Alkaline cation-exchange chromatography for the reduction of aggregate and a mis-formed disulfide variant in a bispecific antibody purification process.

During the purification development of a bispecific antibody, cation-exchange chromatography was screened for its ability to separate a prominently expressed (>12%) mis-formed disulfide bond variant, termed MAb-diabody, and aggregate from the product of interest. The influence of pH, product load (g of product per liter of resin) and linear velocity on the separations were evaluated for the strong cation-exchange resins SP Sepharose HP and POROS(®) HS50. Cation-exchange chromatography is commonly operated distant to the isoelectric point of a molecule, generally leading to acidic conditions for antibody purification. However, the results herein demonstrated improved removal of MAb-diabody with increasing pH, resulting in reduction of MAb-diabody content greater than 12-fold when operating near the alkaline pI of the product. This approach was successful over a range of linear velocities and g/L of resin loading. Aggregate removal was less affected by pH and was effectively reduced from 10.9% to less than 3% for each condition. Furthermore, this method was successfully scaled to a 60 cm diameter column using SP Sepharose HP resin.

Do heterotrimeric G proteins redistribute upon G protein-coupled receptor stimulation in platelets?

Previous studies have proposed that stimulation of G protein-coupled receptors can cause a redistribution of G proteins to other receptors. The redistribution would cause a greater functional sensitivity of unsensitized 'secondary' receptors toward their agonists. Using platelets as a model system, we utilized a proximal signaling event, intracellular calcium mobilization, to determine if agonist stimulation of particular Gq-coupled receptors would result in increased sensitivity for stimulation of other Gq-coupled receptors. Platelets express three Gq-coupled receptors for thrombin, thromboxane A2, and ADP with different potencies. Varying concentrations of a primary agonist (PAR-1 agonist SFLLRN, or the TXA2 agonist U46619) was followed by a constant submaximal concentration of a secondary agonist (U46619, or the P2Y1 agonist ADP). We observed that initial stimulation by SFLLRN was followed by a decrease in the extent of secondary U46619 or ADP-mediated calcium mobilization in comparison to control responses (i.e. without primary stimulation). To extend these studies we examined calcium mobilization in platelets from mice that were either wild-type or homozygous null for the PAR-4 or P2Y1 receptors, hypothesizing that the loss of PAR-4 or P2Y1 receptors would cause redistribution of its Galphaq proteins to other receptors, and elicit a greater response when stimulated with other agonists than in platelets from a wild-type mouse. However, our results showed almost identical levels of peak calcium between wild-type or PAR-4 null mice when stimulated with either ADP or U46619. Similar results were obtained for the P2Y1 null mice stimulated with AYPGKF or U46619. We conclude that stimulation of one Gq coupled receptor does not result in redistribution of Gq to other Gq-coupled receptors.