Effects of Glycan Structure on the Stability and Receptor Binding of an IgG4-Fc.

A series of well-defined N-glycosylated IgG4-Fc variants were utilized to investigate the effect of glycan structure on their physicochemical properties (conformational stability and photostability) and interactions with an Fc γ receptor IIIA (FcγRIIIA). High mannose (HM, GlcNAc2Man(8+n) [n = 0-4]), Man5 (GlcNAc2Man5), GlcNAc1, and N297Q IgG4-Fc were prepared in good quality. The physical stability of these IgG4-Fc variants was examined with differential scanning calorimetry and intrinsic fluorescence spectroscopy. Photostability was assessed after photoirradiation between 295 and 340 nm (λ max = 305 nm), and HPLC-MS/MS analysis of specific products was performed. The size of glycans at Asn297 affects the yields of light-induced Tyr side-chain fragmentation products, where the yields decreased in the following order: N297Q > GlcNAc1 > Man5 > HM. These yields correlate with the thermal stability of the glycoforms. The HM and Man5 glycoforms display increased affinity for FcγRIIIA by at least 14.7-fold compared with GlcNAc1 IgG4-Fc. The affinities measured for the HM and Man5 IgG4-Fc (0.39-0.52 µM) are similar to those measured for fucosylated IgG1. Dependent on the mechanisms of action of IgG4 therapeutics, such glycoforms may need to be carefully monitored. The nonglycosylated N297Q IgG4-Fc did not present measurable affinity to FcγRIIIA.

Photoactivable antibody binding protein: site-selective and covalent coupling of antibody.

Here we report new photoactivable antibody binding proteins, which site-selectively capture antibodies and form covalent conjugates with captured antibodies upon irradiation. The proteins allow the site-selective tagging and/or immobilization of antibodies with a highly preferred orientation and omit the need for prior antibody modifications. The minimal Fc-binding domain of protein G, a widely used antibody binding protein, was genetically and chemically engineered to contain a site-specific photo cross-linker, benzophenone. In addition, the domain was further mutated to have an enhanced Fc-targeting ability. This small engineered protein was successfully cross-linked only to the Fc region of the antibody without any nonspecific reactivity. SPR analysis indicated that antibodies can be site-selectively biotinylated through the present photoactivable protein. Furthermore, the system enabled light-induced covalent immobilization of antibodies directly on various solid surfaces, such as those of glass slides, gold chips, and small particles. Antibody coupling via photoactivable antibody binding proteins overcomes several limitations of conventional approaches, such as random chemical reactions or reversible protein binding, and offers a versatile tool for the field of immunosensors.