Comparative molecular dynamics simulations of uncomplexed, 'agonist-bound' and 'antagonist-bound' α1A adrenoceptor models

Gemma K. Kinsella; Isabel Rozas; Graeme W. Watson

doi:10.1016/j.bbrc.2005.05.159

Comparative molecular dynamics simulations of uncomplexed, 'agonist-bound' and 'antagonist-bound' α_1A adrenoceptor models

Gemma K. Kinsella, Isabel Rozas, Graeme W. Watson

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

Abstract

Molecular dynamics simulations (2 ns) were conducted on a homology model of the α_1A adrenoceptor complexed with agonists and antagonists to examine the various receptor conformations induced. These simulations yield insights into the binding site interactions of the active and inactive states of the receptor. Furthermore, our analysis allowed for the selection of candidate sites for future mutagenesis experiments such as of Glu-180, which may be important for antagonist binding. The interactions of conserved residues of the DRY motif in TM-III and the NPxxY motif in TM-VII in the α_1A adrenoceptor complexes were also examined. The major differences lie in the role of residue Arg-124, which for the agonist complexes formed additional interactions with residues of intracellular loops I and II. Alternatively, for the antagonist complexes, additional interactions were observed for Asn-322 with residues of TM-II and TM-VII.

Original language	English
Pages (from-to)	737-741
Number of pages	5
Journal	Biochemical and Biophysical Research Communications
Volume	333
Issue number	3
DOIs	https://doi.org/10.1016/j.bbrc.2005.05.159
Publication status	Published - 5 Aug 2005
Externally published	Yes

Keywords

G-protein coupled receptor
Ligand docking
Molecular dynamics

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10.1016/j.bbrc.2005.05.159

Cite this

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title = "Comparative molecular dynamics simulations of uncomplexed, 'agonist-bound' and 'antagonist-bound' α1A adrenoceptor models",

abstract = "Molecular dynamics simulations (2 ns) were conducted on a homology model of the α1A adrenoceptor complexed with agonists and antagonists to examine the various receptor conformations induced. These simulations yield insights into the binding site interactions of the active and inactive states of the receptor. Furthermore, our analysis allowed for the selection of candidate sites for future mutagenesis experiments such as of Glu-180, which may be important for antagonist binding. The interactions of conserved residues of the DRY motif in TM-III and the NPxxY motif in TM-VII in the α1A adrenoceptor complexes were also examined. The major differences lie in the role of residue Arg-124, which for the agonist complexes formed additional interactions with residues of intracellular loops I and II. Alternatively, for the antagonist complexes, additional interactions were observed for Asn-322 with residues of TM-II and TM-VII.",

keywords = "G-protein coupled receptor, Ligand docking, Molecular dynamics",

author = "Kinsella, \{Gemma K.\} and Isabel Rozas and Watson, \{Graeme W.\}",

year = "2005",

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T1 - Comparative molecular dynamics simulations of uncomplexed, 'agonist-bound' and 'antagonist-bound' α1A adrenoceptor models

AU - Kinsella, Gemma K.

AU - Rozas, Isabel

AU - Watson, Graeme W.

PY - 2005/8/5

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AB - Molecular dynamics simulations (2 ns) were conducted on a homology model of the α1A adrenoceptor complexed with agonists and antagonists to examine the various receptor conformations induced. These simulations yield insights into the binding site interactions of the active and inactive states of the receptor. Furthermore, our analysis allowed for the selection of candidate sites for future mutagenesis experiments such as of Glu-180, which may be important for antagonist binding. The interactions of conserved residues of the DRY motif in TM-III and the NPxxY motif in TM-VII in the α1A adrenoceptor complexes were also examined. The major differences lie in the role of residue Arg-124, which for the agonist complexes formed additional interactions with residues of intracellular loops I and II. Alternatively, for the antagonist complexes, additional interactions were observed for Asn-322 with residues of TM-II and TM-VII.

KW - G-protein coupled receptor

KW - Ligand docking

KW - Molecular dynamics

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