Gating properties of girk channels activated by gαo‐ and Gαi‐Coupled Muscarinic m2 Receptors in Xenopus Oocytes: The Role of Receptor Precoupling in RGS Modulation

Zhang, Qingli; Pacheco, Mary A.; Doupnik, Craig A.

doi:10.1113/jphysiol.2002.032151

Cited by 71 publications

(81 citation statements)

References 74 publications

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“…To yield reproducible data, we optimized the assay system, primarily in experiments with expressed M2 receptors. In previous studies, RGS proteins were shown to accelerate the deactivation kinetics of GIRK currents via G␣-mediated GTP hydrolysis, while also increasing the activation rates of GIRK currents (18)(19)(20). Coexpression of RGS4 did indeed result in faster activation and deactivation kinetics in I K,Agonist traces.…”

Section: Resultsmentioning

confidence: 99%

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Probing the role of the cation–π interaction in the binding sites of GPCRs using unnatural amino acids

Torrice¹,

Bower²,

Lester

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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We describe a general application of the nonsense suppression methodology for unnatural amino acid incorporation to probe drugreceptor interactions in functional G protein-coupled receptors (GPCRs), evaluating the binding sites of both the M2 muscarinic acetylcholine receptor and the D2 dopamine receptor. Receptors were expressed in Xenopus oocytes, and activation of a G protein-coupled, inward-rectifying K ؉ channel (GIRK) provided, after optimization of conditions, a quantitative readout of receptor function. A number of aromatic amino acids thought to be near the agonist-binding site were evaluated. Incorporation of a series of fluorinated tryptophan derivatives at W6.48 of the D2 receptor establishes a cation-interaction between the agonist dopamine and W6.48, suggesting a reorientation of W6.48 on agonist binding, consistent with proposed ''rotamer switch'' models. Interestingly, no comparable cationinteraction was found at the aligning residue in the M2 receptor.D2 receptor ͉ fluorination ͉ membrane protein G protein-coupled receptors (GPCRs) represent the largest family of transmembrane receptor proteins in the human genome and constitute a prominent class of targets for the pharmaceutical industry (1-3). Accordingly, they have been studied extensively throughout academia and industry, by using the full range of chemical, biochemical, and biophysical techniques. In recent years, the field has been energized by several high-resolution crystal structures of mammalian GPCRs that build upon the earlier, highly informative structural studies of rhodopsin and bacteriorhodopsin (4-9).The structural snapshots provided by crystallography greatly enhance our understanding of specific receptors but also raise many new issues. Key among these is the extent to which the information from available structures can be extrapolated to the hundreds of other GPCRs. In addition, a key goal in the study of GPCRs-and all receptors-is a description of the interconversions among several structural states that underlie the protein's biological function. It can be a challenging task to deduce a signaling mechanism from static images. As such, structure-function studies, guided by the new structural advances, will remain an important tool in evaluating GPCR function and the nature of drug-receptor interactions in this family.In recent years, unnatural amino acid mutagenesis on ion channels and receptors expressed in Xenopus oocytes has provided a powerful tool for uncovering crucial drug-receptor interactions and signaling mechanisms (10, 11). GPCRs present an especially attractive target for unnatural amino acid mutagenesis, given the importance of the family, the significant pharmacological variations among closely related family members, and the central role of structural rearrangements in their biological function.Incorporating unnatural amino acids into GPCRs, however, presents unique challenges. Most unnatural amino acid mutagenesis studies in eukaryotic cells have focused on ion channels. These studies exploit the exquisite s...

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Section: Resultsmentioning

confidence: 99%

“…1 illustrates the basic protocol. The basal K ϩ current (I K,Basal ) results primarily from the presence of free intracellular G␤␥ (17,18). The agonist-induced current (I K,Agonist ) is measured relative to the basal K ϩ current.…”

Section: Resultsmentioning

confidence: 99%

Probing the role of the cation–π interaction in the binding sites of GPCRs using unnatural amino acids

Torrice¹,

Bower²,

Lester

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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“…In addition to the G protein activation steps, signal termination with GTP hydrolysis by the G␣ subunit and G␤␥ reassociation also impacts the kinetics and amplitude of agonist-activated GIRK currents. The ternary complex consisting of agonist, GPCR, and G protein influences the time course of agonist-elicited GIRK channel currents (3), supporting the notion that isoform composition of different GPCR-G␣ i/o ␤␥ protein-RGS protein-GIRK channel signaling complexes have different kinetic properties that affect their functional output (4). We recently reported notable differences in the gating properties of GIRK channels activated by muscarinic m2 receptors coupled specifically to PTX-insensitive G␣ i isoforms (G␣ i1 , G␣ i2 , or G␣ i3 ) versus G␣ o isoforms (G␣ oA or G␣ oB ) in the Xenopus oocyte system (4).…”

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confidence: 76%

“…The ternary complex consisting of agonist, GPCR, and G protein influences the time course of agonist-elicited GIRK channel currents (3), supporting the notion that isoform composition of different GPCR-G␣ i/o ␤␥ protein-RGS protein-GIRK channel signaling complexes have different kinetic properties that affect their functional output (4). We recently reported notable differences in the gating properties of GIRK channels activated by muscarinic m2 receptors coupled specifically to PTX-insensitive G␣ i isoforms (G␣ i1 , G␣ i2 , or G␣ i3 ) versus G␣ o isoforms (G␣ oA or G␣ oB ) in the Xenopus oocyte system (4). The ACh-elicited activation time course for G␣ o -coupled GIRK currents was ϳ3-fold faster than for G␣ i -coupled GIRK currents, and G␣ o expression was significantly more effective than the G␣ i isoforms at reducing receptor-independent basal GIRK channel activity.…”

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confidence: 76%

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Gβγ-activated Inwardly Rectifying K+ (GIRK) Channel Activation Kinetics via Gαi and Gαo-coupled Receptors Are Determined by Gα-specific Interdomain Interactions That Affect GDP Release Rates

Zhang¹,

Dickson

Doupnik

2004

Journal of Biological Chemistry

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G␤␥-activated inwardly rectifying K؉ (GIRK) channels have distinct gating properties when activated by receptors coupled specifically to G␣ o versus G␣ i subunit isoforms, with G␣ o -coupled currents having ϳ3-fold faster agonist-evoked activation kinetics. To identify the molecular determinants in G␣ subunits mediating these kinetic differences, chimeras were constructed using pertussis toxin (PTX)-insensitive G␣ oA and G␣ i2 mutant subunits (G␣ oA(C351G) and G␣ i2(C352G) ) and examined in PTX-treated Xenopus oocytes expressing muscarinic m2 receptors and Kir3.1/3.2a channels. These experiments revealed that the ␣-helical N-terminal region (amino acids 1-161) and the switch regions of G␣ i2 (amino acids 162-262) both partially contribute to slowing the GIRK activation time course when compared with the G␣ oA(C351G) -coupled response. When present together, they fully reproduce G␣ i2(C352G) -coupled GIRK kinetics. The G␣ i2 C-terminal region (amino acids 263-355) had no significant effect on GIRK kinetics. Complementary responses were observed with chimeras substituting the G␣ o switch regions into the G␣ i2(C352G) subunit, which partially accelerated the GIRK activation rate. The G␣ oA /G␣ i2 chimera results led us to examine an interaction between the ␣-helical domain and the Ras-like domain previously implicated in mediating a 4-fold slower in vitro basal GDP release rate in G␣ i1 compared with G␣ o . Mutations disrupting the interdomain contact in G␣ i2(C352G) at either the ␣D-␣E loop (R145A) or the switch III loop (L233Q/A236H/E240T/ M241T), significantly accelerated the GIRK activation kinetics consistent with the G␣ i2 interdomain interface regulating receptor-catalyzed GDP release rates in vivo. We propose that differences in G␣ i versus G␣ o -coupled GIRK activation kinetics are due to intrinsic differences in receptor-catalyzed GDP release that rate-limit G␤␥ production and is attributed to heterogeneity in G␣ i and G␣ o interdomain contacts.Cardiac and neuronal G␤␥-gated inwardly rectifying K ϩ channels (GIRKs) 1 are activated by G protein-coupled receptors (GPCRs) selectively coupled to pertussis toxin (PTX)-sensitive G␣ i/o ␤␥ proteins (1, 2). The time course for GIRK channel activation elicited by application of receptor agonist can be influenced by the multiple intervening steps of the G protein cycle that begin with agonist binding to the GPCR, and end with G␤␥ binding to the GIRK channel subunits that promote gating transitions to the open state. In addition to the G protein activation steps, signal termination with GTP hydrolysis by the G␣ subunit and G␤␥ reassociation also impacts the kinetics and amplitude of agonist-activated GIRK currents. The ternary complex consisting of agonist, GPCR, and G protein influences the time course of agonist-elicited GIRK channel currents (3), supporting the notion that isoform composition of different GPCR-G␣ i/o ␤␥ protein-RGS protein-GIRK channel signaling complexes have different kinetic properties that affect their functional output (4). We recently repor...

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Collision coupling in the GABA_B receptor–G protein–GIRK signaling cascade

2017

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The signaling cascade comprising the 4‐aminobutyrate(B) receptor (GABABR), G protein and the G protein‐gated K+ channel (GIRK) mediates neuronal inhibition in the brain. Precoupling between components of the pathway (within a permanent macromolecular complex) has been proposed, but this remains debatable. We investigated this mechanism in Xenopus oocytes by varying the expression of the GABABR. Increased expression of GABABR accelerates activation of GIRK by agonist, implying that some of the components in this cascade interact by a classical collision mechanism. We also find that GABABR has a bidirectional effect on the basal activity of the GIRK channel. Our results suggest a complex mechanism of coupling between GABABR and GIRK which involves elements of both precoupling and collision coupling.

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Gating properties of girk channels activated by gα_o‐ and Gα_i‐Coupled Muscarinic m2 Receptors in Xenopus Oocytes: The Role of Receptor Precoupling in RGS Modulation

Cited by 71 publications

References 74 publications

Probing the role of the cation–π interaction in the binding sites of GPCRs using unnatural amino acids

Probing the role of the cation–π interaction in the binding sites of GPCRs using unnatural amino acids

Gβγ-activated Inwardly Rectifying K+ (GIRK) Channel Activation Kinetics via Gαi and Gαo-coupled Receptors Are Determined by Gα-specific Interdomain Interactions That Affect GDP Release Rates

Collision coupling in the GABA_B receptor–G protein–GIRK signaling cascade

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Gating properties of girk channels activated by gαo‐ and Gαi‐Coupled Muscarinic m2 Receptors in Xenopus Oocytes: The Role of Receptor Precoupling in RGS Modulation

Cited by 71 publications

References 74 publications

Probing the role of the cation–π interaction in the binding sites of GPCRs using unnatural amino acids

Probing the role of the cation–π interaction in the binding sites of GPCRs using unnatural amino acids

Gβγ-activated Inwardly Rectifying K+ (GIRK) Channel Activation Kinetics via Gαi and Gαo-coupled Receptors Are Determined by Gα-specific Interdomain Interactions That Affect GDP Release Rates

Collision coupling in the GABAB receptor–G protein–GIRK signaling cascade

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Gating properties of girk channels activated by gα_o‐ and Gα_i‐Coupled Muscarinic m2 Receptors in Xenopus Oocytes: The Role of Receptor Precoupling in RGS Modulation

Collision coupling in the GABA_B receptor–G protein–GIRK signaling cascade