Mapping the Energetic Epitope of an Antibody/Interleukin-23 Interaction with Hydrogen/Deuterium Exchange, Fast Photochemical Oxidation of Proteins Mass Spectrometry, and Alanine Shave Mutagenesis.

Epitope mapping the specific residues of an antibody/antigen interaction can be used to support mechanistic interpretation, antibody optimization, and epitope novelty assessment. Thus, there is a strong need for mapping methods, particularly integrative ones. Here, we report the identification of an energetic epitope by determining the interfacial hot-spot that dominates the binding affinity for an anti-interleukin-23 (anti-IL-23) antibody by using the complementary approaches of hydrogen/deuterium exchange mass spectrometry (HDX-MS), fast photochemical oxidation of proteins (FPOP), alanine shave mutagenesis, and binding analytics. Five peptide regions on IL-23 with reduced backbone amide solvent accessibility upon antibody binding were identified by HDX-MS, and five different peptides over the same three regions were identified by FPOP. In addition, FPOP analysis at the residue level reveals potentially key interacting residues. Mutants with 3-5 residues changed to alanine have no measurable differences from wild-type IL-23 except for binding of and signaling blockade by the 7B7 anti-IL-23 antibody. The M5 IL-23 mutant differs from wild-type by five alanine substitutions and represents the dominant energetic epitope of 7B7. M5 shows a dramatic decrease in binding to BMS-986010 (which contains the 7B7 Fab, where Fab is fragment antigen-binding region of an antibody), yet it maintains functional activity, binding to p40 and p19 specific reagents, and maintains biophysical properties similar to wild-type IL-23 (monomeric state, thermal stability, and secondary structural features).

Recombinant soluble human FcgammaR1A (CD64A) reduces inflammation in murine collagen-induced arthritis.

Binding of immune complexes to cellular FcgammaRs can promote cell activation and inflammation. In previous studies, a recombinant human (rh) soluble FcgammaR, rh-FcgammaRIA (CD64A), was shown to block inflammation in passive transfer models of immune complex-mediated disease. To assess whether rh-FcgammaRIA could block inflammation in a T cell- and B cell-dependent model of immune complex-mediated disease, the efficacy of rh-FcgammaRIA in collagen-induced arthritis was evaluated. Mice with established arthritis were treated with a single s.c. injection of rh-FcgammaRIA (0.2-2.0 mg/dose) given every other day for 11 days. Relative to mice injected with vehicle alone, mice treated with rh-FcgammaRIA exhibited lower serum concentrations of IL-6, anti-type II collagen Abs, and total IgG2a. These changes were correlated with lower levels of paw swelling and joint damage in the rh-FcgammaRIA-treated mice and occurred in the presence of a significant murine Ab response to rh-FcgammaRIA. Comparison of the serum rh-FcgammaRIA concentration vs time profiles for rh-FcgammaRIA administered at two dose levels by i.v. and s.c. injection revealed that the bioavailabilty of s.c. administered rh-FcgammaRIA was 27-37%. Taken together, these data show that rh-FcgammaRIA is an effective inhibitor of inflammation in a model of established arthritis in mice.

Generation of a high-affinity Fcgamma receptor by Ig-domain swapping between human CD64A and CD16A.

A recombinant soluble version of the human high-affinity receptor for IgG, rh-FcgammaRIA or CD64A, was expressed in mammalian cells and purified from their conditioned media. As assessed by circular dichroism, size exclusion chromatography and dynamic light scattering, incubation of rh-FcgammaRIA at 37 degrees C resulted in time-dependent formation of soluble aggregates caused by protein unfolding and loss of native structure. Aggregate formation was irreversible, temperature-dependent and was independent of rh-FcgammaRIA concentration. Aggregated rh-FcgammaRIA lost its ability to inhibit immune complex precipitation and failed to bind to IgG-Sepharose. Addition of human IgG1 to rh-FcgammaRIA prior to incubation at 37 degrees C blocked the formation of rh-FcgammaRIA aggregates. Production of soluble monomeric rh-FcgammaRIA was limited by aggregate formation during cell culture. Substitution of the membrane distal D1 Ig domain of FcgammaRIA with the D1 Ig domain of FcgammaRIIIA or CD16A resulted in a chimeric receptor, FcgammaR3A1A, with enhanced temperature stability. Relative to native rh-FcgammaRIA, FcgammaR3A1A exhibited less aggregation in Chinese hamster ovary cell-conditioned media or when purified receptor was incubated for up to 24 h at 37 degrees C. Both receptors bound to immobilized human IgG1 with high affinity and were equipotent at blockade of immune complex-mediated cytokine production from cultured mast cells. Equivalent dose-dependent reductions in edema and neutrophil infiltration in the cutaneous Arthus reaction in mice were noted for rh-FcgammaRIA and FcgammaR3A1A. These data demonstrate that the D1 Ig domains of FcgammaRIA and FcgammaRIIIA are functionally interchangeable and further suggest that the chimeric receptor FcgammaR3A1A is an effective inhibitor of type III hypersensitivity in mice.