Antibody design is a challenging task that could be improved by understanding the conformational changes accompanying affinity maturation. Antibody maturation is a critical immune system process by which antibodies gain mutations that improve affinity and specificity for antigen targets. However, how these mutations change antibody dynamics, specifically whether antibodies become more rigid as they mature, remains a contested topic. Using adaptive sampling molecular dynamics simulations and over 8.5 milliseconds of Folding@home simulations of seven lineages, we discover that affinity maturation selectively tunes the dynamics of antibody paratope regions depending on whether they contact protein residues or glycans. We find that antibody regions that contact glycans evolve to become more flexible and, consistent with other studies, antibody regions that contact protein residues on the antigen become rigid. This pattern holds regardless of whether one includes the constant region in the simulations, indicating that the computational cost of all-atom antibody MD simulations can be reduced by half without sacrificing the accuracy of the variable region dynamics. We expect the principles identified in this study will enable precise, dynamics-based engineering of high-affinity antibodies and to inform immunogen design against challenging, glycan-shielded viral targets such as HIV.
Human and Robot Assistance for Cognitive Load in Younger and Older Adults: Multimodal Within-Subject Experimental Study
Background: Maintaining cognitive efficiency and independence is a central goal of healthy aging. Socially assistive robots (SARs) are increasingly proposed as scalable digital health solutions