TY - JOUR T1 - Distinct chemotactic behavior in the original <em>Escherichia coli</em> K-12 depending on forward-and-backward swimming, not on run-tumble movements JF - bioRxiv DO - 10.1101/2020.02.13.947150 SP - 2020.02.13.947150 AU - Yoshiaki Kinosita AU - Tsubasa Ishida AU - Myu Yoshida AU - Rie Ito AU - Yusuke V. Morimoto AU - Kazuki Goto AU - Richard M. Berry AU - Takayuki Nishizaka AU - Yoshiyuki Sowa Y1 - 2020/01/01 UR - http://biorxiv.org/content/early/2020/02/14/2020.02.13.947150.abstract N2 - Most motile bacteria are propelled by rigid, helical, flagellar filaments and display distinct swimming patterns to explore their favorable environments. Escherichia coli cells have a reversible rotary motor at the base of each filament. They exhibit a run-tumble swimming pattern, driven by switching of rotatory direction which causes polymorphic flagellar transformation. Here we report a novel swimming mode in E. coli ATCC10798, which is one of the original K-12 clones. High-speed tracking of single ATCC10798 cells showed forward and backward swimming with an average turning angle of 150°. The flagellar helicity remained right-handed with a 1.3 μm pitch and 0.14 μm helix radius, which is assumed to be a curly type, regardless of motor switching; the flagella of ATCC10798 did not show polymorphic transformation. The torque and rotational switching of the motor was almost identical to the E. coli W3110 strain, which is a derivative of K-12 and a wild-type for chemotaxis. The single point mutation of N87K in FliC, one of the filament subunits, is critical to the change in flagellar morphology and swimming pattern, and lack of flagellar polymorphism. E. coli cells expressing FliC(N87K) sensed ascending a chemotactic gradient in liquid but did not form rings on a semi-solid surface. Based on these findings, we propose a flagellar polymorphism-dependent migration mechanism in structured environments. ER -