Functional modifications of transducin induced by cholera or pertussis-toxin-catalyzed ADP-ribosylation.

Transducin (T alpha beta gamma), the heterotrimeric GTP-binding protein that interacts with photoexcited rhodopsin (Rh*) and the cGMP-phosphodiesterase (PDE) in retinal rod cells, is sensitive to cholera (CTx) and pertussis toxins (PTx), which catalyze the binding of an ADP-ribose to the alpha subunit at Arg174 and Cys347, respectively. These two types of ADP-ribosylations are investigated with transducin in vitro or with reconstituted retinal rod outer-segment membranes. Several functional perturbations inflicted on T alpha by the resulting covalent modifications are studied such as: the binding of T alpha to T beta gamma to the membrane and to Rh*; the spontaneous or Rh*-catalysed exchange of GDP for GTP or guanosine 5-[gamma-thio]triphosphate (GTP[gamma S]), the conformational switch and activation undergone by transducin upon this exchange, the activation of T alpha GDP by fluoride complexes and the activation of the PDE by T alpha GTP. ADP-ribosylation of transducin by CTx requires the GTP-dependent activation of ADP-ribosylation factors (ARF), takes place only on the high-affinity, nucleotide-free complex, Rh*-T alpha empty-T beta gamma and does not activate T alpha. Subsequent to CTx-catalyzed ADP-ribosylation the following occurs: (a) addition of GDP induces the release from Rh* of inactive CTxT alpha GDP (CTxT alpha, ADP-ribosylated alpha subunit of transducin) which remains associated to T beta gamma; (b) CTxT alpha GDP-T beta gamma exhibits the usual slow kinetics of spontaneous exchange of GDP for GTP[gamma S] in the absence of Rh*, but the association and dissociation of fluoride complexes, which act as gamma-phosphate analogs, are kinetically modified, suggesting that the ADP-ribose on Arg174 specifically perturbs binding of the gamma-phosphate in the nucleotide site; (c) CTxT alpha GDP-T beta gamma can still couple to Rh* and undergo fast nucleotide exchange; (d) CTxT alpha GTP[gamma S] and CTxT alpha GDP-AlFx (AlFx, Aluminofluoride complex) activate retinal cGMP-phosphodiesterase (PDE) with the same efficiency as their unmodified counterparts, but the kinetics and affinities of fluoride activation are changed; (e) CTxT alpha GTP hydrolyses GTP more slowly than unmodified T alpha GTP, which entirely accounts for the prolonged action of CTxT alpha GTP on the PDE; (f) after GTP hydrolysis, CTxT alpha GDP reassociates to T beta gamma and becomes inactive. Thus, CTx catalyzed ADP-ribosylation only perturbs in T alpha the GTP-binding domain, but not the conformational switch nor the domains of contact with the T beta gamma subunit, with Rh* and with the PDE.(ABSTRACT TRUNCATED AT 400 WORDS)     

The transitory complex between photoexcited rhodopsin and transducin. Reciprocal interaction between the retinal site in rhodopsin and the nucleotide site in transducin

In the first step of the visual transduction cascade a photoexcited rhodopsin molecule, R*ret, binds to a GDP-carrying transducin molecule, TGDP. The R*-T interaction causes the opening of the nucleotide site in T and catalyzes the GDP/GTP exchange by allowing the release of the GDP. We have studied the influences on this R*-T transitory complex of the occupancies of the nucleotide site in T and the retinal site in rhodopsin. After elimination of the GDP released from the bound transducin, the complex, named R*ret-te (ret for retinal present, e for nucleotide site empty) remains stabilized almost indefinitely in a medium whose ionic composition is close to physiological. In this complex the bound Te retains a lasting ability to interact with GDP or GTP, and R*ret remains spectroscopically in the meta-II state, by contrast with free R*ret which decays to opsin and free retinal. Hence the R*-T interaction which opens the nucleotide site in T conversely blocks the retinal site in R*ret. Upon prolonged incubation in a low-ionic-strength medium the R*ret-Tc complex dissociates partially, but the liberated Te is then unable to rebind GDP or GTP, even in the presence of R*ret, it is probably denaturated. Upon treatment of the R*ret-Te complex by a high concentration of hydroxylamine, the retinal can be removed from the rhodopsin. The Re-Te complex remains stable and the complexed transducin keeps its capacity to bind GTP. TGTP then dissociates from Re. The liberated Re loses its capacity to interact with a new transducin. These data are integrated into a discussion of the development of the cascade. We stress that affinities, i.e. dissociation equilibrium constants, are insufficient to describe the flow of reactions triggered by one R*ret molecule. It depends on a few critical rapid binding and dissociation processes, and is practically insensitive to other slow ones, hence to the values of affinities that express only the ratio of kinetics constants. The effect of the R*-T interaction on the retinal site in rhodopsin is analogous to the effect of the binding of a G-protein on the apparent affinity of a receptor for its agonist.     

Molecular mechanism of GTP hydrolysis by bovine transducin: pre-steady-state kinetic analyses.

During the visual transduction process in rod photoreceptor cells, transducin (T) mediates the flow of information from photoexcited rhodopsin (R*) to the cGMP phosphodiesterase (PDE) via a cycle of GTP binding and hydrolysis. The pre-steady-state kinetics of GTP hydrolysis by T was studied by rapid quenching and filtration techniques in a reconstituted system containing purified R* and T. Kinetic analyses have shown that the turnover of T-bound GTP can be dissected into four partial reactions: (1) the R*-catalyzed GTP binding via a GDP/GTP exchange reaction, (2) the on-site hydrolysis of bound GTP, which leads to the formation of a T-GDP.Pi complex, (3) the release of the tightly bound inorganic phosphate (Pi) from T-GDP.Pi, and (4) the recycling of T-GDP. The R*-catalyzed GTP binding was estimated to occur in less than 1 s. In rapid acid quenching experiments, the rate of Pi formation due to GTP hydrolysis exhibited biphasic characteristics. An initial burst of Pi formation occurred between 1 and 4 s, which was followed by a slow steady-state rate. Increasing T concentration yielded a proportional increase in the burst and steady-state rate. The addition of Gpp(NH)p decreased both parameters. D2O decreased the rise of the initial burst with a kinetic isotope effect of approximately 1.7 but has no effect on the steady-state rate of Pi formation. These results indicate that the burst represents the fast hydrolysis of GTP at the binding site of T, which results in the accumulation of T-GDP.Pi complexes. The steady-state rate represents the slow release of Pi. This finding was further supported by rapid filtration experiments that monitored the formation of free Pi in solution. An initial lag time in the formation of free Pi was observed before a steady-state rate was established, indicating that the initially formed Pi was tightly bound to T. Finally, the release of GDP from T-GDP.Pi was not detected. This suggests that another cycle of GTP exchange catalyzed by R* should occur before the release of bound GDP. The rate of Pi release from T-GDP.Pi was measured under single-turnover conditions and had a half life of approximately 20 s, which was identical with the rate of deactivation of the PDE due to GTP hydrolysis by T.(ABSTRACT TRUNCATED AT 400 WORDS)     

Allosteric behavior in transducin activation mediated by rhodopsin. Initial rate analysis of guanine nucleotide exchange

Photolyzed rhodopsin acts in a catalytic manner to mediate the exchange of GTP for GDP bound to transducin. We have analyzed the steady-state kinetics of this activation process in order to determine the molecular mechanism of interactions between rhodopsin, transducin, and guanine nucleotides. Initial velocities (Vo) of the exchange reaction catalyzed by rhodopsin were measured for various transducin concentrations at several fixed levels of the GTP analog, [35S]guanosine 5'-(3-O-thio)triphosphate (GTP gamma S). The initial rate data analysis rigorously demonstrates that rhodopsin mediates the activation of transducin by a double-displacement catalytic mechanism. The Michaelis-Menten curves determined as a function of [transducin] reveal remarkable allosteric behavior; analysis of this data yields a Hill coefficient of 2. Lineweaver-Burk plots of Vo-1 versus [transducin]-1 display curvilinearity indicative of positive cooperativity and a series of parallel lines are generated by plotting Vo-1 as a function of [transducin]-2. The plots of Vo-1 versus [GTP gamma S]-1 show no evidence of allosterism and are a parallel series. Furthermore, the allosteric behavior observed in the activation of transducin is also witnessed in the rhodopsin-catalyzed guanine nucleotide exchange of the G protein's purified alpha subunit in the absence of the beta X gamma subunit complex. The latter observation implies that the molecular basis for allosterism in the activation process resides in the interactions between the photoreceptor and transducin's alpha subunit.     

Mechanism of inhibition of transducin guanosine triphosphatase activity by vanadate

The visual excitation system of the retinal rod outer segments and the hormone-sensitive adenylate cyclase complex are regulated through guanine nucleotide-binding proteins, transducin in the former and inhibitory and stimulatory regulatory components, Gi and Gs, in the latter. These proteins are functionally and structurally similar; all are heterotrimers composed of alpha, beta, and gamma subunits and exhibit guanosine triphosphatase activity stimulated by light-activated rhodopsin or the agonist-receptor complex. Adenylate cyclase can be stimulated by vanadate, which, like NaF, probably acts through Gs. Effects of vanadate on the function of a guanine nucleotide-binding protein were investigated in a reconstituted model system consisting of purified transducin subunits (T alpha, T beta gamma) and rhodopsin in phosphatidylcholine vesicles. Vanadate (decameric) inhibited [3H]GTP binding to T alpha and noncompetitively inhibited GTP hydrolysis in a concentration-dependent manner with maximal inhibition of approximately 90% at 3-5 mM. Vanadate also inhibited release of bound GDP but did not affect the rate of hydrolysis of bound GTP (single turnover rate), indicating that vanadate did not interfere with the intrinsic GTPase activity of T alpha. Binding of T alpha to rhodopsin and the ADP-ribosylation of T alpha by pertussis toxin, both of which are enhanced in the presence of T beta gamma, were inhibited by vanadate. These findings are consistent with the conclusion that vanadate can cause the dissociation of T alpha from T beta gamma, resulting in the inhibition of GDP-GTP exchange and thereby GTP hydrolysis. Adenylate cyclase activation could result from a similar effect of vanadate on Gs.     

Probing the mechanism of rhodopsin-catalyzed transducin activation

An agonist-bound G protein-coupled receptor (GPCR) induces a GDP/GTP exchange on the G protein alpha-subunit (G alpha) followed by the release of G alpha GTP and G beta gamma which, subsequently, activate their targets. The C-terminal regions of G alpha subunits constitute a major receptor recognition domain. In this study, we tested the hypothesis that the GPCR-induced conformational change is communicated from the G alpha C-terminus, via the alpha 5 helix, to the nucleotide-binding beta 6/alpha 5 loop causing GDP release. Mutants of the visual G protein, transducin, with a modified junction of the C-terminus were generated and analyzed for interaction with photoexcited rhodopsin (R*). A flexible linker composed of five glycine residues or a rigid three-turn alpha-helical segment was inserted between the 11 C-terminal residues and the alpha 5 helix of G alpha(t)-like chimeric G alpha, G alpha(ti). The mutant G alpha subunits with the Gly-loop (G alpha(ti)L) and the extended alpha 5 helix (G alpha(ti)H) retained intact interactions with G beta gamma(t), and displayed modestly reduced binding to R*. G alpha(ti)H was capable of efficient activation by R*. In contrast, R* failed to activate G alpha(ti)L, suggesting that the Gly-loop absorbs a conformational change at the C-terminus and blocks G protein activation. Our results provide evidence for the role of G alpha C-terminus/alpha 5 helix/beta 6/alpha 5 loop route as a dominant channel for transmission of the GPCR-induced conformational change leading to G protein activation.     

Interaction of retinal transducin with guanosine triphosphate analogues: specificity of the gamma-phosphate binding region

The interaction of six hydrolysis-resistant analogues of GTP with transducin, the signal-coupling protein in vertebrate photoreceptors, was investigated. GppNHp and GppCH2p differ from GTP at the bridging position between the beta- and gamma-phosphate groups. The other analogues studied (GTP gamma F, GTP gamma OMe, GTP gamma OPh, and GTP gamma S) differ from GTP in containing a substituent on the gamma-phosphorus atom or at a nonbridging gamma-oxygen atom. Competition binding experiments were carried out by adding an analogue, [alpha-32P]GTP, and a catalytic amount of photoexcited rhodopsin (R) to transducin and measuring the amount of bound [gamma-32P]GTP. The order of effectiveness of these analogues in binding to transducin was GTP gamma S greater than GTP much greater than GppNHp greater than GTP gamma OPh greater than GTP gamma OMe greater than GppCH2p greater than GTP gamma F A second assay measured the effectiveness of GTP gamma S, GppNHp, and GppCH2p in eluting transducin from disc membranes containing R. The basis of this assay is that transducin is released from disc membranes when it is activated to the GTP form. The relative potency of these three analogues in converting transducin from a membrane-bound to a soluble form was 1000, 75, and 1, respectively. Stimulation of cGMP phosphodiesterase activity served as a third criterion of the interaction of these analogues with transducin. The order of effectiveness of these analogues in promoting the transducin-mediated activation of the phosphodiesterase was GTP gamma S greater than GTP much greater than GppNHp greater than GTP gamma OPh much greater than GppCH2p greater than GTP gamma OMe greater than GTP gamma F GTP gamma S was more than a 1000 times as potent as GTP gamma F in activating the phosphodiesterase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions between the subunits of transducin and cyclic GMP phosphodiesterase in Rana catesbiana rod photoreceptors

In bullfrog (Rana catesbiana) rods the activity of cyclic GMP (cGMP) phosphodiesterase was stimulated 10 times by washing disc membranes with an isotonic, GTP-containing buffer. This stimulation was maintained following hydrolysis of GTP and after removal of guanine nucleotides. At least 60-70% of the inhibitory gamma subunit of cGMP phosphodiesterase (P gamma) was physically released from membranes by these washing procedures. When cGMP phosphodiesterase was activated by a hydrolysis-resistant GTP analogue, P gamma was found in the supernatant complexed with the transducin alpha subunit (T alpha) using three chromatography systems. When GTP was used to activate cGMP phosphodiesterase, P gamma was also found in the supernatant complexed with GDP.T alpha. This complex was also isolated using the same three chromatography systems, indicating that P gamma remained tightly bound to T alpha even after bound GTP was hydrolyzed. Interaction with the beta,gamma subunits of transducin, which remained associated with disc membranes, was required for the release of P gamma from the GDP.T alpha complex, which resulted in the deactivation of active cGMP phosphodiesterase. We conclude that during activation of cGMP phosphodiesterase, P gamma is complexed with T alpha (both GTP and GDP forms) in the supernatant and that, following GTP hydrolysis, beta,gamma subunits of transducin are necessary for the release of P gamma from the complex and the resulting inactivation of cGMP phosphodiesterase in frog photoreceptors.     

Chemical modification of transducin with iodoacetic acid: transducin-alpha carboxymethylated at Cys(347) allows transducin binding to Light-activated rhodopsin but prevents its release in the presence of GTP.

Modification of transducin (T) with iodoacetic acid (IAA) inhibited its light-dependent guanine nucleotide-binding activity. Approximately 1 mol of [(3)H]IAA was incorporated per mole of T. Cys(347), located on the alpha-subunit of T (T(alpha)), was identified as the major labeled residue in the [(3)H]IAA-modified holoenzyme. In contrast, Cys(135) and Cys(347) were modified with [(3)H]IAA in the isolated T(alpha). IAA-modified T was able to bind tightly to photoexcited rhodopsin (R*), but GTP did not promote the dissociation of the complex between alkylated T and R*. In addition, R* protected against the inhibition of T by IAA. A comparable inactivation of T and analogous interactions between T and R* were observed when 2-nitro 5-thiocyanobenzoic acid (NTCBA) was used as the modifying reagent (J. O. Ortiz and J. Bubis, 2001, Effects of differential sulfhydryl group-specific labeling on the rhodopsin and guanine nucleotide binding activities of transducin, Arch. Biochem. Biophys. 387, 233-242). However, while carboxymethylated T was capable of liberating GDP in the presence of R*, NTCBA-modified T was unable to release the guanine nucleotide diphosphate upon incubation with the photoactivated receptor. Thus, IAA-labeling stabilized a T:R* complex intermediate carrying the empty nucleotide pocket conformation of T. On the other hand, NTCBA-modified T seemed to be "locked" in the GDP-bound state of T, even in the presence of R*.     

Maximal rate and nucleotide dependence of rhodopsin-catalyzed transducin activation: initial rate analysis based on a double displacement mechanism

Despite the growing structural information on receptors and G proteins, the information on affinities and kinetics of protein-protein and protein-nucleotide interactions is still not complete. In this study on photoactivated rhodopsin (R*) and the rod G protein, G(t), we have used kinetic light scattering, backed by direct biochemical assays, to follow G protein activation. Our protocol includes the following: (i) to measure initial rates on the background of rapid depletion of the G(t)GDP substrate; (ii) to titrate G(t)GDP, GTP, and GDP; and (iii) to apply a double displacement reaction scheme to describe the results. All data are simultaneously fitted by one and the same set of parameters. We obtain values of K(m) = 2200 G(t)/microm(2) for G(t)GDP and K(m) = 230 microm for GTP; dissociation constants are K(d) = 530 G(t)/microm(2) for R*-G(t)GDP dissociation and K(d) = 270 microm for GDP release from R*G(t)GDP, once formed. Maximal catalytic rates per photoexcited rhodopsin are 600 G(t)/s at 22 degrees C and 1300 G(t)/s at 34 degrees C. The analysis provides a tool to allocate and quantify better the effects of chemical or mutational protein modifications to individual steps in signal transduction.     

Stereochemistry of the guanyl nucleotide binding site of transducin probed by phosphorothioate analogues of GTP and GDP

The stereochemistry of the guanyl nucleotide binding site of transducin from bovine retinal rod outer segments was probed with phosphorothioate analogues of GTP and GDP. Transducin has markedly different affinities for the five thio analogues of GTP, as measured by their effectiveness in inhibiting GTPase activity, competing with GTP for entry into transducin, and displacing GDP bound to transducin. The order of binding affinities is GTP gamma S = (Sp)-GTP alpha S greater than (Rp)-GTP alpha S greater than (Sp)-GTP beta S much greater than (Rp)-GTP beta S. The affinity of transducin for GTP gamma S is greater than 10(4) higher than that for (Rp)-GTP beta S. These five analogues have the same relative potencies in eliciting the release of transducin from the membrane and in activating the phosphodiesterase. Transducin hydrolyzes (Sp)-GTP alpha S with a l/e time of 55 s, compared with 28 s for GTP. In contrast, (Rp)-GTP alpha S, like GTP gamma S, is not hydrolyzed on the time scale of several hours. The order of effectiveness of thio analogues of GDP in displacing bound GDP is (Sp)-GDP alpha S greater than GDP greater than (Rp)-GDP alpha S greater than GDP beta S. The affinity of transducin for (Sp)-GDP alpha S is about 10-fold higher than that for GDP beta S. Mg2+ is required for the binding of GTP and GDP to transducin. Cd2+ does not lead to a reversal of stereospecificity at either the alpha- or beta-phosphorus atom of GTP. These results lead to the following conclusions: The pro-R oxygen atom at the alpha-phosphorus of GTP does not bind Mg2+ but instead interacts with the protein. The pro-S oxygen at the alpha-phosphorus does not appear to be involved in a critical interaction with transducin.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Effect of GDP on transducin interaction with cyclic nucleotide phosphodiesterase and rhodopsin from bovine retinal rods

In the presence of guanyl nucleotides and rhodopsin-containing retinal rod outer segment membranes, transducin stimulates the light-sensitive cyclic nucleotide phosphodiesterase 5.5-7 times. The activation constant (Ka) for GTP and Gpp(NH)p is 0.25 microM, that for GDP and GDP beta S is 14 and 110 microM, respectively. GDP purified from other nucleotide contaminations at concentrations up to 1 mM does not stimulate phosphodiesterase but binds to transducin and inhibits the Gpp(NH)p-dependent activation of phosphodiesterase. The mode of transducin interaction with bleached rhodopsin also depends on the nature of the bound guanyl nucleotide: in the presence of GDP rhodopsin-containing membranes bind 70-100% of transducin, whereas in the presence of Gpp(NH)p the membranes bind only 13% of the protein. The experimental results suggest that GDP and GTP convert transducin into two different functional states, i.e., the transducin X GTP complex binds to phosphodiesterase causing its stimulation, while the transducin X GDP complex is predominantly bound to rhodopsin.     

Labeling of the beta gamma subunit complex of transducin with an environmentally sensitive cysteine reagent. Use of fluorescence spectroscopy to monitor transducin subunit interactions

In this study, we have examined the interactions of the beta gamma subunit complex of the retinal GTP-binding protein transducin (beta gamma T) with its alpha subunit (alpha T) using fluorescence spectroscopic approaches. The beta gamma T subunit complex was covalently labeled with 2-(4'-maleimidylanilino)napthalene-6-sulfonic acid (MIANS), an environmentally sensitive fluorescent cysteine reagent. The formation of the MIANS beta gamma T complexes (two to five MIANS adducts per beta gamma T) resulted in 2-3-fold enhancements in the MIANS fluorescence, and 20-25-nm blue shifts in the fluorescence emission maxima, relative to the emission for identical concentrations of MIANS-labeled MIANS complexes. The addition of alpha T.GDP to these MIANS beta gamma T complexes resulted in an additional enhancement in the MIANS fluorescence (typically ranging from 20 to 40%) and a 5-10-nm blue shift in the wavelength for maximum emission. These fluorescence changes were specifically elicited by the GDP-bound form of alpha T and were not observed upon the addition of purified alpha T.guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) complexes to the MIANS beta gamma T species. Conditions which resulted in the activation of the alpha T.GDP subunit (i.e. the addition of AlF4- or the addition of rhodopsin-containing vesicles and GTP gamma S) resulted in a reversal of the alpha T.GDP-induced enhancement of the MIANS beta gamma T fluorescence. Thus the MIANS beta gamma T fluorescence provided a spectroscopic monitor for transducin-subunit association and transducin-activation. Based on the results from studies using this spectroscopic read-out, it appears that the association of the alpha T.GDP species with the beta gamma T subunit complex to form the holotransducin molecule is rapid and does not limit the rate of the rhodopsin-stimulated activation of holotransducin. However, either the dissociation of the activated alpha T subunit from the beta gamma T complex, or a conformational change in beta gamma T which occurs as a result of the subunit dissociation event, appears to be slow relative to the G protein-subunit association event.     

The intrinsic fluorescence of the alpha subunit of transducin. Measurement of receptor-dependent guanine nucleotide exchange

We have made use of the enhancement of the intrinsic fluorescence of the alpha subunit of transducin (alpha T), which accompanies guanine nucleotide exchange, to follow the reconstituted interactions between pure rhodopsin and pure transducin in phospholipid vesicles. When the pure alpha T.GDP complex is added to lipid vesicles containing rhodopsin and the beta gamma T complex, a light- and guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S)-dependent enhancement of the fluorescence emission of alpha T is observed. When GTP is substituted for GTP gamma S, a similar enhancement of the intrinsic fluorescence of alpha T occurs; however, this enhancement is transient and precedes a fluorescence decay which is complete in 2-5 min. The fact that the fluorescence decay is specifically induced by GTP and is not observed either with nonhydrolyzable GTP analogs or with NaF (plus AlCl3) indicates that the decay represents GTP hydrolysis in alpha T. The dose-response profiles for the effects of the beta gamma T complex on the rate and extent of the GTP gamma S-stimulated fluorescence enhancement of alpha T have also been examined. The addition of relatively low levels of beta gamma T to these reconstituted systems can promote the GTP gamma S-stimulated enhancement of the fluorescence of multiple alpha T subunits with half-maximal enhancement occurring at alpha T:beta gamma T ratios of 150:1. These findings are consistent with earlier suggestions (Fung, B. K.-K. (1983) J. Biol. Chem. 258, 10495-10502) that the beta gamma T subunit dissociates from alpha T as a result of the GDP-GTP exchange reaction and thus can act catalytically to promote the activation of a number of inactive alpha T species. However, the dependence of the rate of the GTP gamma S-stimulated fluorescence enhancement on beta gamma T is complex and cannot be explained adequately by simple models where alpha T-beta gamma T interactions (or rhodopsin-transducin interactions) are rate-limiting for the rhodopsin-stimulated activation of the alpha T subunits. Overall, the results reported here demonstrate that fluorescence spectroscopy can be used to monitor directly a receptor-catalyzed activation-deactivation cycle of a GTP-binding protein within a lipid milieu.     

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.     

Characterization of the aluminum and beryllium fluoride species which activate transducin. Analysis of the binding and dissociation kinetics.

Aluminofluoride and beryllofluoride complexes can activate the heterotrimeric G-proteins by binding next to GDP in the nucleotide site of their G alpha subunit and acting as analogs of the gamma-phosphate of a GTP. However, the exact structures of the activatory complexes in solution as well as those of the bound complexes in the nucleotide site are still disputed. We have studied, by monitoring the activation-dependent tryptophan fluorescence of transducin T alpha subunit, the pF (-log[F-]) and pH dependencies of the kinetics of activation and deactivation of T alpha GDP in the presence of NaF and aluminum or beryllium salts. Comparisons were made with the calculated pF and pH dependencies of the distribution of the metallofluoride complexes, in order to identify the activating species. We observed that the contribution of a magnesium-dependent mechanism of activation by fluoride (Antonny, B., Bigay, J., and Chabre, M. (1990) FEBS Lett. 268, 277-280) and effects due to slow equilibration kinetics between various aluminofluoride complexes could give rise to puzzling kinetics that had caused misinterpretations of previous results. Once corrected for these effects, our results suggest that with aluminum AlF3(OH)- is, rather than AlF4-, the main activating species and that the bound form of the complex is tetracoordinated GDP-AlF3. Deactivation kinetics depend on the free fluoride concentration in the medium, suggesting that the simple bimolecular scheme: T alpha GDP-AlF3 in equilibrium with T alpha GDP+AlF3(OH) does not fully describe the interaction. Fluorides in the bound complexes can also exchange with free F- ions in solution. With beryllium, two complexes are activatory: BeF3-.H2O and BeF2(OH)-.H2O. In the nucleotide site these give two tetracoordinated complexes, GDP.BeF3 and GDP.BeF2(OH), as shown by their different dissociation rates.     

Expression of p21 proteins in Escherichia coli and stereochemistry of the nucleotide-binding site.

v-Ha-ras encoded p21 protein (p21V), the cellular c-Ha-ras encoded protein (p21C) and its T24 mutant form p21T were produced in Escherichia coli under the control of the tac promoter. Large amounts of the authentic proteins in a soluble form can be extracted and purified without the use of denaturants or detergents. All three proteins are highly active in GDP binding, GTPase and, for p21V, autokinase activity. Inhibition of [3H]GDP binding to p21C by regio- and stereospecific phosphorothioate analogs of GDP and GTP was investigated to obtain a measure of the relative affinities of the three diphosphate and five triphosphate analogs of guanosine. p21 has a preference for the Sp isomers of GDP alpha S and GTP alpha S. It has low specificity for the Sp isomer of GTP beta S. Together with the data for GDP beta S and GTP gamma S these results are compared with those obtained for elongation factor (EF)Tu and transducin. This has enabled us to probe the structural relatedness of these proteins. We conclude that p21 seems to be more closely related to EF-Tu than to transducin.     

Affinity of transducin for photoactivated rhodopsin: dependence on nucleotide binding state

The interaction of the rod GTP binding protein, Transducin (G(t)), with bleached Rhodopsin (R(*)) was investigated by measuring radiolabeled guanine nucleotide binding to and release from soluble and/or membrane-bound G(t) by reconstituting G(t) containing bound GDP (G(t-)GDP) or the hydrolysis-resistant GTP analog guanylyl imidodiphosphate (G(t-)p[NH]ppG) with R* under physiological conditions. Release of GDP and p[NH]ppG from G(t) occurred to the same extent and with the same light sensitivity both in the presence and absence of added GTP. Significant amounts of G(t) without bound nucleotide (G(t-)) were generated. When ROS containing bleached rhodopsin (R(*)) were centrifuged in low ionic strength buffer, G(t-) remained associated with the membrane fraction, whereas G(t-)GDP remained in the soluble fraction. These results suggest that G(t-)GDP and G(t-)p[NH]ppG have similar affinities for R(*). The results also suggest that G(t-), rather than G(t-)GDP, is the moiety which exhibits tight, "light-induced" binding to rhodopsin.     

Activation of rat liver adenylate cyclase by guanosine 5''-[beta,gamma-imido]triphosphate and glucagon. Existence of reversibly and irreversibly activated states of the stimulatory GTP-binding protein.

The effects of guanosine 5'-[beta-thio]diphosphate (GDP[S]) on the kinetics of activation of rat liver membrane adenylate cyclase by guanosine 5'-[beta,gamma-imido]triphosphate (p[NH]ppG) were examined. GDP[S] caused immediate inhibition of the activation by p[NH]ppG at all time points tested. Substantial inhibition by GDP[S] was observed even after the time required for the enzyme to reach its steady-state activity, but the extent of inhibition became progressively smaller as the preincubation time with p[NH]ppG increased. The rate at which adenylate cyclase became quasi-irreversibly activated was a strictly first-order process. In the presence of glucagon, the formation of the irreversibly activated state was much slower. A combination of GDP[S] and glucagon could partially reverse the quasi-irreversible activation by p[NH]ppG. Glucagon decreased the lag time required for p[NH]ppG to activate adenylate cyclase and increased the extent of activation by p[NH]ppG. This stimulatory effect of the hormone on top of guanine nucleotide decreased on preincubation with p[NH]ppG, but not with GTP. Our results suggest that the activation of adenylate cyclase by non-hydrolysable GTP analogues is a two-stage process: the formation of a reversibly activated form (G rev) is a rapid process, followed by a much slower formation of the quasi-irreversibly activated form (G irr). Glucagon can stimulate G rev but not G irr, and can partially facilitate the formation of the G rev from the G irr state.