📝 SummarXiv

Abstract

To ensure faithful information transmission, cells utilize nonequilibrium drives to reduce errors. Kinetic proofreading is a classic mechanism known to sharpen ligand discrimination by T lymphocytes. It remains an open question whether the adaptive immune system relies solely on kinetic proofreading to boost fidelity. Here, we suggest an alternative: an enhanced form of mechanical proofreading (MPR) in which adaptive force exertion via dynamic cell-cell contact allows faithful selection of high-affinity B lymphocytes. Using a minimal model validated with experiment, we show that adaptive MPR, characterized by mechanical feedback between force generation and contact formation, enables robust discrimination of receptor quality regardless of ligand quantity. Although MPR generically balances the tradeoffs between speed and fidelity, a negative scaling of contact duration with ligand abundance indicates the presence of feedback. Due to its ability to modulate interactions of distinct ligands that share load at membrane contacts, adaptive MPR can be harnessed to mitigate autoimmunity or enhance multivalent vaccines. Overall, this work suggests a generalization of the proofreading mechanism to encompass cellular designs that act across scales to enable competing functionalities.