The pump process of the ratchet model inspired by the $F_o$ rotatory motor of ATP synthase is investigated. In this model there are two kinds of characteristic time. One is dynamical, the relaxation time of the system. Others are chemical, the chemical reaction rates at which a proton binds to or dissociates from the motor protein. The inequalities between them affect the behavior of the physical quantities, such as the rotation velocity and the proton pumping rates across the membrane. The energy transduction efficiency is calculated and the condition under which the efficiency can become higher is discussed. The proton pumping rate and the efficiency have a peak where a certain set of inequalities between the chemical reaction rates and t...
AbstractThe enzyme F1-ATPase is a rotary nanomotor in which the central γ subunit rotates inside the...
Many biomolecular machines need to be both fast and efficient. How has evolution optimized these mac...
F1-ATPase hydrolyzes ATP into ADP and Pi and converts chemical energy into mechanical rotation with ...
A major goal in the design of synthetic molecular machines is the creation of pumps that can use the...
We examine the dependence of the physical quantities of the rotatory molecular motor, such as the ro...
F1F0 ATP synthase (ATPase) either facilitates the synthesis of ATP in a process driven by the proton...
F1F0 ATP synthase (ATPase) either facilitates the synthesis of ATP in a process driven by the proton...
F1-ATPase is a unique enzyme. The hydrolysis (or synthesis) of ATP into ADP and Pi produces an energ...
AbstractF1-ATPase is a rotatory molecular motor fueled by ATP nucleotides. Different loads can be at...
Abstract Recent theoretical work on the energy conversion by molecular motors coupled to nucleotide ...
AbstractATP synthase is conceived as a rotatory engine with two reversible drives, the proton-transp...
Molecular machines are stochastic systems capable of converting between different forms of energy su...
We present a model for a feedback-controlled ratchet consisting of a Brownian particle and a moving,...
Most of the known molecular motors are fueled by ATP hydrolysis. In vivo these machines work near th...
Enzyme F1-ATPase catalyzes the hydrolysis of ATP and converts chemical energy into mechanical rotati...
AbstractThe enzyme F1-ATPase is a rotary nanomotor in which the central γ subunit rotates inside the...
Many biomolecular machines need to be both fast and efficient. How has evolution optimized these mac...
F1-ATPase hydrolyzes ATP into ADP and Pi and converts chemical energy into mechanical rotation with ...
A major goal in the design of synthetic molecular machines is the creation of pumps that can use the...
We examine the dependence of the physical quantities of the rotatory molecular motor, such as the ro...
F1F0 ATP synthase (ATPase) either facilitates the synthesis of ATP in a process driven by the proton...
F1F0 ATP synthase (ATPase) either facilitates the synthesis of ATP in a process driven by the proton...
F1-ATPase is a unique enzyme. The hydrolysis (or synthesis) of ATP into ADP and Pi produces an energ...
AbstractF1-ATPase is a rotatory molecular motor fueled by ATP nucleotides. Different loads can be at...
Abstract Recent theoretical work on the energy conversion by molecular motors coupled to nucleotide ...
AbstractATP synthase is conceived as a rotatory engine with two reversible drives, the proton-transp...
Molecular machines are stochastic systems capable of converting between different forms of energy su...
We present a model for a feedback-controlled ratchet consisting of a Brownian particle and a moving,...
Most of the known molecular motors are fueled by ATP hydrolysis. In vivo these machines work near th...
Enzyme F1-ATPase catalyzes the hydrolysis of ATP and converts chemical energy into mechanical rotati...
AbstractThe enzyme F1-ATPase is a rotary nanomotor in which the central γ subunit rotates inside the...
Many biomolecular machines need to be both fast and efficient. How has evolution optimized these mac...
F1-ATPase hydrolyzes ATP into ADP and Pi and converts chemical energy into mechanical rotation with ...