Gary L. Ferrell

Thrombomodulin Mutations in Atypical Hemolytic–Uremic Syndrome

BACKGROUND The hemolytic-uremic syndrome consists of the triad of microangiopathic hemolytic anemia, thrombocytopenia, and renal failure. The common form of the syndrome is triggered by infection with Shiga toxin-producing bacteria and has a favorable outcome. The less common form of the syndrome, called atypical hemolytic-uremic syndrome, accounts for about 10% of cases, and patients with this form of the syndrome have a poor prognosis. Approximately half of the patients with atypical hemolytic-uremic syndrome have mutations in genes that regulate the complement system. Genetic factors in the remaining cases are unknown. We studied the role of thrombomodulin, an endothelial glycoprotein with anticoagulant, antiinflammatory, and cytoprotective properties, in atypical hemolytic-uremic syndrome. METHODS We sequenced the entire thrombomodulin gene (THBD) in 152 patients with atypical hemolytic-uremic syndrome and in 380 controls. Using purified proteins and cell-expression systems, we investigated whether thrombomodulin regulates the complement system, and we characterized the mechanisms. We evaluated the effects of thrombomodulin missense mutations associated with atypical hemolytic-uremic syndrome on complement activation by expressing thrombomodulin variants in cultured cells. RESULTS Of 152 patients with atypical hemolytic-uremic syndrome, 7 unrelated patients had six different heterozygous missense THBD mutations. In vitro, thrombomodulin binds to C3b and factor H (CFH) and negatively regulates complement by accelerating factor I-mediated inactivation of C3b in the presence of cofactors, CFH or C4b binding protein. By promoting activation of the plasma procarboxypeptidase B, thrombomodulin also accelerates the inactivation of anaphylatoxins C3a and C5a. Cultured cells expressing thrombomodulin variants associated with atypical hemolytic-uremic syndrome had diminished capacity to inactivate C3b and to activate procarboxypeptidase B and were thus less protected from activated complement. CONCLUSIONS Mutations that impair the function of thrombomodulin occur in about 5% of patients with atypical hemolytic-uremic syndrome.

Human Protein C Receptor Is Present Primarily on Endothelium of Large Blood Vessels Implications for the Control of the Protein C Pathway

BACKGROUND The protein C anticoagulant pathway is critical to the control of hemostasis. Thrombomodulin and a newly identified receptor for protein C/activated protein C, EPCR, are both present on endothelium. EPCR augments activation of protein C by the thrombin-thrombomodulin complex. METHODS AND RESULTS To gain a better understanding of the relationship between thrombomodulin and EPCR, we compared the cellular specificity and tissue distributions of these two receptors by using immunohistochemistry. EPCR expression was detected almost exclusively on endothelium in human and baboon tissues. In most organs, EPCR was expressed relatively intensely on the endothelium of all arteries and veins, most arterioles, and some postcapillary venules. EPCR staining was usually negative on capillary endothelial cells. In contrast, thrombomodulin was detected at high concentrations in both large vessels and capillary endothelium. Both thrombomodulin and EPCR were expressed poorly on brain capillaries. The liver sinusoids were the only capillaries in which EPCR was expressed at moderate levels and thrombomodulin was low. EPCR and thrombomodulin were both expressed on the endothelium of vasa recta in the renal medulla, the lymph node subcapsular and medullary sinuses, and some capillaries within the adrenal gland. Even in these organs the majority of capillaries were EPCR negative or stained weakly. CONCLUSIONS These studies suggest that EPCR may be important in enhancing protein C activation on large vessels. The presence of high levels of EPCR on arterial vessels may help explain why partial protein C deficiency is a weak risk factor for arterial thrombosis.

Overexpressing endothelial cell protein C receptor alters the hemostatic balance and protects mice from endotoxin.

Summary.  Previous studies have shown that blocking endothelial protein C receptor (EPCR)‐protein C interaction results in about an 88% decrease in circulating activated protein C (APC) levels generated in response to thrombin infusion and exacerbates the response to Escherichia coli. To determine whether higher levels of EPCR expression on endothelial cells might further enhance the activation of protein C and protect the host during septicemia, we generated a transgenic mouse (Tie2‐EPCR) line which placed the expression of EPCR under the control of the Tie2 promoter. The mice express abundant EPCR on endothelial cells not only on large vessels, but also on capillaries where EPCR is generally low. Tie2‐EPCR mice show higher levels of circulating APC after thrombin infusion. Upon infusion with factor Xa and phospholipids, Tie2‐EPCR mice generate more APC, less thrombin and are protected from fibrin/ogen deposition compared with wild type controls. The Tie2‐EPCR animals also generate more APC upon lipopolysaccharide (LPS) challenge and have a survival advantage. These results reveal that overexpression of EPCR can protect animals against thrombotic or septic challenge.

Activation of Protein C In Vivo

An endothelial cell-associated cofactor that greatly enhances the rate of protein C activation by thrombin has recently been described. The observation that the cofactor binds thrombin with unusually high affinity (K(d) = 0.5 nM) suggested that low level thrombin infusion into dogs might lead to the selective activation of protein C. Infusion of thrombin (1 U/min per kg body wt) into the jugular vein of dogs leads to the formation of a systemic anticoagulant activity within 5 min of starting the infusion. The plasma has a prolonged partial thromboplastin time and Factor X(a) clotting time, but there is no change in the thrombin clotting time. The systemic anticoagulant activity is identified as activated protein C for the following reasons: (a) anti-canine activated protein C IgG antibodies inhibit the anticoagulant activity; (b) the anticoagulant activity can be partially purified from the plasma of dogs infused with thrombin by barium citrate adsorption; (c) the anticoagulant has chromatographic properties on QAE Sephadex indistinguishable from those of activated protein C, and (d) the rate at which this anticoagulant is inhibited in citrated canine plasma is identical to that of canine activated protein C. The in vivo activation of protein C appears to be receptor mediated since it occurs at low thrombin concentration and since it can be progressively inhibited by simultaneous infusion of diisopropylphospho-thrombin with thrombin. The activation of protein C at low levels of thrombin is selective, since neither the platelet count nor the Factor V levels are altered. Thrombin infusion leads to an elevation in circulating plasminogen activator levels. This appears to be mediated through the activation of protein C since coinfusion of diisopropylphospho-thrombin with thrombin inhibits the increase in plasminogen activator levels. Pretreatment of dogs with dicumarol blocks both the formation of anticoagulant activity and the rise in plasminogen activator. When the dicumarol-treated dogs are supplemented with isolated protein C and thrombin is infused, the anticoagulant activity again appears and the circulating levels of plasminogen activator are again elevated. These studies illustrate that low levels of thrombin in vivo can activate protein C, which in turn can inhibit blood coagulation and initiate fibrinolysis by elevating circulating plasminogen activator levels.

A monoclonal antibody against activated protein C allows rapid detection of activated protein C in plasma and reveals a calcium ion dependent epitope involved in factor Va inactivation

Summary.  Activated protein C (APC) serves as an ‘on demand’ anticoagulant. Defects in the APC anticoagulant pathway are underlying risk factors for the development of venous and arterial thrombosis. APC has recently been shown to significantly reduce mortality in patients with severe sepsis, presumably by virtue of its ability to down‐regulate coagulation as well as inflammation. Our objective was to develop an assay that, for the first time, permits rapid detection of plasma APC. This assay will expedite studies of APC in a variety of vascular disease states including sepsis, severe atherosclerosis, diabetes, and vasculitis. By generating a highly APC‐specific monoclonal antibody (HAPC 1555), we have developed an assay that, for the first time, allows rapid detection of plasma APC. The Kd measured for the interaction between APC and HAPC 1555 based on BIAcore studies and binding to immobilized HAPC on microtiter plates is 6.2 ± 0.9 and 8.8 ± 1.0 nmol L−1, respectively. The interaction between HAPC 1555 and APC is Ca2+‐dependent, with a Ca2+ concentration of 313 ± 48 µmol L−1 required for half maximal binding. HAPC 1555 interferes with APC‐mediated inactivation of factor (F)Va in the presence and absence of phospholipids, suggesting that HAPC 1555 binds to the FVa binding domain of APC. When HAPC 1555 was used in an APC enzyme capture assay, therapeutic APC levels could be measured in 1.5 h, and physiologic levels of APC could be detected between 3 and 19 h. APC levels were also shown to vary markedly in patients with severe sepsis. The rapidity of our APC assay makes APC detection in patients practical clinically. This assay will expedite studies of APC in a variety of vascular disease states including sepsis, severe atherosclerosis, diabetes, and vasculitis.

Activated Protein C Protects Against Myocardial Ischemia/ Reperfusion Injury via Inhibition of Apoptosis and Inflammation

OBJECTIVE In spite of major advances in reperfusion therapy for patients presenting with acute coronary syndrome, long-term morbidity is still substantial. A limitation of initial treatment of myocardial ischemia is the lack of prevention of ischemia/reperfusion (I/R) injury. Activated protein C (APC), a crucial mediator in the coagulation process, plays a prominent role in the crosstalk between coagulation and inflammation and provides cytoprotective effects via inhibition of apoptosis and inflammation in several human and animal studies. METHODS AND RESULTS APC was administered in an animal model for myocardial I/R. APC largely inhibited early myocardial I/R injury after varying reperfusion times, an effect that was absent on administration of heparin, a nonspecific anticoagulant agent. The protective effects of APC were absent in case of absence or blockade of protease activated receptor-1 (PAR-1), indicating a critical role for PAR-1 in this process. Furthermore, we showed a strong antiapoptotic effect of APC in the early phase of reperfusion combined with an antiinflammatory effect at an early stage (IL-6), as well as at a later stage (leukocyte infiltration). CONCLUSIONS APC exerts strong protective effects on early myocardial I/R injury, primarily via inhibition of apoptosis and inflammation, which are regulated via PAR-1.

Non-hematopoietic EPCR regulates the coagulation and inflammatory responses during endotoxemia

Background: Activated protein C (APC) protects the host from severe sepsis. Endothelial protein C receptor (EPCR) is expressed on both hematopoietic leukocytes and non‐hematopoietic endothelium, and plays a key role in protein C activation.Objectives: We explore the influence of EPCR deletion on the responses to lipopolysaccharide (LPS) and then determine whether the observed differences are due to loss of hematopoietic or non‐hematopoietic EPCR.Methods and results: After LPS challenge, EPCR null (Procr−/−) mice exhibited more thrombin and cytokine generation, neutrophil sequestration in the lung and a higher mortality rate than Procr+/− mice. Procr+/− BM/Procr−/− (non‐hematopoietic Procr−/−) and Procr−/− BM/Procr+/− (hematopoietic Procr−/−) chimeric mice were generated by bone marrow (BM) transplantation. Compared with control Procr+/− mice, non‐hematopoietic Procr−/− mice exhibited reduced protein C activation by thrombin and exaggerated responses to LPS challenge, whereas Procr+/− mice and hematopoietic Procr−/− mice exhibited similar protein C activation by thrombin and similar responses to LPS challenge.Conclusions: EPCR deletion exaggerates the host responses to LPS primarily due to deficiency of EPCR on the non‐hematopoietic cells.