Abstract
Structure-based antibody design and accurate predictions of antibody-antigen interactions remain major challenges in computational biology. By using molecular dynamics simulations, we show that a single static X-ray structure is not sufficient to identify determinants of antibody-antigen recognition. Here, we investigate antibodies that undergo substantial conformational changes upon antigen binding and have been classified as difficult cases in an extensive benchmark for antibody-antigen docking. We present thermodynamics and transition kinetics of these conformational rearrangements and show that paratope states can be used to improve antibody-antigen docking. By using the unbound antibody X-ray structure as starting structure for molecular dynamics simulations, we retain a binding competent conformation substantially different to the unbound antibody X-ray structure. We also observe that the kinetically dominant antibody paratope conformations are chosen by the bound antigen conformation with the highest probability. Thus, we show that paratope states in solution can improve antibody-antigen docking and structure prediction.
Highlights
Antibodies are crucial components of the immune response (Medzhitov and Janeway, 1998)
By using molecular dynamics simulations, we show that a single static X-ray structure is not sufficient to identify determinants of antibody-antigen recognition
We present thermodynamics and transition kinetics of these conformational rearrangements and show that paratope states can be used to improve antibody-antigen docking
Summary
Antibodies are crucial components of the immune response (Medzhitov and Janeway, 1998). Their ability to recognize and bind different antigens with high specificity together with their modular anatomy, which facilitates their engineering and design, makes them excellent therapeutic proteins (Chiu et al, 2019). Thereby, the structural characterization of antibody-antigen interactions has provided valuable insights into their binding mechanisms (Colman, 1988). The increase of experimentally available antibody structures resulted in numerous high-quality structure-function relationship studies, which helped to elucidate antibody characteristics and different antigen-binding mechanisms. Even though the number of experimental structures increased substantially, the vast size of immune repertoires and the countless number of antigens make it impossible to structurally and functionally characterize all antibody-antigen complexes and interactions
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