Persistent super-diffusive motion of Escherichia coli chromosomal loci

Avelino Javer; Nathan J. Kuwada; Zhicheng Long; Vincenzo G. Benza; Kevin D. Dorfman; Paul A. Wiggins; Pietro Cicuta; Marco Cosentino Lagomarsino

doi:10.1038/ncomms4854

Persistent super-diffusive motion of Escherichia coli chromosomal loci

Avelino Javer, Nathan J. Kuwada, Zhicheng Long, Vincenzo G. Benza, Kevin D. Dorfman, Paul A. Wiggins, Pietro Cicuta, Marco Cosentino Lagomarsino

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64 Scopus citations

Abstract

The physical nature of the bacterial chromosome has important implications for its function. Using high-resolution dynamic tracking, we observe the existence of rare but ubiquitous 'rapid movements' of chromosomal loci exhibiting near-ballistic dynamics. This suggests that these movements are either driven by an active machinery or part of stress-relaxation mechanisms. Comparison with a null physical model for subdiffusive chromosomal dynamics shows that rapid movements are excursions from a basal subdiffusive dynamics, likely due to driven and/or stress-relaxation motion. Additionally, rapid movements are in some cases coupled with known transitions of chromosomal segregation. They do not co-occur strictly with replication, their frequency varies with growth condition and chromosomal coordinate, and they show a preference for longitudinal motion. These findings support an emerging picture of the bacterial chromosome as off-equilibrium active matter and help developing a correct physical model of its in vivo dynamic structure.

Original language	English (US)
Article number	3854
Journal	Nature communications
Volume	5
DOIs	https://doi.org/10.1038/ncomms4854
State	Published - May 29 2014

Bibliographical note

Funding Information:
We acknowledge useful discussions with Olivier Espeli, Bianca Sclavi, Vittore Scolari, Francois-Xavier Barre, Cristophe Possoz, Frederic Boccard, Camille Cibot, Michele Valens and Paolo Pierobon. This work was supported by the International Human Frontier Science Program Organization, grant RGY0069/2009-C, and Consejo Nacional de Ciencia y Tecnologia (CONACYT).

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title = "Persistent super-diffusive motion of Escherichia coli chromosomal loci",

abstract = "The physical nature of the bacterial chromosome has important implications for its function. Using high-resolution dynamic tracking, we observe the existence of rare but ubiquitous 'rapid movements' of chromosomal loci exhibiting near-ballistic dynamics. This suggests that these movements are either driven by an active machinery or part of stress-relaxation mechanisms. Comparison with a null physical model for subdiffusive chromosomal dynamics shows that rapid movements are excursions from a basal subdiffusive dynamics, likely due to driven and/or stress-relaxation motion. Additionally, rapid movements are in some cases coupled with known transitions of chromosomal segregation. They do not co-occur strictly with replication, their frequency varies with growth condition and chromosomal coordinate, and they show a preference for longitudinal motion. These findings support an emerging picture of the bacterial chromosome as off-equilibrium active matter and help developing a correct physical model of its in vivo dynamic structure.",

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AU - Wiggins, Paul A.

AU - Cicuta, Pietro

AU - Lagomarsino, Marco Cosentino

N1 - Funding Information: We acknowledge useful discussions with Olivier Espeli, Bianca Sclavi, Vittore Scolari, Francois-Xavier Barre, Cristophe Possoz, Frederic Boccard, Camille Cibot, Michele Valens and Paolo Pierobon. This work was supported by the International Human Frontier Science Program Organization, grant RGY0069/2009-C, and Consejo Nacional de Ciencia y Tecnologia (CONACYT).

PY - 2014/5/29

Y1 - 2014/5/29

N2 - The physical nature of the bacterial chromosome has important implications for its function. Using high-resolution dynamic tracking, we observe the existence of rare but ubiquitous 'rapid movements' of chromosomal loci exhibiting near-ballistic dynamics. This suggests that these movements are either driven by an active machinery or part of stress-relaxation mechanisms. Comparison with a null physical model for subdiffusive chromosomal dynamics shows that rapid movements are excursions from a basal subdiffusive dynamics, likely due to driven and/or stress-relaxation motion. Additionally, rapid movements are in some cases coupled with known transitions of chromosomal segregation. They do not co-occur strictly with replication, their frequency varies with growth condition and chromosomal coordinate, and they show a preference for longitudinal motion. These findings support an emerging picture of the bacterial chromosome as off-equilibrium active matter and help developing a correct physical model of its in vivo dynamic structure.

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Persistent super-diffusive motion of Escherichia coli chromosomal loci

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