Mechanism for adaptive remodeling of the bacterial flagellar switch

Pushkar P. Lele; Richard W. Branch; Vedhavalli S.J. Nathan; Howard C. Berg

doi:10.1073/pnas.1212327109

Mechanism for adaptive remodeling of the bacterial flagellar switch

Pushkar P. Lele, Richard W. Branch, Vedhavalli S.J. Nathan, Howard C. Berg

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

82 Scopus citations

Abstract

The bacterial flagellar motor has been shown in previous work to adapt to changes in the steady-state concentration of the chemotaxis signaling molecule, CheY-P, by changing the FliM content. We show here that the number of FliM molecules in the motor and the fraction of FliM molecules that exchange depend on the direction of flagellar rotation, not on CheY-P binding per se. Our results are consistent with a model in which the structural differences associated with the direction of rotation modulate the strength of FliM binding. When the motor spins counterclockwise, FliM binding strengthens, the fraction of FliM molecules that exchanges decreases, and the ring content increases. The larger number of CheY-P binding sites enhances the motor's sensitivity, i.e., the motor adapts. An interesting unresolved question is how additional copies of FliM might be accommodated.

Original language	English (US)
Pages (from-to)	20018-20022
Number of pages	5
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	109
Issue number	49
DOIs	https://doi.org/10.1073/pnas.1212327109
State	Published - Dec 4 2012

Keywords

Escherichia coli
Motility

ASJC Scopus subject areas

General

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10.1073/pnas.1212327109

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title = "Mechanism for adaptive remodeling of the bacterial flagellar switch",

abstract = "The bacterial flagellar motor has been shown in previous work to adapt to changes in the steady-state concentration of the chemotaxis signaling molecule, CheY-P, by changing the FliM content. We show here that the number of FliM molecules in the motor and the fraction of FliM molecules that exchange depend on the direction of flagellar rotation, not on CheY-P binding per se. Our results are consistent with a model in which the structural differences associated with the direction of rotation modulate the strength of FliM binding. When the motor spins counterclockwise, FliM binding strengthens, the fraction of FliM molecules that exchanges decreases, and the ring content increases. The larger number of CheY-P binding sites enhances the motor's sensitivity, i.e., the motor adapts. An interesting unresolved question is how additional copies of FliM might be accommodated.",

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T1 - Mechanism for adaptive remodeling of the bacterial flagellar switch

AU - Lele, Pushkar P.

AU - Branch, Richard W.

AU - Nathan, Vedhavalli S.J.

AU - Berg, Howard C.

PY - 2012/12/4

Y1 - 2012/12/4

N2 - The bacterial flagellar motor has been shown in previous work to adapt to changes in the steady-state concentration of the chemotaxis signaling molecule, CheY-P, by changing the FliM content. We show here that the number of FliM molecules in the motor and the fraction of FliM molecules that exchange depend on the direction of flagellar rotation, not on CheY-P binding per se. Our results are consistent with a model in which the structural differences associated with the direction of rotation modulate the strength of FliM binding. When the motor spins counterclockwise, FliM binding strengthens, the fraction of FliM molecules that exchanges decreases, and the ring content increases. The larger number of CheY-P binding sites enhances the motor's sensitivity, i.e., the motor adapts. An interesting unresolved question is how additional copies of FliM might be accommodated.

AB - The bacterial flagellar motor has been shown in previous work to adapt to changes in the steady-state concentration of the chemotaxis signaling molecule, CheY-P, by changing the FliM content. We show here that the number of FliM molecules in the motor and the fraction of FliM molecules that exchange depend on the direction of flagellar rotation, not on CheY-P binding per se. Our results are consistent with a model in which the structural differences associated with the direction of rotation modulate the strength of FliM binding. When the motor spins counterclockwise, FliM binding strengthens, the fraction of FliM molecules that exchanges decreases, and the ring content increases. The larger number of CheY-P binding sites enhances the motor's sensitivity, i.e., the motor adapts. An interesting unresolved question is how additional copies of FliM might be accommodated.

KW - Escherichia coli

KW - Motility

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Mechanism for adaptive remodeling of the bacterial flagellar switch

Abstract

Keywords

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