Comprehensive analysis of sequences of a protein switch

Szu Hua Chen; Jaroslaw Meller; Ron Elber

doi:10.1002/pro.2723

Comprehensive analysis of sequences of a protein switch

Szu Hua Chen, Jaroslaw Meller, Ron Elber

Biostatistics and Biomedical Informatics

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

15 Scopus citations

Abstract

Switches form a special class of proteins that dramatically change their three-dimensional structures upon a small perturbation. One possible perturbation that we explore is that of a single point mutation. Building on the pioneering experimental work of Alexander et al. (Alexander et al. PNAS, 2007; 104,11963-11968) that determines switch sequences between α and α+β folds we conduct a comprehensive sequence sampling by a Markov Chain with multiple fitness criteria to identify new switches given the experimental folds. We screen for switch sequences using a combination of contact potential, secondary structure prediction, and finally molecular dynamics simulations. Statistical properties of switch sequences are discussed and illustrated to be most sensitive to mutation at the N- and C- termini of the switch protein. Based on this analysis, a particularly stable putative switch pair is identified and proposed for further experimental analysis.

Original language	English
Pages (from-to)	135-146
Number of pages	12
Journal	Protein Science
Volume	25
Issue number	1
DOIs	https://doi.org/10.1002/pro.2723
State	Published - Jan 1 2016

Keywords

contact maps
molecular dynamics
mutations
protein folds
secondary structure prediction
structural flips

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10.1002/pro.2723

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title = "Comprehensive analysis of sequences of a protein switch",

abstract = "Switches form a special class of proteins that dramatically change their three-dimensional structures upon a small perturbation. One possible perturbation that we explore is that of a single point mutation. Building on the pioneering experimental work of Alexander et al. (Alexander et al. PNAS, 2007; 104,11963-11968) that determines switch sequences between α and α+β folds we conduct a comprehensive sequence sampling by a Markov Chain with multiple fitness criteria to identify new switches given the experimental folds. We screen for switch sequences using a combination of contact potential, secondary structure prediction, and finally molecular dynamics simulations. Statistical properties of switch sequences are discussed and illustrated to be most sensitive to mutation at the N- and C- termini of the switch protein. Based on this analysis, a particularly stable putative switch pair is identified and proposed for further experimental analysis.",

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AU - Chen, Szu Hua

AU - Meller, Jaroslaw

AU - Elber, Ron

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AB - Switches form a special class of proteins that dramatically change their three-dimensional structures upon a small perturbation. One possible perturbation that we explore is that of a single point mutation. Building on the pioneering experimental work of Alexander et al. (Alexander et al. PNAS, 2007; 104,11963-11968) that determines switch sequences between α and α+β folds we conduct a comprehensive sequence sampling by a Markov Chain with multiple fitness criteria to identify new switches given the experimental folds. We screen for switch sequences using a combination of contact potential, secondary structure prediction, and finally molecular dynamics simulations. Statistical properties of switch sequences are discussed and illustrated to be most sensitive to mutation at the N- and C- termini of the switch protein. Based on this analysis, a particularly stable putative switch pair is identified and proposed for further experimental analysis.

KW - contact maps

KW - molecular dynamics

KW - mutations

KW - protein folds

KW - secondary structure prediction

KW - structural flips

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JO - Protein Science

JF - Protein Science

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Comprehensive analysis of sequences of a protein switch

Abstract

Keywords

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