G protein-coupled receptor oligomerization provides the framework for signal discrimination

The idea that G protein-coupled receptors (GPCRs) may undergo homo- or hetero-oligomerization, although highly controversial up to a few years ago, has recently gained wide acceptance. The recognition that GPCRs may exhibit either dimeric or oligomeric structures is based upon a large body of biochemical and biophysical evidence. While much effort has been spent to demonstrate the mechanism(s) by which GPCRs interact with each other, the physiological relevance of this phenomenon remains rather elusive. GPCR oligomerization has been proposed to play a role in receptor ontogeny by either chaperoning protein folding or controlling trafficking to the cell surface. However, the acquisition of these roles does not rule out the possibility that oligomeric receptors may have additional functions, once they are brought to the cell surface. Herein, we propose that protein-protein as well as protein-lipid interactions may provide the structural basis for organizing distinct cell compartments along the plasma membrane where different extracellular signals may be perceived and discriminated.     

Homo- and hetero-oligomerization of β2-adrenergic receptor in receptor trafficking,signaling pathways and receptor pharmacology

The β₂-adrenergic receptor (β₂AR) is the prototypic member of G protein-coupled receptors (GPCRs) involved in the production of physiological responses to adrenaline and noradrenaline. Research done in the past few years vastly demonstrated that β₂AR can form homo- and hetero-oligomers. Despite the fact that currently this phenomenon is widely accepted, the spread and relevance of β₂AR oligomerization are still a matter of debate. This review considers the progress achieved in the field of β₂AR oligomerization with focus on the implications of the receptor–receptor interactions to β₂AR trafficking, pharmacology and downstream signal transduction pathways.     

Adenosine receptor containing oligomers: their role in the control of dopamine and glutamate neurotransmission in the brain

While the G protein-coupled receptor (GPCR) oligomerization has been questioned during the last fifteen years, the existence of a multi-receptor complex involving direct receptor-receptor interactions, called receptor oligomers, begins to be widely accepted. Eventually, it has been postulated that oligomers constitute a distinct functional form of the GPCRs with essential receptorial features. Also, it has been proven, under certain circumstances, that the GPCR oligomerization phenomenon is crucial for the receptor biosynthesis, maturation, trafficking, plasma membrane diffusion, and pharmacology and signalling. Adenosine receptors are GPCRs that mediate the physiological functions of adenosine and indeed these receptors do also oligomerize. Accordingly, adenosine receptor oligomers may improve the molecular mechanism by which extracellular adenosine signals are transferred to the G proteins in the process of receptor transduction. Importantly, these adenosine receptor-containing oligomers may allow not only the control of the adenosinergic function but also the fine-tuning modulation of other neurotransmitter systems (i.e. dopaminergic and glutamatergic transmission). Overall, we underscore here recent significant developments based on adenosine receptor oligomerization that are essential for acquiring a better understanding of neurotransmission in the central nervous system under normal and pathological conditions.     

Use of fluorescence resonance energy transfer to analyze oligomerization of G-protein-coupled receptors expressed in yeast

Oligomerization or dimerization of G-protein-coupled receptors (GPCRs) has emerged as an important theme in signal transduction. This concept has recently gained widespread interest due to the application of direct and noninvasive biophysical techniques such as fluorescence resonance energy transfer (FRET), which have shown unequivocally that several types of GPCR can form dimers or oligomers in living cells. Current challenges are to determine which GPCRs can self-associate and/or interact with other GPCRs, to define the molecular principles that govern these specific interactions, and to establish which aspects of GPCR function require oligomerization. Although these questions ultimately must be addressed by using GPCRs expressed endogenously in their native cell types, analysis of GPCR oligomerization in heterologous expression systems will be useful to survey which GPCRs can interact, to conduct structure-function studies, and to identify peptides or small molecules that disrupt GPCR oligomerization and function. Here, we describe methods employing scanning fluorometry to detect FRET between GPCRs tagged with enhanced cyan and yellow fluorescent proteins (CFP and YFP) in living yeast cells. This approach provides a powerful means to analyze oligomerization of a variety of GPCRs that can be expressed in yeast, such as adrenergic, adenosine, C5a, muscarinic acetylcholine, vasopressin, opioid, and somatostatin receptors.     

Oligomerization, biogenesis, and signaling is promoted by a glycophorin A-like dimerization motif in transmembrane domain 1 of a yeast G protein-coupled receptor

G protein-coupled receptors (GPCRs) can form dimeric or oligomeric complexes in vivo. However, the functions and mechanisms of oligomerization remain poorly understood for most GPCRs, including the alpha-factor receptor (STE2 gene product) of the yeast Saccharomyces cerevisiae. Here we provide evidence indicating that alpha-factor receptor oligomerization involves a GXXXG motif in the first transmembrane domain (TM1), similar to the transmembrane dimerization domain of glycophorin A. Results of fluorescence resonance energy transfer, fluorescence microscopy, endocytosis assays of receptor oligomerization in living cells, and agonist binding assays indicated that amino acid substitutions affecting the glycine residues of the GXXXG motif impaired alpha-factor receptor oligomerization and biogenesis in vivo but did not significantly impair agonist binding affinity. Mutant receptors exhibited signaling defects that were not due to impaired cell surface expression, indicating that oligomerization promotes alpha-factor receptor signal transduction. Structure-function studies suggested that the GXXXG motif in TM1 of the alpha-factor receptor promotes oligomerization by a mechanism similar to that used by the GXXXG dimerization motif of glycophorin A. In many mammalian GPCRs, motifs related to the GXXXG sequence are present in TM1 or other TM domains, suggesting that similar mechanisms are used by many GPCRs to form dimers or oligomeric arrays.     

C5a receptor oligomerization. II. Fluorescence resonance energy transfer studies of a human G protein-coupled receptor expressed in yeast

Recent studies demonstrate that members of the superfamily of G protein-coupled receptors (GPCRs) form oligomers both in vitro and in vivo. The mechanisms by which GPCRs oligomerize and the roles of accessory proteins in this process are not well understood. We used disulfide-trapping experiments to show that C5a receptors, expressed in mammalian cells, reside in membranes as oligomers (Klco, J. M., Lassere, T. B., and Baranski, T. J. (2003) J. Biol. Chem. 278, 35345-35353). To begin to address how C5a receptors form oligomers, we now use fluorescence resonance energy transfer experiments on human C5a receptors expressed in the lower eukaryote Saccharomyces cerevisiae. C5a receptors tagged with variants of the green fluorescent protein display energy transfer in intact yeast, demonstrating that mammalian accessory proteins are not required for C5a receptor oligomerization. In both intact yeast cells and membrane preparations, agonist does not affect FRET efficiency, and little energy transfer is observed between the C5a receptor and a co-expressed yeast pheromone receptor (encoded by STE2), indicating that C5a receptor oligomerization is both receptor-specific and constitutive. FRET studies performed on fractionated membranes demonstrate similar levels of energy transfer between tagged C5a receptors in endoplasmic reticulum compared with plasma membrane, and urea washing of membranes has little effect on the extent of energy transfer. The oligomerization of C5a receptors expressed in yeast displays characteristics similar to those observed for other GPCRs studied in mammalian cells. This model system should prove useful for further studies to define mechanisms of oligomerization of mammalian GPCRs.     

Applications of BRET to study dynamic G-protein coupled receptor interactions in living cells

Protein-protein interactions are fundamental processes for manybiological systems including those involving the superfamily ofG-protein coupled receptors (GPCRs). When addressing keyquestions concerning the regulation of GPCR-protein complexes andtheir functional significance, the development and refinement ofnon-invasive techniques to study these interactions will be ofgreat value. One such technique, bioluminescence resonanceenergy transfer (BRET), is a recently described biophysicalmethod that represents a powerful tool with which to measureprotein-protein interactions in live cells, in real time. Thisminireview highlights the impact that evolving techniques such asBRET have had on the study of dynamic protein interactionsinvolving GPCRs. In particular, the application of BRET to thestudy of protein interactions involving the receptors forhypothalamic peptide hormones, thyrotropin-releasing hormone(TRH) and gonadotropin-releasing hormone (GnRH), will bediscussed. Using these receptors, BRET has successfully beenused to demonstrate formation of both agonist-dependent andindependent GPCR-GPCR complexes (oligomerization) and theagonist-dependent interaction of GPCRs with their intracellularadaptor protein partners, the arrestins. In summary, BRET is ahighly sensitive method that will not only aid in advancing ourunderstanding of GPCR signalling and trafficking but could alsopotentially lead to the development of novel therapeutics thattarget these GPCR-protein complexes.     

Applications of BRET to study dynamic G-protein coupled receptor interactions in living cells

Summary Protein-protein interactions are fundamental processes for many biological systems including those involving the superfamily of G-protein coupled receptors (GPCRs). When addressing key questions concerning the regulation of GPCR-protein complexes and their functional significance, the development and refinement of non-invasive techniques to study these interactions will be of great value. One such technique, bioluminescence resonance energy transfer (BRET), is a recently described biophysical method that represents a powerful tool with which to measure protein-protein interactions in live cells, in real time. This minireview highlights the impact that evolving techniques such as BRET have had on the study of dynamic protein interactions involving GPCRs. In particular, the application of BRET to the study of protein interactions involving the receptors for hypothalamic peptide hormones, thyrotropin-releasing hormone (TRH) and gonadotropin-releasing hormone (GnRH), will be discussed. Using these receptors, BRET has successfully been used to demonstrate formation of both agonist-dependent and independent GPCR-GPCR complexes (oligomerization) and the agonist-dependent interaction of GPCRs with their intracellular adaptor protein partners, the arrestins. In summary, BRET is a highly snnsitive method that will not only aid in advancing our understanding of GPCR signalling and trafficking bout coud also potentially lead to the development of novel therapeutics that target these GPCR-protein complexes.     

Homo- and hetero-oligomerization of G protein-coupled receptors

G protein-coupled receptors (GPCRs) form homo-oligomeric and hetero-oligomeric complexes. This understanding has prompted a re-evaluation of many aspects of GPCR biology, however the concept of receptor complexes has not been fully integrated into the current thinking about GPCR structure and function. Nevertheless, receptor oligomerization is a pivotal aspect of the structure and function of GPCRs that has been shown to have implications for receptor trafficking, signaling, and pharmacology and more intricate models for understanding the physiological roles of these receptors are emerging. Here, we summarize some of the advances made in understanding the structural basis and the functional roles of homo- and hetero- oligomerization in this important group of receptors. Although this discussion focuses primarily on the dopamine receptors, particularly the D2 dopamine receptor, and the opioid and serotonin receptors, we discuss the principles governing the oligomerization of all rhodopsin-like GPCRs and potentially of the entire superfamily of these receptors.     

The study of G-protein coupled receptor oligomerization with computational modeling and bioinformatics

To achieve a structural context for the analysis of G-protein coupled receptor (GPCR) oligomers, molecular modeling must be used to predict the corresponding interaction interfaces. The task is complicated by the paucity of detailed structural data at atomic resolution, and the large number of possible modes in which the bundles of seven transmembrane (TM) segments of the interacting GPCR monomers can be packed together into dimers and/or higher-order oligomers. Approaches and tools offered by bioinformatics can be used to reduce the complexity of this task and, combined with computational modeling, can serve to yield testable predictions for the structural properties of oligomers. Most of the bioinformatics methods take advantage of the evolutionary relation that exists among GPCRs, as expressed in their sequences and measurable in the common elements of their structural and functional features. These common elements are responsible for the presence of detectable patterns of motifs and correlated mutations evident from the alignment of the sequences of these complex biological systems. The decoding of these patterns in terms of structural and functional determinants can provide indications about the most likely interfaces of dimerization/oligomerization of GPCRs. We review here the main approaches from bioinformatics, enhanced by computational molecular modeling, that have been used to predict likely interfaces of dimerization/oligomerization of GPCRs, and compare results from their application to rhodopsin-like GPCRs. A compilation of the most frequently predicted GPCR oligomerization interfaces points to specific regions of TMs 4-6.     

Monomeric G-protein-coupled receptor as a functional unit

Rhodopsin, the first purified G-protein-coupled receptor (GPCR), was characterized as a functional monomer 30 year ago, but dimerization of GPCRs recently became the new paradigm of signal transduction. It has even been claimed, on the basis of recent biophysical and biochemical studies, that this new concept could be extended to higher-order oligomerization. Here this view is challenged. The new studies of rhodopsin and other simple (class 1a) GPCRs solubilized in detergent are re-assessed and are compared to the earlier classical studies of rhodopsin and other membrane proteins solubilized in detergent. The new studies are found to strengthen rather than invalidate the conclusions of the early ones and to support a monomeric model for rhodopsin and other class 1a GPCRs. A molecular model is proposed for the functional coupling of a rhodopsin monomeric unit with a G-protein heterotrimer. This model should be valid even for GPCRs that exist as structural dimers.     

Oligomerization of the alpha and beta isoforms of the thromboxane A2 receptor: relevance to receptor signaling and endocytosis

Thromboxane A(2) (TXA(2)) is a potent mediator of inflammation, vasoconstriction and oxidative stress. The TXA(2) receptor (TP) is a G protein-coupled receptor (GPCR) that is expressed as two alternatively spliced isoforms, alpha (343 residues) and beta (407 residues) that share the first 328 residues. For many years GPCRs were assumed to exist and function as monomeric species, but increasing evidence suggests that a dimer is the minimal functional unit of GPCRs. In the present report, using co-immunoprecipitation of differentially tagged TP expressed in HEK293 cells, we demonstrate that TPalpha and TPbeta form homo- and hetero-oligomers. Immunoblotting of lysates from human platelets with an anti-TP specific antibody revealed the presence of endogenously expressed TP oligomers. We show that TP oligomerization is an agonist-independent process highly affected by the reducing agent dithiothreitol suggesting the involvement of disulfide bonds in TP oligomerization. Over-expression of G protein-coupled receptor kinases and arrestins did not modulate the extent of receptor dimerization/oligomerization. Co-expression of two TP signaling-deficient mutants, R60L and E2402R, resulted in rescuing of receptor signal transduction suggesting that dimers/oligomers constitute the functional units of this receptor. Interestingly, TPalpha which does not undergo constitutive or agonist-induced endocytosis on its own was subjected to both types of endocytosis when co-expressed with TPbeta, indicating that TPalpha can display intracellular trafficking when complexed through hetero-oligomerization with TPbeta.     

Identification of G protein-coupled receptor genes from the human genome sequence

We have identified novel G protein-coupled receptors (GPCRs) with no introns in the coding region from the human genome sequence: 322 olfactory receptors; 22 taste receptors; 128 registered GPCRs for endogenous ligands; 50 novel GPCR candidates homologous to registered GPCRs for endogenous ligands; and 59 novel GPCR candidates not homologous to registered GPCRs. The total number of GPCRs with and without introns in the human genome was estimated to be approximately 950, of which 500 are odorant or taste receptors and 450 are receptors for endogenous ligands.     

荧光互补与光能量共振转移检测B类G蛋白偶联受体PAC1二聚化

G蛋白偶联受体（G—protein couple receptors,GPCRs）是最大的超家族膜受体,其中它的B家族成员垂体腺苷酸环化酶激活肽（PACl）是垂体腺苷酸环化酶激动多肽（PAcAP）的特异受体,介导PAcAP神经保护等功能,是神经系统疾病药物开发的重要靶点之一。二聚化或寡聚化是GPCRs普遍存在的现象,但是目前尚没有关于PACl形成同源二聚体或寡聚体的报道。为了验证PACl也能进行同源二聚化,该文采用生物发光能量转移（bioluminescence resonance energy transfer,BRET）方法进行检测,结果显示不同浓度梯度共转染中国仓鼠卵巢细胞（Chinesehamsterovary,CHO）的PACl一Rluc与PACl一EYFP重组载体,在底物腔肠素h（coelenterazineh）作用下呈现明显的BRET信号。双分子荧光互补（BiFc）检测显示,带有EYFPN端基因标记的PACl与带有EYFPC端基因标记的PACl共转染CHO细胞,能呈现完整的EYFP荧光信号。同时,Westemblot检测也显示,高表达PACl的细胞中可检测到JPACl二聚体的大分子。因此,PACl是能够进行正常同源二聚化的,这个发现将为后续神经损伤药物的开发奠定全新的理论基础,同时也为其他GPCRs同源二聚化的研究起到启发和借鉴作用。     

C5a receptor oligomerization. I. Disulfide trapping reveals oligomers and potential contact surfaces in a G protein-coupled receptor

G protein-coupled receptors (GPCRs), stimulated by hormones and sensory stimuli, act as molecular switches to relay activation to heterotrimeric G proteins. Recent studies suggest that GPCRs form dimeric or oligomeric structures, a phenomenon that has long been established for growth factor receptors. The elucidation of the domains of GPCRs that mediate receptor association is of critical importance for understanding the function of GPCR oligomers. Using a disulfide-trapping strategy to probe the intermolecular contact surfaces, we demonstrate cross-linking of C5a receptors in membranes prepared from both human neutrophils and stably transfected mammalian cells that is mediated by a cysteine in the second intracellular loop. To explore other surfaces that might be involved in the oligomerization of C5a receptors, we constructed receptors with individual cysteines in other intracellular regions. C5a receptors with a cysteine in the first intracellular loop or the carboxyl terminus displayed the fastest kinetics of dimer formation, whereas an intracellular loop 3 cysteine displayed minimal cross-linking. Since the rate of disulfide trapping reflects the proximity of sulfhydryl groups, assuming similar accessibility and flexibility, these results imply a symmetric dimer interface that may involve either transmembrane helices 1 and 2 or helix 4. However, neither model can account for the ability of the native cysteine in the second intracellular loop to mediate efficient crosslinking. Based on these observations, we propose that C5a receptors form higher order oligomers (i.e. tetramers) or clusters in the membrane.     

Influence of MT7 toxin on the oligomerization state of the M1 muscarinic receptor1

Background information. The idea that GPCRs (G‐protein‐coupled receptors) may exist as homo‐ or hetero‐oligomers, although still controversial, is now widely accepted. Nevertheless, the functional roles of oligomerization are still unclear and gaining greater insight into the mechanisms underlying the dynamics of GPCR assembly and, in particular, assessing the effect of ligands on this process seems important. We chose to focus our present study on the effect of MT7 (muscarinic toxin 7), a highly selective allosteric peptide ligand, on the oligomerization state of the hM₁ (human M₁ muscarinic acetylcholine receptor subtype). Results. We analysed the hM₁ oligomerization state in membrane preparations or in live cells and observed the effect of MT7 via four complementary techniques: native‐PAGE electrophoresis analysed by both Western blotting and autoradiography on solubilized membrane preparations of CHO‐M1 cells (Chinese‐hamster ovary cells expressing muscarinic M₁ receptors); FRET (fluorescence resonance energy transfer) experiments on cells expressing differently tagged M₁ receptors using either an acceptor photobleaching approach or a novel fluorescence emission anisotropy technique; and, finally, by BRET (bioluminescence resonance energy transfer) assays. Our results reveal that MT7 seems to protect the M₁ receptor from the dissociating effect of the detergent and induces an increase in the FRET and BRET signals, highlighting its ability to affect the dimeric form of the receptor. Conclusions. Our results suggest that MT7 binds to a dimeric form of hM₁ receptor, favouring the stability of this receptor state at the cellular level, probably by inducing some conformational rearrangements of the pre‐existing muscarinic receptor homodimers.     

The extracellular N-terminal domain and transmembrane domains 1 and 2 mediate oligomerization of a yeast G protein-coupled receptor

G protein-coupled receptors (GPCRs) can form homodimers/oligomers and/or heterodimers/oligomers. The mechanisms used to form specific GPCR oligomers are poorly understood because the domains that mediate such interactions and the step(s) in the secretory pathway where oligomerization occurs have not been well characterized. Here we have used subcellular fractionation and fluorescence resonance energy transfer (FRET) experiments to show that oligomerization of a GPCR (alpha-factor receptor; STE2 gene product) of the yeast Saccharomyces cerevisiae occurs in the endoplasmic reticulum. To identify domains of this receptor that mediate oligomerization, we used FRET and endocytosis assays of oligomerization in vivo to analyze receptor deletion mutants. A mutant lacking the N-terminal extracellular domain and transmembrane (TM) domain 1 was expressed at the cell surface but did not self-associate. In contrast, a receptor fragment containing only the N-terminal extracellular domain and TM1 could self-associate and heterodimerize with wild type receptors. Analysis of other mutants suggested that oligomerization is facilitated by the N-terminal extracellular domain and TM2. Therefore, the N-terminal extracellular domain, TM1, and TM2 appear to stabilize alpha-factor receptor oligomers. These domains may form an interface in contact or domain-swapped oligomers. Similar domains may mediate dimerization of certain mammalian GPCRs.     

Melanocortin receptors form constitutive homo- and heterodimers

A significant number of G protein-coupled receptors are shown to form homo- or heterodimers/oligomers, and oligomerization of GPCRs may be a quite general phenomenon. We have here explored the possibility that the two closely related human melanocortin receptor 1 (MC(1)R) and melanocortin receptor 3 (MC(3)R) form dimers. Using bioluminescence resonance energy transfer (BRET(2)) we demonstrate that MC(1) and MC(3)Rs form homo- and heterodimers, when expressed in Cos-7 cells. Treatment with agonist, partial agonist or antagonists did not modify the BRET(2) signal for any of the receptor pairs studied, suggesting that the dimerization is not regulated by ligand binding. Rather our results indicate that melanocortin receptors exist as constitutively pre-formed dimers.     

Order changes within receptor systems upon ligand binding: receptor tightening/oligomerisation and the interpretation of binding parameters

Recent hydrogen-deuterium exchange experiments have highlighted tightening and loosening of protein structures upon ligand binding, with changes in bonding (DeltaH) and order (DeltaS) which contribute to the overall thermodynamics of ligand binding. Tightening and loosening show that ligand binding respectively stabilises or destabilises the internal structure of the protein, i.e. it shows positive or negative cooperativity between ligand binding and the receptor structure. In the case of membrane-bound receptors, such as G protein-coupled receptors (GPCRs) and ligand gated ion channel receptors (LGICRs), most binding studies have focussed on association/dissociation constants. Where these have been broken down into enthalpic and entropic contributions, the phenomenon of "thermodynamic discrimination" between antagonists and agonists has often been noted; e.g. for a receptor where agonist binding is predominantly enthalpy driven, antagonist binding is predominantly entropy driven and vice versa. These data have not previously been considered in terms of the tightening, or loosening, of receptor structures that respectively occurs upon positively, or negatively, cooperative binding of ligand. Nor have they been considered in light of the homo- and hetero-oligomerisation of GPCRs and the possibility of ligand-induced changes in oligomerisation. Here, we argue that analysis of the DeltaH and DeltaS of ligand binding may give useful information on ligand-induced changes in membrane-bound receptor oligomers, relevant to the differing effects of agonists and antagonists.     

Dimerization of G protein-coupled purinergic receptors: increasing the diversity of purinergic receptor signal responses and receptor functions

It is well accepted that G protein-coupled receptors (GPCRs) arrange into dimers or higher-order oligomers that may modify various functions of GPCRs. GPCR-type purinergic receptors (i.e. adenosine and P2Y receptors) tend to form heterodimers with GPCRs not only of the different families but also of the same purinergic receptor families, leading to alterations in functional properties. In the present review, we focus on current knowledge of the formation of heterodimers between metabotropic purinergic receptors that activate novel functions in response to extracellular nucleosides/nucleotides, revealing that the dimerization seems to be employed for ‘fine-tuning’ of purinergic signaling. Thus, the relationship between adenosine and adenosine triphosphate is likely to be more and more intimate than simply being a metabolite of the other.