Ann Lövgren

A Triple-Transgenic Immunotolerant Mouse Model

Avoiding unwanted immunogenicity is of key importance in the development of therapeutic drug proteins. Animal models are of less predictive value because most of the drug proteins are recognized as foreign proteins. However, different methods have been developed to obtain immunotolerant animal models. So far, the immunotolerant animal models have been developed to assess one protein at a time and are not suitable for the assessment of combination products. Our aim was to develop an animal model for evaluating the impact of manufacturing and formulation changes on immunogenicity, suitable for both single protein and combination products. We constructed two lines of transgenic mice expressing the three human coagulation factors, II, VII, and X, by inserting a single vector containing the three coagulation factors encoding sequences separated by insulator sequences derived from the chicken beta-globin locus into the mouse genome. Immunization of transgenic mice from the two lines and their wild-type littermates showed that transgenic mice from both lines were immunotolerant to the expressed human coagulation factors. We conclude that transgenic mice immunotolerant to multiple proteins can be obtained, and that these mice are potentially useful as animal models in the assessment of immunogenicity in response to manufacturing changes.

Recombinant snake venom prothrombin activators

Three prothrombin activators; ecarin, which was originally isolated from the venom of the saw-scaled viper Echis carinatus, trocarin from the rough-scaled snake Tropidechis carinatus, and oscutarin from the Taipan snake Oxyuranus scutellatus, were expressed in mammalian cells with the purpose to obtain recombinant prothrombin activators that could be used to convert prothrombin to thrombin. We have previously reported that recombinant ecarin can efficiently generate thrombin without the need for additional cofactors, but does not discriminate non-carboxylated prothrombin from biologically active γ-carboxylated prothrombin. Here we report that recombinant trocarin and oscutarin could not efficiently generate thrombin without additional protein co-factors. We confirm that both trocarin and oscutarin are similar to human coagulation Factor X (FX), explaining the need for additional cofactors. Sequencing of a genomic fragment containing 7 out of the 8 exons coding for oscutarin further confirmed the similarity to human FX.

Recombinant human prothrombin reduced blood loss in a porcine model of dilutional coagulopathy with uncontrolled bleeding.

&NA; Uncontrolled bleeding remains one of the leading causes of trauma-induced death. Treatment recommendations focus on fresh frozen plasma and blood cell transfusions, whereas plasma concentrates or single coagulation factors have been studied in recent years. The effect of recombinant human prothrombin factor II (rhFII, 8 mg/kg), activated recombinant human factor VII (rhFVIIa, 300 &mgr;g/kg), plasma-derived human fibrinogen (pdhFib) (200 mg/kg), activated prothrombin complex concentrate (aPCC, 40 IU/kg), a three-factor combination intended as a minimal PCC (8 mg/kg rhFII, 640 &mgr;g/kg recombinant human factor X (rhFX), and 12 &mgr;g/kg rhFVIIa), and vehicle were investigated in a porcine model of dilutional coagulopathy with uncontrolled bleeding. Survival time and blood loss were determined up to 120 min after induction of liver injury. Rotational thromboelastometry EXTEM coagulation time and maximum clot firmness, prothrombin time, thrombin-antithrombin complex (TAT), thrombin generation (endogenous thrombin potential, ETP) were measured at baseline, after dilution, drug administration, and end of experiment. rhFII, the three-factor combination, and aPCC significantly (P < 0.01) decreased blood loss vs. vehicle and rhFII also vs. fibrinogen (P < 0.05). Survival times increased significantly for rhFII, aPCC, rhFVIIa, and pdhFib vs. vehicle (P < 0.05), and, coagulation time, maximum clot firmness, and prothrombin time improved in all groups. TAT and ETP increased transiently for rhFII and three-factor combination, whereas persistently increased for aPCC. PdhFib and rhFVIIa did not increase TAT and ETP. rhFII decreased blood loss and improved hemostatic markers and survival. In vivo, thrombin generation (TAT) and potential to form thrombin (ETP) were transiently elevated by rhFII. Addition of rhFVIIa and rhFX to rhFII did not further improve hemostatic efficacy.

Characterization of thrombin derived from human recombinant prothrombin

Thrombin (FIIa) is the key enzyme in haemostasis and acts on several substrates involved in clot formation, platelet activation and feed-back regulation of its own formation. During activation of blood coagulation, FIIa is formed by proteolytic cleavage of prothrombin (FII). In the production of recombinant human FII (rhFII), a key question is whether the thrombin formed has the same properties as endogenous thrombin. We have investigated whether FIIa formed from rhFII and plasma-derived human FII (pdhFII) have the same enzymatic and haemostatic properties against a number of substrates and the same haemostatic capacity in plasma, whole blood and on platelets. Pure FIIa was isolated from rhFII and pdhFII cleaved by recombinant ecarin, and analytical methods were developed to compare the activity of FIIa against different substrates. FIIa derived from rhFII and pdhFII were found to have very similar properties in activating FVIII, FXIII, protein C, platelet aggregation and plasma or whole blood coagulation. Further, the same turnover for S-2366 was found with similar K M. However, activation of FV with rhFIIa was approximately 25% more effective than with pdhFIIa and heparin-enhanced inhibition of rhFIIa by antithrombin was significantly more efficient compared with pdhFIIa with 10% higher inhibition both at steady state and at initial rate conditions. Although differences between the two FIIa preparations using ecarin cleavage were observed, FIIa derived from rhFII administered to human would likely be very similar in activity and function as FIIa formed from endogenous FII.

Preclinical evaluation of point-of-care prothrombin time as a biomarker test to guide prothrombin replacement therapy in coagulopathic bleeding

Essentials Prediction of bleeding risk in trauma patients is difficult. We evaluated a test which measures prothrombin time/ability of blood to clot. We showed the prothrombin time test reflected prothrombin concentration in blood. The test could be used in trauma patients to identify those in need of prothrombin replacement.

Recombinant human prothrombin (MEDI8111) prevents bleeding in haemophilia A and B mice

Haemophilia A and B are treated with FVIII and FIX replacement therapy. Treatment may be complicated by inhibitory antibodies that require bypass therapy such as FEIBA® in which prothrombin (FII) is suggested to be the main active component.

A Comparison of the Humoral Immune Response Induced by a Recombinant Human Protein in Wild Type Mice and in Transgenic Mice Expressing the Protein

Clinical Chemistry and Transfusion Medicine, Sahlgrenska Academy, University of Gothenburg, S-413 45, Sweden. Department of Clinical and Experimental Medicine, Faculty of Health Sciences, Linkoping University, Department of Clinical Pathology and Clinical Genetics, Ostergotland County Council, Linkoping, Sweden and Swetox, Swedish Toxicology Sciences Research Center, Forskargatan 20, S-15136, Sweden. Astra Zeneca, Innovative Medicine, Molndal, Sweden. Department of Non-Clinical Safety and Pharmacology, Swedish Orphan Biovitrum AB, Stockholm, Sweden.