Unraveling structure and performance of protein a ligands at liquid–solid interfaces: A multi-techniques analysis

Abstract

Oriented ligand immobilization is one of the most effective strategies used in the design and construction of a high-capacity protein A chromatography. In this work, cysteine was introduced as anchoring sites by substituting a specific residue on Helix I, II, and at C-terminus of antibody binding domain Z from protein A, respectively, to investigate structural evolution and binding behavior of protein A ligands at liquid–solid interfaces. Among the three affinity dextran-coated Fe3O4 magnetic nanoparticles (Fe3O4@Dx MNPs), affinity MNPs with the immobilized ligand via N11C on Helix I (Fe3O4@Dx-Z1 MNPs) had the highest helical content, and MNPs with the immobilized ligand via G29C on Helix II (Fe3O4@Dx-Z2 MNPs) had the lowest helical content at the same pHs. It was attributed to less electrostatic attraction of ligand to negatively charged surface on Fe3O4@Dx-Z1 MNPs because of less positive charged residues on Helix I (K6) than Helix II (R27/K35). Among the three affinity MNPs, moreover, the highest affinity to immunoglobulin G (IgG) binding was observed on Fe3O4@Dx-Z1 MNPs in isothermal titration calorimetry measurement, further validating greater structural integrity of the ligand on Fe3O4@Dx-Z1 MNPs. Finally, the study of IgG binding on MNPs and 96-well plates showed that anchoring sites for ligand immobilization had distinct influences on IgG binding and IgG-mediated antigen binding. This work illustrated that anchoring sites of the ligands had a striking significance for the molecular structure of the ligand at liquid–solid interfaces and raised an important implication for the design and optimization of protein A chromatography and protein A-based immunoassay analysis.