Identification of porcine coagulation factor VIII domains responsible for high level expression via enhanced secretion

Blood coagulation factor VIII has a domain structure designated A1-A2-B-ap-A3-C1-C2. Human factor VIII is present at low concentration in normal plasma and, comparably, is produced at low levels in vitro and in vivo using transgenic expression techniques. Heterologous expression of B domain-deleted porcine factor VIII in mammalian cell culture is significantly greater than B domain-deleted human or murine factor VIII. Novel hybrid human/porcine factor VIII molecules were constructed to identify porcine factor VIII domains that confer high level expression. Hybrid human/porcine factor VIII constructs containing the porcine factor VIII A1 and ap-A3 domains expressed at levels comparable with recombinant porcine factor VIII. A hybrid construct containing only the porcine A1 domain expressed at intermediate levels between human and porcine factor VIII, whereas a hybrid construct containing the porcine ap-A3 domain expressed at levels comparable with human factor VIII. Additionally, hybrid murine/porcine factor VIII constructs containing the porcine factor VIII A1 and ap-A3 domain sequences expressed at levels significantly higher than recombinant murine factor VIII. Therefore, the porcine A1 and ap-A3 domains are necessary and sufficient for the high level expression associated with porcine factor VIII. Metabolic radiolabeling experiments demonstrated that high level expression was attributable to enhanced secretory efficiency.     

Binding of recombinant human coagulation factor VIII to lipid nanotubes

Cryo-electron microscopy has the power to visualise lipid membranes at the closest to in vivo conditions. The structure of the lipid bilayer can be well resolved and the interactions between lipid-protein and protein-protein molecules followed at the molecular level. We undertook an extended Cryo-electron microscopy study to follow the factor VIII binding to phosphatidylserine containing lipid nanotubes at different lipid composition. Obtaining well ordered tubes is required to define the factor VIII membrane-bound structure. The observed alterations in the arrangement of the protein molecules are indicative for the flexibility of the membrane-bound factor VIII. Understanding the significance of these conformational changes is essential to comprehend the function of factor VIII in coagulation and as a drug for Hemophilia A.     

B-Domain deleted recombinant coagulation factor VIII modified with monomethoxy polyethylene glycol

Recombinant coagulation factor VIII (r-VIII SQ) was chemically modified with monomethoxy poly(ethylene glycol) (mPEG). Three mPEG derivatives were used for coupling to the r-VIII SQ lysines, a mixed anhydride of monomethoxy poly(ethylene glycol) succinic acid (mPEG-SAH), monomethoxy poly(ethylene glycol) succinimidyl succinate (mPEG-SS), and monomethoxy poly(ethylene glycol) tresylate (mPEG-TRES). A consequence of the modification with all derivatives was a substantial reduction in coagulant activity, even at very low degrees of modification. A method was developed with the purpose of avoiding conjugation at certain important biological sites on the factor VIII and thereby producing conjugates with better retained activity. This was achieved by immobilizing the protein onto a solid matrix during the modification reaction. Characterization of conjugates by SDS-PAGE, western blots, interaction with von Willebrand factor (vWf), and thrombin activation/inactivation analyses was undertaken. The SDS-PAGE and western blots revealed coupling heterogeneity regarding degree of modification. The amount of factor VIII able to bind to vWf decreased with the conjugation. Thrombin activated the modified factor VIII to essentially the same extent as the reference preparation of r-VIII SQ. Inactivation of the modified factor VIII was, however, slower than inactivation of the unmodified protein. Finally, an in vitro study was performed to evaluate the influence of the mPEG modification on the protein stability in extract of porcine tissue. Despite that conjugates with low degrees of modification were included in the study, the coagulant activity was preserved to a significantly higher extent in all incubation mixtures containing conjugates compared to that with unmodified protein.     

Characterization of recombinant human factor VIII

Recently, complete human factor VIII DNA clones have been obtained and subsequently expressed in baby hamster kidney cells (Wood, W. I., Capon, D. J., Simonsen, C. C., Eaton, D. L., Gitschier, J., Keyt, B., Seeburg, P. H., Smith, D. H., Hollingshead, P., Wion, K. L., Delwart, E., Tuddenham, E. G. D., Vehar, G. A., and Lawn, R. M. (1984) Nature 312, 330-337). The recombinant factor VIII (rVIII) protein secreted from these cells has now been purified allowing its structural analysis and comparison to plasma-derived factor VIII (pdVIII). Analysis of purified rVIII by sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows that it consists of multiple polypeptides with relative mobilities (Mr) ranging from 80,000-210,000. The same pattern of polypeptides is also observed for pdVIII resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The proteins associated with rVIII are recognized by pdVIII antibodies in a Western blot. When rVIII and pdVIII are subjected to isoelectric focusing they are resolved into a similar pattern of protein bands. Thrombin, factor Xa, and activated protein C, which modulate factor VIII activity by proteolysis, process rVIII in the same manner they do pdVIII. As is the case for pdVIII, thrombin activation of rVIII coagulant activity correlates with the generation of subunits with Mr of 73,000, 50,000 and 43,000. These subunits appear to form a metal-(perhaps Ca2+) linked complex. EDTA inactivates thrombin-activated rVIII and pdVIII, with the activity being regenerated after the addition of a molar excess of MnCl2. The results suggest that rVIII is structurally and functionally very similar to pdVIII.     

Subunit structure of thrombin-activated porcine factor VIII

Factor VIII (fVIII) is synthesized as a single chain having a domainal sequence A1-A2-B-A3-C1-C2. Analysis of the proteolyic cleavage of fVIII by thrombin by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) identifies three fragments designated fVIIIA1, fVIIIA2, and fVIIIA3-C1-C2 with fragment(s) derived from the B domain being difficult to visualize. The appearance of these fragments is associated with the development of coagulant activity, but the activity is labile without further apparent proteolysis. In this study, porcine fVIII was reacted with thrombin until peak coagulant activity was obtained and then subjected to cation-exchange (Mono S) high-pressure liquid chromatography. Coagulant activity was recovered in a single peak that contained all three fragments and was stable for weeks at 20 degrees C in 0.65 M NaCl/0.01 M His-HCl/0.005 M CaCl2 at pH 6.0. Analytical ultracentrifugation of activated fVIII was done to test whether all three fragments were associated. The apparent molecular weight of activated fVIII from equilibrium sedimentation increased from 148,000 to 161,000 as the loading concentration was increased from 0.06 to 0.16 mg/mL. This agrees well with the summed apparent molecular weights of fVIIIA1, fVIIIA2, and fVIIIA3-C1-C2 calculated from SDS-PAGE analysis (148,000) or from the amino acid sequence of human fVIII (159,000). This establishes the major species in the preparation as a fVIIIA1/A2/A3-C1-C2 heterotrimer and additionally indicates either weak self-association of the trimer and/or incomplete association of the individual subunits to form the trimer. Velocity sedimentation of activated fViii revealed a single boundry (S020,w = 7.2 S).(ABSTRACT TRUNCATED AT 250 WORDS)     

Roles of phytanoyl-CoA alpha-hydroxylase in mediating the expression of human coagulation factor VIII

The coagulation factor VIII (FVIII) is the coagulation factor deficient in the X-chromosome-linked bleeding disorder hemophilia A. Previous transfection studies demonstrated that factor VIII was 10-100-fold less efficiently expressed than the homologous coagulation factor, factor V. To investigate the regulatory mechanisms of FVIII synthesis and secretion, we used the yeast two-hybrid system as an approach to search for proteins that associated with FVIII. The A2 domain (337-740 amino acids) of factor VIII (FVIII-A2) was used as a bait and phytanoyl-CoA alpha-hydroxylase (PAHX) was identified as a binding protein of FVIII-A2. PAHX had potential to interact with the residues 373-508 within the A2 domain, but not with A1 and A3 (the homologous domains of A2). The interaction between the A2 domain and PAHX was independent of the type 2 peroxisomal targeting signal (PTS2) of PAHX. Overexpression of PAHX in FVIII-produced cells decreased the expression of FVIII by about 70%. The elevated expression of von Willebrand factor had no effect on the suppression of FVIII secretion by PAHX. Expression of the green fluorescent PAHX fusion protein in SMMC-7721 cells affected the intracellular trafficking of FVIII-A2. These results suggested that the interaction between PAHX and FVIII-A2 was in part responsible for the low-level expression of factor VIII.     

pH-dependent denaturation of thrombin-activated porcine factor VIII

Thrombin-activated porcine factor VIII (fVIIIaIIa) is a stable, active, 160-kDa heterotrimer at concentrations exceeding 2 x 10(-7) M in 0.7 M NaCl, 0.01 M histidine Cl, 5 mM CaCl2, pH 6.0, at 4 degrees C or 20 degrees C. Two of the subunits, fVIIIA1 and fVIIIA2, are derived from the heavy chain of the plasma-derived, heterodimeric fVIII precursor. The third subunit, fVIIIA3-C1-C2, is derived from the fVIII light chain. We now find that fVIIIaIIa undergoes a sharp decline in coagulant activity between pH 7 and 8. At pH 7.5, the activity of fVIIIaIIa at 3 x 10(-7) M decays within a few hours to a stable level that is approximately 70% of the value at pH 6.0, whereas at pH 8.0, greater than 99% of the activity is lost. The activity cannot be restored by readjusting the pH to 6.0. The loss of activity at pH 8.0 coincides with dissociation of the fVIIIA2 subunit since an inactive fVIIIA1/A3-C1-C2 heterodimer can be isolated by Mono S high performance liquid chromatography. After prolonged incubation at pH 8.0, the fVIIIA1 subunit also dissociates. The free fVIIIA2 fragment appears to be poorly soluble which may explain the irreversible loss of activity. Analytical velocity sedimentation of the pH-inactivated fVIIIaIIa preparation also is consistent with dissociation and precipitation of the fVIIIA2 fragment. We propose that denaturation of fVIIIaIIa by pH-dependent subunit dissociation may provide a major mechanism of inactivation of fVIIIaIIa under physiologic conditions.     

Blood coagulation factor VIII: An overview

Factor VIII (FVIII) functions as a co-factor in the blood coagulation cascade for the proteolytic activation of factor X by factor IXa. Deficiency of FVIII causes hemophilia A, the most commonly inherited bleeding disorder. This review highlights current knowledge on selected aspects of FVIII in which both the scientist and the clinician should be interested.     

High level expression and simple purification of recombinant human granulocyte colony-stimulating factor in E. coli

Summary A human granulocyte colony-stimulating factor (hG-CSF) gene was synthesized and inserted into a trp expression vector for over-expression in E. coli. A strong expression vector was constructed, and a simple purification procedure including in vitro refolding was established. The final productivity of hG-CSF was 500~600mg per l culture, and the purified hG-CSF showed the proliferation of neutrophils in vivo assays.     

High-level expression of functional recombinant human coagulation factor VII in insect cells

Recombinant coagulation factor VII (FVII) is used as a potential therapeutic intervention in hemophilia patients who produce antibodies against the coagulation factors. Mammalian cell lines provide low levels of expression, however, the Spodoptera frugiperda Sf9 cell line and baculovirus expression system are powerful systems for high-level expression of recombinant proteins, but due to the lack of endogenous vitamin K-dependent carboxylase, expression of functional FVII using this system is impossible. In the present study, we report a simple but versatile method to overcome the defect for high-level expression of the functional recombinant coagulation FVII in Sf9 cells. This method involves simultaneous expression of both human γ-carboxylase (hGC) and human FVII genes in the host. It may be possible to express other vitamin K-dependent coagulation factors using this method in the future.     

重组鸡γ_干扰素在昆虫细胞中的高效表达

将鸡γ-干扰素(ChIFN-γ)基因克隆到载体pFASTBAC1中,构建转移载体pFASTBAC1-ChIFN-γ,然后转化DH10Bac感受态大肠杆菌,通过位点特异性转座,将ChIFN-γ基因整合到Bacmid穿梭载体中,构建表达质粒Bacmid-ChIFN-γ;通过脂质体将表达质粒转染Sf9昆虫细胞,用间接免疫荧光试验鉴定重组鸡γ-干扰素(rChIFN-γ)的表达;通过水泡性口炎病毒感染鸡胚成纤维细胞(CEF)的细胞病变抑制试验,检测rChIFN-γ的活性。研究结果表明,感染重组杆状病毒的Sf9细胞能高效表达rChIFN-γ,且当每个细胞的感染量为1个病毒时,细胞在感染96h后,rChIFN-γ基因表达产物的活性最高,达到106~107.2U/mL。以rChIFN-γ进行对新城疫病毒(NDV)F48E8株、禽流感H5N1病毒(AIV-H5)和马立克氏病病毒(MDV)GA株的抗病毒活性试验,发现rChIFN-γ对AIV-H5和MDV GA株病毒有明显的抑制其致细胞病变作用,但对NDVF48E8株病毒在体外不能抑制其致细胞病变作用,仅能在病毒滴度上表现抑制效果。     

High level of expression of recombinant human granulocyte-macrophage colony stimulating factor in transgenic rice cell suspension culture

Recombinant human granulocyte-macrophage colony stimulating factor (hGM-CSF) has been previously produced in tobacco cell suspension cultures. However, the amount of hGM-CSF accumulated in the culture medium dropped quickly from its maximum of 150 microg/L at 5 d after incubation. To overcome this problem, we sought an expression system in which heterologous gene expression could be induced at high levels. We selected a rice amylase expression system in which the promoter Ramy3D is induced to express recombinant protein by sucrose starvation. This induction system was found to give good yield of recombinant hGM-CSF in transgenic rice cell suspension culture and protease activity of this culture medium was low compared to that of tobacco culture system.     

The functional domains of coagulation factor VIII:C

A lack of factor VIII:C, manifested as a bleeding disorder due to the absence of clot formation, is known as hemophilia A, an X chromosome-linked inherited disease afflicting 1-2 males/10,000. To determine the minimum functional domain(s) essential for factor VIII:C activity, we have expressed the amino-terminal (92-kDa) and carboxyl-terminal (80-kDa) proteolytic cleavage products as individual, secreted polypeptides in monkey cells without the 909-residue central region. We have found that neither terminal domain alone is able to promote coagulation in factor VIII:C-deficient plasma. However, when the 92- and 80-kDa peptides are co-expressed, clotting activity is readily detected. Thus, these two chains alone constitute an active or activatable complex. The central domain is required neither for activity nor for the assembly of an active complex from two chains expressed in trans. These results suggest that a truncated derivative of factor VIII:C may be useful in coagulation therapy.     

Generation of active coagulation factor VIII from isolated subunits

Factor VIII-light chain (FVIII-LC) and Factor VIII-heavy chain (FVIII-HC) were isolated separately from human plasma and were without coagulation activity. When FVIII-LC and FVIII-HC preparations were mixed, coagulation activity was generated in the presence of Mn2+, Ca2+, or Co2+. Mn2+ was most effective and with Ca2+ maximal activity was first obtained after 8 days. Bovine Factor X (FX) accelerated recombination and was able to increase the amount of FVIII:C generated up to 10-fold when FVIII-LC/HC were incubated with Ca2+ for 20 h. When recombination was performed in the presence of micromolar concentrations of sulfhydryl reagents, the total amount of FVIII:C generated was increased up to 4-fold and in excess of FVIII-HC it was possible to drive 70% of FVIII-LC into active complex. If FVIII-HC was prepared in the presence of a sulfhydryl reagent it was possible to drive 75% of FVIII-HC into active complex with FVIII-LC in excess. Me2+, which is necessary for recombination, catalyzes disulfide formation, and it is proposed that FVIII subunits have free sulfhydryl groups. The presence of sulfhydryl reagents during purification of FVIII-HC and during recombination retains the individual subunits in a conformation suitable for recombination.     

Autoactivation of human recombinant coagulation factor VII

Single-chain human recombinant factor VII produced by transfected baby hamster kidney cells was purified to homogeneity in the presence of benzamidine. The amidolytic activity of single-chain recombinant factor VII with a peptidylnitroanilide substrate, methoxycarbonyl-D-cyclohexanylglycyl-L-arginine-p-nitroanilide, was less than 1% of that obtained with factor VIIa. Purified single-chain recombinant factor VII spontaneously activated in the absence of inhibitor. The activation reaction was enhanced by at least 2 orders of magnitude in the presence of a positively charged surface, provided either as an anion-exchange matrix or as poly(D-lysine). The progress curve for factor VIIa generation was sigmoidal. Benzamidine inhibits recombinant factor VIIa activity and factor VII activation with identical inhibition constants (Ki) of 11 mM. In contrast, benzamidine inhibition of bovine factor Xa and bovine factor IIa was observed at Ki values equal to 0.3 and 0.5 mM, respectively. Bovine factors Xa and IIa are known activators of factor VII and the most likely contaminants of our recombinant factor VII preparations. Single-chain recombinant factor VII purified from cells cultured in the absence of bovine serum activated at the same rate as factor VII from cells cultured in the presence of bovine serum. This also excluded the possibility that the activation reaction was caused by contaminating bovine proteases. On the basis of these observations, we propose that factor VII is autoactivated in vitro in the presence of a positively charged surface.     

Purification of porcine plasma factor VIII using chromatographic methods

Factor VIII was purified from porcine plasma using adsorption on aluminium hydroxide with CM-cellulose as a filtration aid, cold ethanol precipitation, and two anion-exchange (Q-Sepharose fast flow) chromatographies. The final product was purified 264-fold and had a specific activity of 10 U mg^–1. The method is suitable to produce purified porcine FVIII by an easy process where all steps can be scaled up. The final product is free of von Willebrand factor that is responsible for the main side effects in patients. Finally, this method can be used to obtain purified porcine plasma FVIII for use in haemophilic patients with inhibitors.     

Proteolysis of blood coagulation factor VIII by the factor VIIa-tissue factor complex: generation of an inactive factor VIII cofactor.

Activation of factor VIII by thrombin occurs via limited proteolysis at R372, R740, and R1689. The resultant active factor VIIIa molecule consists of three noncovalently associated subunits: A1-a1, A2-a2, and A3-C1-C2 (50, 45, and 73 kDa respectively). Further proteolysis of factor VIIIa at R336 and R562 by activated protein C subsequently inactivates this cofactor. We now find that the factor VIIa-tissue factor complex (VIIa-TF/PL), the trigger of blood coagulation with restricted substrate specificity, can also catalyze limited proteolysis of factor VIII. Proteolysis of factor VIII was observed at 10 sites, producing 2 major fragments (47 and 45 kDa) recognized by an anti-factor VIII A2 domain antibody. Time courses indicated the slow conversion of the large fragment to 45 kDa, followed by further degradation into at least two smaller fragments. N-Terminal sequencing along with time courses of proteolysis indicated that VIIa-TF/PL cleaved factor VIII first at R740, followed by concomitant cleavage at R336 and R372. Although cleavage of the light chain at R1689 was observed, the majority remained uncleaved after 17 h. Consistent with this, only a transient 2-fold increase in factor VIII clotting activity was observed. Thus, heavy chain cleavage of factor VIII by VIIa-TF/PL produces an inactive factor VIII cofactor no longer capable of activation by thrombin. In addition, VIIa-TF/PL was found to inactivate thrombin-activated factor VIII. We hypothesize that these proteolyses may constitute an alternative pathway to regulate coagulation under certain conditions. In addition, the ability of VIIa-TF/PL to cleave factor VIII at 10 sites greatly expands the known protein substrate sequences recognized by this enzyme-cofactor complex.