Rapid kinetics of regulator of G-protein signaling (RGS)-mediated Galphai and Galphao deactivation. Galpha specificity of RGS4 AND RGS7.

Regulator of G-protein signaling (RGS) proteins accelerate GTP hydrolysis by Galpha subunits speeding deactivation. Galpha deactivation kinetics mediated by RGS are too fast to be directly studied using conventional radiochemical methods. We describe a stopped-flow spectroscopic approach to visualize these rapid kinetics by measuring the intrinsic tryptophan fluorescence decrease of Galpha accompanying GTP hydrolysis and Galpha deactivation on the millisecond time scale. Basal k(cat) values for Galpha(o), Galpha(i1), and Galpha(i2) at 20 degrees C were similar (0.025-0.033 s(-1)). Glutathione S-transferase fusion proteins containing RGS4 and an RGS7 box domain (amino acids 305-453) enhanced the rate of Galpha deactivation in a manner linear with RGS concentration. RGS4-stimulated rates could be measured up to 5 s(-1) at 3 microm, giving a catalytic efficiency of 1.7-2.8 x 10(6) m(-1) s(-1) for all three Galpha subunits. In contrast, RGS7 showed catalytic efficiencies of 0.44, 0.10, and 0.02 x 10(6) m(-1) s(-1) toward Galpha(o), Galpha(i2), and Galpha(i1), respectively. Thus RGS7 is a weaker GTPase activating protein than RGS4 toward all Galpha subunits tested, but it is specific for Galpha(o) over Galpha(i1) or Galpha(i2). Furthermore, the specificity of RGS7 for Galpha(o) does not depend on N- or C-terminal extensions or a Gbeta(5) subunit but resides in the RGS domain itself.

G(i) activator region of alpha(2A)-adrenergic receptors: distinct basic residues mediate G(i) versus G(s) activation.

The structural determinants of G protein coupling versus activation by G protein-coupled receptors are not well understood. We examine the role of two distinct basic regions in the carboxyl terminal portion of the third intracellular loop of the alpha(2A)-adrenergic receptor to dissect these aspects of function. Changing three arginines to alanines by mutagenesis and stable expression in Chinese hamster ovary-K1 cells impaired the alpha(2)-adrenergic receptor G(s)-mediated stimulation of cyclic AMP (cAMP) accumulation, whereas G(i)-mediated inhibition was normal. When two (B2) or three (B3) basic residues closer to transmembrane span 6 were mutated to alanine, normal ligand binding was observed, but G(i)-mediated inhibition of cAMP accumulation showed 20-fold and 50-fold decreases in agonist potency for the B2 and B3 mutants, respectively. Surprisingly, a normal G(s) response was seen for the B2 mutant, and the B3 mutant showed only a 6-fold decrease in agonist potency. Mutation of both the three alanines and B3 residues to alanines showed a 200-fold decrease in agonist potency for G(i)-mediated inhibition of cAMP accumulation, whereas the G(s) response was nearly completely eliminated. The three basic residues (which include the BB of the BBXXF motif) play a role as G(i) activators rather than in receptor-G protein coupling, because high-affinity agonist binding is intact. Thus, we have identified three basic residues required for activation of G(i) but not required for receptor-G protein coupling. Also, distinct basic residues are required for optimal G(i) and G(s) responses, defining a microspecificity determinant within the carboxyl terminal portion of the third intracellular loop of the alpha(2a) adrenergic receptor.

A point mutation in Galphao and Galphai1 blocks interaction with regulator of G protein signaling proteins.

Regulator of G protein-signaling (RGS) proteins accelerate GTP hydrolysis by Galpha subunits and are thought to be responsible for rapid deactivation of enzymes and ion channels controlled by G proteins. We wanted to identify and characterize Gi-family alpha subunits that were insensitive to RGS action. Based on a glycine to serine mutation in the yeast Galpha subunit Gpa1(sst) that prevents deactivation by Sst2 (DiBello, P. R., Garrison, T. R., Apanovitch, D. M., Hoffman, G., Shuey, D. J., Mason, K., Cockett, M. I., and Dohlman, H. G. (1998) J. Biol. Chem. 273, 5780-5784), site-directed mutagenesis of alphao and alphai1 was done. G184S alphao and G183S alphai1 show kinetics of GDP release and GTP hydrolysis similar to wild type. In contrast, GTP hydrolysis by the G --> S mutant proteins is not stimulated by RGS4 or by a truncated RGS7. Quantitative flow cytometry binding studies show IC50 values of 30 and 96 nM, respectively, for aluminum fluoride-activated wild type alphao and alphai1 to compete with fluorescein isothiocyanate-alphao binding to glutathione S-transferase-RGS4. The G --> S mutant proteins showed a greater than 30-100-fold lower affinity for RGS4. Thus, we have defined the mechanism of a point mutation in alphao and alphai1 that prevents RGS binding and GTPase activating activity. These mutant subunits should be useful in biochemical or expression studies to evaluate the role of endogenous RGS proteins in Gi function.

Roles of G(o)alpha tryptophans in GTP hydrolysis, GDP release, and fluorescence signals.

Single tryptophan mutants of a histidine-tagged G(o)alpha (W132F and W212F) were prepared to examine the functional and spectroscopic role of tryptophan in G(o)alpha. The mutants bound GTP gamma S with high affinity and showed only modest changes in GDP affinity. GTP gamma S-stimulated intrinsic fluorescence changes were completely abolished by removal of W212 but were not affected by elimination of W132. In contrast, both W132 and W212 contributed to the fluorescence signal from binding of methylanthraniloyl-GTP gamma S (mGTP gamma S). W132F and W212F mutants showed 57% and 34% of the mGTP gamma S fluorescence change of wild type (WT), respectively. The decreased fluorescence signals were not due to reduced activation of the W212F protein by nucleotide as protection from tryptic digestion was unchanged. The kinetics of nucleotide binding and hydrolysis were also altered in both mutants. GDP dissociation was slower (0.14 min-1) for W132F and faster (0.54 min-1) for W212F than for WT (0.25 min-1). As expected, the steady-state Vmax for GTPase was lower for W132F, but surprisingly it was also lower for W212F despite faster GDP release. Single turnover kinetics revealed a lower kcat for W212F (0.52 min-1) compared to WT (1.39 min-1) and W132F (1.0 min-1). Thus, W212 in G(o)alpha makes a dominant contribution to both intrinsic and extrinsic fluorescence signals upon alpha subunit activation. In addition, both tryptophans modulate the kinetics of nucleotide binding and hydrolysis.