Factor IX oligomerization underlies reduced activity upon disruption of physiological conditions.

Coagulation factor IX (FIX) is a serine protease that plays a pivotal role in the blood coagulation cascade. FIX deficiency leads to a blood clotting disorder known as haemophilia B. FIX, synthesized as a prepro-peptide of 461 amino acids, is processed and secreted into plasma. The protein undergoes numerous modifications, including, but not limited to glycosylation, γ-carboxylation and disulphide bond formation. Upon processing and limited proteolysis, the protein is converted into an active protease. Under physiological conditions, the FIX zymogen is a monomer. The purpose of this work was to analyse the conditions that may affect FIX monomeric state and promote and/or reduce oligomerization. Using native gel electrophoresis and size exclusion chromatography, we found that under decreased pH and ionic strength conditions, the FIX zymogen can oligomerize, resulting in the formation of higher molecular weight species, with a concomitant reduction in specific activity. Similarly, FIX oligomers formed readily with low bovine serum albumin (BSA) concentrations; however, increased BSA concentrations impeded FIX oligomerization. We hypothesize that normal blood physiological conditions are critical for maintaining active FIX monomers. Under conditions of stress associated with acidosis, electrolyte imbalance and low albumin levels, FIX oligomerization is expected to take place thus leading to compromised activity. Furthermore, albumin, which is commonly used as a drug stabilizer, may enhance the efficacy of FIX biological drugs by reducing oligomerization.

Efficacy of a potential trivalent vaccine based on Hc fragments of botulinum toxins A, B, and E produced in a cell-free expression system.

Botulinum toxins produced by the anaerobic bacterium Clostridium botulinum are the most potent biological toxins in nature. Traditionally, people at risk are immunized with a formaldehyde-inactivated toxin complex. Second generation vaccines are based on the recombinant carboxy-terminal heavy-chain (Hc) fragment of the neurotoxin. However, the materialization of this approach is challenging, mainly due to the high AT content of clostridial genes. Herein, we present an alternative strategy in which the native genes encoding Hc proteins of botulinum toxins A, B, and E were used to express the recombinant Hc fragments in a cell-free expression system. We used the unique property of this open system to introduce different combinations of chaperone systems, protein disulfide isomerase (PDI), and reducing/oxidizing environments directly to the expression reaction. Optimized expression conditions led to increased production of soluble Hc protein, which was successfully scaled up using a continuous exchange (CE) cell-free system. Hc proteins were produced at a concentration of more than 1 mg/ml and purified by one-step Ni(+) affinity chromatography. Mice immunized with three injections containing 5 microg of any of the in vitro-expressed, alum-absorbed, Hc vaccines generated a serum enzyme-linked immunosorbent assay (ELISA) titer of 10(5) against the native toxin complex, which enabled protection against a high-dose toxin challenge (10(3) to 10(6) mouse 50% lethal dose [MsLD(50)]). Finally, immunization with a trivalent HcA, HcB, and HcE vaccine protected mice against the corresponding trivalent 10(5) MsLD(50) toxin challenge. Our results together with the latest developments in scalability of the in vitro protein expression systems offer alternative routes for the preparation of botulinum vaccine.