Defective glycosylation of coagulation factor XII underlies hereditary angioedema type III
Jenny Björkqvist, … , Coen Maas, Thomas Renné
Jenny Björkqvist, … , Coen Maas, Thomas Renné
Published July 20, 2015
Citation Information: J Clin Invest. 2015;125(8):3132-3146. https://doi.org/10.1172/JCI77139.
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Research Article Vascular biology

Defective glycosylation of coagulation factor XII underlies hereditary angioedema type III

Abstract

Hereditary angioedema type III (HAEIII) is a rare inherited swelling disorder that is associated with point mutations in the gene encoding the plasma protease factor XII (FXII). Here, we demonstrate that HAEIII-associated mutant FXII, derived either from HAEIII patients or recombinantly produced, is defective in mucin-type Thr309-linked glycosylation. Loss of glycosylation led to increased contact-mediated autoactivation of zymogen FXII, resulting in excessive activation of the bradykinin-forming kallikrein-kinin pathway. In contrast, both FXII-driven coagulation and the ability of C1-esterase inhibitor to bind and inhibit activated FXII were not affected by the mutation. Intravital laser-scanning microscopy revealed that, compared with control animals, both F12–/– mice reconstituted with recombinant mutant forms of FXII and humanized HAEIII mouse models with inducible liver-specific expression of Thr309Lys-mutated FXII exhibited increased contact-driven microvascular leakage. An FXII-neutralizing antibody abolished bradykinin generation in HAEIII patient plasma and blunted edema in HAEIII mice. Together, the results of this study characterize the mechanism of HAEIII and establish FXII inhibition as a potential therapeutic strategy to interfere with excessive vascular leakage in HAEIII and potentially alleviate edema due to other causes.

Authors

Jenny Björkqvist, Steven de Maat, Urs Lewandrowski, Antonio Di Gennaro, Chris Oschatz, Kai Schönig, Markus M. Nöthen, Christian Drouet, Hal Braley, Marc W. Nolte, Albert Sickmann, Con Panousis, Coen Maas, Thomas Renné

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Figure 4

C1INH binds similarly to WT and mutated FXIIa.

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C1INH binds similarly to WT and mutated FXIIa. (A and B) Chromogenic sub...
(A and B) Chromogenic substrate conversion by preactivated FXII variants. Equimolar amounts of recombinant WT FXII, FXII_Thr309Lys, and FXII_Thr309Arg were preactivated with kallikrein that was subsequently blocked by aprotinin. S-2302 chromogenic substrate was added in the absence (empty columns) or presence (filled columns) of C1INH (250 μg/ml). Bars represent the optical density at 60 minutes. Mean ± SEM. n = 3. ***P < 0.001, unpaired 2-tailed Student’s t test. (B) Human FXII–deficient plasma was reconstituted to normal FXII plasma levels (375 nM) with purified activated WT FXIIa, FXIIa_Thr309Lys, or FXIIa_Thr309Arg and analyzed for time-dependent disappearance of FXIIa variants, indicating FXIIa-C1INH complex formation. Capture ELISA using B7 nanobody determined levels of free FXIIa in solution. Captured FXIIa was detected with a polyclonal antibody against FXII that in turn was photometrically quantified with a detection antibody and substrate reaction. Background signal in wells coated with control nanobodies (light colors). (C and D) 6xHis-tagged WT FXII and FXII_Thr309Lys proteins were immobilized on Biacore NTA sensor chips. C1INH was added in a dilution series (0.625–10 μM). Sensorgram of C1INH binding to (C) FXII and (D) FXII_Thr309Lys. Data from a single experiment that was performed 3 times are shown. Second-order rate constants were calculated from the binding data.