Lipid agonism: The PIP2 paradigm of ligand-gated ion channels

The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels remained poorly described due to a lack of structural information and assays to quantify and measure lipid binding in a membrane. How does a...

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Published in	Biochimica et biophysica acta Vol. 1851; no. 5; pp. 620 - 628
Main Author	Hansen, Scott B.
Format	Journal Article
Language	English
Published	Netherlands Elsevier B.V 01.05.2015
Subjects	agonists Animals biophysics blood proteins electrophysiology enzymes G-protein Humans Ion channel Ion Channel Gating - drug effects Ligand-Gated Ion Channels - agonists Ligand-Gated Ion Channels - chemistry Ligand-Gated Ion Channels - metabolism Ligands Lipid gated Lipid raft lipids Membrane Microdomains - drug effects Membrane Microdomains - metabolism Membrane Potentials Models, Molecular neurotransmitters pharmacology Phosphatidylinositol 4,5-Diphosphate - metabolism PIP2 plasma membrane potassium channels Potassium Channels, Inwardly Rectifying - agonists Potassium Channels, Inwardly Rectifying - chemistry Potassium Channels, Inwardly Rectifying - metabolism Protein Conformation protein structure Signaling lipid Structure-Activity Relationship PS TREK PI3 kinase PTEN Kv TRP Lipid gated Sn2 Signaling lipid Ld AA Lipid raft PUFA VSD PLA2 ER HCN CoA Kir P2X Cav GPCR PIP3 GIRK Mg PIP2 PLC BK Gβγ PLD Katp ASIC nAChR NMDA TM1 G-protein Ci-VSP K2P TMD DAG Ion channel IP3 PA CTD MARCKS PH PI ATP DRM LAT C8PIP2 PIP
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Abstract	The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels remained poorly described due to a lack of structural information and assays to quantify and measure lipid binding in a membrane. How does a lipid–ligand bind to a membrane protein in the plasma membrane, and what does it mean for a lipid to activate or regulate an ion channel? How does lipid binding compare to activation by soluble neurotransmitter? And how does the cell control lipid agonism? This review focuses on lipids and their interactions with membrane proteins, in particular, ion channels. I discuss the intersection of membrane lipid biology and ion channel biophysics. A picture emerges of membrane lipids as bona fide agonists of ligand-gated ion channels. These freely diffusing signals reside in the plasma membrane, bind to the transmembrane domain of protein, and cause a conformational change that allosterically gates an ion channel. The system employs a catalog of diverse signaling lipids ultimately controlled by lipid enzymes and raft localization. I draw upon pharmacology, recent protein structure, and electrophysiological data to understand lipid regulation and define inward rectifying potassium channels (Kir) as a new class of PIP2 lipid-gated ion channels. [Display omitted] •Membrane resident lipids bind to and activate ion channels with ligand-like properties.•Inward rectifier potassium channel Kir2.2 is a PIP2 lipid-gated ion channel.•Lipid microdomains compartmentalize lipid signals.•Lipases and endocytosis terminate lipid signaling to ion channels.
AbstractList	The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels remained poorly described due to a lack of structural information and assays to quantify and measure lipid binding in a membrane. How does a lipid-ligand bind to a membrane protein in the plasma membrane and what does it mean for a lipid to activate or regulate an ion channel? How does lipid-binding compare to activation by soluble neurotransmitter? And how does the cell control lipid agonism? This review focuses on lipids and their interactions with membrane proteins, in particular ion channels. I discuss the intersection of membrane lipid biology and ion channel biophysics. A picture emerges of membrane lipids as bona fide agonists of ligand-gated ion channels. These freely diffusing signals reside in the plasma membrane, bind to the transmembrane domain of protein, and cause a conformational change that allosterically gates an ion channel. The system employs a catalog of diverse signaling lipids ultimately controlled by lipid enzymes and raft localization. I draw upon pharmacology, recent protein structure, and electrophysiological data to understand lipid regulation and define inward rectifying potassium channels (K ir ) as a new class of PIP 2 lipid-gated ion channels. The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels remained poorly described due to a lack of structural information and assays to quantify and measure lipid binding in a membrane. How does a lipid-ligand bind to a membrane protein in the plasma membrane, and what does it mean for a lipid to activate or regulate an ion channel? How does lipid binding compare to activation by soluble neurotransmitter? And how does the cell control lipid agonism? This review focuses on lipids and their interactions with membrane proteins, in particular, ion channels. I discuss the intersection of membrane lipid biology and ion channel biophysics. A picture emerges of membrane lipids as bona fide agonists of ligand-gated ion channels. These freely diffusing signals reside in the plasma membrane, bind to the transmembrane domain of protein, and cause a conformational change that allosterically gates an ion channel. The system employs a catalog of diverse signaling lipids ultimately controlled by lipid enzymes and raft localization. I draw upon pharmacology, recent protein structure, and electrophysiological data to understand lipid regulation and define inward rectifying potassium channels (Kir) as a new class of PIP2 lipid-gated ion channels.The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels remained poorly described due to a lack of structural information and assays to quantify and measure lipid binding in a membrane. How does a lipid-ligand bind to a membrane protein in the plasma membrane, and what does it mean for a lipid to activate or regulate an ion channel? How does lipid binding compare to activation by soluble neurotransmitter? And how does the cell control lipid agonism? This review focuses on lipids and their interactions with membrane proteins, in particular, ion channels. I discuss the intersection of membrane lipid biology and ion channel biophysics. A picture emerges of membrane lipids as bona fide agonists of ligand-gated ion channels. These freely diffusing signals reside in the plasma membrane, bind to the transmembrane domain of protein, and cause a conformational change that allosterically gates an ion channel. The system employs a catalog of diverse signaling lipids ultimately controlled by lipid enzymes and raft localization. I draw upon pharmacology, recent protein structure, and electrophysiological data to understand lipid regulation and define inward rectifying potassium channels (Kir) as a new class of PIP2 lipid-gated ion channels. The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels remained poorly described due to a lack of structural information and assays to quantify and measure lipid binding in a membrane. How does a lipid–ligand bind to a membrane protein in the plasma membrane, and what does it mean for a lipid to activate or regulate an ion channel? How does lipid binding compare to activation by soluble neurotransmitter? And how does the cell control lipid agonism? This review focuses on lipids and their interactions with membrane proteins, in particular, ion channels. I discuss the intersection of membrane lipid biology and ion channel biophysics. A picture emerges of membrane lipids as bona fide agonists of ligand-gated ion channels. These freely diffusing signals reside in the plasma membrane, bind to the transmembrane domain of protein, and cause a conformational change that allosterically gates an ion channel. The system employs a catalog of diverse signaling lipids ultimately controlled by lipid enzymes and raft localization. I draw upon pharmacology, recent protein structure, and electrophysiological data to understand lipid regulation and define inward rectifying potassium channels (Kir) as a new class of PIP2 lipid-gated ion channels. [Display omitted] •Membrane resident lipids bind to and activate ion channels with ligand-like properties.•Inward rectifier potassium channel Kir2.2 is a PIP2 lipid-gated ion channel.•Lipid microdomains compartmentalize lipid signals.•Lipases and endocytosis terminate lipid signaling to ion channels. The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels remained poorly described due to a lack of structural information and assays to quantify and measure lipid binding in a membrane. How does a lipid–ligand bind to a membrane protein in the plasma membrane, and what does it mean for a lipid to activate or regulate an ion channel? How does lipid binding compare to activation by soluble neurotransmitter? And how does the cell control lipid agonism? This review focuses on lipids and their interactions with membrane proteins, in particular, ion channels. I discuss the intersection of membrane lipid biology and ion channel biophysics. A picture emerges of membrane lipids as bona fide agonists of ligand-gated ion channels. These freely diffusing signals reside in the plasma membrane, bind to the transmembrane domain of protein, and cause a conformational change that allosterically gates an ion channel. The system employs a catalog of diverse signaling lipids ultimately controlled by lipid enzymes and raft localization. I draw upon pharmacology, recent protein structure, and electrophysiological data to understand lipid regulation and define inward rectifying potassium channels (Kir) as a new class of PIP2 lipid-gated ion channels.
Author	Hansen, Scott B.
Author_xml	– sequence: 1 givenname: Scott B. surname: Hansen fullname: Hansen, Scott B. email: shansen@scripps.edu organization: Department of Molecular Therapeutics, The Scripps Research Institute, Jupiter FL 33458, USA
BackLink	https://www.ncbi.nlm.nih.gov/pubmed/25633344$$D View this record in MEDLINE/PubMed
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Keywords	PS TREK PI3 kinase PTEN Kv TRP Lipid gated Sn2 Signaling lipid Ld AA Lipid raft PUFA VSD PLA2 ER HCN CoA Kir P2X Cav GPCR PIP3 GIRK Mg PIP2 PLC BK Gβγ PLD Katp ASIC nAChR NMDA TM1 G-protein Ci-VSP K2P TMD DAG Ion channel IP3 PA CTD MARCKS PH PI ATP DRM LAT C8PIP2 PIP
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Snippet	The past decade, membrane signaling lipids emerged as major regulators of ion channel function. However, the molecular nature of lipid binding to ion channels...
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SubjectTerms	agonists Animals biophysics blood proteins electrophysiology enzymes G-protein Humans Ion channel Ion Channel Gating - drug effects Ligand-Gated Ion Channels - agonists Ligand-Gated Ion Channels - chemistry Ligand-Gated Ion Channels - metabolism Ligands Lipid gated Lipid raft lipids Membrane Microdomains - drug effects Membrane Microdomains - metabolism Membrane Potentials Models, Molecular neurotransmitters pharmacology Phosphatidylinositol 4,5-Diphosphate - metabolism PIP2 plasma membrane potassium channels Potassium Channels, Inwardly Rectifying - agonists Potassium Channels, Inwardly Rectifying - chemistry Potassium Channels, Inwardly Rectifying - metabolism Protein Conformation protein structure Signaling lipid Structure-Activity Relationship
Title	Lipid agonism: The PIP2 paradigm of ligand-gated ion channels
URI	https://dx.doi.org/10.1016/j.bbalip.2015.01.011 https://www.ncbi.nlm.nih.gov/pubmed/25633344 https://www.proquest.com/docview/1702087993 https://www.proquest.com/docview/2000323661 https://pubmed.ncbi.nlm.nih.gov/PMC4540326
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