Swimming Escherichia coli Cells Explore the Environment by Levy Walk

Escherichia coli cells swim in aqueous environment in a random walk of alternating runs and tumbles. The diffusion characteristics of this random walk remains unclear. In this study, by tracking the swimming of wild-type cells in a three-dimensional (3D) homogeneous environment, we found that their trajectories are superdiffusive, consistent with Levy walk behavior. For comparison, we tracked the swimming of mutant cells that lack the chemotaxis signaling noise (the steady-state fluctuation of the concentration of the chemotaxis response regulator CheY-P) and found that their trajectories are normal diffusive. Therefore, wild-type E. coli cells explore the environment by Levy walk, which originates from the chemotaxis signaling noise. This Levy walk pattern enhances their efficiency in environmental exploration. IMPORTANCE E. coli cells explore the environment in a random walk of alternating runs and tumbles. By tracking the 3D trajectories of E. colt cells in an aqueous environment, we found that their trajectories are superdiffusive, with a power-law shape for the distribution of run lengths, which is characteristics of Levy walk. We further show that this Levy walk behavior is due to the random fluctuation of the output level of the bacterial chemotaxis pathway, and it enhances the efficiency of the bacteria in exploring the environment.

Automated summary

E. coli cells exhibit superdiffusive behavior in their swimming trajectories in a 3D aqueous environment, displaying Levy walk characteristics. Wild-type cells explore the environment efficiently through Levy walk originating from chemotaxis signaling noise, while mutant cells without this noise show normal diffusive trajectories.