Biophysical characterization of flagellar motor functions

Katie M. Ford; Ravi Chawla; Pushkar P. Lele

doi:10.3791/55240

Biophysical characterization of flagellar motor functions

Katie M. Ford, Ravi Chawla, Pushkar P. Lele

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

6 Scopus citations

Abstract

The role of flagellar motors in bacterial motility and chemotaxis is well-understood. Recent discoveries suggest that flagellar motors are able to remodel in response to a variety of environmental stimuli and are among the triggers for surface colonization and infections. The precise mechanisms by which motors remodel and promote cellular adaptation likely depend on key motor attributes. The photomultiplier-based bead-tracking technique presented here enables accurate biophysical characterization of motor functions, including adaptations in motor speeds and switch-dynamics. This approach offers the advantage of real-time tracking and the ability to probe motor behavior over extended durations. The protocols discussed can be readily extended to study flagellar motors in a variety of bacterial species.

Original language	English (US)
Article number	e55240
Journal	Journal of Visualized Experiments
Volume	2017
Issue number	119
DOIs	https://doi.org/10.3791/55240
State	Published - Jan 18 2017

Keywords

Bacterial motility
Biophysics
Chemotaxis
Issue 119
Mechanosensing
Particle tracking
Switching
Torque

ASJC Scopus subject areas

General Neuroscience
General Chemical Engineering
General Biochemistry, Genetics and Molecular Biology
General Immunology and Microbiology

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10.3791/55240

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title = "Biophysical characterization of flagellar motor functions",

abstract = "The role of flagellar motors in bacterial motility and chemotaxis is well-understood. Recent discoveries suggest that flagellar motors are able to remodel in response to a variety of environmental stimuli and are among the triggers for surface colonization and infections. The precise mechanisms by which motors remodel and promote cellular adaptation likely depend on key motor attributes. The photomultiplier-based bead-tracking technique presented here enables accurate biophysical characterization of motor functions, including adaptations in motor speeds and switch-dynamics. This approach offers the advantage of real-time tracking and the ability to probe motor behavior over extended durations. The protocols discussed can be readily extended to study flagellar motors in a variety of bacterial species.",

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AU - Chawla, Ravi

AU - Lele, Pushkar P.

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N2 - The role of flagellar motors in bacterial motility and chemotaxis is well-understood. Recent discoveries suggest that flagellar motors are able to remodel in response to a variety of environmental stimuli and are among the triggers for surface colonization and infections. The precise mechanisms by which motors remodel and promote cellular adaptation likely depend on key motor attributes. The photomultiplier-based bead-tracking technique presented here enables accurate biophysical characterization of motor functions, including adaptations in motor speeds and switch-dynamics. This approach offers the advantage of real-time tracking and the ability to probe motor behavior over extended durations. The protocols discussed can be readily extended to study flagellar motors in a variety of bacterial species.

AB - The role of flagellar motors in bacterial motility and chemotaxis is well-understood. Recent discoveries suggest that flagellar motors are able to remodel in response to a variety of environmental stimuli and are among the triggers for surface colonization and infections. The precise mechanisms by which motors remodel and promote cellular adaptation likely depend on key motor attributes. The photomultiplier-based bead-tracking technique presented here enables accurate biophysical characterization of motor functions, including adaptations in motor speeds and switch-dynamics. This approach offers the advantage of real-time tracking and the ability to probe motor behavior over extended durations. The protocols discussed can be readily extended to study flagellar motors in a variety of bacterial species.

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KW - Biophysics

KW - Chemotaxis

KW - Issue 119

KW - Mechanosensing

KW - Particle tracking

KW - Switching

KW - Torque

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JO - Journal of Visualized Experiments

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Biophysical characterization of flagellar motor functions

Abstract

Keywords

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