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Oscillatory surface rheotaxis of swimming E. coli bacteria. | LitMetric

Oscillatory surface rheotaxis of swimming E. coli bacteria.

Nat Commun

Rudolf Peierls Centre for Theoretical Physics, University of Oxford, Oxford, 1 Keble Road, OX1 3NP, UK.

Published: July 2019

AI Article Synopsis

  • Bacterial contamination in channels, catheters, and water supplies poses a serious public health risk, and bacteria can swim against flow, a behavior called 'rheotaxis.'
  • This study investigates E. coli swimming under flow using advanced tracking and labeling techniques, revealing that bacteria adjust their swimming direction in response to different shear rates.
  • The research outlines three critical shear rate thresholds that correspond to distinct rheotactic behaviors, providing insights that could help improve strategies for contamination control and enhance navigation of microscopic swimmers in complex fluid environments.

Article Abstract

Bacterial contamination of biological channels, catheters or water resources is a major threat to public health, which can be amplified by the ability of bacteria to swim upstream. The mechanisms of this 'rheotaxis', the reorientation with respect to flow gradients, are still poorly understood. Here, we follow individual E. coli bacteria swimming at surfaces under shear flow using 3D Lagrangian tracking and fluorescent flagellar labelling. Three transitions are identified with increasing shear rate: Above a first critical shear rate, bacteria shift to swimming upstream. After a second threshold, we report the discovery of an oscillatory rheotaxis. Beyond a third transition, we further observe coexistence of rheotaxis along the positive and negative vorticity directions. A theoretical analysis explains these rheotaxis regimes and predicts the corresponding critical shear rates. Our results shed light on bacterial transport and reveal strategies for contamination prevention, rheotactic cell sorting, and microswimmer navigation in complex flow environments.

Download full-text PDF

Source
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6668461PMC
http://dx.doi.org/10.1038/s41467-019-11360-0DOI Listing

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