Computational methods to engineer antibodies for vaccines and therapeutics

Abstract

Antibodies (Abs) are proteins of the adaptive immune response that bind to and neutralize body-foreign particles (antigens). Specific binding to a wide variety of antigens is achieved by the tremendous variability inherent to the variable region. Engineered Abs that specifically bind to clinically relevant targets are administered as vaccines and therapeutics. Antibody vaccines and therapeutics need to meet special requirements important for their development, and must be subsequently approved by the Food and Drug Administration (FDA). These criteria include their expressability under experimental conditions and low risk for eliciting adverse effects. Technologies developed for this dissertation make use of the observed antibody space (OAS), which contains antibody sequences obtained from healthy, human blood donors. Recent advances in Next Generation Sequencing (NGS) dramatically increased the OAS up to hundreds of million sequences per healthy human blood donor. Novel computational approaches were developed to process large NGS datasets and to assess their human-likeness using the OAS. High human-likeness is generally associated with a low risk of an immunogenic response. It could be demonstrated that our technology is able to differentiate between human, non-human, and mixed human-like Ab sequences. In addition, our approach enables us to generate human-like nucleotide sequences with a sequence recovery of up to 97.2%. To support the development of Abs under experimental conditions, a Deep Learning approach was developed to classify between Abs likely, and unlikely, to express in Chinese Hamster Ovary cells, with an average AUC score of up to 0.71± 0.04. In combination with the Rosetta protein modeling suite, the Ab expressability and human-likeness could be increased via structural re- design of the Ab proteins. Our human-likeness modeling approach also increased the human- likeness of the CDRH3 region in 8 out of 28 cases, which is inherently difficult to model due to its high diversity. We further introduce a novel Rosetta design approach that is capable of conserving functionally relevant residues in proteins without their explicit knowledge and hypothesize, that this approach has the potential to functionally characterize antibodies for future computational antibody discovery.