Constitutive and agonist-induced dimerizations of the P2Y1 receptor: relationship to internalization and scaffolding

In living cells, P2Y(1) receptor dimerization was quantitated by an improved version of fluorescence resonance energy transfer donor photobleaching analysis. 44% of the P2Y(1) receptors expressed in HEK293 cell membranes exist as dimers in the resting state, inducible by agonist exposure to give 85-100% dimerization. Monomer and constitutive dimers are fully active. Agonist-induced dimerization follows desensitization and is fully reversible upon withdrawal of agonist. Receptor dimers are required for internalization at 37 degrees C but are not sufficient; at 20 degrees C dimerization also occurs, but endocytosis is abolished. Removal of the C-terminal 19 amino acids abolished both dimerization and internalization, whereas full activation by agonists was retained up to a loss of 39 amino acids, confirming active monomers. This receptor is known to bind through its last four amino acids (DTSL) to a scaffolding protein, Na/H exchanger regulatory factor-2, which was endogenous here, and DTSL removal blocked constitutive dimerization specifically. Distinction should therefore be made between the following: 1) constitutive dimers tethered to a scaffolding protein, together with effector proteins, within a signaling micro-domain, and 2) free dimers in the cell membrane, which here are inducible by agonist exposure. For the class A G-protein-coupled receptors, we suggest that the percentages of free monomers, and in many cases of induced free dimers, commonly become artifactually increased; this would arise from an excess there of the receptor over its specific scaffold and from a lack of the native targeting of the receptor to that site.     

Dimerization and phosphorylation of thyrotropin-releasing hormone receptors are modulated by agonist stimulation

Dimerization and phosphorylation of thyrotropin-releasing hormone (TRH) receptors was characterized using HEK293 and pituitary GHFT cells expressing epitope-tagged receptors. TRH receptors tagged with FLAG and hemagglutinin epitopes were co-precipitated only if they were co-expressed, and 10-30% of receptors were isolated as hemagglutinin/FLAG-receptor dimers under basal conditions. The abundance of receptor dimers was increased when cells had been stimulated by TRH, indicating that TRH either stabilizes pre-existing dimers or increases dimer formation. TRH increased receptor dimerization and phosphorylation within 1 min in a dose-dependent manner. TRH increased phosphorylation of both receptor monomers and dimers, documented by incorporation of (32)P and an upshift in receptor mobility reversed by phosphatase treatment. The ability of TRH to increase receptor phosphorylation and dimerization did not depend on signal transduction, because it was not inhibited by the phospholipase C inhibitor. Receptor phosphorylation required an agonist but was not blocked by the casein kinase II inhibitor apigenin, the protein kinase C inhibitor GF109203X, or expression of a dominant negative form of G protein-coupled receptor kinase 2. TRH receptors lacking most of the cytoplasmic carboxyl terminus formed dimers constitutively but failed to undergo agonist-induced dimerization and phosphorylation. TRH also increased phosphorylation and dimerization of TRH receptors expressed in GHFT pre-lactotroph cells.     

Identification and molecular characterization of m3 muscarinic receptor dimers.

Several studies suggest, but do not prove directly, that muscarinic receptors may be able to form dimeric or oligomeric arrays. To address this issue in a more direct fashion, we designed a series of biochemical experiments using a modified version of the rat m3 muscarinic receptor (referred to as m3') as a model system. When membrane lysates prepared from m3' receptor-expressing COS-7 cells were subjected to Western blot analysis under non-reducing conditions, several immunoreactive species were observed corresponding in size to putative receptor monomers, dimers, and oligomers. However, under reducing conditions, the monomeric receptor species represented the only detectable immunoreactive protein, consistent with the presence of disulfide-linked m3 receptor complexes. Similar results were obtained when native m3 muscarinic receptors present in rat brain membranes were analyzed. Control experiments carried out in the presence of high concentrations of the SH group alkylating agent, N-ethylmaleimide, suggested that disulfide bond formation did not occur artifactually during the preparation of cell lysates. The formation of m3' receptor dimers/multimers was confirmed in coimmunoprecipitation studies using differentially epitope-tagged m3' receptor constructs. In addition, these studies showed that m3' receptors were also able to form non-covalently associated receptor dimers and that m3' receptor dimer formation was receptor subtype-specific. Immunological studies also demonstrated that m3' receptor dimers/multimers were abundantly expressed on the cell surface. Site-directed mutagenesis studies indicated that two conserved extracellular Cys residues (Cys-140 and Cys-220) play key roles in the formation of disulfide-linked m3' receptor dimers. These results provide the first direct evidence for the existence of muscarinic receptor dimers and highlight the specificity and molecular diversity of G protein-coupled receptor dimerization/oligomerization.     

Interleukin-22 forms dimers that are recognized by two interleukin-22R1 receptor chains

Interleukin-22 (IL-22) is a class 2 cytokine whose primary structure is similar to that of interleukin 10 (IL-10) and interferon-γ (IFN-γ). IL-22 induction during acute phase immune response indicates its involvement in mechanisms of inflammation. Structurally different from IL-10 and a number of other members of IL-10 family, which form intertwined inseparable V-shaped dimers of two identical polypeptide chains, a single polypeptide chain of IL-22 folds on itself in a relatively globular structure. Here we present evidence, based on native gel electrophoresis, glutaraldehyde cross-linking, dynamic light scattering, and small angle x-ray scattering experiments, that human IL-22 forms dimers and tetramers in solution under protein concentrations assessable by these experiments. Unexpectedly, low-resolution molecular shape of IL-22 dimers is strikingly similar to that of IL-10 and other intertwined cytokine dimeric forms. Furthermore, we determine an ab initio molecular shape of the IL-22/IL-22R1 complex which reveals the V-shaped IL-22 dimer interacting with two cognate IL-22R1 molecules. Based on this collective evidence, we argue that dimerization might be a common mechanism of all class 2 cytokines for the molecular recognition with their respective membrane receptor. We also speculate that the IL-22 tetramer formation could represent a way to store the cytokine in nonactive form at high concentrations that could be readily converted into functionally active monomers and dimers upon interaction with the cognate cellular receptors.     

Human bradykinin B2 receptor sialylation and N-glycosylation participate with disulfide bonding in surface receptor dimerization

G-Protein-coupled receptors (GPCRs) act on the cell surface where they recognize and convert external stimuli to modulate cellular activity and are regulated by agonist and various partner molecules. We here studied the cell surface post-translationally modified forms of a GPCR, the human bradykinin B2 receptor. This was by means of detailed molecular analysis of the cell surface forms of N-glycosylation site mutant and wild-type receptors that were treated with glycosidases, neuraminidase, and/or the reducing agent dithiothreitol or not treated before Western blotting. We found that the receptor undergoes similar glycosylation processes and similar cell surface organization in CHO-K1 and HEK 293 cells, used for stable and transient receptor expression, respectively. The receptor is present as dimers and monomers on the cell surface. The dimers result from heterologous association of differently glycosylated mature receptor molecules. Importantly, receptor sialylation and N-glycosylation participate with disulfide bonding in the stabilization of the cell surface human B2 receptor dimers.     

Full characterization of GPCR monomer-dimer dynamic equilibrium by single molecule imaging

Receptor dimerization is important for many signaling pathways. However, the monomer-dimer equilibrium has never been fully characterized for any receptor with a 2D equilibrium constant as well as association/dissociation rate constants (termed super-quantification). Here, we determined the dynamic equilibrium for the N-formyl peptide receptor (FPR), a chemoattractant G protein-coupled receptor (GPCR), in live cells at 37°C by developing a single fluorescent-molecule imaging method. Both before and after liganding, the dimer-monomer 2D equilibrium is unchanged, giving an equilibrium constant of 3.6 copies/μm(2), with a dissociation and 2D association rate constant of 11.0 s(-1) and 3.1 copies/μm(2)s(-1), respectively. At physiological expression levels of ～2.1 receptor copies/μm(2) (～6,000 copies/cell), monomers continually convert into dimers every 150 ms, dimers dissociate into monomers in 91 ms, and at any moment, 2,500 and 3,500 receptor molecules participate in transient dimers and monomers, respectively. Not only do FPR dimers fall apart rapidly, but FPR monomers also convert into dimers very quickly.     

Functional and structural characterization of rhodopsin oligomers

A major question in G protein-coupled receptor signaling concerns the quaternary structure required for signal transduction. Do these transmembrane receptors function as monomers, dimers, or larger oligomers? We have investigated the oligomeric state of the model G protein-coupled receptor rhodopsin (Rho), which absorbs light and initiates a phototransduction-signaling cascade that forms the basis of vision. In this study, different forms of Rho were isolated using gel filtration techniques in mild detergents, including n-dodecyl-beta-D-maltoside, n-tetradecyl-beta-D-maltoside, and n-hexadecyl-beta-D-maltoside. The quaternary structure of isolated Rho was determined by transmission electron microscopy, demonstrating that in micelles containing n-dodecyl-beta-D-maltoside, Rho exists as a mixture of monomers and dimers whereas in n-tetradecyl-beta-D-maltoside and n-hexadecyl-beta-D-maltoside Rho forms higher ordered structures. Especially in n-hexadecyl-beta-D-maltoside, most of the particles are present in tightly packed rows of dimers. The oligomerization of Rho seems to be important for interaction with its cognate G protein, transducin. Although the activated Rho (Meta II) monomer or dimers are capable of activating the G protein, transducin, the activation process is much faster when Rho exists as organized dimers. Our studies provide direct comparisons between signaling properties of Meta II in different quaternary complexes.     

Cross-linking of receptor-bound IgE to aggregates larger than dimers leads to rapid immobilization

Controlled cross-linking of IgE-receptor complexes on the surface of rat basophilic leukemia cells and mast cells has allowed a comparison of the lateral mobility and cell triggering activity of monomers, dimers, and higher oligomers of receptors. Addition of a monoclonal anti-IgE(Fc) antibody to IgE-sensitized cells in stoichiometric amounts relative to IgE produces IgE-receptor dimers with high efficiency. These dimers are nearly as mobile as IgE-receptor monomers and trigger cellular degranulation poorly, but in the presence of 30% D2O, substantial immobilization of the dimers is seen and degranulation activity doubles. Addition of this monoclonal antibody in larger amounts results in the formation of larger oligomeric receptor clusters which are immobile and effectively trigger the cells. Thus, small receptor clusters that are active in stimulating degranulation are immobilized in a process that is not anticipated by simple hydrodynamic theories. Further experiments involving cross-linking of receptor-bound IgE by multivalent antigen demonstrate that immobilization of receptors occurs rapidly (less than 2 min) upon cross-linking and is fully and rapidly reversible by the addition of excess monovalent hapten. The rapidity and reversibility of the immobilization process are entirely consistent with the possibility that immobilization represents a recognition event between clustered receptors and cytoskeleton-associated components that plays an important role early in the cell triggering mechanism.     

Cis- and trans-activation of hormone receptors: the LH receptor

G protein-coupled receptors (GPCRs) accommodate a wide spectrum of activators from ions to glycoprotein hormones. The mechanism of activation for this large and clinically important family of receptors is poorly understood. Although initially thought to function as monomers, there is a growing body of evidence that GPCR dimers form, and in some cases that these dimers are essential for signal transduction. Here we describe a novel mechanism of intermolecular GPCR activation, which we refer to as trans-activation, in the LH receptor, a GPCR that does not form stable dimers. The LH receptor consists of a 350-amino acid amino-terminal domain, which is responsible for high-affinity binding to human CG, followed by seven-transmembrane domains and connecting loops. This seven-transmembrane domain bundle transmits the signal from the extracellular amino terminus to intracellular G proteins and adenylyl cyclase. Here, we show that binding of hormone to one receptor can activate adenylyl cyclase through its transmembrane bundle, intramolecular activation (cis-activation), as well as trans-activation through the transmembrane bundle of an adjacent receptor, without forming a stable receptor dimer. Coexpression of a mutant receptor defective in hormone binding and another mutant defective in signal generation rescues hormone-activated cAMP production. Our observations provide new insights into the mechanism of receptor activation mechanisms and have implications for the treatment of inherited disorders of glycoprotein hormone receptors.     

Bax inserts into the mitochondrial outer membrane by different mechanisms

Bax insertion into the mitochondrial outer membrane is essential for the implementation of apoptosis. However, little is known about the first stage of Bax integration into the mitochondrial outer membrane. We have recently shown that TOM22, a mitochondrial outer membrane receptor, is important for insertion, although other reports have suggested that only mitochondrial lipids are involved in this process. Here, we show that monomers, but not dimers, of Bax require the presence of TOM22 and TOM40 to integrate into mitochondria. In addition we show that once inserted into the membrane, Bax can act as a receptor for cytosolic Bax.     

Proreceptor dimerization is required for insulin receptor post-translational processing

The insulin receptor is a transmembrane protein dimer composed of two alphabeta monomers held together by inter-alpha-chain disulfide bonds. In a previous report we described a monomeric insulin receptor obtained by replacing Cys-524, -682, -683, and -685 with serine. The membrane-bound monomeric insulin receptors could be cross-linked to dimers in the presence of insulin, indicating that although covalent interactions had been abolished, noncovalent dimerization could still occur in the membrane. To eliminate noncovalent dimerization, we replaced all or some of Cys-524, -682, -683, and -685 with arginine or aspartic acid with the expectation that the electrostatic repulsion at these contact sites would prevent noncovalent dimerization. The results indicate that mutant insulin receptors that are able to form covalent dimers are expressed at the wild type level; mutants that can form noncovalent dimers are expressed at half the level of the wild type receptor, whereas insulin receptor mutants that cannot dimerize are expressed at less than 10% of the wild type level. To elucidate the mechanism of the decrease in expression of the mutant insulin receptors, we examined their subcellular localization and biosynthesis. The results suggest that the extent of expression of these mutant receptors is related to their ability to form covalent or noncovalent dimers at the proreceptor stage.     

Interactions and aggregation of apoferritin molecules in solution: effects of added electrolytes

We have studied the structure of the protein species and the protein-protein interactions in solutions containing two apoferritin molecular forms, monomers and dimers, in the presence of Na(+) and Cd(2+) ions. We used chromatographic, and static and dynamic light scattering techniques, and atomic force microscopy (AFM). Size-exclusion chromatography was used to isolate these two protein fractions. The sizes and shapes of the monomers and dimers were determined by dynamic light scattering and AFM. Although the monomer is an apparent sphere with a diameter corresponding to previous x-ray crystallography determinations, the dimer shape corresponds to two, bound monomer spheres. Static light scattering was applied to characterize the interactions between solute molecules of monomers and dimers in terms of the second osmotic virial coefficients. The results for the monomers indicate that Na(+) ions cause strong intermolecular repulsion even at concentrations higher than 0.15 M, contrary to the predictions of the commonly applied Derjaguin-Landau-Verwey-Overbeek theory. We argue that the reason for such behavior is hydration force due to the formation of a water shell around the protein molecules with the help of the sodium ions. The addition of even small amounts of Cd(2+) changes the repulsive interactions to attractive but does not lead to oligomer formation, at least at the protein concentrations used. Thus, the two ions provide examples of strong specificity of their interactions with the protein molecules. In solutions of the apoferritin dimer, the molecules attract even in the presence of Na(+) only, indicating a change in the surface of the apoferritin molecule. In view of the strong repulsion between the monomers, this indicates that the dimers and higher oligomers form only after partial denaturation of some of the apoferritin monomers. These observations suggest that aggregation and self-assembly of protein molecules or molecular subunits may be driven by forces other than those responsible for crystallization and other phase transitions in the protein solution.     

Isolation of four isomers of the 20,000 dalton variant of human pituitary growth hormone

A simple procedure has been developed which for the first time describes the isolation of isomers of the 20,000 dalton variant of human growth hormone (20K hGH). From a human pituitary hormone concentrate different hGH dimers (covalently and noncovalently linked) were enriched by chromatography on SP-Sephadex C-50, DEAE-Sepharose CL-6B and Sephadex G-100. Noncovalently-linked dimers were split by 6 M urea into 20K hGH and 22K hGH monomers. A complete group-separation of 20K hGH and 22K hGH monomers was achieved by chromatography on DEAE-Sepharose CL-6B at neutral pH. The 20K hGH monomer was resolved into four isomers either by preparative isoelectric focusing or by zone electrophoresis in agarose suspension at alkaline pH. The three latter techniques were all used in the presence of 6 M urea. Radioimmunoassay and radioreceptorassay indicated that the isomers obtained were true components of human growth hormone.     

Biochemical and biophysical characterization of serotonin 5-HT2C receptor homodimers on the plasma membrane of living cells

While many studies have provided evidence of homodimerization and heterodimerization of G-protein-coupled receptors (GPCRs), few studies have used fluorescence resonance energy transfer (FRET) combined with confocal microscopy to visualize receptor dimerization on the plasma membrane, and there have been no reports demonstrating the expression of serotonin receptor dimers/oligomers on the plasma membrane of living cells. In the study presented here, biochemical and biophysical techniques were used to determine if 5-HT(2C) receptors exist as homodimers on the plasma membrane of living cells. Immunoprecipitation followed by Western blotting revealed the presence of immunoreactive bands the predicted size of 5-HT(2C) receptor monomers and homodimers that were detergent and cross-linker sensitive. Bioluminescence resonance energy transfer (BRET) was assessed in HEK293 cells expressing 5-HT(2C) receptors labeled with Renilla luciferase and yellow fluorescent protein. BRET levels were not altered by pretreatment with serotonin. Confocal microscopy provided direct visualization of FRET on the plasma membrane of live cells expressing 5-HT(2C) receptors labeled with cyan (donor) and yellow (acceptor) fluorescent proteins. FRET, assessed by acceptor photobleaching, was dependent on the donor/acceptor ratio and independent of acceptor expression levels, indicating that FRET resulted from receptor clustering and not from overexpression of randomly distributed receptors, providing evidence for GPCR dimers/oligomers in a clustered distribution on the plasma membrane. The results of this study suggest that 5-HT(2C) receptors exist as constitutive homodimers on the plasma membrane of living cells. In addition, a confocal-based FRET method for monitoring receptor dimerization directly on the plasma membrane of living cells is described.     

Allosteric functioning of dimeric class C G-protein-coupled receptors

Whereas most membrane receptors are oligomeric entities, G-protein-coupled receptors have long been thought to function as monomers. Within the last 15 years, accumulating data have indicated that G-protein-coupled receptors can form dimers or even higher ordered oligomers, but the general functional significance of this phenomena is not yet clear. Among the large G-protein-coupled receptor family, class C receptors represent a well-recognized example of constitutive dimers, both subunits being linked, in most cases, by a disulfide bridge. In this review article, we show that class C G-protein-coupled receptors are multidomain proteins and highlight the importance of their dimerization for activation. We illustrate several consequences of this in terms of specific functional properties and drug development.     

Protein kinase C inhibition of the epidermal growth factor receptor tyrosine protein kinase activity is independent of the oligomeric state of the receptor

Treatment of A431 human epidermoid carcinoma cells with 4-phorbol 12-myristate 13-acetate (PMA) causes an inhibition of the high affinity binding of epidermal growth factor (EGF) to cell surface receptors and an inhibition of the EGF receptor tyrosine protein kinase activity. The hypothesis that PMA controls EGF receptor function by regulating the oligomeric state of the receptor was tested. Dimeric EGF receptors bound to 125I-EGF were identified by covalent cross-linking analysis using disuccinimidyl suberimidate. Treatment of cells with PMA in the presence of 20 nM 125I-EGF caused no significant change in the level of labeled cross-linked monomeric and dimeric receptor species. Investigation of the in vitro autophosphorylation of receptor monomers and dimers cross-linked with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide demonstrated that the treatment of cells with PMA caused an inhibition of the tyrosine phosphorylation of both monomeric and dimeric EGF receptors. We conclude that the inhibition of the EGF receptor tyrosine protein kinase activity caused by PMA is not associated with the regulation of the oligomeric state of the EGF receptor.     

Isolation of Four Isomers of the 20,000 Dalton Variant of Human Pituitary Growth Hormone

A simple procedure has been developed which for the first time describes the isolation of isomers of the 20, 000 dalton variant of human growth hormone (20K hGH). From a human pituitary hormone concentrate different hGH dimers (covalently and noncova-lently linked) were enriched by chromatography on SP-Sephadex C-50, DEAE-Sepharose CL-6B and Sephadex G-100. Noncovalently-1inked dimers were split by 6 M urea into 20K hGH and 22K hGH monomers. A complete group-separation of 20K hGH and 22K hGH monomers was achieved by chromatography on DEAE-Sepharose CL-6B at neutral pH. The 20K hGH monomer was resolved into four isomers either by preparative isoelectric focusing or by zone electrophoresis in agarose suspension at alkaline pH. The three latter techniques were all used in the presence of 6 M urea. Radioimmunoassay and radioreceptorassay indicated that the isomers obtained were true components of human growth hormone.     

Synthesis of N-terminally linked protein and peptide dimers by native chemical ligation

Dimerization can be utilized to double the molecular weight of proteins and peptides and potentially increase their avidity of binding to target receptors. These dimerization effects may be utilized to increase in vivo half-lives in a manner similar to PEGylation and may also improve biological activity. In this paper, we report a new strategy for the synthesis of N-terminally linked protein and peptide homodimers utilizing native chemical ligation to conjugate a short dithioester linker to the N-terminal cysteines of protein and peptide monomers to form dimers in a single step. This strategy is general and has been applied to the production of dimers from three recombinantly expressed polypeptides, the IgG binding domain Protein G, an HIV entry inhibitor peptide C37H6, and human interleukin-1 receptor antagonist (IL-1ra). The biological activities of the C37H6 and IL-1ra dimers produced by these methods were retained or even slightly increased when compared to their corresponding monomers.     

An extra cysteine proximal to the transmembrane domain induces differential cross-linking of p185neu and p185neu.

The neu proto-oncogene encodes a receptor tyrosine kinase (p185) that is closely related to the epidermal growth factor receptor. It has been proposed that receptor tyrosine kinases are activated through oligomerization. Because this clustering model predicts that oligomerization of receptors is sufficient to activate them, we determined if p185 can be activated by introducing an extra cysteine proximal to the transmembrane domain. This should induce inter-receptor disulfide bonding and, according to the clustering model, activate the receptor. This amino acid substitution enhanced recovery of both normal and transforming neu proteins as dimers, with normal p185 recovered predominantly as monomers and transforming p185* as dimers. However, the cysteine substitution did not affect the transforming activity of the two proteins.     

Self-association of the low density lipoprotein receptor mediated by the cytoplasmic domain

When the low density lipoprotein (LDL) receptor was solubilized from bovine adrenal cortex membranes and subjected to electrophoresis in the absence of reducing agents, a disulfide-bonded dimeric species was demonstrated. Formation of these covalent bonds was blocked when the tissue was homogenized in the presence of sulfhydryl alkylating agents, indicating that the native receptor was self-associated noncovalently and that the disulfide bond formation occurred only after homogenization. The disulfide-linked dimers were disrupted and the receptor was restored to a monomeric form when inside-out adrenal vesicles were treated with trypsin, suggesting that the disulfide bond formation involved the 50-amino acid cytoplasmic domain of the receptor. When the receptor was solubilized from bovine adrenal cortex membranes and then purified by ion exchange and affinity chromatography, it could be covalently coupled into dimers and trimers in the presence of bivalent cross-linking agents. Receptor dimers could also be demonstrated by chemical cross-linking of intact cells that were transfected with an expressible cDNA encoding the normal human LDL receptor. Dimer formation was markedly reduced in transfected cells expressing mutated cDNAs that had premature termination codons at positions 792, 807, and 812, which produced shortened receptors that retained 2, 17, and 22 of the original 50 amino acids of the cytoplasmic domain, respectively. The first two mutant receptors, which did not form oligomers, did not enter coated pits and were not rapidly internalized by cells. However, the mutant receptor that terminates at position 812 was internalized normally even though oligomer formation was greatly reduced. Moreover, a mutant receptor with a cysteine substituted for a tyrosine at position 807, which internalized very slowly, showed a normal susceptibility to chemical cross-linking. Deletion of external domains of the LDL receptor, including the epidermal growth factor homology region and the O-linked sugar domain, did not alter susceptibility to chemical cross-linking. We conclude that the cytoplasmic domain of the LDL receptor is responsible both for self-association into oligomers and for clustering in coated pits, but the available data do not establish a causal connection between these two events.