Gα Binding Research Articles

Palmitoylation modification of Gα o depresses its susceptibility to GAP-43 activation

Interaction between GAP-43 (growth associated protein-43) and Gα o (alpha subunit of Go protein) influences the signal transduction pathways leading to differentiation of neural cells. GAP-43 is known to increase guanine nucleotide exchange by Gα o, which is a major component of neuronal growth cone membranes. However, it is not clear whether GAP-43 stimulation is related to the Gα o palmitoylation or the conversion of Gα o from oligmers to monomers, which was shown to be a necessary regulatory factor in GDP/GTP exchange of Gα o. Here we expressed and purified GAP-43, GST-GAP-43 and Gα o proteins, detected their stimulatory effect on [ 35S]-GTPγS binding of Gα o. It was found that the EC 50 of both GAP-43 and GST-GAP-43 activation were tenfold lower in case of depalmitoylated Gα o than palmitoylated Gα o. Non-denaturing gel electrophoresis and p-PDM cross-linking analysis revealed that addition of GST-GAP-43 induced disassociation of depalmitoylated Gα o from oligomers to monomers, but did not influence the oligomeric state of palmitoylated Gα o, which suggests that palmitoylation is a key regulatory factor in GAP-43 stimulation on Gα o. These results indicated the interaction of GAP-43 and Gα o could accelerate conversion of depalmitoylated Gα o but not palmitoylated Gα o from oligomers to monomers, so as to increase the GTPγS binding activity of Gα o. Results here provide new evidence about how signaling protein palmitoylation is involved in the G-protein-coupled signal transduction cascade, and give a useful clue on the participation of GAP-43 in G-protein cycle by its preferential activation of depalmitoylated Gα o.

Mutations on the Switch III region and the alpha3 helix of Galpha<sub>16</sub> differentially affect receptor coupling and regulation of downstream effectors

BackgroundGα16 can activate phospholipase Cβ (PLCβ) directly like Gαq. It also couples to tetratricopeptide repeat 1 (TPR1) which is linked to Ras activation. It is unknown whether PLCβ and TPR1 interact with the same regions on Gα16. Previous studies on Gαq have defined two minimal clusters of amino acids that are essential for the coupling to PLCβ. Cognate residues in Gα16 might also be essential for interacting with PLCβ, and possibly contribute to TPR1 interaction and other signaling events.ResultsAlanine mutations were introduced to the two amino acid clusters (246–248 and 259–260) in the switch III region and α3 helix of Gα16. Regulations of PLCβ and STAT3 were partially weakened by each cluster mutant. A mutant harboring mutations at both clusters generally produced stronger suppressions. Activation of Jun N-terminal kinase (JNK) by Gα16 was completely abolished by mutating either clusters. Contrastingly, phosphorylations of extracellular signal-regulated kinase (ERK) and nuclear factor κB (NF-κB) were not significantly affected by these mutations. The interactions between the mutants and PLCβ2 and TPR1 were also reduced in co-immunoprecipitation assays. Coupling between G16 and different categories of receptors was impaired by the mutations, with the effect of switch III mutations being more pronounced than those in the α3 helix. Mutations of both clusters almost completely abolished the receptor coupling and prevent receptor-induced Gβγ release.ConclusionThe integrity of the switch III region and α3 helix of Gα16 is critical for the activation of PLCβ, STAT3, and JNK but not ERK or NF-κB. Binding of Gα16 to PLCβ2 or TPR1 was reduced by the mutations of either cluster. The same region could also differentially affect the effectiveness of receptor coupling to G16. The studied region was shown to bear multiple functionally important roles of G16.

Structural model of a complex between the heterotrimeric G protein, Gsα, and tubulin

A number of studies have demonstrated interplay between the cytoskeleton and G protein signaling. Many of these studies have determined a specific interaction between tubulin, the building block of microtubules, and G proteins. The α subunits of some heterotrimeric G proteins, including Gsα, have been shown to interact strongly with tubulin. Binding of Gα to tubulin results in increased dynamicity of microtubules due to activation of GTPase of tubulin. Tubulin also activates Gsα via a direct transfer of GTP between these molecules. Structural insight into the interaction between tubulin and Gsα was required, and was determined, in this report, through biochemical and molecular docking techniques. Solid phase peptide arrays suggested that a portion of the amino terminus, α2–β4 (the region between switch II and switch III) and α3–β5 (just distal to the switch III region) domains of Gsα are important for interaction with tubulin. Molecular docking studies revealed the best-fit models based on the biochemical data, showing an interface between the two molecules that includes the adenylyl cyclase/Gβγ interaction regions of Gsα and the exchangeable nucleotide-binding site of tubulin. These structural models explain the ability of tubulin to facilitate GTP exchange on Gα and the ability of Gα to activate tubulin GTPase.

Signaling by a Non-dissociated Complex of G Protein βγ and α Subunits Stimulated by a Receptor-independent Activator of G Protein Signaling, AGS8

Accumulating evidence suggests that heterotrimeric G protein activation may not require G protein subunit dissociation. Results presented here provide evidence for a subunit dissociation-independent mechanism for G protein activation by a receptor-independent activator of G protein signaling, AGS8. AGS8 is a member of the AGS group III family of AGS proteins thought to activate G protein signaling primarily through interactions with Gbetagamma subunits. Results are presented demonstrating that AGS8 binds to the effector and alpha subunit binding "hot spot" on Gbetagamma yet does not interfere with Galpha subunit binding to Gbetagamma or phospholipase C beta2 activation. AGS8 stimulates activation of phospholipase C beta2 by heterotrimeric Galphabetagamma and forms a quaternary complex with Galpha(i1), Gbeta(1)gamma(2), and phospholipase C beta2. AGS8 rescued phospholipase C beta binding and regulation by an inactive beta subunit with a mutation in the hot spot (beta(1)(W99A)gamma(2)) that normally prevents binding and activation of phospholipase C beta2. This demonstrates that, in the presence of AGS8, the hot spot is not used for Gbetagamma interactions with phospholipase C beta2. Mutation of an alternate binding site for phospholipase C beta2 in the amino-terminal coiled-coil region of Gbetagamma prevented AGS8-dependent phospholipase C binding and activation. These data implicate a mechanism for AGS8, and potentially other Gbetagamma binding proteins, for directing Gbetagamma signaling through alternative effector activation sites on Gbetagamma in the absence of subunit dissociation.

The RGS protein inhibitor CCG-4986 is a covalent modifier of the RGS4 Gα-interaction face

Regulator of G-protein signaling (RGS) proteins accelerate GTP hydrolysis by Gα subunits and are thus crucial to the timing of G protein-coupled receptor (GPCR) signaling. Small molecule inhibition of RGS proteins is an attractive therapeutic approach to diseases involving dysregulated GPCR signaling. Methyl- N-[(4-chlorophenyl)sulfonyl]-4-nitrobenzenesulfinimidoate (CCG-4986) was reported as a selective RGS4 inhibitor, but with an unknown mechanism of action [D.L. Roman, J.N. Talbot, R.A. Roof, R.K. Sunahara, J.R. Traynor, R.R. Neubig, Identification of small-molecule inhibitors of RGS4 using a high-throughput flow cytometry protein interaction assay, Mol. Pharmacol. 71 (2007) 169–75]. Here, we describe its mechanism of action as covalent modification of RGS4. Mutant RGS4 proteins devoid of surface-exposed cysteine residues were characterized using surface plasmon resonance and FRET assays of Gα binding, as well as single-turnover GTP hydrolysis assays of RGS4 GAP activity, demonstrating that cysteine-132 within RGS4 is required for sensitivity to CCG-4986 inhibition. Sensitivity to CCG-4986 can be engendered within RGS8 by replacing the wildtype residue found in this position to cysteine. Mass spectrometry analysis identified a 153-Dalton fragment of CCG-4986 as being covalently attached to the surface-exposed cysteines of the RGS4 RGS domain. We conclude that the mechanism of action of the RGS protein inhibitor CCG-4986 is via covalent modification of Cys-132 of RGS4, likely causing steric hindrance with the all-helical domain of the Gα substrate.

The Gα12-RGS RhoGEF-RhoA signalling pathway regulates neurotransmitter release in C. elegans

In Caenorhabditis elegans adults, the single Rho GTPase orthologue, RHO-1, stimulates neurotransmitter release at synapses. We show that one of the pathways acting upstream of RHO-1 in acetylcholine (ACh)-releasing motor neurons depends on Galpha12 (GPA-12), which acts via the single C. elegans RGS RhoGEF (RHGF-1). Activated GPA-12 has the same effect as activated RHO-1, inducing the accumulation of diacylglycerol and the neuromodulator UNC-13 at release sites, and increased ACh release. We showed previously that RHO-1 stimulates ACh release by two separate pathways-one that requires UNC-13 and a second that does not. We show here that a non-DAG-binding-UNC-13 mutant that partially blocks increased ACh release by activated RHO-1 completely blocks increased ACh release by activated GPA-12. Thus, the upstream GPA-12/RHGF-1 pathway stimulates only a subset of RHO-1 downstream effectors, suggesting that either the RHO-1 effectors require different levels of activated RHO-1 for activation or there are two distinct pools of RHO-1 within C. elegans neurons.

The Drosophila NuMA Homolog Mud Regulates Spindle Orientation in Asymmetric Cell Division

During asymmetric cell division, the mitotic spindle must be properly oriented to ensure the asymmetric segregation of cell fate determinants into only one of the two daughter cells. In Drosophila neuroblasts, spindle orientation requires heterotrimeric G proteins and the G alpha binding partner Pins, but how the Pins-G alphai complex interacts with the mitotic spindle is unclear. Here, we show that Pins binds directly to the microtubule binding protein Mud, the Drosophila homolog of NuMA. Like NuMA, Mud can bind to microtubules and enhance microtubule polymerization. In the absence of Mud, mitotic spindles in Drosophila neuroblasts fail to align with the polarity axis. This can lead to symmetric segregation of the cell fate determinants Brat and Prospero, resulting in the mis-specification of daughter cell fates and tumor-like over proliferation in the Drosophila nervous system. Our data suggest a model in which asymmetrically localized Pins-G alphai complexes regulate spindle orientation by directly binding to Mud.

RACK1 Binds to a Signal Transfer Region of Gβγ and Inhibits Phospholipase C β2 Activation

RACK1 Binds to a Signal Transfer Region of Gβγ and Inhibits Phospholipase C β2 Activation

Identification and Characterization of GIV, a Novel Gαi/s -interacting Protein Found on COPI, Endoplasmic Reticulum-Golgi Transport Vesicles

In this report, we characterize GIV (Gα-interacting vesicle-associated protein), a novel protein that binds members of the Gαi and Gα subfamilies of heterotrimeric G proteins. The Gαs interaction site was mapped to an 83-amino acid region of GIV that is enriched in highly charged amino acids. BLAST searches revealed two additional mammalian family members, Daple and an uncharacterized protein, FLJ00354. These family members share the highest homology at the Gα binding domain, are homologous at the N terminus and central coiled coil domain but diverge at the C terminus. Using affinity-purified IgG made against two different regions of the protein, we localized GIV to COPI, endoplasmic reticulum (ER)-Golgi transport vesicles concentrated in the Golgi region in GH3 pituitary cells and COS7 cells. Identification as COPI vesicles was based on colocalization with β-COP, a marker for these vesicles. GIV also codistributes in the Golgi region with endogenous calnuc and the KDEL receptor, which are cis Golgi markers and with Gαi3-yellow fluorescent protein expressed in COS7 cells. By immunoelectron microscopy, GIV colocalizes with β-COP and Gαi3 on vesicles found in close proximity to ER exit sites and to cis Golgi cisternae. In cell fractions prepared from rat liver, GIV is concentrated in a carrier vesicle fraction (CV2) enriched in ER-Golgi transport vesicles. β-COP and several Gα subunits (Gαi1–3, Gαs) are also most enriched in CV2. Our results demonstrate the existence of a novel Gα-interacting protein associated with COPI transport vesicles that may play a role in Gα-mediated effects on vesicle trafficking within the Golgi and/or between the ER and the Golgi.

The 1.1-Å Structure of the Spindle Checkpoint Protein Bub3p Reveals Functional Regions

Bub3p is a protein that mediates the spindle checkpoint, a signaling pathway that ensures correct chromosome segregation in organisms ranging from yeast to mammals. It is known to function by co-localizing at least two other proteins, Mad3p and the protein kinase Bub1p, to the kinetochore of chromosomes that are not properly attached to mitotic spindles, ultimately resulting in cell cycle arrest. Prior sequence analysis suggested that Bub3p was composed of three or four WD repeats (also known as WD40 and beta-transducin repeats), short sequence motifs appearing in clusters of 4-16 found in many hundreds of eukaryotic proteins that fold into four-stranded blade-like sheets. We have determined the crystal structure of Bub3p from Saccharomyces cerevisiae at 1.1 angstrom and a crystallographic R-factor of 15.3%, revealing seven authentic repeats. In light of this, it appears that many of these repeats therefore remain hidden in sequences of other proteins. Analysis of random and site-directed mutants identifies the surface of Bub3p involved in checkpoint function through binding of Bub1p and Mad3p. Sequence alignments indicate that these surfaces are mostly conserved across Bub3 proteins from diverse species. A structural comparison with other proteins containing WD repeats suggests that these folds may bind partner proteins using similar surface areas on the top and sides of the propeller. The sequences composing these regions are the most divergent within the repeat across all WD repeat proteins and could potentially be modulated to provide specificity in partner protein binding without perturbation of the core structure.

Mammalian Pins Is a Conformational Switch that Links NuMA to Heterotrimeric G Proteins

During asymmetric cell divisions, mitotic spindles align along the axis of polarization. In invertebrates, spindle positioning requires Pins or related proteins and a G protein α subunit. A mammalian Pins, called LGN, binds Gαi and also interacts through an N-terminal domain with the microtubule binding protein NuMA. During mitosis, LGN recruits NuMA to the cell cortex, while cortical association of LGN itself requires the C-terminal Gα binding domain. Using a FRET biosensor, we find that LGN behaves as a conformational switch: in its closed state, the N and C termini interact, but NuMA or Gαi can disrupt this association, allowing LGN to interact simultaneously with both proteins, resulting in their cortical localization. Overexpression of Gαi or YFP-LGN causes a pronounced oscillation of metaphase spindles, and NuMA binding to LGN is required for these spindle movements. We propose that a related switch mechanism might operate in asymmetric cell divisions in the fly and nematode.

Guanine nucleotide dissociation inhibitor activity of the triple GoLoco motif protein G18: alanine-to-aspartate mutation restores function to an inactive second GoLoco motif.

GoLoco ('Galpha(i/o)-Loco' interaction) motif proteins have recently been identified as novel GDIs (guanine nucleotide dissociation inhibitors) for heterotrimeric G-protein alpha subunits. G18 is a member of the mammalian GoLoco-motif gene family and was uncovered by analyses of human and mouse genomes for anonymous open-reading frames. The encoded G18 polypeptide is predicted to contain three 19-amino-acid GoLoco motifs, which have been shown in other proteins to bind Galpha subunits and inhibit spontaneous nucleotide release. However, the G18 protein has thus far not been characterized biochemically. Here, we have cloned and expressed the G18 protein and assessed its ability to act as a GDI. G18 is capable of simultaneously binding more than one Galpha(i1) subunit. In binding assays with the non-hydrolysable GTP analogue guanosine 5'-[gamma-thio]triphosphate, G18 exhibits GDI activity, slowing the exchange of GDP for GTP by Galpha(i1). Only the first and third GoLoco motifs within G18 are capable of interacting with Galpha subunits, and these bind with low micromolar affinity only to Galpha(i1) in the GDP-bound form, and not to Galpha(o), Galpha(q), Galpha(s) or Galpha12. Mutation of Ala-121 to aspartate in the inactive second GoLoco motif of G18, to restore the signature acidic-glutamine-arginine tripeptide that forms critical contacts with Galpha and its bound nucleotide [Kimple, Kimple, Betts, Sondek and Siderovski (2002) Nature (London) 416, 878-881], results in gain-of-function with respect to Galpha binding and GDI activity.

Mapping the Gα13 Binding Interface of the rgRGS Domain of p115RhoGEF

Structural requirements for function of the Rho GEF (guanine nucleotide exchange factor) regulator of G protein signaling (rgRGS) domains of p115RhoGEF and homologous exchange factors differ from those of the classical RGS domains. An extensive mutagenesis analysis of the p115RhoGEF rgRGS domain was undertaken to determine its functional interface with the Galpha(13) subunit. Results indicate that there is global resemblance between the interaction surface of the rgRGS domain with Galpha(13) and the interactions of RGS4 and RGS9 with their Galpha substrates. However, there are distinct differences in the distribution of functionally critical residues between these structurally similar surfaces and an additional essential requirement for a cluster of negatively charged residues at the N terminus of rgRGS. Lack of sequence conservation within the N terminus may also explain the lack of GTPase-activating protein (GAP) activity in a subset of the rgRGS domains. For all mutations, loss of functional GAP activity is paralleled by decreases in binding to Galpha(13). The same mutations, when placed in the context of the p115RhoGEF molecule, produce deficiencies in GAP activity as observed with the rgRGS domain alone but show no attenuation of the regulation of Rho exchange activity by Galpha(13). This suggests that the rgRGS domain may serve a structural or allosteric role in the regulation of the nucleotide exchange activity of p115RhoGEF on Rho by Galpha(13).

Binding of Gα0 N‐Terminus Is Responsible for the Voltage‐Resistant Inhibition of α1A (P/Q‐Type, Cav2.1) Ca2+ Channels

AbstractFor Abstract see ChemInform Abstract in Full Text.

A cysteine-11 to serine mutant of Gα 12 impairs activation through the thrombin receptor

We have recently reported that Gα 12 is acylated with palmitic acid [Veit et al., FEBS Lett. 339 (1994) 160–164]. Here we identify cysteine 11 as the sole palmitoylation site and assess the function of Gα 12 palmitoylation after expression of wild type and acylation-deficient mutant in insect cells. Our experimental approach yielded the following results. (1) Palmitoylation of Gα 12 has no influence on the subunit interactions. (2) Palmitoylation promotes membrane binding of Gα 12 when this protein is expressed alone. Membrane attachment of the heterotrimer occurs independent of the presence of fatty acids in Gα 12. (3) Assays for agonist-stimulated binding of [ 35S]GTPγS after expression of the human thrombin receptor (PAR1) along with Gα 12 and the βγ subunits revealed a 70% inhibition with the palmitoyl-deficient mutant.

Sites for Gα Binding on the G Protein β Subunit Overlap with Sites for Regulation of Phospholipase Cβ and Adenylyl Cyclase

Heterotrimeric G proteins, composed of alpha and betagamma subunits, forward signals from transmembrane receptors to intracellular effector enzymes and ion channels. Free betagamma activates downstream targets, but its action is terminated by association with GDP-liganded alpha subunits. Because alpha can inhibit activation of many effectors by betagamma, it is likely that the alpha subunit binding surfaces on betagamma overlap the surfaces necessary for effector activation. To test this hypothesis, we mutated residues on beta shown to contact alpha in the recently published crystal structures of the alphabetagamma heterotrimer (Wall, M. A., Coleman, D. E., Lee, E., Iniguez-Lluhi, J. A., Posner, B. A., Gilman, A. G., and Sprang, S. R. (1995) Cell 83, 1047-1058; Lambright, D. G., Sondek, J., Bohm, A., Skiba, N. P., Hamm, H. E., and Sigler, P. B. (1996) Nature 379, 311-319.). The alpha subunit binds to the flat, top surface of the toroidal beta subunit and also extends a helix along the side of the beta subunit at blade 1. We mutated four residues on the top surface of beta (Hbeta1[L117A], Hbeta1[D228R], Hbeta1[D246S], and Hbeta1[W332A]) and two residues on the side of beta that contacts alpha (Hbeta1[N88A/K89A]). Each of the mutant proteins was able to form beta gamma dimers, but they differed in their ability to bind alpha and to activate phospholipase C beta2 (PLCbeta2), PLCbeta3, and adenylyl cyclase II. Mutation of residues along the side of the torus at blade 1 diminish affinity for alpha but do not prevent activation of any of the effectors. Mutations on the alpha binding surface differentially affected PLCbeta2, PLCbeta3, and adenylyl cyclase II. Residues that affect PLCbeta and adenylyl cyclase II activity are found on opposite sides of the central tunnel, suggesting that PLC and adenylyl cyclase, like the alpha subunit, make many contacts on the top surface. None of the mutations affected the ability of betagamma to inhibit adenylyl cyclase I. We conclude that alpha, PLCbeta2, PLCbeta3, and adenylyl cyclase II share an interaction on the top surface of beta. The importance of individual residues is different for alpha binding and for effector activation and differs even between closely related isoforms of the same effector.

Molecular basis for interactions of G protein betagamma subunits with effectors.

Both the alpha and betagamma subunits of heterotrimeric guanine nucleotide-binding proteins (G proteins) communicate signals from receptors to effectors. Gbetagamma subunits can regulate a diverse array of effectors, including ion channels and enzymes. Galpha subunits bound to guanine diphosphate (Galpha-GDP) inhibit signal transduction through Gbetagamma subunits, suggesting a common interface on Gbetagamma subunits for Galpha binding and effector interaction. The molecular basis for interaction of Gbetagamma with effectors was characterized by mutational analysis of Gbeta residues that make contact with Galpha-GDP. Analysis of the ability of these mutants to regulate the activity of calcium and potassium channels, adenylyl cyclase 2, phospholipase C-beta2, and beta-adrenergic receptor kinase revealed the Gbeta residues required for activation of each effector and provides evidence for partially overlapping domains on Gbeta for regulation of these effectors. This organization of interaction regions on Gbeta for different effectors and Galpha explains why subunit dissociation is crucial for signal transmission through Gbetagamma subunits.