Active modulation of surfactant-driven flow instabilities by swarming bacteria

Harshitha S. Kotian; Shalini Harkar; Shubham Joge; Ayushi Mishra; Amith Z. Abdulla; K. N. Hithysini; Varsha Singh; Manoj M. Varma

doi:10.1103/PhysRevE.101.012407

Active modulation of surfactant-driven flow instabilities by swarming bacteria

Harshitha S. Kotian, Shalini Harkar, Shubham Joge, Ayushi Mishra, Amith Z. Abdulla, K. N. Hithysini, Varsha Singh, Manoj M. Varma (Lead / Corresponding author)

Molecular Microbiology

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

Models based on surfactant-driven instabilities have been employed to describe pattern formation by swarming bacteria. However, by definition, such models cannot account for the effect of bacterial sensing and decision making. Here we present a more complete model for bacterial pattern formation which accounts for these effects by coupling active bacterial motility to the passive fluid dynamics. We experimentally identify behaviors which cannot be captured by previous models based on passive population dispersal and show that a more accurate description is provided by our model. It is seen that the coupling of bacterial motility to the fluid dynamics significantly alters the phase space of surfactant-driven pattern formation. We also show that our formalism is applicable across bacterial species.

Original language	English
Article number	012407
Journal	Physical Review E
Volume	101
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevE.101.012407
Publication status	Published - 15 Jan 2020

ASJC Scopus subject areas

Statistical and Nonlinear Physics
Statistics and Probability
Condensed Matter Physics

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10.1103/PhysRevE.101.012407

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abstract = "Models based on surfactant-driven instabilities have been employed to describe pattern formation by swarming bacteria. However, by definition, such models cannot account for the effect of bacterial sensing and decision making. Here we present a more complete model for bacterial pattern formation which accounts for these effects by coupling active bacterial motility to the passive fluid dynamics. We experimentally identify behaviors which cannot be captured by previous models based on passive population dispersal and show that a more accurate description is provided by our model. It is seen that the coupling of bacterial motility to the fluid dynamics significantly alters the phase space of surfactant-driven pattern formation. We also show that our formalism is applicable across bacterial species.",

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AU - Harkar, Shalini

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AU - Abdulla, Amith Z.

AU - Hithysini, K. N.

AU - Singh, Varsha

AU - Varma, Manoj M.

PY - 2020/1/15

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AB - Models based on surfactant-driven instabilities have been employed to describe pattern formation by swarming bacteria. However, by definition, such models cannot account for the effect of bacterial sensing and decision making. Here we present a more complete model for bacterial pattern formation which accounts for these effects by coupling active bacterial motility to the passive fluid dynamics. We experimentally identify behaviors which cannot be captured by previous models based on passive population dispersal and show that a more accurate description is provided by our model. It is seen that the coupling of bacterial motility to the fluid dynamics significantly alters the phase space of surfactant-driven pattern formation. We also show that our formalism is applicable across bacterial species.

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Active modulation of surfactant-driven flow instabilities by swarming bacteria

Abstract

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