An expanded view of the protein folding landscape of PDZ domains

Greta Hultqvist; Søren W Pedersen; Celestine N. Chi; Kristian Strømgaard; Stefano Gianni; Per Jemth

doi:10.1016/j.bbrc.2012.04.042

An expanded view of the protein folding landscape of PDZ domains

Greta Hultqvist, Søren W Pedersen, Celestine N. Chi, Kristian Strømgaard, Stefano Gianni, Per Jemth

9 Citations (Scopus)

Abstract

Most protein domains fold in an apparently co-operative and two-state manner with only the native and denatured states significantly populated at any experimental condition. However, the protein folding energy landscape is often rugged and different transition states may be rate limiting for the folding reaction under different conditions, as seen for the PDZ protein domain family. We have here analyzed the folding kinetics of two PDZ domains and found that a previously undetected third transition state is rate limiting under conditions that stabilize the native state relative to the denatured state. In light of these results, we have re-analyzed previous folding data on PDZ domains and present a unified folding mechanism with three distinct transition states separated by two high-energy intermediates. Our data show that sequence composition tunes the relative stabilities of folding transition states within the PDZ family, while the overall mechanism is determined by topology. This model captures the kinetic folding mechanism of all PDZ domains studied to date.

Original language	English
Journal	Biochemical and Biophysical Research Communications
Volume	421
Issue number	3
Pages (from-to)	550-553
Number of pages	4
ISSN	0006-291X
DOIs	https://doi.org/10.1016/j.bbrc.2012.04.042
Publication status	Published - 11 May 2012

Keywords

Kinetics
Models, Chemical
Mutation
PDZ Domains
Protein Folding

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10.1016/j.bbrc.2012.04.042

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title = "An expanded view of the protein folding landscape of PDZ domains",

abstract = "Most protein domains fold in an apparently co-operative and two-state manner with only the native and denatured states significantly populated at any experimental condition. However, the protein folding energy landscape is often rugged and different transition states may be rate limiting for the folding reaction under different conditions, as seen for the PDZ protein domain family. We have here analyzed the folding kinetics of two PDZ domains and found that a previously undetected third transition state is rate limiting under conditions that stabilize the native state relative to the denatured state. In light of these results, we have re-analyzed previous folding data on PDZ domains and present a unified folding mechanism with three distinct transition states separated by two high-energy intermediates. Our data show that sequence composition tunes the relative stabilities of folding transition states within the PDZ family, while the overall mechanism is determined by topology. This model captures the kinetic folding mechanism of all PDZ domains studied to date.",

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T1 - An expanded view of the protein folding landscape of PDZ domains

AU - Hultqvist, Greta

AU - Pedersen, Søren W

AU - Chi, Celestine N.

AU - Strømgaard, Kristian

AU - Gianni, Stefano

AU - Jemth, Per

PY - 2012/5/11

Y1 - 2012/5/11

N2 - Most protein domains fold in an apparently co-operative and two-state manner with only the native and denatured states significantly populated at any experimental condition. However, the protein folding energy landscape is often rugged and different transition states may be rate limiting for the folding reaction under different conditions, as seen for the PDZ protein domain family. We have here analyzed the folding kinetics of two PDZ domains and found that a previously undetected third transition state is rate limiting under conditions that stabilize the native state relative to the denatured state. In light of these results, we have re-analyzed previous folding data on PDZ domains and present a unified folding mechanism with three distinct transition states separated by two high-energy intermediates. Our data show that sequence composition tunes the relative stabilities of folding transition states within the PDZ family, while the overall mechanism is determined by topology. This model captures the kinetic folding mechanism of all PDZ domains studied to date.

AB - Most protein domains fold in an apparently co-operative and two-state manner with only the native and denatured states significantly populated at any experimental condition. However, the protein folding energy landscape is often rugged and different transition states may be rate limiting for the folding reaction under different conditions, as seen for the PDZ protein domain family. We have here analyzed the folding kinetics of two PDZ domains and found that a previously undetected third transition state is rate limiting under conditions that stabilize the native state relative to the denatured state. In light of these results, we have re-analyzed previous folding data on PDZ domains and present a unified folding mechanism with three distinct transition states separated by two high-energy intermediates. Our data show that sequence composition tunes the relative stabilities of folding transition states within the PDZ family, while the overall mechanism is determined by topology. This model captures the kinetic folding mechanism of all PDZ domains studied to date.

KW - Kinetics

KW - Models, Chemical

KW - Mutation

KW - PDZ Domains

KW - Protein Folding

U2 - 10.1016/j.bbrc.2012.04.042

DO - 10.1016/j.bbrc.2012.04.042

M3 - Journal article

C2 - 22521641

SN - 0006-291X

VL - 421

SP - 550

EP - 553

JO - Biochemical and Biophysical Research Communications

JF - Biochemical and Biophysical Research Communications

IS - 3

ER -

An expanded view of the protein folding landscape of PDZ domains

Abstract

Keywords

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