A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.

It is challenging to decipher molecular mechanisms in biological systems from system-level input-output data, especially for complex processes that involve interactions among multiple components. We addressed this general problem for the bacterial histidine kinase CheA, the activity of which is regu...

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Main Authors: Bernardo A Mello, Wenlin Pan, Gerald L Hazelbauer, Yuhai Tu
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2018-07-01
Series:PLoS Computational Biology
Online Access:http://europepmc.org/articles/PMC6044545?pdf=render
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spelling doaj-22a81f82c7a342b9b827c23ca949373c2020-11-25T01:37:15ZengPublic Library of Science (PLoS)PLoS Computational Biology1553-734X1553-73582018-07-01147e100630510.1371/journal.pcbi.1006305A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.Bernardo A MelloWenlin PanGerald L HazelbauerYuhai TuIt is challenging to decipher molecular mechanisms in biological systems from system-level input-output data, especially for complex processes that involve interactions among multiple components. We addressed this general problem for the bacterial histidine kinase CheA, the activity of which is regulated in chemotaxis signaling complexes by bacterial chemoreceptors. We developed a general network model to describe the dynamics of the system, treating the receptor complex with coupling protein CheW and the P3P4P5 domains of kinase CheA as a regulated enzyme with two substrates, ATP and P1, the phosphoryl-accepting domain of CheA. Our simple network model allowed us to search hypothesis space systematically. For different and progressively more complex regulation schemes, we fit our models to a large set of input-output data with the aim of identifying the simplest possible regulation mechanisms consistent with the data. Our modeling and analysis revealed novel dual regulation mechanisms in which receptor activity regulated ATP binding plus one other process, either P1 binding or phosphoryl transfer between P1 and ATP. Strikingly, in our models receptor control affected the kinetic rate constants of substrate association and dissociation equally and thus did not alter the respective equilibrium constants. We suggest experiments that could distinguish between the two dual-regulation mechanisms. This systems-biology approach of combining modeling and a large input-output dataset should be applicable for studying other complex biological processes.http://europepmc.org/articles/PMC6044545?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Bernardo A Mello
Wenlin Pan
Gerald L Hazelbauer
Yuhai Tu
spellingShingle Bernardo A Mello
Wenlin Pan
Gerald L Hazelbauer
Yuhai Tu
A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.
PLoS Computational Biology
author_facet Bernardo A Mello
Wenlin Pan
Gerald L Hazelbauer
Yuhai Tu
author_sort Bernardo A Mello
title A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.
title_short A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.
title_full A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.
title_fullStr A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.
title_full_unstemmed A dual regulation mechanism of histidine kinase CheA identified by combining network-dynamics modeling and system-level input-output data.
title_sort dual regulation mechanism of histidine kinase chea identified by combining network-dynamics modeling and system-level input-output data.
publisher Public Library of Science (PLoS)
series PLoS Computational Biology
issn 1553-734X
1553-7358
publishDate 2018-07-01
description It is challenging to decipher molecular mechanisms in biological systems from system-level input-output data, especially for complex processes that involve interactions among multiple components. We addressed this general problem for the bacterial histidine kinase CheA, the activity of which is regulated in chemotaxis signaling complexes by bacterial chemoreceptors. We developed a general network model to describe the dynamics of the system, treating the receptor complex with coupling protein CheW and the P3P4P5 domains of kinase CheA as a regulated enzyme with two substrates, ATP and P1, the phosphoryl-accepting domain of CheA. Our simple network model allowed us to search hypothesis space systematically. For different and progressively more complex regulation schemes, we fit our models to a large set of input-output data with the aim of identifying the simplest possible regulation mechanisms consistent with the data. Our modeling and analysis revealed novel dual regulation mechanisms in which receptor activity regulated ATP binding plus one other process, either P1 binding or phosphoryl transfer between P1 and ATP. Strikingly, in our models receptor control affected the kinetic rate constants of substrate association and dissociation equally and thus did not alter the respective equilibrium constants. We suggest experiments that could distinguish between the two dual-regulation mechanisms. This systems-biology approach of combining modeling and a large input-output dataset should be applicable for studying other complex biological processes.
url http://europepmc.org/articles/PMC6044545?pdf=render
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