G protein-coupled receptor allosterism and complexing

G protein-coupled receptors (GPCRs) represent the largest family of cell-surface receptors. These receptors are natural allosteric proteins because agonist-mediated signaling by GPCRs requires a conformational change in the receptor protein transmitted between two topographically distinct binding sites, one for the agonist and another for the G protein. It is now becoming increasingly recognized, however, that the agonist-bound GPCR can also form ternary complexes with other ligands or "accessory" proteins and display altered binding and/or signaling properties in relation to the binary agonist-receptor complex. Allosteric sites on GPCRs represent novel drug targets because allosteric modulators possess a number of theoretical advantages over classic orthosteric ligands, such as a ceiling level to the allosteric effect and a potential for greater GPCR subtype-selectivity. Because of the noncompetitive nature of allosteric phenomena, the detection and quantification of such effects often relies on a combination of equilibrium binding, nonequilibrium kinetic, and functional signaling assays. This review discusses the development and properties of allosteric receptor models for GPCRs and the detection and quantification of allosteric effects. Moreover, we provide an overview of the current knowledge regarding the location of possible allosteric sites on GPCRs and candidate endogenous allosteric modulators. Finally, we discuss the potential for allosteric effects arising from the formation of GPCR oligomers or GPCRs complexed with accessory cellular proteins. It is proposed that the study of allosteric phenomena will become of progressively greater import to the drug discovery process due to the advent of newer and more sensitive GPCR screening technologies.     

GPCR-GIP networks: a first step in the discovery of new therapeutic drugs?

G protein-coupled receptors (GPCRs) are transmembrane molecules that, on interaction with G proteins upon ligand binding, can associate with a large variety of transmembrane or soluble proteins, termed 'GPCR-interacting proteins' (GIPs). Some special transmembrane GIPs are themselves GPCRs that form homo- or heterodimers, while other transmembrane GIPs are ionic channels, ionotropic receptors and single transmembrane proteins that control GPCR pharmacology and trafficking. Most soluble GIPs interact with the C-termini of GPCRs and often physically link GPCRs to large protein networks, called 'receptosomes', that include ionic channels, protein kinases, small G proteins, cytoskeletal proteins and adhesion molecules. Here, we review the nature and functions of some of these networks, such as the glutamate and serotonin receptosomes, and focus on the fine-tuning of GPCR signaling by GIPs. Finally, we discuss the possibilities for developing new therapeutic drugs capable of modulating GPCR signaling by disrupting or reinforcing specific GPCR-GIP interactions.     

Regulation of G protein-coupled receptor function by Na+/H+ exchange regulatory factors

Many G protein-coupled receptors (GPCR) exert patterns of cell-specific signaling and function. Mounting evidence now supports the view that cytoplasmic adapter proteins contribute critically to this behavior. Adapter proteins recognize highly conserved motifs such as those for Src homology 3 (SH3), phosphotyrosine-binding (PTB), and postsynaptic density 95/discs-large/zona occludens (PDZ) docking sequences in candidate GPCRs. Here we review the behavior of the Na+/H+ exchange regulatory factor (NHERF) family of PDZ adapter proteins on GPCR signalling, trafficking, and function. Structural determinants of NHERF proteins that allow them to recognize targeted GPCRs are considered. NHERF1 and NHERF2 are capable also of modifying the assembled complex of accessory proteins such as β-arrestins, which have been implicated in regulating GPCR signaling. In addition, NHERF1 and NHERF2 modulate GPCR signaling by altering the G protein to which the receptor binds or affect other regulatory proteins that affect GTPase activity, protein kinase A, phospholipase C, or modify downstream signaling events. Small molecules targeting the site of NHERF1-GPCR interaction are being developed and may become important and selective drug candidates.     

The evolving role of lipid rafts and caveolae in G protein-coupled receptor signaling: implications for molecular pharmacology

The many components of G-protein-coupled receptor (GPCR) signal transduction provide cells with numerous combinations with which to customize their responses to hormones, neurotransmitters, and pharmacologic agonists. GPCRs function as guanine nucleotide exchange factors for heterotrimeric (alpha, beta, gamma) G proteins, thereby promoting exchange of GTP for GDP and, in turn, the activation of 'downstream' signaling components. Recent data indicate that individual cells express mRNA for perhaps over 100 different GPCRs (out of a total of nearly a thousand GPCR genes), several different combinations of G-protein subunits, multiple regulators of G-protein signaling proteins (which function as GTPase activating proteins), and various isoforms of downstream effector molecules. The differential expression of such protein combinations allows for modulation of signals that are customized for a specific cell type, perhaps at different states of maturation or differentiation. In addition, in the linear arrangement of molecular interactions involved in a given GPCR-G-protein-effector pathway, one needs to consider the localization of receptors and post-receptor components in subcellular compartments, microdomains, and molecular complexes, and to understand the movement of proteins between these compartments. Co-localization of signaling components, many of which are expressed at low overall concentrations, allows cells to tailor their responses by arranging, or spatially organizing in unique and kinetically favorable ways, the molecules involved in GPCR signal transduction. This review focuses on the role of lipid rafts and a subpopulation of such rafts, caveolae, as a key spatial compartment enriched in components of GPCR signal transduction. Recent data suggest cell-specific patterns for expression of those components in lipid rafts and caveolae. Such domains likely define functionally important, cell-specific regions of signaling by GPCRs and drugs active at those GPCRs.     

Optical techniques to analyze real-time activation and signaling of G-protein-coupled receptors

The activation of G-protein-coupled receptors (GPCRs) is traditionally measured either by monitoring downstream physiological events or by membrane-based biochemical assays. Neither of these approaches permits detailed kinetic or spatial analysis of receptor activation and signaling. Recently, several optical techniques have been developed to monitor receptor activation either by using purified reconstituted GPCRs or by observing GPCRs, G proteins and second messengers in intact cells. These techniques are providing, literally, new views on both the mechanistic basis of the signaling process and the kinetic and spatial properties of GPCR-mediated signals. They suggest that agonists can activate GPCRs within milliseconds, that different compounds can induce distinct active conformations of GPCRs, that G-protein activation is the rate-limiting step in GPCR signaling, and that cellular signals can be temporally and spatially confined. They are also raising controversial issues, such as whether or not receptors and G proteins are pre-coupled and whether G proteins dissociate during activation.     

G蛋白偶联受体固有活性研究进展与新药开发

G蛋白偶联受体(G-prote in-coup led receptor,GPCR)是与G蛋白有信号连接的一大类受体家族,是人体内最大的膜受体蛋白家族,是一类具有7个跨膜螺旋的跨膜蛋白受体。GPCR的结构特征和在信号传导中的重要作用决定了其可以作为很好的药物靶标。目前世界药物市场上有三分之一的小分子药物是GPCR的激活剂(agon ist)或拮抗剂(antagon ist)。以其为靶点的药物在医药产业中占据显著地位。在当今前50种最畅销的上市药物中,20%属于G蛋白受体相关药物。近来的研究发现,大多数G蛋白偶联受体具有一个很重要的特性,就是具有固有活性(Constitutive ac-tivity),即无激动剂条件受体自发的维持激活并维持下游信号传导通路的活性。固有活性涉及受体、G蛋白及下游信号通路之间的关系。该文就G蛋白偶联受体固有活性概念、研究进展、反相激动剂与固有活性研究、固有活性与新药开发4个方面,进行以下论述。     

G proteins in drug screening: from analysis of receptor-G protein specificity to manipulation of GPCR-mediated signalling pathways

Seven transmembrane G protein coupled receptors (7TM GPCRs) represent one of the largest gene familes in the human genome. Because of the size of the GPCR family, their proven history of being valuable targets for small molecule drug design, the fact that the absolute number of GPCRs that are targets for current medicines represents only a small fraction of the total encoded by the human genome, and that ligands for GPCRs do not have to enter the cell to exert their function, it is very likely that GPCRs will remain major targets for the pharmaceutical industry in the foreseeable future. Despite recent evidence indicating that GPCRs can provide information to cells, that does not require activation of G proteins ("signaling at zero G"), most of the GPCRs known to date function via interaction with and activation of heterotrimeric (alphabetagamma) G proteins. Thus, assay systems translating ligand modulation of GPCRs into G protein-dependent intracellular responses are a key component of both basic research and the drug discovery process. This article will review the current knowledge and recent progress in understanding molecular aspects of specific receptor-G protein recognition. It will also highlight how the knowledge generated by such studies can be transformed into assay systems for GPCR drug discovery.     

Heterodimerization of g protein-coupled receptors: specificity and functional significance

G protein-coupled receptors (GPCRs) are cell surface receptors that mediate physiological responses to a diverse array of stimuli. GPCRs have traditionally been thought to act as monomers, but recent evidence suggests that GPCRs may form dimers (or higher-order oligomers) as part of their normal trafficking and function. In fact, certain GPCRs seem to have a strict requirement for heterodimerization to attain proper surface expression and functional activity. Even those GPCRs that do not absolutely require heterodimerization may still specifically associate with other GPCR subtypes, sometimes resulting in dramatic effects on receptor pharmacology, signaling, and/or internalization. Understanding the specificity and functional significance of GPCR heterodimerization is of tremendous clinical importance since GPCRs are the molecular targets for numerous therapeutic drugs.     

Non-canonical signaling of the PTH receptor

The classical model of arrestin-mediated desensitization of cell-surface G-protein-coupled receptors (GPCRs) is thought to be universal. However, this paradigm is incompatible with recent reports that the parathyroid hormone (PTH) receptor (PTHR), a crucial GPCR for bone and mineral ion metabolism, sustains G(S) activity and continues to generate cAMP for prolonged periods after ligand washout; during these periods the receptor is observed mainly in endosomes, associated with the bound ligand, G(S) and β-arrestins. In this review we discuss possible molecular mechanisms underlying sustained signaling by the PTHR, including modes of signal generation and attenuation within endosomes, as well as the biological relevance of such non-canonical signaling.     

G protein-coupled receptors and their signaling pathways: classical therapeutical targets susceptible to novel therapeutic concepts

In recent years, new strategies in cancer therapy have been developed targeting key signaling molecules in the receptor tyrosine kinase signal transduction pathway. In contrast, most therapeutical concepts to manipulate G protein-coupled receptors (GPCR)-mediated disorders are still limited to the use of receptor-specific agonists or antagonists. Visible progress in the understanding of GPCR signaling complexity, especially the detection of several families of highly target- and cell-specific regulator proteins of GPCRs, G proteins, and effector components may open new horizons to develop novel therapeutical concepts targeting GPCR signaling elements. Thus, this review will focus on different molecular levels that may be of particular interest in terms of new drug development such as: (i) GPCR subtypes, allosteric binding sites, dimerization and constitutive activity, the use of RAMPs (receptor-activity-modifying proteins) and RASSLs (receptor activated solely by synthetic ligands); (ii) AGS (activators of G protein signaling) and RGS (regulators of G protein signaling) proteins which modify G protein activity; (iii) the high diversity of isozymes involved in the generation, signal transmission, and degradation of second messenger molecules.     

Functional signaling biases in G protein-coupled receptors: Game Theory and receptor dynamics

Pharmacotherapeutic targeting of G protein-coupled receptors (GPCRs) is perhaps the most important field of drug design, as agents designed to control these receptors constitute more than half of the pharmacopeia. Initially GPCRs were considered to be unitary entities, possessing all of their potential functionality in their characteristic heptahelical core. Early models of the functional activity of GPCRs considered them to possess just a simple 'on' or 'off' status. Recent research however has allowed us to realize that GPCR functionality is dependent upon many other proteins outside of the heptahelical core, on the site of GPCR expression in a tissue or a microdomain in a cell, and, most importantly, on the formation of differential 'active' states preferentially coupled to specific signal transduction structures. The recognition of such signaling diversity has facilitated the ability to appreciate and identify ligands for GPCRs that demonstrate a bias towards one signaling form of a receptor to another. However while potentially increasing our ability for selective signal targeting, our approach to understanding the physiological ramifications of systemic signaling manipulation is underdeveloped. This explosion in the complexity of GPCR signaling is now becoming familiar territory to receptor biologists, yet the application of this knowledge to drug design is relatively limited. This review will attempt to outline potential pitfalls and unseen benefits of using signaling bias in therapeutic design as well as highlighting new applications such as Game Theory for uncovering new therapeutic applications for biased agonists.     

The structure and dynamics of GPCR oligomers: a new focus in models of cell-signaling mechanisms and drug design

G protein-coupled receptors (GPCRs) represent approximately half of the potential pharmaceutical targets for current drugs, and thus the way in which these receptors assemble into dimeric/oligomeric structures is of vital interest in practical as well as conceptual aspects of current drug discovery efforts. The significance of such structures is based on the recent realization that ligand-dependent signaling by GPCRs is not necessarily transduced to the G protein by receptor monomers, but possibly by GPCR dimers or even oligomers that function as dynamic macromolecular assemblies. In addition, recent evidence that GPCR hetero-oligomerization can produce signaling units with unexpected combinations of pharmacological properties suggests entirely new methods for developing successful drugs. The dynamic mechanisms of these signaling assemblies remain to be elucidated. The development of increasingly accurate dynamic molecular models of GPCR dimers is expected to produce a more complete structural context for understanding the molecular mechanisms of GPCR function, and to aid in drug discovery.     

Signal transduction pathways of G protein-coupled receptors and their cross-talk with receptor tyrosine kinases: lessons from bradykinin signaling

G protein-coupled receptors (GPCRs) represent a major class of drug targets. Recent investigation of GPCR signaling has revealed interesting novel features of their signal transduction pathways which may be of great relevance to drug application and the development of novel drugs. Firstly, a single class of GPCRs such as the bradykinin type 2 receptor (B2R) may couple to different classes of G proteins in a cell-specific and time-dependent manner, resulting in simultaneous or consecutive initiation of different signaling chains. Secondly, the different signaling pathways emanating from one or several GPCRs exhibit extensive cross-talk, resulting in positive or negative signal modulation. Thirdly, GPCRs including B2R have the capacity for generation of mitogenic signals. GPCR-induced mitogenic signaling involves activation of the p44/p42 "mitogen activated protein kinases" (MAPK) and frequently "transactivation" of receptor tyrosine kinases (RTKs), an unrelated class of receptors for mitogenic polypeptides, via currently only partly understood pathways. Cytoplasmic tyrosine kinases and protein-tyrosine phosphatases (PTPs) which regulate RTK signaling are likely mediators of RTK transactivation in response to GPCRs. Finally, GPCR signaling is the subject of regulation by RTKs and other tyrosine kinases, including tyrosine phosphorylation of GPCRs itself, of G proteins, and of downstream molecules such as members of the protein kinase C family. In conclusion, known agonists of GPCRs are likely to have unexpected effects on RTK pathways and activators of signal-mediating enzymes previously thought to be exclusively linked to RTK activity such as tyrosine kinases or PTPs may be of much interest for modulating GPCR-mediated biological responses.     

Domain coupling in GPCRs: the engine for induced conformational changes

Recent solved structures of G protein-coupled receptors (GPCRs) provide insights into variation of the structure and molecular mechanisms of GPCR activation. In this review, we provide evidence for the emerging paradigm of domain coupling facilitated by intrinsic disorder of the ligand-free state in GPCRs. The structure-function and dynamic studies suggest that ligand-bound GPCRs exhibit multiple active conformations in initiating cellular signals. Long-range intramolecular and intermolecular interactions at distant sites on the same receptor are crucial factors that modulate signaling function of GPCRs. Positive or negative coupling between the extracellular, the transmembrane and the intracellular domains facilitates cooperativity of activating 'switches' as requirements for the functional plasticity of GPCRs. Awareness that allosteric ligands robustly affect domain coupling provides a novel mechanistic basis for rational drug development, small molecule antagonism and GPCR regulation by classical as well as nonclassical modes.     

Regulators of G protein signaling (RGS proteins): Novel central nervous system drug targets

Abstract: Many drugs of abuse signal through receptors that couple to G proteins (GPCRs), so the factors that control GPCR signaling are likely to be important to the understanding of drug abuse. Contributions by the recently identified protein family, regulators of G protein signaling (RGS) to the control of GPCR function are just beginning to be understood. RGS proteins can accelerate the deactivation of G proteins by 1000‐fold and in cell systems they profoundly inhibit signaling by many receptors, including mu‐opioid receptors. Coupled with the known dynamic regulation of RGS protein expression and function, they are of obvious interest in understanding tolerance and dependence mechanisms. Furthermore, drugs that could inhibit their activity could be useful in preventing the development of or in treating drug dependence.     

Crosstalk within GPCR heteromers in schizophrenia and Parkinson's disease: physical or just functional?

Crosstalk between G protein-coupled receptors (GPCRs) is one of the key mechanisms used by the cell for integrating multiple signaling pathways. Functional crosstalk at the level of signaling pathways was initially thought to regulate receptor function. Importantly, the existence of GPCR heteromers demonstrates that direct physical interactions between GPCRs could also be behind the crosstalk phenomenon. Neurological disorders such as Parkinson's disease (PD) and schizophrenia have been linked to a dysfunctional communication between certain GPCRs. In this review, we discuss functional and physical crosstalk of the main GPCR families involved in the aforementioned disorders. In addition, we analyze the available structural information on physical crosstalk and highlight some strategies in drug discovery based on these crosstalk mechanisms.     

The family B1 GPCR: structural aspects and interaction with accessory proteins

G protein coupled receptors (GPCRs) play a crucial role in physiology and pathophysiology in humans. Beside the large family A (rhodopsin-like receptors) and family C GPCR (metabotropic glutamate receptors), the small family B1 GPCR (secretin-like receptors) includes important receptors such as vasoactive intestinal peptide receptors (VPAC), pituitary adenylyl cyclase activating peptide receptor (PAC1R), secretin receptor (SECR), growth hormone releasing factor receptor (GRFR), glucagon receptor (GCGR), glucagon like-peptide 1 and 2 receptors (GLPR), gastric inhibitory peptide receptor (GIPR), parathyroid hormone receptors (PTHR), calcitonin receptors (CTR) and corticotropin-releasing factor receptors (CRFR). They represent very promising targets for the development of drugs having therapeutical impact on many diseases such as chronic inflammation, neurodegeneration, diabetes, stress and osteoporosis. Over the past decade, structure-function relationship studies have demonstrated that the N-terminal ectodomain (N-ted) of family B1 receptors plays a pivotal role in natural ligand recognition. Structural analysis of some family B1 GPCR N-teds revealed the existence of a Sushi domain fold consisting of two antiparallel β sheets stabilized by three disulfide bonds and a salt bridge. The family B1 GPCRs promote cellular responses through a signaling pathway including predominantly the Gsadenylyl cyclase-cAMP pathway activation. Family B1 GPCRs also interact with a few accessory proteins which play a role in cell signaling, receptor expression and/or pharmacological profiles of receptors. These accessory proteins may represent new targets for the design of new drugs. Here, we review the current knowledge regarding: i) the structure of family B1 GPCR binding domain for natural ligands and ii) the interaction of family B1 GPCRs with accessory proteins.     

Embracing emerging paradigms of G protein-coupled receptor agonism and signaling to address airway smooth muscle pathobiology in asthma

G protein-coupled receptors (GPCRs) regulate numerous airway cell functions, and signaling events transduced by GPCRs are important in both asthma pathogenesis and therapy. Indeed, most asthma therapies target GPCRs either directly or indirectly. Within recent years, our understating of how GPCRs signal and are regulated has changed significantly as new concepts have emerged and traditional ideas have evolved. In this review, we discuss current concepts regarding constitutive GPCR activity and receptor agonism, functional selectivity, compartmentalized signaling, and GPCR desensitization. We further discuss the relevance of these ideas to asthma and asthma therapy, while emphasizing their potential application to the GPCR signaling in airway smooth muscle that regulates airway patency and thus disease severity.     

Evolving concepts in G protein-coupled receptor endocytosis: the role in receptor desensitization and signaling

G protein-coupled receptors (GPCRs) are seven transmembrane proteins that form the largest single family of integral membrane receptors. GPCRs transduce information provided by extracellular stimuli into intracellular second messengers via their coupling to heterotrimeric G proteins and the subsequent regulation of a diverse variety of effector systems. Agonist activation of GPCRs also initiates processes that are involved in the feedback desensitization of GPCR responsiveness, the internalization of GPCRs, and the coupling of GPCRs to heterotrimeric G protein-independent signal transduction pathways. GPCR desensitization occurs as a consequence of G protein uncoupling in response to phosphorylation by both second messenger-dependent protein kinases and G protein-coupled receptor kinases (GRKs). GRK-mediated receptor phosphorylation promotes the binding of beta-arrestins, which not only uncouple receptors from heterotrimeric G proteins but also target many GPCRs for internalization in clathrin-coated vesicles. beta-Arrestin-dependent endocytosis of GPCRs involves the direct interaction of the carboxyl-terminal tail domain of beta-arrestins with both beta-adaptin and clathrin. The focus of this review is the current and evolving understanding of the contribution of GRKs, beta-arrestins, and endocytosis to GPCR-specific patterns of desensitization and resensitization. In addition to their role as GPCR-specific endocytic adaptor proteins, beta-arrestins also serve as molecular scaffolds that foster the formation of alternative, heterotrimeric G protein-independent signal transduction complexes. Similar to what is observed for GPCR desensitization and resensitization, beta-arrestin-dependent GPCR internalization is involved in the intracellular compartmentalization of these protein complexes.