Project description:-arrestins (arr1 and arr2) are ubiquitous regulators of G protein-coupled receptor (GPCR) signalling. Available data suggest that -arrestins dock to different receptors in different ways. However, the structural characterization of arrestin-GPCR complexes is challenging and alternative approaches to study arrestin-GPCR complexes are needed. Here, starting from the finger loop as a major site for the interaction of arrestins with GPCRs, we genetically incorporate non-canonical amino acids for photo- and chemical crosslinking into arr1 and arr2 and explore binding topologies to GPCRs forming either stable or transient complexes with arrestin: the vasopressin receptor 2 (rhodopsin-like), the corticotropin releasing factor receptor 1 and the parathyroid hormone receptor 1 (both secretin-like). We show that each receptor leaves a unique footprint on arrestin, whereas the two -arrestins yield quite similar crosslinking patterns. Furthermore, we show that the method allows defining the orientation of arrestin respect to the GPCR. Finally, we provide direct evidence for the formation of arrestin oligomers in the cell.

Project description:In humans, the 813 G protein-coupled receptors (GPCRs) are responsible for transducing diverse chemical stimuli to alter cell state, and are the largest class of drug targets. Their myriad structural conformations and various modes of signaling make it challenging to understand their structure and function. Here we developed a platform to characterize large libraries of GPCR variants in human cell lines with a barcoded transcriptional reporter of G-protein signal transduction. We tested 7,800 of 7,828 possible single amino acid substitutions to the beta-2 adrenergic receptor (β2AR) at four concentrations of the agonist isoproterenol. We identified residues specifically important for β2AR signaling, mutations in the human population that are potentially loss of function, and residues that modulate basal activity. Using unsupervised learning, we resolve residues critical for signaling, including all major structural motifs and molecular interfaces. We also find a previously uncharacterized structural latch spanning the first two extracellular loops that is highly conserved across Class A GPCRs and is conformationally rigid in both the inactive and active states of the receptor. More broadly, by linking deep mutational scanning with engineered transcriptional reporters, we establish a generalizable method for exploring pharmacogenomics, structure and function across broad classes of drug receptors.

Project description:G-protein coupled receptors (GPCRs) are pivotal in regulating T cell responses in steady state and inflammation. GPCR expression was intensively studied in bulk cDNA of T cell populations, but limited data are available with respect to expression in individual cells. We here present an analysis of a selected set of 125 different GPCRs expressed on distinct single T cells under naive conditions and during experimental autoimmune encephalomyelitis (EAE), the mouse model of multiple sclerosis. We found that neuroinflammation induces characteristic changes in GPCR heterogeneity and patterning, and we identified functionally relevant subgroups with specific GPCR expression profiles among spinal cord-infiltrating CD4 T cells. In spinal cord-infiltrating T helper 17 (Th17) cells, for example, expression of receptors such as Cxcr3, Cxcr4, P2ry10, or S1pr1 was associated with reduced pathogenicity, and we show that these correlations also exists on the protein level. Using CXCR4 and S1P1 as examples, we demonstrate that pharmacological targeting of these receptors is able to modulate Th17 pathogenicity in vitro and in vivo. Taken together, GPCR single-cell expression analysis provides a basis for the development of new strategies for pharmacological modulation of pathogenic immune cell subtypes.

Project description:G-protein coupled receptors (GPCRs) belong to the seven transmembrane receptors superfamily that in response to external stimuli, transduce signals via G proteins to initiate different intracellular signaling pathways which culminate in specific cellular responses. Although in somatic cells the GPCR participate in a broad variety of physiological processes, the expression of diverse GPCRs at the plasma membrane of human spermatozoa suggests their involvement in the regulation of sperm fertility. Mature spermatozoa could present unique features in their molecular mechanisms downstream GPCRs due to the fact that they possess sperm-specific proteins and are transcriptionally and translationally silent. In order to decipher the signaling pathways engaged by this receptor superfamily in human spermatozoa, we selected the kappa-opioid receptor (KOR) as a study model and applied, for first time, phosphoproteomic approach based on TMT labeling and LC-MS/MS analyses combined with functional studies using a specific agonist of KOR, U50488H.

Project description:Trafficking of G protein-coupled receptors (GPCRs) through the endo-lysosomal pathway is critical to homeostatic regulation of GPCRs following activation with agonist. Identifying the genes involved in GPCR trafficking is challenging due to the complexity of sorting operations and low affinity protein-receptor interactions. Here we show that the engineered enzyme APEX2 is a highly sensitive biosensor for GPCR trafficking to the lysosome, and this trafficking can be monitored through APEX-based activation of fluorogenic substrates such as Amplex UltraRed (AUR). We used GPCR-APEX2/AUR to perform a genome-wide CRISPR interference screen focused on the delta type opioid receptor (DOR), a GPCR which modulates anxiety and pain. We provide a genetic map of components in the endo-lysosomal pathway necessary for DOR trafficking to the lysosome and subsequent downregulation. Using our GPCR-APEX2 pipeline, we demonstrate that a gene identified in our screen, DNAJC13, controls trafficking of DOR to the lysosome by regulating the endosomal proteome and endosomal homeostasis.

Project description:Chemokine receptors are GPCRs that regulate chemotactic migration of a wide variety of cells including immune and cancer cells. Most chemokine receptors harbor molecular properties, which are associated with an ability to stimulate G proteins during b-arrestin-mediated internalization into endosomes. As endosomal signaling of certain non-GPCR receptors plays major roles in cell migration, we here investigated the potential role of endosomal chemokine receptor signaling on mechanisms governing this function. Applying cell biological approaches and spatiotemporal-resolved proteome profiling, we demonstrate that the model chemokine receptor CCR7 upon chemokine stimulation recruits G protein and b-arrestin simultaneously enabling internalized receptors to activate G protein from endosomes. Furthermore, endosomal CCR7 uniquely enriches specific Rho-GTPase regulators as compared to plasma membrane CCR7, which correlates with the activity of Rho-GTPase Rac1. As Rac1 drives the formation of membrane protrusions during chemotaxis, our findings suggest an important integrated function of endosomal chemokine receptor signaling in this physiological event.

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:The two non-visual arrestin isoforms, arrestin2 and arrestin3, recognize and bind hundreds of G protein-coupled receptors (GPCRs) with different phosphorylation patterns leading to distinct functional outcomes. Whereas the impact of phosphorylation of the vasopressin 2 receptor and rhodopsin on arrestin interactions has been well studied, much less known for other GPCRs. Here we have characterized the interaction between the phosphorylated CC chemokine receptor 5 (CCR5) and arrestin2. Mass spectrometry and biochemical revealed several new CCR5 phosphorylation sites, which proved essential for the formation of stable complexes with arrestin2. Crystal structures of arrestin2 in apo form and in complexes with two CCR5 C-terminal phosphopeptides revealed three key CCR5 phosphoresidues in a pXpp motif that form extensive interactions with arrestin2 and lead to activation. The same phosphoresidue-cluster is present in other receptors which form stable complexes with arrestin2. The contributions of each CCR5 phosphoresidue on arrestin2 conformation and binding have been characterized by a combination of NMR spectroscopy, biochemical and functional assays. We propose that the identified pXpp motif is responsible for robust arrestin2 recruitment in many GPCRs. Moreover, an analysis of available sequence, structural and functional information on other GPCR arrestin interactions suggests a particular spatial arrangement of phosphoresidues within the GPCR intracellular loops and C-terminal tail determines arrestin2 and 3 isoform specificity.

Project description:G protein coupled receptor (GPCR) signalling covers three major mechanisms. GPCR agonist engagement allows for the G proteins to bind to the receptor leading to a classical downstream signalling cascade. The second mechanism is via the utilization of the β-arrestin signalling molecule and thirdly via transactivation dependent signalling. GPCRs can transactivate protein tyrosine kinase receptors (PTKR) to activate respective downstream signalling intermediates. In the past decade GPCR transactivation dependent signalling was expanded to show transactivation of serine/threonine kinase receptors (S/TKR). Kinase receptor transactivation enormously broadens the GPCR signalling paradigm. This work utilizes next generation RNA-sequencing to study the contribution of transactivation dependent signalling to total protease activated receptor (PAR)-1 signalling. Transactivation, assessed as gene expression, accounted for 50 percent of the total genes regulated by thrombin acting through PAR-1 in human coronary artery smooth muscle cells. GPCR transactivation of PTKRs is approximately equally important as the transactivation of the S/TKR with 209 and 177 genes regulated respectively, via either signalling pathway. This work shows that genome wide studies can provide powerful insights into GPCR mediated signalling pathways

Project description:GPCRs have emerged as crucial regulators of muscle stem cell (MuSC) quiescence, yet the specific repertoire of GPCRs in quiescent MuSCs and the underlying regulatory network remain largely elusive. By employing pharmacological and inducible-genetic methods, we have identified two niche-derived GPCR ligands, endothelin-3 (ET-3) and neurotensin (NT), which bind to EDNRB and NTSR2 receptors, respectively, reinforcing the maintenance of MuSC quiescence. To comprehensively unravel the molecular mechanisms underlying the inhibitory effects of ET-3 and NT on MuSC activation, we conducted RNA sequencing (RNA-seq) analysis on FACS-purified MuSCs that underwent a 5-day in vitro treatment with ET-3 or NT