Identification of a thrombin-interactive site within the FVIII A2 domain that is responsible for the cleavage at Arg372

Protein residue network analysis reveals fundamental properties of the human coagulation factor VIII

Hemophilia A is an X-linked inherited blood coagulation disorder caused by the production and circulation of defective coagulation factor VIII protein. People living with this condition receive either prophylaxis or on-demand treatment, and approximately 30% of patients develop inhibitor antibodies, a serious complication that limits treatment options. Although previous studies performed targeted mutations to identify important residues of FVIII, a detailed understanding of the role of each amino acid and their neighboring residues is still lacking. Here, we addressed this issue by creating a residue interaction network (RIN) where the nodes are the FVIII residues, and two nodes are connected if their corresponding residues are in close proximity in the FVIII protein structure. We studied the characteristics of all residues in this network and found important properties related to disease severity, interaction to other proteins and structural stability. Importantly, we found that the RIN-derived properties were in close agreement with in vitro and clinical reports, corroborating the observation that the patterns derived from this detailed map of the FVIII protein architecture accurately capture the biological properties of FVIII.

The C-terminal acidic region in the A1 domain of factor VIII facilitates thrombin-catalyzed activation and cleavage at Arg372

BACKGROUND

Factor VIII (FVIII) is activated by thrombin-catalyzed cleavage at three sites. Previous reports indicated that the A2 domain contained thrombin-interactive sites responsible for cleavage at Arg372 . We have also found that the A1 domain of FVIII bound to the anion-binding exosite I of thrombin. The present study focused, therefore, on thrombin interaction with A1 residues 337-372 containing clustered acidic and hirugen-like sequences.

AIM

To identify specific thrombin-interactive site(s) within the A1 acidic region of FVIII.

METHODS AND RESULTS

The synthetic peptide of residues 337-353 with sulfated Tyr346 (337-353S) significantly blocked thrombin-catalyzed FVIII activation and cleavage at Arg372 , while a corresponding peptide of residues 354-372 had no significant effect. Treatment with 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide to cross-link thrombin and 340-350S suggested that the 344-349 clustered acidic region was involved in thrombin interaction. Alanine-substituted FVIII mutants, Y346A and D347A/D348A/D349A, depressed thrombin-catalyzed activation and cleavage at Arg372 , with peak activation at ~ 50% and cleavage rates of ~ 10% to 20% compared to wild type (WT). The peak level of thrombin-catalyzed activation and the cleavage rate at Arg372 using FVIII mutants with 337-346 residues substituted with hirugen-sequences (MKNNEEAEDY337-346GDFEEIPEEY) were ~ 1.5- and ~ 2.5-fold of WT, respectively. Surface plasmon resonance-based analysis demonstrated that the Kd for active-site modified thrombin interactions using Y346A and D347A/D348A/D349A mutants was ~ 3- to 6-fold higher than that of WT, and that the hirugen-hybrid mutant facilitated association kinetics ~ 1.8-fold of WT.

CONCLUSION

Residues 346-349 with sulfated Tyr provided a thrombin-interactive site responsible for activation and cleavage at Arg372 . A hirugen-hybrid A1 mutant showed more efficient thrombin-catalyzed cleavage at Arg372 .

Acidic Region Residues 1680-1684 in the A3 Domain of Factor VIII Contain a Thrombin-Interactive Site Responsible for Proteolytic Cleavage at Arg1689

Factor VIII (FVIII) is activated by thrombin-catalyzed cleavage at Arg³⁷², Arg⁷⁴⁰, and Arg¹⁶⁸⁹. Our previous studies suggested that thrombin interacted with the FVIII C2 domain specific for cleavage at Arg¹⁶⁸⁹. An alternative report demonstrated, however, that a recombinant (r)FVIII mutant lacking the C2 domain retained >50% cofactor activity, indicating the presence of other thrombin-interactive site(s) associated with cleavage at Arg¹⁶⁸⁹. We have focused, therefore, on the A3 acidic region of FVIII, similar to the hirugen sequence specific for thrombin interaction (54-65 residues). Two synthetic peptides, spanning residues 1659-1669 with sulfated Tyr¹⁶⁶⁴ and residues 1675-1685 with sulfated Try¹⁶⁸⁰, inhibited thrombin-catalyzed FVIII activation and cleavage at Arg¹⁶⁸⁹. Treatment with 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide to cross-link thrombin with either peptide showed possible contributions of both 1664-1666 and 1683-1684 residues for thrombin interaction. Thrombin-catalyzed activation and cleavage at Arg¹⁶⁸⁹ in the alanine-substituted rFVIII mutants within 1663-1666 residues were similar to those of wild type (WT). Similar studies of 1680-1684 residues, however, demonstrated that activation and cleavage by thrombin of the FVIII mutant with Y1680A or D1683A/E1684A, in particular, were severely or moderately reduced to 20 to 30% or 60 to 70% of WT, respectively. Surface plasmon resonance-based analysis revealed that thrombin interacted with both Y1680A and D1683A/E1684A mutants with approximately sixfold weaker affinities of WT. Cleavage at Arg¹⁶⁸⁹ in the isolated light-chain fragments from both mutants was similarly depressed, independently of the heavy-chain subunit. In conclusion, the 1680-1684 residues containing sulfated Tyr¹⁶⁸⁰ in the A3 acidic region also contribute to a thrombin-interactive site responsible for FVIII activation through cleavage at Arg¹⁶⁸⁹.

A putative inhibitory mechanism in the tenase complex responsible for loss of coagulation function in acquired haemophilia A patients with anti-C2 autoantibodies

Acquired haemophilia A (AHA) is caused by the development of factor (F)VIII autoantibodies, demonstrating type 1 or type 2 inhibitory behaviour, and results in more serious haemorrhagic symptoms than in congenital severe HA. The reason(s) for this remains unknown, however. The global coagulation assays, thrombin generation tests and clot waveform analysis, demonstrated that coagulation parameters in patients with AHA-type 2 inhibitor were more significantly depressed than those in patients with moderate HA with similar FVIII activities. Thrombin and intrinsic FXa generation tests were significantly depressed in AHA-type 1 and AHA-type 2 compared to severe HA, and more defective in AHA-type 1 than in AHA-type 2. To investigate these inhibitory mechanism(s), anti-FVIII autoantibodies were purified from AHA plasmas. AHA-type 1 autoantibodies, containing an anti-C2 ESH4-epitope, blocked FVIII(a)-phospholipid binding, whilst AHA-type 2, containing an anti-C2 ESH8-epitope, inhibited thrombin-catalysed FVIII activation. The coagulation function in a reconstituted AHA-model containing exogenous ESH4 or ESH8 was more abnormal than in severe HA. The addition of anti-FIX antibody to FVIII-deficient plasma resulted in lower coagulation function than its absence. These results support the concept that global coagulation might be more suppressed in AHA than in severe HA due to the inhibition of FIXa-dependent FX activation by steric hindrance in the presence of FVIII-anti-C2 autoantibodies. Additionally, AHA-type 1 inhibitors prevented FVIIIa-phospholipid binding, essential for the tenase complex, whilst AHA-type 2 antibodies decreased FXa generation by inhibiting thrombin-catalysed FVIII activation. These two distinct mechanisms might, in part, contribute to and exacerbate the serious haemorrhagic symptoms in AHA.

Presented in abstract form at the 52nd annual meeting of the American Society of Hematology, Orlando, Florida, USA, December 6, 2010.

Effects of anti-factor VIII inhibitor antibodies on factor VIIa/tissue factor-catalysed activation and inactivation of factor VIII

Factor (F)VIIa/tissue factor (TF) rapidly activates FVIII activity by proteolysis at Arg372 and Arg740, and subsequently inactivates FVIIIa activity by proteolysis at Arg336, although this activation is weaker than that by thrombin. The effects of anti-FVIII inhibitor antibodies on these reactions remain unknown, however. In this study, 13 of anti-FVIII inhibitor antibodies recognising the A2 or C2 domain were prepared. None of them, irrespective of epitope specificity, significantly affected FVIIa/TFcatalysed FVIII activation in one-stage clotting assays. Anti-A2 and anti-C2 type 2 antibodies had little effect on the inactivation phase. Anti-C2 type 1 antibodies, however, modulated inactivation by 40–60% of that seen with control IgG, suggesting that the activity of FVIIIa generated by FVIIa/TF persisted in the presence of this specific type of inhibitor. SDS-PAGE analysis demonstrated that all antibodies had little effect on FVIIa/TF-catalyzed proteolysis at Arg372 and Arg740. Anti-C2 type 1, however, significantly delayed cleavage at Arg336 in dose-dependent manners. Neither anti-A2 nor anti-C2 type 2 affected this reaction, and the findings were consistent with the results of the functional assays. In addition, anti-C2 monoclonal antibodies with type 1 and 2 demonstrated similar patterns of reaction as the anti-C2 polyclonal antibodies in FVIIa/TF-mediated FVIII mechanisms. We demonstrated that FVIIa/TF activated FVIII even in the presence of anti-FVIII antibodies, but inactivation patterns appeared to depend on inhibitor type. It could be important to determine the characteristic of these inhibitor antibodies for prediction of their effects on FVIIa-related FVIII reactions, and the results could have significant therapeutic implications.

Note: An account of this work was presented at the 51st annual meeting of the American Society of Hematology, 2009, New Orleans, LA, USA. This work was supported by grants for MEXT KAKENHI 21591370 in Japan and Bayer Hemophilia Award program.

Functional mapping of the A2 domain from human factor VIII

Coagulation factor VIII (FVIII) is a multidomain glycoprotein in which the FVIII A2 domain is a key structural element. We aimed at identifying residues within FVIII A2 domain that are crucial for the maintenance of the cofactor function. A high number (n=206) of mutants were generated by substituting original residues with alanine. The mutants were expressed in COS-1 cells and their antigen levels and procoagulant activities were measured. The residues were classified in three categories: those with a non-detrimental alteration of their activities (activity >50 % of control FVIII; n=98), those with a moderate alteration (15 %<activity<50%; n=45) and those that were severely affected (activity<15%; n=63). The mutants sensitive to mutation were retrieved in the HAMSTeRS database with a higher percentage than those that were not affected (58.8% vs. 9.2%). The results revealed the existence of clusters of residues that are sensitive (Arg418-Phe436, Thr459-Ile475, Ser535-Gly549, Asn618-Ala635) or not (Leu398-Arg418, Pro485-Asp500, Gly506-Gly520, Pro596-Asp605) to mutations. The stretches of residues sensitive to mutations were buried within the molecule suggesting that these amino acids participate in the maintenance of the A2 domain structure. In contrast, residues resistant to mutations formed external loops without well- defined structures suggesting that these loops were not crucial for the process of factor X activation. This study provided a detailed map of the FVIII A2 domain between residues 371 and 649, identifying residues crucial for maintaining FVIII function and residues that can be mutated without jeopardising the coagulant activity.

Grading the commercial optical biosensor literature-Class of 2008: 'The Mighty Binders'

Optical biosensor technology continues to be the method of choice for label-free, real-time interaction analysis. But when it comes to improving the quality of the biosensor literature, education should be fundamental. Of the 1413 articles published in 2008, less than 30% would pass the requirements for high-school chemistry. To teach by example, we spotlight 10 papers that illustrate how to implement the technology properly. Then we grade every paper published in 2008 on a scale from A to F and outline what features make a biosensor article fabulous, middling or abysmal. To help improve the quality of published data, we focus on a few experimental, analysis and presentation mistakes that are alarmingly common. With the literature as a guide, we want to ensure that no user is left behind.