Summary
Nicotinic acetylcholine receptors (nAChRs) mediate neuronal synaptic transmission and modulation. They contribute to higher brain functions such as cognition and reward and are important drug targets. Recent studies have revealed that these acetylcholine-gated ion channels display an unanticipated conformational plasticity, adopting multiple allosteric states that shape the time course of their electrophysiological response. To date, a single nAChR structure has been solved at high resolution, and our understanding of the conformational transitions remains so far elusive.
To address this challenge, we propose to develop a top-down approach starting from the study of the conformational transitions of nAChRs functionally expressed in cells, and then dissecting the molecular mechanisms on purified proteins. In WP1, we will develop an innovative fluorescence quenching approach to follow the protein motions concomitant with channel opening at the cell membrane. In WP2, we will further exploit this technique on purified proteins, to study the role/requirement of lipids, and their pharmacological crosstalk with allosteric modulators acting at the transmembrane domain. In WP3, the gained knowledge will open original routes to solve 3D structures of nAChRs, in novel conformations and in complex with allosteric modulators. The research will be centered on the major brain nAChRs, primarily the homomeric α7 and also the heteromeric α4β2 nAChRs that are major physiological players and key potential therapeutic targets.
This multidisciplinary project combines electrophysiology, fluorescence, pharmacology, membrane protein biochemistry and structural biology, together with in silico modeling, molecular dynamics and ligand docking. The results will provide fundamental insights into the allosteric mechanisms underlying both nAChR function and its modulation by allosteric modulators that hold promises in therapeutics.
To address this challenge, we propose to develop a top-down approach starting from the study of the conformational transitions of nAChRs functionally expressed in cells, and then dissecting the molecular mechanisms on purified proteins. In WP1, we will develop an innovative fluorescence quenching approach to follow the protein motions concomitant with channel opening at the cell membrane. In WP2, we will further exploit this technique on purified proteins, to study the role/requirement of lipids, and their pharmacological crosstalk with allosteric modulators acting at the transmembrane domain. In WP3, the gained knowledge will open original routes to solve 3D structures of nAChRs, in novel conformations and in complex with allosteric modulators. The research will be centered on the major brain nAChRs, primarily the homomeric α7 and also the heteromeric α4β2 nAChRs that are major physiological players and key potential therapeutic targets.
This multidisciplinary project combines electrophysiology, fluorescence, pharmacology, membrane protein biochemistry and structural biology, together with in silico modeling, molecular dynamics and ligand docking. The results will provide fundamental insights into the allosteric mechanisms underlying both nAChR function and its modulation by allosteric modulators that hold promises in therapeutics.
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More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/788974 |
Start date: | 01-01-2019 |
End date: | 31-12-2024 |
Total budget - Public funding: | 2 282 105,00 Euro - 2 282 105,00 Euro |
Cordis data
Original description
Nicotinic acetylcholine receptors (nAChRs) mediate neuronal synaptic transmission and modulation. They contribute to higher brain functions such as cognition and reward and are important drug targets. Recent studies have revealed that these acetylcholine-gated ion channels display an unanticipated conformational plasticity, adopting multiple allosteric states that shape the time course of their electrophysiological response. To date, a single nAChR structure has been solved at high resolution, and our understanding of the conformational transitions remains so far elusive.To address this challenge, we propose to develop a top-down approach starting from the study of the conformational transitions of nAChRs functionally expressed in cells, and then dissecting the molecular mechanisms on purified proteins. In WP1, we will develop an innovative fluorescence quenching approach to follow the protein motions concomitant with channel opening at the cell membrane. In WP2, we will further exploit this technique on purified proteins, to study the role/requirement of lipids, and their pharmacological crosstalk with allosteric modulators acting at the transmembrane domain. In WP3, the gained knowledge will open original routes to solve 3D structures of nAChRs, in novel conformations and in complex with allosteric modulators. The research will be centered on the major brain nAChRs, primarily the homomeric α7 and also the heteromeric α4β2 nAChRs that are major physiological players and key potential therapeutic targets.
This multidisciplinary project combines electrophysiology, fluorescence, pharmacology, membrane protein biochemistry and structural biology, together with in silico modeling, molecular dynamics and ligand docking. The results will provide fundamental insights into the allosteric mechanisms underlying both nAChR function and its modulation by allosteric modulators that hold promises in therapeutics.
Status
SIGNEDCall topic
ERC-2017-ADGUpdate Date
27-04-2024
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