Coupling of receptor conformation and ligand orientation determine graded activity

John B. Bruning; Alexander A. Parent; German Gil; Min Zhao; Jason Nowak; Margaret C. Pace; Carolyn L. Smith; Pavel V. Afonine; Paul D. Adams; John A. Katzenellenbogen; Kendall W. Nettles

doi:10.1038/nchembio.451

Coupling of receptor conformation and ligand orientation determine graded activity

John B. Bruning, Alexander A. Parent, German Gil, Min Zhao, Jason Nowak, Margaret C. Pace, Carolyn L. Smith, Pavel V. Afonine, Paul D. Adams, John A. Katzenellenbogen, Kendall W. Nettles

Chemistry

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

Abstract

Small molecules stabilize specific protein conformations from a larger ensemble, enabling molecular switches that control diverse cellular functions. We show here that the converse also holds true: the conformational state of the estrogen receptor can direct distinct orientations of the bound ligand. 'Gain-of-allostery' mutations that mimic the effects of ligand in driving protein conformation allowed crystallization of the partial agonist ligand WAY-169916 with both the canonical active and inactive conformations of the estrogen receptor. The intermediate transcriptional activity induced by WAY-169916 is associated with the ligand binding differently to the active and inactive conformations of the receptor. Analyses of a series of chemical derivatives demonstrated that altering the ensemble of ligand binding orientations changes signaling output. The coupling of different ligand binding orientations to distinct active and inactive protein conformations defines a new mechanism for titrating allosteric signaling activity.

Original language	English (US)
Pages (from-to)	837-843
Number of pages	7
Journal	Nature chemical biology
Volume	6
Issue number	11
DOIs	https://doi.org/10.1038/nchembio.451
State	Published - Nov 2010

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Molecular Biology
Cell Biology

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10.1038/nchembio.451

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title = "Coupling of receptor conformation and ligand orientation determine graded activity",

abstract = "Small molecules stabilize specific protein conformations from a larger ensemble, enabling molecular switches that control diverse cellular functions. We show here that the converse also holds true: the conformational state of the estrogen receptor can direct distinct orientations of the bound ligand. 'Gain-of-allostery' mutations that mimic the effects of ligand in driving protein conformation allowed crystallization of the partial agonist ligand WAY-169916 with both the canonical active and inactive conformations of the estrogen receptor. The intermediate transcriptional activity induced by WAY-169916 is associated with the ligand binding differently to the active and inactive conformations of the receptor. Analyses of a series of chemical derivatives demonstrated that altering the ensemble of ligand binding orientations changes signaling output. The coupling of different ligand binding orientations to distinct active and inactive protein conformations defines a new mechanism for titrating allosteric signaling activity.",

author = "Bruning, {John B.} and Parent, {Alexander A.} and German Gil and Min Zhao and Jason Nowak and Pace, {Margaret C.} and Smith, {Carolyn L.} and Afonine, {Pavel V.} and Adams, {Paul D.} and Katzenellenbogen, {John A.} and Nettles, {Kendall W.}",

note = "Funding Information: This work was supported by the US National Institutes of Health PHS R37 DK15556 (J.A.K.), DK53002 (C.L.S.), CA132022 and DK077085 (K.W.N.) and the Frenchman{\textquoteright}s Creek Women for Cancer Research (G.G.). We would like to thank J. Cleveland for comments on the manuscript, L. Potterton and S. McNicholas (University of York) for help with CCP4MG and K. Carlson (University of Illinois) for performing the ERα ligand-binding assays.",

year = "2010",

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doi = "10.1038/nchembio.451",

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AU - Bruning, John B.

AU - Parent, Alexander A.

AU - Gil, German

AU - Zhao, Min

AU - Nowak, Jason

AU - Pace, Margaret C.

AU - Smith, Carolyn L.

AU - Afonine, Pavel V.

AU - Adams, Paul D.

AU - Katzenellenbogen, John A.

AU - Nettles, Kendall W.

N1 - Funding Information: This work was supported by the US National Institutes of Health PHS R37 DK15556 (J.A.K.), DK53002 (C.L.S.), CA132022 and DK077085 (K.W.N.) and the Frenchman’s Creek Women for Cancer Research (G.G.). We would like to thank J. Cleveland for comments on the manuscript, L. Potterton and S. McNicholas (University of York) for help with CCP4MG and K. Carlson (University of Illinois) for performing the ERα ligand-binding assays.

PY - 2010/11

Y1 - 2010/11

N2 - Small molecules stabilize specific protein conformations from a larger ensemble, enabling molecular switches that control diverse cellular functions. We show here that the converse also holds true: the conformational state of the estrogen receptor can direct distinct orientations of the bound ligand. 'Gain-of-allostery' mutations that mimic the effects of ligand in driving protein conformation allowed crystallization of the partial agonist ligand WAY-169916 with both the canonical active and inactive conformations of the estrogen receptor. The intermediate transcriptional activity induced by WAY-169916 is associated with the ligand binding differently to the active and inactive conformations of the receptor. Analyses of a series of chemical derivatives demonstrated that altering the ensemble of ligand binding orientations changes signaling output. The coupling of different ligand binding orientations to distinct active and inactive protein conformations defines a new mechanism for titrating allosteric signaling activity.

AB - Small molecules stabilize specific protein conformations from a larger ensemble, enabling molecular switches that control diverse cellular functions. We show here that the converse also holds true: the conformational state of the estrogen receptor can direct distinct orientations of the bound ligand. 'Gain-of-allostery' mutations that mimic the effects of ligand in driving protein conformation allowed crystallization of the partial agonist ligand WAY-169916 with both the canonical active and inactive conformations of the estrogen receptor. The intermediate transcriptional activity induced by WAY-169916 is associated with the ligand binding differently to the active and inactive conformations of the receptor. Analyses of a series of chemical derivatives demonstrated that altering the ensemble of ligand binding orientations changes signaling output. The coupling of different ligand binding orientations to distinct active and inactive protein conformations defines a new mechanism for titrating allosteric signaling activity.

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Coupling of receptor conformation and ligand orientation determine graded activity

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