Endogenous Gαq-Coupled Neuromodulator Receptors Activate Protein Kinase A

Yao Chen; Adam J. Granger; Trinh Tran; Jessica L. Saulnier; Alfredo Kirkwood; Bernardo L. Sabatini

doi:10.1016/j.neuron.2017.10.023

Endogenous Gαq-Coupled Neuromodulator Receptors Activate Protein Kinase A

Yao Chen, Adam J. Granger, Trinh Tran, Jessica L. Saulnier, Alfredo Kirkwood, Bernardo L. Sabatini

School of Medicine

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

20 Scopus citations

Abstract

Protein kinase A (PKA) integrates inputs from G-protein-coupled neuromodulator receptors to modulate synaptic and cellular function. Gαs signaling stimulates PKA activity, whereas Gαi inhibits PKA activity. Gαq, on the other hand, signals through phospholipase C, and it remains unclear whether Gαq-coupled receptors signal to PKA in their native context. Here, using two independent optical reporters of PKA activity in acute mouse hippocampus slices, we show that endogenous Gαq-coupled muscarinic acetylcholine receptors activate PKA. Mechanistically, this effect is mediated by parallel signaling via either calcium or protein kinase C. Furthermore, multiple Gαq-coupled receptors modulate phosphorylation by PKA, a classical Gαs/Gαi effector. Thus, these results highlight PKA as a biochemical integrator of three major types of GPCRs and necessitate reconsideration of classic models used to predict neuronal signaling in response to the large family of Gαq-coupled receptors. Chen et al. show that hippocampal Gαq-coupled muscarinic receptors activate PKA, an effector classically associated with the Gαs/Gαi pathways. The regulation is mediated by parallel signaling via either Ca²⁺ or PKC and generalizes to other endogenous and designer Gαq-coupled receptors.

Original language	English (US)
Pages (from-to)	1070-1083.e5
Journal	Neuron
Volume	96
Issue number	5
DOIs	https://doi.org/10.1016/j.neuron.2017.10.023
State	Published - Dec 6 2017

Keywords

G protein-coupled receptor
Gαq signaling
acetylcholine
designer receptors
fluorescence lifetime imaging microscopy
hippocampus
muscarinic receptors
neuromodulation
optical reporters
protein kinase A

ASJC Scopus subject areas

General Neuroscience

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10.1016/j.neuron.2017.10.023

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title = "Endogenous Gαq-Coupled Neuromodulator Receptors Activate Protein Kinase A",

abstract = "Protein kinase A (PKA) integrates inputs from G-protein-coupled neuromodulator receptors to modulate synaptic and cellular function. Gαs signaling stimulates PKA activity, whereas Gαi inhibits PKA activity. Gαq, on the other hand, signals through phospholipase C, and it remains unclear whether Gαq-coupled receptors signal to PKA in their native context. Here, using two independent optical reporters of PKA activity in acute mouse hippocampus slices, we show that endogenous Gαq-coupled muscarinic acetylcholine receptors activate PKA. Mechanistically, this effect is mediated by parallel signaling via either calcium or protein kinase C. Furthermore, multiple Gαq-coupled receptors modulate phosphorylation by PKA, a classical Gαs/Gαi effector. Thus, these results highlight PKA as a biochemical integrator of three major types of GPCRs and necessitate reconsideration of classic models used to predict neuronal signaling in response to the large family of Gαq-coupled receptors. Chen et al. show that hippocampal Gαq-coupled muscarinic receptors activate PKA, an effector classically associated with the Gαs/Gαi pathways. The regulation is mediated by parallel signaling via either Ca2+ or PKC and generalizes to other endogenous and designer Gαq-coupled receptors.",

keywords = "G protein-coupled receptor, Gαq signaling, acetylcholine, designer receptors, fluorescence lifetime imaging microscopy, hippocampus, muscarinic receptors, neuromodulation, optical reporters, protein kinase A",

author = "Yao Chen and Granger, {Adam J.} and Trinh Tran and Saulnier, {Jessica L.} and Alfredo Kirkwood and Sabatini, {Bernardo L.}",

note = "Funding Information: The authors thank Haining Zhong, S. Dymecki, B. Lowell, K. Deisseroth, and M. During for plasmids; Arpiar Saunders for making the AAV-DFI-Gcamp3.8 plasmid; P. Jonak for assistance with development of image analysis code; Eli Lilly and Company for provision of the 77-LH-28-1 compound; Victoria Caldwell, Wagner Faria Messias, Jackie Birnbaum, and Lauren Chung for assistance; and Jonathan Cohen, Rafael Luna, and members of the Sabatini laboratory for critical comments on the manuscript. This work was supported by grants from the Nancy Lurie Marks Family Foundation ( 6193253-02 to B.L.S.), the Goldenson Fund (to Y.C.), and the NIH ( R01NS046579 to B.L.S., F32DA035543 to Y.C., and P30NS072030 to the Neurobiology Imaging Facility). Publisher Copyright: {\textcopyright} 2017 Elsevier Inc.",

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doi = "10.1016/j.neuron.2017.10.023",

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T1 - Endogenous Gαq-Coupled Neuromodulator Receptors Activate Protein Kinase A

AU - Chen, Yao

AU - Granger, Adam J.

AU - Tran, Trinh

AU - Saulnier, Jessica L.

AU - Kirkwood, Alfredo

AU - Sabatini, Bernardo L.

N1 - Funding Information: The authors thank Haining Zhong, S. Dymecki, B. Lowell, K. Deisseroth, and M. During for plasmids; Arpiar Saunders for making the AAV-DFI-Gcamp3.8 plasmid; P. Jonak for assistance with development of image analysis code; Eli Lilly and Company for provision of the 77-LH-28-1 compound; Victoria Caldwell, Wagner Faria Messias, Jackie Birnbaum, and Lauren Chung for assistance; and Jonathan Cohen, Rafael Luna, and members of the Sabatini laboratory for critical comments on the manuscript. This work was supported by grants from the Nancy Lurie Marks Family Foundation ( 6193253-02 to B.L.S.), the Goldenson Fund (to Y.C.), and the NIH ( R01NS046579 to B.L.S., F32DA035543 to Y.C., and P30NS072030 to the Neurobiology Imaging Facility). Publisher Copyright: © 2017 Elsevier Inc.

PY - 2017/12/6

Y1 - 2017/12/6

N2 - Protein kinase A (PKA) integrates inputs from G-protein-coupled neuromodulator receptors to modulate synaptic and cellular function. Gαs signaling stimulates PKA activity, whereas Gαi inhibits PKA activity. Gαq, on the other hand, signals through phospholipase C, and it remains unclear whether Gαq-coupled receptors signal to PKA in their native context. Here, using two independent optical reporters of PKA activity in acute mouse hippocampus slices, we show that endogenous Gαq-coupled muscarinic acetylcholine receptors activate PKA. Mechanistically, this effect is mediated by parallel signaling via either calcium or protein kinase C. Furthermore, multiple Gαq-coupled receptors modulate phosphorylation by PKA, a classical Gαs/Gαi effector. Thus, these results highlight PKA as a biochemical integrator of three major types of GPCRs and necessitate reconsideration of classic models used to predict neuronal signaling in response to the large family of Gαq-coupled receptors. Chen et al. show that hippocampal Gαq-coupled muscarinic receptors activate PKA, an effector classically associated with the Gαs/Gαi pathways. The regulation is mediated by parallel signaling via either Ca2+ or PKC and generalizes to other endogenous and designer Gαq-coupled receptors.

AB - Protein kinase A (PKA) integrates inputs from G-protein-coupled neuromodulator receptors to modulate synaptic and cellular function. Gαs signaling stimulates PKA activity, whereas Gαi inhibits PKA activity. Gαq, on the other hand, signals through phospholipase C, and it remains unclear whether Gαq-coupled receptors signal to PKA in their native context. Here, using two independent optical reporters of PKA activity in acute mouse hippocampus slices, we show that endogenous Gαq-coupled muscarinic acetylcholine receptors activate PKA. Mechanistically, this effect is mediated by parallel signaling via either calcium or protein kinase C. Furthermore, multiple Gαq-coupled receptors modulate phosphorylation by PKA, a classical Gαs/Gαi effector. Thus, these results highlight PKA as a biochemical integrator of three major types of GPCRs and necessitate reconsideration of classic models used to predict neuronal signaling in response to the large family of Gαq-coupled receptors. Chen et al. show that hippocampal Gαq-coupled muscarinic receptors activate PKA, an effector classically associated with the Gαs/Gαi pathways. The regulation is mediated by parallel signaling via either Ca2+ or PKC and generalizes to other endogenous and designer Gαq-coupled receptors.

KW - G protein-coupled receptor

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KW - acetylcholine

KW - designer receptors

KW - fluorescence lifetime imaging microscopy

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KW - muscarinic receptors

KW - neuromodulation

KW - optical reporters

KW - protein kinase A

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Endogenous Gαq-Coupled Neuromodulator Receptors Activate Protein Kinase A

Abstract

Keywords

ASJC Scopus subject areas

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