CT-001 is a rapid clearing factor VIIa with enhanced clearance and hemostatic activity for the treatment of acute bleeding in non-hemophilia settings.

INTRODUCTION: Acute bleeding leads to significant morbidity and mortality. Recombinant wildtype Factor VIIa (WT FVIIa) had been reported to have some therapeutic effects in some clinical trials, however, its use was associated with thromboembolic events. We sought to develop a novel FVIIa molecule (CT-001) with enhanced activity and lowered thrombogenicity risk. METHODS AND METHODS: CT-001 has 4 N-glycans (T106N/N145/V253N/N322) with terminal sialic acid residues removed to promote active clearance via the asialoglycoprotein receptor, and P10Q/K32E substitutions introduced to its gamma-carboxyglutamic acid (Gla) domain for enhanced phospholipid affinity and activity. RESULTS: In mice, CT-001 had a half-life of 5 min and a clearance of 467 mL/h/kg at 3 mg/kg, significantly faster than WT FVIIa (t1/2 = 1.8 h, Cl = 39 mL/h/kg). Interestingly, CT-001 was efficacious in reducing blood loss even with its rapid clearance. In a severe hemorrhage mouse model with tail amputated 5 cm from the tip, 1 mg/kg CT-001 provided efficacy comparable to 3 mg/kg WT FVIIa. The fast clearance of CT-001 resulted in significantly reduced thrombogenicity in comparison to WT FVIIa in a FeCl3-induced carotid artery thrombosis mouse model, and further confirmed in a soluble tissue factor-induced thrombosis model. CONCLUSIONS: The data on CT-001 demonstrate that a short duration of highly active FVIIa procoagulant activity has the potential to be an optimal paradigm for the treatment of acute bleeds.

In vitro characterization of CT-001-a short-acting factor VIIa with enhanced prohemostatic activity.

BACKGROUND: Traumatic injury and the associated acute bleeding are leading causes of death in people aged 1 to 44 years. Acute bleeding in pathological and surgical settings also represents a significant burden to the society. Yet there are no approved hemostatic drugs currently available. While clinically proven as an effective pro-coagulant, activated factor VII (FVIIa) use in acute bleeding has been hampered by unwanted thromboembolic events. Enhancing the ability of FVIIa to quickly stop a bleed and clear rapidly from circulation may yield an ideal molecule suitable for use in patients with acute bleeding. OBJECTIVES: To address this need and the current liability of FVIIa, we produced a novel FVIIa molecule (CT-001) with enhanced potency and shortened plasma residence time by cell line engineering and FVIIa protein engineering for superior efficacy for acute bleeding and safety. METHODS: To address safety, CT-001, a FVIIa protein with 4 desialylated N-glycans was generated to promote active recognition and clearance via the asialoglycoprotein receptor. To enhance potency, the gamma-carboxylated domain was modified with P10Q and K32E, which enhanced membrane binding. RESULTS: Together, these changes significantly enhanced potency and clearance while retaining the ability to interact with the key hemostatic checkpoint proteins antithrombin and tissue factor pathway inhibitor. CONCLUSIONS: These results demonstrate that a FVIIa molecule engineered to combine supra-physiological activity and shorter duration of action has the potential to overcome the current limitations of recombinant FVIIa to be a safe and effective approach to the treatment of acute bleeding.

Increased branching and sialylation of N-linked glycans correlate with an improved pharmacokinetic profile for BAY 81-8973 compared with other full-length rFVIII products.

BACKGROUND: BAY 81-8973 (Kovaltry) is an unmodified full-length recombinant factor VIII (rFVIII) for treatment of hemophilia A. The BAY 81-8973 manufacturing process results in a product of enhanced purity with a consistently high degree of branching and sialylation of N-linked glycans. This study evaluated whether a relationship exists between N-linked glycosylation patterns of BAY 81-8973 and two other rFVIII (sucrose-formulated rFVIII [rFVIII-FS; Kogenate FS]) and antihemophilic factor (recombinant) plasma/albumin-free method (rAHF-PFM; Advate) and their pharmacokinetic (PK) characteristics. MATERIALS AND METHODS: N-linked glycans or terminal carbohydrates were enzymatically removed from immobilized BAY 81-8973, rFVIII-FS, and rAHF-PFM proteins and analyzed using high-performance liquid chromatography to determine the percentage of individual N-linked glycan structures and degree of sialylation of each structure. PK data were available from two separate phase 1 crossover studies in which the PK profile of BAY 81-8973 was compared with that of rFVIII-FS (n=26) and rAHF-PFM (n=18) in patients with severe hemophilia A who received a single 50 IU/kg dose of each product. RESULTS: BAY 81-8973 and rFVIII-FS had increased N-linked glycan branching with higher levels of sialylation compared with rAHF-PFM. Levels of trisialylated glycans were 29.0% for BAY 81-8973 vs 11.5% for rFVIII-FS and 4.8%-5.5% for rAHF-PFM; tetrasialylated glycans were 12.0% vs 2.8% and 0.6%, respectively. Degree of sialylation was 96% for BAY 81-8973, 94% for rFVIII-FS, and 78%-81% for rAHF-PFM. Based on chromogenic assay results from the single-dose phase 1 PK studies, BAY 81-8973 half-life was 15% longer than that for rFVIII-FS and 16% longer than rAHF-PFM. CONCLUSION: Increased N-glycan branching and sialylation were seen for BAY 81-8973 vs rFVIII-FS and rAHF-PFM. Improved PK for BAY 81-8973 relative to rFVIII-FS and rAHF-PFM as seen in single-dose crossover PK studies might be related to this greater level of branching and sialylation, which can prolong the time BAY 81-8973 remains in the circulation.

The capacity to form H-DNA cannot substitute for GAGA factor binding to a (CT)n*(GA)n regulatory site.

Previous studies of the Drosophila melanogaster hsp26 gene promoter have demonstrated the importance of a homopurine*homopyrimidine segment [primarily (CT)n*(GA)n] for chromatin structure formation and gene activation. (CT)n regions are known to bind GAGA factor, a dominant enhancer of PEV thought to play a role in generating an accessible chromatin structure. The (CT)n region can also form an H-DNA structure in vitro under acidic pH and negative supercoiling; a detailed map of that structure is reported here. To test whether the (CT)n sequence can function through H-DNA in vivo, we have analyzed a series of hsp26-lacZ transgenes with altered sequences in this region. The results indicate that a 25 bp mirror repeat within the homopurine.homopyrimidine region, while adequate for H-DNA formation, is neither necessary nor sufficient for positive regulation of hsp26 when GAGA factor-binding sites have been eliminated. The ability to form H-DNA cannot substitute for GAGA factor binding to the (CT)n sequence.