfide and sulfone metabolites were compared in primary rat hepatocytes and HepG2 cells; SLD sulfide was more toxic in both types of cells than SLD or SLD sulfone. TNF-α augmented the cytotoxicity of SLD sulfide in primary hepatocytes and HepG2 cells. These results suggest that TNF-α can enhance SLD sulfide-induced hepatotoxicity, thereby contributing to liver injury in SLD/LPS-cotreated rats

Inhibition of Factor XII Attenuates Prothrombotic Complications in Sickle Cell Mice

Sickle Cell Disease (SCD) is the most common inherited hemoglobinopathy, affecting millions worldwide. Although characterized by chronic hemolytic anemia and recurrent vaso-occlusive episodes, SCD is increasingly recognized as a hypercoagulable state. Indeed, SCD patients have an 11-25% incidence of venous thromboembolism at a median age of 30 years, associated with a 3-fold increased risk of mortality. Moreover, ischemic stroke and silent cerebral infarctions occur in 7-13% of SCD patients. We have previously shown that tissue factor, an initiator of the extrinsic coagulation pathway, contributes to thrombo-inflammation and microvascular cerebral thrombosis in mouse models of SCD . Recently, the intrinsic coagulation pathway, including Factor XII (FXII), has received significant attention because targeting components of this pathway reduces thrombosis without affecting primary hemostasis. We have shown that FXII deficiency reduces plasma markers of thrombin generation and inflammation in sickle mice. However, the contribution of FXII to thrombosis and prothrombotic complications in SCD is not known. In this study we evaluated the effects of blocking FXII activity on venous thrombosis and ischemia/reperfusion (IR)-induced brain injury in SCD mice. First, Townes HbSS mice (SS) and non-sickle Townes HbAA controls (AA) (male and female, 16 weeks) received anti-FXII antibody or control IgGκ1 (10 mg/kg, IV) 30 minutes prior to subjecting them to venous thrombosis, initiated by applying positive current (3 volts, 90 sec) to the femoral vein. To visualize platelet and fibrin accumulation, mice were injected with rhodamine 6G and anti-fibrin antibody 59D8 labeled with Alexa Fluor 647, respectively. The femoral vein thrombi were imaged by intravital fluorescence microscopy using time-lapse capture every 10 seconds, to acquire images of fibrin and platelets over 60 min. The accumulation of platelets and fibrin was quantified for relative intensity of each fluorophore over the region of the observed thrombus. As previously shown, thrombi of SS/IgG mice showed an increased fibrin and platelet accumulation compared to AA/IgG group. Importantly, 15D10 treatment significantly attenuated both fibrin (p<0.001) and platelet (p<0.05) deposition over time in SS mice compared to SS/IgG group. The same effect of 15D10 treatment was observed in AA mice. At the end of experiment, clots were collected and stained with hematoxylin and eosin, and clot volume was assessed histomorphometrically (Nikon Ti-2, FIJI Software). Surprisingly, despite higher fibrin content, clots from SS/IgG mice had significantly smaller volume than clots from AA/IgG group (0.32 ± 0.04 versus 0.60 ± 0.11 mm 3, p<0.05). Importantly, administration of 15D10 significantly reduced clot volume in both SS (0.086 ± 0.01 mm 3, p<0.05) and AA mice (0.1 ± 0.02 mm 3, p<0.05). Next, AA and SS mice (male and female, 8-10 weeks) were subjected to brain IR injury induced by middle cerebral artery occlusion for 60 minutes followed by 24 hours of reperfusion (mouse model of ischemic stroke). 15D10 or control IgGκ1 (10 mg/kg, IV) were injected 30 minutes before occlusion and again at 6 hours into the reperfusion period to generate 3 experimental groups: AA/IgG, SS/IgG and SS/15D10. All analyzed parameters of brain IR injury were significantly worse in the SS/IgG group compared to the AA/IgG group. Compared to IgG, pre-treatment of SS mice with 15D10 significantly attenuated neuronal damage determined by volume of brain infarction (11.7 ± 3.7 vs 24.9 ± 2.4%, p<0.001) and improved behavioral deficit assessed by mean stroke score (9.0 ± 0.9 vs 14.6 ± 0.9, p<0.01). These changes were accompanied by a significant increase in leukocytes rolling (1978.0 ± 93.5 vs 1517.0 ± 180.3 rolling leukocytes/sec/mm 2, p<0.001), and significant reduction in the number of adherent leukocytes (367.2 ± 49.0 vs 723.4 ± 48.5, adherent leukocytes/mm 2, p<0.001) observed in the brain microvasculature of SS mice treated with 15D10 compared to SS/IgG group. Together, our data indicates that in the mouse model of SCD FXII contributes to the experimental venous thrombosis and ischemic stroke. Given that targeting the intrinsic pathway can reduce thrombosis without affecting hemostasis, our data suggest that targeting FXII might be a beneficial treatment in reducing inflammatory and thrombotic complications in SCD patients without a risk of bleeding

Excess of heme induces tissue factor-dependent activation of coagulation in mice

An excess of free heme is present in the blood during many types of hemolytic anemia. This has been linked to organ damage caused by heme-mediated oxidative stress and vascular inflammation. We investigated the mechanism of heme-induced coagulation activation in vivo. Heme caused coagulation activation in wild-type mice that was attenuated by an anti-tissue factor antibody and in mice expressing low levels of tissue factor. In contrast, neither factor XI deletion nor inhibition of factor XIIa-mediated factor XI activation reduced heme-induced coagulation activation, suggesting that the intrinsic coagulation pathway is not involved. We investigated the source of tissue factor in heme-induced coagulation activation. Heme increased the procoagulant activity of mouse macrophages and human PBMCs. Tissue factor-positive staining was observed on leukocytes isolated from the blood of heme-treated mice but not on endothelial cells in the lungs. Furthermore, heme increased vascular permeability in the mouse lungs, kidney and heart. Deletion of tissue factor from either myeloid cells, hematopoietic or endothelial cells, or inhibition of tissue factor expressed by non-hematopoietic cells did not reduce heme-induced coagulation activation. However, heme-induced activation of coagulation was abolished when both non-hematopoietic and hematopoietic cell tissue factor was inhibited. Finally, we demonstrated that coagulation activation was partially attenuated in sickle cell mice treated with recombinant hemopexin to neutralize free heme. Our results indicate that heme promotes tissue factor-dependent coagulation activation and induces tissue factor expression on leukocytes in vivo. We also demonstrated that free heme may contribute to thrombin generation in a mouse model of sickle cell disease