Daisuke Nakane, Shoko Odaka, Kana Suzuki, Takayuki Nishizaka
Journal of bacteriology, Apr 29, 2021
A collective motion of self-driven particles has been a fascinating subject in physics and biology. Sophisticated macroscopic behavior emerges through a population in thousands or millions of bacterial cells, propelling itself by flagellar rotation and its chemotactic response. Here we found a series of collective motions accompanying successive phase-transitions in a non-flagellated rod-shaped soil bacterium, Flavobacterium johnsoniae, which was driven by a surface cell movement known as gliding motility. When we spot the cells on an agar plate with a low level of nutrients, the bacterial community exhibited vortex patterns that spontaneously appeared as lattice and integrated into a large-scale circular plate. All patterns exhibit with monolayer of bacteria, which enable to visualize an individual cell with a high resolution among a wide-range pattern two-dimensionally. The single cells moved at random orientation, but the cells connected with one another showed left-turn biased trajectories in starved environment. This feature is possibly due to the collision of cells inducing a nematic alignment of dense cells as self-propelled rods. Subsequently, each vortex oscillated independently, and then transformed to the rotating mode as an independent circular plate. Notably, the rotational direction of the circular plate was counterclockwise without exception. The plates developed accompanying rotation with constant angular velocity, suggesting that the mode is an efficient strategy for bacterial survival.ImportanceSelf-propelled bacteria propelled by flagella rotation often display highly organized dynamic patterns at high cell densities. Here we found a new mode of collective motion in non-flagellated bacteria: vortex patterns were spontaneously appeared as lattice and integrated into a large-scale circular plate comprising hundreds of thousands of cells, which exhibited unidirectional rotation in a counterclockwise manner and expanded in size on agar. A series of collective motions was driven by gliding motility of the rod-shaped soil bacterium Flavobacterium johnsoniae In a low nutrient environment, single cells moved at random orientation while cells at high density moved together as a unitary cluster. This might be an efficient strategy for cells of this species to find nutrients.