The Range of Attractant Concentrations for Bacterial Chemotaxis and the Threshold and Size of Response over This Range

Mesibov, Robert; Ordal, George; Adler, Julius

doi:10.1085/jgp.62.2.203

Cited by 265 publications

(223 citation statements)

References 22 publications

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“…The chemotactic bias is now a linear function of the relative gradient, shown by the dashed line of best fit (constrained to pass through the origin). This behaviour is interpreted as a change from a low background concentration response regime, where the bacteria respond to absolute changes in concentration to a high-concentration response regime, where they respond to relative change in concentration ('logarithmic sensing'), as previously observed [26]. Semi-empirical mean-field models have been developed [22,27,37] to explain the large dynamic range of the chemotaxis system.…”

Section: Creating a Chemical Gradientmentioning

confidence: 81%

Fast, high-throughput measurement of collective behaviour in a bacterial population

Colin¹,

Zhang

Wilson³

2014

J. R. Soc. Interface.

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Swimming bacteria explore their environment by performing a random walk, which is biased in response to, for example, chemical stimuli, resulting in a collective drift of bacterial populations towards 'a better life'. This phenomenon, called chemotaxis, is one of the best known forms of collective behaviour in bacteria, crucial for bacterial survival and virulence. Both single-cell and macroscopic assays have investigated bacterial behaviours. However, theories that relate the two scales have previously been difficult to test directly. We present an image analysis method, inspired by light scattering, which measures the average collective motion of thousands of bacteria simultaneously. Using this method, a time-varying collective drift as small as 50 nm s 21 can be measured. The method, validated using simulations, was applied to chemotactic Escherichia coli bacteria in linear gradients of the attractant a-methylaspartate. This enabled us to test a coarse-grained minimal model of chemotaxis. Our results clearly map the onset of receptor methylation, and the transition from linear to logarithmic sensing in the bacterial response to an external chemoeffector. Our method is broadly applicable to problems involving the measurement of collective drift with high time resolution, such as cell migration and fluid flows measurements, and enables fast screening of tactic behaviours.

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Section: Creating a Chemical Gradientmentioning

confidence: 81%

Fast, high-throughput measurement of collective behaviour in a bacterial population

Colin¹,

Zhang

Wilson³

2014

J. R. Soc. Interface.

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“…The mechanism of bacterial chemotaxis is a subject of wide interest since it is the most primitive sensory-motor process and might be the prototype from which the others have evolved. Increase of attractant concentration brings about increased amounts of attractant-chemoreceptor complex (Adler, 1969 ;Brown & Berg, 1974;Mesibov et al, 1973;Spudich & Koshland, 1975) (considering the chemoreceptor to be binding protein and signaller, see below) which is believed to bind (Ordal & Fields, 1977) to a membrane protein called the methyl-accepting chemotaxis protein (MCP). The MCP is subsequently methylated (Kort et al, 1975;Silverman & Simon, 1977;Springer et al, 1977).…”

Section: Introductionmentioning

confidence: 99%

Chemotaxis Towards Sugars by Bacillus subtilis

Ordal

Villani

Rosendahl

1979

Journal of General Microbiology

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Many sugars and derivatives were tested in the capillary assay for their attraction of Bacillus subtilis. The major attractants were 2-deoxy-~-ghcose, D-fructose, gentiobiose, D-glucose, maltose, D-mannitol, D-mannose, N-acetylglucosamine, a-methyl-D-glucoside, P-methyl-Dglucoside, N-acetylmannosamine, a-methyl-D-mannoside, D-sorbitol, L-sorbose, sucrose, trehalose and D-XylOSe. Only glucose chemotaxis was completely constitutive. Competition experiments were carried out to determine the specificities of chemoreceptors. There were 25 instances of no influence of two sugars on each other's taxis, 92 instances of one sugar interfering non-reciprocally with chemotaxis towards another and 49 instances of two sugars reciprocally competing. However, in most of the last instances, other sugars were identified that interfered with chemotaxis towards one member of the pair but not the other. Thus, nearly all sugars and related compounds appear to be detected by their own chemoreceptors, but many secondary interactions exist.

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“…Current data suggest that chemotactic factors induce cell response by interacting with a receptor (11). If we are indeed measuring a specific receptor responsible for mediating chemotaxis in human neutrophils, a close correlation should exist between the Kd of the receptor and the concentration of the chemotactic factor required to give half-maximal chemotactic response (12,13). The Scatchard analysis of specific 125I-CCF binding revealed the presence of a binding site with a dissociation constant of 0.446 ,uM a value close to the concentration of CCF required to elicit a half-maximal chemotactic response, 1.5 ,uM (5).…”

Section: Discussionmentioning

confidence: 97%

Demonstration of a specific neutrophil receptor for a cell-derived chemotactic factor.

Spilberg¹,

Mehta²

1979

J. Clin. Invest.

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The Range of Attractant Concentrations for Bacterial Chemotaxis and the Threshold and Size of Response over This Range

Cited by 265 publications

References 22 publications

Fast, high-throughput measurement of collective behaviour in a bacterial population

Fast, high-throughput measurement of collective behaviour in a bacterial population

Chemotaxis Towards Sugars by Bacillus subtilis

Demonstration of a specific neutrophil receptor for a cell-derived chemotactic factor.

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