Prolonged half-life and preserved enzymatic properties of factor IX selectively PEGylated on native N-glycans in the activation peptide.

Current management of hemophilia B entails multiple weekly infusions of factor IX (FIX) to prevent bleeding episodes. In an attempt to make a longer acting recombinant FIX (rFIX), we have explored a new releasable protraction concept using the native N-glycans in the activation peptide as sites for attachment of polyethylene glycol (PEG). Release of the activation peptide by physiologic activators converted glycoPEGylated rFIX (N9-GP) to native rFIXa and proceeded with normal kinetics for FXIa, while the K(m) for activation by FVIIa-tissue factor (TF) was increased by 2-fold. Consistent with minimal perturbation of rFIX by the attached PEG, N9-GP retained 73%-100% specific activity in plasma and whole-blood-based assays and showed efficacy comparable with rFIX in stopping acute bleeds in hemophilia B mice. In animal models N9-GP exhibited up to 2-fold increased in vivo recovery and a markedly prolonged half-life in mini-pig (76 hours) and hemophilia B dog (113 hours) compared with rFIX (16 hours). The extended circulation time of N9-GP was reflected in prolonged correction of coagulation parameters in hemophilia B dog and duration of effect in hemophilia B mice. Collectively, these results suggest that N9-GP has the potential to offer efficacious prophylactic and acute treatment of hemophilia B patients at a reduced dosing frequency.

Generation and biochemical characterization of glycoPEGylated factor VIIa derivatives.

Prophylaxis with 2-4 times weekly dosing of factor (F)VIII or FIX is established as an efficacious and safe treatment in haemophilia. Although prophylaxis is not readily available for the inhibitor patient, recent studies have demonstrated a reduction in bleeding episodes in inhibitor patients treated with daily infusions of FVIIa. In order to develop a treatment option comparable to prophylaxis with FVIII or FIX we looked to PEGylation which is an established method for prolonging the circulatory half-life of proteins. However, due to the numerous interactions of FVIIa with the cell surface, TF, FIX and FX there are limited options for unspecific chemical modification of FVIIa without loss of activity. Consequently, we explored the GlycoPEGylationtrade mark technology for selective PEGylation of the two N-glycans in the FVIIa light chain and protease domain to generate seven specifically modified derivatives with PEG groups ranging from 2 to 40 kDa. These derivatives were evaluated in vitro for their ability to interact with small synthetic substrates as well as key molecules relevant to function in the coagulation pathway. The results demonstrate that modification of FVIIa using glycoPEGylation has only a very limited effect on the hydrolysis S-2288 and FX activation. However, the modification does to some extend alter the ability of FVIIa to interact with TF and more importantly, reduces the rate of ATIII inhibition by up to 50% which could allow for an extended active half-life in circulation.