Inhibition of GDP/GTP exchange on G alpha subunits by proteins containing G-protein regulatory motifs.

A novel Galpha binding consensus sequence, termed G-protein regulatory (GPR) or GoLoco motif, has been identified in a growing number of proteins, which are thought to modulate G-protein signaling. Alternative roles of GPR proteins as nucleotide exchange factors or as GDP dissociation inhibitors for Galpha have been proposed. We investigated the modulation of the GDP/GTP exchange of Gialpha(1), Goalpha, and Gsalpha by three proteins containing GPR motifs (GPR proteins), LGN-585-642, Pcp2, and RapIGAPII-23-131, to elucidate the mechanisms of GPR protein function. The GPR proteins displayed similar patterns of interaction with Gialpha(1) with the following order of affinities: Gialpha(1)GDP >> Gialpha(1)GDPAlF(4)(-) > or = Gialpha(1)GTPgammaS. No detectable binding of the GPR proteins to Gsalpha was observed. LGN-585-642, Pcp2, and RapIGAPII-23-131 inhibited the rates of spontaneous GTPgammaS binding and blocked GDP release from Gialpha(1) and Goalpha. The inhibitory effects of the GPR proteins on Gialpha(1) were significantly more potent, indicating that Gi might be a preferred target for these modulators. Our results suggest that GPR proteins are potent GDP dissociation inhibitors for Gialpha-like Galpha subunits in vitro, and in this capacity they may inhibit GPCR/Gi protein signaling in vivo.

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.

AGS3 inhibits GDP dissociation from galpha subunits of the Gi family and rhodopsin-dependent activation of transducin.

A number of recently discovered proteins that interact with the alpha subunits of G(i)-like G proteins contain homologous repeated sequences named G protein regulatory (GPR) motifs. Activator of G protein signaling 3 (AGS3), identified as an activator of the yeast pheromone pathway in the absence of the pheromone receptor, has a domain with four such repeats. To elucidate the potential mechanisms of regulation of G protein signaling by proteins containing GPR motifs, we examined the effects of the AGS3 GPR domain on the kinetics of guanine nucleotide exchange and GTP hydrolysis by G(i)alpha(1) and transducin-alpha (G(t)alpha). The AGS3 GPR domain markedly inhibited the rates of spontaneous guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS) binding to G(i)alpha and rhodopsin-stimulated GTPgammaS binding to G(t)alpha. The full-length AGS3 GPR domain, AGS3-(463-650), was approximately 30-fold more potent than AGS3-(572-629), containing two AGS3 GPR motifs. The IC(50) values for the AGS3-(463-650) inhibitory effects on G(i)alpha and transducin were 0.12 and 0.15 microm, respectively. Furthermore, AGS3-(463-650) and AGS3-(572-629) effectively blocked the GDP release from G(i)alpha and rhodopsin-induced dissociation of GDP from G(t)alpha. The potencies of AGS3-(572-629) and AGS3-(463-650) to suppress the GDP dissociation rates correlated with their ability to inhibit the rates of GTPgammaS binding. Consistent with the inhibition of nucleotide exchange, the AGS3 GPR domain slowed the rate of steady-state GTP hydrolysis by G(i)alpha. The catalytic rate of G(t)alpha GTP hydrolysis, measured under single turnover conditions, remained unchanged with the addition of AGS3-(463-650). Altogether, our results suggest that proteins containing GPR motifs, in addition to their potential role as G protein-coupled receptor-independent activators of Gbetagamma signaling pathways, act as GDP dissociation inhibitors and negatively regulate the activation of a G protein by a G protein-coupled receptor.

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.

Modulation of transducin GTPase activity by chimeric RGS16 and RGS9 regulators of G protein signaling and the effector molecule.

RGS9, a member of the family of regulators of G protein signaling (RGS), serves as a GTPase-activating protein (GAP) for the transducin alpha-subunit (Gtalpha) in the vertebrate visual transduction cascade. The GAP activity of RGS9 is uniquely potentiated by the gamma-subunit of the effector enzyme, cGMP-phosphodiesterase (Pgamma). In contrast, Pgamma attenuates the GAP effects of several other RGS proteins, including RGS16. We demonstrate here that the Pgamma subunit exerts its effects on the GTPase activity of the Gtalpha-RGS complex via the C-terminal domain, Pgamma-63-87. The structural determinants that control the direction of Pgamma effects on the RGS-Gtalpha system are localized within the RGS domains. The addition of Pgamma caused an increase in the maximal stimulation of Gtalpha GTPase activity by RGS9d without affecting the EC50 value. Modulation of Gtalpha GTPase activity by chimeric RGS16 and RGS9 proteins and Pgamma has been investigated. This analysis suggests that in addition to the differences in primary structures, the overall conformations of the RGS fold in RGS9 and RGS16 are likely to be responsible for the opposite effects of Pgamma on the RGS9 and RGS16 GAP activity. The RGS9 alpha3-alpha5 region constituted the minimal insertion of the RGS9 domain into RGS16 that reversed the inhibitory effect of Pgamma. A model of the RGS9 complex with Gtalpha shows the alpha3-alpha5 helices in RGS9 facing the proximate Pgamma binding site on Gtalpha. Our results and this model demonstrate that the mechanism of potentiation of RGS9 GAP activity by Pgamma involves a more rigid stabilization of the Gtalpha switch regions when Gtalpha is bound to both RGS9 and Pgamma.

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.

Probing domain functions of chimeric PDE6alpha'/PDE5 cGMP-phosphodiesterase.

Chimeric cGMP phosphodiesterases (PDEs) have been constructed using components of the cGMP-binding PDE (PDE5) and cone photoreceptor phosphodiesterase (PDE6alpha') in order to study structure and function of the photoreceptor enzyme. A fully functional chimeric PDE6alpha'/PDE5 enzyme containing the PDE6alpha' noncatalytic cGMP-binding sites, and the PDE5 catalytic domain has been efficiently expressed in the baculovirus/High Five cell system. The catalytic properties of this chimera were practically indistinguishable from those of PDE5, whereas the noncatalytic cGMP binding was similar to that of native purified PDE6alpha'. The inhibitory gamma subunit of PDE6 (Pgamma) enhanced the affinity of cGMP binding at noncatalytic sites of native PDE6alpha' by approximately 6-fold. The polycationic region of Pgamma, Pgamma-24-45, was mainly responsible for this effect, while the inhibitory domain of Pgamma, Pgamma-63-87, was ineffective. On the contrary, Pgamma failed to inhibit catalytic activity of the chimeric PDE6alpha'/PDE5 or to modulate its noncatalytic cGMP binding. Substitutions of Ala residues for the conserved Asn, Asn193 or Asn402, in the two N(K/R)XD-like motifs of the chimeric PDE noncatalytic cGMP-binding sites, each led to a loss of the noncatalytic cGMP binding. Our data suggest that both putative noncatalytic sites of PDE6alpha' are important for binding of cGMP, and that the two binding sites are coupled. Furthermore, mutation Asn402 --> Ala resulted in an approximately 10-fold increase of the Km value for cGMP, indicating that occupation of the noncatalytic cGMP- binding sites of PDE6alpha' may regulate catalytic properties of the enzyme.

A single mutation Asp229 --> Ser confers upon Gs alpha the ability to interact with regulators of G protein signaling.

RGS proteins (regulators of G protein signaling) are GTPase activating proteins (GAPs) for Gi and Gq families of heterotrimeric G proteins but have not been found to interact with Gs alpha. The Gs alpha residue Asp229 has been suggested to be responsible for the inability of RGS proteins to interact with Gs alpha [Natochin, M., and Artemyev, N. O. (1998) J. Biol. Chem. 273, 4300-4303]. To test this hypothesis, we have investigated the possibility of generating an interaction between Gs alpha and RGS proteins by substituting Gs alpha Asp229 with Ser and replacing the potential Gs alpha Asp229 contact residues in RGS16, Glu129 and Asn131, by Ala and Ser, respectively. RGS16 and its mutants failed to interact with Gs alpha. A single mutation of Gs alpha, Asp229Ser, rendered the Gs alpha subunit with the ability to interact with RGS16 and RGS4. Like RGS protein binding to Gi and Gq alpha-subunits, RGS16 preferentially recognized the AlF4--bound conformation of Gs alpha Asp229Ser. In a single-turnover assay, RGS16 maximally stimulated GTPase activity of Gs alpha Asp229Ser by approximately 5-fold with an EC50 value of 7.5 microM. Our findings demonstrate that Asp229 of Gs alpha represents a major barrier for Gs alpha interaction with known RGS proteins.

Identification of effector residues on photoreceptor G protein, transducin.

Transducin is a photoreceptor-specific heterotrimeric GTP-binding protein that plays a key role in the vertebrate visual transduction cascade. Here, using scanning site-directed mutagenesis of the chimeric Galphat/Galphai1 alpha-subunit (Galphat/i), we identified Galphat residues critical for interaction with the effector enzyme, rod cGMP phosphodiesterase (PDE). Our evidence suggests that residue Ile208 in the switch II region directly interacts with the effector in the active GTP-bound conformation of Galphat. Residues Arg201, Arg204, and Trp207 are essential for the conformation-dependent Galphat/effector interaction either via direct contacts with the inhibitory PDE gamma-subunit or by forming an effector-competent conformation through the communication network between switch II and the switch III/alpha3-helix domain of Galphat. Residues His244 and Asn247 in the alpha3 helix of Galphat are responsible for the conformation-independent effector-specific interaction. Insertion of these residues rendered the Galphat/i chimera with the ability to bind PDE gamma-subunit and stimulate PDE activity approaching that of native Galphat. Comparative analysis of the interactions of Galphat/i mutants with PDE and RGS16 revealed two adjacent but distinct interfaces on transducin. This indicates a possibility for a functional trimeric complex, RGS/Galpha/effector, that may play a central role in turn-off mechanisms of G protein signaling systems, particularly in phototransduction.

Mutational analysis of the Asn residue essential for RGS protein binding to G-proteins.

Members of the RGS family serve as GTPase-activating proteins (GAPs) for heterotrimeric G-proteins and negatively regulate signaling via G-protein-coupled receptors. The recently resolved crystal structure of RGS4 bound to Gialpha1 suggests two potential mechanisms for the GAP activity of RGS proteins as follows: stabilization of the Gialpha1 switch regions by RGS4 and the catalytic action of RGS4 residue Asn128. To elucidate a role of the Asn residue for RGS GAP function, we have investigated effects of the synthetic peptide corresponding to the Galpha binding domain of human retinal RGS (hRGSr) containing the key Asn at position 131, and we have carried out mutational analysis of Asn131. Synthetic peptide hRGSr-(123-140) retained its ability to bind the AlF4--complexed transducin alpha-subunit, Gtalpha.AlF4-, but failed to elicit stimulation of Gtalpha GTPase activity. Wild-type hRGSr stimulated Gtalpha GTPase activity by approximately 10-fold with an EC50 value of 100 nM. Mutant hRGSr proteins with substitutions of Asn131 by Ser and Gln had a significantly reduced affinity for Gtalpha but were capable of substantial stimulation of Gtalpha GTPase activity, 80 and 60% of Vmax, respectively. Mutants hRGSr-Leu131, hRGSr-Ala131, and hRGSr-Asp131 were able to accelerate Gtalpha GTPase activity only at very high concentrations (>10 microM) which appears to correlate with a further decrease of their affinity for transducin. Two mutants, hRGSr-His131 and hRGSr-Delta131, had no detectable binding to transducin. Mutational analysis of Asn131 suggests that the stabilization of the G-protein switch regions rather than catalytic action of the Asn residue is a key component for the RGS GAP action.

Substitution of transducin ser202 by asp abolishes G-protein/RGS interaction.

Known RGS proteins stimulate GTPase activity of Gi and Gq family members, but do not interact with Gsalpha and G12alpha. To determine the role of specific Galpha residues for RGS protein recognition, six RGS contact residues of chimeric transducin alpha-subunit (Gtalpha) corresponding to the residues that differ between Gialpha and Gsalpha have been replaced by Gsalpha residues. The ability of human retinal RGS (hRGSr) to bind mutant Gtalpha subunits and accelerate their GTPase activity was investigated. Substitutions Thr178 --> Ser, Ile181 --> Phe, and Lys205 --> Arg of Gtalpha did not alter its interaction with hRGSr. The Lys176 --> Leu mutant had the same affinity for hRGSr as Gtalpha, but the maximal GTPase stimulation by hRGSr was reduced by approximately 2.5-fold. The substitution His209 --> Gln led to a 3-fold decrease in the affinity of hRGSr for the Gtalpha mutant without significantly affecting the maximal GTPase enhancement. The Ser202 --> Asp mutation abolished Gtalpha recognition by hRGSr. A counteracting replacement of Glu129 by Ala in hRGSr did not restore the interaction of hRGSr with the Gtalpha Ser202 --> Asp mutant. Our data suggest that the Ser residue at position 202 of Gtalpha is critical for the specificity of RGS proteins toward Gi and Gq families of G-proteins. Consequently, the corresponding residue, Asp229 of Gsalpha, is likely responsible for the inability of RGS proteins to interact with Gsalpha.

Regulation of transducin GTPase activity by human retinal RGS.

The intrinsic GTPase activity of transducin controls inactivation of the effector enzyme, cGMP phosphodiesterase (PDE), during turnoff of the visual signal. The inhibitory gamma-subunit of PDE (Pgamma), an unidentified membrane factor and a retinal specific member of the RGS family of proteins have been shown to accelerate GTP hydrolysis by transducin. We have expressed a human homologue of murine retinal specific RGS (hRGSr) in Escherichia coli and investigated its role in the regulation of transducin GTPase activity. As other RGS proteins, hRGSr interacted preferentially with a transitional conformation of the transducin alpha-subunit, GtalphaGDPAlF4-, while its binding to GtalphaGTPgammaS or GtalphaGDP was weak. hRGSr and Pgamma did not compete for the interaction with GtalphaGDPAlF4-. Affinity of the Pgamma-GtalphaGDPAlF4- interaction was modestly enhanced by addition of hRGSr, as measured by a fluorescence assay of GtalphaGDPAlF4- binding to Pgamma labeled with 3-(bromoacetyl)-7-diethylaminocoumarin (PgammaBC). Binding of hRGSr to GtalphaGDPAlF4- complexed with PgammaBC resulted in a maximal approximately 40% reduction of BC fluorescence allowing estimation of the hRGSr affinity for GtalphaGDPAlF4- (Kd 35 nM). In a single turnover assay, hRGSr accelerated GTPase activity of transducin reconstituted with the urea-stripped rod outer segment (ROS) membranes by more than 10-fold to a rate of 0.23 s-1. Addition of Pgamma to the reconstituted system reduced the GTPase level accelerated by hRGSr (kcat 0.085 s-1). The GTPase activity of transducin and the PDE inactivation rates in native ROS membranes in the presence of hRGSr were elevated 3-fold or more regardless of the membrane concentrations. In ROS suspensions containing 30 microM rhodopsin these rates exceeded 0.7 s-1. Our data suggest that effects of hRGSr on transducin's GTPase activity are attenuated by Pgamma but independent of a putative membrane GTPase activating protein factor. The rate of transducin GTPase activity in the presence of hRGSr is sufficient to correlate it with in vivo turnoff kinetics of the visual cascade.

Interaction of human retinal RGS with G-protein alpha-subunits.

A novel family of RGS proteins negatively regulates signaling via heterotrimeric G-proteins by accelerating the GTPase activity of G-protein alpha subunits. We have investigated interaction of human retinal RGS protein (hRGSr) with in vitro translated G(alpha) subunits: G(t alpha), G(i alpha1), G(o alpha) and G(s alpha). hRGSr binds well to G(t alpha), G(i alpha1) and G(o alpha) in the presence of AIF4-, but does not interact with G(s alpha). The N- and C-terminally truncated G(alpha) subunits interact with hRGSr similarly to the intact G(alpha) polypeptides. Analysis of interaction between hRGSr and G(o alpha)/G(s alpha) chimeras suggests that a region of G(o alpha), G(o alpha)22-212, contains major structural determinants for binding to RGS proteins.

The gamma subunit of rod cGMP-phosphodiesterase blocks the enzyme catalytic site.

Cyclic GMP phosphodiesterase (PDE) is the effector enzyme in the visual transduction cascade of vertebrate photoreceptor cells. In the dark, the activity of the enzyme catalytic alpha and beta subunits (Palphabeta) is inhibited by two gamma subunits (Pgamma). Previous results have established that approximately 5-7 C-terminal residues of Pgamma comprise the inhibitory domain. To study the interaction between the Pgamma C-terminal region and Palphabeta, the Pgamma mutant (Cys68 --> Ser, and the last 4 C-terminal residues replaced with cysteine, Pgamma-1-83Cys) was labeled with the fluorescent probe 3-(bromoacetyl)-7-diethylaminocoumarin (BC) at the cysteine residue (Pgamma-1-83BC). Pgamma-1-83BC was a more potent inhibitor of PDE activity than the unlabeled mutant, suggesting that the fluorescent probe in part substitutes for the Pgamma C terminus in PDE inhibition. HoloPDE (Palphabetagamma2) had no effect on the Pgamma-1-83BC fluorescence, but the addition of Palphabeta to Pgamma-1-83BC resulted in an approximately 8-fold maximal fluorescence increase. A Kd for the Pgamma-1-83BC-Palphabeta interaction was 4.0 +/- 0.5 nM. Zaprinast, a specific competitive inhibitor of PDE, effectively displaced the Pgamma-1-83BC C terminus from its binding site on Palphabeta (IC50 = 0.9 microM). cGMP and its analogs, 8-Br-cGMP and 2'-butyryl-cGMP, also competed with the Pgamma-1-83BC C terminus for binding to Palphabeta. Our results provide new insight into the mechanism of PDE inhibition by showing that Pgamma blocks the binding of cGMP to the PDE catalytic site.

An interface of interaction between photoreceptor cGMP phosphodiesterase catalytic subunits and inhibitory gamma subunits.

Cyclic guanosine 5'-monophosphate (cGMP) phosphodiesterase (PDE) regulates the level of cGMP on transduction of a visual signal in vertebrate photoreceptor cells. Two identical inhibitory PDE gamma subunits (Pgammas) block catalytic activity of PDE-alpha and -beta subunits (Palphabeta) in the dark. The primary regions of Pgamma involved in the interaction with Palphabeta are a central polycationic region, Pgamma-24-45, and a C-terminal region of Pgamma. Recently, we have shown that the C-terminal region of Pgamma, which is the major Pgamma inhibitory domain, blocks PDE activity by binding to the catalytic site of PDE (Artemyev, N. O., Natochin, M., Busman, M., Schey, K. L., and Hamm, H. E. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 5407-5412). Here, we localize the site on the rod cGMP PDE alpha subunit that binds to the central polycationic domain of Pgamma. This site is located within a region that links a second noncatalytic cGMP binding site with the catalytic domain of PDE. A polypeptide coresponding to this region, Palpha-461-553, expressed as a glutathione S-transferase fusion protein in Escherichia coli and isolated after cleavage of the fusion protein with thrombin, blocks inhibition of PDE activity by Pgamma. In addition, Palpha-461-553 binds to the Pgamma-24-45 region (Kd, 7 microM), as measured by a fluorescent increase in a Pgamma-24-45Cys peptide labeled with 3-(bromoacetyl)-7-diethylaminocoumarin. The Palpha-461-553 region was further characterized by using a set of synthetic peptides. A peptide corresponding to residues 517-541 of Palpha (Palpha-517-541) effectively suppressed inhibition of PDE activity by Pgamma and bound to Pgamma-24-45Cys labeled with 3-(bromoacetyl)-7-diethylaminocoumarin (Kd, 22 microM). Palpha-517-541 also competes with the activated rod G-protein alpha-subunit for binding to Pgamma labeled with lucifer yellow vinyl sulfone. This suggests that light activation of rod PDE by the G-protein transducin involves competition between transducin alpha-guanosine 5'-triphosphate and Palpha-517-541 for binding to the Pgamma-24-45 region. Based on the results, we propose a linear model of interactions between catalytic and inhibitory PDE subunits.

Overexpression, solubilization and purification of rat and human olfactory receptors.

The superfamily of olfactory receptor genes, whose products are thought to be activated by odorant ligands, is critical for odor recognition. Two olfactory receptors, olp4 from rat and OR17-4 from human, were overexpressed in Sf9 insect cells. The presence of the proteins in cell membranes was monitored by immunoblotting with peptide-specific polyclonal antibodies directed against the C-terminal sequences of these receptors and with a mAb against an N-terminal octapeptide epitope tag. A DNA sequence that codes for a His6 tag, which binds tightly to a Ni2+-chelate-affinity column, was incorporated into the N-termini of both genes. The expressed olfactory receptors were found mainly in the cell-membrane fraction. The proteins were difficult to solubilize by many detergents and only lysophosphatidylcholine was found to be both suitable for efficient solubilization of the overexpressed olfactory receptors and compatible with the purification system used. After solubilization, the olfactory receptors were purified to near homogeneity by affinity chromatography on nickel nitrilotriacetic acid resin and by cation-exchange chromatography. Electrophoresis of the purified proteins and visualization with Coomassie Blue staining or by immunoblotting with specific antibodies, revealed bands of 32, 69 and 94 kDa, which were identified as the monomeric, dimeric and trimeric forms of the receptor proteins. The oligomeric forms were resistant to reduction and alkylation, and are therefore thought to be held together by non-covalent hydrophobic interactions that are resistant to SDS. This finding is similar to previous observations for other guanine-nucleotide-binding-regulatory-protein-coupled receptors. Reconstitution in phospholipid vesicles showed that the purified olfactory receptors insert specifically into the lipid bilayer. This provides a means to study functional reconstitution with putative transduction components such as olfactory guanine-nucleotide-binding-regulatory protein.

Mechanism of photoreceptor cGMP phosphodiesterase inhibition by its gamma-subunits.

cGMP phosphodiesterase (PDE) is the key effector enzyme of vertebrate photoreceptor cells that regulates the level of the second messenger, cGMP. PDE consists of catalytic alpha and beta subunits (Palpha and Pbeta) and two inhibitory gamma subunits (Pgamma) that block PDE activity in the dark. The major inhibitory region has been localized to the C terminus of Pgamma. The last C-terminal residues -IleIle form an important hydrophobic domain critical for the inhibition of PDE activity. In this study, mutants of Pgamma were designed for cross-linking experiments to identify regions on Palpha and Pbeta subunits that bind to the Pgamma C terminus. In one of the mutants, the cysteine at position 68 was substituted with serine, and the last four C-terminal residues of Pgamma were replaced with a single cysteine. This mutant, Pgamma83Cys, was labeled with photoprobe 4-(N-maleimido) benzophenone (MBP) at the cysteine residue. The labeled Pgamma83CysMBP mutant was a more potent inhibitor of PDE activity than the unlabeled mutant, indicating that the hydrophobic MBP probe mimics the Pgamma hydrophobic C terminus. A specific, high-yield cross-linking of up to 70% was achieved between the Pgamma83CysMBP and PDE catalytic subunits. Palpha and the N-terminally truncated Pbeta (lacking 147 aa residues) cross-linked to Pgamma83CysMBP with the same efficiency. Using mass spectrometric analysis of tryptic fragments from the cross-linked PDE, we identified the site of cross-linking to aa residues 751-763 of Palpha. The corresponding region of Pbeta, Pbeta-749-761, also may bind to the Pgamma C terminus. Our data suggest that Pgamma blocks PDE activity through the binding to the catalytic site of PDE, near the NKXD motif, a consensus sequence for interaction with the guanine ring of cGMP.

Olfactory receptor proteins. Expression, characterization and partial purification.

A rat olfactory epithelium cDNA library was screened for olfactory receptor clones. One of the positively hybridizing cDNA clones was sequenced and found to encode a new member of the olfactory receptor superfamily. This cDNA, termed olp4, was used as a model of olfactory receptor for expression, both in vitro and in vivo. Expression of olp4, as well as of another previously cloned olfactory receptor (F5), was monitored by immunoprecipitation was a monoclonal antibody directed against a Flag peptide epitope tag, inserted at the N-terminus of the open reading frame, and a specific polyclonal antibody against a C-terminal peptide of olp4. Translation in vitro, followed by immunoprecipitation, showed a major olp4-specific band of 27-29 kDa. The olp4 and F5 polypeptides were found to be inserted into microsomal membranes as expected for integral membrane proteins. Expression in vivo of Flag-olp4 in Sf9 insect cells, using the baculovirus expression system, showed a specific polypeptide of the same size as the in vitro species, with an additional band of 34 kDa, which is most likely a glycosylated form. Fluorescence cytometry and immunohistochemical assays demonstrated the localization of the Flag-olp4 product on the cell surface of the infected host Sf9 cells, with the N-terminus and C-terminus in the proper orientation. Affinity chromatography was used for the partial purification of the olp4 polypeptide from infected Sf9 cells. The identification and purification of this expressed olfactory receptor polypeptide could open the way for further characterization and functional studies of the olfactory receptor superfamily members.

Olfactory receptors: transduction, diversity, human psychophysics and genome analysis.

The emerging understanding of the molecular basis of olfactory mechanisms allows one to answer some long-standing questions regarding the complex recognition machinery involved. The ability of the olfactory system to detect chemicals at sub-nanomolar concentrations is explained by a plethora of amplification devices, including the coupling of receptors to second messenger generation through GTP-binding proteins. Specificity and selectivity may be understood in terms of a diverse repertoire of olfactory receptors of the seven-transmembrane-domain receptor superfamily, which are probably disposed on olfactory sensory neurons according to a clonal exclusion rule. Signal termination may be related to sets of biotransformation enzymes that process odorant molecules, as well as to receptor desensitization. Many of the underlying molecular components show specific expression in olfactory epithelium, with a well-orchestrated developmental sequence of emergence, possibly related to sensory neuronal function and connectivity requirements. A general model for molecular recognition in biological receptor repertoires allows a prediction of the number of olfactory receptors necessary to achieve efficient detection and sheds light on the analogy between the immune and olfactory systems. The molecular cloning and mapping of a human genomic olfactory receptor cluster on chromosome 17 provides insight into olfactory receptor diversity, polymorphism and evolution. Combined with future genotype-phenotype correlation, with particular reference to specific anosmia, as well as with computer-based molecular modelling, these studies may provide insight into the odorant specificity of olfactory receptors.