Kinetic analysis of the activation of transducin by photoexcited rhodopsin. Influence of the lateral diffusion of transducin and competition of guanosine diphosphate and guanosine triphosphate for the nucleotide site.

The activation of transducin (T) by photoexcited rhodopsin (R*) is kinetically dissected within the framework of Michaelis-Menten enzymology, taking transducin as substrate of the enzyme R*. The light scattering "release" signal (Vuong, T.M., M. Chabre, and L. Stryer, 1984, Nature (Lond.). 311:659-661) was used to monitor the kinetics of transducin activation at 20 degrees C. In addition, the influence of nonuniform distributions of R* on these activation kinetics is also explored. Sinusoidal patterns of R* were created with interference fringes from two crossed laser beams. Two characteristic times were extracted from the Michaelis-Menten analysis: t(form), the diffusion-related time needed to form the enzyme-substrate R*-transducin is 0.25 +/- 0.1 ms, and T(cat), the time taken by R* to perform the chemistry of catalysis on transducin is 1.2 +/- 0.2 ms, in the absence of added guanosine diphosphate (GDP) and at saturating levels of guanosine triphosphate (GTP). With t(form) being but 20% of the total activation time t(form) + t(cat), transducin activation by R* is not limited by lateral diffusion. This is further borne out by the observation that uniform and sinusoidal patterns of R* elicited release signals of indistinguishable kinetics. When (GDP) = (GTP) = 500 microM, t(cat) is lengthened twofold. As the in vivo GDP and GTP levels are comparable, the exchange of nucleotides may well be the rate-limiting process.     

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.     

Cyclic GMP and photoreceptor function.

A single photon can be detected by a rod photoreceptor cell. The absorption of light by rhodopsin triggers a cascade of reactions that amplifies the photon signal and results in ion channel closure with hyperpolarization of the rod photoreceptor cell. Light-induced conformational changes in rhodopsin facilitate the binding of a guanosine nucleotide-binding protein, transducin, which then undergoes a GTP-GDP exchange reaction and dissociation of the transducin complex. A subunit of transducin then activates a phosphodiesterase complex that hydrolyzes cyclic GMP. In darkness, cyclic GMP binds to cation channels of the photoreceptor plasma membrane, maintaining them in an open configuration. The light-induced reduction in cyclic GMP concentration dissociates the bound cyclic GMP, resulting in channel closure and hyperpolarization. Down-regulation of the cascade involves other proteins that block the interaction of transducin with rhodopsin and another protein that may interfere with transducin recycling. Cone photoreceptors possess a light-activated cascade that follows the rod format, but it is composed of proteins that are homologous to those of rod photoreceptors. Phototransduction in invertebrate photoreceptors uses rhodopsin to activate a cascade that uses phosphoinositides and calcium ion to regulate membrane polarization.     

The gain of rod phototransduction: reconciliation of biochemical and electrophysiological measurements

We have resolved a central and long-standing paradox in understanding the amplification of rod phototransduction by making direct measurements of the gains of the underlying enzymatic amplifiers. We find that under optimized conditions a single photoisomerized rhodopsin activates transducin molecules and phosphodiesterase (PDE) catalytic subunits at rates of 120-150/s, much lower than indirect estimates from light-scattering experiments. Further, we measure the Michaelis constant, Km, of the rod PDE activated by transducin to be 10 microM, at least 10-fold lower than published estimates. Thus, the gain of cGMP hydrolysis (determined by kcat/Km) is at least 10-fold higher than reported in the literature. Accordingly, our results now provide a quantitative account of the overall gain of the rod cascade in terms of directly measured factors.     

Effect of detergents and lipids on transducin photoactivation by rhodopsin.

Rhodopsin samples, isolated using four different extraction procedures, were used to investigate the photodependent activation of the GTPase activity of transducin. A complete inhibition of transducin light-dependent GTP hydrolytic activity was observed when rhodopsin purified in the presence of 1% digitonin, following rod outer segment (ROS) solubilization with 1% 3-[(3-cholamidopropyl) dimethylammonio]-1-propane-sulfonate (CHAPS), was used for its activation [0 pmol of inorganic phosphate (Pi) released/min/pmol of rhodopsin]. Rhodopsin, isolated in the presence of 1% digitonin following ROS solubilization with 1% digitonin, was capable of stimulating slightly transducin GTPase activity, with an initial rate of 1 pmol of GTP hydrolyzed/min/pmol of rhodopsin. However, rhodopsin purified in the presence of 0.2% n-dodecyl-beta-D-maltoside (DM), following ROS solubilization with either 1% CHAPS or 1% DM, stimulated the enzymatic activity of transducin in a light-dependent manner, with an initial rate of 5 pmol of Pi released/min/pmol of rhodopsin. Addition of 0.075% egg phosphatidylcholine (PC) to the four different solubilized rhodopsin samples significantly enhanced light-stimulated GTP hydrolysis by transducin, with initial rates increasing from 0 to 1, 1 to 2, and 5 to 30 pmol of Pi released/min/pmol of rhodopsin, respectively. Furthermore, DM-solubilized rhodopsin induced the hydrolysis of the maximum amount of GTP by transducin at 0.0075% PC, while digitonin-solubilized rhodopsin only stimulated the GTPase activity of transducin to a similar value, when the amount of the photoreceptor protein was increased 4-fold and 0.15% PC was added to the assay mixture. These results suggest that the effective photoactivation of transducin by rhodopsin requires phospholipids, which seem to be differentially eliminated with the detergent extraction procedure utilized during ROS membranes solubilization and photopigment isolation.     

An improved rhodopsin/EGFP fusion protein for use in the generation of transgenic Xenopus laevis

Previous studies by Papermaster and coworkers introduced the use of rhodopsin-green fluorescent protein (rho-GFP) fusion proteins in the construction of transgenic Xenopus laevis with retinal rod photoreceptor cell-specific transgene expression [Moritz et al., J. Biol. Chem. 276 (2001) 28242-28251]. These pioneering studies have helped to develop the Xenopus system not only for use in the investigation of rhodopsin biosynthesis and targeting, but for studies of the phototransduction cascade as well. However, the rho-GFP fusion protein used in the earlier work had only 50% of the specific activity of wild-type rhodopsin for activation of transducin and only 10% of the activity of wild-type in rhodopsin kinase assays. While not a problem for the biosynthesis studies, this does present a problem for investigation of the phototransduction cascade. We report here an improved rhodopsin/EGFP fusion protein in which placement of the EGFP domain at the C-terminus of rhodopsin results in wild-type activity for activation of transducin, wild-type ability to serve as a substrate for rhodopsin kinase, and wild-type localization of the protein to the rod photoreceptor cell outer segment in transgenic X. laevis.     

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.     

Calcium-dependent assembly of centrin-G-protein complex in photoreceptor cells

Photoexcitation of rhodopsin activates a heterotrimeric G-protein cascade leading to cyclic GMP hydrolysis in vertebrate photoreceptors. Light-induced exchanges of the visual G-protein transducin between the outer and inner segment of rod photoreceptors occur through the narrow connecting cilium. Here we demonstrate that transducin colocalizes with the Ca(2+)-binding protein centrin 1 in a specific domain of this cilium. Coimmunoprecipitation, centrifugation, centrin overlay, size exclusion chromatography, and kinetic light-scattering experiments indicate that Ca(2+)-activated centrin 1 binds with high affinity and specificity to transducin. The assembly of centrin-G-protein complex is mediated by the betagamma-complex. The Ca(2+)-dependent assembly of a G protein with centrin is a novel aspect of the supply of signaling proteins in sensory cells and a potential link between molecular translocations and signal transduction in general.     

Chromium(III) beta, gamma-bidentate guanine nucleotide complexes as probes of the GTP-activated cGMP cascade of retinal rod outer segments

The exchange-inert Cr(III) beta, gamma-bidentate guanine nucleotide complexes Cr(III)GTP and Cr(III)Gpp(NH)p were used to probe the role of transducin in activating the retinal cGMP cascade. The Cr(III) nucleotide complexes were found to have lower binding affinity for transducin as compared to the Mg2+ complexes. However, the rate of hydrolysis of the transducin-bound Cr(III)GTP was similar to that of Mg(II)GTP. Cr(III)Gpp(NH)p activated the cGMP phosphodiesterase of photolyzed rod outer segment membranes up to 75% of the Mg(II)Gpp(NH)p level but lacked the ability to dissociated the transducin subunits from the rod outer segment membrane. This result implies that the activation of the phosphodiesterase by transducin-GTP complex is a membrane-associated event and the formation of a soluble complex of transducin-GTP with the inhibitory peptide of the phosphodiesterase may not be an obligatory step. Both the delta and lambda screw sense stereoisomers of Cr(III)Gpp(NH)p were capable of activating the cGMP cascade with no apparent stereoselectivity. The nature of the interaction of the metal ion and GTP at the nucleotide-binding site of transducin is discussed together with the results from previous studies using the phosphorothioate GTP analogues [Yamanaka, G., Eckstein, F., & Stryer, L. (1985) Biochemistry 24, 8094-8101] and is compared to the site found in homologous GTP-binding proteins such as elongation factor Tu [Jurnak, F. (1985) Science (Washington, D.C.) 230, 32-36; la Cour, T.F.M., Nyborg, J., Thirup, S., & Clark, B.F.C. (1985) EMBO J. 4, 2385-2388]. The implications of the observed results on the molecular mechanism of visual signal transduction are discussed.     

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.     

Preferential retention of paternal alleles in human retinoblastoma: evidence for genomic imprinting

The origins of the initial mutations in sporadic retinoblastoma were explored using polymorphic markers from chromosome 13q. The paternal chromosome was maintained in 3 of 3 informative bilateral tumors which had undergone reduction to homozygosity for regions of this chromosome. The paternal chromosome was maintained in 7 of 8 informative unilateral tumors which likewise demonstrated a reduction of homozygosity. These data are in contrast to previously published studies of chromosome retention in unilateral retinoblastoma [Dryja, T. P., Mukai, S., Petersen, R., Rapaport, J. M., Walton, D., and Yandel, D. W. Nature (Lond.), 339: 556-558, 1989; Zhu, Z., Dunn, J. M., Phillips, R. A., Goddard, A. D., Paton, K. E., Becker, A., and Gallie, B. L. Nature (Lond.), 340: 312-313, 1989] and provide the first evidence that genomic imprinting may play a role in this disease.     

Molecular design of an amplification cascade in vision

The photoexcitation of rhodopsin triggers a cascade that results in the hydrolysis of a large number of molecules of cyclic GMP. The molecular mechanism of this amplification cascade has been delineated. Transducin, a multisubunit perpheral membrane protein, is the information-carrying intermediate in the activation of the cyclic GMP phosphodiesterase. Photoexcited rhodopsin (R*) castalyzes the exchange of GRP for GDP bound to the α-subunit of transducin (T). About 500 molecules of T_α-GTP are formed per absorbed photon at low light levels. T_α-GTP, rekeased from the β- and γ-subunits of transducin, then activates the phosphodiesterase by relieving an inhibitory constraint imposed by its small sununit. Each actived phosphodiesterase molecule hydrolyzes more than 100 cyclic GMP/s, giving an overall gain of more than 500,000. Photoexcited rhodopsin triggers the activation of a molecule of transducin in a millisecond, which is sufficiently rapid to enable this cascade to participate in visual excitation. Hydrolysis of GTP bound to T_α seves to restore the system to the dark state. Transducin, like the G proteins of the adenylate cyclase casecade, can be specifically ADP-ribosylated by cholera toxin and pertussis toxin. In both cascades, labling by pertussis toxin blocks the capacity of transducin to interact with the excited receptor, whereas labeling by cholera toxin inhibits the hydrolysis of bound GTP, leading to persistent activation. Moreover, the moleculaar design of the hormone-triggered cyclic AMP cascade is similar to that of the light-triggered cyclic GMP cascade. It seems likely that transducin, the stimulatory G protein, the inhibitor G protein, and the ras protein are members of the same family of signal amplifiers. The study of the cyclic nucleotide cascade of vision is providing rewarding views of recurring motifs of signal amplification in nature.     

Characterization of transducin from bovine retinal rod outer segments. Mechanism and effects of cholera toxin-catalyzed ADP-ribosylation

Transducin, a guanine nucleotide-binding protein consisting of two subunits (T alpha and T beta gamma), mediates the signal coupling between rhodopsin and a membrane-bound cyclic GMP phosphodiesterase in retinal rod outer segments. The T alpha subunit is an activator of the phosphodiesterase, and the function of the T beta gamma subunit is to physically link T alpha with photolyzed rhodopsin. In this study, the mechanism of cholera toxin-catalyzed ADP-ribosylation of T alpha has been examined in a reconstituted system consisting of purified transducin and stripped rod outer segment membranes. Limited proteolysis of the labeled T alpha with trypsin indicated that the inserted ADP-ribose is located exclusively on a single proteolytic fragment with an apparent molecular weight of 23,000. Maximal incorporation of ADP-ribose was achieved when guanosine 5'-(beta, gamma-imido)triphosphate (Gpp(NH)p) and T beta gamma were present at concentrations equal to that of T alpha and when rhodopsin was continuously irradiated with visible light in the 400-500 nm region. The stimulating effect of illumination was related to the direct interaction of the retinal chromophore with opsin. These findings strongly suggest that a transient protein complex consisting of T alpha X Gpp(NH)p, T beta gamma, and a photointermediate of rhodopsin is the required substrate for cholera toxin. Single turnover kinetic measurements demonstrated that the ADP-ribosylation of T alpha coincided with the appearance of a population of transducin molecules having a very slow rate of GTP hydrolysis. The hydrolysis rate of the bound GTP for this population was 1.1 X 10(-3)/s, which was 22-fold slower than the rate for the unmodified transducin.     

Reaction rate and collisional efficiency of the rhodopsin-transducin system in intact retinal rods.

A model of transducin activation is constructed from its partial reactions (formation of metarhodopsin II, association, and dissociation of the rhodopsin-transducin complex). The kinetic equations of the model are solved both numerically and, for small photoactivation, analytically. From data on the partial reactions in vitro, rate and activation energy profile of amplified transducin turnover are modeled and compared with measured light-scattering signals of transducin activation in intact retinal rods. The data leave one free parameter, the rate of association between transducin and rhodopsin. Best fit is achieved for an activation energy of 35 kJ/mol, indicating lateral membrane diffusion of the proteins as its main determinant. The absolute value of the association rate is discussed in terms of the success of collisions to form the catalytic complex. It is greater than 30% for the intact retina and 10 times lower after permeabilization with staphylococcus aureus alpha-toxin. Dissociation rates for micromolar guanosinetriphosphale (GTP) (Kohl, B., and K. P. Hofmann, 1987. Biophys. J. 52:271-277) must be extrapolated linearly up to the millimolar range to explain the rapid transducin turnover in situ. This is interpreted by an unstable rhodopsin-transducin-GTP transient state. At the time of maximal turnover after a flash, the rate of activation is determined as 30, 120, 800, 2,500, and 4,000 activated transducins per photoactivated rhodopsin and second at 5, 10, 20, 30, 37 degrees C, respectively.     

The delta subunit of type 6 phosphodiesterase reduces light-induced cGMP hydrolysis in rod outer segments

The delta subunit of the rod photoreceptor PDE has previously been shown to copurify with the soluble form of the enzyme and to solubilize the membrane-bound form (). To determine the physiological effect of the delta subunit on the light response of bovine rod outer segments, we measured the real time accumulation of the products of cGMP hydrolysis in a preparation of permeablized rod outer segments. The addition of delta subunit GST fusion protein (delta-GST) to this preparation caused a reduction in the maximal rate of cGMP hydrolysis in response to light. The maximal reduction of the light response was about 80%, and the half-maximal effect occurred at 385 nm delta subunit. Several experiments suggest that this effect was not due to the effects of delta-GST on transducin or rhodopsin kinase. Immunoblots demonstrated that exogenous delta-GST solubilized the majority of the PDE in ROS but did not affect the solubility of transducin. Therefore, changes in the solubility of transducin cannot account for the effects of delta-GST in the pH assay. The reduction in cGMP hydrolysis was independent of ATP, which indicates that it was not due to effects of delta-GST on rhodopsin kinase. In addition to the effect on cGMP hydrolysis, the delta-GST fusion protein slowed the turn-off of the system. This is probably due, at least in part, to an observed reduction in the GTPase rate of transducin in the presence of delta-GST. These results demonstrate that delta-GST can modify the activity of the phototransduction cascade in preparations of broken rod outer segments, probably due to a functional uncoupling of the transducin to PDE step of the signal transduction cascade and suggest that the delta subunit may play a similar role in the intact outer segment.     

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.     

Reconstitution of the vertebrate visual cascade using recombinant heterotrimeric transducin purified from Sf9 cells

For reconstitution studies with rhodopsin and cGMP phosphodiesterase (PDE), all three subunits of heterotrimeric transducin (T alpha beta gamma) were simultaneously expressed in Sf9 cells at high levels using a baculovirus expression system and purified to homogeneity. Light-activated rhodopsin catalyzed the loading of purified recombinant T alpha with GTP gamma S. In vitro reconstitution of rhodopsin, recombinant transducin, and PDE in detergent solution resulted in cGMP hydrolysis upon illumination, demonstrating that recombinant transducin was able to activate PDE. The rate of cGMP hydrolysis by PDE as a function of GTP gamma S-loaded recombinant transducin (T(*)) concentration gave a Hill coefficient of approximately 2, suggesting that the activation of PDE by T(*) was cooperatively regulated. Furthermore, the kinetic rate constants for the activation of PDE by T(*) suggested that only the complex of PDE with two T(*) molecules, PDE. T(2)(*), was significantly catalytically active under the conditions of the assay. We conclude that the model of essential coactivation best describes the activation of PDE by T(*) in a reconstituted vertebrate visual cascade using recombinant heterotrimeric transducin.     

On the role of transducin GTPase in the quenching of a phosphodiesterase cascade of vision

The rate of GTP hydrolysis in the active site of transducin and that of the release of the phosphate thus formed have been measured. The former step has been found to be a rate-limiting one. The rate constant for GTP hydrolysis is equal to 0.027 s-1 at 23 degrees C, and 0.07 s-1 at 37 degrees C. Besides, it has been shown that the rate of GTPase reaction on the transducin alpha-subunit does not depend on the concentration of a complex of transducin beta- and gamma-subunits or on the presence of cGMP phosphodiesterase and a 48 kDa protein from rod outer segments. According to the results, GTP hydrolysis on transducin proceeds too slowly to account for the rapid quenching of a phosphodiesterase cascade in rod outer segments.     

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.     

Light-induced conformational changes of rhodopsin probed by fluorescent alexa594 immobilized on the cytoplasmic surface

A novel fluorescence method has been developed for detecting the light-induced conformational changes of rhodopsin and for monitoring the interaction between photolyzed rhodopsin and G-protein or arrestin. Rhodopsin in native membranes was selectively modified with fluorescent Alexa594-maleimide at the Cys(316) position, with a large excess of the reagent Cys(140) that was also derivatized. Modification with Alexa594 allowed the monitoring of fluorescence changes at a red excitation light wavelength of 605 nm, thus avoiding significant rhodopsin bleaching. Upon absorption of a photon by rhodopsin, the fluorescence intensity increased as much as 20% at acidic pH with an apparent pK(a) of approximately 6.8 at 4 degrees C, and was sensitive to the presence of hydroxylamine. These findings indicated that the increase in fluorescence is specific for metarhodopsin II. In the presence of transducin, a significant increase in fluorescence was observed. This increase of fluorescence emission intensity was reduced by addition of GTP, in agreement with the fact that transducin enhances the formation of metarhodopsin II. Under conditions that favored the formation of a metarhodopsin II-Alexa594 complex, transducin slightly decreased the fluorescence. In the presence of arrestin, under conditions that favored the formation of metarhodopsin I or II, a phosphorylated, photolyzed rhodopsin-Alexa594 complex only slightly decreased the fluorescence intensity, suggesting that the cytoplasmic surface structure of metarhodopsin II is different in the complex with arrestin and transducin. These results demonstrate the application of Alexa594-modified rhodopsin (Alexa594-rhodopsin) to continuously monitor the conformational changes in rhodopsin during light-induced transformations and its interactions with other proteins.