Allosteric transitions in biological nanomachines are described by robust normal modes of elastic networks

Wenjun Zheng; Bernard R. Brooks; D. Thirumalai

doi:10.2174/138920309787847608

Allosteric transitions in biological nanomachines are described by robust normal modes of elastic networks

Wenjun Zheng
, Bernard R. Brooks
, D. Thirumalai

Physics

National Institutes of Health
University of Maryland, College Park

Research output: Contribution to journal › Review article › peer-review

43 Scopus citations

Abstract

Allostery forms the basis of intra-molecular communications in various enzymes, however the underlying conformational changes are largely elusive. Recently, we have proposed to employ an elastic model based normal mode analysis to investigate the allosteric transitions in several molecular nanomachines (including myosin II, DNA polymerase and chaperonin GroEL). After combining with bioinformatics analysis of the evolutionary sequence variations, we have been able to identify the highly conserved and robust modes of collective motions that are capable of transmitting molecular signals over long distances.

Original language	English
Pages (from-to)	128-132
Number of pages	5
Journal	Current Protein and Peptide Science
Volume	10
Issue number	2
DOIs	https://doi.org/10.2174/138920309787847608
State	Published - 2009

Keywords

Allostery
Chaperonin
Elastic network model
Myosin
Normal mode analysis
Polymerase

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abstract = "Allostery forms the basis of intra-molecular communications in various enzymes, however the underlying conformational changes are largely elusive. Recently, we have proposed to employ an elastic model based normal mode analysis to investigate the allosteric transitions in several molecular nanomachines (including myosin II, DNA polymerase and chaperonin GroEL). After combining with bioinformatics analysis of the evolutionary sequence variations, we have been able to identify the highly conserved and robust modes of collective motions that are capable of transmitting molecular signals over long distances.",

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AU - Brooks, Bernard R.

AU - Thirumalai, D.

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N2 - Allostery forms the basis of intra-molecular communications in various enzymes, however the underlying conformational changes are largely elusive. Recently, we have proposed to employ an elastic model based normal mode analysis to investigate the allosteric transitions in several molecular nanomachines (including myosin II, DNA polymerase and chaperonin GroEL). After combining with bioinformatics analysis of the evolutionary sequence variations, we have been able to identify the highly conserved and robust modes of collective motions that are capable of transmitting molecular signals over long distances.

AB - Allostery forms the basis of intra-molecular communications in various enzymes, however the underlying conformational changes are largely elusive. Recently, we have proposed to employ an elastic model based normal mode analysis to investigate the allosteric transitions in several molecular nanomachines (including myosin II, DNA polymerase and chaperonin GroEL). After combining with bioinformatics analysis of the evolutionary sequence variations, we have been able to identify the highly conserved and robust modes of collective motions that are capable of transmitting molecular signals over long distances.

KW - Allostery

KW - Chaperonin

KW - Elastic network model

KW - Myosin

KW - Normal mode analysis

KW - Polymerase

UR - https://www.scopus.com/pages/publications/65649154062

U2 - 10.2174/138920309787847608

DO - 10.2174/138920309787847608

M3 - Review article

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AN - SCOPUS:65649154062

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JO - Current Protein and Peptide Science

JF - Current Protein and Peptide Science

IS - 2

ER -

Allosteric transitions in biological nanomachines are described by robust normal modes of elastic networks

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Keywords

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