Luciferase-based GloSensor™ cAMP assay: Temperature optimization and application to cell-based kinetic studies

Extracellular ATP and structurally related molecules potentiate adenosine A2a receptor-stimulated cAMP production

Extracellular ATP has been reported to potentiate signalling by several Class B G protein-coupled receptors (GPCRs). The adenosine A2a receptor (A2aR) is a Class A GPCR that regulates many physiological processes, and a potential therapeutic target for many diseases. In vivo, A2aR is exposed transiently to extracellular ATP within the cellular microenvironment under both physiological and pathological conditions. The modulating effects of extracellular ATP seen with Class B GPCRs have not previously been investigated in other classes of GPCRs. In the present study, we investigated the effects of extracellular ATP on A2aR signalling. We also studied the actions of similar molecules to explore the structure-activity relationship. Cyclic 3',5'-adenosine monophosphate (cAMP) levels were monitored following agonist-induced receptor activation in cells co-transfected with plasmids encoding A2aR and a luminescent cAMP biosensor. Extracellular ATP increased the potency of both adenosine and selective A2aR agonists by approximately an order of magnitude. In the absence of agonist, ATP did not activate A2aR, arguing against an effect due to ATP metabolism to adenosine. The potentiating effect of ATP was mimicked by other nucleotides and similarly by phosphorylated sugars. Non-phosphorylated sugars produced comparable effects, but higher concentrations were required to do so. This difference in potency implies that the phosphate group is important for modulating A2aR activity. Here, we present the first evidence that A2aR can be positively modulated by extracellular ATP, thus the effect of ATP is not limited to Class B GPCRs.

Extracellular ATP increases agonist potency and reduces latency at class B G protein-coupled receptors

Class B G protein-coupled receptors (GPCRs) are peptide hormone receptors, many of which, such as parathyroid hormone receptor 1, calcitonin receptor (CTR), and corticotropin-releasing factor receptor (CRF1R), are established or emerging therapeutic targets. Previously, we showed that extracellular ATP and related molecules act as positive modulators of parathyroid hormone receptor 1 signaling through an undefined mechanism. Here, we investigated whether ATP enhances signaling by other members of the class B family of GPCRs. Cyclic AMP (cAMP) accumulation was monitored in cells expressing a bioluminescent sensor. Extracellular ATP, which did not induce cAMP accumulation on its own, potentiated agonist-induced cAMP accumulation mediated by CTR, CRF1R, calcitonin receptor-like receptor, pituitary adenylyl cyclase-activating polypeptide receptor 1, and vasoactive intestinal peptide receptors 1 and 2. ATP induced a comparable effect on agonist-stimulated recruitment of β-arrestin to pituitary adenylyl cyclase-activating polypeptide receptor 1. Depending on the receptor and agonist, ATP increased agonist potency by up to 50-fold. The enhancing effect of ATP was mimicked by cytidine 5'-monophosphate, ruling out involvement of purinergic receptors, ATPase activity, or ectokinase activity. For certain receptors (CTR, calcitonin receptor-like receptor + receptor activity-modifying protein 1, and CRF1R), there were temporal lags of up to 30 minutes following agonist application before maximal rates of cAMP accumulation were reached. Lag duration decreased with increasing agonist concentration, suggesting an inverse relationship with receptor occupancy. ATP virtually abolished this temporal lag, even at relatively low agonist concentrations. Thus, ATP both increases the potency of orthosteric agonists at class B GPCRs and reduces latency for adenylyl cyclase activation. SIGNIFICANCE STATEMENT: In addition to acting as a positive modulator of PTH1R signaling, extracellular ATP increases the potency of orthosteric agonists at other class B GPCRs and reduces the latency for adenylyl cyclase activation. Further insight into the precise mechanism of ATP-mediated potentiation of class B GPCR signaling may identify new targets for the development of therapeutic agents aimed at the treatment of endocrine disorders.

Subtle Structural Modifications Spanning from EP4 Antagonism to EP2/EP4 Dual Antagonism: A Novel Class of Thienocyclic-Based Derivatives

The development of dual prostaglandin E2 receptors 2/4 (EP2/EP4) antagonists represents an attractive strategy for cancer immunotherapy. Herein, a series of 4,7-dihydro-5H-thieno[2,3-c]pyran derivatives with potent EP2/EP4 dual antagonism were discovered by fine-tuned structural modifications. The biphenyl side chain was found to be the key pharmacophore for the transition from EP4 antagonism to EP2/EP4 dual antagonism. The introduction of large sterically hindered segments posed challenges on obtaining EP2 potency, while having minimal impact on EP4 potency. Molecular dynamics simulations verified that the EP2 pocket is relatively narrow compared to EP4, and the key residues surrounding the EP2 pocket impose spatial restrictions on the entry of antagonists. Representative compound 29 (CZY-1068) significantly reduced PGE2-induced expression of immunosuppression-related genes in macrophages. Notably, compound 29 elicited robust antitumor efficacy in the syngeneic MC38 tumor model. Taken together, this study provides a proof-of-concept for obtaining novel potent dual EP2/EP4 antagonists based on rational structural modifications.

Exploiting Cell-Based Assays to Accelerate Drug Development for G Protein-Coupled Receptors

G protein-coupled receptors (GPCRs) are relevant targets for health and disease as they regulate various aspects of metabolism, proliferation, differentiation, and immune pathways. They are implicated in several disease areas, including cancer, diabetes, cardiovascular diseases, and mental disorders. It is worth noting that about a third of all marketed drugs target GPCRs, making them prime pharmacological targets for drug discovery. Numerous functional assays have been developed to assess GPCR activity and GPCR signaling in living cells. Here, we review the current literature of genetically encoded cell-based assays to measure GPCR activation and downstream signaling at different hierarchical levels of signaling, from the receptor to transcription, via transducers, effectors, and second messengers. Singleplex assay formats provide one data point per experimental condition. Typical examples are bioluminescence resonance energy transfer (BRET) assays and protease cleavage assays (e.g., Tango or split TEV). By contrast, multiplex assay formats allow for the parallel measurement of multiple receptors and pathways and typically use molecular barcodes as transcriptional reporters in barcoded assays. This enables the efficient identification of desired on-target and on-pathway effects as well as detrimental off-target and off-pathway effects. Multiplex assays are anticipated to accelerate drug discovery for GPCRs as they provide a comprehensive and broad identification of compound effects.

Association of Neurokinin-1 Receptor Signaling Pathways with Cancer

BACKGROUND

Numerous biochemical reactions leading to altered cell proliferation cause tumorigenesis and cancer treatment resistance. The mechanisms implicated include genetic and epigenetic changes, modified intracellular signaling, and failure of control mechanisms caused by intrinsic and extrinsic factors alone or combined. No unique biochemical events are responsible; entangled molecular reactions conduct the resident cells in a tissue to display uncontrolled growth and abnormal migration. Copious experimental research supports the etiological responsibility of NK-1R (neurokinin-1 receptor) activation, alone or cooperating with other mechanisms, in cancer appearance in different tissues. Consequently, a profound study of this receptor system in the context of malignant processes is essential to design new treatments targeting NK-1R-deviated activity.

METHODS

This study reviews and discusses recent literature that analyzes the main signaling pathways influenced by the activation of neurokinin 1 full and truncated receptor variants. Also, the involvement of NK-1R in cancer development is discussed.

CONCLUSION

NK-1R can signal through numerous pathways and cross-talk with other receptor systems. The participation of override or malfunctioning NK-1R in malignant processes needs a more precise definition in different types of cancers to apply satisfactory and effective treatments. A long way has already been traveled: the current disposal of selective and effective NK-1R antagonists and the capacity to develop new drugs with biased agonistic properties based on the receptor's structural states with functional significance opens immediate research action and clinical application.

Phosphorylation Sites of the Gastric Inhibitory Polypeptide Receptor (GIPR) Revealed by Trapped-Ion-Mobility Spectrometry Coupled to Time-of-Flight Mass Spectrometry (TIMS-TOF MS)

The gastric inhibitory polypeptide receptor (GIPR), a G protein-coupled receptor (GPCR) that regulates glucose metabolism and insulin secretion, is a target for the development of therapeutic agents to address type 2 diabetes and obesity. Signal transduction processes mediated by GPCR activation typically result in receptor phosphorylation, but very little is known about GIPR phosphorylation. Mass spectrometry (MS) is a powerful tool for detecting phosphorylation and other post-translational modifications of proteins and for identifying modification sites. However, applying MS methods to GPCRs is challenging because the native expression levels are low and the hydrophobicity of these proteins complicates isolation and enrichment. Here we use a widely available technique, trapped-ion-mobility spectrometry coupled to time-of-flight mass spectrometry (TIMS-TOF MS), to characterize the phosphorylation status of the GIPR. We identified eight serine residues that are phosphorylated, one in an intracellular loop and the remainder in the C-terminal domain. Stimulation with the native agonist GIP enhanced phosphorylation at four of these sites. For comparison, we evaluated tirzepatide (TZP), a dual agonist of the glucagon-like peptide-1 (GLP-1) receptor and the GIPR that has recently been approved for the treatment of type 2 diabetes. Stimulation with TZP enhanced phosphorylation at the same four sites that were enhanced with GIP; however, TZP also enhanced phosphorylation at a fifth site that is unique to this synthetic agonist. This work establishes an important and accessible tool for the characterization of signal transduction via the GIPR and reveals an unanticipated functional difference between GIP and TZP.

Recognition of methamphetamine and other amines by trace amine receptor TAAR1

Trace amine-associated receptor 1 (TAAR1), the founding member of a nine-member family of trace amine receptors, is responsible for recognizing a range of biogenic amines in the brain, including the endogenous β-phenylethylamine (β-PEA)1 as well as methamphetamine2, an abused substance that has posed a severe threat to human health and society3. Given its unique physiological role in the brain, TAAR1 is also an emerging target for a range of neurological disorders including schizophrenia, depression and drug addiction2,4,5. Here we report structures of human TAAR1-G-protein complexes bound to methamphetamine and β-PEA as well as complexes bound to RO5256390, a TAAR1-selective agonist, and SEP-363856, a clinical-stage dual agonist for TAAR1 and serotonin receptor 5-HT1AR (refs. 6,7). Together with systematic mutagenesis and functional studies, the structures reveal the molecular basis of methamphetamine recognition and underlying mechanisms of ligand selectivity and polypharmacology between TAAR1 and other monoamine receptors. We identify a lid-like extracellular loop 2 helix/loop structure and a hydrogen-bonding network in the ligand-binding pockets, which may contribute to the ligand recognition in TAAR1. These findings shed light on the ligand recognition mode and activation mechanism for TAAR1 and should guide the development of next-generation therapeutics for drug addiction and various neurological disorders.

Encystation stimuli sensing is mediated by adenylate cyclase AC2-dependent cAMP signaling in Giardia

Protozoan parasites use cAMP signaling to precisely regulate the place and time of developmental differentiation, yet it is unclear how this signaling is initiated. Encystation of the intestinal parasite Giardia lamblia can be activated by multiple stimuli, which we hypothesize result in a common physiological change. We demonstrate that bile alters plasma membrane fluidity by reducing cholesterol-rich lipid microdomains, while alkaline pH enhances bile function. Through depletion of the cAMP producing enzyme Adenylate Cyclase 2 (AC2) and the use of a newly developed Giardia-specific cAMP sensor, we show that AC2 is necessary for encystation stimuli-induced cAMP upregulation and activation of downstream signaling. Conversely, over expression of AC2 or exogenous cAMP were sufficient to initiate encystation. Our findings indicate that encystation stimuli induce membrane reorganization, trigger AC2-dependent cAMP upregulation, and initiate encystation-specific gene expression, thereby advancing our understanding of a critical stage in the life cycle of a globally important parasite.

Effects of Replacing a Central Glycine Residue in GLP-1 on Receptor Affinity and Signaling Profile

Agonists of the glucagon-like peptide-1 receptor (GLP-1R) are used to treat diabetes and obesity. Cryo-EM structures indicate that GLP-1 is completely α-helical when bound to the GLP-1R. The mature form of this hormone, GLP-1(7-36), contains a glycine residue near the center (Gly22). Since glycine has the second-lowest α-helix propensity among the proteinogenic α-amino acid residues, and Gly22 does not appear to make direct contact with the receptor, we were motivated to explore the impact on agonist activity of altering the α-helix propensity at this position. We examined GLP-1 analogues in which Gly22 was replaced with L-Ala, D-Ala, or β-amino acid residues with varying helix propensities. The results suggest that the receptor is reasonably tolerant of variations in helix propensity, and that the functional receptor-agonist complex may comprise a conformational spectrum rather than a single fixed structure.

Location-biased activation of the proton-sensor GPR65 is uncoupled from receptor trafficking

The canonical view of G protein-coupled receptor (GPCR) function is that receptor trafficking is tightly coupled to signaling. GPCRs remain on the plasma membrane (PM) at the cell surface until they are activated, after which they are desensitized and internalized into endosomal compartments. This canonical view presents an interesting context for proton-sensing GPCRs because they are more likely to be activated in acidic endosomal compartments than at the PM. Here, we show that the trafficking of the prototypical proton-sensor GPR65 is fully uncoupled from signaling, unlike that of other known mammalian GPCRs. GPR65 internalizes and localizes to early and late endosomes, from where they signal at steady state, irrespective of extracellular pH. Acidic extracellular environments stimulate receptor signaling at the PM in a dose-dependent manner, although endosomal GPR65 is still required for a full signaling response. Receptor mutants that were incapable of activating cAMP trafficked normally, internalize and localize to endosomal compartments. Our results show that GPR65 is constitutively active in endosomes, and suggest a model where changes in extracellular pH reprograms the spatial pattern of receptor signaling and biases the location of signaling to the cell surface.

Development and application of potency assays based on genetically modified cells for biological products

Potency assays are key to the development, registration, and quality control of biological products. Although previously preferred for clinical relevance, in vivo bioassays have greatly diminished with the advent of dependent cell lines as well as due to ethical concerns. However, for some products, the development of in vitro cell-based assay is challenging, or existing method has limitations such as tedious procedure or low sensitivity. The generation of genetically modified (GM) cell line with improved response to the analyte provides a scientific and promising solution. Potency assays based on GM cell lines are currently used for the quality control of biological products including cytokines, hormones, therapeutic antibodies, vaccines and gene therapy products. In this review, we have discussed the general principles of designing and developing GM cells-based potency assays, including identification of cellular signaling pathways and detectable biological effects, generation of responsive cell lines and constitution of test systems, based on the current research progress. In addition, the applications of some novel technologies and the common concerns regarding GM cells have also been discussed. The research presented in this review provides insights for the development and application of novel GM cells-based potency assays for biological products.

Encystation stimuli sensing mediated by adenylate cyclase AC2-dependent cAMP signaling in Giardia

Protozoan parasites use cAMP signaling to precisely regulate the place and time of developmental differentiation, yet it is unclear how this signaling is initiated. Encystation of the intestinal parasite Giardia lamblia can be activated by multiple stimuli, which we hypothesize result in a common physiological change. We demonstrate that bile alters plasma membrane fluidity by reducing cholesterol-rich lipid microdomains, while alkaline pH enhances bile function. Through depletion of the cAMP producing enzyme Adenylate Cyclase 2 (AC2) and the use of a newly developed Giardia-specific cAMP sensor, we show that AC2 is necessary for encystation stimuli-induced cAMP upregulation and activation of downstream signaling. Conversely, over expression of AC2 or exogenous cAMP were sufficient to initiate encystation. Our findings indicate that encystation stimuli induce membrane reorganization, trigger AC2-dependent cAMP upregulation, and initiate encystation-specific gene expression, thereby advancing our understanding of a critical stage in the life cycle of a globally important parasite.

Compartment-Specific Activation of the Proton-Sensor GPR65 is Uncoupled from Receptor Trafficking

The canonical view of G protein-coupled receptor (GPCR) function is that receptor trafficking is tightly coupled to signaling. GPCRs remain on the plasma membrane (PM) at the cell surface until they are activated, after which they are desensitized and internalized into endosomal compartments. This canonical view presents an interesting context for proton-sensing GPCRs because they are more likely to be activated in acidic endosomal compartments than at the PM. Here we show that the trafficking of the prototypical proton-sensor GPR65 is fully uncoupled from signaling, unlike that of other known mammalian GPCRs. GPR65 internalized and localized to early and late endosomes, from where they signal at steady state, irrespective of extracellular pH. Acidic extracellular environments stimulated receptor signaling at the PM in a dose-dependent manner, although endosomal GPR65 was still required for a full signaling response. Receptor mutants that were incapable of activating cAMP trafficked normally, internalized, and localized to endosomal compartments. Our results show that GPR65 is constitutively active in endosomes, and suggest a model where changes in extracellular pH reprograms the spatial pattern of receptor signaling and biases the location of signaling to the cell surface.

Modified Akuamma Alkaloids with Increased Potency at the Mu-opioid Receptor

Akuammine (1) and pseudoakuammigine (2) are indole alkaloids found in the seeds of the akuamma tree (Picralima nitida). Both alkaloids are weak agonists of the mu opioid receptor (μOR); however, they produce minimal effects in animal models of antinociception. To probe the interactions of 1 and 2 at the opioid receptors, we have prepared a collection of 22 semisynthetic derivatives. Evaluation of this collection at the μOR and kappa opioid receptor (κOR) revealed structural-activity relationship trends and derivatives with improved potency at the μOR. Most notably, the introduction of a phenethyl moiety to the N1 of 2 produces a 70-fold increase in potency and a 7-fold increase in selectivity for the μOR. The in vitro potency of this compound resulted in increased efficacy in the tail-flick and hot-plate assays of antinociception. The improved potency of these derivatives highlights the promise of exploring natural product scaffolds to probe the opioid receptors.