Constitutively activated G protein-coupled receptors: a novel approach to CNS drug discovery

G protein-coupled receptors (GPCRs) represent a major class of signal transduction proteins that modulate various biological functions. GPCRs are one of the most common targets for drug development-currently, 39 of the top 100 marketed drugs in use act directly or indirectly through activation or blockade of GPCR-mediated receptors. Nearly 160 GPCRs have been identified based on their gene sequence and their ability to interact with known endogenous ligands. However, an estimated 500-800 additional GPCRs have been classified as "orphan" receptors (oGPCRs) because their endogenous ligands have not yet been identified. Given that known GPCRs have proven to be such clinically useful drug targets, these oGPCRs represent a rich group of receptor targets for the development of novel and improved medicines. To develop ligands for these potential drug targets requires the ability to identify groups or pools of GPCRs that are likely to be involved in a specific disease process (obesity, schizophrenia, depression, etc.) and to dissect out the pharmacological and signal transduction differences between these GPCR subtypes. It also requires the development of assays to detect ligands of GPCRs even when the endogenous ligands are unidentified. This paper will review novel strategies to identify clinically interesting oGPCRs and to screen for small molecules that act as ligands without prior knowledge of endogenous ligands. This involves the use of constitutively activated GPCRs, a technology that provides a unique opportunity to identify several classes of pharmacological agents, including agonists, inverse agonists and allosteric modulators.     

The use of constitutively active receptors for drug discovery at the G protein-coupled receptor gene pool

Several lines of evidence over the last decade have established that G protein-coupled receptors (GPCRs) can signal in the absence of their natural ligand which results in ligand-independent or constitutive activity. Natural genetic mutation, overexpression and site-directed mutagenesis all result in constitutive activation of GPCRs. Of the 100 leading pharmaceutical products in 2000, 39, wholly or in part, acted through a GPCR-mediated mechanism, a fact that underlines the extreme importance of GPCRs as pharmaceutical drug targets. In addition, the sequencing of the human genome and database mining has revealed that there are hundreds of putative orphan GPCRs for which the natural ligands have not been identified. These orphan GPCRs have largely been inaccessible to drug discovery because traditional methods have mainly relied on ligand-dependent binding assays to discover and pharmacologically characterize potential drug candidates from this receptor class. In the absence of ligand identification, constitutively active receptors allow for a logical and direct way forward through the drug discovery pathway by providing the tool necessary to find modulators of this receptor class in a ligand-independent fashion.     

Allostery at G protein-coupled receptor homo- and heteromers: uncharted pharmacological landscapes

For many years seven transmembrane domain G protein-coupled receptors (GPCRs) were thought to exist and function exclusively as monomeric units. However, evidence both from native cells and heterologous expression systems has demonstrated that GPCRs can both traffic and signal within higher-order complexes. As for other protein-protein interactions, conformational changes in one polypeptide, including those resulting from binding of pharmacological ligands, have the capacity to alter the conformation and therefore the response of the interacting protein(s), a process known as allosterism. For GPCRs, allosterism across homo- or heteromers, whether dimers or higher-order oligomers, represents an additional topographical landscape that must now be considered pharmacologically. Such effects may offer the opportunity for novel therapeutic approaches. Allosterism at GPCR heteromers is particularly exciting in that it offers additional scope to provide receptor subtype selectivity and tissue specificity as well as fine-tuning of receptor signal strength. Herein, we introduce the concept of allosterism at both GPCR homomers and heteromers and discuss the various questions that must be addressed before significant advances can be made in drug discovery at these GPCR complexes.     

Synthesis and characterization of a cellular membrane affinity chromatography column containing histamine 1 and P2Y1 receptors: A multiple G-protein coupled receptor column

A cellular membrane affinity chromatography (CMAC) column has been created using cellular membrane fragments from a 1321N1 cell line stably transfected with the P2Y₁ receptor. The CMAC(1321N1_P2Y1) column contained functional P2Y₁ and histamine 1 receptors, which independently bound receptor-specific ligands. The data obtained with the CMAC(1321N1_P2Y1) column demonstrate that multiple-G-protein coupled receptor (GPCR) columns can be developed and used to probe interactions with the immobilized receptors and that endogenously expressed GPCRs can be used to create CMAC columns. The results also establish that the histamine 1 receptor can be immobilized with retention of ligand-specific binding.     

The future of G protein-coupled receptors as targets in drug discovery

G protein-coupled receptors (GPCRs) represent the most abundant drug targets today. A large number of GPCR-based drugs have already been developed for a variety of indications in human disease. However, orphan receptors with unidentified ligands serve as potential targets still to be explored. Moreover, research on the interaction of GPCRs with different molecules in the signal transduction pathways, and further studies on receptor dimerization may also lead to the discovery of new drugs. Structure-based drug design will eventually play a key role in generating better and more selective drugs more rapidly when high-resolution structures of GPCRs can be provided by expression, purification and crystallography technologies.     

Novel roles for arrestins in G protein-coupled receptor biology and drug discovery

The G protein-coupled receptors (GPCRs) are the largest family of membrane proteins and represent some of the most important pharmaceutical targets. These receptors, encoded by several hundred genes, are activated by a wide variety of endogenous and synthetic ligands. The study of the signal transduction pathways activated by these receptors and the associated mechanisms controlling biological responses have been pivotal in identifying key intracellular molecules for regulating receptor responsiveness. The beta-arrestin proteins, which were initially discovered due to their role in GPCR desensitization, serve equally important roles in regulating internalization and alternative signaling events. This review focuses on the different functions of beta-arrestins to demonstrate how these proteins can help to identify new ligands for GPCRs and how they can serve as a platform for drug discovery.     

Techniques: plasmon-waveguide resonance (PWR) spectroscopy as a tool to study ligand-GPCR interactions

Plasmon-waveguide resonance (PWR) spectroscopy can be applied to integral membrane proteins incorporated into a supported lipid bilayer without the need for labeling. With high sensitivity and wide dynamic range, this technique can be used to characterize the kinetics and thermodynamics of conformational events associated with the binding of ligands to G-protein-coupled receptors (GPCRs), and to directly examine the interactions of GPCRs with G proteins and other downstream effectors in signal transduction. This allows an easy distinction to be made between agonists, antagonists and inverse agonists, and provides a powerful new tool for studying membrane signaling and for drug development.     

细胞核G蛋白偶联受体研究进展

传统观念认为,G蛋白偶联受体通过自身在细胞表面的激活启动信号转导,从而介导细胞响应外界刺激.近年来研究发现了细胞核G蛋白偶联受体(nGPCR)的存在,有别于细胞质膜G蛋白偶联受体(mGPCR),细胞核G蛋白偶联受体具有独特的来源、功能、信号途径和作用模式.本文总结了目前对于细胞核G蛋白偶联受体的研究成果,以期为靶向G蛋...     

孤儿G蛋白偶联受体及其作为新药靶点的重要意义

作为膜受体最大的一个家族,G蛋白偶联受体(GPCRs)参与了广泛的生理与病理过程,因而一直是新药发现及研究的最重要靶点。孤儿GPCRs(oGPCRs)是一类内源性配基未定、功能未知的GPCRs,作为创新药物的靶点具有重要的地位和意义。     

The influence of target family and functional activity on the physicochemical properties of pre-clinical compounds

The target families of greatest interest in drug discovery can be differentiated on the basis of the physicochemical properties of their pre-clinical ligands. The ligands for peptidergic targets, such as peptide GPCRs and integrin receptors, possess significantly higher median property values than those for aminergic targets, such as monoamine transporters and GPCRs. The ligands for peptide GPCRs were found to be less efficient, in terms of their binding energy per unit of molecular weight or lipophilicity, than ligands for monoamine GPCRs. The changes in the property values during the optimization process were found to vary only slightly across the target families, with the main determinant of the drug-likeness of the optimized compounds being the profile of the starting compounds. Agonists for monoamine GPCRs, opioid receptors and ion channels were typically smaller and less lipophilic than the antagonists, but there was no difference between the agonists and the antagonists for peptide GPCRs and nuclear receptors.     

Functional selectivity in GPCR signaling: understanding the full spectrum of receptor conformations

The great versatility of G protein-coupled receptors (GPCRs), in terms of both their ability to bind different types of ligands and initiate a large number of distinct cellular signaling events, remains incompletely understood. In recent years, the classical view of the nature and consequences of ligand binding to GPCRs has dramatically changed. The notion of functional selectivity, achieved through both biased ligands and allosteric modulators, has brought substantial new insight into our comprehension of the pluridimensionality of signaling achieved by GPCRs. Moreover, receptor heterodimerization adds another important dimension to the diversity of cellular responses controlled by GPCRs. Here, we review these considerations and discuss how they will impact the design of improved therapeutics.     

Alternative drug discovery approaches for orphan GPCRs

G protein-coupled receptors (GPCRs) are well-known drug targets. However, a question mark remains for the more than 100 orphan GPCRs as current deorphanisation strategies failed to identify specific ligands for these receptors. Recent advances have shown that orphan GPCRs may have important functions that are ligand-independent. Orphan GPCRs can modulate the function of well-defined drug targets such as GPCRs with identified ligands and neurotransmitter transporters though physical association with those molecules. Thus, compounds that bind to orphan GPCRs and allosterically regulate the function of the interacting partner or even disrupt the interaction with the latter could become new drugs.     

An ultra-HTS process for the identification of small molecule modulators of orphan G-protein-coupled receptors

G-protein-coupled receptors (GPCRs) are the most successful target proteins for drug discovery research to date. More than 150 orphan GPCRs of potential therapeutic interest have been identified for which no activating ligands or biological functions are known. One of the greatest challenges in the pharmaceutical industry is to link these orphan GPCRs with human diseases. Highly automated parallel approaches that integrate ultra-high throughput and focused screening can be used to identify small molecule modulators of orphan GPCRs. These small molecules can then be employed as pharmacological tools to explore the function of orphan receptors in models of human disease. In this review, we describe methods that utilize powerful ultra-high-throughput screening technologies to identify surrogate ligands of orphan GPCRs.     

Orphan G protein-coupled receptors: from DNA to drug targets

Although G protein-coupled receptors (GPCRs) are the most numerous therapeutic targets to date, ligands remain unknown for approximately two-thirds of these receptors. The challenge in the post-genomic era is to evaluate the role of these 'orphan' GPCRs in normal physiology and disease, and to develop new therapeutics based on this information. A prevalent strategy to determine the function of these orphan GPCRs is to identify specific ligands that conditionally modulate their function. These ligands can then be used to explore the role of the receptor-ligand pair in relevant models of disease. Some promise is emerging from this infant field of functional genomics as several recently deorphanized GPCRs may be potential drug targets for many diseases, including obesity, cardiovascular disease, inflammation and cancer.     

Agonists and antagonists of protease activated receptors (PARs)

Protease activated receptors (PARs) are a category of G-protein coupled receptors (GPCRs) implicated in the progression of a wide range of diseases, including thrombosis, inflammatory disorders, and proliferative diseases. Signal transduction via PARs proceeds via an unusual activation mechanism. Instead of being activated through direct interaction with an extracellular signal like most GPCRs, they are self-activated following cleavage of their extracellular N-terminus by serine proteases to generate a new receptor N-terminus that acts as an intramolecular ligand by folding back onto itself and triggering receptor activation. Short synthetic peptides corresponding to this newly exposed N-terminal tethered ligand can activate three of the four known PARs in the absence of proteases, and such PAR activating peptides (PAR-APs) have served as templates for agonist/antagonist development. In fact much of the evidence for involvement of PARs in diseases has relied upon use of PAR-APs, often of low potency and uncertain selectivity. This review summarizes current structures of PAR agonists and antagonists, the need for more selective and more potent PAR ligands that activate or antagonize this intriguing class of receptors, and outlines the background relevant to PAR activation, assay methods, and physiological properties anticipated for PAR ligands.     

Anti-inflammatory signaling through G protein-coupled receptors

G protein-coupled receptors (GPCRs) play important roles in human physiology. GPCRs are involved in immunoregulation including regulation of the inflammatory response. Chemotaxis of phagocytes and lymphocytes is mediated to a great extent by the GPCRs for chemoattractants including myriads of chemokines. Accumulation and activation of phagocytes at the site of inflammation contribute to local inflammatory response. A handful of GPCRs have been found to transduce anti-inflammatory signals that promote resolution of inflammation. These GPCRs interact with selected metabolites of arachdonic acid, such as lipoxins, and of omega-3 essential fatty acids, such as resolvins and protectins. Despite mounting evidence for the in vivo functions of these anti-inflammatory and pro-resolving ligands paired with their respective GPCRs, the underlying signaling mechanisms have not been fully delineated. The present review summarizes what we have learned about these GPCRs, their structures and signaling pathways and the prospect of targeting these receptors for novel anti-inflammatory therapies.     

G protein-coupled receptors: walking hand-in-hand,talking hand-in-hand?

Most cells express a panel of different G protein-coupled receptors (GPCRs) allowing them to respond to at least a corresponding variety of extracellular ligands. In order to come to an integrative well-balanced functional response these ligand-receptor pairs can often cross-regulate each other. Although most GPCRs are fully capable to induce intracellular signalling upon agonist binding on their own, many GPCRs, if not all, appear to exist and function in homomeric and/or heteromeric assemblies for at least some time. Such heteromeric organization offers unique allosteric control of receptor pharmacology and function between the protomers and might even unmask 'new' features. However, it is important to realize that some functional consequences that are proposed to originate from heteromeric receptor interactions may also be observed due to intracellular crosstalk between signalling pathways of non-associated GPCRs.     

Orphan G-protein-coupled receptors: the next generation of drug targets?

The pharmaceutical industry has readily embraced genomics to provide it with new targets for drug discovery. Large scale DNA sequencing has allowed the identification of a plethora of DNA sequences distantly related to known G protein-coupled receptors (GPCRs), a superfamily of receptors that have a proven history of being excellent therapeutic targets. In most cases the extent of sequence homology is insufficient to assign these `orphan'' receptors to a particular receptor subfamily. Consequently, reverse molecular pharmacological and functional genomic strategies are being employed to identify the activating ligands of the cloned receptors. Briefly, the reverse molecular pharmacological methodology includes cloning and expression of orphan GPCRs in mammalian cells and screening these cells for a functional response to cognate or surrogate agonists present in biological extract preparations, peptide libraries, and complex compound collections. The functional genomics approach involves the use of `humanized yeast cells, where the yeast GPCR transduction system is engineered to permit functional expression and coupling of human GPCRs to the endogenous signalling machinery. Both systems provide an excellent platform for identifying novel receptor ligands. Once activating ligands are identified they can be used as pharmacological tools to explore receptor function and relationship to disease.     

Receptor tyrosine kinase-G-protein-coupled receptor signalling platforms: out of the shadow?

Receptor tyrosine kinases (RTKs) and G-protein-coupled receptors (GPCRs) can form platforms in which protein signalling components specific for each receptor are shared (owing to close proximity) to produce an integrated response upon engagement of ligands. RTK-GPCR signalling platforms respond to growth factors and GPCR agonists to increase gain over and above that which is normally produced by separate receptors. They can also function to change the spatial context of signalling in response to growth factor activation. The function of RTK-GPCR signalling platforms can be modulated with conformational-specific inhibitors that stabilise defined GPCR states to abrogate both GPCR agonist- and growth factor-stimulated cell responses. In this paper, we provide an opinion of the biology and unusual pharmacology of RTK-GPCR signalling platforms and make comparisons with a more traditional model of crosstalk between RTKs and GPCRs.