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DOI: 10.1160/th14-03-0198
Coagulation factor VII variants resistant to inhibitory antibodies
Financial support: This work was supported by AIFA (AIFA 2008 – Bando per le malattie rare – Progetto RF-null-2008–1235892) (Francesco Bernardi, Mirko Pinotti), Telethon-Italy (GGP09183)(Alessio Branchini, Marcello Baroni, Francesco Bernardi, Mirko Pinotti) and CSL Behring (Muriel Giansily-Blaizot and Caroline Pfeiffer).
Publication History
Received:
05 March 2014
Accepted after minor revision:
19 June 2014
Publication Date:
20 November 2017 (online)
Summary
Replacement therapy is currently used to prevent and treat bleeding episodes in coagulation factor deficiencies. However, structural differences between the endogenous and therapeutic proteins might increase the risk for immune complications. This study was aimed at identifying factor (F)VII variants resistant to inhibitory antibodies developed after treatment with recombinant activated factor VII (rFVIIa) in a FVII-deficient patient homozygous for the p.A354V-p.P464Hfs mutation, which predicts trace levels of an elongated FVII variant in plasma. We performed fluorescent bead-based binding, ELISA-based competition as well as fluorogenic functional (activated FX and thrombin generation) assays in plasma and with recombinant proteins. We found that antibodies displayed higher affinity for the active than for the zymogen FVII (half-maximal binding at 0.54 ± 0.04 and 0.78 ± 0.07 BU/ml, respectively), and inhibited the coagulation initiation phase with a second-order kinetics. Isotypic analysis showed a polyclonal response with a large predominance of IgG1. We hypothesised that structural differences in the carboxyl-terminus between the inherited FVII and the therapeutic molecules contributed to the immune response. Intriguingly, a naturally-occurring, poorly secreted and 5-residue truncated FVII (FVII-462X) escaped inhibition. Among a series of truncated rFVII molecules, we identified a well-secreted and catalytically competent variant (rFVII-464X) with reduced binding to antibodies (half-maximal binding at 0.198 ± 0.003 BU/ml) as compared to the rFVII-wt (0.032 ± 0.002 BU/ml), which led to a 40-time reduced inhibition in activated FX generation assays. Taken together our results provide a paradigmatic example of mutation-related inhibitory antibodies, strongly support the FVII carboxyl-terminus as their main target and identify inhibitor-resistant FVII variants.
Keywords
Inhibitory antibodies - replacement therapy - factor VII deficiency - carboxyl-terminus - recombinant proteins* A. Branchini and M. Baroni contributed equally to this study.
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