Biomolecular machines consume free energy to break symmetry and make directed progress. Nonequilibrium ATP concentrations are the typical free energy source, with one cycle of a molecular machine consuming a certain number of ATP, providing a fixed free energy budget. Since evolution is expected to favor rapid-turnover machines that operate efficiently, we investigate how this free energy budget can be allocated to maximize flux. Unconstrained optimization eliminates intermediate metastable states, indicating that flux is enhanced in molecular machines with fewer states. When maintaining a set number of states, we show that—in contrast to previous findings—the flux-maximizing allocation of dissipation is not even. This result is consistent ...
Living things avoid equilibrium using molecular machines. Such microscopic soft-matter objects encou...
AbstractMotor proteins are essential in life processes because they convert the free energy of ATP h...
F1-ATPase is a highly efficient molecular motor that can synthesize ATP driven by a mechanical torqu...
Biomolecular machines transduce between different forms of energy. These machines make directed prog...
F$_{1}$-ATPase is a rotary molecular motor that \emph{in vivo} is subject to strong nonequilibrium d...
Living systems efficiently use chemical fuel to do work, process information, and assemble patterns ...
At molecular scales, fluctuations play a significant role and prevent biomolecular processes from al...
How does a biomolecular machine achieve high speed at high efficiency? We explore optimization princ...
AbstractF1-ATPase (or F1), the highly efficient and reversible biochemical engine, has motivated phy...
Many biomolecular machines need to be both fast and efficient. How has evolution optimized these mac...
We present a chemomechanical network model of the rotary molecular motor F1-ATPase which quantitativ...
Biological processes are inherently stochastic, and to achieve directionality, consume free energy. ...
Cells must operate far from equilibrium, utilizing and dissipating energy continuously to maintain t...
We show that the molecular motor ATP synthase has evolved in accordance with the statistical selecti...
Transitions between enzyme functional states are often connected to conformational changes involving...
Living things avoid equilibrium using molecular machines. Such microscopic soft-matter objects encou...
AbstractMotor proteins are essential in life processes because they convert the free energy of ATP h...
F1-ATPase is a highly efficient molecular motor that can synthesize ATP driven by a mechanical torqu...
Biomolecular machines transduce between different forms of energy. These machines make directed prog...
F$_{1}$-ATPase is a rotary molecular motor that \emph{in vivo} is subject to strong nonequilibrium d...
Living systems efficiently use chemical fuel to do work, process information, and assemble patterns ...
At molecular scales, fluctuations play a significant role and prevent biomolecular processes from al...
How does a biomolecular machine achieve high speed at high efficiency? We explore optimization princ...
AbstractF1-ATPase (or F1), the highly efficient and reversible biochemical engine, has motivated phy...
Many biomolecular machines need to be both fast and efficient. How has evolution optimized these mac...
We present a chemomechanical network model of the rotary molecular motor F1-ATPase which quantitativ...
Biological processes are inherently stochastic, and to achieve directionality, consume free energy. ...
Cells must operate far from equilibrium, utilizing and dissipating energy continuously to maintain t...
We show that the molecular motor ATP synthase has evolved in accordance with the statistical selecti...
Transitions between enzyme functional states are often connected to conformational changes involving...
Living things avoid equilibrium using molecular machines. Such microscopic soft-matter objects encou...
AbstractMotor proteins are essential in life processes because they convert the free energy of ATP h...
F1-ATPase is a highly efficient molecular motor that can synthesize ATP driven by a mechanical torqu...