Stochastic simulation of activation in the G-protein cascade of phototransduction.

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Stochastic simulation of activation in the G-protein cascade of phototransduction.

T D Lamb

Physiological Laboratory, University of Cambridge, United Kingdom.

ABSTRACT

Activation of the G-protein cascade underlying phototransductionhas been modeled by simulating the two-dimensional diffusionalinteractions that occur at the rod disc membrane between thethree reacting protein species, which are the activated rhodopsin(R*), the G-protein (G), and the effector protein (E, the phosphodiesterase,PDE). The stochastic simulations confirm the main predictionsof a simplified analytical model (Lamb, T. D., and E. N. Pugh,1992, Journal of Physiology 449:719-758), and extend that treatmentto more complicated cases, where there is a finite probabilityof reaction or a finite time for reaction. The simulations alsoprovide quantitative estimates of the efficiency of couplingfrom activated G-protein (G*) to activated effector (E*) interms of the concentrations, lateral diffusion coefficients,and binding rate constants of the participating molecules; theefficiency of coupling from G* to E* is found to be not as highas in the previous simplified analytical theory. The findingscan be extended to other G-protein cascades, provided that thephysical parameters of those cascades are specified.

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