Selective activation of Gαob by an adenosine A1 receptor agonist elicits analgesia without cardiorespiratory depression

Wall, Mark J.; Hill, Emily; Huckstepp, Robert; Barkan, Kerry; Deganutti, Giuseppe; Leuenberger, Michele; Preti, Barbara; Winfield, Ian J.; Carvalho, Sabrina do Espirito Santo; Suchankova, Anna; Wei, Haifeng; Safitri, Dewi; Huang, Xianglin; Imlach, Wendy L.; Mache, Circe La; Dean, Eve; Hume, Cherise; Hayward, Stephanie; Oliver, Jess; Zhao, Fengshu; Spanswick, David; Reynolds, Christopher A.; Lochner, Martin; Ladds, Graham; Frenguelli, Bruno G.

doi:10.1038/s41467-022-31652-2

Cited by 37 publications

(45 citation statements)

References 156 publications

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“…BnOCPA has previously been identified as a high-potency A 1 R-selective full agonist. , Using insights from BnOCPA MD simulations , and with the aim of further improving the A 1 R selectivity and potency, we designed extended BnOCPA derivatives 15 – 18 . Their binding and activity at human A 1 R (hA 1 R) were then explored using both a NanoBRET binding assay and a cAMP accumulation assay, respectively (Table ).…”

Section: Resultsmentioning

confidence: 99%

“…13 Subsequently, we demonstrated that BnOCPA was able to specifically activate Gα ob protein subtype-mediated signaling, which translated into potent in vivo analgesia without causing sedation, bradycardia, hypotension, or respiratory depression. 22 Molecular dynamics (MD) simulations using the cryo-EM structure of the active adenosine-bound A 1 R-heterotrimeric G i2 protein complex (PDB code 6D9H 23 ) proposed four binding modes of BnOCPA 22 due to the high flexibility of the N 6 appended benzyloxy group. 24 Based on these molecular modeling studies, we have designed a series of adenosine-and NECA-based compounds with extended N 6 -benzyloxy-and N 6 -phenoxycyclopentyl substituents (Chart 1) with the aim of improving the potency at A 1 R while maintaining or improving the subtype selectivity.…”

Section: ■ Introductionmentioning

confidence: 99%

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Discovery and Structure–Activity Relationship Studies of Novel Adenosine A₁ Receptor-Selective Agonists

et al. 2022

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A series of benzyloxy and phenoxy derivatives of the adenosine receptor agonists N 6 -cyclopentyl adenosine (CPA) and N 6 -cyclopentyl 5′-N-ethylcarboxamidoadenosine (CP-NECA) were synthesized, and their potency and selectivity were assessed. We observed that the most potent were the compounds with a halogen in the meta position on the aromatic ring of the benzyloxy-or phenoxycyclopentyl substituent. In general, the NECA-based compounds displayed greater A 1 R selectivity than the adenosine-based compounds, with N 6 -2-(3-bromobenzyloxy)cyclopentyl-NECA and N 6 -2-(3-methoxyphenoxy)cyclopentyl-NECA showing ∼1500fold improved A 1 R selectivity compared to NECA. In addition, we quantified the compounds' affinity and kinetics of binding at both human and rat A 1 R using a NanoBRET binding assay and found that the halogen substituent in the benzyloxy-or phenoxycyclopentyl moiety seems to confer high affinity for the A 1 R. Molecular modeling studies suggested a hydrophobic subpocket as contributing to the A 1 R selectivity displayed. We believe that the identified selective potent A 1 R agonists are valuable tool compounds for adenosine receptor research.

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Section: Resultsmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Discovery and Structure–Activity Relationship Studies of Novel Adenosine A₁ Receptor-Selective Agonists

et al. 2022

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“…Optimized sensors consisting of Gα-Rluc8 and Gβɣ-GFP2 were developed for all non-visual G proteins, with the exception of G olf and G 14 , and included the first sensors for G 15 and G gust (Olsen et al, 2020). TRUPATH has since been employed to assess the G protein activation profile of a number of GPCRs (Knight et al, 2021; Lieb et al, 2021; Singh, Senatorov, Cheshmehkani, Karmokar, & Moniri, 2022; Voss, Mahardhika, Inoue, & Müller, 2022; Wall et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Pleiotropic signalling has been documented for numerous GPCRs (Avet et al, 2022; Hauser et al, 2022; Knight et al, 2021; Lieb et al, 2021; Olsen et al, 2020; Singh et al, 2022; Voss et al, 2022; Wall et al, 2022). Class B1 GPCRs, for example, are classically considered Gα s- coupled GPCRs but have now been demonstrated to consistently exhibit secondary G protein coupling (Wootten et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

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Cancer-Associated Mutations Enhance The Sensitivity Of The Trupath Gα_Q/11 System

Safitri

Harris

Pearce

et al. 2022

Preprint

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G protein-coupled receptors (GPCRs) are the largest family of cell surface receptors and are a common drug target. They can be stabilised in different conformational states by ligands to activate multiple transducers and effectors leading to a variety of cellular responses. The potential of agonists to activate select pathways has important implications for drug discovery. Thus, there is a clear need to profile the initial GPCR signal transduction event, activation of G proteins, to enhance understanding of receptor coupling and guide drug design. The BRET-based biosensor suite, TRUPATH, was recently developed to enable quantification of the activation profiles of all non-visual G proteins (excluding Golf and G14) and has since been utilised in numerous studies. However, it fails to detect Gq/11 activation for a number of GPCRs previously reported to display promiscuous secondary coupling to Gq/11. Here we report modifications to the Gαq and Gα11 biosensors in the switch I region that prevent intrinsic GTPase activity (R183C/Q). Except for the PAC1R, substitution with cancer-associated mutations, Cys or Gln, significantly increased sensitivity to allow detection of robust, reliable, and representative Gq/11 responses to Class B1 GPCRs. We also demonstrate the utility of these modified biosensors for promiscuously coupled class A GPCR that have primary Gs-coupling. Thus, we propose that modification to Gαq/11 may also be necessary in other biosensor systems to enable detection of Gq/11 activation.

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Species dependence of A3 adenosine receptor pharmacology and function

Gao

Auchampach

Jacobson

2022

Purinergic Signalling

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Efforts to fully understand pharmacological differences between G protein-coupled receptor (GPCR) species homologues are generally not pursued in detail during the drug development process. To date, many GPCRs that have been successfully targeted are relatively well-conserved across species in amino acid sequence and display minimal variability of biological effects. However, the A 3 adenosine receptor (AR), an exciting drug target for a multitude of diseases associated with tissue injury, ischemia, and inflammation, displays as little as 70% sequence identity among mammalian species (e.g., rodent vs. primate) commonly used in drug development. Consequently, the pharmacological properties of synthetic A 3 AR ligands vary widely, not only in binding affinity, selectivity, and signaling efficacy, but to the extent that some function as agonists in some species and antagonists in others. Numerous heterocyclic antagonists that have nM affinity at the human A 3 AR are inactive or weakly active at the rat and mouse A 3 ARs. Positive allosteric modulators, including the imidazo [4,5-c]quinolin-4-amine derivative LUF6000, are only active at human and some larger animal species that have been evaluated (rabbit and dog), but not rodents. A 3 AR agonists evoke systemic degranulation of rodent, but not human mast cells. The rat A 3 AR undergoes desensitization faster than the human A 3 AR, but the human homologue can be completely re-sensitized and recycled back to the cell surface. Thus, comprehensive pharmacological evaluation and awareness of potential A 3 AR species differences are critical in studies to further understand the basic biological functions of this unique AR subtype. Recombinant A 3 ARs from eight different species have been pharmacologically characterized thus far. In this review, we describe in detail current knowledge of species differences in genetic identity, G protein-coupling, receptor regulation, and both orthosteric and allosteric A 3 AR pharmacology.

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Selective activation of Gαob by an adenosine A1 receptor agonist elicits analgesia without cardiorespiratory depression

Cited by 37 publications

References 156 publications

Discovery and Structure–Activity Relationship Studies of Novel Adenosine A₁ Receptor-Selective Agonists

Discovery and Structure–Activity Relationship Studies of Novel Adenosine A₁ Receptor-Selective Agonists

Cancer-Associated Mutations Enhance The Sensitivity Of The Trupath Gα_Q/11 System

Species dependence of A3 adenosine receptor pharmacology and function

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Selective activation of Gαob by an adenosine A1 receptor agonist elicits analgesia without cardiorespiratory depression

Cited by 37 publications

References 156 publications

Discovery and Structure–Activity Relationship Studies of Novel Adenosine A1 Receptor-Selective Agonists

Discovery and Structure–Activity Relationship Studies of Novel Adenosine A1 Receptor-Selective Agonists

Cancer-Associated Mutations Enhance The Sensitivity Of The Trupath GαQ/11 System

Species dependence of A3 adenosine receptor pharmacology and function

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Product

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Discovery and Structure–Activity Relationship Studies of Novel Adenosine A₁ Receptor-Selective Agonists

Discovery and Structure–Activity Relationship Studies of Novel Adenosine A₁ Receptor-Selective Agonists

Cancer-Associated Mutations Enhance The Sensitivity Of The Trupath Gα_Q/11 System