Side Chain Flexibilities in the Human Ether-a-go-go Related Gene Potassium Channel (hERG) Together with Matched-Pair Binding Studies Suggest a New Binding Mode for Channel Blockers

Ulrich Zachariae; Fabrizio Giordanetto; Andrew G. Leach

doi:10.1021/jm900002x

Side Chain Flexibilities in the Human Ether-a-go-go Related Gene Potassium Channel (hERG) Together with Matched-Pair Binding Studies Suggest a New Binding Mode for Channel Blockers

Ulrich Zachariae, Fabrizio Giordanetto, Andrew G. Leach

Pharmacy

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

Abstract

The cardiac hERG K+ channel constitutes a long-standing and expensive antitarget for the drug industry. From a study of the flexibility of hERG around its internal binding cavity, we have developed a new structural model of drug binding to hERG, which involves binding orthogonal to the pore channel and therefore can exploit the up to 4-fold symmetry of the tetrameric channel. This binding site has a base formed by four tyrosine side chains that complement reported ligand-based pharmacophores. The model is able to rationalize reduced hERG potency in matched molecular pair studies and suggests design guidelines to optimize against hERG not relying simply on lipophilicity reduction. The binding model also suggests a molecular mechanism for the link between high-affinity hERG binding and C-type inactivation.

Original language	English
Pages (from-to)	4266-4276
Journal	Journal of Medicinal Chemistry
Volume	52
Issue number	14
DOIs	https://doi.org/10.1021/jm900002x
Publication status	Published - 23 Jul 2009

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10.1021/jm900002x

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abstract = "The cardiac hERG K+ channel constitutes a long-standing and expensive antitarget for the drug industry. From a study of the flexibility of hERG around its internal binding cavity, we have developed a new structural model of drug binding to hERG, which involves binding orthogonal to the pore channel and therefore can exploit the up to 4-fold symmetry of the tetrameric channel. This binding site has a base formed by four tyrosine side chains that complement reported ligand-based pharmacophores. The model is able to rationalize reduced hERG potency in matched molecular pair studies and suggests design guidelines to optimize against hERG not relying simply on lipophilicity reduction. The binding model also suggests a molecular mechanism for the link between high-affinity hERG binding and C-type inactivation.",

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Side Chain Flexibilities in the Human Ether-a-go-go Related Gene Potassium Channel (hERG) Together with Matched-Pair Binding Studies Suggest a New Binding Mode for Channel Blockers. / Zachariae, Ulrich; Giordanetto, Fabrizio; Leach, Andrew G.
In: Journal of Medicinal Chemistry, Vol. 52, No. 14, 23.07.2009, p. 4266-4276.

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

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AU - Giordanetto, Fabrizio

AU - Leach, Andrew G.

PY - 2009/7/23

Y1 - 2009/7/23

N2 - The cardiac hERG K+ channel constitutes a long-standing and expensive antitarget for the drug industry. From a study of the flexibility of hERG around its internal binding cavity, we have developed a new structural model of drug binding to hERG, which involves binding orthogonal to the pore channel and therefore can exploit the up to 4-fold symmetry of the tetrameric channel. This binding site has a base formed by four tyrosine side chains that complement reported ligand-based pharmacophores. The model is able to rationalize reduced hERG potency in matched molecular pair studies and suggests design guidelines to optimize against hERG not relying simply on lipophilicity reduction. The binding model also suggests a molecular mechanism for the link between high-affinity hERG binding and C-type inactivation.

AB - The cardiac hERG K+ channel constitutes a long-standing and expensive antitarget for the drug industry. From a study of the flexibility of hERG around its internal binding cavity, we have developed a new structural model of drug binding to hERG, which involves binding orthogonal to the pore channel and therefore can exploit the up to 4-fold symmetry of the tetrameric channel. This binding site has a base formed by four tyrosine side chains that complement reported ligand-based pharmacophores. The model is able to rationalize reduced hERG potency in matched molecular pair studies and suggests design guidelines to optimize against hERG not relying simply on lipophilicity reduction. The binding model also suggests a molecular mechanism for the link between high-affinity hERG binding and C-type inactivation.

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Side Chain Flexibilities in the Human Ether-a-go-go Related Gene Potassium Channel (hERG) Together with Matched-Pair Binding Studies Suggest a New Binding Mode for Channel Blockers

Abstract

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