Coupling mode of receptors and G proteins

Signaling via G-protein-coupled receptors (GPCRs) is crucial to many physiological and pathophysiological processes in multicellular organisms, and GPCRs themselves are targets for important drugs. Classical cell supplementation experiments suggest a collision coupling model, in which receptors and G proteins diffuse randomly within the cell membrane and interact only if receptors are activated. This model is also backed by kinetic and live cell imaging data. According to the challenging theory, receptors and G proteins are precoupled--meaning they are forming stable complexes in the absence of agonist, which prevail during signaling. This model has been favored on the basis of copurification and coimmunoprecipitation of inactive receptors with G proteins and more recently by some approaches measuring energy transfer between labeled receptors and G proteins. This article reviews key findings regarding the receptor/G protein coupling mode, including most recent findings obtained by optical techniques.

Alternative splicing of the guanylyl cyclase-A receptor modulates atrial natriuretic peptide signaling

Atrial (ANP) and B-type natriuretic peptides (BNP) modulate blood pressure and volume through the stimulation of cyclic GMP production by their guanylyl cyclase-A (GC-A) receptor. A novel isoform of GC-A has been identified that is the result of differential splicing of exon 4. The deletion of a 51-bp sequence is predicted to delete 17 amino acids (Lys314-Gln330) in the membrane-distal part of the extracellular domain. Reverse transcription-PCR analyses demonstrated low messenger RNA expression levels of spliced GC-A in all tissues. Homology modeling suggested that the alterations in the protein structure could interfere with ANP binding or signaling. Indeed, functional studies in transfected HEK 293 cells demonstrated that binding of ANP and ANP-induced cyclic GMP formation by GC-ADelta(Lys314-Gln330) were totally abolished. Furthermore, cotransfection studies showed that this GC-A variant forms heterodimers with the wild type receptor and inhibits ligand-inducible cGMP generation. Finally, treatment of mice with angiotensin II (300 ng/kg/min during 7 days) resulted in enhanced pulmonary mRNA expression of spliced GC-A, which was concomitant to diminished GC-A/cGMP responses to ANP. We conclude that alternative splicing can regulate endogenous ANP/GC-A signaling. Angiotensin II-induced alternative splicing of GC-A may represent a novel mechanism for reducing the sensitivity to ANP.

Kinetics of G-protein-coupled receptor signals in intact cells

G-protein-coupled receptors (GPCRs) are the largest group of cell surface receptors. They are stimulated by a variety of stimuli and signal to different classes of effectors, including several types of ion channels and second messenger-generating enzymes. Recent technical advances, most importantly in the optical recording with energy transfer techniques--fluorescence and bioluminescence resonance energy transfer, FRET and BRET--, have permitted a detailed kinetic analysis of the individual steps of the signalling chain, ranging from ligand binding to the production of second messengers in intact cells. The transfer of information, which is initiated by ligand binding, triggers a signalling cascade that displays various rate-controlling steps at different levels. This review summarizes recent findings illustrating the speed and the complexity of this signalling system.

Monitoring receptor signaling by intramolecular FRET

A large variety of techniques has been used to monitor activation of G protein-coupled receptors (GPCRs) both in isolated membranes and in intact cells. However, most of these techniques cannot resolve receptor activation and signaling in space and in time. Here, we describe techniques that allow the temporally and spatially resolved monitoring of these processes by optical recording with energy transfer techniques. Fluorescence and bioluminescence resonance energy transfer, FRET and BRET, are based on energy transfer between two closely spaced probes. The exquisite sensitivity of FRET and BRET to the distance of the two probes makes these techniques ideal tools to study either protein-protein interactions (when the two probes are localized on two different proteins) or conformational changes within a given protein (when the two probes are localized on a single protein). Here, we review the latter approach as a tool to study receptor activation and the levels of the second messengers cAMP and cGMP in intact cells.

Live cell monitoring of mu-opioid receptor-mediated G-protein activation reveals strong biological activity of close morphine biosynthetic precursors

G-protein activation by receptors is generally measured using (35)S-GTPgammaS binding assays in cell membranes and cannot be well assessed in intact cells. We have recently developed a fluorescence resonance energy transfer (FRET)-based approach to monitor G(i)-protein activation in living cells. Here we report that this technique can be used to determine structure-activity relationships of receptor agonists in intact cells. We have recently shown that morphine is biosynthesized de novo by mammals via a multistep pathway different from that in plants. However, the pharmacological properties of morphine precursors are poorly understood. Here, we directly monitored mu-opioid receptor (MOR)-mediated G(i)-protein activation in living cells by FRET and validated this method with classical GTPgammaS binding assays. Receptor binding studies and FRET measurements demonstrated that several (R)-configurated morphine precursors such as (R)-reticuline, salutaridine, salutaridinol, thebaine, and codeine were partial MOR agonists. Some closer precursors such as oripavine, codeinone, and morphinone activated G(i)-proteins as strongly as morphine, but with slightly lower potencies. The more distant the precursors were positioned in the pathway with respect to morphine, the less efficient and potent they were at MOR. Comparison of pharmacological properties of close morphine precursors and concentrations in which they occur in animal tissues suggests that they might activate MOR signaling under physiological conditions. Taken together, our data indicate that FRET-based assays of G-protein activation can serve to determine the abilities of compounds to activate G-protein signaling directly and in living cells.

Increased expression of the auxiliary beta(2)-subunit of ventricular L-type Ca(2)+ channels leads to single-channel activity characteristic of heart failure

Background

Increased activity of single ventricular L-type Ca²⁺-channels (L-VDCC) is a hallmark in human heart failure. Recent findings suggest differential modulation by several auxiliary β-subunits as a possible explanation.

Methods and Results

By molecular and functional analyses of human and murine ventricles, we find that enhanced L-VDCC activity is accompanied by altered expression pattern of auxiliary L-VDCC β-subunit gene products. In HEK293-cells we show differential modulation of single L-VDCC activity by coexpression of several human cardiac β-subunits: Unlike β₁ or β₃ isoforms, β_2a and β_2b induce a high-activity channel behavior typical of failing myocytes. In accordance, β₂-subunit mRNA and protein are up-regulated in failing human myocardium. In a model of heart failure we find that mice overexpressing the human cardiac Ca_V1.2 also reveal increased single-channel activity and sarcolemmal β₂ expression when entering into the maladaptive stage of heart failure. Interestingly, these animals, when still young and non-failing (“Adaptive Phase”), reveal the opposite phenotype, viz: reduced single-channel activity accompanied by lowered β₂ expression. Additional evidence for the cause-effect relationship between β₂-subunit expression and single L-VDCC activity is provided by newly engineered, double-transgenic mice bearing both constitutive Ca_V1.2 and inducible β₂ cardiac overexpression. Here in non-failing hearts induction of β₂-subunit overexpression mimicked the increase of single L-VDCC activity observed in murine and human chronic heart failure.

Conclusions

Our study presents evidence of the pathobiochemical relevance of β₂-subunits for the electrophysiological phenotype of cardiac L-VDCC and thus provides an explanation for the single L-VDCC gating observed in human and murine heart failure.

Real-time optical recording of beta1-adrenergic receptor activation reveals supersensitivity of the Arg389 variant to carvedilol

Antagonists of beta-adrenergic receptors (beta-ARs) have become a main therapeutic regimen for the treatment of heart failure even though the mechanisms of their beneficial effects are still poorly understood. Here, we used fluorescent resonance energy transfer-based (FRET-based) approaches to directly monitor activation of the beta(1)-AR and downstream signaling. While the commonly used beta-AR antagonists metoprolol, bisoprolol, and carvedilol displayed varying degrees of inverse agonism on the Gly389 variant of the receptor (i.e., actively switching off the beta(1)-AR), surprisingly, only carvedilol showed very specific and marked inverse agonist effects on the more frequent Arg389 variant. These specific effects of carvedilol on the Arg389 variant of the beta(1)-AR were also seen for control of beating frequency in rat cardiac myocytes expressing the 2 receptor variants. This FRET sensor permitted direct observation of activation of the beta(1)-AR in living cells in real time. It revealed that beta(1)-AR variants dramatically differ in their responses to diverse beta blockers, with possible consequences for their clinical use.

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.

Cyclic AMP Imaging in Adult Cardiac Myocytes Reveals Far-Reaching β 1 -Adrenergic but Locally Confined β 2 -Adrenergic Receptor–Mediated Signaling

β 1 - and β 2 -adrenergic receptors (βARs) are known to differentially regulate cardiomyocyte contraction and growth. We tested the hypothesis that these differences are attributable to spatial compartmentation of the second messenger cAMP. Using a fluorescent resonance energy transfer (FRET)-based approach, we directly monitored the spatial and temporal distribution of cAMP in adult cardiomyocytes. We developed a new cAMP-FRET sensor (termed HCN2-camps) based on a single cAMP binding domain of the hyperpolarization activated cyclic nucleotide-gated potassium channel 2 (HCN2). Its cytosolic distribution, high dynamic range, and sensitivity make HCN2-camps particularly well suited to monitor subcellular localization of cardiomyocyte cAMP. We generated HCN2-camps transgenic mice and performed single-cell FRET imaging on freshly isolated cardiomyocytes. Whole-cell superfusion with isoproterenol showed a moderate elevation of cAMP. Application of various phosphodiesterase (PDE) inhibitors revealed stringent control of cAMP through PDE4>PDE2>PDE3. The β 1 AR-mediated cAMP signals were entirely dependent on PDE4 activity, whereas β 2 AR-mediated cAMP was under control of multiple PDE isoforms. β 1 AR subtype–specific stimulation yielded ≈2-fold greater cAMP responses compared with selective β 2 -subtype stimulation, even on treatment with the nonselective PDE inhibitor 3-isobutyl-1-methylxanthine (IBMX) (ΔFRET, 17.3±1.3% [β 1 AR] versus 8.8±0.4% [β 2 AR]). Treatment with pertussis toxin to inactivate G i did not affect cAMP production. Localized β 1 AR stimulation generated a cAMP gradient propagating throughout the cell, whereas local β 2 AR stimulation did not elicit marked cAMP diffusion. Our data reveal that in adult cardiac myocytes, β 1 ARs induce far-reaching cAMP signals, whereas β 2 AR-induced cAMP remains locally confined.

Gs activation is time-limiting in initiating receptor-mediated signaling

To analyze individual steps of G(S)-linked signaling in intact cells, we used fluorescence resonance energy transfer (FRET)-based assays for receptor-G protein interaction, G protein activation, and cAMP effector activation. To do so, we developed a FRET-based sensor to directly monitor G(S) activation in living cells. This was done by coexpressing a Galpha(s) mutant, in which a yellow fluorescent protein was inserted, together with cyan fluorescent protein-tagged Gbetagamma subunits and appropriate receptors in HEK293 cells. Together with assays for receptor activation and receptor-G protein interaction, it is possible to characterize large parts of the G(S) signaling cascade. When A(2A)-adenosine or beta(1)-adrenergic receptors are coexpressed with G(S) in HEK293T cells, the receptor-G(S) interaction was on the same time scale as A(2A) receptor activation with a time constant of <50 ms. G(S) activation was markedly slower and around 450 ms with similar kinetics following activation of A(2A)- or beta(1)-receptors. Taken together, our kinetic measurements demonstrate that the rate of G(S) activation limits initiation of G(S)-coupled receptor signaling.

Molecular basis of partial agonism at the neurotransmitter alpha2A-adrenergic receptor and Gi-protein heterotrimer

To characterize the mechanism by which heterotrimeric G-proteins interpret the signals coming from various neurotransmitters of diverse efficacies (agonists and partial agonists) acting on alpha(2A)-adrenergic receptors, we used a fluorescent resonance energy transfer-based approach to study the effects of these partial agonists on the activation process of both the alpha(2A)-adrenergic receptor and its cognate G(i)-protein. We show that ligands of different efficacies switch the receptor into distinct conformational states, which in turn set the speed and extent of the G(i)-protein signaling. Thus, in cells the efficacy by which a receptor responds to diverse ligands is caused by the ability of the G-protein to differentiate between distinct receptor conformations. The data provide a new key characteristic underlying the mechanism of partial agonism at G-protein-coupled receptors.

G protein-coupled receptors serve as mechanosensors for fluid shear stress in neutrophils

Many cells respond to fluid shear stress but in a cell type-specific fashion. Fluid shear stress applied to leukocytes serves to control pseudopod formation, migration, and other functions. Specifically, fresh neutrophils or neutrophilic leukocytes derived from differentiated HL60 cells respond to fluid shear stress by cytoplasmic pseudopod retraction. The membrane elements that sense fluid shear and induce such a specific response are still unknown, however. We hypothesized that membrane receptors may serve as fluid shear sensors. We found that fluid shear decreased the constitutive activity of G protein-coupled receptors (GPCRs). Inhibition of GPCR constitutive activity by inverse agonists abolished fluid shear stress-induced cell area reduction. Among the GPCRs in neutrophils, the formyl peptide receptor (FPR) exhibits relatively high constitutive activity. Undifferentiated HL60 cells that lacked FPR formed few pseudopods and showed no detectable response to fluid shear stress, whereas expression of FPR in undifferentiated HL60 cells caused pseudopod projection and robust pseudopod retraction during fluid shear. FPR small interfering RNA-transfected differentiated HL60 cells exhibited no response to fluid shear stress. These results suggest that GPCRs serve as mechanosensors for fluid shear stress in neutrophils by decreasing its constitutive activity and reducing pseudopod projection.

Dynamics of receptor/G protein coupling in living cells

The interaction of activated G protein-coupled receptors with G proteins is a key event in signal transduction. Here, using a fluorescence resonance energy transfer (FRET)-based assay, we measure directly and in living cells the interaction of YFP-labeled alpha(2A)-adrenergic receptors with CFP-labeled G proteins. Upon agonist stimulation, a small, concentration-dependent increase in FRET was observed. No specific basal FRET was detected in the absence of agonist. Kinetics of the onset of receptor/G protein interaction were <100 ms and depended on expression levels of Galpha. Simultaneously recorded G protein-regulated inwardly rectifying K(+) channel currents revealed a maximal current response already at agonist concentrations producing submaximal FRET amplitudes. By analyzing FRET signals in the presence of a Galpha mutant, which dissociates more slowly from activated receptors, it was demonstrated that only a fraction of wild-type G proteins interacts with the activated receptor at any time. Our data suggest that alpha(2A)-adrenergic receptors and G proteins interact by rapid collision coupling and indicate that there is no significant precoupling between these receptors and G proteins.

G Protein Activation without Subunit Dissociation Depends on a Gαi-specific Region

G proteins transmit a variety of extracellular signals into intracellular responses. The Galpha and Gbetagamma subunits are both known to regulate effectors. Interestingly, the Galpha subunit also determines subtype specificity of Gbetagamma effector interactions. However, in light of the common paradigm that Galpha and Gbetagamma subunits dissociate during activation, a plausible mechanism of how this subtype specificity is generated was lacking. Using a fluorescence resonance energy transfer (FRET)-based assay developed to directly measure mammalian G protein activation in intact cells, we demonstrate that fluorescent Galpha(i1,2,3), Galpha(z), and Gbeta(1)gamma(2) subunits do not dissociate during activation but rather undergo subunit rearrangement as indicated by an activation-induced increase in FRET. In contrast, fluorescent Galpha(o) subunits exhibited an activation-induced decrease in FRET, reflecting subunit dissociation or, alternatively, a distinct subunit rearrangement. The alpha(B/C)-region within the alpha-helical domain, which is much more conserved within Galpha(i1,2,3) and Galpha(z) as compared with that in Galpha(o), was found to be required for exhibition of an activation-induced increase in FRET between fluorescent Galpha and Gbetagamma subunits. However, the alpha(B/C)-region of Galpha(il) alone was not sufficient to transfer the activation pattern of Galpha(i) to the Galpha(o) subunit. Either residues in the first 91 amino acids or in the C-terminal remainder (amino acids 93-354) of Galpha(il) together with the alpha(B/C)-helical region of Galpha(i1) were needed to transform the Galpha(o)-activation pattern into a Galpha(i1)-type of activation. The discovery of subtype-selective mechanisms of G protein activation illustrates that G protein subfamilies have specific mechanisms of activation that may provide a previously unknown basis for G protein signaling specificity.

Phosducin-like Protein Regulates G-Protein βγ Folding by Interaction with Tailless Complex Polypeptide-1α

Phosducin-like protein (PhLP) exists in two splice variants PhLP(LONG) (PhLP(L)) and PhLP(SHORT) (PhLP(S)). Whereas PhLP(L) directly inhibits Gbetagamma-stimulated signaling, the G betagamma-inhibitory mechanism of PhLP(S) is not understood. We report here that inhibition of Gbetagamma signaling in intact HEK cells by PhLP(S) was independent of direct Gbetagamma binding; however, PhLP(S) caused down-regulation of Gbeta and Ggamma proteins. The down-regulation was partially suppressed by lactacystine, indicating the involvement of proteasomal degradation. N-terminal fusion of Gbeta or Ggamma with a dye-labeling protein resulted in their stabilization against down-regulation by PhLP(S) but did not lead to a functional rescue. Moreover, in the presence of PhLP(S), stabilized Ggamma subunits did not coprecipitate with stabilized Gbeta subunits, suggesting that PhLP(S) might interfere with Gbetagamma folding. PhLP(S) and several truncated mutants of PhLP(S) interacted with the subunit tailless complex polypeptide-1alpha (TCP-1alpha) of the CCT chaperonin complex, which is involved in protein folding. Knock-down of TCP-1alpha in HEK cells by small interfering RNA also led to down-regulation of Gbetagamma. We therefore conclude that the strong inhibitory action of PhLP(S) on Gbetagamma signaling is the result of a previously unrecognized mechanism of Gbetagamma-regulation, inhibition of Gbetagamma-folding by interference with TCP-1alpha.

A FlAsH-based FRET approach to determine G protein–coupled receptor activation in living cells

Fluorescence resonance energy transfer (FRET) from cyan to yellow fluorescent proteins (CFP/YFP) is a well-established method to monitor protein-protein interactions or conformational changes of individual proteins. But protein functions can be perturbed by fusion of large tags such as CFP and YFP. Here we use G protein-coupled receptor (GPCR) activation in living cells as a model system to compare YFP with the small, membrane-permeant fluorescein derivative with two arsen-(III) substituents (fluorescein arsenical hairpin binder; FlAsH) targeted to a short tetracysteine sequence. Insertion of CFP and YFP into human adenosine A(2A) receptors allowed us to use FRET to monitor receptor activation but eliminated coupling to adenylyl cyclase. The CFP/FlAsH-tetracysteine system gave fivefold greater agonist-induced FRET signals, similar kinetics (time constant of 66-88 ms) and perfectly normal downstream signaling. Similar results were obtained for the mouse alpha(2A)-adrenergic receptor. Thus, FRET from CFP to FlAsH reports GPCR activation in living cells without disturbing receptor function and shows that the small size of the tetracysteine-biarsenical tag can be decisively advantageous.

Beta-arrestin binding to the beta2-adrenergic receptor requires both receptor phosphorylation and receptor activation

Homologous desensitization of beta2-adrenergic receptors has been shown to be mediated by phosphorylation of the agonist-stimulated receptor by G-protein-coupled receptor kinase 2 (GRK2) followed by binding of beta-arrestins to the phosphorylated receptor. Binding of beta-arrestin to the receptor is a prerequisite for subsequent receptor desensitization, internalization via clathrin-coated pits, and the initiation of alternative signaling pathways. In this study we have investigated the interactions between receptors and beta-arrestin2 in living cells using fluorescence resonance energy transfer. We show that (a) the initial kinetics of beta-arrestin2 binding to the receptor is limited by the kinetics of GRK2-mediated receptor phosphorylation; (b) repeated stimulation leads to the accumulation of GRK2-phosphorylated receptor, which can bind beta-arrestin2 very rapidly; and (c) the interaction of beta-arrestin2 with the receptor depends on the activation of the receptor by agonist because agonist withdrawal leads to swift dissociation of the receptor-beta-arrestin2 complex. This fast agonist-controlled association and dissociation of beta-arrestins from prephosphorylated receptors should permit rapid control of receptor sensitivity in repeatedly stimulated cells such as neurons.

Kinetics of G-protein-coupled receptor signalling and desensitization

The kinetics of G-protein-coupled receptor activation and deactivation has, so far, been measured only indirectly, most frequently by assessing the production of various second messengers. We have developed methods based on fluorescence resonance energy transfer to quantify the kinetics of receptor activation by agonist (measured as conformational change in the receptor), the kinetics of G-protein activation (measured as G-protein subunit rearrangement) and the kinetics of receptor inactivation by arrestins (measured as receptor–arrestin interaction). Using these methods, we show that receptor activation by agonists and signalling to G-proteins occur on the subsecond time scale, whereas receptor desensitization is limited by receptor phosphorylation and proceeds more slowly.

Novel Single Chain cAMP Sensors for Receptor-induced Signal Propagation

cAMP is a universal second messenger of many G-protein-coupled receptors and regulates a wide variety of cellular events. cAMP exerts its effects via cAMP-dependent protein kinase (PKA), cAMP-gated ion channels, and two isoforms of exchange protein directly activated by cAMP (Epac). Here we report the development of novel fluorescent indicators for cAMP based on the cAMP-binding domains of Epac and PKA. Fluorescence resonance energy transfer between variants of green fluorescent protein (enhanced cyan fluorescent protein and enhanced yellow fluorescent protein) fused directly to the cAMP-binding domains was used to analyze spatial and temporal aspects of cAMP-signaling in different cells. In contrast to previously developed PKA-based indicators, these probes are comprised of only a single binding site lacking cooperativity, catalytic properties, and interactions with other proteins and thereby allow us to easily image free intracellular cAMP and rapid signaling events. Rapid beta-adrenergic receptor-induced cAMP signals were observed to travel with high speed ( approximately 40 microm/s) throughout the entire cell body of hippocampal neurons and peritoneal macrophages. The developed indicators could be ubiquitously applied to studying cAMP, its physiological role and spatio-temporal regulation.

Direct optical recording of intrinsic efficacy at a G protein-coupled receptor

Full and partial agonists activate receptors to varying degrees, presumably by inducing full or partial conformational changes in the receptor protein. Varying degrees of partial agonism corresponding to varying intrinsic efficacies have been demonstrated for many compounds acting at G-protein-coupled receptors, but a method to determine intrinsic efficacies directly at the receptor level has so far been lacking. Here we describe a method that allows the direct monitoring of agonist-induced conformational changes in G-protein-coupled receptors. The cyan (CFP) and yellow (YFP) variants of the green fluorescent protein were fused to the receptors. This resulted in fluorescence resonance energy transfer (FRET) between the CFP- and YFP-moieties. The extent of FRET was reduced in the presence of an agonist. The FRET signal strictly followed agonist occupancy of the receptor. Using the alpha(2)-adrenergic receptor as a model system, the full agonist noradrenaline produced a full signal, the partial agonist clonidine produced only a partial signal, and the antagonist phentolamine had no effect. Thus, optical recording of the agonist-induced conformational change in a G-protein-coupled receptor allows the direct analysis of the intrinsic efficacies of agonists.

Gi protein activation in intact cells involves subunit rearrangement rather than dissociation

G protein-coupled receptors transduce diverse extracellular signals, such as neurotransmitters, hormones, chemokines, and sensory stimuli, into intracellular responses through activation of heterotrimeric G proteins. G proteins play critical roles in determining specificity and kinetics of subsequent biological responses by modulation of effector proteins. We have developed a fluorescence resonance energy transfer (FRET)-based assay to directly measure mammalian G protein activation in intact cells and found that Gi proteins activate within 1-2 s, which is considerably slower than activation kinetics of the receptors themselves. More importantly, FRET measurements demonstrated that Galphai- and Gbetagamma-subunits do not dissociate during activation, as has been previously postulated. Based on FRET measurements between Galphai-yellow fluorescent protein and Gbetagamma-subunits that were fused to cyan fluorescent protein at various positions, we conclude that, instead, G protein subunits undergo a molecular rearrangement during activation. The detection of a persistent heterotrimeric composition during G protein activation will impact the understanding of how G proteins achieve subtype-selective coupling to effectors. This finding will be of particular interest for unraveling Gbetagamma-induced signaling pathways.

Measurement of the millisecond activation switch of G protein-coupled receptors in living cells

Hormones and neurotransmitters transduce signals through G protein-coupled receptors (GPCR). Despite their common signaling pathways, however, the responses they elicit have different temporal patterns. To reveal the molecular basis for these differences we have developed a generally applicable fluorescence-based technique for real-time monitoring of the activation switch of GPCRs in living cells. We used such direct measurements to investigate the activation of the alpha(2A)-adrenergic receptor (alpha(2A)AR; neurotransmitter) and the parathyroid hormone receptor (PTHR; hormone) and observed much faster kinetics than expected: approximately 40 ms for the alpha(2A)AR and approximately 1 s for the PTHR. The different switch times are in agreement with the different receptors' biological functions. Agonists and antagonists could rapidly switch the receptors on or off, whereas a partial agonist caused only a partial signal. This approach allows the comparison of agonist and partial agonist intrinsic activities at the receptor level and provides evidence for millisecond activation times of GPCRs.

Regulation of the inward rectifying properties of G-protein-activated inwardly rectifying K+ (GIRK) channels by Gbeta gamma subunits

Gbetagamma subunits are known to bind to and activate G-protein-activated inwardly rectifying K(+) channels (GIRK) by regulating their open probability and bursting behavior. Studying G-protein regulation of either native GIRK (I(KACh)) channels in feline atrial myocytes or heterologously expressed GIRK1/4 channels in Chinese hamster ovary cells and HEK 293 cells uncovered a novel Gbetagamma subunit mediated regulation of the inwardly rectifying properties of these channels. I(KACh) activated by submaximal concentrations of acetylcholine exhibited a approximately 2.5-fold stronger inward rectification than I(KACh) activated by saturating concentrations of acetylcholine. Similarly, the inward rectification of currents through GIRK1/4 channels expressed in HEK cells was substantially weakened upon maximal stimulation with co-expressed Gbetagamma subunits. Analysis of the outward current block underlying inward rectification demonstrated that the fraction of instantaneously blocked channels was reduced when Gbetagamma was over-expressed. The Gbetagamma induced weakening of inward rectification was associated with reduced potencies for Ba(2+) and Cs(+) to block channels from the extracellular side. Based on these results we propose that saturation of the channel with Gbetagamma leads to a conformational change within the pore of the channel that reduced the potency of extracellular cations to block the pore and increased the fraction of channels inert to a pore block in outward direction.

Activation and deactivation kinetics of alpha 2A- and alpha 2C-adrenergic receptor-activated G protein-activated inwardly rectifying K+ channel currents

Although G protein-coupled receptor-mediated signaling is one of the best studied biological events, little is known about the kinetics of these processes in intact cells. Experiments with neurons from alpha(2A)-adrenergic receptor knockout mice suggested that the alpha(2A)-receptor subtype inhibits neurotransmitter release with higher speed and at higher action potential frequencies than the alpha(2C)-adrenergic receptor. Here we investigated whether these functional differences between presynaptic alpha(2)-adrenergic receptor subtypes are the result of distinct signal transduction kinetics of these two receptors and their coupling to G proteins. alpha(2A)- and alpha(2C)-receptors were stably expressed in HEK293 cells at moderate ( approximately 2 pmol/mg) or high (17-24 pmol/mg) levels. Activation of G protein-activated inwardly rectifying K(+) (GIRK) channels was similar in extent and kinetics for alpha(2A)- and alpha(2C)-receptors at both expression levels. However, the two receptors differed significantly in their deactivation kinetics after removal of the agonist norepinephrine. alpha(2C)-Receptor-activated GIRK currents returned much more slowly to base line than did alpha(2A)-stimulated currents. This observation correlated with a higher affinity of norepinephrine at the murine alpha(2C)- than at the alpha(2A)-receptor subtype and may explain why alpha(2C)-adrenergic receptors are especially suited to control sympathetic neurotransmission at low action potential frequencies in contrast to the alpha(2A)-receptor subtype.

Agonist-dependent delivery of M(2) muscarinic acetylcholine receptors to the cell surface after pertussis toxin treatment

The internalization of the M(2) muscarinic cholinergic receptor (mAChR) proceeds through an atypical pathway that is independent of arrestin and clathrin function and shows a unique sensitivity to dynamin when the receptor is expressed in human embryonic kidney 293 cells. In this report we demonstrate that the internalization of the M(2) mAChR was modulated by activation of heterotrimeric G proteins, because treatment with pertussis toxin, which ADP-ribosylates G proteins of the G(i/o) family, caused a significant delay in the onset of internalization of the M(2) mAChR. The effects of pertussis toxin could not be explained by alteration of the agonist-dependent phosphorylation of the M(2) mAChR. The modulation of internalization by pertussis toxin was revealed to be due to recruitment of intracellular receptors to the cell surface upon agonist treatment. Pretreatment with pertussis toxin also greatly increased both the rate and extent of recovery of M(2) mAChRs to the cell surface after agonist-mediated internalization. These results demonstrate a novel aspect involved in the regulation of GPCRs. As with the tightly controlled internalization of GPCRs, the delivery of GPCRs to the cell surface is also highly regulated.

Novel signalling events mediated by muscarinic receptor subtypes

The M2 muscarinic acetylcholine receptor (mAChR) activates Gi protein coupled pathways, such as stimulation of G-protein activated inwardly rectifying K channels (GIRKs). Here we report a novel heterologous desensitization of these GIRK currents, which appeared to be specifically induced by M2/M4 mAChR stimulation, but not via adenosine (Ado) and alpha2-adrenergic receptors (AR). This heterologous desensitization reflected an inhibition of the GIRK signalling pathway downstream of G-protein activation. It was mediated in a membrane-delimited fashion via a PTX insensitive GTP dependent pathway and could be competed with exogenous Gbetagamma. The activation of M3 mAChR/Gq coupled receptors potently inhibited GIRK currents similar as M2 mAChR. By monitoring simultaneously the response of A1 adenosine receptor (AdoR) activation on N-type Ca2+ channels and GIRK channels, the stimulation of M3 mAChR was found to cause an inhibition of the Ado response in both effector systems, suggesting that the inhibition occurred at the level of the G-protein common to both effectors. These results indicated that Gq proteins inhibit pathways that are commonly regulated by Gbetagamma proteins.

Sphingosylphosphocholine is a naturally occurring lipid mediator in blood plasma: a possible role in regulating cardiac function via sphingolipid receptors

Blood plasma and serum contain factors that activate inwardly rectifying GIRK1/GIRK4 K+ channels in atrial myocytes via one or more non-atropine-sensitive receptors coupled to pertussis-toxin-sensitive G-proteins. This channel is also the target of muscarinic M(2) receptors activated by the physiological release of acetylcholine from parasympathetic nerve endings. By using a combination of HPLC and TLC techniques with matrix-assisted laser desorption ionization-time-of-flight MS, we purified and identified sphingosine 1-phosphate (SPP) and sphingosylphosphocholine (SPC) as the plasma and serum factors responsible for activating the inwardly rectifying K+ channel (I(K)). With the use of MS the concentration of SPC was estimated at 50 nM in plasma and 130 nM in serum; those concentrations exceeded the 1.5 nM EC(50) measured in guinea-pig atrial myocytes. With the use of reverse-transcriptase-mediated PCR and/or Western blot analysis, we detected Edg1, Edg3, Edg5 and Edg8 as well as OGR1 sphingolipid receptor transcripts and/or proteins. In perfused guinea-pig hearts, SPC exerted a negative chronotropic effect with a threshold concentration of 1 microM. SPC was completely removed after perfusion through the coronary circulation at a concentration of 10 microM. On the basis of their constitutive presence in plasma, the expression of specific receptors, and a mechanism of ligand inactivation, we propose that SPP and SPC might have a physiologically relevant role in the regulation of the heart.

Novel inhibition of gbetagamma-activated potassium currents induced by M(2) muscarinic receptors via a pertussis toxin-insensitive pathway

G(i) protein-coupled receptors such as the M(2) muscarinic acetylcholine receptor (mAChR) and A(1) adenosine receptor have been shown to activate G protein-activated inwardly rectifying K(+) channels (GIRKs) via pertussis toxin-sensitive G proteins in atrial myocytes and in many neuronal cells. Here we show that muscarinic M(2) receptors not only activate but also reversibly inhibit these K(+) currents when stimulated with agonist for up to 2 min. The M(2) mAChR-mediated inhibition of the channel was also observed when the channels were first activated by inclusion of guanosine 5'-O-(thiotriphosphate) in the pipette. Under these conditions the M(2) mAChR-induced inhibition was quasi-irreversible, suggesting a role for G proteins in the inhibitory process. In contrast, when GIRK currents were maximally activated by co-expressing exogenous Gbetagamma, the extent of acetylcholine (ACh)-induced inhibition was significantly reduced, suggesting competition between the receptor-mediated inhibition and the large pool of available Gbetagamma subunits. The signaling pathway that led to the ACh-induced inhibition of GIRK channels was unaffected by pertussis toxin pretreatment. Furthermore, the internalization and agonist-induced phosphorylation of M(2) mAChR was not required because a phosphorylation- and internalization-deficient mutant of the M(2) mAChR was as potent as the wild-type counterpart. Pharmacological agents modulating various protein kinases or phosphatidylinositol 3-kinase did not affect the inhibition of GIRK currents. Furthermore, the signaling pathway that mediates GIRK current inhibition was found to be membrane-delimited because bath application of ACh did not inhibit GIRK channel activity in cell-attached patches. Other G protein-coupled receptors including M(4) mAChR and alpha(1A) adrenergic receptors also caused the inhibition, whereas other G protein-coupled receptors including A(1) and A(3) adenosine receptors and alpha(2A) and alpha(2C) adrenergic receptors could not induce the inhibition. The presented results suggest the existence of a novel signaling pathway that can be activated selectively by M(2) and M(4) mAChR but not by adenosine receptors and that involves non-pertussis toxin-sensitive G proteins leading to an inhibition of Gbetagamma-activated GIRK currents in a membrane-delimited fashion.

Overexpressed A(1) adenosine receptors reduce activation of acetylcholine-sensitive K(+) current by native muscarinic M(2) receptors in rat atrial myocytes

In adult rat atrial myocytes, muscarinic acetylcholine (ACh)-sensitive K(+) current activated by a saturating concentration of adenosine (I(K(ACh),(Ado))) via A(1) receptors (A(1)Rs) amounts to only 30% of the current activated by a saturating concentration of ACh (I(K(ACh),(ACh))) via muscarinic M(2) receptors. The half-time of activation of I(K(ACh),(Ado)) on a rapid exposure to agonist was approximately 4-fold longer than that of I(K(ACh),(ACh)). Furthermore, I(K(ACh),(Ado)) never showed fast desensitization. To study the importance of receptor density for A(1)R-I(K(ACh),(Ado)) signaling, adult atrial myocytes in vitro were transfected with cDNA encoding for rat brain A(1)R and enhanced green fluorescent protein (EGFP) as a reporter. Whole-cell current was measured on days 3 and 4 after transfection. Time-matched cells transfected with only the EGFP vector served as controls. In approximately 30% of EGFP-positive cells (group I), the density of I(K(ACh),(Ado)) was increased by 72%, and its half-time of activation was reduced. Density and kinetic properties of I(K(ACh),(ACh)) were not affected in this fraction. In approximately 70% of transfection-positive myocytes (group II), the density of I(K(ACh),(ACh)) was significantly reduced, its activation was slowed, and the fast desensitizing component was lost. Adenosine-induced currents were larger in group II than in group I, their activation rate was further increased, and a fast desensitizing component developed. These data indicate that in native myocytes the amplitude and activation kinetics of I(K(ACh),(Ado)) are limited by the expression of A(1)R. Overexpression of A(1)R negatively interferes with signal transduction via the muscarinic M(2) receptor-linked pathway, which might reflect a competition of receptors with a common pool of G proteins. Negative interference of an overexpressed receptor with physiological regulation of a target protein by a different receptor should be considered in attempts to use receptor overexpression for gene therapy.

Proteolytic processing of the C terminus of the alpha(1C) subunit of L-type calcium channels and the role of a proline-rich domain in membrane tethering of proteolytic fragments

Although most L-type calcium channel alpha(1C) subunits isolated from heart or brain are approximately 190-kDa proteins that lack approximately 50 kDa of the C terminus, the C-terminal domain is present in intact cells. To test the hypothesis that the C terminus is processed but remains functionally associated with the channels, expressed, full-length alpha(1C) subunits were cleaved in vitro by chymotrypsin to generate a 190-kDa C-terminal truncated protein and C-terminal fragments of 30-56 kDa. These hydrophilic C-terminal fragments remained membrane-associated. A C-terminal proline-rich domain (PRD) was identified as the mediator of membrane association. The alpha(1C) PRD bound to SH3 domains in Src, Lyn, Hck, and the channel beta(2) subunit. Mutant alpha(1C) subunits lacking either approximately 50 kDa of the C terminus or the PRD produced increased barium currents through the channels, demonstrating that these domains participate in the previously described (Wei, X., Neely, a., Lacerda, A. E. Olcese, r., Stefani, E., Perez-Reyes, E., and Birnbaumer, L. (1994) J. Biol. Chem. 269, 1635-1640) inhibition of channel function by the C terminus.

Functional regulation of L-type calcium channels via protein kinase A-mediated phosphorylation of the beta(2) subunit

Activation of protein kinase A (PKA) through the beta-adrenergic receptor pathway is crucial for the positive regulation of cardiac L-type currents; however it is still unclear which phosphorylation events cause the robust regulation of channel function. In order to study whether or not the recently identified PKA phosphorylation sites on the beta(2) subunit are of functional significance, we coexpressed wild-type (WT) or mutant beta(2) subunits in tsA-201 cells together with an alpha(1C) subunit, alpha(1C)Delta1905, that lacked the C-terminal 265 amino acids, including the only identified PKA site at Ser-1928. This truncated alpha(1C) subunit was similar to the truncated alpha(1C) subunit isolated from cardiac tissue not only in size ( approximately 190 kDa), but also with respect to its failure to serve as a PKA substrate. In cells transfected with the WT beta(2) subunit, voltage-activated Ba(2+) currents were significantly increased when purified PKA was included in the patch pipette. Furthermore, mutations of Ser-478 and Ser-479 to Ala, but not Ser-459 to Ala, on the beta(2) subunit, completely abolished the PKA-induced increase of currents. The data indicate that the PKA-mediated stimulation of cardiac L-type Ca(2+) currents may be at least partially caused by phosphorylation of the beta(2) subunit at Ser-478 and Ser-479.

G-protein coupled receptor kinases as modulators of G-protein signalling

G-protein coupled receptors (GPCRs) comprise one of the largest classes of signalling molecules. A wide diversity of activating ligands induce the active conformation of GPCRs and lead to signalling via heterotrimeric G-proteins and downstream effectors. In addition, a complex series of reactions participate in the 'turn-off' of GPCRs in both physiological and pharmacological settings. Some key players in the inactivation or 'desensitization' of GPCRs have been identified, whereas others remain the target of ongoing studies. G-protein coupled receptor kinases (GRKs) specifically phosphorylate activated GPCRs and initiate homologous desensitization. Uncoupling proteins, such as members of the arrestin family, bind to the phosphorylated and activated GPCRs and cause desensitization by precluding further interactions of the GPCRs and G-proteins. Adaptor proteins, including arrestins, and endocytic machinery participate in the internalization of GPCRs away from their normal signalling milieu. In this review we discuss the roles of these regulatory molecules as modulators of GPCR signalling.

Desensitization of G-protein-coupled receptors in the cardiovascular system

Multiple mechanisms exist to control the signaling and density of G-protein-coupled receptors (GPRs). Upon agonist binding and receptor activation, a series of reactions participate in the turn off or desensitization of GPRs. Many GPRs are phosphorylated by protein kinases and consequently uncoupled from G proteins. In addition, many GPRs are sequestered from the cell surface and become inaccessible to their activating ligands. Both receptor:G protein uncoupling and receptor sequestration may involve the participation of arrestins or other proteins. A model for receptor regulation has been developed from studies of the beta-adrenergic receptor. However, recent studies suggest that other GPRs important in the cardiovascular system, such as the muscarinic cholinergic receptors that regulate heart rate, might be regulated by mechanisms other than those that regulate the beta-adrenergic receptors. This review summarizes our current understanding of the processes involved in the desensitization of GPRs.

Molecular events associated with the regulation of signaling by M2 muscarinic receptors

Multiple events are associated with the regulation of signaling by the M2 muscarinic cholinergic receptors (mAChRs). Desensitization of the attenuation of adenylyl cyclase by the M2 mAChRs appears to involve agonist-dependent phosphorylation of M2 mAChRs by G-protein coupled receptor kinases (GRKs) that phosphorylate the receptors in a serine/threonine rich motif in the 3rd intracellular domain of the receptors. Mutation of residues 307-311 from TVSTS to AVAAA in this domain of the human M2 mAChR results in a loss of receptor/G-protein uncoupling and a loss of arrestin binding. Agonist-induced sequestration of receptors away from their normal membrane environment is also regulated by agonist-induced phosphorylation of the M2 mAChRs on the 3rd intracellular domain, but in HEK cells, the predominant pathway of internalization is not regulated by GRKs or arrestins. This pathway of internalization is not inhibited by a dominant negative dynamin, and does not appear to involve either clathrin coated pits or caveolae. The signaling of the M2 mAChR to G-protein regulated inwardly rectifying K channels (GIRKs) can be modified by RGS proteins. In HEK cells, expression of RGS proteins leads to a constitutive activation of the channels through a mechanism that depends on Gbetagamma. RGS proteins appear to increase the concentration of free Gbetagamma in addition to acting as GAPs. Thus multiple mechanisms acting at either the level of the M2 mAChRs or the G-proteins can contribute to the regulation of signaling via the M2 mAChRs.

A dominant-negative strategy for studying roles of G proteins in vivo

G proteins play a critical role in transducing a large variety of signals into intracellular responses. Increasingly, there is evidence that G proteins may play other roles as well. Dominant-negative constructs of the alpha subunit of G proteins would be useful in studying the roles of G proteins in a variety of processes, but the currently available dominant-negative constructs, which target Mg2+-binding sites, are rather leaky. A variety of studies have implicated the carboxyl terminus of G protein alpha subunits in both mediating receptor-G protein interaction and in receptor selectivity. Thus we have made minigene plasmid constructs that encode oligonucleotide sequences corresponding to the carboxyl-terminal undecapeptide of Galphai, Galphaq, or Galphas. To determine whether overexpression of the carboxyl-terminal peptide would block cellular responses, we used as a test system the activation of the M2 muscarinic receptor activated K+ channels in HEK 293 cells. The minigenes were transiently transfected along with G protein-regulated inwardly rectifying K+ channels (GIRK) into HEK 293 cells that stably express the M2 muscarinic receptor. The presence of the Galphai carboxyl-terminal peptide results in specific inhibition of GIRK activity in response to agonist stimulation of the M2 muscarinic receptor. The Galphai minigene construct completely blocks agonist-mediated M2 mAChR K+ channel response whereas the control minigene constructs (empty vector, pcDNA3.1, and the Galpha carboxyl peptide in random order, pcDNA-GalphaiR) had no effect on agonist-mediated M2 muscarinic receptor GIRK response. The inhibitory effects of the Galphai minigene construct were specific because overexpression of peptides corresponding to the carboxyl terminus of Galphaq or Galphas had no effect on M2 muscarinic receptor stimulation of the K+ channel.

Regulators of G protein signaling (RGS) proteins constitutively activate Gbeta gamma-gated potassium channels

Here we report novel effects of regulators of G protein signaling (RGS) on G protein-regulated ion channels. RGS3 and RGS4 induced a substantial increase in currents through the Gbeta gamma-regulated inwardly rectifying K+ channels, IK(ACh), in the absence of receptor activation. Concomitantly, the amount of current that could be activated by agonist was reduced. Pretreatment with pertussis toxin or a muscarinic receptor antagonist abolished agonist-induced currents but did not modify RGS effects. Cotransfection of cells with a Gbetagamma-binding protein significantly reduced the RGS4-induced basal IK(ACh) currents. The RGS proteins also modified the properties of another Gbeta gamma effector, the N-type Ca2+ channels. These observations strongly suggest that RGS proteins increase the availability of Gbeta gamma in addition to their previously described GTPase-activating function.

Inhibition of muscarinic K+ current in guinea-pig atrial myocytes by PD 81,723, an allosteric enhancer of adenosine binding to A1 receptors

1. PD 81,723 has been shown to enhance binding of adenosine to A1 receptors by stabilizing G protein-receptor coupling ('allosteric enhancement'). Evidence has been provided that in the perfused hearts and isolated atria PD 81,723 causes a sensitization to adenosine via this mechanism. 2. We have studied the effect of PD 81,723 in guinea-pig isolated atrial myocytes by use of whole-cell measurement of the muscarinic K+ current (I[K(ACh)]) activated by different Gi-coupled receptors (A1, M2, sphingolipid). PD 81,273 caused inhibition of I[K(ACh)] (IC50 approximately 5 microM) activated by either of the three receptors. Receptor-independent I[K(ACh)] in cells loaded with GTP-gamma-S and background I[K(ACh)], which contributes to the resting conductance of atrial myocytes, were equally sensitive to PD 81,723. At no combination of concentrations of adenosine and PD 81,723 could an enhancing effect be detected. 3. The compound was active from the outside only. Loading of the cells with PD 81,723 (50 microM) via the patch pipette did not affect either I[K(ACh)] or its sensitivity to adenosine. We suggest that PD 81,723 acts as an inhibitor of inward rectifying K+ channels; this is supported by the finding that ventricular I(K1), which shares a large degree of homology with the proteins (GIRK1/GIRK4) forming I[K(ACh)] but is not G protein-gated, was also blocked by this compound. 4. It is concluded that the functional effects of PD 81,723 described in the literature are not mediated by the A1 adenosine receptor-Gi-I[K(ACh)] pathway.

In vivo downregulation of M2 receptors revealed by measurement of muscarinic K+ current in cultured guinea-pig atrial myocytes

1. Muscarinic K+ current (IK(ACh)) elicited by acetylcholine (ACh) was measured in guinea-pig atrial myocytes, which were either freshly isolated or cultured for up to 8 days. 2. The half-time of activation of inward IK(ACh) by a saturating concentration (10 microM) of ACh decreased from approximately 400 ms (in freshly isolated cells) to 250 ms after 6 days in culture. This was paralleled by an increase in the fast desensitizing component of IK(ACh). The density of steady-state currents was not changed. Downregulation of M2 receptors by long-term treatment of isolated myocytes with carbachol in vitro had opposite effects. 3. The EC50 of ACh for the activation of steady-state IK(ACh) was reduced from 5 x 10(-7) M (day 0) to 8 x 10(-8) M (day 6). The shift in EC50 occurred with a half-time of about 2 days, similar to the recovery from downregulation induced by treating atrial myocytes with carbachol in vitro. 4. The increase in sensitivity to ACh can be accounted for by an approximately 6-fold increase in the density of M2 receptors. 5. It is concluded that sensitization in culture reflects recovery from downregulation of M2 receptors due to the tonic vagal input to the heart in the intact animal.

A novel membrane receptor with high affinity for lysosphingomyelin and sphingosine 1-phosphate in atrial myocytes

Activation of IK(ACh) is the major effect of the vagal neutrotransmitter acetylcholine in the heart. We report that both lysosphingomyelin (D-erythro-sphingosyl-phosphorylcholine; SPC) and sphingosine 1-phosphate (SPP) activate IK(ACh) in guinea pig atrial myocytes through the same receptor with an EC50 of 1.5 and 1.2 nM, respectively. Pertussis toxin abolished the activation of IK(ACh) by either lipid. The putative receptor showed an exquisite stereoselectivity for the naturally occurring D-erythro-(2S,3R)-SPC stereoisomer, the structure of which was confirmed by mass spectroscopy and NMR. These lipids caused complete homologous and heterologous desensitization with each other but not with ACh, indicating that both act on the same receptor. This receptor displays a distinct structure-activity relationship: it requires an unsubstituted amino group because N-acetyl-SPC, lysophosphatidic acid and lysophosphatidylcholine were inactive. Because SPP and SPC are naturally occurring products of membrane lipid metabolism, it appears that these compounds might be important extracellular mediators acting on a family of bona fide G protein-coupled receptors. Expression of these receptors in the heart raises the possibility that sphingolipids may be a part of the physiological and/or pathophysiological regulation of the heart. Based on their ligand selectivity we propose a classification of the sphingolipid receptors.

Downregulation of muscarinic M2 receptors linked to K+ current in cultured guinea-pig atrial myocytes

1. Desensitization of muscarinic K+ current (IK(ACh)) was studied in cultured atrial myocytes from guinea-pig hearts using whole-cell voltage clamp. 2. Three different types of desensitization could be identified. A fast component which upon rapid superfusion with ACh resulted in a partial relaxation of IK(ACh) within a few seconds to a plateau which was maintained in the presence of ACh. Recovery from this type of desensitization paralleled the decay of IK(ACh) after washout of the agonist. A second type of desensitization was observed within minutes. This was reversed around 10 min after washout of ACh. Both types were heterologous with regard to the A1 receptor and the novel phospholipid (Pl) receptor, both of which activate IK(ACh) via the same signalling pathway. 3. A third type of desensitization (downregulation) occurred upon exposure of the cultures for 24-48 h to the muscarinic agonist carbachol (CCh). The level of downregulation depended on the concentration of CCh (0.1 microM < or = [CCh] < or = 10 microM). No recovery was observed within 5 h after washout of CCh. Thereafter sensitivity to ACh slowly returned (half-time (t1/2), approximately 20 h). 4. Downregulation by CCh (0.1-5 microM) was characterized by an increase in EC50 for ACh with no reduction in maximum IK(ACh). With 5 microM CCh, EC50 was increased from 0.1 to 3.7 microM. At 10 microM CCh EC50 was increased to 15 microM and maximal current that could be evoked by ACh was reduced to 15%. 5. Downregulation by CCh was homologous with regard to A1 and Pl receptors. Maximum IK(ACh), assayed by a saturating concentration of Pl, was not reduced in downregulated cells, suggesting a mechanism localized at the M2 receptor. 6. The changes in the concentration-response curves can be accounted for by assuming an excess of M2 receptors relative to the subsequent component of the signalling pathway. 7. As the intact heart is under tonic vagal control, downregulation is likely to contribute to controlling the sensitivity of the heart to vagal activity in situ.

Activation of a high affinity Gi protein-coupled plasma membrane receptor by sphingosine-1-phosphate

Sphingosine-1-phosphate (SPP) has attracted much attention as a possible second messenger controlling cell proliferation and motility and as an intracellular Ca(2+)-releasing agent. Here, we present evidence that SPP activates a G protein-coupled receptor in the plasma membrane of various cells, leading to increase in cytoplasmic Ca2+ concentration ([Ca2+]i), inhibition of adenylyl cyclase, and opening of G protein-regulated potassium channels. In human enbryonic kidney (HEK) cells, SPP potently (EC50, 2 nM) and rapidly increased [Ca2+]i in a pertussis toxin-sensitive manner. Pertussis toxin-sensitive increase in [Ca2+]i was also observed with sphingosylphosphorylcholine (EC50, 460 nM), whereas other sphingolipids, including ceramide-1-phosphate, N-palmitoyl-sphingosine, psychosine, and D-erythro-sphingosine at micromolar concentrations did not or only marginally increased [Ca2+]i. Furthermore, SPP inhibited forskolin-stimulated cAMP accumulation in HEK cells and increased binding of guanosine 5'3-O-(thio) triphosphate to HEK cell membranes. Rapid [Ca2+]i responses were also observed in human transitional bladder carcinoma (J82) cells, monkey COS-1 cells, mouse NIH 3T3 cells, Chinese hamster ovary (CHO-K1) cells, and rat C6 glioma cells, whereas human HL-60 leukemia cells and human erythroleukemia cells failed to respond to SPP. In guinea pig atrial myocytes, SPP activated Gi protein-regulated inwardly rectifying potassium channels. Activation of these channels occurred strictly when SPP was applied at the extracellular face of atrial myocyte plasma membrane as measured in cell-attached and inside-out patch clamp current recordings. We conclude that SPP, in addition to its proposed direct action on intracellular Ca2+ stores, interacts with a high affinity Gi protein-coupled receptor in the plasma membrane of apparently many different cell types.

Activation of muscarinic K+ current in guinea-pig atrial myocytes by sphingosine-1-phosphate

1. Activation of muscarinic K+ current (IK(ACh)) by sphingosine-1-phosphate (Sph-1-P) was studied in isolated cultured guinea-pig atrial myocytes using whole-cell voltage clamp. 2. Sph-1-P caused activation of IK(ACh) with an EC50 of 1.2 nM. The maximal current that could be activated by Sph-1-P amounted to about 90% of the IK(ACh) caused by a saturating concentration of acetylcholine (ACh, 10 microM). Sphingosine (1 microM), which can mimic the signalling effects of Sph-1-P in other cells, failed to cause measurable activation of IK(ACh). 3. IK(ACh) activation by Sph-1-P was completely suppressed in cells treated with pertussis toxin. 4. Desensitization of muscarinic receptors by pre-incubation of the cells with carbachol did not affect the response to Sph-1-P; likewise, pre-incubation of the cells with Sph-1-P resulted in a reduced sensitivity to the phospholipid but not to ACh. In contrast, pre-incubation with either Sph-1-P or a serum phospholipid previously described as activating atrial IK(ACh) resulted in reduced sensitivity to both phospholipids. 5. It is concluded that activation of IK(ACh) by Sph-1-P in atrial myocytes is induced by binding to a novel G protein-coupled phospholipid receptor.

Down-regulation of A1 adenosine receptors coupled to muscarinic K+ current in cultured guinea-pig atrial myocytes

1. Muscarinic K+ current (IK(ACh)) was measured in cultured atrial myocytes from hearts of adult guinea-pigs using whole-cell voltage clamp. IK(ACh) was activated by superfusion with solutions containing either acetylcholine (ACh) or adenosine (Ado), in saturating concentrations of 2 microM (ACh) and 1 mM (Ado), respectively. 2. In freshly isolated cells the amplitude of the current activated by Ado (IK(Ado)) was 58% (mean) of the current that was induced by ACh. In serum-free culture this relation, but also the absolute density of IK(ACh), remained fairly constant for up to 8 days. 3. If the culture medium was supplemented with fetal calf serum (FCS, 5%) the relation IK(Ado)/IK(ACh) gradually decayed, reaching a value of less than 0.1 on days 7-8, whereas the response to ACh remained stable over this period of time. 4. After treatment of cells with FCS-containing medium, no recovery was observed upon FCS withdrawal for up to 4 days. 5. The effect of FCS on responsiveness to Ado was half-maximal at about 1% (v/v). The active principle can be dialysed (mol. mass exclusion: 10 kDa). It is not identical with an albumin-associated factor that has been shown to be a potent activator of atrial IK(ACh) upon acute superfusion. Loss of responsiveness to Ado was paralleled by a reduction of binding sites to the A1 adenosine receptor-specific radioligand 8-cyclopentyl-1,3-dipropylxanthine ([3H]CPX). 6. It is concluded that FCS contains a factor that causes down-regulation of A1 Ado receptors. The signalling pathway that leads to an increased opening activity of IK(ACh) channels and other receptors, such as the M2 muscarinic receptor, linked to this signalling pathway are not affected by this factor.

Membrane-delimited activation of muscarinic K current by an albumin-associated factor in guinea-pig atrial myocytes

Atrial myocytes obtained by enzymatic perfusion of hearts from adult guinea-pigs and cultured for 0-14 days were studied using different configurations of the patch-clamp technique. Activation of muscarinic K current [IK(ACh)] in whole-cell voltage-clamp mode by strongly diluted sera from various sources could be mimicked by corresponding concentrations of albumin, but not by delipidated ("fatty-acid-free") samples of albumin. In cell-attached membrane patches activity of IK(ACh) channels was significantly higher than basal IK(ACh) channel activity, if the pipette contained serum, whereas application of serum-containing solution to the cell outside the patch did not affect channel activity. In isolated inside-out membrane patches, strong IK(ACh) activation by internal guanosine triphosphate (GTP, 5 microM) was observed if the pipette contained serum. If no activator was presented to the outer face of the membrane, only weak opening activity was observed during bath application of GTP. These results demonstrate that the serum factor which causes activation of IK(ACh) is associated with albumin. Furthermore activation of IK(ACh) by that factor proceeds analogous to ACh or adenosine, i.e. via a membrane-delimited receptor, G-protein, channel interaction.

Serum contains a potent factor that decreases beta-adrenergic receptor-stimulated L-type Ca2+ current in cardiac myocytes

L-type Ca2+ current (ICa) was measured in cultured atrial myocytes from hearts of adult guinea-pigs using whole-cell voltage clamp. Potentiation of ICa induced by beta-adrenergic stimulation (isoprenaline 2.10(-7) M) could be completely antagonized by diluted sera (1:100 v/v). Half-maximal inhibition of beta-receptor-stimulated ICa occurred at about 1:1000. Basal ICa was not affected by serum. Atropine in a concentration (10(-6) M) that completely antagonized the anti-adrenergic effect of acetylcholine (ACh, 2.10(-6) M) did not interfere with the effect of serum. In cells dialysed with cyclic adenosine monophosphate (cAMP)-containing (10(-4) M) pipette solution, potentiated ICa was insensitive to both ACh and serum. Preincubation of the myocytes with pertussis toxin almost completely abolished the anti-adrenergic effects of both ACh and serum. The potency of serum was not reduced by dialysis. It is concluded that serum contains a factor which, like ACh, inhibits beta-receptor-stimulated adenylyl cyclase via Gi-protein.