Niloofar Gopal Pour scite author profile

G protein-coupled receptors (GPCRs) are embedded in phospholipids that strongly influence drug-stimulated signaling. Anionic lipids are particularly important for GPCR signaling complex formation, but a mechanism for this role is not understood. Using NMR spectroscopy, we explore the impact of anionic lipids on the function-related conformational equilibria of the human A2A adenosine receptor (A2AAR) in bilayers containing defined mixtures of zwitterionic and anionic phospholipids. Anionic lipids prime the receptor to form complexes with G proteins through a conformational selection process. Without anionic lipids, signaling complex formation proceeds through a less favorable induced fit mechanism. In computational models, anionic lipids mimic interactions between a G protein and positively charged residues in A2AAR at the receptor intracellular surface, stabilizing a pre-activated receptor conformation. Replacing these residues strikingly alters the receptor response to anionic lipids in experiments. High sequence conservation of the same residues among all GPCRs supports a general role for lipid-receptor charge complementarity in signaling.

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Atomic‐Scale View of Protein‐PEG Interactions that Redirect the Thermal Unfolding Pathway of PEGylated Human Galectin‐3

Pritzlaff

Ferré

Mulry

et al. 2022

Angew Chem Int Ed

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PEGylation is a promising approach to address the central challenge of applying biologics, i.e., lack of protein stability in the demanding environment of the human body. Wider application is hindered by lack of atomic level understanding of protein-PEG interactions, preventing design of conjugates with predicted properties. We deployed an integrative structural and biophysical approach to address this critical challenge with the PEGylated carbohydrate recognition domain of human galectin-3 (Gal3C), a lectin essential for cell adhesion and potential biologic. PEGylation dramatically increased Gal3C thermal stability, forming a stable intermediate and redirecting its unfolding pathway. Structural details revealed by NMR pointed to a potential role of PEG localization facilitated by charged residues. Replacing these residues subtly altered the protein-PEG interface and thermal unfolding behavior, providing insight into rationally designing conjugates while preserving PEGylation benefits.

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Dual mechanisms of cholesterol-GPCR interactions that depend on membrane phospholipid composition

et al. 2023

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Atomic‐Scale View of Protein‐PEG Interactions that Redirect the Thermal Unfolding Pathway of PEGylated Human Galectin‐3

et al. 2022

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PEGylation is a promising approach to address the central challenge of applying biologics, i.e., lack of protein stability in the demanding environment of the human body. Wider application is hindered by lack of atomic level understanding of protein‐PEG interactions, preventing design of conjugates with predicted properties. We deployed an integrative structural and biophysical approach to address this critical challenge with the PEGylated carbohydrate recognition domain of human galectin‐3 (Gal3C), a lectin essential for cell adhesion and potential biologic. PEGylation dramatically increased Gal3C thermal stability, forming a stable intermediate and redirecting its unfolding pathway. Structural details revealed by NMR pointed to a potential role of PEG localization facilitated by charged residues. Replacing these residues subtly altered the protein‐PEG interface and thermal unfolding behavior, providing insight into rationally designing conjugates while preserving PEGylation benefits.

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Anionic Phospholipids Control Mechanisms of GPCR-G Protein Recognition

Thakur

Ray

Sharp

et al. 2023

Preprint

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G protein-coupled receptors (GPCRs) are embedded in phospholipids that strongly influence drug-stimulated signaling. Anionic lipids are particularly important for GPCR signaling complex formation, but a mechanism for this role is not understood. Using NMR spectroscopy, we visualized the impact of anionic lipids on the function-related conformational equilibria of the human A2A adenosine receptor (A2AAR) in bilayers containing defined mixtures of zwitterionic and anionic phospholipids. Anionic lipids primed the receptor to form complexes with G proteins through a conformational selection process. Without anionic lipids, signaling complex formation proceeded through a less favorable induced fit mechanism. In computational models, anionic lipids mimicked interactions between a G protein and positively charged residues in A2AAR at the receptor intracellular surface, stabilizing a pre-activated receptor conformation. Replacing these residues strikingly altered the receptor response to anionic lipids in experiments. High sequence conservation of the same residues among all GPCRs supports a general role for lipid-receptor charge complementarity in signaling.

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Structural basis for regulation of a human GPCR by membrane lipids investigated by NMR spectroscopy

Eddy¹,

Thakur²,

Ray³

et al. 2022

Biophysical Journal

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Regulation of human A2A adenosine receptor conformational dynamics by endogenous phospholipids

Thakur

Ray

Sharp

et al. 2022

Biophysical Journal

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