Rapid Perturbation of Free‐Energy Landscapes: From In Vitro to In Vivo

Abstract

Biological systems are often studied under the most “physiological” conditions possible. However, purposeful perturbation of biological systems can provide much information about their dynamics, robustness, and function. Such perturbations are particularly easy to apply at the interface of molecular biophysics and cellular biology, at which complex and highly regulated networks emerge from the behavior of individual biomolecules. Due to the size of diffusion coefficients and the length scale of biomolecules, the fastest timescales at this interface extend to below a microsecond. Thus perturbations must be induced and detected rapidly. We focus on examples of proteins and RNAs interacting with themselves (folding) or one another (binding, signaling). Beginning with general principles that have been learned from simple models and perturbation experiments in vitro, we progress to more complex environments that mimic aspects of the living cell, and finally rapid perturbation experiments in living cells. On the experimental side we highlight in particular two classes of rapid perturbation methods (nanoseconds to seconds) that have been traditionally employed in biophysical chemistry, but that will become increasingly important in cell biology and in vivo: fast relaxation techniques and phase‐sensitive modulation techniques. These techniques are now increasingly married with imaging to produce a spatiotemporal map of biomolecular stability, dynamics and, in the near future, interaction networks inside cells. Many important chemical processes occur on biologically fast timescales, and yet have important ramifications for slower biological networks.

New frontiers: Molecular biophysics has investigated the dynamics of biomolecular reactions by rapid perturbation in vitro for more than a half century. Modern‐day imaging and labeling techniques allow for the application of these methods in vivo. This new frontier will provide insight into the active and passive methods used by the cell to regulate protein function, protein–RNA binding and many other biomolecular interactions, connecting the molecular level to the systems biology of the cell.