Chromatographic behavior of bivalent bispecific antibodies on hydrophobic interaction chromatography columns

Abstract

The elution behavior of bivalent bispecific antibodies (BiSAb) comprising an immunoglobulin G framework genetically fused to a pair of single chain variable fragments (scFvs) was studied on hydrophobic interaction chromatography (HIC) columns using ammonium sulfate gradients. Each of the BiSAb molecules studied exhibited a three-peak elution behavior regardless of the location of scFv attachment to the framework IgG. Collecting and re-injecting each of the isolated peaks and eluting with the same gradient resulted in the same three-peak profile indicating that the behavior is reversible. Analogous behavior was observed for HIC resins with different functional ligands, matrix structures, and particle sizes. Residence time, operating temperature, and hold time were shown to affect the elution behavior. While three peaks were obtained at short residence times and room temperature, residence times longer than about 27 min or operating at 45 °C resulted in a single merged peak indicating that the underlying mechanism occurs on time scales comparable to that of chromatographic separation. Holding the protein on the resins prior to elution enriched the late eluting peak indicating that multiple binding states formed on the chromatographic surface are responsible for this behavior. Tryptophan auto-fluorescence measurements show that stronger binding forms have increased solvent exposure indicating that surface-catalyzed conformational changes play a role. A model was developed to describe the interplay of chromatographic separation and slow conformational changes.