G-protein-coupled receptors and signaling networks: emerging paradigms.

G-protein-coupled receptors (GPCRs) constitute the largest family of cell-surface molecules involved in signal transmission. These receptors play key physiological roles and their dysfunction results in several diseases. Recently, it has been shown that many of the cellular responses mediated by GPCRs do not involve the sole stimulation of conventional second-messenger-generating systems, but instead result from the functional integration of an intricate network of intracellular signaling pathways. Effectors for GPCRs that are independent of G proteins have now also been identified, thus changing the conventional view of the GPCR-heterotrimeric-G-protein-associated effector. The emerging information is expected to help elucidate the most basic mechanism by which these receptors exert their numerous physiological roles, in addition to determining why the perturbation of their function results in many pathological conditions.     

Novel G-protein-coupled receptor genes expressed in the brain: continued discovery of important therapeutic targets

The rhodopsin family of G-protein-coupled receptors (GPCRs) is the largest known group of cell-surface mediators of signal transduction. The vast majority of these receptors were discovered by methods based upon shared sequence homologies found throughout this family. While such efforts identified a multitude of receptor subtypes for previously known ligands, numerous receptors have been discovered for which endogenous ligands were unknown. These receptors are commonly referred to as orphan receptors. One of the most important tasks of modern pharmacology lies in elucidating the functions of these receptors. Of particular interest are receptors with recognised expression in the central nervous system, given that many psychiatric and neurodegenerative disorders are mediated by unknown mechanisms. Hence, this collection of putative neurotransmitter and neuromodulator signal mediators represents a substantial and untapped resource for novel drug discovery. Recently, various methodologies have accelerated the discovery of novel ligands for these orphan receptors, identifying the basic components required for further physiological ligand/receptor system characterisation. Equipped with proven ligand identification strategies, the characterisation of all orphan GPCRs and the exploitation of their exciting potential as targets for the discovery of novel drugs is anticipated.     

Free fatty acid receptors and their physiological role in metabolic regulation

Free fatty acids (FFAs) are not only essential nutrient components, but they also function as signaling molecules in various physiological processes. In the progression of genomic analysis, many orphan G-protein coupled receptors (GPCRs) are found. Recently, GPCRs deorphanizing strategy successfully identified multiple receptors for FFAs. In these FFA receptors (FFARs), GPR40 (FFAR1) and GPR120 are activated by medium- to long- chain FFAs. GPR40 is expressed mainly in pancreatic β-cell and mediates insulin secretion, whereas GPR120 is expressed abundantly in the intestine and regulates the secretion of cholecystokinin (CCK) and glucagons-like peptide-1 (GLP-1), it promotes insulin secretion. Due to these biological activity, GPR40 and GPR120 are potential drug target for type 2 diabetes and selective ligands have been developed. In this review, we provide recent development in the field and discuss their physiological roles and their potential as drug targets.     

New Frontiers in Gut Nutrient Sensor Research: Free Fatty Acid Sensing in the Gastrointestinal Tract

Utilizing the human genome database, the recently developed G-protein–coupled receptors (GPCRs) deorphanizing strategy successfully identified multiple receptors of free fatty acids (FFAs). FFAs have been demonstrated to act as ligands of several GPCRs (FFAR1, FFAR2, FFAR3, and GPR120). These fatty acid receptors are proposed to play critical roles in various types of physiological homeostases. FFAR1 and GPR120 are activated by medium- and long-chain FFAs. In contrast, FFAR2 and FFAR3 are activated by short-chain FFAs. It has been elucidated that these four receptors are expressed in the gastrointestinal tract and have many essential roles as sensors of FFA. In this review, we summarize the physiological and pharmacological function of the receptors in the gastrointestinal tract.     

GPCRs: The most promiscuous druggable receptor of the mankind

All physiological events in living organisms originated as specific chemical/biochemical signals on the cell surface and transmitted into the cytoplasm. This signal is translated within milliseconds–hours to a specific and unique order required to maintain optimum performance and homeostasis of living organisms. Examples of daily biological functions include neuronal communication and neurotransmission in the process of learning and memory, secretion (hormones, sweat, and saliva), muscle contraction, cellular growth, differentiation and migration during wound healing, and immunity to fight infections. Among the different transducers for such life-dependent signals is the large family of G protein-coupled receptors (GPCRs). GPCRs constitute roughly 800 genes, corresponding to 2% of the human genome. While GPCRs control a plethora of pathophysiological disorders, only approximately one-third of GPCR families have been deorphanized and characterized. Recent drug data show that around 40% of the recommended drugs available in the market target mainly GPCRs. In this review, we presented how such system signals, either through G protein or via other players, independent of G protein, function within the biological system. We also discussed drugs in the market or clinical trials targeting mainly GPCRs in various diseases, including cancer.     

Co-ordinated covalent modification of G-protein coupled receptors

The G-protein coupled receptor (GPCR) gene family represents one of the largest families in the mammalian genome. The flexibility of signalling and widespread tissue distribution of these receptors has allowed GPCRs to be employed in the physiological regulation of nearly all biological functions. This, coupled with the fact that it is possible to chemically produce highly specific ligands to these receptors have made GPCRs attractive targets for pharmacological intervention in a wide variety of disease states. When targeting GPCRs in therapeutic drug design it is traditional, and eminently sensible, to focus on ligands that will provide agonism, antagonism or allosteric modulation. However, as more is understood of the mechanisms that regulate GPCRs, and in particular the dynamic covalent modifications that might endow tissue specific functions, then these regulatory processes may provide alternative targets for GPCR drug discovery. In this review we consider three of the covalent modifications which are considered to regulate the function of GPCRs namely; receptor phosphorylation, palmitoylation and ubiquitination. In particular, we will describe the mechanisms of modification, the functional consequences and the relationship between these three covalent modification events.     

Fatty acid receptors as new therapeutic targets for diabetes

G-protein-coupled receptors (GPCRs) are key regulators of several physiological functions. Their roles in cellular signal transduction have made them the target for majority of all currently prescribed drugs. Additionally, there are many orphan GPCRs that provide potential novel therapeutic targets. Several GPCRs are involved in metabolic regulation and glucose homeostasis such as GLP-1 receptor, glucagon receptor, adiponectin receptor and so on. Recently, free fatty acids (FFAs) have been demonstrated as ligands for orphan GPCRs and have been proposed to play a critical role in physiological glucose homeostasis. GPR40 and GPR120 are activated by medium and long-chain FFAs, whereas GPR41 and GPR43 can be activated by short-chain FFAs. GPR40, which is preferentially expressed in pancreatic β-cells, mediates the majority of the effects of FFAs on insulin secretion. In this review, these findings and also critical analysis of these GPCRs as novel targets for diabetes are discussed.     

Fatty acid receptors as new therapeutic targets for diabetes

G-protein-coupled receptors (GPCRs) are key regulators of several physiological functions. Their roles in cellular signal transduction have made them the target for majority of all currently prescribed drugs. Additionally, there are many orphan GPCRs that provide potential novel therapeutic targets. Several GPCRs are involved in metabolic regulation and glucose homeostasis such as GLP-1 receptor, glucagon receptor, adiponectin receptor and so on. Recently, free fatty acids (FFAs) have been demonstrated as ligands for orphan GPCRs and have been proposed to play a critical role in physiological glucose homeostasis. GPR40 and GPR120 are activated by medium and long-chain FFAs, whereas GPR41 and GPR43 can be activated by short-chain FFAs. GPR40, which is preferentially expressed in pancreatic beta-cells, mediates the majority of the effects of FFAs on insulin secretion. In this review, these findings and also critical analysis of these GPCRs as novel targets for diabetes are discussed.     

G protein-coupled receptors in drug discovery

G protein-coupled receptors (GPCRs) represent one of the most important drug discovery targets such that compounds targeted against GPCRs represent the single largest drug class currently on the market. With the revolutionary advances in human genome sciences and the identification of numerous orphan GPCRs, it is even more important to identify ligands for these orphan GPCRs so that their physiological and pathological roles can be delineated. To this end, major pharmaceutical industries are investing enormous amounts of time and money to achieve this object. This review is a bird's eye view on the various aspects of GPCRs in drug discovery.     

Beta-arrestins and heterotrimeric G-proteins: collaborators and competitors in signal transduction

G-protein-coupled receptors (GPCRs), also known as seven transmembrane receptors (7-TMRs), are the largest protein receptor superfamily in the body. These receptors and their ligands direct a diverse array of physiological responses, and hence have broad relevance to numerous diseases. As a result, they have generated considerable interest in the pharmaceutical industry as drug targets. Recently, GPCRs have been demonstrated to elicit signals through interaction with the scaffolding proteins, beta-arrestins-1 and 2, independent of heterotrimeric G-protein coupling. This review discusses several known G-protein-independent, beta-arrestin-dependent pathways and their potential physiological and pharmacological significance. The emergence of G-protein-independent signalling changes the way in which GPCR signalling is evaluated, from a cell biological to a pharmaceutical perspective and raises the possibility for the development of pathway specific therapeutics.     

Neurotransmitters, more than meets the eye--neurotransmitters and their perspectives in cancer development and therapy

The neurotransmitter/receptor system has been shown to modulate various aspects of tumor development including cell proliferation, angiogenesis, invasion, migration and metastasis. It has been found that tumor tissues can not only synthesize and release a wide range of neurotransmitters but also produce different biological effects via respective receptors. These tissues are also innervated by nerve fibers but the biological significance is unknown. Nevertheless neurotransmitters can produce either stimulatory or inhibitory effect in normal and tumor tissues. These effects are dependent on the types of tissues and the kinds of neurotransmitter as well as the subtypes of corresponding receptors being involved. These findings clearly extend the conventional role of neurotransmitters in nervous system to the actions in oncogenesis. In this regard, intervention or stimulation of these neuronal pathways in different cancer diseases would have significant clinical implications in cancer treatments. Here, we summarize the influences of various well-characterized neurotransmitters and their receptors on tumor growth and further discuss the respective possible strategies and perspectives for cancer therapy in the future.     

Non-invasive optical biosensor for assaying endogenous G protein-coupled receptors in adherent cells

INTRODUCTION: Screening drugs against G protein-coupled receptors (GPCRs) - the single largest family of drug targets in the human genome - is still a major effort in pharmaceutical and biotech industries. Conventional cell-based assays generally measure a single cellular event, such as the generation of a second messenger or the relocation of a specific protein target. However, manipulation or engineering of cells is often a prerequisite for these technologies to achieve desired sensitivities. The present study is focused on the use of non-invasive and manipulation-free optical biosensors for assaying endogenous GPCRs in adherent cells. METHODS: Resonant waveguide grating (RWG) biosensor was applied to manifest ligand-induced dynamic mass redistribution (DMR) within the bottom portion of adherent cell layer. The DMR signatures mediated through the activation of several endogenous GPCRs in cells were characterized. Endogenous receptor panning was examined at cell system level by using a panel of agonists known to activate many GPCRs, and also at family receptor level by determining the efficacies of a set of family-specific agonists. RESULTS: Three major types of optical signatures were identified; each was correlated with the activation of a class of GPCRs, depending on the G protein with which the receptor is coupled (i.e., G(q), G(s) and G(i)). The characteristics of DMR signals, mostly the amplitude and kinetics of a DMR event, were dependent on the doses of agonists and the expression levels of endogenous receptors. All three classes of endogenous receptors were found in human epidermoid carcinoma A431 cells. Interestingly, the dose-dependent switching from one type of DMR signal to another was observed for several GPCR agonists examined. A small panel of P2Y receptor agonists exhibited distinct efficacies in three cell lines examined. DISCUSSIONS: The RWG biosensors were applicable to study the activation of endogenous GPCRs. Like second messengers or gene expression, the DMR signals obtained could be considered as novel and quantifiable physiological responses of living cells mediated through GPCRs and used for studying receptor biology.     

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.     

Yeast system as a screening tool for pharmacological assessment of g protein coupled receptors

G-protein-coupled receptors (GPCRs) constitute the largest but the most divergent class of cell surface proteins. Although they are thought to share a common 3D-structure composed of seven transmembrane helical domains, they can be activated by extracellular signals as diverse as light, peptides, proteins, lipids, organic odorants, taste molecules, nucleotides or nucleosides. They are involved in an extraordinarily large number of physiological functions and are therefore potential drug targets for many human diseases. During the last decade various GPCRs have been successfully expressed in S. cerevisiae. Yeast is an attractive expression system because it offers the genetic engineering tools typical of a microorganism while possessing an eukaryotic type of secretory pathway and post-translational machinery. This host is particularly attractive for in-vivo manipulation of these receptors due to the high homology between the yeast pheromone signaling pathway and that of mammalian GPCRs. When expressed in yeast, mammalian GPCRs have been shown to couple functionally to either the endogenous yeast Galpha (Gpa1), or co-expressed mammalian Galpha subunits (wild-type or chimeric), and are characterized by a similar pharmacology in response to agonists or antagonists as in native cells. Heterologous expression of wild type or mutant GPCRs in S. cerevisiae allows a rapid assessment of their ability to detect and transduce extracellular stimulations, through the use of a reporter system. Furthermore, this approach is amenable to high-throughput screening of new drugs, which would provide a determinant advantage in the field of therapeutic research, and also for investigation of the still unknown ligands of orphan receptors. This review will focus on the latest developments of yeast-based technology to screen for potential GPCR agonists/antagonists.     

Ubiquitination of g protein-coupled receptors: functional implications and drug discovery

G protein-coupled receptors (GPCRs) comprise the largest and most diverse family of signaling receptors and control a vast array of physiological responses. Modulating the signaling responses of GPCRs therapeutically is important for the treatment of various diseases, and discovering new aspects of GPCR signal regulation is critical for future drug development. Post-translational modifications are integral to the regulation of GPCR function. In addition to phosphorylation, many GPCRs are reversibly modified with ubiquitin. Ubiquitin is covalently attached to lysine residues within the cytoplasmic domains of GPCRs by ubiquitin ligases and removed by ubiquitin-specific proteases. In many cases, ubiquitin functions as a sorting signal that facilitates trafficking of mammalian GPCRs from endosomes to lysosomes for degradation, but not all GPCRs use this pathway. Moreover, there are distinct types of ubiquitin conjugations that are known to serve diverse functions in controlling a wide range of cellular processes, suggesting broad roles for GPCR ubiquitination. In this review, we highlight recent studies that illustrate various roles for ubiquitin in regulation of GPCR function. Ubiquitination is known to target many GPCRs for lysosomal degradation, and current studies now indicate that basal ubiquitination, deubiquitination, and transubiquitination of certain GPCRs are important for controlling cell surface expression and cellular responsiveness. In addition, novel functions for ubiquitin in regulation of GPCR dimers and in mediating differential GPCR regulation induced by biased agonists have been reported. We will discuss the implications of these new discoveries for ubiquitin regulation of GPCR function in the context of drug development.     

The G-protein coupled receptor family: actors with many faces

G-protein coupled receptors (GPCRs) comprise the largest family of proteins in our body, which have many important physiological functions and are implicated in the pathophysiology of many serious diseases. GPCRs therefore are significant targets in pharmaceutical research. GPCRs share the common architecture of seven plasma membrane-spanning segments connected to each other with three extracellular and three intracellular loops. In addition, GPCRs contain an extracellular N-terminal region and an intracellular C-terminal tail. GPCRs could stimulate different intracellular G-proteins (internal stimuli) and signaling pathways after their interaction with different ligands (external stimuli). The exceptional functional plasticity of GPCRs could be attributed to their inherent dynamic nature to adopt different active conformations, which are stabilized differentially by different stimuli as well as by several mutations. This review describes the structural changes of GPCRs associated with their activation. Understanding the dynamic nature of GPCRs could potentially contribute in the development of future structure-based approaches to design new receptor-specific, signaling-selective ligands, which will enrich the pharmaceutical armamentarium against various diseases.     

Trafficking of delta-opioid receptors and other G-protein-coupled receptors: implications for pain and analgesia

A cell can regulate how it interacts with its external environment by controlling the number of plasma membrane receptors that are accessible for ligand stimulation. G-protein-coupled receptors (GPCRs) are the largest superfamily of cell surface receptors and have a significant role in physiological and pathological processes. Much research effort is now focused on understanding how GPCRs are delivered to the cell surface to enhance the number of 'bioavailable' receptors accessible for activation. Knowing how such processes are triggered or modified following induction of various pathological states will inevitably identify new therapeutic strategies for treating various diseases, including chronic pain. Here, we highlight recent advances in this field, and provide examples of the importance of such trafficking events in pain.     

G protein-coupled receptors: novel targets for drug discovery in cancer

G protein-coupled receptors (GPCRs) belong to a superfamily of cell surface signalling proteins that have a pivotal role in many physiological functions and in multiple diseases, including the development of cancer and cancer metastasis. Current drugs that target GPCRs - many of which have excellent therapeutic benefits - are directed towards only a few GPCR members. Therefore, huge efforts are currently underway to develop new GPCR-based drugs, particularly for cancer. We review recent findings that present unexpected opportunities to interfere with major tumorigenic signals by manipulating GPCR-mediated pathways. We also discuss current data regarding novel GPCR targets that may provide promising opportunities for drug discovery in cancer prevention and treatment.     

Orphan G-protein-coupled receptors : strategies for identifying ligands and potential for use in eating disorders

G-protein-coupled receptors (GPCRs) are key regulators of intercellular interactions, participating in almost every physiological response. They exert their effects by being activated by a variety of endogenous ligands. Traditionally, these ligands were identified first, providing tools to characterise the receptors. However, since the late 1980s, homology screening approaches have allowed the GPCRs to be found first, and in turn used as orphan targets to identify their ligands. Over the last decade this method has led to the identification of 12 novel neuropeptide families. Interestingly, four of these deorphanised GPCR systems, melanin-concentrating hormone, ghrelin, orexin and neuropeptide B/neuropeptide W, have been found to play a role in the control of energy balance. This article reviews the role of these GPCR systems in the control of food intake and energy expenditure, and discusses their potential use in therapies directed at eating disorders. As obesity has reached epidemic proportions across the developed world, pharmacotherapy has focused on this condition. However, difficulties in weight control also characterise disorders of binge eating such as bulimia and binge-eating disorder. Consequently, hypophagic treatments may be of potential benefit in normal, overweight or obese individuals displaying aberrant (out of control) eating behaviour.