Retrovirus-Mediated Expression of the Galr1 Galanin Receptor: Implication for Efficient Stable Expression of Functional G Protein-Coupled Receptors

Abstract

The rat GalR1 galanin receptor was used as a prototypic G protein-coupled receptor to test the feasibility of heterologous expression in a retrovirus-based system. The system utilizes an independent retroviral vector pMX, a virus-packaging cell line BOSC23 and a pre-B cell line BA/F3 as the host for expression. A polyclonal cell population that expresses high ligand affinity (K_D = 0.18 nM) and high level (7 pmol/mg) of GalR1 was generated within days with no drug sensitivity-based selection. The expression represented a 20-fold increase over the expression level of GalR1 achieved in CHO cells. The affinity of galanin for the expressed receptor was decreased by 19-fold in the presence of GTP-γ-S, suggesting that the expression system can produce active galanin receptor functionally coupled to G proteins. The fast and efficient method to generate stable cell lines and to prepared large quantities of receptors may provide a general application for expression of other G protein-coupled receptors.     

Identification of a neuronal calcium sensor (NCS-1) possibly involved in the regulation of receptor phosphorylation

Abstract

Persistent stimulation of G protein-coupled receptors by agonists leads rapidly to reduced responses, a phenomenon described as desensitization. It involves primarily the phosphorylation of receptor sites by specific kinases of the G protein-coupled receptor kinase (GRK) family. The β-adrenergic receptor kinase 1 (GRK2) desensitizes agonist-activated β₂-adrenergic receptors, whereas rhodopsin kinase (GRK1) phosphorylates and inactivates photon-activated rhodopsin. Little is known about the role of calcium in desensitization. Here we report the characterization of a novel neuronal calcium sensor (NCS) named NCS-1 possibly involved in the regulation of receptor phosphorylation. NCS-1 is a new member of the EF-hand superfamily, which includes calmodulin, troponin C, parvalbumin, and recoverins. By Northern analysis and in situ hybridization, we discovered that NCS-1 is specifically expressed in the central and peripheral nervous systems. Chick NCS-1 has 72% of amino acid identity with Drosophila frequenin, a protein found in the nervous system and at the motor nerve terminals of neuromuscular junctions. By analogy with the reported function for two other members of the NCS family, we discuss whether G protein-coupled receptors or GRKs are the targets of neuronal calcium sensors.     

Minireview: Factors to Consider in the Naming of a G Protein-Coupled Receptor Subtype

Abstract

Receptors that mediate their effects through G proteins are predicted to have a seven transmembrane domain architecture. The last few years have seen a remarkable increase in the cloning of members of this superfamily leading to the identification of many more receptors than previously thought to exist on the basis of differences in agonist and antagonist specificities. This has important implications for nomenclature and classification, especially in view of the difficulty in relating receptors identified through cloning techniques to endogenously expressed receptors. Receptor cloning has also identified important differences in receptors between species raising the question as to whether these should be considered as species homologues or distinct subtypes. It is also becoming increasingly apparent that the pharmacology of this superfamily of receptors is influenced by the nature of the G protein present in the host cell and by alternative splicing of the receptor. The rapid pace of developments in this area necessitate the need for a regular publication summarizing recent developments. In the future, the cloning of G protein-coupled receptors will enable rationalization of the naming of individual receptor subtypes and identification of their inter-relationships.     

A Family of Heptahelical Receptors With Adhesion-Like Domains: A Marriage Between Two Super Families

Abstract

Some G protein-coupled receptors (GPCRs) are regulators of cell adhesion via inside-out effector signaling pathways. Such is the case with leukocyte chemokine receptors which stimulate intracellular second messenger pathways resulting in upregulation of integrin adhesion to ligands present in the extracellular matrix or on opposing cells resulting in chemotaxis and extravasation during immune surveillance. Remarkably, a family of GPCRs has recently been discovered that may themselves be triggered by cell-cell or cell-matrix interactions. Along with a canonical heptahelical membrane-spanning region, these intriguing proteins contain putative cell adhesionlike modules. The evidence to date suggests that they are involved in lymphocyte activation, macrophage biology, synaptic exocytosis and planar polarization during organogenesis.     

Measurement of G protein-coupled receptor surface expression

Abstract

The quantity of G protein-coupled receptors (GPCRs) expressed on the cell surface is an important factor regulating receptor signaling. Maturation, internalization, recycling and degradation together determine the net amount of receptor surface expression. Understanding every aspect of the receptor lifecycle will facilitate the development of therapeutic applications. A number of assays for measuring the surface expression of GPCRs are currently available. This minireview summarizes the currently available assays and their suitability and usage for measuring GPCR surface expression.     

Molecular dynamics study of 4-OH-phenylacetyl-D-Y(Me)FQNRPR-NH2 selectivity to V1a receptor

G protein-coupled receptors relay diverse extracellular signals into cells via a common mechanism, involving activation of cytosol G proteins. The mechanism underlies the actions of ~50% of all drugs. In this work, we focus on simulating three protein–ligand complexes of the neurohypophyseal hormone analog 4-OH-phenylacetyl-D-Y(Me)FQNRPR-NH₂ (I) with the human V1a, V2 and oxytocin receptors. The peptide I is a potent selective V1a receptor antagonist. To obtain relaxed models of the complexes, the following techniques were used: docking of I into the vasopressin V1a, V2 and oxytocin receptor models, optimization of the geometry of the resulting complexes and molecular dynamics in a fully hydrated 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine lipid bilayer. The results of the simulations allow us to draw some conclusions about the ligand selectivity to V1aR.     

G protein-coupled receptor dimers: look like their parents,but act like teenagers!

Abstract

G protein-coupled receptors (GPCRs) represent the largest group of cell surface receptors and an important pharmacological target. Though originally thought to act in a one receptor–one effector fashion, it is now known that these receptors are capable of oligomerization and can function as dimers or higher order oligomers in native tissue. They do not only assemble with identical receptors as homodimers, but also associate with different GPCRs to form heterodimers. We discuss here how heterodimeric GPCRs can assemble, traffic and signal in a manner distinct from their individual receptor components or from homodimers. These receptor pairs are also demonstrated to be regulated by different chaperones, Rabs and scaffolding proteins, further emphasizing their potential as unique targets. We believe in the importance of investigating each GPCR heterodimer as an individual signaling complex, as they appear to act differently from each monomer constituting them. Just as teenagers may resemble their parents and share their genetic makeup, they can still act in a manner that is entirely unique!     

Yeast Ste2 receptors as tools for study of mammalian protein kinases and adaptors involved in receptor trafficking

Background

Mammalian receptors that couple to effectors via heterotrimeric G proteins (e.g., beta ₂-adrenergic receptors) and receptors with intrinsic tyrosine kinase activity (e.g., insulin and IGF-I receptors) constitute the proximal points of two dominant cell signaling pathways. Receptors coupled to G proteins can be substrates for tyrosine kinases, integrating signals from both pathways. Yeast cells, in contrast, display G protein-coupled receptors (e.g., alpha-factor pheromone receptor Ste2) that have evolved in the absence of receptor tyrosine kinases, such as those found in higher organisms. We sought to understand the motifs in G protein-coupled receptors that act as substrates for receptor tyrosine kinases and the functional consequence of such phosphorylation on receptor biology. We expressed in human HEK 293 cells yeast wild-type Ste2 as well as a Ste2 chimera engineered with cytoplasmic domains of the beta₂-adrenergic receptor and tested receptor sequestration in response to activation of the insulin receptor tyrosine kinase.

Results

The yeast Ste2 was successfully expressed in HEK 293 cells. In response to alpha-factor, Ste2 signals to the mitogen-activated protein kinase pathway and internalizes. Wash out of agonist and addition of antagonist does not lead to Ste2 recycling to the cell membrane. Internalized Ste2 is not significantly degraded. Beta₂-adrenergic receptors display internalization in response to agonist (isoproterenol), but rapidly recycle to the cell membrane following wash out of agonist and addition of antagonist. Beta₂-adrenergic receptors display internalization in response to activation of insulin receptors (i.e., cross-regulation), whereas Ste2 does not. Substitution of the cytoplasmic domains of the β₂-adrenergic receptor for those of Ste2 creates a Ste2/beta₂-adrenergic receptor chimera displaying insulin-stimulated internalization.

Conclusion

Chimera composed of yeast Ste2 into which domains of mammalian G protein-coupled receptors have been substituted, when expressed in animal cells, provide a unique tool for study of the regulation of G protein-coupled receptor trafficking by mammalian receptor tyrosine kinases and adaptor proteins.     

A Fluorescent Reporter Assay for the Detection of Ligands Acting Through GI Protein-Coupled Receptors

Abstract

Accompanying the advances in basic biology of G protein-coupled receptors (GPCRs) is the practical need among biopharmaceutical companies for sensitive assays to assess GPCR function, particularly formats that are compatible with high-throughput drug screening. Here we describe a novel cell-based assay format for the high-throughput detection of ligands for G, protein-coupled receptors. Two G_i-GPCRs, μ-opioid receptor (μ-OPR) and 5-hydroxytryptamine receptor la (5HTlaR) are employed as model receptor targets. The key feature of this assay system is the isolation of stable, clonal Chinese hamster ovary (CHO) cell lines that carry three separate expression plasmids: (1) a chimeric G_q/i5 protein (which re-directs a negative G_i-type signal to a positive Gq-type response), (2) a given G_i-GPCR, and (3) a β-lactamase (βla) reporter gene responsive to G_i-GPCR signaling. Cell-based assays built using this format show appropriate rank order of potency among a reference set of receptor agonist and antagonist compounds. Such assays are also robust, reliable, and can be used for industrial-scale applications such as high-throughput screening for drug leads.     

Construction of hypothetical three-dimensional structure of P2Y1 receptor based on Fourier transform analysis

G protein-coupled receptors constitute a large family of homologous transmembrane proteins that represents one of the most important classes of confirmed drug targets. For novel drug discovery, the 3D structure of target protein is indispensable. To construct hypothetical 3D structures of G protein-coupled receptors, several prediction methods have been proposed. But none of the them has confirmed a correct ligand binding site. In this study we constructed the 3D structure of bovine rhodopsin using the prediction method proposed by Donnelly et al., with some modification. We found that our 3D model showed a good agreement with the reported retinal binding site. Using the similar method, we constructed the 3D structure of the P2Y₁ receptor; one of the G protein-coupled receptors, and showed a binding site of an endogenous ligand, ADP, on the basis of the 3D model and in vitro experimental data. These results should be valuable for design of a specific antagonist for P2Y₁ receptor.     

Detecting and minimizing zinc contamination in physiological solutions

Background  

Rat liver endosomes contain activated insulin receptors and downstream signal transduction molecules. We undertook these studies to determine whether endosomes also contain heterotrimeric G proteins that may be involved in signal transduction from G protein-coupled receptors.     

Protease Signaling to G Protein-Coupled Receptors: Implications for Inflammation and Pain

Proteases, like thrombin, trypsin, cathepsins, or tryptase, can signal to cells by cleaving in a specific manner, a family of G protein-coupled receptors, the protease-activated receptors (PARs). Proteases cleave the extracellular N-terminal domain of PARs to reveal tethered ligand domains that bind to and activate the receptors. Recent evidence has supported the involvement of PARs in inflammation and pain. Activation of PAR₁, PAR₂, and PAR₄ either by proteinases or by selective agonists causes inflammation inducing most of the cardinal signs of inflammation: swelling, redness, and pain. Recent studies suggest a crucial role for the different PARs in innate immune response. The role of PARs in the activation of pain pathways appears to be dual. Subinflammatory doses of PAR₂ agonists induce hyperalgesia and allodynia, and PAR₂ activation has been implicated in the generation of inflammatory hyperalgesia. In contrast, subinflammatory doses of PAR₁ or PAR₄ increase nociceptive threshold, inhibiting inflammatory hyperalgesia, thereby acting as analgesic mediators. PARs have to be considered as an additional subclass of G protein-coupled receptors that are active participants to inflammation and pain responses and that could constitute potential novel therapeutic targets.     

Optical biosensor differentiates signaling of endogenous PAR<Subscript>1</Subscript> and PAR<Subscript>2</Subscript> in A431 cells

Background  

Protease activated receptors (PARs) consist of a family of four G protein-coupled receptors. Many types of cells express several PARs, whose physiological significance is mostly unknown.     

Receptor-Operated Calcium Influx Mediated by Protein Tyrosine Kinase Pathways

Abstract

Calcium influx from the extracellular space elicited by activation of heterotrimeric G protein-coupled and heptahelical receptors plays a critical role in transmembrane signal transduction in a wide variety of cell systems. In nonexcitable cells, the precise voltage-independent mechanism by which calcium enters the cell remains unknown. Multiple mechanisms appear to be operating in different cell types (1–3): 1. G protein-operated calcium influx, 2. second messenger-operated calcium influx, 3. capacitative calcium influx, and 4. phosphorylation of calcium channels. Receptor-operated calcium channels have a fundamental role in stimulus-secretion coupling in many different cells, but these channels remain to be purified and cloned. This review proposes that receptor-operated calcium influx is mediated by protein tyrosine kinase pathways. The function of protein tyrosine kinase pathways and their interactions with other receptor-operated calcium influx mechanisms are described.     

Functional characterization of two melanocortin (MC) receptors in lamprey showing orthology to the MC1 and MC4 receptor subtypes

Background  

The melanocortin (MC) receptors have a key role in regulating body weight and pigmentation. They belong to the rhodopsin family of G protein-coupled receptors (GPCRs). The purpose of this study was to identify ancestral MC receptors in agnathan, river lamprey.     

Coupling of dopamine receptors to G proteins: studies with chimeric D2/D3 dopamine receptors

D₂ and D₃ dopamine receptors belong to the superfamily of G protein-coupled receptors; they share a high degree of homology and are structurally similar. However, they differ from each other in their second messenger coupling properties. Previously, we have studied the differential coupling of these receptors to G proteins and found that while D₂ receptor couples only to inhibitory G proteins, D₃ receptor couples also to a stimulatory G protein, Gs. We aimed to investigate the molecular basis of these differences and to determine which domains in the receptor control its coupling to G proteins. For this purpose four chimeras were constructed, each composed of different segments of the original D₂ and D₃ receptors. We have demonstrated that chimeras with a third cytoplasmic loop of D₂ receptor couple to Gi protein in a pattern characteristic of D₂ receptor. On the other hand chimeras containing a third cytoplasmic loop of D₃ receptor have coupling characteristics like those of D₃ receptor, and they couple also to Gs protein. These findings demonstrate that the third cytoplasmic loop determines and accounts for the coupling of dopamine receptors D₂ and D₃ to G proteins.     

The amidated PACAP1–23 fragment is a potent reduced-size neuroprotective agent

BackgroundNeurodegenerative disorders, such as Parkinson's disease (PD), are characterized by neuronal death involving, among other events, mitochondrial dysfunction and excitotoxicity. Along these lines, several attempts have been made to slow this pathology but none have been yet discovered. Based on its capacity to cross the blood-brain barrier and provide neuronal protection in vitro and in vivo, the pituitary adenylate cyclase-activating polypeptide (PACAP) represents a promising lead molecule. Pharmacological studies showed that PACAP interacts with three different G protein-coupled receptors, i.e. PAC1, VPAC1 and VPAC2. However, only PAC1 is associated with neuronal anti-apoptotic actions, whilst VPAC activation might cause adverse effects. In the context of the development of PAC1-selective agonists, PACAP(1−23) (PACAP23) appears as the shortest known PACAP bioactive fragment.MethodsHence, the capacity of this peptide to bind PACAP receptors and protect neuroblastoma cells was evaluated under conditions of mitochondrial dysfunction and glutamate excitotoxicity. In addition, its ability to activate downstream signaling events involving G proteins (Gα_s and Gα_q), EPAC, and calcium was also assessed.ResultsCompared to the endogenous peptide, PACAP23 showed a reduced affinity towards PAC1, although this fragment exerted potent neuroprotection. However, surprisingly, some disparities were observed for PACAP23 signaling compared to full length PACAP, suggesting that downstream signaling related to neuroprotection is distinctly regulated following subtle differences in their PAC1 interactions.ConclusionsAltogether, this study demonstrates the potent neuroprotective action of amidated PACAP23.General significancePACAP23 represents an attractive template for development of shorter PACAP-derived neuroprotective molecules.     

G protein-coupled receptor cross-talk: pivotal roles of protein phosphorylation and protein-protein interactions

G protein-coupled receptors are dynamically regulated. Such regulation is frequently associated with covalent posttranslational modifications, such as phosphorylation, and with regulatory elements. G protein-coupled receptor kinases and casein kinase 1alpha play key roles in agonist-dependent receptor phosphorylations. Cross-talk between different receptors frequently involves second messenger-activated proteins, such as protein kinase C and protein kinase A. There is some evidence indicating that such kinases may not only turn off receptors but also switch their coupling to different G proteins. Receptor tyrosine kinases may phosphorylate and regulate G protein-coupled receptors and recent evidence indicates that other kinases, such as Akt/protein kinase B and phosphoinositide 3-kinase, may participate in such regulations as integrators of signalling.Recent approaches have shed new light on G protein-coupled receptor interactions that provide novel mechanisms of action and regulation. G protein-coupled receptor activities go beyond G proteins and receptors can be partners of exquisitely assembled signalling complexes through molecular bridges composed of multidomain proteins. The possibilities of interaction increase enormously through the diversity of structural and functional domains present in complex proteins, many of them just known as predicted sequences.     

多巴胺受体的cDNA克隆

通过多巴胺受体的5个cDNA克隆,综述和分析了5个多巴胺受体(D₁R-D₅R)的基因结构,在染色体上的定位及其mRNA在中枢脑区的分布;比较了这5个受体cDNA克隆的结构特征和药理学性质.     

Application of photoaffinity crosslinking in determining the interaction between calcitonin and its receptor

Summary Understanding the molecular mechanism underlying how the peptide ligands bind to their receptors with subsequent receptor activation and cellular response is of great long-term value in designing receptor-targeted drugs. This is more difficult for class-II G protein-coupled receptors as only minimal structural data is available and their natural peptide ligands contain a large and diffuse pharmacophore. To address this problem, photoaffinity labeling studies have been developed to identify the spatial proximity between the photophore-modified ligand and its receptor. This minireview looks at the application of this approach in determining the proximal sites between class-II G protein-coupled receptor peptide ligands and their corresponding receptors, including parathyroid hormone, secretin and vasoactive intestinal polypeptide. More specifically, we will highlight interaction sites between positions 19, 16 and 26 of calcitonin with C¹³⁴−K¹⁴¹, and F¹³⁷ and T³⁰ of the receptor, respectively.