Subunit interactions of GTP-binding proteins

Optical approaches for single-cell and subcellular analysis of GPCR-G protein signaling

G protein-coupled receptors (GPCRs), G proteins, and their signaling associates are major signal transducers that control the majority of cellular signaling and regulate key biological functions including immune, neurological, cardiovascular, and metabolic processes. These pathways are targeted by over one-third of drugs on the market; however, the current understanding of their function is limited and primarily derived from cell-destructive approaches providing an ensemble of static, multi-cell information about the status and composition of molecules. Spatiotemporal behavior of molecules involved is crucial to understanding in vivo cell behaviors both in health and disease, and the advent of genetically encoded fluorescence proteins and small fluorophore-based biosensors has facilitated the mapping of dynamic signaling in cells with subcellular acuity. Since we and others have developed optogenetic methods to regulate GPCR-G protein signaling in single cells and subcellular regions using dedicated wavelengths, the desire to develop and adopt optogenetically amenable assays to measure signaling has motivated us to take a broader look at the available optical tools and approaches compatible with measuring single-cell and subcellular GPCR-G protein signaling. Here we review such key optical approaches enabling the examination of GPCR, G protein, secondary messenger, and downstream molecules such as kinase and lipid signaling in living cells. The methods reviewed employ both fluorescence and bioluminescence detection. We not only further elaborate the underlying principles of these sensors but also discuss the experimental criteria and limitations to be considered during their use in single-cell and subcellular signal mapping.

Fluorescence/bioluminescence resonance energy transfer techniques to study G-protein-coupled receptor activation and signaling

Fluorescence and bioluminescence resonance energy transfer (FRET and BRET) techniques allow the sensitive monitoring of distances between two labels at the nanometer scale. Depending on the placement of the labels, this permits the analysis of conformational changes within a single protein (for example of a receptor) or the monitoring of protein-protein interactions (for example, between receptors and G-protein subunits). Over the past decade, numerous such techniques have been developed to monitor the activation and signaling of G-protein-coupled receptors (GPCRs) in both the purified, reconstituted state and in intact cells. These techniques span the entire spectrum from ligand binding to the receptors down to intracellular second messengers. They allow the determination and the visualization of signaling processes with high temporal and spatial resolution. With these techniques, it has been demonstrated that GPCR signals may show spatial and temporal patterning. In particular, evidence has been provided for spatial compartmentalization of GPCRs and their signals in intact cells and for distinct physiological consequences of such spatial patterning. We review here the FRET and BRET technologies that have been developed for G-protein-coupled receptors and their signaling proteins (G-proteins, effectors) and the concepts that result from such experiments.

Activation of G-protein-coupled receptors in cell-derived plasma membranes supported on porous beads

G-protein-coupled receptors (GPCRs) are ubiquitous mediators of signal transduction across cell membranes and constitute a very important class of therapeutic targets. In order to study the complex biochemical signaling network coupling to the intracellular side of GPCRs, it is necessary to engineer and control the downstream signaling components, which is difficult to realize in living cells. We have developed a bioanalytical platform enabling the study of GPCRs in their native membrane transferred inside-out from live cells to lectin-coated beads, with both membrane sides of the receptor being accessible for molecular interactions. Using heterologously expressed adenosine A(2A) receptor carrying a yellow fluorescent protein, we showed that the tethered membranes comprised fully functional receptors in terms of ligand and G protein binding. The interactions between the different signaling partners during the formation and subsequent dissociation of the ternary signaling complex on single beads could be observed in real time using multicolor fluorescence microscopy. This approach of tethering inside-out native membranes accessible from both sides is straightforward and readily applied to other transmembrane proteins. It represents a generic platform suitable for ensemble as well as single-molecule measurements to investigate signaling processes at plasma membranes.

Illuminating the life of GPCRs

The investigation of biological systems highly depends on the possibilities that allow scientists to visualize and quantify biomolecules and their related activities in real-time and non-invasively. G-protein coupled receptors represent a family of very dynamic and highly regulated transmembrane proteins that are involved in various important physiological processes. Since their localization is not confined to the cell surface they have been a very attractive "moving target" and the understanding of their intracellular pathways as well as the identified protein-protein-interactions has had implications for therapeutic interventions. Recent and ongoing advances in both the establishment of a variety of labeling methods and the improvement of measuring and analyzing instrumentation, have made fluorescence techniques to an indispensable tool for GPCR imaging. The illumination of their complex life cycle, which includes receptor biosynthesis, membrane targeting, ligand binding, signaling, internalization, recycling and degradation, will provide new insights into the relationship between spatial receptor distribution and function. This review covers the existing technologies to track GPCRs in living cells. Fluorescent ligands, antibodies, auto-fluorescent proteins as well as the evolving technologies for chemical labeling with peptide- and protein-tags are described and their major applications concerning the GPCR life cycle are presented.

Kinetic Analysis of G Protein–Coupled Receptor Signaling Using Fluorescence Resonance Energy Transfer in Living Cells

We describe and review methods for the kinetic analysis of G protein-coupled receptor (GPCR) activation and signaling that are based on optical methods. In particular, we describe the use of fluorescence resonance energy transfer (FRET) as a means of analyzing conformational changes within a single protein (for example a receptor) or between subunits of a protein complex (such as a G protein heterotrimer) and finally between distinct proteins (such as a receptor and a G protein). These methods allow the analysis of signaling kinetics in intact cells with proteins that retain their essential functional properties. They have produced a number of unexpected results: fast receptor activation kinetics in the millisecond range, similarly fast kinetics for receptor-G protein interactions, but much slower activation kinetics for G protein activation.

Self-assembly and applications of biomimetic and bioactive peptide-amphiphiles

Peptide-amphiphiles are amphiphilic structures with a hydrophilic peptide headgroup that incorporates a bioactive sequence and has the potential to form distinct structures, and a hydrophobic tail that serves to align the headgroup, drive self-assembly, and induce secondary and tertiary conformations. In this paper we review the different self-assembled structures of peptide-amphiphiles that range from micelles and nanofibers, to patterned membranes. We also describe several examples where peptide-amphiphiles have found applications as soft bioactive materials for model studies of bioadhesion and characterization of different cellular phenomena, as well as scaffolds for tissue engineering, regenerative medicine, and targeted drug delivery.

Structural flexibility of small GTPases. Can it explain their functional versatility?

Multiple interactions with many different partners are responsible for the amazing functional versatility of proteins, especially those participating in cellular regulation. The structural properties that could facilitate multiple interactions are examined for small GTPases. The role of cellular constraints, compartmentation and scaffolds on protein-protein interactions is considered.

Chemically Distinct Ligands Promote Differential CB1Cannabinoid Receptor-Gi Protein Interactions

To understand how structurally distinct ligands regulate CB(1) receptor interactions with Gi1, Gi2, and Gi3, we quantified the Galphai and betagamma proteins that coimmunoprecipitate with the CB(1) receptor from a detergent extract of N18TG2 membranes in the presence of ligands. A mixture of A, R, G(GDP) (or G_), and ARG(GDP) (or ARG_) complexes was observed in the presence of aminoalkylindole (R)-(+)-[2,3-dihydro-5-methyl-3-(4-morpholinylmethyl)pyrrolo[1,2,3-de]-1,4-benzoxazin-6-yl]-1-naphthalenylmethanone (WIN 55,212-2) for all three RGalphai complexes, cannabinoid desacetyllevonantradol for Galphai1 and Galphai2, and eicosanoid (R)-methanandamide for Galphai3. Desacetyllevonantradol maintained RGalphai3 complexes and (R)-methanandamide maintained RGalphai1 and RGalphai2 complexes even in the presence of a nonhydrolyzable GTP analog. The biaryl pyrazole antagonist N-(piperidin-1-yl)-5-(4-chlorophenyl)-1-(2,4-dichlorophenyl)-4-methyl-1H-pyrazole-3-carboximide hydrochloride (SR141716) maintained all three RGalphai complexes. Gbeta proteins, and to a certain extent Ggamma2, exhibited the same association/dissociation pattern as the Galpha proteins. A GDP analog had no influence on any of these association/dissociation reactions and failed to promote sequestration of G proteins. These results can be explained by invoking the existence of an inverse agonist-supported inactive state in the ternary complex equilibrium model. WIN 55,212-2 behaves as an agonist for all three Gi subtypes; SR141716 behaves as an inverse agonist for all three Gi subtypes; desacetyllevonantradol behaves as an agonist for Gi1 and Gi2, and an inverse agonist at Gi3; and (R)-methanandamide behaves as an inverse agonist at Gi1 and Gi2, and an agonist at Gi3. These ligand-selective G protein responses imply that multiple conformations of the receptor could be evoked by ligands to regulate individual G proteins.

Suramin disrupts receptor-G protein coupling by blocking association of G protein alpha and betagamma subunits

Most drugs target a receptor for a hormone or neurotransmitter. A newer strategy for drug development is to target a downstream signaling element, such as the G protein associated with a receptor. Suramin is considered a lead compound targeting this moiety. It inhibits binding of guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS) to G proteins and reduces agonist binding to G protein-coupled receptors. Suramin is thought to uncouple the G protein from its associated receptor, although there is no direct evidence for this mechanism. We have now examined the effect of suramin on G protein signaling for the vasoactive intestinal peptide (VIP) receptor in lung. The primary experimental strategy was a two-step cross-linking reaction that covalently captures the VIP-receptor-G protein ternary complex. Such cross-linking provided the first direct evidence that suramin physically disrupts receptor-G protein coupling. We investigated how this uncoupling relates to the inhibition of GTPgammaS binding. Suramin indiscriminately hindered the dissociation of various guanine nucleotides from the G protein, implying that its action is not allosteric. Further cross-linking studies suggested that suramin does not obstruct the receptor docking site directly but appears to block the interface between G protein alpha and betagamma subunits. Observations with a purified system of recombinant G protein subunits without a receptor yielded direct evidence that suramin suppresses the association between these subunits. This action can explain how it both disrupts receptor-G protein coupling and inhibits guanine nucleotide release. The improved understanding of suramin's action advances the development of selective inhibitors of G protein signaling.

Arrangement of apolipoprotein A-I in reconstituted high-density lipoprotein disks: an alternative model based on fluorescence resonance energy transfer experiments

The folding and organization of apolipoprotein A-I (apoA-I) in discoidal, high-density lipoprotein (HDL) complexes with phospholipids are not yet completely resolved. For about 20 years, it was generally accepted that the amphipathic helices of apoA-I lie parallel to the acyl chains of the phospholipids ("picket fence" model). However, based on the X-ray crystal structure of a large, lipid-free fragment of apoA-I, a "belt model" was recently proposed. In this model, the helices of two antiparallel apoA-I molecules are extended in a circular arrangement and lie perpendicular to the phospholipid acyl chains. To obtain conclusive information on the spatial organization of apoA-I in discoidal HDL, we engineered three separate cysteine mutants of apoA-I (D9C, A124C, A232C) for specific labeling with the fluorescence probes ALEXA-488 or ALEXA-546 (fluorescein and rhodamine derivatives). The labeled apoA-I was reconstituted into well-defined HDL complexes containing two molecules of protein and dipalmitoylphosphatidylcholine, and the complexes were used in three quantitative fluorescence resonance energy transfer (FRET) experiments to determine the distances between two specific sites in an HDL particle. Comparison of the distances measured by FRET (4.7-7.8 nm) with those predicted from the existing models indicated that neither the picket fence nor the belt model can account for the experimental results; rather, a hairpin folding of each apoA-I monomer with most helices perpendicular to the phospholipid acyl chains and a random head-to-tail and head-to-head arrangement of the two apoA-I molecules in the HDL particles are strongly suggested by the distance and lifetime data.

Localization and signaling of G(beta) subunit Ste4p are controlled by a-factor receptor and the a-specific protein Asg7p

Haploid yeast cells initiate pheromone signaling upon the binding of pheromone to its receptor and activation of the coupled G protein. A regulatory process termed receptor inhibition blocks pheromone signaling when the a-factor receptor is inappropriately expressed in MATa cells. Receptor inhibition blocks signaling by inhibiting the activity of the G protein beta subunit, Ste4p. To investigate how Ste4p activity is inhibited, its subcellular location was examined. In wild-type cells, alpha-factor treatment resulted in localization of Ste4p to the plasma membrane of mating projections. In cells expressing the a-factor receptor, alpha-factor treatment resulted in localization of Ste4p away from the plasma membrane to an internal compartment. An altered version of Ste4p that is largely insensitive to receptor inhibition retained its association with the membrane in cells expressing the a-factor receptor. The inhibitory function of the a-factor receptor required ASG7, an a-specific gene of previously unknown function. ASG7 RNA was induced by pheromone, consistent with increased inhibition as the pheromone response progresses. The a-factor receptor inhibited signaling in its liganded state, demonstrating that the receptor can block the signal that it initiates. ASG7 was required for the altered localization of Ste4p that occurs during receptor inhibition, and the subcellular location of Asg7p was consistent with its having a direct effect on Ste4p localization. These results demonstrate that Asg7p mediates a regulatory process that blocks signaling from a G protein beta subunit and causes its relocalization within the cell.

Receptor inhibition of pheromone signaling is mediated by the Ste4p Gbeta subunit

The pheromone response pathway of the yeast Saccharomyces cerevisiae is initiated in MATa cells by binding of alpha-factor to the alpha-factor receptor. MATa cells in which the a-factor receptor is inappropriately expressed exhibit reduced pheromone signaling, a phenomenon termed receptor inhibition. In cells undergoing receptor inhibition, activation of the signaling pathway occurs normally at early time points but decreases after prolonged exposure to pheromone. Mutations that suppress the effects of receptor inhibition were obtained in the STE4 gene, which encodes the beta-subunit of the G protein that transmits the pheromone response signal. These mutations mapped to the N terminus and second WD repeat of Ste4p in regions that are not part of its Galpha binding surface. A STE4 allele containing several of these mutations, called STE4(SD13), reversed the signaling defect seen at late times in cells undergoing receptor inhibition but had no effect on the basal activity of the pathway. Moreover, the signaling properties of STE4(SD13) were indistinguishable from those of STE4 in wild-type MATa and MATalpha cells. These results demonstrate that the effect of the STE4(SD13) allele is specific to the receptor inhibition function of STE4. STE4(SD13) suppressed the signaling defect conferred by receptor inhibition in a MATa strain containing a deletion of GPA1, the G protein alpha-subunit gene; however, STE4(SD13) had no effect in a MATalpha strain containing a GPA1 deletion. Suppression of receptor inhibition by STE4(SD13) in a MATa strain containing a GPA1 deletion was unaffected by deletion of STE2, the alpha-factor receptor gene. The results presented here are consistent with a model in which an a-specific gene product other than Ste2p detects the presence of the a-factor receptor and blocks signaling by inhibiting the function of Ste4p.

Molecular basis of receptor/G-protein-coupling selectivity

Molecular cloning studies have shown that G-protein-coupled receptors form one of the largest protein families found in nature, and it is estimated that approximately 1000 different such receptors exist in mammals. Characteristically, when activated by the appropriate ligand, an individual receptor can recognize and activate only a limited set of the many structurally closely related heterotrimeric G-proteins expressed within a cell. To understand how this selectivity is achieved at a molecular level has become the focus of an ever increasing number of laboratories. This review provides an overview of recent structural, molecular genetic, biochemical, and biophysical studies that have led to novel insights into the molecular mechanisms governing receptor-mediated G-protein activation and receptor/G-protein coupling selectivity.

Determinants of gi1alpha and beta gamma binding. Measuring high affinity interactions in a lipid environment using flow cytometry

G protein heterocomplex undergoes dissociation and association during its functional cycle. Quantitative measurements of alpha and betagamma subunit binding have been difficult due to a very high affinity. We used fluorescence flow cytometry to quantitate binding of fluorescein-labeled Gi1alpha (F-alpha) to picomolar concentrations of biotinylated G beta gamma. Association in Lubrol solution was rapid (kon = 0.7 x 10(6) M-1 s-1), and equilibrium binding revealed a Kd of 2.9 +/- 0.8 nM. The binding showed a complex dependence on magnesium concentration, but activation of F-alpha with either GDP/aluminum fluoride or guanosine 5'-O-(3-thiotriphosphate) completely prevented formation of the heterocomplex (Kd > 100 nM). The binding was also influenced by the detergent or lipid environment. Unlabeled betagamma reconstituted in biotinylated phospholipid vesicles (pure phosphatidylcholine or mixed brain lipids) bound F-alpha approximately 2-3-fold less tightly (Kd = 6-9 nM) than in Lubrol. In contrast, beta gamma in ionic detergents such as cholate and 3-[(cholamidopropyl)diethylammonio]-1-propanesulfonate exhibited substantially lower affinities for F-alpha. Dissociation of F-alpha from beta gamma reconstituted in lipid vesicles was observed upon addition of aluminum fluoride or excess unlabeled alpha subunit, indicating that myristoylated alpha subunit has only a weak interaction with lipids without the beta gamma subunit. The kinetics of aluminum fluoride-stimulated dissociation were slower than those of the alpha subunit conformational change detected by intrinsic fluorescence. These results quantitatively demonstrate G protein subunit dissociation upon activation and provide a simple but powerful new approach for studying high affinity protein/protein interactions in solution or in a lipid environment.

Reconstitution of bovine A1 adenosine receptors and G proteins in phospholipid vesicles: betagamma-subunit composition influences guanine nucleotide exchange and agonist binding

We have studied the interactions of purified A1 adenosine receptors and G proteins reconstituted into phospholipid vesicles to investigate how the betagamma composition of G protein heterotrimers influences coupling. Recombinant hexahistidine-tagged bovine A1 adenosine receptors were expressed in Sf9 cells and purified to homogeneity by sequential chromatography over heparin-sepharose, xanthine amino congener-agarose, and nickel-nitrilotriacetic acid columns. These receptors were reconstituted with pure recombinant G proteins of defined subunit composition. Receptor-G protein complexes containing alphai2 and beta1gamma2 or beta1gamma3 and stimulated with the agonist, (R)-phenylisopropyladenosine, exchange guanine nucleotide 2-3 times more rapidly than do complexes containing beta1gamma1. This difference is not overcome by increasing the concentration of betagamma subunits. Receptor-G protein complexes containing beta1gamma1 also bind less of the agonist, [125I]-iodoaminobenzyladenosine (125I-ABA), than do complexes containing beta1gamma3. Kinetic experiments show that 125I-ABA dissociates 2-fold more rapidly from receptor-G protein complexes containing beta1gamma1 than from complexes containing the other betagamma subunits. The affinity of the interaction between immobilized Galphai2 subunits and beta1gamma1 or beta1gamma2 measured with an optical biosensor in the absence of receptor is similar. Taken together, these data implicate the gamma-subunit in influencing the interaction between the A1 adenosine receptor and G proteins.

Is signal transduction modulated by an interaction between heterotrimeric G-proteins and tubulin?

Although it is generally accepted that tubulin plays an important role in G-protein-mediated signal transduction in a variety of systems, the mechanism of this phenomenon is not completely understood. G-protein-tubulin interaction at the cell membrane and the cytosol, and the influence of such an interaction on cellular signaling are discussed in this review article. Because the diameter of a microtubule is 25 nm and the plasma membrane is 9-11 nm thick, it is not possible for membrane-associated tubulin to assemble into a complete microtubule in the membrane environment. However, tubulin heterodimers may be able to function in the membrane environment as individual heterodimers or as polymers arranged into short protofilaments. At the cell membrane, membrane-associated tubulin may influence hormone-receptor interaction, receptor-G-protein coupling, and G-protein-effector coupling. Structural proteins, such as tubulin, can participate in cellular signaling by communicating through physical forces. By virtue of its interaction with the submembranous network of cytoskeletal proteins, tubulin, when perturbed in one locus, can transmit large changes in conformations to other points. Thus, GTP binding to membrane-associated tubulin might lead to a conformational change in either receptors or G proteins. This may, in turn, influence the binding of an agonist to its receptor. On the other hand, in the cell cytosol, subsequent to agonist-induced translocation of G-proteins from the membrane compartment to the cytosol, G-proteins may affect microtubule formation. In GH3 and AtT-20 cells (stably expressing TRH receptor), transiently transfected with Gq alpha cDNA, soluble tubulin levels decreased in Gq alpha-transfected GH3 and AtT-20 cells, by 33% and 52%, respectively. These results suggest that G-proteins may have a direct effect on the microtubule function in vivo. Because tubulin and G-protein families are ubiquitous and highly conserved, an interaction between these two protein families may occur in vivo, and this, in turn, can have an impact on signal transduction. However, the physiological significance of this interaction remains to be demonstrated.

G protein beta gamma subunits

Guanine nucleotide binding (G) proteins relay extracellular signals encoded in light, small molecules, peptides, and proteins to activate or inhibit intracellular enzymes and ion channels. The larger G proteins, made up of G alpha beta gamma heterotrimers, dissociate into G alpha and G beta gamma subunits that separately activate intracellular effector molecules. Only recently has the G beta gamma subunit been recognized as a signal transduction molecule in its own right; G beta gamma is now known to directly regulate as many different protein targets as the G alpha subunit. Recent X-ray crystallography of G alpha, G beta gamma, and G alpha beta gamma subunits will guide the investigation of structure-function relationships.

Phospholipase C beta2 association with phospholipid interfaces assessed by fluorescence resonance energy transfer. G protein betagamma subunit-mediated translocation is not required for enzyme activation

Phospholipase C beta2 (PLC beta2) is activated by G protein betagamma subunits and calcium. The enzyme is soluble and its substrate, phosphatidylinositol 4,5-bisphosphate (PIP2), is present in phospholipid membranes. A potential mechanism for regulation of this enzyme is through influencing the equilibrium association of the enzyme with membrane surfaces. In this paper we describe a fluorescence resonance energy transfer (FRET) method for measuring the association of PLC beta2 with phospholipid bilayers. The method allows equilibrium measurements to be made under a variety of conditions, including those that support enzymatic activity and ability to be regulated by G proteins. Using this method it was found that PLC beta2 bound to vesicles containing anionic lipids and demonstrated a selective and unique interaction with PIP2-containing vesicles. The FRET data were corroborated with a centrifugation based method for estimating the affinity of PLC beta2 for vesicles. Apparently different modes of association of PLC beta2 with vesicles of different composition can be distinguished based on alterations in resonance energy transfer efficiency. Association of PLC beta2 with PIP2 vesicles requires an intact lipid bilayer, is blocked by neomycin, and is not affected by D-myo-inositol 1,4,5-trisphosphate (D-IP3). G protein betagamma subunits do not alter the affinity of PLC beta2 for lipid bilayers and at the PIP2 concentrations used to measure betagamma-dependent stimulation of PLC activity, the majority of the PLC beta2 is already associated with the vesicle surface. Furthermore, under conditions where betagamma subunits strongly activate PLC activity, the extent of association with vesicles is unaffected by betagamma subunits or calcium. These results indicate that activation of PLC beta2 by G protein betagamma subunits or Ca2+ in vitro does not involve translocation to the vesicle surface.

Interactions of phosducin with defined G protein beta gamma-subunits

Phosducin has recently been identified as a cytosolic protein that interacts with the beta gamma-subunits of G proteins and thereby may regulate transmembrane signaling. It is expressed predominantly in the retina but also in many other tissues, which raises the question of its potential specificity for retinal versus nonretinal beta gamma-subunits. We have therefore expressed and purified different combinations of beta- and gamma-subunits from Sf9 cells and have also purified transducin-beta gamma from bovine retina and a mixture of beta gamma complexes from bovine brain. Their interactions with phosducin were determined in a variety of assays for beta gamma function: support of ADP-ribosylation of alpha 0 by pertussis toxin, enhancement of the GTPase activity of alpha 0, and enhancement of rhodopsin phosphorylation by the beta-adrenergic receptor kinase 1 (betaARK1). There were only moderate differences in the effects of the various beta gamma complexes alone on alpha 0, but there were marked differences in their ability to support betaARK1 catalyzed rhodopsin phosphorylation. Phosducin inhibited all beta gamma-mediated effects and showed little specificity toward specific defined beta gamma complexes with the exception of transducin-beta gamma (beta1 gamma1), which was inhibited more efficiently than the other beta gamma combinations. In a direct binding assay, there was no apparent selectivity of phosducin for any beta gamma combination tested. Thus, in contrast to betaARK1, phosducin does not appear to discriminate strongly between different G protein beta- and gamma-subunits.

Receptor and membrane interaction sites on Gbeta. A receptor-derived peptide binds to the carboxyl terminus

The functional organization of Gbetagamma is poorly understood. Regions of bovine brain Gbetagamma that interact with a photoaffinity derivative of an alpha2-adrenergic receptor-derived peptide from the third intracellular loop (diazopyruvoyl-modified peptide Q (DAP-Q)) and a hydrophobic membrane probe (3-trifluoromethyl-3-(m-iodophenyl)diazirine (TID)) were examined. We previously showed that DAP-Q cross-links to specific, competable sites on both the alpha and beta subunits of Go/Gi but not on the gamma subunit and that betagamma subunit was required for stimulation of Go/Gi GTPase activity (Taylor, J. M., Jacob Mosier, G. G., Lawton, R. G., Remmers, A. E., and Neubig, R. R. (1994) J. Biol. Chem. 269, 27618-27624). Similarly, we show here that the membrane-associated photoprobe [125I]TID labels alpha and beta but not gamma. We have now mapped the sites of incorporation of DAP-Q and TID into the beta subunit. TID labels both the 14-kDa amino-terminal and the 23-kDa carboxyl-terminal fragments from a partial tryptic digest of beta while DAP-Q labels only the carboxyl-terminal fragment. Further mapping with endopeptidase Lys C reveals substantial labeling of multiple fragments by TID while DAP-Q labels predominantly a approximately 6-kDa fragment within the carboxyl-terminal 60 amino acids of beta1. Thus, regions within the 7th (or possibly 6th) WD-40 repeat of the beta subunit of G protein interact with the receptor-derived peptide while membrane interaction involves multiple sites throughout the beta subunit.

Covalent attachment of functionalized lipid bilayers to planar waveguides for measuring protein binding to biomimetic membranes

A new method is presented for measuring sensitively the interactions between ligands and their membrane-bound receptors in situ using integrated optics, thus avoiding the need for additional labels. Phospholipid bilayers were attached covalently to waveguides by a novel protocol, which can in principle be used with any glass-like surface. In a first step, phospholipids carrying head-group thiols were covalently immobilized onto SiO2-TiO2 waveguide surfaces. This was accomplished by acylation of aminated waveguides with the heterobifunctional crosslinker N-succinimidyl-3-maleimidopropionate, followed by the formation of thioethers between the surface-grafted maleimides and the synthetic thiolipids. The surface-attached thiolipids served as hydrophobic templates and anchors for the deposition of a complete lipid bilayer either by fusion of lipid vesicles or by lipid self-assembly from mixed lipid/detergent micelles. The step-by-step lipid bilayer formation on the waveguide surface was monitored in situ by an integrated optics technique, allowing the simultaneous determination of optical thickness and one of the two refractive indices of the adsorbed organic layers. Surface coverages of 50-60% were calculated for thiolipid layers. Subsequent deposition of POPC resulted in an overall lipid layer thickness of 45-50 A, which corresponds to the thickness of a fluid bilayer membrane. Specific recognition reactions occurring at cell membrane surfaces were modeled by the incorporation of lipid-anchored receptor molecules into the supported bilayer membranes. (1) The outer POPC layer was doped with biotinylated phosphatidylethanolamine. Subsequent specific binding of streptavidin was optically monitored. (2) A lipopeptide was incorporated in the outer POPC monolayer. Membrane binding of monoclonal antibodies, which were directed against the peptide moiety of the lipopeptide, was optically detected. The specific antibody binding correlated well with the lipopepitde concentration in the outer monolayer.

S-prenylated cysteine analogues inhibit receptor-mediated G protein activation in native human granulocyte and reconstituted bovine retinal rod outer segment membranes

We have previously shown that the S-prenylated cysteine analogue N-acetyl-S-trans,trans-farnesyl-L-cysteine (L-AFC) inhibits basal and formyl peptide receptor-stimulated binding of guanosine 5'-O-(3-thiotriphosphate) (GTP[S]) to and hydrolysis of GTP by membranes of HL-60 granulocytes and have presented evidence suggesting that this inhibition was not caused by reduced protein carboxyl methylation [Scheer, A., & Gierschik, P. (1993) FEBS Lett. 319, 110-114]. We now report a detailed analysis of the structural properties of S-prenylated cysteine analogues required for this inhibition and demonstrate that S-prenylcysteines also suppress basal and receptor-stimulated GTP[S] binding to human peripheral neutrophil and HL-60 granulocyte membranes when stimulated by formyl peptide and complement C5a, respectively. S-Prenylcysteines did not affect pertussis toxin-mediated [32P]ADP-ribosylation of Gi proteins. The inhibitory effect of L-AFC was reversible and was not mimicked by farnesylic acid. L-AFC also interfered with GTP[S] binding to retinal transducin when stimulated by light-activated rhodopsin in a reconstituted system. This inhibitory effect was fully reversed upon increasing the concentration of either the G protein beta gamma dimer or the activated receptor. On the basis of these results, we suggest that S-prenylated cysteine analogues like L-AFC inhibit receptor-mediated G protein activation by specifically and reversibly interfering with the interaction of activated receptors with G proteins, most likely with their beta gamma dimers, rather than by inhibiting alpha.beta gamma heterotrimer formation.

Rapid kinetics of G protein subunit association: a rate-limiting conformational change?

G protein subunit association and dissociation are thought to play an important role in signal transduction. We measured alpha beta gamma heterocomplex formation using resonance energy transfer. Fluorescein-labelled alpha(F-alpha) emission was quenched approximately 10% on mixing with eosin-labelled beta gamma(E-beta gamma). Unlabelled beta gamma did not quench F-alpha fluorescence. Stopped-flow kinetics showed a t1/2 ranging from 2.5 s to 0.25 s for 50 nM to 1200 nM E-beta gamma. The rate saturated at high E-beta gamma concentrations consistent with a two-step mechanism. We report the first rapid-mix studies of G protein subunit association kinetics which suggest that alpha and beta gamma combine by a two-step process with a maximal rate of 4.1 +/- 0.4 s-1.

Cloned adenosine A3 receptors: pharmacological properties, species differences and receptor functions

In this review, Joel Linden summarizes what is known about a new and intriguing member of the adenosine receptor family, the A3 receptor. This receptor exhibits unusually large differences in structure, tissue distribution and pharmacological properties between species. Rat A3 receptors are resistant to blockade by xanthine antagonists, but human and sheep A3 receptors can be potently blocked by certain xanthines, notably acidic 8-phenylxanthines. One function of the receptor is to facilitate degranulation of mast cells, and a role for mast cells and A3 receptors in mediating myocardial preconditioning has been proposed. Therefore, selective antagonists of A3 receptors have potential for the treatment of allergic, inflammatory and possibly ischaemic disorders.

Specific enhancement of beta-adrenergic receptor kinase activity by defined G-protein beta and gamma subunits

The beta and gamma subunits of heterotrimeric guanine nucleotide-binding proteins (G proteins) have recently been shown to play an active role in signal transduction. Among other effects they enable translocation of the beta-adrenergic receptor kinase (beta ARK) from the cytosol to the plasma membrane and thus permit phosphorylation and ultimately desensitization of beta-adrenergic receptors and other G-protein-coupled receptors. To investigate the specificity of this effect, we have purified various combinations of recombinant beta and gamma subunits expressed in Sf9 cells and measured their effects on beta ARK-catalyzed phosphorylation of beta 2-adrenergic receptors and of rhodopsin. The combinations tested were beta 1 gamma 2, beta 1 gamma 3, beta 2 gamma 2, beta 2 gamma 3, and transducin beta gamma (beta 1 gamma 1). There were clear differences in enhancement of rhodopsin phosphorylation, with an order of efficacy beta 2 gamma 2 > beta 1 gamma 2 >> beta 2 gamma 3 approximately beta 1 gamma 3 approximately beta 1 gamma 1. The first two combinations had larger effects than a mixed beta gamma preparation from bovine brain. In enhancing phosphorylation of beta 2-adrenergic receptors, beta 1 gamma 2 was more efficient and potent than all other combinations. These data suggest a twofold specificity of beta gamma complexes in enhancing beta ARK-catalyzed receptor phosphorylation: the gamma subunits may be important in interacting with beta ARK, with gamma 2 being more potent than gamma 3, whereas the beta subunits may determine coupling to the receptors, with beta 2 being more effective than beta 1 for rhodopsin and beta 1 being more effective than beta 2 for beta 2-adrenergic receptors.

The mobile receptor hypothesis revisited: a mechanistic role for hormone receptor lateral mobility in signal transduction

Recent application of the technique of fluorescence photobleaching recovery to direct measurement of the lateral mobility of plasma membrane-localized hormone receptors has shed new light on the role of receptor lateral mobility in signal transduction. Receptors for insulin and EGF have been known for some time to be largely immobile at physiological temperatures. This presumably relates to their signal transduction mechanism, which appears to require intermolecular autophosphorylation (receptor aggregation) for activation. In contrast, G-protein coupled receptors must interact with other membrane components to bring about signal transduction, and it is interesting in this regard that the adenylate cyclase (AC) activating vasopressin V2-receptor is highly laterally mobile at 37 degrees C. It has recently been possible to reversibly modulate the V2-receptor mobile fraction (f) to largely varying extents, and to demonstrate thereby a direct effect on the maximal rate of in vivo cAMP production at 37 degrees C in response to vasopressin. A direct correlation between f and maximal cAMP production indicates that f may be a key parameter in hormone signal transduction in vivo, especially at sub-KD (physiological) hormone concentrations, with mobile receptors being required to effect G-protein activation.