Abstract
Protein-protein interactions are critical determinants in biological systems. Engineered proteins binding to specific areas on protein surfaces could lead to therapeutics or diagnostics for treating diseases in humans. But designing epitope-specific protein-protein interactions with computational atomistic interaction free energy remains a difficult challenge. Here we show that, with the antibody-VEGF (vascular endothelial growth factor) interaction as a model system, the experimentally observed amino acid preferences in the antibody-antigen interface can be rationalized with 3-dimensional distributions of interacting atoms derived from the database of protein structures. Machine learning models established on the rationalization can be generalized to design amino acid preferences in antibody-antigen interfaces, for which the experimental validations are tractable with current high throughput synthetic antibody display technologies. Leave-one-out cross validation on the benchmark system yielded the accuracy, precision, recall (sensitivity) and specificity of the overall binary predictions to be 0.69, 0.45, 0.63, and 0.71 respectively, and the overall Matthews correlation coefficient of the 20 amino acid types in the 24 interface CDR positions was 0.312. The structure-based computational antibody design methodology was further tested with other antibodies binding to VEGF. The results indicate that the methodology could provide alternatives to the current antibody technologies based on animal immune systems in engineering therapeutic and diagnostic antibodies against predetermined antigen epitopes.
Highlights
Antibody has become the most prominent class of protein therapeutics and diagnostics [1,2]
Experimental antibody-VEGF interface sequences The experimental amino acid preferences of antibody CDRs binding to VEGF were elucidated with VEGF-binding scFv/scdsFv variants derived from the G6 Fab-VEGF complex [26] as a model system
Nine synthetic scFv or sc-dsFv libraries were constructed with a recombinant phage display system to systematically randomize 5 consecutive residues on each of the 6 CDRs on the variable domains [27]; more than 500 variants for which the scFv/sc-dsFv expressed on bacterial phage surfaces are able to bind to VEGF with high affinity were systematically discovered with high throughput phage display selection and screening [27,28]
Summary
Antibody has become the most prominent class of protein therapeutics and diagnostics [1,2].
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