Proteins can dynamically switch between metastable structures and associate into signaling machineries that give rise to cellular function. Molecular dynamics (MD) simulations can simultaneously probe structure and dynamics of such processes at atomistic resolution. Recently, breakthroughs have been achieved in the long-standing problem to sample rare transition events in unbiased MD. In the past, we have pioneered the development and application of Markov state models (MSMs), which, combined with MD simulations on graphical processing units, make millisecond-timescale kinetics broadly accessible. With multi-ensemble techniques, timescales of seconds and beyond can be reached. Recently, we have demonstrated protein-protein association and dissociation with atomistic MD. Long-timescale simulation of small to medium-sized protein systems is thus now possible in atomistic MD.
However, these methods have fundamental scaling limitations that prevents long-timescale simulation to be employed in the modeling of large protein systems and whole cells. To address these limitations, this ERC project has set out to develop multiscale models for coarse-grained representations of proteins and upscaling methods from the molecular scale to reaction-diffusion simulations of cellular signal transduction.