Dynamics of chemo-receptor activity with time-periodic attractant field

Abstract

When exposed to a time-periodic chemical signal, an E.~coli cell responds by modulating its receptor activity in a similar time-periodic manner. However, there exists a phase lag between the applied signal and the activity response. We study the variation of the activity amplitude and phase lag as a function of the applied frequency~ω, using numerical simulations. The amplitude increases with~ω, reaches a plateau, and then decreases again for large~ω. The phase lag increases monotonically with~ω and finally saturates to 3π/2 when~ω is large. The activity is no longer a single-valued function of the attractant signal, and plotting activity versus attractant concentration over one complete time period generates a loop. We monitor the loop area as a function of~ω and find two peaks for small and large~ω, and a sharp minimum at intermediate~ω values. We explain these results as an interplay between the time scales associated with adaptation, activity switching, and applied signal variation. In particular, for very large~ω, the quasi-equilibrium approximation for activity dynamics breaks down, a regime that has not been explored in earlier studies. We perform analytical calculations in this limit and find good agreement with our simulation results.

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