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.     

Defining the interface between the C-terminal fragment of alpha-transducin and photoactivated rhodopsin

A novel combination of experimental data and extensive computational modeling was used to explore probable protein-protein interactions between photoactivated rhodopsin (R*) and experimentally determined R*-bound structures of the C-terminal fragment of alpha-transducin (Gt(alpha)(340-350)) and its analogs. Rather than using one set of loop structures derived from the dark-adapted rhodopsin state, R* was modeled in this study using various energetically feasible sets of intracellular loop (IC loop) conformations proposed previously in another study. The R*-bound conformation of Gt(alpha)(340-350) and several analogs were modeled using experimental transferred nuclear Overhauser effect data derived upon binding R*. Gt(alpha)(340-350) and its analogs were docked to various conformations of the intracellular loops, followed by optimization of side-chain spatial positions in both R* and Gt(alpha)(340-350) to obtain low-energy complexes. Finally, the structures of each complex were subjected to energy minimization using the OPLS/GBSA force field. The resulting residue-residue contacts at the interface between R* and Gt(alpha)(340-350) were validated by comparison with available experimental data, primarily from mutational studies. Computational modeling performed for Gt(alpha)(340-350) and its analogs when bound to R* revealed a consensus of general residue-residue interactions, necessary for efficient complex formation between R* and its Gt(alpha) recognition motif.     

Probing rhodopsin-transducin interactions by surface modification and mass spectrometry

The interactions of rhodopsin and the alpha-subunit of transducin (G(t)) have been mapped using a surface modification "footprinting" approach in conjunction with mass spectrometric analysis employing a synthetic peptide corresponding to C-terminal residues 340-350 of the alpha-subunit of G(t), G(t)alpha(340-350). Membrane preparations of unactivated (Rh) and light-activated rhodopsin (Rh*), each in the presence or absence of G(t)alpha(340-350), were acetylated with the water-soluble reagent sulfosuccinimidyl acetate, and the extent of the acetylation was determined by mass spectrometry. By comparing the differences in acetylation among Rh, Rh*, and the Rh-G(t)alpha(340-350) and Rh*-G(t)alpha(340-350) complexes, we demonstrate that the surface exposure of the acetylation sites was reduced by the conformational change associated with light activation, and that binding of G(t)alpha(340-350) blocks acetylation sites on cytoplasmic loops 1, 2, and 4 of Rh*. In addition, we show evidence of interaction between the end of the C-terminal tail of rhodopsin and G(t)alpha in the unactivated state of rhodopsin.     

Sequence of interactions in receptor-G protein coupling

Guanine nucleotide exchange in heterotrimeric G proteins catalyzed by G protein-coupled receptors (GPCRs) is a key event in many physiological processes. The crystal structures of the GPCR rhodopsin and two G proteins as well as binding sites on both catalytically interacting proteins are known, but the temporal sequence of events leading to nucleotide exchange remains to be elucidated. We employed time-resolved near infrared light scattering to study the order in which the Galpha and Ggamma C-terminal binding sites on the holo-G protein interact with the active state of the GPCR rhodopsin (R*) in native membranes. We investigated these key binding sites within mass-tagged peptides and G proteins and found that their binding to R* is mutually exclusive. The interaction of the holo-G protein with R* requires at least one of the lipid modifications of the G protein (i.e. myristoylation of the Galpha N terminus and/or farnesylation of the Ggamma C terminus). A holo-G protein with a high affinity Galpha C terminus shows a specific change of the reaction rate in the GDP release and GTP uptake steps of catalysis. We interpret the data by a sequential fit model where (i) the initial encounter between R* and the G protein occurs with the Gbetagamma subunit, and (ii) the Galpha C-terminal tail then interacts with R* to release bound GDP, thereby decreasing the affinity of R* for the Gbetagamma subunit. The mechanism limits the time in which both C-terminal binding sites of the G protein interact simultaneously with R* to a short lived transitory state.     

The receptor-bound "empty pocket" state of the heterotrimeric G-protein alpha-subunit is conformationally dynamic

Heterotrimeric G-protein activation by a G-protein-coupled receptor (GPCR) requires the propagation of structural signals from the receptor-interacting surfaces to the guanine nucleotide-binding pocket. To probe conformational changes in the G-protein alpha-subunit (G(alpha)) associated with activated GPCR (R*) interactions and guanine nucleotide exchange, high-resolution solution NMR methods are being applied in studying signaling of the G-protein, transducin, by light-activated rhodopsin. Using these methods, we recently demonstrated that an isotope-labeled G(alpha) reconstituted heterotrimer forms functional complexes under NMR experimental conditions with light-activated, detergent-solubilized rhodopsin and a soluble mimic of R*, both of which trigger guanine nucleotide exchange [Ridge, K. D., et al. (2006) J. Biol. Chem. 281, 7635-7648]. Here, it is shown that both light-activated rhodopsin and the soluble mimic of R form trapped intermediate complexes with a GDP-released "empty pocket" state of the heterotrimer in the absence of GTP (or GTPgammaS). In contrast to guanine nucleotide-bound forms of G(alpha), the NMR spectra of the GDP-released, R-bound empty pocket state of G(alpha) display severe line broadening suggestive of a dynamic intermediate state. Interestingly, the conformation of a GDP-depleted, Mg(2+)-bound state of G(alpha) generated in a manner independent of R* does not exhibit a similar degree of line broadening but rather appears structurally similar to the GDP/Mg(2+)-bound form of the protein. Taken together, these results suggest that R*-mediated changes in the receptor-interacting regions of G(alpha), and not the absence of bound guanine nucleotide, are the predominant factors which dictate G(alpha) conformation and dynamics in this R*-bound state of the heterotrimer.     

Interaction between photoexcited rhodopsin and peripheral enzymes in frog retinal rods. Influence on the postmetarhodopsin II decay and phosphorylation rate of rhodopsin

The major peripheral and soluble proteins in frog rod outer segment preparations, and their interactions with photoexcited rhodopsin, have been compared to those in cattle rod outer segments and found to be similar in both systems. In particular the GTP-binding protein (G) has the same subunit composition, the same abundance relative to rhodopsin (1/10) and it undergoes the same light and nucleotide-dependent interactions with rhodopsin in both preparations. Previous work on cattle rod outer segments has shown that photoexcited rhodopsin (R*), in a state identified with metarhodopsin II, associates with the G protein as a first step to the light-activated GDP/GTP exchange on G. The complex R*-G is stable in absence of GTP, but is rapidly dissociated by GTP owing to the GDP/GTP exchange reaction. Low bleaching extents (less than 10% R*) in absence of GTP therefore create predominantly R*-G complexes, whereas bleaching in presence of GTP creates free R*. We report here that, under conditions of complexed R*, two reactions of R* in frog rod outer segments are highly perturbed as compared to free R*: (a) the spectral decay of metarhodopsin II (MII) into later photoproducts, and (b) the phosphorylation of R* by an ATP-dependent protein kinase. a) The spectral measurements have been performed using linear dichroism on oriented frog rod outer segments; this technique allows discrimination between MII and later photoproducts absorbing at the same wavelength. Association of R* with G leads to a strong reduction of the amount of MIII formed and to an acceleration of the decay of MIII. Furthermore, MII is significantly stabilized, in agreement with the hypothesis that MII is the intermediate which binds to G. b) The phosphorylation of R* is strongly inhibited under conditions of R*-G complex formation as compared to free R*. Interferences between reactions at the three sites involved in R* are discussed: the retinal binding site in the hydrophobic core is sensitive to the presence of GTP-binding protein at its binding site on the cytoplasmic surface of R*; the kinase and the GTP-binding protein compete for access to their respective binding sites, both located on the surface of R*. We also observed a slow and nucleotide-dependent light-induced binding of a protein of molecular weight 50 000, which we consider as the equivalent of the 48 000 Mr light-dependent protein previously identified in cattle rod outer segments.     

Rhodopsin recognition by mutant G(s)alpha containing C-terminal residues of transducin

The C-terminal regions of the heterotrimeric G protein alpha-subunits play key roles in selective activation of G proteins by their cognate receptors. In this study, mutant G(s)alpha proteins with substitutions by C-terminal residues of transducin (G(t)alpha) were analyzed for their interaction with light-activated rhodopsin (R*) to delineate the critical determinants of the G(t)alpha/R* coupling. In contrast to G(s)alpha, a chimeric G(s)alpha/G(t)alpha protein containing only 11 C-terminal residues from transducin was capable of binding to and being potently activated by R*. Our results suggest that Cys(347) and Gly(348) are absolutely essential, whereas Asp(346) is more modestly involved in the G(t) activation by R*. In addition, the analysis of the intrinsic nucleotide exchange in mutant G(s)alpha indicated an interaction between the C terminus and the switch II region in G(t)alpha.GDP. Mutant G(s)alpha containing the G(t)alpha C terminus and substitutions of Asn(239) and Asp(240) (switch II) by the corresponding G(t)alpha residues, Glu(212) and Gly(213), displayed significant reductions in spontaneous guanosine 5'-O-(3-thiotriphosphate)-binding rates to the levels approaching those in G(t)alpha. Communication between the C terminus and switch II of G(t)alpha does not appear essential for the activational coupling between G(t) and R*, but may represent one of the mechanisms by which Galpha subunits control intrinsic nucleotide exchange.     

Mutations at position 125 in transmembrane helix III of rhodopsin affect the structure and signalling of the receptor.

Mutation of L125R in trasmembrane helix III of rhodopsin, associated with the retinal degenerative disease retinitis pigmentosa, was previously shown to cause structural misfolding of the mutant protein. Also, conservative mutations at this position were found to cause partial misfolding of the mutant receptors. We report here on a series of mutations at position 125 to further investigate the role of Leu125 in the correct folding and function of rhodopsin. In particular, the effect of the size of the substituted amino-acid side chain in the functionality of the receptor, measured as the ability of the mutant rhodopsins to activate the G protein transducin, has been analysed. The following mutations have been studied: L125G, L125N, L125I, L125H, L125P, L125T, L125D, L125E, L125Y and L125W. Most of the mutant proteins, expressed in COS-1 cells, showed reduced 11-cis-retinal binding, red-shifts in the wavelength of the visible absorbance maximum, and increased reactivity towards hydroxylamine in the dark. Thermal stability in the dark was reduced, particularly for L125P, L125Y and L125W mutants. The ability of the mutant rhodopsins to activate the G protein transducin was significantly reduced in a size dependent manner, especially in the case of the bulkier L125Y and L125W substitutions, suggesting a steric effect of the substituted amino acid. On the basis of the present and previous results, Leu125 in transmembrane helix III of rhodopsin, in the vicinity of the beta-ionone ring of 11-cis-retinal, is proposed to be an important residue in maintaining the correct structure of the chromophore binding pocket. Thus, bulky substitutions at this position may affect the structure and signallling of the receptor by altering the optimal conformation of the retinal binding pocket, rather than by direct interaction with the chromophore, as seen from the recent crystallographic structure of rhodopsin.     

Mutation of the fourth cytoplasmic loop of rhodopsin affects binding of transducin and peptides derived from the carboxyl-terminal sequences of transducin alpha and gamma subunits

The role of the putative fourth cytoplasmic loop of rhodopsin in the binding and catalytic activation of the heterotrimeric G protein, transducin (G(t)), is not well defined. We developed a novel assay to measure the ability of G(t), or G(t)-derived peptides, to inhibit the photoregeneration of rhodopsin from its active metarhodopsin II state. We show that a peptide corresponding to residues 340-350 of the alpha subunit of G(t), or a cysteinyl-thioetherfarnesyl peptide corresponding to residues 50-71 of the gamma subunit of G(t), are able to interact with metarhodopsin II and inhibit its photoconversion to rhodopsin. Alteration of the amino acid sequence of either peptide, or removal of the farnesyl group from the gamma-derived peptide, prevents inhibition. Mutation of the amino-terminal region of the fourth cytoplasmic loop of rhodopsin affects interaction with G(t) (Marin, E. P., Krishna, A. G., Zvyaga T. A., Isele, J., Siebert, F., and Sakmar, T. P. (2000) J. Biol. Chem. 275, 1930-1936). Here, we provide evidence that this segment of rhodopsin interacts with the carboxyl-terminal peptide of the alpha subunit of G(t). We propose that the amino-terminal region of the fourth cytoplasmic loop of rhodopsin is part of the binding site for the carboxyl terminus of the alpha subunit of G(t) and plays a role in the regulation of betagamma subunit binding.     

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.     

Roles of the transducin alpha-subunit alpha4-helix/alpha4-beta6 loop in the receptor and effector interactions

The visual GTP-binding protein, transducin, couples light-activated rhodopsin (R*) with the effector enzyme, cGMP phosphodiesterase in vertebrate photoreceptor cells. The region corresponding to the alpha4-helix and alpha4-beta6 loop of the transducin alpha-subunit (Gtalpha) has been implicated in interactions with the receptor and the effector. Ala-scanning mutagenesis of the alpha4-beta6 region has been carried out to elucidate residues critical for the functions of transducin. The mutational analysis supports the role of the alpha4-beta6 loop in the R*-Gtalpha interface and suggests that the Gtalpha residues Arg310 and Asp311 are involved in the interaction with R*. These residues are likely to contribute to the specificity of the R* recognition. Contrary to the evidence previously obtained with synthetic peptides of Gtalpha, our data indicate that none of the alpha4-beta6 residues directly or significantly participate in the interaction with and activation of phosphodiesterase. However, Ile299, Phe303, and Leu306 form a network of interactions with the alpha3-helix of Gtalpha, which is critical for the ability of Gtalpha to undergo an activational conformational change. Thereby, Ile299, Phe303, and Leu306 play only an indirect role in the effector function of Gtalpha.     

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.     

Differences in peptide-binding specificity of two ankylosing spondylitis-associated HLA-B27 subtypes

Two HLA-B27 subtypes, B*2702 and B*2705, both associated with ankylosing spondylitis, were tested for binding affinity with a panel of polyalanine model nonapeptides carrying Arg at position 2 (P2) and a series of different amino acids at position 9 (P9). The alpha chains were isolated from BTB(B*2705), C1R/B*2702 (a B*2702 transfectant cell line) and from the NW(B*2702) cell line that has a peculiar peptide presentation behavior. Peptide binding was measured by the HLA alpha chain refolding assay. The results obtained show that: 1) Peptides with basic residues (Arg and Lys) and also aliphatic (Leu) and aromatic (Phe and Tyr) peptides at P9 have a similar high affinity in the binding to B*2705; 2) B*2702 binds well to P9 aliphatic and aromatic peptides but only very weakly to P9 basic peptides. Since both B*2702 and B*2705 are associated with AS the presumed arthritogenic peptide is hypothesized to have an aromatic or aliphatic residue at position 9. Peptides with basic residues in this position would be excluded as candidates because of their low binding affinity with B*2702.     

Binding of human hemoglobin and its polypeptide chains with haptoglobin coupled to an agarose matrix.

The interactions of human haptoglobin covalently linked to agarose with human hemoglobin and with p-chloromercuribenzoic-acid-treated alpha and beta chains (alpha* and beta* chains) were studied by flow chromatography and equilibrium binding. The results indicate that in solid state, haptoglobin maintains the same binding characteristics as in solution, the order of binding affinities being: hemoglobin greater than alpha* chain greater than beta* chain. The study of the binding parameters of the alpha* chain shows an heterogeneity of binding sites on the haptoglobin and an average affinity constant Ka of 3.6 X 10(4)l/mol.     

Crystal structure and ligand-binding studies of a screened peptide complexed with streptavidin.

The thermodynamic binding parameters and crystal structure for streptavidin-peptide complexes where the peptide sequences were obtained by random screening methods are reported. The affinities between streptavidin and two heptapeptides were determined by titrating calorimetric methods [Phe-Ser-His-Pro-Gln-Asn-Thr, Ka = 7944 (+/- 224) M-1, delta G degrees = -5.32 (+/- 0.01) kcal/mol, and delta H degrees = -19.34 (+/- 0.48) kcal/mol; His-Asp-His-Pro-Gln-Asn-Leu, Ka = 3542 (+/- 146) M-1, delta G degrees = -4.84 (+/- 0.03) kcal/mol, and delta H degrees = -19.00 (+/- 0.64) kcal/mol]. The crystal structure of streptavidin complexed with one of these peptides has been determined at 2.0-A resolution. The peptide (Phe-Ser-His-Pro-Gln-Asn-Thr) binds in a turn conformation with the histidine, proline, and glutamine side chains oriented inward at the biotin-binding site. A water molecule is immobilized between the histidine and glutamine side chains of the peptide and an aspartic acid side chain of the protein. Although some of the residues that participate in binding biotin also interact with the screened peptide, the peptide adopts an alternate method of utilizing binding determinants in the biotin-binding site of streptavidin.     

Side chain-side chain interactions of arginine with tyrosine and aspartic acid in Arg/Gly/Tyr-rich domains within plant glycine-rich RNA binding proteins

Plant glycine-rich RNA-binding proteins (GRRBPs) contain a glycine-rich region at the C-terminus whose structure is quite unknown. The C-terminal glycine-rich part is interposed with arginine and tyrosine (arginine/glycine/tyrosine (RGY)-rich domain). Comparative sequence analysis of forty-one GRRBPs revealed that the RGY-rich domain contains multiple repeats of Tyr-(Xaa)h-(Arg)k-(Xaa)l, where Xaa is mainly Gly, "k" is 1 or 2, and "h" and "l" range from 0 to 10. Two peptides, 1 (G1G2Y3G4G5G6R7R8D9G10) and 2 (G1G2R3R4D5G6G7Y8G9G10), corresponding to sections of the RGY-rich domain in Zea mays RAB15, were selected for CD and NMR experiments. The CD spectra indicate a unique, positive band near 228 nm in both peptides that has been ascribed to tyrosine residues in ordered structures. The pH titration by NMR revealed that a side chain-side chain interaction, presumably an H-Nepsilon...O=Cgamma hydrogen bonding interaction in the salt bridge, occurs between Arg (i) and Asp (i + 2). 1D GOESY experiments indicated the presence of NOE between the aromatic side chain proton and the arginine side chain proton in the two peptides suggesting strongly that the Arg (i) aromatic side chain interacts directly with the Tyr (i +/- 4 or i +/- 5) side chain.     

Two-step mechanism of interaction of rhodopsin intermediates with the C-terminal region of the transducin alpha-subunit

Rhodopsin is a prototypical G-protein-coupled receptor that contains 11-cis-retinal as a light-absorbing chromophore. Light causes conformational changes in the protein moiety through cis-trans isomerization of the chromophore, which leads to the formation of G-protein-interacting states. Our previous studies indicated that there are two intermediate states of rhodopsin, Meta Ib and Meta II, which interact differently with retinal G-protein transducin (Gt) [S. Tachibanaki, H. Imai, T. Mizukami, T. Okada, Y. Imamoto, T. Matsuda, Y. Fukada, A. Terakita, and Y. Shichida (1997) Biochemistry 36, 14173-14180]. Here we demonstrate that the interactions of Gt with these intermediates in the absence of GTPgammaS can be mimicked by the C-terminus 11-amino acid peptide (340-350) of the alpha-subunit of Gt (Gt(alpha)), suggesting that the C-terminal region of Gt(alpha) plays important roles in the interaction with rhodopsin intermediates. Replacement of either of the two leucine residues (Leu344 and Leu349) in the peptide with alanine caused the loss of the interaction with Meta II. However, the interaction with Meta Ib was abolished only when both residues were replaced. These results indicate that rearrangement of the C-terminal region of Gt(alpha) after the binding of a rhodopsin intermediate is necessary for the GDP-GTP exchange reaction on Gt(alpha).     

Structural basis of neurophysin hormone specificity: Geometry, polarity, and polarizability in aromatic ring interactions

The structural origins of the specificity of the neurophysin hormone-binding site for an aromatic residue in peptide position 2 were explored by analyzing the binding of a series of peptides in the context of the crystal structure of liganded neurophysin. A new modeling method for describing the van der Waals surface of binding sites assisted in the analysis. Particular attention was paid to the unusually large (5 kcal/mol) difference in binding free energy between Phe and Leu in position 2, a value representing more than three times the maximum expected based on hydrophobicity alone, and additionally remarkable since modeling indicated that the Leu side chain was readily accommodated by the binding pocket. Although evidence was obtained of a weak thermodynamic linkage between the binding interactions of the residue 2 side chain and of the peptide alpha-amino group, two factors are considered central. (1) The bound Leu side chain can establish only one-third of the van der Waals contacts available to a Phe side chain. (2) The bound Phe side chain appears to be additionally stabilized relative to Leu by more favorable dipole and induced dipole interactions with nonaromatic polar and sulfur ligands in the binding pocket, as evidenced by examination of its interactions in the pocket, analysis of the detailed energetics of transfer of Phe and Leu side chains from water to other phases, and comparison with thermodynamic and structural data for the binding of residue 1 side chains in this system. While such polar interactions of aromatic rings have been previously observed, the present results suggest their potential for significant thermodynamic contributions to protein structure and ligand recognition.     

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.     

Extended repertoire of permissible peptide ligands for HLA-B*2702.

Recognition of self peptides bound to the class I major histocompatibility complex molecule HLA-B27 is thought to trigger proliferation of autoreactive T cells and result in autoimmune arthritic diseases. Previous work from other laboratories established that a predominant feature of endogenous peptides eluted from purified B27 is an arginine at position 2. We studied the binding of peptides containing both natural and unnatural amino acids by the subtype HLA-B*2702, with the goal of gaining insight into peptide binding by this B27 subtype that is associated with susceptibility to arthritic disease. A soluble from of B*2702 was depleted of endogenous peptides. We tested the binding of peptides substituted with cysteine, homocysteine, or an alpha-amino-epsilon-mercapto hexanoic acid side chain (Amh) instead of the naturally occurring arginine at position 2, to determine whether the peptide sulfhydryl residue could be covalently linked to cysteine 67 in the B*2702 binding cleft. Although none of the altered peptide sequences bound covalently to B*2702, the affinities of the homocysteine- and Amh-substituted peptides were close to that of the native peptide sequence. Substitutions at position 2 with other side chains, such as glutamine and methionine, also resulted in peptides that bound with only slightly reduced affinity. These results demonstrate that peptide side chains other than arginine at position 2 can be accomodated within the B*2702 peptide binding site with only minor reductions in affinity. This extended repertoire of permissible B27-binding peptides should be taken into account for a consideration of disease-associated peptide sequences.