Project description:Biased G protein-coupled receptor agonists engender a restricted repertoire of downstream events from their cognate receptors, permitting them to produce mixed agonist-antagonist effects in vivo. While this opens the possibility of novel therapeutics, it complicates rational drug design, since the in vivo response to a biased agonist cannot be reliably predicted from its in vitro efficacy. We have employed novel informatic approaches to characterize the in vivo transcriptomic signature of the arrestin pathway-selective parathyroid hormone analog [D-Trp12, Tyr34]-bPTH(7-34) in six different murine tissues after chronic drug exposure. We find that [D-Trp12, Tyr34]-bPTH(7-34) elicits a distinctive arrestin-signaling focused transcriptomic response that is more coherently regulated across tissues than that of the pluripotent agonist, hPTH(1-34). This arrestin-focused network is closely associated with transcriptional control of cell growth and development. Our demonstration of a conserved arrestin-dependent transcriptomic signature suggests a framework within which the in vivo outcomes of arrestin-biased signaling may be generalized.

Project description:Angiotensin II type 1 receptors (AT1Rs) are one of the most widely studied G protein-coupled receptors. To fully appreciate the diversity in cellular signaling profiles activated by AT1R transducer-biased ligands, we utilized peroxidase-catalyzed proximity labeling to capture proteins in close proximity to AT1Rs in response to six different ligands: Angiotensin II (full agonist), S1I8 (partial agonist), TRV055 and TRV056 (G protein-biased agonists), TRV026 and TRV027 (β-arrestin biased agonists) at 90s, 10min, and 60min after stimulation. We systematically analyzed the kinetics of AT1R trafficking and determined that distinct ligands lead AT1R to different cellular compartments for downstream signaling activation and receptor degradation/recycling. Distinct proximity labelling of proteins from a number of functional classes, including GTPases, adaptor proteins, and kinases were activated by different ligands suggesting unique signaling and physiological roles of the AT1R. Ligands within the same class, i.e. either G protein-biased or -arrestin-biased, shared high similarity in their labelling profiles. Comparison between ligand classes revealed distinct signaling activation such as greater labeling by G protein biased ligands on ESCRT-0 complex proteins that act as sorting machinery for ubiquitinated proteins. Our study provides a comprehensive analysis of AT1R receptor trafficking kinetics and signaling activation profiles induced by distinct classes of ligands.

Project description:Chemokine receptors (CKRs), a class of G protein-coupled receptors (GPCRs), interact with transducers like G proteins and β-arrestins. Many chemokines act as “biased agonists” that activate certain transducers over others. There has been limited success in pharmacologically targeting CKRs, with little evidence that differential receptor phosphorylation, or “phosphorylation barcodes,” direct biased responses. Here, we used mass spectrometry to demonstrate that CXCR3 chemokines generate different phosphorylation barcodes associated with differential activation of transducers. Chemokine stimulation resulted in distinct changes throughout the kinome in global phosphoproteomic studies. Mutation of CXCR3 phosphosites altered β-arrestin conformation and activation in molecular dynamics simulations. T-cells expressing phosphorylation-deficient CXCR3 mutants resulted in agonist- and receptor-specific chemotactic profiles not completely explained by engagement of G proteins and β-arrestins. Our results demonstrate that CXCR3 chemokines act as biased agonists through differential encoding of phosphorylation barcodes, and highlight the limitations of assessing GPCR physiology with proximal effector activity alone.

Project description:G protein-coupled receptors (GPCRs) are typically characterized by their seven transmembrane (7TM) architecture, and interaction with two universal signal-transducers namely, the heterotrimeric G-proteins and β-arrestins (βarrs). Synthetic ligands and receptor mutants have been designed to elicit transducer-coupling preferences and distinct downstream signaling outcomes for many GPCRs. This raises the question if some naturally-occurring 7TMRs may selectively engage one of these two signal-transducers, even in response to their endogenous agonists. Although there are scattered hints in the literature that some 7TMRs lack G-protein coupling but interact with βarrs, an in-depth understanding of their transducer-coupling preference, GRK-engagement, downstream signaling and structural mechanism remains elusive. Here, we use an array of cellular, biochemical and structural approaches to comprehensively characterize two non-canonical 7TMRs namely, the human decoy D6 receptor (D6R) and the human complement C5a receptor (C5aR2), in parallel with their canonical GPCR counterparts, CCR2 and C5aR1, respectively. We discover that D6R and C5aR2 couple exclusively to βarrs, exhibit distinct GRK-preference, and activate non-canonical downstream signaling partners. We also observe that βarrs, in complex with these receptors, adopt distinct conformations compared to their canonical GPCR counterparts despite being activated by a common natural agonist. Our study therefore establishes D6R and C5aR2 as bona-fide arrestin-coupled receptors (ACRs), and provides important insights into their regulation by GRKs and downstream signaling with direct implications for biased agonism.

Project description:Structural studies have recently shown that mechanism of selective AT1R activation by different classes of ligands is initiated by the ability of ligands to stabilize unique active conformations of the receptor. Active conformations enhance transducer coupling leading to effector mediated signaling, that has been proposed to be linked to differential phosphorylation of the c-terminal tail of the receptor. To determine how different classes of AT1R ligands effect receptor phosphorylation and activation of downstream signaling we used TMT-MS to identify the amino acid residues of the AT1R phosphorylated following treatment with the full balanced agonist Angiotensin II and a β-arrestin biased ligand, TRV023. Here we show that Ang and TRV 023 induce two distinct patterns of phosphorylation clusters a.a. residues along the entire c-tail with AngII inducing a greater magnitude than the β-arrestin biased ligand TRV 023, particularly in the proximal part of the tail. Selective mutagenesis of Ser and Thr residues, we found that of the 12 Ser/Thr residues within the c-tail, only the 4 proximal and 4 middle residues are all required for full β -arrestin functionality in response to either a balanced or β-arrestin-based ligand. Surprisingly, phosphorylation of 4 residues in the proximal c-tail is necessary for maximal G-protein activation to a full agonist. Taken together our data demonstrate that a AT1R ligands that stabilize different active confirmations of the receptor (full agonist vs. β-arrestin biased) induce distinct phosphorylation patterns on the c-tail of the receptor to evoke distinct receptor-transducer engagement and downstream receptor trafficking and signaling.

Project description:Delineation of a conserved arrestin-biased signaling repertoire in vivo

Project description:The microbiota generates diverse metabolites to modulate host physiology and disease, but their protein targets and mechanisms of action have not been fully elucidated. To address this challenge, we focused on microbiota-derived indole metabolites and develop photoaffinity chemical probes for proteomic studies. We identified many potential indoleinteracting proteins, including metabolic enzymes, transporters, immune sensors, and Gprotein coupled receptors. Notably, we discovered aromatic monoamines can activate - arrestin recruitment by the orphan receptor GPRC5A. Metabolomic and functional profiling of microbiota species revealed specific aromatic amino acid decarboxylaseexpressing bacteria producing monoamine agonists for GPRC5A. Structure-activity relationship studies of synthetic aromatic monoamines identified 7-fluorotryptamine as a more potent activator of -arrestin recruitment by GPRC5A. Our results highlight the utility of chemoproteomics to identify novel microbiota metabolite-interacting proteins and discover potential microbiota-derived small molecule agonists for orphan receptors.

Project description:Biased GPCR agonists are orthosteric ligands that possess pathway-selective efficacy, activating or inhibiting only a subset of the signaling repertoire of their cognate receptors. In vitro, D-Trp12,Tyr34-bPTH(7-34) (PTH-{beta}arr), a biased agonist for the type 1 parathyroid hormone receptor, antagonizes receptor-G protein coupling but activates arrestin-dependent signaling. In vivo, both PTH-{beta}arr and the conventional agonist PTH(1-34) stimulate anabolic bone formation. To understand how two PTH1R ligands with markedly different in vitro efficacy could elicit similar in vivo responses, we analyzed transcriptional profiles from calvarial bone of mice treated for 8 weeks with vehicle, PTH-{beta}arr or PTH(1-34). Treatment of wild type mice with PTH-{beta}arr primarily affected pathways that promote expansion of the osteoblast pool, notably cell cycle regulation, cell survival and migration. These responses were absent in beta-arrestin2 null mice, identifying them as downstream targets of beta-arrestin2-mediated signaling. In contrast, PTH(1-34) primarily affected pathways classically associated with enhanced bone formation, including collagen synthesis and matrix mineralization. PTH(1-34) actions were less dependent on beta-arrestin2, as might be expected of a ligand capable of G protein activation. These results illustrate the uniqueness of biased agonism in vivo and demonstrate that functional selectivity can be exploited to change the quality of GPCR efficacy.

Project description:The transcriptional responses of heterotrimeric g-protein mutants of Arabidopsis following treatment with 20uM methyl jasmonate for 6 hours compared to a control treatment

Project description:Obesity is associated with the development of type 2 diabetes. In recent years, incretin analogs are prescribed at a high rate for treatment of obesity and diabetes due to their potent effects on lowering bodyweight and improving glucose homeostasis. However, many patients do not stay on incretin analog therapy and thereby rapidly regain bodyweight. The non-compliance of patients to incretin analog therapy is not only due to drug shortage but also insufficient knowledge on the long-term effects of the therapy. To address this knowledge gap, we examined the effects of incretin analog treatment and withdrawal on adipose tissue functions in high fat diet (HFD)-induced obese mice. Our transcriptome data suggest that incretin analog treatment restored most of obesity-mediated deregulated gene expression in adipose tissue. However, genes encoding lipogenic enzymes, downregulated by HFD, were not restored by incretin analog treatment. Interestingly, a dietary intervention with normal chow diet (ND) feeding, but not calorie-matched HFD feeding, restored the expression of lipogenic enzymes. Upon incretin therapy withdrawal, mice displayed rapid bodyweight regain, impaired adipose tissue function, and glucose intolerance. In contrast, a ND intervention following incretin analog therapy withdrawal restored lipogenic gene expression in adipose tissue, maintained glucose homeostasis, and minimized body weight regain. This study revealed the effects of incretin analog therapy and therapy withdrawal on adipose tissue and highlights the importance of the dietary composition during and after incretin analog therapy. Thus, our findings may contribute to the development of long-term therapy guidelines of incretin analog therapy for patients with obesity.