Disruption of the alpha5 helix of transducin impairs rhodopsin-catalyzed nucleotide exchange

Photoactivated rhodopsin (R) catalyzes nucleotide exchange by transducin, the heterotrimeric G protein of the rod cell. Recently, we showed that certain alanine replacement mutants of the alpha5 helix of the alpha subunit of transducin (Galpha(t)) displayed very rapid nucleotide exchange rates even in the absence of R [Marin, E. P., Krishna, A. G., and Sakmar, T. P. (2001) J. Biol. Chem. 276, 27400-27405]. We suggested that R catalyzes nucleotide exchange by perturbing residues on the alpha5 helix. Here, we characterize deletion, insertion, and proline replacement mutants of amino acid residues in alpha5. In general, the proline mutants exhibited rates of uncatalyzed nucleotide exchange that were 4-8-fold greater than wild type. The proline mutants also generally displayed decreased rates of R-catalyzed activation. The degree of reduction of the activation rate correlated with the position of the residue replaced with proline. Mutants with replacement of residues at the amino terminus of alpha5 exhibited mild (<2-fold) decreases, whereas mutants with replacement of residues at the carboxyl terminus of alpha5 were completely resistant to R-catalyzed activation. In addition, insertion of a single helical turn in the form of four alanine residues following Ile339 at the carboxyl terminus of alpha5 prevented R-catalyzed activation. Together, the results provide evidence that alpha5 serves an important function in mediating R-catalyzed nucleotide exchange. In particular, the data suggest the importance of the connection between the alpha5 helix and the adjacent carboxyl-terminal region of Galpha(t).     

Rapid activation of transducin by mutations distant from the nucleotide-binding site: evidence for a mechanistic model of receptor-catalyzed nucleotide exchange by G proteins

G proteins act as molecular switches in which information flow depends on whether the bound nucleotide is GDP ("off") or GTP ("on"). We studied the basal and receptor-catalyzed nucleotide exchange rates of site-directed mutants of the alpha subunit of transducin. We identified three amino acid residues (Thr-325, Val-328, and Phe-332) in which mutation resulted in dramatic increases (up to 165-fold) in basal nucleotide exchange rates in addition to enhanced receptor-catalyzed nucleotide exchange rates. These three residues are located on the inward facing surface of the alpha5 helix, which lies between the carboxyl-terminal tail and a loop contacting the nucleotide-binding pocket. Mutation of amino acid residues on the outward facing surface of the same alpha5 helix caused a decrease in receptor-catalyzed nucleotide exchange. We propose that the alpha5 helix comprises a functional microdomain in G proteins that affects basal nucleotide release rates and mediates receptor-catalyzed nucleotide exchange at a distance from the nucleotide-binding pocket.     

A bifunctional Galphai/Galphas modulatory peptide that attenuates adenylyl cyclase activity

Signaling via G-protein coupled receptors is initiated by receptor-catalyzed nucleotide exchange on Galpha subunits normally bound to GDP and Gbetagamma. Activated Galpha . GTP then regulates effectors such as adenylyl cyclase. Except for Gbetagamma, no known regulators bind the adenylyl cyclase-stimulatory subunit Galphas in its GDP-bound state. We recently described a peptide, KB-752, that binds and enhances the nucleotide exchange rate of the adenylyl cyclase-inhibitory subunit Galpha(i). Herein, we report that KB-752 binds Galpha(s) . GDP yet slows its rate of nucleotide exchange. KB-752 inhibits GTPgammaS-stimulated adenylyl cyclase activity in cell membranes, reflecting its opposing effects on nucleotide exchange by Galpha(i) and Galpha(s).     

The function of interdomain interactions in controlling nucleotide exchange rates in transducin

The intramolecular contacts in heterotrimeric G proteins that determine the rates of basal and receptor-stimulated nucleotide exchange are not fully understood. The alpha subunit of heterotrimeric G proteins consists of two domains: a Ras-like domain with structural homology to the monomeric G protein Ras and a helical domain comprised of six alpha-helices. The bound nucleotide lies in a deep cleft between the two domains. Exchange of the bound nucleotide may involve opening of this cleft. Thus interactions between the domains may affect the rate of nucleotide exchange in G proteins. We have tested this hypothesis in the alpha subunit of the rod cell G protein transducin (Galpha(t)). Site-directed mutations were prepared in a series of residues located at the interdomain interface. The proteins were expressed in vitro in a reticulocyte lysate system. The rates of basal and rhodopsin-catalyzed nucleotide exchange were determined using a trypsin digestion assay specifically adapted for kinetic measurements. Charge-altering substitutions of two residues at the interdomain interface, Lys(273) and Lys(276), increased basal nucleotide exchange rates modestly (5-10-fold). However, we found no evidence that interactions spanning the two domains in Galpha(t) significantly affected either basal or rhodopsin-catalyzed nucleotide exchange rates. These results suggest that opening of the interdomain cleft is not an energetic barrier to nucleotide exchange in Galpha(t). Experiments with Galpha(i1) suggest by comparison that the organization and function of the interdomain region differ among various G protein subtypes.     

The amino terminus of the fourth cytoplasmic loop of rhodopsin modulates rhodopsin-transducin interaction

Rhodopsin is a seven-transmembrane helix receptor that binds and catalytically activates the heterotrimeric G protein transducin (G(t)). This interaction involves the cytoplasmic surface of rhodopsin, which comprises four putative loops and the carboxyl-terminal tail. The fourth loop connects the carboxyl end of transmembrane helix 7 with Cys(322) and Cys(323), which are both modified by membrane-inserted palmitoyl groups. Published data on the roles of the fourth loop in the binding and activation of G(t) are contradictory. Here, we attempt to reconcile these conflicts and define a role for the fourth loop in rhodopsin-G(t) interactions. Fluorescence experiments demonstrated that a synthetic peptide corresponding to the fourth loop of rhodopsin inhibited the activation of G(t) by rhodopsin and interacted directly with the alpha subunit of G(t). A series of rhodopsin mutants was prepared in which portions of the fourth loop were replaced with analogous sequences from the beta(2)-adrenergic receptor or the m1 muscarinic receptor. Chimeric receptors in which residues 310-312 were replaced could not efficiently activate G(t). The defect in G(t) interaction in the fourth loop mutants was not affected by preventing palmitoylation of Cys(322) and Cys(323). We suggest that the amino terminus of the fourth loop interacts directly with G(t), particularly with Galpha(t), and with other regions of the intracellular surface of rhodopsin to support G(t) binding.     

Mammalian Ric-8A (synembryn) is a heterotrimeric Galpha protein guanine nucleotide exchange factor

The activation of heterotrimeric G proteins is accomplished primarily by the guanine nucleotide exchange activity of ligand-bound G protein-coupled receptors. The existence of nonreceptor guanine nucleotide exchange factors for G proteins has also been postulated. Yeast two-hybrid screens with Galpha(o) and Galpha(s) as baits were performed to identify binding partners of these proteins. Two mammalian homologs of the Caenorhabditis elegans protein Ric-8 were identified in these screens: Ric-8A (Ric-8/synembryn) and Ric-8B. Purification and biochemical characterization of recombinant Ric-8A revealed that it is a potent guanine nucleotide exchange factor for a subset of Galpha proteins including Galpha(q), Galpha(i1), and Galpha(o), but not Galpha(s). The mechanism of Ric-8A-mediated guanine nucleotide exchange was elucidated. Ric-8A interacts with GDP-bound Galpha proteins, stimulates release of GDP, and forms a stable nucleotide-free transition state complex with the Galpha protein; this complex dissociates upon binding of GTP to Galpha.     

Site-directed sulfhydryl labeling of the lactose permease of Escherichia coli: helix X

Helix X in the lactose permease of Escherichia coli contains two residues that are irreplaceable with respect to active transport, His322 and Glu325, as well as Lys319, which is charge-paired with Asp240 in helix VII. Structural and dynamic features of transmembrane helix X are investigated here by site-directed thiol modification of 14 single-Cys replacement mutants with N-[(14)C]ethylmaleimide (NEM) in right-side-out membrane vesicles. Permease mutants with a Cys residue at position 326, 327, 329, 330, or 331 in the cytoplasmic half of the transmembrane domain are alkylated by NEM at 25 degrees C, a mutant with Cys at position 315 at the periplasmic surface is labeled in the presence of substrate exclusively, and mutants with Cys at positions 317, 318, 320, 321, 324, 328, 332, or 333 do not react with NEM under the conditions tested. Binding of substrate causes increased labeling of a Cys residue at position 315 and decreased labeling of Cys residues at positions 326, 327, and 329. Studies with methanethiosulfonate ethylsulfonate indicate that Cys residues at positions 326, 329, 330, and 331 in the cytoplasmic half are accessible to the aqueous phase from the periplasmic face of the membrane. Ligand binding results in clear attenuation of solvent accessibility of Cys at position 326 and a marginal increase in accessibility of Cys at position 327 to solvent. The findings indicate that the cytoplasmic half of helix X is more reactive/accessible to thiol reagents and more exposed to solvent than the periplasmic half. Furthermore, positions that reflect ligand-induced conformational changes are located on the same face of helix X as Lys319, His322, and Glu325.     

New insights into the role of conserved, essential residues in the GTP binding/GTP hydrolytic cycle of large G proteins

The GTP hydrolytic (GTPase) reaction terminates signaling by both large (heterotrimeric) and small (Ras-related) GTP-binding proteins (G proteins). Two residues that are necessary for GTPase activity are an arginine (often called the "arginine finger") found either in the Switch I domains of the alpha subunits of large G proteins or contributed by the GTPase-activating proteins of small G proteins, and a glutamine that is highly conserved in the Switch II domains of Galpha subunits and small G proteins. However, questions still exist regarding the mechanism of the GTPase reaction and the exact role played by the Switch II glutamine. Here, we have characterized the GTP binding and GTPase activities of mutants in which the essential arginine or glutamine residue has been changed within the background of a Galpha chimera (designated alpha(T)*), comprised mainly of the alpha subunit of retinal transducin (alpha(T)) and the Switch III region from the alpha subunit of G(i1). As expected, both the alpha(T)*(R174C) and alpha(T)*(Q200L) mutants exhibited severely compromised GTPase activity. Neither mutant was capable of responding to aluminum fluoride when monitoring changes in the fluorescence of Trp-207 in Switch II, although both stimulated effector activity in the absence of rhodopsin and Gbetagamma. Surprisingly, each mutant also showed some capability for being activated by rhodopsin and Gbetagamma to undergo GDP-[(35)S]GTPgammaS exchange. The ability of the mutants to couple to rhodopsin was not consistent with the assumption that they contained only bound GTP, prompting us to examine their nucleotide-bound states following their expression and purification from Escherichia coli. Indeed, both mutants contained bound GDP as well as GTP, with 35-45% of each mutant being isolated as GDP-P(i) complexes. Overall, these findings suggest that the R174C and Q200L mutations reveal Galpha subunit states that occur subsequent to GTP hydrolysis but are still capable of fully stimulating effector activity.     

Activated Galpha subunits can inhibit multiple signal transduction pathways during Dictyostelium development.

Mutations impairing the GTPase activity of G protein Galpha subunits can result in activated Galpha subunits that affect signal transduction and cellular responses and, in some cases, promote tumor formation. An analogous mutation in the Dictyostelium Galpha4 subunit gene (Q200L substitution) was constructed and found to inhibit Galpha4-mediated responses to folic acid, including the accumulation of cyclic nucleotides and chemotactic cell movement. The Galpha4-Q200L subunit also severely inhibited responses to cAMP, including cyclic nucleotide accumulation, cAMP chemotaxis, and cellular aggregation. An analogous mutation in the Galpha2 subunit (Q208L substitution), previously reported to inhibit cAMP responses (K. Okaichi et al., 1992, Mol. Biol. Cell 3, 735-747), was also found to partially inhibit folic acid chemotaxis. Chemotactic responses to folic acid and cAMP and developmental aggregation were also inhibited by a mutant Galpha5 subunit with the analogous alteration (Q199L substitution). All aggregation-defective Galpha mutants were capable of multicellular development after a temporary incubation at 4 degrees C and this development was found to be dependent on wild-type Galpha4 function. This study indicates that mutant Galpha subunits can inhibit signal transduction pathways mediated by other Galpha subunits.     

Motion of carboxyl terminus of Galpha is restricted upon G protein activation. A solution NMR study using semisynthetic Galpha subunits

The carboxyl terminus of the G protein alpha subunit plays a key role in interactions with G protein-coupled receptors. Previous studies that have incorporated covalently attached probes have demonstrated that the carboxyl terminus undergoes conformational changes upon G protein activation. To examine the conformational changes that occur at the carboxyl terminus of Galpha subunits upon G protein activation in a more native system, we generated a semisynthetic Galpha subunit, site-specifically labeled in its carboxyl terminus with 13C amino acids. Using expressed protein ligation, 9-mer peptides were ligated to recombinant Galpha(i1) subunits lacking the corresponding carboxyl-terminal residues. In a receptor-G protein reconstitution assay, the truncated Galpha(i1) subunit could not be activated by receptor; whereas the semisynthetic protein demonstrated functionality that was comparable with recombinant Galpha(i1). To study the conformation of the carboxyl terminus of the semisynthetic G protein, we applied high resolution solution NMR to Galpha subunits containing 13C labels at the corresponding sites in Galpha(i1): Leu-348 (uniform), Gly-352 (alpha carbon), and Phe-354 (ring). In the GDP-bound state, the spectra of the ligated carboxyl terminus appeared similar to the spectra obtained for 13C-labeled free peptide. Upon titration with increasing concentrations of AlF4-, the 13C resonances demonstrated a marked loss of signal intensity in the semisynthetic Galpha subunit but not in free peptide subjected to the same conditions. Because AlF4- complexes with GDP to stabilize an activated state of the Galpha subunit, these results suggest that the Galpha carboxyl terminus is highly mobile in its GDP-bound state but adopts an ordered conformation upon activation by AlF4-.     

A novel site on the Galpha -protein that recognizes heptahelical receptors

Specific domains of the G-protein alpha subunit have been shown to control coupling to heptahelical receptors. The extreme N and C termini and a region between alpha4 and alpha5 helices of the G-protein alpha subunit are known to determine selective interaction with the receptors. The metabotropic glutamate receptor 2 activated both mouse Galpha(15) and its human homologue Galpha(16), whereas metabotropic glutamate receptor 8 activated Galpha(15) only. The extreme C-terminal 20 amino acid residues are identical between the Galpha(15) and Galpha(16) and are therefore unlikely to be involved in coupling selectivity. Our data reveal two regions on Galpha(16) that inhibit its coupling to metabotropic glutamate receptor 8. On a three-dimensional model, both regions are found in a close proximity to the extreme C terminus of Galpha(16). One module comprises alpha4 helix, alpha4-beta6 loop (L9 Loop), beta6 sheet, and alpha5 helix. The other, not described previously, is located within the loop that links the N-terminal alpha helix to the beta1 strand of the Ras-like domain of the alpha subunit. Coupling of Galpha(16) protein to the metabotropic glutamate receptor 8 is partially modulated by each module alone, whereas both modules are needed to eliminate the coupling fully.     

Interaction sites of the G protein beta subunit with brain G protein-coupled inward rectifier K+ channel

G protein-coupled inward rectifier K(+) channels (GIRK channels) are activated directly by the G protein betagamma subunit. The crystal structure of the G protein betagamma subunits reveals that the beta subunit consists of an N-terminal alpha helix followed by a symmetrical seven-bladed propeller structure. Each blade is made up of four antiparallel beta strands. The top surface of the propeller structure interacts with the Galpha subunit. The outer surface of the betagamma torus is largely made from outer beta strands of the propeller. We analyzed the interaction between the beta subunit and brain GIRK channels by mutating the outer surface of the betagamma torus. Mutants of the outer surface of the beta(1) subunit were generated by replacing the sequences at the outer beta strands of each blade with corresponding sequences of the yeast beta subunit, STE4. The mutant beta(1)gamma(2) subunits were expressed in and purified from Sf9 cells. They were applied to inside-out patches of cultured locus coeruleus neurons. The wild type beta(1)gamma(2) induced robust GIRK channel activity with an EC(50) of about 4 nm. Among the eight outer surface mutants tested, blade 1 and blade 2 mutants (D1 and CD2) were far less active than the wild type in stimulating GIRK channels. However, the ability of D1 and CD2 to regulate type I and type II adenylyl cyclases was not very different from that of the wild type beta(1)gamma(2). As to the activities to stimulate phospholipase Cbeta(2), D1 was more potent and CD2 was less potent than the wild type beta(1)gamma(2). Additionally we tested four beta(1) mutants in which mutated residues are located in the top Galpha/beta interacting surface. Among them, mutant W332A showed far less ability than the wild type to activate GIRK channels. These results suggest that the outer surface of blade 1 and blade 2 of the beta subunit might specifically interact with GIRK and that the beta subunit interacts with GIRK both over the outer surface and over the top Galpha interacting surface.     

The role of an extra fragment of cytochrome b (residues 309-326) in the cytochrome bc1 complex from Rhodobacter sphaeroides

In bacterial cytochrome b of the cytochrome bc(1) complex, there is an extra fragment located between the amphipathic helix ef and the transmembrane helix F compared to the mitochondrial counterparts. In this work, mutants at various positions of this extra fragment were generated in Rhodobacter sphaeroides in an effort to investigate its specific role in the bacterial bc(1) complex. The total deletion [cytb-Delta(309-326)] and alanine substitution [cytb-(309-326)A] mutant complexes have about 20% of the bc(1) activity found in the wild-type complex. Mutant complexes of cytb-(309-311)A, cytb-(312-314)A, cytb-(315-317)A, cytb-(318-321)A, cytb-(322-323)A, cytb-(324-326)A, cytb-(F323A), and cytb-(S322A) have respectively 87%, 85%, 89%, 100%, 32%, 90%, 100%, and 32% of the bc(1) activity, indicating that the S322 of cytochrome b is important. EPR spectral analysis reveals that the [2Fe-2S] cluster in the cytb-(S322A) mutant complex has a broadened and shifted g(x)() signal (g = 1.76). The rate of superoxide anion (O(2)(*)(-)) generation is 4 times higher in the cytb-(S322A) mutant complex than in the wild-type or mutant complexes of S322T, S322Y, or S322C. These results support the idea that alanine substitution at S322 of cytochrome b causes conformational changes at the Q(o) site by weakening the binding between cytochrome b and ISP through hydrogen bonding provided by the hydroxyl group of this residue. This change facilitates electron leakage from the Q(o) site for reaction with molecular oxygen to form superoxide anion, thus decreasing bc(1) activity.     

Activation mechanism of Gi and Go by reactive oxygen species.

Reactive oxygen species are proposed to work as intracellular mediators. One of their target proteins is the alpha subunit of heterotrimeric GTP-binding proteins (Galpha(i) and Galpha(o)), leading to activation. H(2)O(2) is one of the reactive oxygen species and activates purified Galpha(i2). However, the activation requires the presence of Fe(2+), suggesting that H(2)O(2) is converted to more reactive species such as c*OH. The analysis with mass spectrometry shows that seven cysteine residues (Cys(66), Cys(112), Cys(140), Cys(255), Cys(287), Cys(326), and Cys(352)) of Galpha(i2) are modified by the treatment with *OH. Among these cysteine residues, Cys(66), Cys(112), Cys(140), Cys(255), and Cys(352) are not involved in *OH-induced activation of Galpha(i2). Although the modification of Cys(287) but not Cys(326) is required for subunit dissociation, the modification of both Cys(287) and Cys(326) is necessary for the activation of Galpha(i2) as determined by pertussis toxin-catalyzed ADP-ribosylation, conformation-dependent change of trypsin digestion pattern or guanosine 5'-3-O-(thio)triphosphate binding. Wild type Galpha(i2) but not Cys(287)- or Cys(326)-substituted mutants are activated by UV light, singlet oxygen, superoxide anion, and nitric oxide, indicating that these oxidative stresses activate Galpha(i2) by the mechanism similar to *OH-induced activation. Because Cys(287) exists only in G(i) family, this study explains the selective activation of G(i)/G(o) by oxidative stresses.     

Mechanism of the receptor-catalyzed activation of heterotrimeric G proteins

Heptahelical receptors activate intracellular signaling pathways by catalyzing GTP for GDP exchange on the heterotrimeric G protein alpha subunit (G alpha). Despite the crucial role of this process in cell signaling, little is known about the mechanism of G protein activation. Here we explore the structural basis for receptor-mediated GDP release using electron paramagnetic resonance spectroscopy. Binding to the activated receptor (R*) causes an apparent rigid-body movement of the alpha5 helix of G alpha that would perturb GDP binding at the beta6-alpha5 loop. This movement was not observed when a flexible loop was inserted between the alpha5 helix and the R*-binding C terminus, which uncouples R* binding from nucleotide exchange, suggesting that this movement is necessary for GDP release. These data provide the first direct observation of R*-mediated conformational changes in G proteins and define the structural basis for GDP release from G alpha.     

Effective information transfer from the alpha 1b-adrenoceptor to Galpha 11 requires both beta/gamma interactions and an aromatic group four amino acids from the C terminus of the G protein

Co-expression of the alpha(1b)-adrenoreceptor and Galpha(11) in cells derived from a Galpha(q)/Galpha(11) knock-out mouse allows agonist-mediated elevation of intracellular Ca(2+) levels that is transduced by beta/gamma released from the G protein alpha subunit. Mutation of Tyr(356) of Galpha(11) to Phe, within a receptor contact domain, had little effect on function but this was reduced greatly by alteration to Ser and virtually eliminated by conversion to Asp. This pattern was replicated following incorporation of each form of Galpha(11) into fusion proteins with the alpha(1b)-adrenoreceptor. Following a [(35)S]guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS) binding assay, immunoprecipitation of the wild type alpha(1b)-adrenoreceptor-Galpha(11) fusion protein indicated that the agonist phenylephrine stimulated guanine nucleotide exchange on Galpha(11) more than 30-fold. Information transfer by agonist was controlled in residue 356 Galpha(11) mutants with rank order Tyr > Phe > Trp > Ile > Ala = Gln = Arg > Ser > Asp, although these alterations did not alter the binding affinity of either phenylephrine or an antagonist ligand. Mutation of a beta/gamma contact interface in the alpha(1b)-adrenoreceptor-Tyr(356) Galpha(11) fusion protein did not alter ligand binding affinity but did reduce greatly beta/gamma binding and phenylephrine stimulation of [(35)S]GTPgammaS binding. It also prevented agonist elevation of intracellular Ca(2+) levels, as did a mutation in Galpha(11) that prevents G protein subunit dissociation. These results indicate that a bulky aromatic group is required four amino acids from the C terminus of Galpha(11) to maximize information transfer from an agonist-occupied receptor and disprove the hypothesis that tyrosine phosphorylation of this residue is required for G protein activation (Umemori, H., Inoue, T., Kume, S., Sekiyama, N., Nagao, M., Itoh, H., Nakanishi, S., Mikoshiba, K., and Yamamoto, T. (1997) Science 276, 1878-1881). This is distinct from Galpha(i1), where hydrophobicity of the amino acid is the key determinant at this location. They also further demonstrate a key role for the beta/gamma complex in enhancing receptor to G protein alpha subunit information transfer.     

The GAPs, GEFs, and GDIs of heterotrimeric G-protein alpha subunits

The heterotrimeric G-protein alpha subunit has long been considered a bimodal, GTP-hydrolyzing switch controlling the duration of signal transduction by seven-transmembrane domain (7TM) cell-surface receptors. In 1996, we and others identified a superfamily of "regulator of G-protein signaling" (RGS) proteins that accelerate the rate of GTP hydrolysis by Galpha subunits (dubbed GTPase-accelerating protein or "GAP" activity). This discovery resolved the paradox between the rapid physiological timing seen for 7TM receptor signal transduction in vivo and the slow rates of GTP hydrolysis exhibited by purified Galpha subunits in vitro. Here, we review more recent discoveries that have highlighted newly-appreciated roles for RGS proteins beyond mere negative regulators of 7TM signaling. These new roles include the RGS-box-containing, RhoA-specific guanine nucleotide exchange factors (RGS-RhoGEFs) that serve as Galpha effectors to couple 7TM and semaphorin receptor signaling to RhoA activation, the potential for RGS12 to serve as a nexus for signaling from tyrosine kinases and G-proteins of both the Galpha and Ras-superfamilies, the potential for R7-subfamily RGS proteins to couple Galpha subunits to 7TM receptors in the absence of conventional Gbetagamma dimers, and the potential for the conjoint 7TM/RGS-box Arabidopsis protein AtRGS1 to serve as a ligand-operated GAP for the plant Galpha AtGPA1. Moreover, we review the discovery of novel biochemical activities that also impinge on the guanine nucleotide binding and hydrolysis cycle of Galpha subunits: namely, the guanine nucleotide dissociation inhibitor (GDI) activity of the GoLoco motif-containing proteins and the 7TM receptor-independent guanine nucleotide exchange factor (GEF) activity of Ric8/synembryn. Discovery of these novel GAP, GDI, and GEF activities have helped to illuminate a new role for Galpha subunit GDP/GTP cycling required for microtubule force generation and mitotic spindle function in chromosomal segregation.     

Gαs protein C‐terminal α‐helix at the interface: does the plasma membrane play a critical role in the Gαs protein functionality?

The heterotrimeric guanine nucleotide-binding regulatory proteins (G proteins, Galphabetagamma) mediate the signalling process of a large number of receptors, known as G protein-coupled receptors. The C-terminal domain of the heterotrimeric G protein alpha-subunit plays a key role in the selective activation of G proteins by their cognate receptors. The interaction of this domain can take place at the end of a cascade including several successive conformational modifications. Galpha(s)(350-394) is the 45-mer peptide corresponding to the C-terminal region of the Galpha(s) subunit. In the crystal structure of the Galpha(s) subunit it encompasses the alpha4/beta6 loop, the beta6 beta-sheet segment and the alpha5 helix region. Following a previous study based on the synthesis, biological activity and conformational analysis of shorter peptides belonging to the same Galpha(s) region, Galpha(s)(350-394) was synthesized and investigated. The present study outlines the central role played by the residues involved in the alpha4/beta6 loop and beta6/alpha5 loops in the stabilization of the C-terminal Galpha(s)alpha-helix. H(2)O/(2)H(2)O exchange experiments, and NMR diffusion experiments show interesting evidence concerning the interaction between the SDS micelles and the polypeptide. These data prompt intriguing speculations on the role of the intracellular environment/cellular membrane interface in the stabilization and functionality of the C-terminal Galpha(s) region.     

GDP affinity and order state of the catalytic site are critical for function of xanthine nucleotide-selective Galphas proteins

Xanthine nucleotide-selective small GTP-binding proteins with an Asp/Asn mutation are valuable for the analysis of individual GTP-binding proteins in complex systems. Similar applications can be devised for heterotrimeric G-proteins. However, Asp/Asn mutants of Galpha(o), Galpha(11), and Galpha(16) were inactive. An additional Gln/Leu mutation in the catalytic site, reducing GTPase activity and increasing GDP affinity, was required to generate xanthine nucleotide-selective unspecified G-protein alpha-subunit (Galpha). Our study aim was to generate xanthine nucleotide-selective mutants of Galpha(s), the stimulatory G-protein of adenylyl cyclase. The short splice variant of Galpha(s) (Galpha(sS)) possesses higher GDP affinity than the long splice variant (Galpha(sL)). Nucleoside 5'-[gamma-thio]triphosphates (NTPgammaSs) and nucleoside 5'-[beta,gamma-imido]triphosphates effectively activated a Galpha(sS) mutant with a D280N exchange (Galpha(sS)-N280), whereas nucleotides activated a Galpha(sL) mutant with a D295N exchange (Galpha(sL)-N295) only weakly. The Gln/Leu mutation enhanced Galpha(sL)-N295 activity. NTPgammaSs activated Galpha(sS)-N280 and a Galpha(sL) mutant with a Q227L and D295N exchange (Galpha(sL)-L227/N295) with similar potencies, whereas xanthosine 5'-triphosphate and xanthosine 5'-[beta,gamma-imido]triphosphate were more potent than GTP and guanosine 5'-[beta,gamma-imido]triphosphate, respectively. Galpha(sS)-N280 interacted with the beta(2)-adrenoreceptor and exhibited high-affinity XTPase activity. Collectively, (i) Galpha(sS)-N280 is the first functional xanthine nucleotide-selective Galpha with the Asp/Asn mutation alone; (ii) sufficiently high GDP affinity is crucial for Galpha Asp/Asn mutant function; (iii) with nucleoside 5'-triphosphates and nucleoside 5'-[beta,gamma-imido]triphosphates, Galpha(s)-N280 and Galpha(sL)-L227/N295 exhibit xanthine nucleotide selectivity, whereas NTPgammaSs sterically perturb the catalytic site of Galpha and annihilate xanthine selectivity.     

Ric-8A catalyzes guanine nucleotide exchange on G alphai1 bound to the GPR/GoLoco exchange inhibitor AGS3

Microtubule pulling forces that govern mitotic spindle movement of chromosomes are tightly regulated by G-proteins. A host of proteins, including Galpha subunits, Ric-8, AGS3, regulators of G-protein signalings, and scaffolding proteins, coordinate this vital cellular process. Ric-8A, acting as a guanine nucleotide exchange factor, catalyzes the release of GDP from various Galpha.GDP subunits and forms a stable nucleotide-free Ric-8A:Galpha complex. AGS3, a guanine nucleotide dissociation inhibitor (GDI), binds and stabilizes Galpha subunits in their GDP-bound state. Because Ric-8A and AGS3 may recognize and compete for Galpha.GDP in this pathway, we probed the interactions of a truncated AGS3 (AGS3-C; containing only the residues responsible for GDI activity), with Ric-8A:Galpha(il) and that of Ric-8A with the AGS3-C:Galpha(il).GDP complex. Pulldown assays, gel filtration, isothermal titration calorimetry, and rapid mixing stopped-flow fluorescence spectroscopy indicate that Ric-8A catalyzes the rapid release of GDP from AGS3-C:Galpha(i1).GDP. Thus, Ric-8A forms a transient ternary complex with AGS3-C:Galpha(i1).GDP. Subsequent dissociation of AGS3-C and GDP from Galpha(i1) yields a stable nucleotide free Ric-8A.Galpha(i1) complex that, in the presence of GTP, dissociates to yield Ric-8A and Galpha(i1).GTP. AGS3-C does not induce dissociation of the Ric-8A.Galpha(i1) complex, even when present at very high concentrations. The action of Ric-8A on AGS3:Galpha(i1).GDP ensures unidirectional activation of Galpha subunits that cannot be reversed by AGS3.