Purification and characterization of transducin from capybara Hydrochoerus hydrochaeris

Polypeptides of approximately 39, 36 and 相似文献   

Functional homology between signal-coupling proteins. Cholera toxin inactivates the GTPase activity of transducin

Both the light-stimulated cGMP phosphodiesterase of retinal rod outer segments (ROS) and hormone-stimulated adenylate cyclase are regulated by guanine nucleotide-binding regulatory proteins (N). Transducin serves as the signal-carrying regulatory protein in ROS, and the N protein (also called G or G/F) performs this role in the adenylate cyclase system. The GTP form of these regulatory proteins activates the corresponding enzyme, whereas the GDP form does not. Both transducin and the N protein possess a GTPase activity that restores the regulatory protein to the unstimulated state. Cholera enterotoxin catalyzes the transfer of ADP-ribose from NAD+ to the N protein, which inhibits its GTPase activity and activates adenylate cyclase. We report here that the toxin also catalyzes ADP-ribosylation of the alpha-subunit of transducin in ROS membranes. This modification of the guanine nucleotide-binding subunit of transducin is markedly enhanced by the bleaching of rhodopsin and by the addition of guanosine-5'-(beta, gamma-imino)triphosphate. In contrast, GDP, GTP, and guanosine-5'-(3-O)thiotriphosphate inhibit the reaction, while GMP and ATP have no effect. Under optimal conditions, toxin catalyzes labeling of 0.7 mol of the alpha-subunit of transducin/mol of bound [3H]guanosine-5'-(beta, gamma-imido)triphosphate and causes 70% inhibition of the light-dependent GTPase activity of transducin in ROS. These results indicate close functional homology between transducin of ROS and the N protein of adenylate cyclase.     

Purification and characteristics of photoreceptor light-activated guanosinetriphosphatase

We describe a reconstitution of light-activated vertebrate photoreceptor GTPase and a purification of the GTP-binding protein (G protein), which is a component of the GTPase and modulates the light-activated phosphodiesterase (PDE) enzyme system. Rod outer segments (ROS) of bull frogs were treated with ethylenediaminetetraacetic acid (EDTA), and the GTPase and PDE fractions were solubilized (EDTA supernatant). When the EDTA supernatant and EDTA-treated membrane fraction (EDTA-washed membranes) were recombined, light-dependent GTPase activity appeared. In the reconstituted system, the Km for GTP as substrate was 0.5 microM; the optimum pH was 7.5-8.0. The isoelectric point of GTPase in EDTA supernatant was 4.8. G protein was purified 400-fold from ROS, and the molecular weight of G protein was determined to be 40 000 by polyacrylamide gel electrophoresis. The amount of G protein in ROS was calculated as at least 1 molecule per 400 rhodopsin molecules. By recombining (in the presence or absence of GTP) purified G protein, PDE, H fraction (an additional component of GTPase), and illuminated or unilluminated EDTA-washed membranes (as a source of rhodopsin), we showed that illuminated rhodopsin, G protein, PDE, and GTP are the minimum requirements for light-dependent PDE activity. We discuss the significance of these findings in the regulation of the light-activated GTPase and PDE activities, especially with regard to the mechanism of activation.     

Specificity of the functional interactions of the beta-adrenergic receptor and rhodopsin with guanine nucleotide regulatory proteins reconstituted in phospholipid vesicles

We have assessed the functional interactions of two pure receptor proteins with three different pure guanine nucleotide regulatory proteins in phosphatidylcholine vesicles. The receptor proteins are the guinea pig lung beta-adrenergic receptor (beta AR) and the retinal photon receptor rhodopsin. The guanine nucleotide regulatory proteins were the stimulatory (Ns) and inhibitory (Ni) proteins of the adenylate cyclase system and transducin (T), the regulatory protein from the light-activated cyclic GMP phosphodiesterase system in retinal rod outer segments. The insertion of Ns with beta AR in lipid vesicles increases the extent of binding of [35S] GTP gamma S to Ns and in parallel, the total GTPase activity. However, there is little change in the actual rate of catalytic turnover of GTPase activity (defined as mol of Pi released/min/mol of Ns-guanine nucleotide complexes). Enhancement of this turnover rate requires the beta-agonist isoproterenol and is accounted for by an isoproterenol-promoted increase in the rate and extent of [35S]GTP gamma S binding to Ns. The co-insertion of the beta AR with Ni or transducin results in markedly lower stimulation by isoproterenol of both the GTPase activity and [35S]GTP gamma S binding to these nucleotide regulatory proteins indicating that their preferred order of interaction with beta AR is Ns much greater than Ni greater than T. This contrasts with the preferred order of interaction of these different nucleotide regulatory proteins with light-activated rhodopsin which we find to be T approximately equal to Ni much greater than Ns. Nonetheless the fold stimulation of GTPase activity and [35S]GTP gamma S binding in T, induced by light-activated rhodopsin, is significantly greater than the "fold" stimulation of these activities in Ni. This reflects the greater intrinsic ability of Ni to hydrolyze GTP and bind guanine nucleotides (at 10 mM MgCl2, 100-200 nM GTP or [35S] GTP gamma S) compared to T. The maximum turnover numbers for the rhodopsin-stimulated GTPase in both Ni and T are similar to those obtained for isoproterenol-stimulated activity in Ns. This suggests that the different nucleotide regulatory proteins are capable of a common upper limit of catalytic efficiency which can best be attained when coupled to the appropriate receptor.     

Functional reconstitution of the alpha 2-adrenergic receptor with guanine nucleotide regulatory proteins in phospholipid vesicles

We describe the successful reconstitution of functional interactions between an inhibitory adenylate cyclase-coupled receptor and various nucleotide-binding regulatory proteins in phospholipid vesicles. The receptor is the alpha 2-adrenergic receptor (alpha 2AR) which has been partially purified (approximately 500-5000-fold) from human platelet membranes. The nucleotide-binding regulatory proteins include purified preparations of human erythrocyte Ni and Ns, bovine retinal transducin and the recently discovered bovine brain No. Addition of the physiologic ligand, epinephrine, to vesicles containing the alpha 2AR and Ni results in stimulation of the GTPase activity in Ni. This stimulation of GTPase activity by epinephrine is prevented in the presence of the alpha-adrenergic antagonist, phentolamine, which indicates that a functional reconstitution of the alpha 2AR and Ni has been established. The maximum turnover number for the alpha 2AR-mediated epinephrine-stimulated GTPase activity in Ni is similar to the maximal turnover numbers obtained for the beta-adrenergic receptor-mediated isoproterenol-stimulated GTPase activity in Ns and the rhodopsin-mediated light-stimulated GTPase activity in transducin (0.5-1.5 mol of Pi released per min per mol of nucleotide regulatory protein). Functional similarities between the alpha 2AR and rhodopsin are observed in their interactions with the various nucleotide-binding regulatory proteins. Thus, both of these receptor proteins are capable of promoting the maximal activation of Ni and No while being much less effective in promoting the activation of Ns. However, there are differences between the alpha 2AR and rhodopsin in their interactions with transducin. Specifically, while rhodopsin will maximally activate transducin, the alpha 2AR is much less effective in promoting this activation (i.e. approximately 20% as effective as rhodopsin). Overall, these results suggest the following specificities of interaction: for rhodopsin, transducin approximately equal to Ni approximately equal to No much greater than Ns; while for alpha 2AR, Ni approximately equal to No greater than transducin greater than or equal to Ns.     

Depalmitylation with hydroxylamine alters the functional properties of rhodopsin

Rhodopsin, the photosensitive protein found in rod photoreceptors, has two covalently attached palmitates that are thought to anchor a portion of the C terminus to the disc membrane, forming a fourth cytoplasmic loop. Using hydroxylamine (NH2OH) to cleave the thioester linkage, we have characterized the effect of depalmitylation on certain functional properties of rhodopsin. Treatment of rod outer segment membranes (prepared from rat retinas previously labeled in vivo with [3H]palmitate) with 1 M NH2OH typically removed greater than or equal to 75% of the [3H]palmitate initially bound to rhodopsin. Spectrophotometry of rod outer segment membranes that had been treated with 1 M NH2OH indicated preservation of 85% of the native rhodopsin and no effect on the shape of the absorbance spectrum of rhodopsin. In vivo labeled rhodopsin that had been treated with 1 M NH2OH did not reincorporate free endogenous [3H] palmitate over a 2-h incubation period. Both NH2OH-treated and untreated rhodopsin incorporated [14C]palmitate from exogenously added [14C]palmitoyl-CoA. This incorporation was substantially greater in the NH2OH-treated sample. The removal of palmitate by NH2OH inhibited rhodopsin regeneration by 44% and increased the ability of rhodopsin to activate transducin's light-dependent GTPase activity by 61%. However, the removal of palmitate from rhodopsin did not affect the light-dependent binding of transducin (T alpha and T beta gamma).     

Rhodopsin-stimulated activation-deactivation cycle of transducin: kinetics of the intrinsic fluorescence response of the alpha subunit

The intrinsic tryptophan fluorescence of the alpha subunit of transducin (alpha T) has been shown to be sensitive to the binding of guanine nucleotides, with the fluorescence being enhanced by as much as 2-fold upon the binding of GTP or nonhydrolyzable GTP analogues [cf. Phillips and Cerione (1988) J. Biol. Chem. 263, 15498-15505]. In this work, we have used these fluorescence changes to analyze the kinetics for the activation (GTP binding)-deactivation (GTPase) cycle of transducin in a well-defined reconstituted phospholipid vesicle system containing purified rhodopsin and the alpha T and beta gamma T subunits of the retinal GTP-binding protein. Both the rate and the extent of the GTP-induced fluorescence enhancement are dependent on [rhodopsin], while only the rate (and not the extent) of the GTP gamma S-induced enhancement is dependent on the levels of rhodopsin. Comparisons of the fluorescence enhancements elicited by GTP gamma S and GTP indicate that the GTP gamma S-induced enhancements directly reflect the GTP gamma S-binding event while the GTP-induced enhancements represent a composite of the GTP-binding and GTP hydrolysis events. At high [rhodopsin], the rates for GTP binding and GTPase are sufficiently different such that the GTP-induced enhancement essentially reflects GTP binding. A fluorescence decay, which always follows the GTP-induced enhancement, directly reflects the GTP hydrolytic event. The rate of the fluorescence decay matches the rate of [32P]Pi production due to [gamma-32P]GTP hydrolysis, and the decay is immediately reversed by rechallenging with GTP. The GTP-induced fluorescence changes (i.e., the enhancement and ensuing decay) could be fit to a simple model describing the activation-deactivation cycle of transducin. The results of this modeling suggest the following points: (1) the dependency of the activation-deactivation cycle on [rhodopsin] can be described by a simple dose response profile; (2) the rate of the rhodopsin-stimulated activation of multiple alpha T(GDP) molecules is dependent on [rhodopsin] and when [alpha T] greater than [rhodopsin], the activation of the total alpha T pool may be limited by the rate of dissociation of rhodopsin from the activated alpha T(GTP) species; and (3) under conditions of optimal rhodopsin-alpha T coupling (i.e., high [rhodopsin]), the cycle is limited by GTP hydrolysis with the rate of Pi release, or any ensuing conformational change, being at least as fast as the hydrolytic event.     

cGMP suppresses GTPase activity of a portion of transducin equimolar to phosphodiesterase in frog rod outer segments. Light-induced cGMP decreases as a putative feedback mechanism of the photoresponse.

In rod photoreceptor cells, the light response is triggered by an enzymatic cascade that causes cGMP levels to fall: excited rhodopsin (Rho*)----rod G-protein (transducin, Gt)----cGMP-phosphodiesterase (PDE). This results in the closure of plasma membrane channels that are gated by cGMP. PDE activation by Gt occurs when GDP bound to the alpha-subunit of Gt (Gt alpha) is exchanged with free GTP. The interaction of Gt alpha-GTP with the gamma-subunits of PDE releases their inhibitory action and causes cGMP hydrolysis. Inactivation is thought to be caused by subsequent hydrolysis of Gt alpha-GTP by an intrinsic Gt-GTPase activity. Here we report that there are two portions of Gt in frog rod outer segments (ROS) expressing different rates of GTP hydrolysis: 19.5 +/- 3 mmol of Gt/mol of Rho, equivalent to that amount which participates in PDE activation, hydrolyzing GTP at a rate of approximately 0.6 turnover/s ("fast") and the remaining Gt (80.5 +/- 3 mmol/mol Rho) hydrolyzing GTP at a rate of 0.058 +/- 0.009 turnover/s. Fast GTPase activity is abolished in the presence of cGMP. This effect occurs over the physiological range of cGMP concentration changes in ROS, half-saturating at approximately 2 microM and saturating at 5 microM cGMP. cGMP-dependent suppression of GTPase is specific for cGMP; cAMP in millimolar concentration does not affect GTPase, while the poorly hydrolyzable cGMP analogue, 8-bromo-cGMP, mimics the effect. GTPase regulation by cGMP is not affected by Ca2+ over the concentration range 5-500 nM, which spans the physiological changes in cytoplasmic Ca2+ in rod cells. We suggest that the fast cGMP-sensitive GTPase activity is a property of the Gt that activates PDE. In this model, cGMP serves not only as a messenger of excitation but also modulates GTPase activity, thereby mediating negative feedback regulation of the pathway via PDE turnoff: a light-dependent decrease in cGMP accelerates the hydrolysis of GTP bound to Gt, resulting in the rapid inactivation of PDE.     

Interplay of phosphorylation and dephosphorylation in vision: protein phosphatases of bovine rod outer segments

Two types of protein phosphatases were identified in carefully prepared bovine rod outer segments (ROS). Extraction of the ROS with a medium-salt buffer solubilized protein phosphatase activity that was mainly type 2A, since it was active toward phosphorylase a in the absence of divalent cations, was not retained by heparin-Sepharose, dephosphorylated the alpha-subunit of phosphorylase kinase faster that the beta-subunit, and was unaffected by inhibitor 2. Further extraction of the resulting membranes with a high-salt buffer solubilized additional phosphatase activity which was predominantly type 1, since it was retained by heparin-Sepharose and was blocked by inhibitor 2. The molecular mass of the type 2A phosphatase estimated by gel permeation chromatography on Superose 12 was 100 kDa, suggesting it may be the 2A2 form. Only the ROS type 2A phosphatase dephosphorylated opsin and rhodopsin efficiently. Concordant with this finding, the purified catalytic subunit of protein phosphatase 2A from rabbit skeletal muscle dephosphorylated opsin efficiently, while the type 1 catalytic subunit isolated from this tissue was inactive. Together, the results suggest that the ROS type 2A protein phosphatase plays an important role in regenerating rhodopsin from the various phosphorylated species in vivo. The activity of the enzyme per retina (approximately 85 pmol of Pi released/min) is comparable to that of rhodopsin kinase (100 pmol of phosphate transferred/min).     

Transducin GTPase provides for rapid quenching of the cGMP cascade in rod outer segments

The role of transducin GTPase in rapid cGMP phosphodiesterase quenching was studied by simultaneous registration of GTP hydrolysis and phosphodiesterase activity in the same rod outer segments (ROS) preparation. The results thus obtained allow the conclusion that: (i) phosphodiesterase quenching coincides with transducin-bound GTP hydrolysis independently of ROS concentration; (ii) an increase in the ROS concentration results in the acceleration of cascade quenching due to the existence of a GTPase accelerating mechanism in ROS; (iii) approximation to physiological conditions (protein concentration, temperature) provides a transducin GTPase rate equal to 1–2 turnovers per second i.e., sufficiently high for satisfying the real rate of photoresponse reversion in dark-adapted rods.     

Rapid transducin deactivation in intact stacks of bovine rod outer segment disks as studied by light scattering techniques. Arrestin requires additional soluble proteins for rapid quenching of rhodopsin catalytic activity

In photoreceptors of the living retina both activation and deactivation of transducin must occur in less than 1 s. In ROS preparations used for in vitro studies, however, deactivation takes minutes. This is due to the fact that activated transducin is released into the free aqueous space, whereby GTPase activity and consequent deactivation of the protein are slowed down, and due to the dilution of soluble ROS proteins involved in the quenching of rhodopsin activity. In this paper, using a convenient, non-invasive light scattering assay, we demonstrate that in an intact stack of disks, where active transducin stays membrane associated and is rapidly deactivated, the activity of rhodopsin can also be quenched in the time range of seconds when soluble ROS proteins are supplemented. Arrestin, the 48 kDa protein of the photoreceptor, is one of the proteins required for rapid recovery, however, it requires the synergistic action of other soluble proteins (besides rhodopsin kinase) in order to exert its effect: When arrestin is included in the reaction mixture without the 'helper protein(s)', it cannot speed recovery, and when a mixture of soluble proteins is added which lacks arrestin, there is also no effect. The nature and identity of this (these) helper protein(s) are still unclear.     

Sub-second turnover of transducin GTPase in bovine rod outer segments. A light scattering study

A fast, regenerative light scattering signal from bovine ROS, the PA-signal, reflects the light-induced, transient activation of transducin. Its rate of recovery depends on the number of photolysed rhodopsin molecules, indicating that rhodopsin deactivation and not GTPase activity is rate limiting in our in vitro system. When rhodopsin deactivation is accelerated (in the presence of NH2OH), PA-signal recovery is also accelerated. A GTPase turnover number of more than 2 s-1 (at 37 degrees C) can be derived from these experiments. This is more than one order of magnitude faster than the GTPase rates so far described in the literature and is rapid enough for a physiological shut-off mechanism. The fast GTPase is attributed to a highly intact disk stack, which never releases transducin into the free aqueous space.     

Regulation of retinal transducin by C-terminal peptides of rhodopsin.

Transducin is a multi-subunit guanine-nucleotide-binding protein that mediates signal coupling between rhodopsin and cyclic GMP phosphodiesterase in retinal rod outer segments. Whereas the T alpha subunit of transducin binds guanine nucleotides and is the activator of the phosphodiesterase, the T beta gamma subunit may function to link physically T alpha with photolysed rhodopsin. In order to determine the binding sites of rhodopsin to transducin, we have synthesized eight peptides (Rhod-1 etc.) that correspond to the C-terminal regions of rhodopsin and to several external and one internal loop region. These peptides were tested for their inhibition of restored GTPase activity of purified transducin reconstituted into depleted rod-outer-segment disc membranes. A marked inhibition of GTPase activity was observed when transducin was pre-incubated with peptides Rhod-1, Rhod-2 and Rhod-3. These peptides correspond to opsin amino acid residues 332-339, 324-331 and 317-321 respectively. Peptides corresponding to the three external loop regions or to the C-terminal residues 341-348 did not inhibit reconsituted GTPase activity. Likewise, Rhod-8, a peptide corresponding to an internal loop region of rhodopsin, did not inhibit GTPase activity. These findings support the concept that these specific regions of the C-terminus of rhodopsin serve as recognition sites for transducin.     

Role of membrane integrity on G protein-coupled receptors: Rhodopsin stability and function

Rhodopsin is a prototypical G protein-coupled receptor (GPCR) - a member of the superfamily that shares a similar structural architecture consisting of seven-transmembrane helices and propagates various signals across biological membranes. Rhodopsin is embedded in the lipid bilayer of specialized disk membranes in the outer segments of retinal rod photoreceptor cells where it transmits a light-stimulated signal. Photoactivated rhodopsin then activates a visual signaling cascade through its cognate G protein, transducin or Gt, that results in a neuronal response in the brain. Interestingly, the lipid composition of ROS membranes not only differs from that of the photoreceptor plasma membrane but is critical for visual transduction. Specifically, lipids can modulate structural changes in rhodopsin that occur after photoactivation and influence binding of transducin. Thus, altering the lipid organization of ROS membranes can result in visual dysfunction and blindness.     

Regulation of retinal cGMP cascade by phosducin in bovine rod photoreceptor cells. Interaction of phosducin and transducin.

Photoexcitation of retinal rod photoreceptor cells involves the activation of cGMP enzyme cascade in which sequential activation of rhodopsin, transducin, and the cGMP phosphodiesterase in the rod outer segment constitutes the signal amplification mechanism. Phosducin, a 33-kDa phosphoprotein, has been shown to form a tight complex with the T beta gamma subunit of transducin. In this study, we examined the interaction of phosducin-T beta gamma and the possible regulatory role of phosducin on the cGMP cascade. Addition of phosducin to photolyzed rod outer segment (ROS) membrane reduced the GTP hydrolysis activity of transducin as well as the subsequent activation of the cGMP phosphodiesterase. Phosducin also inhibited the pertussis toxin-catalyzed ADP-ribosylation of transducin, indicating that the interaction between the T alpha and T beta gamma subunits of transducin was interrupted upon binding of phosducin. The inhibitory effects of phosducin were reversed by the addition of exogenous T beta gamma. These results suggest that phosducin is capable of regulating the amount of T beta gamma available to interact with T alpha to form the active transducin complex and thereby functions as a negative regulator of the cGMP cascade. The phosducin-induced alteration of the subunit organization of transducin was examined by chemical cross-linking method using para-phenyl dimaleimide as cross-linker. It was found that the cross-linking among T alpha and T beta gamma was blocked in the presence of phosducin. This result implies that T beta gamma may undergo a conformational change upon phosducin binding which leads to the release of T alpha. Since phosducin is a soluble protein, the interaction with transducin only occurs when transducin is dissociated from ROS disc membrane. Indeed, phosducin failed to dissociate membrane-bound transducin and did not inhibit the initial cycle of transducin activation as measured by the presteady state GTP hydrolysis. However, phosducin interacts effectively with transducin released into solution after the initial activation and blocks the re-binding of T alpha. T beta gamma to ROS membrane by forming a tight complex with T beta gamma. This interaction may play an important role in regulating the turnover of the cGMP cascade in photoreceptor cells.     

Protein kinase activity of bovine retina rod outer segments

Dark-adapted pure bovine rod outer segments (ROS) (A280/A500--2.1) can be phosphorylated in the presence of [gamma-32P]ATP and [gamma-32P]GTP. The constant levels of phosphorylation, reached within 10--15 min, are 100 +/- 30 pmol 32P/nmol of rhodopsin for [gamma-32P]ATP and 2--4 pmol 32P/nmol of rhodopsin for [gamma-32P]GTP. These processes are not controlled by 10(-4)--10(-8) cAMP, cGMP or Ca2+, but are inhibited at higher concentrations of these agents. In the presence of histone the constant level of phosphorylation is increased up to 200 +/- 30 pmol 32P/nmol of rhodopsin for [gamma-32P]ATP, but is not changed when [gamma-32P]GTP is used. 10(-5) M cAMP is found to activate the phosphorylation in the presence of histone and [gamma-32P]ATP by 5--6 times. All this evidences that ROS contains cAMP-dependent protein kinase, which utilizes ATP, but not GTP. Moreover, ROS contains cyclic nucleotides- and Ca2+-independent protein kinase. These protein kinases are the ROS endogenous enzymes. This is shown in experiments on separation of pure ROS in a sucrose density gradient.     

A single amino acid substitution in rhodopsin (lysine 248----leucine) prevents activation of transducin

In structure-function studies on bovine rhodopsin by in vitro site-specific mutagenesis, we have prepared three mutants in the cytoplasmic loop between the putative transmembrane helices E and F. In each mutant, charged amino acid residues were replaced by neutral residues: mutant 1, Glu239----Gln; mutant 2, Lys248----Leu; and mutant 3, Glu247----Gln, Lys248----Leu, and Glu249----Gln. The mutant rhodopsin genes were expressed in monkey kidney (COS-1) cells. After the addition of 11-cis-retinal to the cells, the rhodopsin mutants were purified by immunoaffinity adsorption. Each mutant gave a wild-type rhodopsin visible absorption spectrum. The mutants were assayed for their ability to stimulate the GTPase activity of transducin in a light-dependent manner. While mutants 1 and 3 showed wild-type activity, mutant 2 (Lys248----Leu) was inactive.     

Reconstitution of catecholamine-stimulated guanosinetriphosphatase activity

beta-Adrenergic receptors were partially purified from turkey erythrocyte membranes by alprenolol-agarose chromatography to 0.25-2 nmol/mg of protein, and the stimulatory guanosine 5'-triphosphate (GTP) binding protein of adenylate cyclase (Gs) was purified from rabbit liver. These proteins were reconstituted into phospholipid vesicles by addition of phospholipids and removal of detergent by gel filtration. This preparation hydrolyzes GTP to guanosine 5'-diphosphate (GDP) plus inorganic phosphate (Pi) in response to beta-adrenergic agonists. The initial rate of isoproterenol-stimulated hydrolysis is approximately 1 mol of GTP hydrolyzed min-1 X mol-1 of Gs. This low rate may be limited by the hormone-stimulated binding of substrate, since it is roughly equal to the rate of binding of the GTP analogue guanosine 5'-O-(3-[35S] thiotriphosphate) [( 35S]GTP gamma S) to Gs in the vesicles. Activity in the absence of agonist, or in the presence of agonist plus a beta-adrenergic antagonist, is 8-25% of the hormone-stimulated activity. Guanosinetriphosphatase (GTPase) is not saturated at 10 microM GTP, and the response to GTP is formally consistent either with the existence of multiple Km's or of a separate stimulatory site for GTP. The GTPase activity of Gs in vesicles is also stimulated by 50 mM MgCl2 in the presence or absence of receptor. Significant GTPase activity is not observed with Lubrol-solubilized Gs, although [35S]-GTP gamma S binding is increased by Lubrol solubilization.     

Catecholamine-stimulated GTPase activity in turkey erythrocyte membranes.

Determination of specific GTPase (EC 3.6.1.--) activity in turkey erythrocyte membranes was achieved using low concentration of GTP (0.25 muM), inhibition of nonspecific nucleoside triphosphatases by adenosine 5'(beta,gamma-imino-triphosphate (App(NH)p) and suppression of the transfer of gamma-32P from GTP to ADP with an ATP regeneration system. Under these conditions catacholamines caused a 30--70% increase in GTP hydrolysis. The stimulation of GTPase activity by catecholamines required the presence of Mg2+ or Mn2+. DIfferent batches of membranes revealed the following specific activities (pmol 32Pi/mg protein min): basal GTPase (determined in the absence of catecholamine), 6-- 11; catecholamine-stimulated TTPase, 3--7; and residual non-specific NTPase 3--5. The stimulation of GTPase activity by catecholamines fulfilled the stereospecific requirements of the beta-adrenergic receptor, and was inhibited by propranolol. The concentrations of DL-isoproterenol which half-maximally activated the GTPase and adenylate cyclase were 1 and 1.2 muM, respectively. The following findings indicate that the catecholamine-stimulated GTPase is independent of the catalytic production of cyclic AMP by the adenylate cyclase. Addition of cyclic AMP to the GTPase assay did not change the rate of GTP hydrolysis. Furthermore, treatment of the membrane with N-ethylmaleimide (MalNEt) at 0 degrees C which caused 98% inhibition of the adenylate cyclase, had no effect on the catecholamine-stimulated GTPase. The affinity and specificity for GTP in the GTPase reactions are similar to those previously reported for the stimulation of the adenylate cyclase. The apparent Km for GTP in the basal and the catecholamine-stimulated GTPase reaction was 0.1 muM. These GTPase activities were inhibited by ITP but not by CTP and UTP. It is proposed that a catecholamine-stimulated GTPase is a component of the turkey erythrocyte adenylate cyclase system.     

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.