In-Solution Characterization of Biomolecular Interaction Kinetics under Native Conditions.

Characterizing the kinetics of biomolecular interactions is fundamental for understanding biological mechanisms, developing novel drugs for advancing healthcare and for optimizing processes in protein engineering. Although modern surface-based methods have advanced our understanding of protein-protein and protein-ligand kinetics, they rely on immobilized samples, preventing the study of interactions under native conditions and leading to an incomplete understanding. In this work, we propose a paradigm shift by introducing a new method based on flow-induced dispersion analysis to study interaction kinetics while keeping biomolecules in solution, eliminating the need for surface immobilization and thereby preserving molecular mobility and avoiding structural constraints. The method examines reactions outside equilibrium conditions by inducing a rapid concentration change in one of the binding partners (C-Jump) in a controlled microfluidic environment. Notably, it operates without buffer restrictions and requires only minimal sample quantities. We demonstrate C-Jump's capability by accurately determining the association and dissociation rates of both protein-protein and protein-small molecule interactions. Furthermore, we validate its robustness by measuring the rates of a protein-protein interaction in human serum as well as a protein-small molecule interaction in-solution and label free. This underlines C-Jump's broad applicability for studying biomolecular interactions under native conditions, offering a powerful tool for advancing protein engineering and drug discovery, as well as enabling the characterization of previously inaccessible interactions.