Impact of IgG2 high molecular weight species on neonatal Fc receptor binding assays.

A cell-based assay and a solution neonatal Fc receptor (FcRn) binding assay were implemented for the characterization of an IgG2 antibody after observation that different product lots exhibited unexpected differences in FcRn binding in the cell-based format with membrane-bound FcRn. The experiments described here suggest that the apparent differences observed in the FcRn binding across different product lots in the cell-based format can be attributed to the different levels of the higher order high molecular weight species (HMWs) in them. A strong correlation between FcRn binding in the cell-based format and the percentage (%) higher order HMWs suggests that small amounts (∼0.1%) of the latter could cause the enhanced apparent FcRn binding (% relative binding ranging from 50 to 100%) in the format. However, when the binding was assessed with recombinant FcRn in soluble form, avidity effects were minimal and the assay format exhibited less sensitivity toward the differences in higher order HMWs levels across product lots. In conclusion, a solution-based assay may be a more appropriate assay to assess FcRn binding of the dominant species of an Fc-fusion protein or monoclonal antibody if minor differences in product variants such as higher order HMWs are shown to affect the binding significantly.

Demonstration of Functional Similarity of Proposed Biosimilar ABP 501 to Adalimumab.

BACKGROUND: Due to the complex molecular structure and proprietary manufacturing processes of monoclonal antibodies (mAbs), differences in structure and function may be expected during development of biosimilar mAbs. Important regulatory requirements for approval of biosimilar products involve comprehensive assessments of any potential differences between proposed biosimilars and reference mAbs, including differences in all known mechanisms of action, using sensitive and relevant methods. Any identified structural differences should not result in differences in biofunctional or clinical activity. OBJECTIVE: A comprehensive assessment comparing the Amgen biosimilar candidate ABP 501 with FDA-licensed adalimumab (adalimumab [US]) and EU-authorized adalimumab (adalimumab [EU]) was conducted to demonstrate similarity in biofunctional activity. METHODS: The functional similarity assessment included testing of binding kinetics to soluble tumor necrosis factor α (TNFα) and relative binding to transmembrane TNFα. The neutralization of TNFα-induced caspase activation, TNFα- and lymphotoxin-α (LTα)-induced chemokine production, and cytotoxicity was also tested. Binding to Fc-gamma receptors FcγRIa, FcγRIIa (131H), FcγRIIIa (158V and 158F), and neonatal Fc receptor (FcRn) was compared with the reference mAbs, as was antibody-dependent cell-mediated cytotoxicity and complement-dependent cytotoxicity. RESULTS: The data demonstrate that ABP 501 is similar to both adalimumab (US) and adalimumab (EU) with respect to evaluated biofunctional activities. CONCLUSION: Similarity in biofunctional activity is a critical component of the totality of evidence required for demonstration of biosimilarity. The functional similarity demonstrated for ABP 501 comprehensively assesses the known mechanisms of action of adalimumab, supporting the conclusion that ABP 501, adalimumab (US), and adalimumab (EU) are likely to be clinically similar.