Implications of 3-step swimming patterns in bacterial chemotaxis

TL;DR

This paper investigates the unique 3-step swimming pattern of Vibrio alginolyticus, analyzing its regulation and chemotactic efficiency, revealing a natural biphasic response that may aid adaptation in ocean environments.

Contribution

It introduces a theoretical analysis of the 3-step swimming pattern's impact on chemotaxis, highlighting its distinct regulation and potential advantages over traditional patterns.

Findings

Biphasic chemotactic response emerges from the 3-step pattern.

The 3-step pattern affects migration speed in chemical gradients.

Discussion of adaptation advantages in ocean environments.

Abstract

We recently found that marine bacteria Vibrio alginolyticus execute a cyclic 3-step (run- reverse-flick) motility pattern that is distinctively different from the 2-step (run-tumble) pattern of Escherichia coli. How this novel swimming pattern is regulated by cells of V. alginolyticus is not currently known, but its significance for bacterial chemotaxis is self- evident and will be delineated herein. Using an approach introduced by de Gennes, we calculated the migration speed of a cell executing the 3-step pattern in a linear chemical gradient, and found that a biphasic chemotactic response arises naturally. The implication of such a response for the cells to adapt to ocean environments and its possible connection to E. coli 's response are also discussed.