Effect of haemodilution, acidosis, and hypothermia on the activity of recombinant factor VIIa (NovoSeven).

BACKGROUND: A range of plasma volume expanders is used clinically, often in settings where haemostasis may already be impaired. The haemostatic agent, recombinant activated factor VII (rFVIIa, NovoSeven), may be used to improve haemostasis but potential interactions with different volume expanders are poorly understood. METHODS: Clot formation was measured by thromboelastography (TEG) using blood from healthy volunteers. In vitro effects of rFVIIa with haemodilution, acidosis, and hypothermia were examined. Conditions were induced by dilution with NaCl (0.9%), lactated Ringer's solution, albumin 5%, or hydroxyethyl starch (HES) solutions [MW (molecular weight) 130-670 kDa]; by adjusting pH to 6.8 with 1 M HEPES (N-2-hydroxyethylpiperazine-N'-2-ethanesulphonic acid) buffer; or by reducing temperature to 32 degrees C. We also studied the effect of low vs high MW HES (MW 200 vs 600 kDa) and rFVIIa on in vivo bleeding time (BT) in rabbits. RESULTS: Haemodilution progressively altered TEG parameters. rFVIIa improved TEG parameters in the presence of acidosis, hypothermia or 20% haemodilution (P<0.05). At 40% haemodilution, the rFVIIa effect was diminished particularly with high MW HES. In vivo, rFVIIa shortened the BT (P<0.05) with low but not high MW HES. CONCLUSIONS: Efficacy of rFVIIa was affected by the degree of haemodilution and type of volume expander, but not by acidosis or hypothermia.

Preferential localization of recombinant factor VIIa to platelets activated with a combination of thrombin and a glycoprotein VI receptor agonist.

BACKGROUND: Activation of platelets with a combination of collagen and thrombin generates a subpopulation of highly procoagulant 'coated' platelets characterized by high surface expression of fibrinogen and other procoagulant proteins. OBJECTIVES: To analyze the interaction of recombinant factor VIIa (rFVIIa) with coated platelets. METHODS AND RESULTS: rFVIIa localized to the coated platelets in flow cytometry experiments, while minimal rFVIIa was found on platelets activated with adenosine diphosphate, thrombin or via glycoprotein VI individually, and essentially no rFVIIa was found on non-stimulated platelets. Removal of the gamma-carboxyglutamic acid (Gla) domain of rFVIIa, and addition of EDTA, annexin V or excess prothrombin inhibited rFVIIa localization to the coated platelets, indicating that the interaction was mediated by the calcium-dependent conformation of the Gla domain and platelet exposure of negatively charged phospholipids. A reduced level of platelet fibrinogen exposure was observed at hemophilia A-like conditions in a model system of cell-based coagulation, indicating that coated platelet formation in hemophilia may be diminished. Addition of rFVIIa dose-dependently enhanced thrombin generation and partly restored platelet fibrinogen exposure. CONCLUSIONS: The data suggest that rFVIIa localized preferentially on platelets activated with dual agonists, thereby ensuring enhanced thrombin generation localized at the site of injury where both collagen and tissue factor are exposed, the latter ensuring the formation of thrombin necessary for coated platelet formation.

Enhanced in vitro procoagulant and antifibrinolytic potential of superactive variants of recombinant factor VIIa in severe hemophilia A.

BACKGROUND: Recombinant coagulation factor VIIa (rFVIIa) is generally accepted for treatment of patients with inhibitor-complicated hemophilia. Recently, rFVIIa variants with a specific enhancement of the tissue factor (TF)-independent proteolytic activity have been described. OBJECTIVES: The procoagulant and [thrombin-activatable fibrinolysis inhibitor (TAFI)-dependent] antifibrinolytic potentials of two superactive rFVIIa variants were compared with those of wild-type rFVIIa in a hemophilic setting. PATIENTS AND METHODS: Clot lysis assays were performed in plasma from six patients with inhibitor-complicated hemophilia A or in antibody-induced factor VIII-deficient platelet-rich plasma in the presence of different concentrations of the rFVIIa variants. RESULTS AND DISCUSSION: In the plasma model, M298Q-rFVIIa had a moderately increased procoagulant and antifibrinolytic potential, whereas V158D/E296V/M298Q/K337A-rFVIIa had a strongly increased procoagulant and antifibrinolytic activity compared with wild-type rFVIIa. The increased antifibrinolytic potential of the rFVIIa variants was completely dependent on enhancement of TAFI activation. In the platelet-rich plasma model similar results were obtained. The presence of TF was mandatory for clot formation in the absence of exogenous rFVIIa. At lower concentrations of rFVIIa (wild-type or variants), clot formation did occur but was significantly slower when TF activity was blocked. At increasing concentrations of rFVIIa, clotting times were no longer dependent on TF. In conclusion, should a TF-independent mechanism be involved in the efficacy of rFVIIa in patients with hemophilia, the superactive rFVIIa variants studied here might be clinically advantageous, as both procoagulant and antifibrinolytic potencies are significantly enhanced compared with those of wild-type rFVIIa. This ought to result in more efficient cessation of bleeding episodes and reduced risk of rebleeding.

Assembly and activation of HK-PK complex on endothelial cells results in bradykinin liberation and NO formation.

Prekallikrein (PK) activation on human umbilical endothelial cells (HUVEC) presumably leads to bradykinin liberation. On HUVEC, PK activation requires the presence of cell-bound high-molecular-weight kininogen (HK) and Zn(2+). We examined the Zn(2+) requirement for HK binding to and the consequences of PK activation on endothelial cells. Optimal HK binding (14 pmol/10(6) HUVEC) is seen with no added Zn(2+) in HEPES-Tyrode buffer containing gelatin versus 16--32 microM added Zn(2+) in the same buffer containing bovine serum albumin. The affinity and number of HK binding sites on HUVEC are a dissociation constant of 9.6 +/- 1.8 nM and a maximal binding of 1.08 +/- 0.26 x 10(7) sites/cell (means +/- SD). PK is activated to kallikrein by an antipain-sensitive mechanism in the presence of HK and Zn(2+) on HUVEC, human microvascular endothelial cells, umbilical artery smooth muscle cells, and bovine pulmonary artery endothelial cells. Simultaneous with kallikrein formation, bradykinin (5.0 or 10.3 pmol/10(6) HUVEC in the absence or presence of lisinopril, respectively) is liberated from cell-bound HK. Liberated bradykinin stimulates the endothelial cell bradykinin B2 receptor to form nitric oxide. Assembly and activation of PK on endothelial cells modulates their physiological activities.

Activation of the plasma kallikrein/kinin system on endothelial cell membranes.

For more than three decades, it has been known that the plasma kallikrein/kinin system becomes activated when exposed to artificial, negatively charged surfaces. The existence of an encompassing in vivo, negatively charged surface capable of activation of the plasma kallikrein/kinin system has, however, never been convincingly demonstrated. In this report, we describe current knowledge on how the proteins of the plasma kallikrein/kinin system assemble to become activated on cell membranes. On endothelial cells, the activation of the plasma kallikrein/kinin system is not initiated by factor XII autoactivation as seen on artificial surfaces. On endothelial cells, prekallikrein is activated by an antipain sensitive protease. Prekallikrein activation is dependent on the presence of high molecular weight kininogen and an optimal free Zn2+ concentration. Kallikrein generated on the surface of endothelial cell is capable of activating factor XII. Further, kallikrein formed on endothelial cell membranes is capable of cleaving its receptor and native substrate, high molecular weight kininogen, liberating bradykinin and the HK PK complex from the endothelial cell surface. Endothelial cell-associated kallikrein also is capable of kinetically favorable pro-urokinase and, subsequent, plasminogen activation.

Factor XIIa is a kinetically favorable plasminogen activator.

Initiation of the plasma contact system has been shown to play a significant role in the fibrinolysis, activating both pro-urokinase and plasminogen. The aim of the present study was to further evaluate the functional role of the factor XIIa catalyzed activation of plasminogen. Activation of plasminogen by factor XIIa followed the Michaelis-Menten rate equation. In a continuous assay system the Km was 0.27 microM; the kcat 0.078 min(-1) and the kcat/Km 0.31x10(6) M(-1) x min(-1). In an end-point assay system the Km was 0.58 microM; the kcat 0.096 min(-1) and the kcat/Km 0.16x10(6) M(-1) x min(-1). The discrepancy between the kcat in the two assays is not significant. Theoretically the higher Km in the end-point assay system may be due to the presence or generation of an unidentified competitive inhibitor in this assay system. Comparing the catalytic constants of factor XIIa with those of urokinase activation of plasminogen, the specificity constant, kcat/Km, of factor XIIa activation of plasminogen was 20-fold lower. However, taking the low physiological concentration of urokinase into account, the efficiency of activated factor XII is equivalent to that of urokinase. When monitoring factor XIIa activation of plasminogen in a clot lysis assay, the clot lysis time was 2- to 4-fold as long as that accommodated by urokinase at factor XIIa concentrations equivalent with 5-20% of the zymogen concentration in plasma. The factor XIIa mediated clot lysis was prevented completely by the presence of a polyclonal antibody to factor XII.

Activation of the plasma kallikrein/kinin system on endothelial cells.

For more than two decades, it has been known that activation of the plasma kallikrein/kinin system only occurs when it is exposed to artificial, negatively charged surfaces. The existence of physiological, negatively charged surfaces has, however, never been demonstrated in vivo. In this report, we describe current knowledge about how the proteins of the plasma kallikrein/kinin system interact with and become activated on cell membranes. In this model, activation of the plasma kallikrein/kinin system on endothelial cells is not initiated by factor XII autoactivation, as seen on artificial surfaces. On endothelial cells, plasma prekallikrein is activated by a membrane-associated cysteine protease. This activation is dependent on the presence of high molecular weight kininogen and an optimal zinc (Zn2+) concentration. Although the initiation of activation of plasma prekallikrein is independent of factor XII, kallikrein-mediated factor XIIa generation, in turn, accelerates the activation of the system. Further kallikrein formed on endothelial cell membranes is capable of cleaving its receptor and native substrate, high molecular weight kininogen, liberating bradykinin and terminating activation. In addition, the kallikrein formed on the surface of endothelial cells results in kinetically favorable activation of prourokinase and, subsequently, plasminogen. Activation of the plasma kallikrein/kinin system on endothelial cells proceeds by a physiological mechanism to initiate cellular fibrinolysis independent of plasmin, fibrin, and tissue-type plasminogen activator.

Factor XII does not initiate prekallikrein activation on endothelial cells.

It is well known that on artificial surfaces, binding and autoactivation of factor XII (FXII) is the initiating event of plasma prekallikrein (PK) activation. We performed investigations to examine whether this mechanism was true for FXII activation on endothelial cells (HUVEC). Activation of PK on HUVEC required an optimal substrate and Zn2+ concentration, the latter of which varied with the buffer's carrier protein. Maximal PK activation required the addition of 250 microM or 10 microM Zn2+ to buffers containing bovine serum albumin (BSA) or gelatin, respectively. However, the actual free Zn2+ concentration in these buffers was the same at 8 microM. In both BSA- and gelatin-containing buffers and using two different chromogenic substrates for FXII, no autoactivation of FXII on HUVEC was seen when incubated for up to 60 min. Rather, initiation of FXII enzymatic activity required the presence of PK. FXII activation after PK activation contributed to the extent of measured enzymatic activity, but its role was secondary because treatment with corn trypsin inhibitor or a neutralizing antibody to FXIIa did not abolish the measured enzymatic activity. They also reduced the activity to the level seen with PK activation alone. Alternatively, soybean trypsin inhibitor abolished the proteolytic activity associated with PK and FXII activation on HUVEC. Further, only normal human and FXII-deficient plasmas, not PK-deficient plasma, had the ability to generate proteolytic activity when incubated over endothelial cells. In a purified system, maximal PK activation was measured after a 10-15 min incubation depending upon the concentration of reactants. When FXII was added with the PK, maximal activation occurred within 7.5-10 min. In normal human or FXII-deficient plasmas, but not in PK-deficient plasma, maximal activation was seen in 4 min. These data indicate that on HUVEC, unlike artificial surfaces, PK activation when bound to HK is the initiating activation event in this system. FXII activation is secondary to PK activation and contributes to the extent of measured enzymatic activity. These data challenge the accepted dogmas of "contact activation" and suggest that on biologic membranes a new notion as to how this system is activated needs to be considered.

High molecular weight kininogen regulates prekallikrein assembly and activation on endothelial cells: a novel mechanism for contact activation.

The consequences of assembling the contact system of proteins on the surface of vascular cells has received little study. We asked whether assembly of these proteins on the surface of cultured human endothelial cells (HUVECs) results in the activation of prekallikrein (PK) and its dependent pathways. Biotinylated PK binds specifically and reversibly to HUVECs in the presence of high molecular weight kininogen (HK) (apparent Kd of 23 +/- 11 nmol/L, Bmax of 1.7 +/- 0.5 x 10(7) sites per cell [mean +/- SD, n = 5 experiments]). Cell-associated PK is rapidly converted to kallikrein. Surprisingly, the activation of cell-associated HK.PK complexes is entirely independent of exogenous factor XII (Km = 30 nmol/L, Vmax = 12 +/- 3 pmol/L/min in the absence v Km = 20 nmol/L, Vmax = 9.2 +/- 2.1 pmol/L/min in the presence of factor XII). Rather, kallikrein formation is mediated by an endothelial cell-associated, thiol protease. Cell-associated HK is proteolyzed during the course of prekallikrein activation, releasing kallikrein from the surface. Furthermore, activation of PK bound to HK on HUVECs promotes kallikrein-dependent activation of pro-urokinase, resulting in the formation of plasmin. These results indicate the existence of a previously undescribed, factor XII-independent pathway for contact factor activation on HUVECs that regulates the production of bradykinin and may contribute to cell-associated plasminogen activation in vivo.

Identification of beta2-glycoprotein I as a membrane-associated protein in kidney: purification by calmodulin affinity chromatography.

Outer renal medulla calmodulin-binding proteins from a soluble protein fraction and a plasma membrane fraction solubilized in CHAPS were retained on a calmodulin-Sepharose 4B column in the presence of Ca2+, and subsequently eluted by EGTA. The calmodulin-binding proteins constituted 2.5% of the soluble protein and 0.1% of the solubilized membrane protein. beta2-glycoprotein I was identified as a calmodulin-binding protein both by N-terminal sequencing and by immunoblotting. Quantification showed that beta2-glycoprotein I constituted the major part (approx. 35%) of the calmodulin-binding membrane proteins, but only a minor part (approx. 0.1%) of the calmodulin-binding proteins in the soluble fraction. These results show for the first time that beta2-glycoprotein I binds calmodulin and that beta2-glycoprotein I may in kidney be a membrane-associated protein. Immunohistochemical studies identified beta2-glycoprotein I in several parts of the cortex and the medulla of the kidney, including Bowman's capsula, the tubular lumen and the tubular epithelium, indicating that beta2-glycoprotein I, despite its relatively high molecular mass, is filtrated in the glomerulus and subsequently reabsorbed by the tubular epithelium. This is in agreement with beta2-glycoprotein I being a marker for renal tubular disease.

Characterization of the interaction between beta2-glycoprotein I and calmodulin, and identification of a binding sequence in beta2-glycoprotein I.

beta2-Glycoprotein I was shown to bind reversibly to calmodulin in a Ca2+-dependent manner with a 1:1 stoichiometry, a Kd of 3 x 10(-9) M and a Hill coefficient of 1.4. A sequence in beta2-glycoprotein I (Lys-Pro-Gly-Tyr-Val-Ser-Arg-Gly-Gly-Met-Arg-Lys-Phe-Ile-) limited by Cys-32 and Cys-47 is suggested to be the calmodulin-binding region. This sequence was the only one in beta2-glycoprotein I theoretically having the ability to form a basic amphiphilic alpha-helix typical of a calmodulin binding sequence. The peptide corresponding to this sequence was synthesized and found to inhibit the interaction between beta2-glycoprotein I and calmodulin with an IC50 value of 0.38 x [beta2-glycoprotein I] and to displace the beta2-glycoprotein I from the beta2-glycoprotein I/calmodulin complex with an IC50 value of 0.90 x [beta2-glycoprotein I].

The surface-dependent autoactivation mechanism of factor XII.

The dependency of concentrations of Zn2+ and the negatively charged surfaces, phosphatidylinositol phosphate (PtdInsP), sulfatide and dextran sulfate, on the autoactivation of human factor XII, has been studied. While the autoactivation induced by sulfatide, and low concentrations of dextran sulfate, was unaffected by the presence of Zn2+, that induced by PtdInsP and higher concentrations of dextran sulfate was completely dependent on Zn2+: the excess of Zn2+ needed to induce maximal activity with PtdInsP was 12-fold the concentration of factor XII, while with dextran sulfate it was 40-fold. Determination of the Zn2+-binding properties of factor XII revealed that a total of four zinc ions could bind to each factor XII molecule. The first bound zinc ions (Kd 0.1 microM) induced an increase in the intrinsic tryptophan fluorescence of factor XII, while further titration up to a 40-fold surplus resulted in a quenching of the fluorescence. Binding of the zinc ions that caused the quenching had an average Kd of approximately 1 microM, independent of whether it was determined from the fluorescence changes or by equilibrium filtration. Low concentrations of both sulfatide and PtdInsP induced a fluorescence increase similar to that at low concentrations of Zn2+ but, in contrast to sulfatide, higher concentrations of PtdInsP did not induce a quenching in fluorescence. As the Zn2+-independent activating surface (sulfatide) induced quenching in the fluorescence intensity, while the Zn2+-dependent activating surface (PtdInsP) did not, the quenching, whether it was caused by sulfatide or zinc ions, was assigned to a change in the conformation which resulted in a molecular structure of factor XII that could be autoactivated. Association of factor XII in this conformation on the activating surface was suggested to be responsible for the autoactivation.