Multidomain Protein-Urea Interactions: Differences in Binding Behavior Lead to Different Destabilization Tendencies for Monoclonal Antibodies.

We study the influence of urea on the stability of monoclonal antibodies (mAbs) using molecular dynamics (MD) simulations in combination with differential scanning fluorimetry (DSF). We show that a denaturing cosolute such as urea binds strongly to the protein, which can lead to denaturation and enhanced aggregation behavior at high temperatures. The interaction between protein and urea crucially depends on the surface properties of the individual mAb domains and therefore affects the general binding to the protein differently. The study of these mechanisms for proteins with multiple domains, such as mAbs, encounters significant limitations in experimental analysis methods due to their complexity. Using computational and experimental methods, we are able to separate the protein-urea interaction by domain and show that Lennard-Jones interactions are mainly responsible for significant binding effects. Our results emphasize the potential of MD simulations in combination with Kirkwood-Buff theory to study the interactions between proteins with multiple domains and cosolutes as formulation excipients for drug discovery and development.