A structure-based engineering approach to abrogate pre-existing antibody binding to biotherapeutics.

Petra Verdino,Anna M. Russell,Joanne Lin,Andrea Ferrante,Shawn S. Chang,Micheal A. Batt,Rong Fong Huang,Kevin A. Henry,Stacey L. Lee

doi:10.1371/journal.pone.0254944

Petra Verdino, Anna M. Russell + Show 7 more

Open Access

https://doi.org/10.1371/journal.pone.0254944

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Journal: PloS one	Publication Date: Jul 23, 2021
Citations: 7	License type: CC BY 4.0

Affiliation: Eli Lilly (United States)

Abstract

Development of biotherapeutics is hampered by the inherent risk of immunogenicity, which requires extensive clinical assessment and possible re-engineering efforts for mitigation. The focus in the pre-clinical phase is to determine the likelihood of developing treatment-emergent anti-drug antibodies (TE-ADA) and presence of pre-existing ADA in drug-naïve individuals as risk-profiling strategies. Pre-existing ADAs are routinely identified during clinical immunogenicity assessment, but their origin and impact on drug safety and efficacy have not been fully elucidated. One specific class of pre-existing ADAs has been described, which targets neoepitopes of antibody fragments, including Fabs, VH, or VHH domains in isolation from their IgG context. With the increasing number of antibody fragments and other small binding scaffolds entering the clinic, a widely applicable method to mitigate pre-existing reactivity against these molecules is desirable. Here is described a structure-based engineering approach to abrogate pre-existing ADA reactivity to the C-terminal neoepitope of VH(H)s. On the basis of 3D structures, small modifications applicable to any VH(H) are devised that would not impact developability or antigen binding. In-silico B cell epitope mapping algorithms were used to rank the modified VHH variants by antigenicity; however, the limited discriminating capacity of the computational methods prompted an experimental evaluation of the engineered molecules. The results identified numerous modifications capable of reducing pre-existing ADA binding. The most efficient consisted of the addition of two proline residues at the VHH C-terminus, which led to no detectable pre-existing ADA reactivity while maintaining favorable developability characteristics. The method described, and the modifications identified thereby, may provide a broadly applicable solution to mitigate immunogenicity risk of antibody-fragments in the clinic and increase safety and efficacy of this promising new class of biotherapeutics.

Highlights

Biotherapeutics are the most rapidly evolving drug class with monoclonal antibodies constituting the majority of biomolecules in development [1]
This research demonstrates that the elimination of potential immunogenicity-related liabilities can be achieved through the iteration of structural analysis and in-vitro experimental validation, augmenting the poor discriminating capacity of in-silico B cell epitope prediction
To abrogate pre-existing ADA binding to the C-terminal neoepitope of isolated VH and VHH domains, a structure-based approach was utilized

Summary

Introduction

Biotherapeutics are the most rapidly evolving drug class with monoclonal antibodies constituting the majority of biomolecules in development [1]. Small Ab fragments have gained considerable attention due to distinct properties from full-length antibodies; i.e., these constructs maintain specific high-affinity binding, facile developability, and cost-effective manufacturing, altered tissue distribution, pharmacokinetics, and assembly into modular multi-specifics are possible. One key aspect of any protein biotherapeutic, in particular engineered non-naturally occurring molecules, is the inherent risk of immunogenicity Any changes such as chemical modifications of side chains, fragmentation or aggregation can elicit unwanted adverse reactions and impact the clinical safety and efficacy profiles [5, 6]. Inflammation- and tumor-related as well as microbial proteases are capable of cleaving human IgG in the hinge region [14, 15] This might be a strategy of tumors and microbes to avoid immune-surveillance under the coating of dysfunctional F(ab’) (or similar) fragments. This research demonstrates that the elimination of potential immunogenicity-related liabilities can be achieved through the iteration of structural analysis and in-vitro experimental validation, augmenting the poor discriminating capacity of in-silico B cell epitope prediction

Materials and methods

Design Rational

Results and discussion

Conclusion