A human FVIII inhibitor modulates FVIII surface electrostatics at a VWF-binding site distant from its epitope.

SUMMARY BACKGROUND: BO2C11 is a human monoclonal factor (F) VIII inhibitor. When bound to the C2 domain of FVIII, the Fab fragment of BO2C11 (Fab(BO2C11)) buries a surface of C2 that contains residues participating in a binding site for von Willebrand factor (VWF). BO2C11 has thus been proposed to neutralize FVIII by steric hindrance. OBJECTIVES: The BO2C11 epitope on C2 overlaps with residues located at the periphery of the putative VWF binding site; hence, most of the residues that constitute the VWF binding site on C2 and a3 remain accessible for VWF interaction following BO2C11/FVIII complex formation. We thus investigated the contribution of alternative molecular mechanisms to FVIII inactivation by BO2C11. METHODS: Continuum electrostatic calculations were applied to the crystal structure of C2, free or Fab(BO2C11)-complexed. In silico predictions were confirmed by site-directed mutagenesis and VWF-binding assays of the mutated FVIII. RESULTS: Binding of Fab(BO2C11) to C2 induced perturbations in the electrostatic potential of C2 and in the local electrostatic parameters of 18 charged residues in C2, which are distant from the BO2C11 epitope. Nine of the predicted electrostatic hotspots clustered on the VWF-binding site of C2. Mutation of some of the predicted electrostatic hotspots has been associated with hemophilia A and reduced VWF binding in vitro. CONCLUSIONS: Inhibitors may neutralize FVIII by alteration of protein surface electrostatics at a long distance from their epitope. Perturbation of the electrostatic environment of C2, either upon binding by anti-FVIII antibodies or consecutive to missense mutations in the F8 gene, may lead to hampered VWF binding and reduced FVIII residence time in circulation.

Activated factor X cleaves factor VIII at arginine 562, limiting its cofactor efficiency.

BACKGROUND: Factor VIII (FVIII) and its activated form (FVIIIa) are subject to proteolysis that dampens their cofactor function. Among the proteases that attack FVIII (activated factor X (FXa), activated protein C (APC) and plasmin), only APC cleaves within the FVIII A2 domain at R562 to fully abolish FVIII activity. OBJECTIVES: We investigated the possible involvement of the FXa cleavage at R562 within the A2 domain in the process of FVIII inactivation. METHODS: An antibody (GMA012/R8B12) that recognizes the carboxy-terminus extremity of the A2 domain (A2C) was used to evaluate FXa action. A molecule mutated at R562 was also generated to assess the functional role of this particular residue. RESULTS AND CONCLUSIONS: The appearance of the A2C domain as a function of time evidenced the identical cleavage within the A2 domain of FVIII and FVIIIa by FXa. This cleavage required phospholipids and occurred within minutes. In contrast, the isolated A2 domain was not cleaved by FXa. Von Willebrand factor and activated FIX inhibited the cleavage in a dose-dependent manner. Mutation R562K increased both the FVIII specific activity and the generation of FXa due to an increase in FVIII catalytic efficiency. Moreover, A2C fragment could not be identified from FVIII-R562K cleavage. In summary, this study defines a new mechanism for A2 domain-mediated FVIII degradation by FXa and implicates the bisecting of the A2 domain at R562.

Two novel mutations in EGF-like domains of human factor IX dramatically impair intracellular processing and secretion.

We investigated the mechanisms responsible for severe factor IX (FIX) deficiency in two cross-reacting material (CRM)-negative hemophilia B patients with a mutation in the first and second epidermal growth factor (EGF) domains of FIX (C71Y and C109Y, respectively). We have determined the kinetics of mutant FIX biosynthesis and secretion in comparison with wild-type FIX (FIXwt). In transfected cells, FIXwt was retrieved as two intracellular molecular forms, rapidly secreted into the culture medium. One appeared to be correctly N-glycosylated, and corresponded to a form trafficking between the endoplasmic reticulum (ER) and Golgi apparatus. The other corresponded to the mature form, ready to be secreted, exhibiting correct N-glycosylation and sialylation. In contrast, the two mutants, FIXC71Y and FIXC109Y, were not secreted from the cells and did not accumulate intracellularly. Relative to FIXwt, they were retained longer in the ER and were only N-glycosylated. In addition, the intracellular concentration of the FIX mutants increased when ALLN, an inhibitor of cysteine proteases and of the proteasome degradation pathway, was added to the culture medium. Both the FIX mutants and FIXwt were associated in the ER with the 78-kDa glucose-regulated protein (GRP78/BiP) and calreticulin (CRT), though the amount of CRT associated with the two mutants was twice as strong as with FIXwt. These results strongly suggest that chaperone and lectin molecules act in concert to ensure both proper folding of FIXwt and the retention of mutant molecules.

The P-selectin cytoplasmic domain directs the cellular storage of a recombinant chimeric factor IX.

Hemophilia B was recognized as a good candidate for gene therapy. Several strategies have been attempted and gave promising results in hemophilic animals but failed to achieve corrective levels in humans. To overcome this inconvenience we aimed to generate intracellular pools of factor (F)IX in cells that are implicated in the hemostatic response, e.g. endothelial cells and platelets. Upon stimulation, these cells release their granule content, which in this case would result in an increase in local FIX concentration, and could locally produce an effective hemostasis. In an attempt to produce an intracellular pool of releasable coagulation FIX, the cytoplasmic domain of the P-selectin (pselCT) molecule was fused to the carboxy-terminal extremity of the human FIX protein. The properties of this chimeric molecule (FIX-pselCT) were studied in AtT20, a cell line which possesses storage granules. As previously shown for transmembrane molecules but not for a soluble protein such as FIX, the pselCT fragment induces the storage of FIX-pselCT. The coagulant activity of FIX-pselCT was not affected by the addition of the pselCT tail. The treatment of AtT20 cells with different inhibitors revealed that FIX-pselCT was not submitted to intracellular degradation and that the half-life of the chimeric molecule was at least two times longer than that of FIX-WT. An immunoelectron microscopic analysis demonstrated a specific localization of FIX-pselCT within the ACTH-containing granules. Cell stimulation using Phorbol Myristrate Acetate (PMA), ionophore A-23187 or 8-Br-cAMP induced efficient release of an active FIX-pselCT. These data demonstrate that the addition of the cytoplasmic domain of P-selectin to FIX modifies the cellular fate of the FIX molecule by directing the recombinant protein toward regulated-secretory granules without altering its coagulant activity.

Expression of coagulation factor IX in a haematopoietic cell line.

We have developed a gene therapy project for haemophilia B which aims to express factor IX (FIX) in haematopoietic lineage. Haematopoietic stem cells and subsequent megakaryocyte-derived cells represent the target cells of this approach. Our speculation is that platelets can deliver the coagulation factor at the site of injury, and subsequently correct the haemostasis defect. In order to direct FIX expression in cells from the megakaryocytic lineage, we designed a FIX cassette where the FIX cDNA was placed under the control of the tissue-specific glycoprotein IIb (GPIIb) promoter. In stably transfected HEL cells, FIX production was higher when driven by the GPIIb promoter compared to the CMV promoter. Using a cassette containing both the GPIIb promoter and a truncated FIX intron 1, FIX synthesis was dramatically increased in HEL cells. Northern blot analysis demonstrated an increase in FIX mRNA amounts, which paralleled with an increase of FIX antigen in the culture supernatants. Using a one-stage clotting assay and an activation by FXIa and FVIIa/TF, the HEL-derived recombinant FIX was shown to be a biologically active protein. This recombinant protein exhibited a 60-kDa molecular mass and was more heterogeneous than plasma immunopurified FIX (Mononine). The molecular mass difference could be partly explained by a different glycosylation pattern. The GPIIb promoter appears therefore to be a very attractive sequence to specifically direct FIX production in the megakaryocytic compartment of hematopoietic cells. These data also demonstrate that hematopoietic cells may represent potential target cells in an approach to gene therapy of haemophilia B.

A factor VIII minigene comprising the truncated intron I of factor IX highly improves the in vitro production of factor VIII.

The biosynthesis of coagulation factor VIII (FVIII) is hampered by successive controls that limit its production. To improve this production, a truncated intron I sequence of factor IX (TFIXI1) was inserted in FVIII cDNA in place of FVIII introns 1, 12 and 13 and also as a combination between introns 1 and 12, and introns 1 and 13. The intron 12 and 13 locations were targeted because this region was previously shown to contain a transcriptional silencer. The expression of FVIII in CHO and HepG2 cells revealed important variations in the properties of the minigenes depending on the TFIXI1 insertion sites. In FVIII intron 13 location the TFIXI1 seemed to diminish the transcriptional silencer activity, whereas it was poorly spliced in intron 12 position. Among the five constructs, FVIII I1+13 leaded to a significant improvement in FVIII secretion (13 times) that was associated with a dramatic intracellular accumulation in cells. Therefore, the FVIII I1+13 minigene could represent a particular interest to produce recombinant FVIII in vitro as well as in the aim of gene therapy of haemophilia A.

The three in-frame ATG, clustered in the translation initiation sequence of human factor IX gene, are required for an optimal protein production.

Three in-frame potential methionine codons have been identified in human factor IX gene and are clustered at amino acids -46, -41 and -39. In view of initiating a gene therapy approach, human factor IX production has been evaluated after modifications of these first three in-frame translation start sites. To characterize the most efficient translation initiation context, five factor IX cDNA expression vectors directed by CMV promoter-enhancer were generated. These vectors contained different starting site combinations including one, two or three ATG. A quantitative analysis of factor IX production in stably transfected CHO cells and in a rabbit reticulocyte lysate cell free system revealed the ability of all single site to generate fully active factor IX. However, the factor IX production level increased with the ATG number and the wild type (WT) cDNA bearing the 3 ATG induced the highest protein production. A truncated intron I of factor IX, previously suggested of having an expression-augmenting activity, was also placed in the WT factor IX cDNA. In stably transfected CHO cells, a 8-fold increase in protein production was measured. These results show that at least in vitro, the presence of the three ATG seems to be crucial for a maximal factor IX production. The data also suggest that both the three ATG and the truncated intron I are required for an optimal factor IX production in a perspective of a human gene therapy of haemophilia.

Thrombin-induced increase in endothelial permeability is associated with changes in cell-to-cell junction organization.

Thrombin increases endothelial permeability in a rapid and reversible way. This effect requires the catalytic activity of the enzyme and thrombin receptor engagement. Endothelial cell permeability is mostly regulated by intercellular junction organization. In the present study, we investigated whether opening of intercellular gaps after thrombin treatment could be related to changes in adherence-junction molecular organization. By immunofluorescence analysis, we found that thrombin stimulation of endothelial cells caused a marked alteration of the distribution of vascular endothelial (VE)-cadherin and of the associated catenins. These molecules, which are strictly localized at intercellular boundaries in confluent resting cells, were absent in the areas of intercellular retraction. Immunoprecipitation analysis indicated that thrombin disrupted the VE-cadherin/catenin complex. This effect was reversible and correlated with the increase in endothelial permeability. The use of a protein kinase C inhibitor (calphostin C) blocked both thrombin-induced permeability and disassembly of adherence-junction components. We propose that thrombin's effect on endothelial cell junction organization is an important determinant in the increase in endothelial permeability induced by this agent.

Role of the thrombin insertion loop 144-155. Study of thrombin mutations W148G, K154E and a thrombin-based synthetic peptide.

Thrombin is a multifunctional serine protease that plays a critical role in hemostasis. Crystallographic studies revealed that the insertion loop, residues 144-155 (human thrombin B chain numbering) located on the surface of thrombin, might be involved in the access of substrates to the active-site of the enzyme. This loop has also been proposed as a potential candidate for a binding site for thrombomodulin and selected thrombin substrates. In order to examine this hypothesis, we have introduced single amino acid substitutions into the loop 144-155 (W148G, K154E). These point mutations did not result in major changes in thrombin specificity. However, the mutant thrombins presented slight modifications in their catalytic activity on the tripeptidic substrate H-D-Lys-(epsilon-benzyloxycarbonyl)-Pro-Arg-NH-nitroanilide ([K154E]thrombin) or tosyl-Gly-Pro-Arg-NH-nitroanilide ([W148G]thrombin), and in the second-order rate constants of inhibition by antithrombin III ([K154E]thrombin) and ([W148G]thrombin) compared to recombinant wild-type thrombin. Kinetics of fibrinogen hydrolysis were minimally affected by the K154E mutation and were not affected by the W148G mutation. Neither of the mutations affected thrombin interaction with hirudin or its C-terminal tail, protein C activation by thrombin or thrombin-thrombomodulin, or platelet activation. We also examined the properties of a synthetic peptide corresponding to the sequence T147-S158. The synthetic peptide T147-S158 did not inhibit thrombin interaction with fibrin, thrombomodulin or protein C. Together, our results indicate that the thrombin loop 144-155 is indirectly involved in the catalytic function of the enzyme, most probably by limiting the access of the substrates to the catalytic site, and argue against the presence of a recognition exosite for fibrin(ogen), thrombomodulin or platelets within the loop.

Thrombin-induced endothelial cell dysfunction.

Endothelium is a multifunctional organ which can directly influence circulating blood components as well as other cells within the vessel wall. The clotting enzyme thrombin, generated at the surface of damaged endothelium, induces blood coagulation but also exerts a variety of functional effects on the endothelium itself. Thrombin acts on endothelial cells to stimulate synthesis and release of various agents, such as inflammatory mediators, vasoactive substances and growth factors. It causes leukocyte adhesion to the endothelium by triggering expression of adhesion molecules on the cell surface and causes disruption of endothelial permeability properties. The majority of thrombin effects on endothelial cells are mediated by its receptor and require its lytic activity. Differences have been observed among the response to thrombin of endothelial cells of different origin. In general microvascular endothelial cells appear to be particularly sensitive to this enzyme. Thrombin induced microvascular dysfunction can have pathological consequences and contribute to organ reactions to inflammation and ischaemia.

Evidence for a selective inhibitory effect of thrombin on megakaryocyte progenitor growth mediated by the thrombin receptor.

An efficient method for the culture of human megakaryocyte precursors in serum-free medium has been developed facilitating study of the effect of regulators of megakaryocyte growth and maturation without interference by serum-derived factors. We have investigated how megakaryocytes and their precursors respond to the procoagulant enzyme, thrombin. In addition to its already documented agonist effect on mature megakaryocytes, thrombin was found to have a marked inhibitory effect on the growth of megakaryocyte colonies from CD34+ bone marrow cells stimulated by IL3. This inhibitory effect, not previously reported, was selective for megakaryocytic cells. The growth of granulomonocytic and erythroid colonies was not affected. A monoclonal antibody which neutralized the effect of exogenous transforming growth factor beta (TGF beta) was unable to fully neutralize the inhibitory effect of thrombin. With the use of a synthetic peptide, corresponding to the tethered thrombin receptor ligand, and of a recombinant inactive form of thrombin, we provide direct evidence that both the inhibitory effect of thrombin on megakaryocyte proliferation and its agonist effect on mature megakaryocytes are mediated by a receptor analogous to the recently cloned platelet thrombin receptor.