1区 · 医学
Article
作者: Urbanus, Rolf ; Gabriels, Sofie ; Percier, Jean-Michel ; de Haard, Hans ; Silence, Karen ; Blanchetot, Christophe ; Meeldijk, Jan ; Hack, C Erik ; Boon, Louis ; Van de Walle, Inge ; Cox, Linda ; Boross, Peter ; Holgate, Rob ; de Zeeuw, Elisabeth ; Dijkxhoorn, Kim ; Van de Ven, Liesbeth ; Simons, Peter J ; Budding, Kevin ; Leusen, Jeanette H W ; Yildiz, Cafer ; Wildemann, Johanna ; Otten, Henny G
BACKGROUND:Activation of the classical and lectin pathway of complement may contribute to tissue damage and organ dysfunction of antibody-mediated diseases and ischemia-reperfusion conditions. Complement factors are being considered as targets for therapeutic intervention.
OBJECTIVE:We sought to characterize ARGX-117, a humanized inhibitory monoclonal antibody against complement C2.
METHODS:The mode-of-action and binding characteristics of ARGX-117 were investigated in detail. Furthermore, its efficacy was analyzed in in vitro complement cytotoxicity assays. Finally, a pharmacokinetic/pharmacodynamic study was conducted in cynomolgus monkeys.
RESULTS:Through binding to the Sushi-2 domain of C2, ARGX-117 prevents the formation of the C3 proconvertase and inhibits classical and lectin pathway activation upstream of C3 activation. As ARGX-117 does not inhibit the alternative pathway, it is expected not to affect the antimicrobial activity of this complement pathway. ARGX-117 prevents complement-mediated cytotoxicity in in vitro models for autoimmune hemolytic anemia and antibody-mediated rejection of organ transplants. ARGX-117 exhibits pH- and calcium-dependent target binding and is Fc-engineered to increase affinity at acidic pH to the neonatal Fc receptor, and to reduce effector functions. In cynomolgus monkeys, ARGX-117 dose-dependently reduces free C2 levels and classical pathway activity. A 2-dose regimen of 80 and 20 mg/kg separated by a week, resulted in profound reduction of classical pathway activity lasting for at least 7 weeks.
CONCLUSIONS:ARGX-117 is a promising new complement inhibitor that is uniquely positioned to target both the classical and lectin pathways while leaving the alternative pathway intact.