Litcius/Paper detail

The role of kinetic asymmetry and power strokes in an information ratchet

Lorna Binks, Stefan Borsley, Todd R. Gingrich, David A. Leigh, Emanuele Penocchio, Benjamin M. W. Roberts

2023Chem55 citationsDOIOpen Access PDF

Abstract

Biomolecular machines are driven by information ratchet mechanisms, where kinetic asymmetry in the machine's chemomechanical cycle of fuel-to-waste catalysis induces net directional dynamics. A large-scale energetically downhill conformational change, termed a "power stroke," has often been erroneously implicated as a mechanistic driving feature in such machines. We investigated the roles of kinetic asymmetry and power strokes in a series of rotaxane-based information ratchets and found that kinetic asymmetry alone determines ratchet directionality such that all ratchets use the same amount of fuel to reach the same normalized steady state. However, power strokes can nonetheless influence ratchet performance, such as how fast the steady state is reached. Moreover, nonequilibrium thermodynamic analysis revealed that power strokes alter the amount and form (information [Shannon entropy] versus intercomponent binding energy) of the free energy stored by ratchets. These findings have implications for both the understanding of biological ratchets and the design principles for artificial nonequilibrium (supra)molecular machines.

Topics & Concepts

RatchetKinetic energyAsymmetryMolecular machineNon-equilibrium thermodynamicsBiological systemPower (physics)PhysicsComputer scienceStatistical physicsChemistryNanotechnologyThermodynamicsMaterials scienceClassical mechanicsBiologyQuantum mechanicsWork (physics)Protein Structure and DynamicsAdvanced Thermodynamics and Statistical MechanicsPhotoreceptor and optogenetics research