Control of conformational equilibria in the human B2 bradykinin receptor. Modeling of nonpeptidic ligand action and comparison to the rhodopsin structure.

A prototypic study of the molecular mechanisms of activation or inactivation of peptide hormone G protein-coupled receptors was carried out on the human B2 bradykinin receptor. A detailed pharmacological analysis of receptor mutants possessing either increased constitutive activity or impaired activation or ligand recognition allowed us to propose key residues participating in intramolecular interaction networks stabilizing receptor inactive or active conformations: Asn(113) and Tyr(115) (TM III), Trp(256) and Phe(259) (TM VI), Tyr(295) (TM VII) which are homologous of the rhodopsin residues Gly(120), Glu(122), Trp(265), Tyr(268), and Lys(296), respectively. An essential experimental finding was the spatial proximity between Asn(113), which is the cornerstone of inactive conformations, and Trp(256) which plays a subtle role in controlling the balance between active and inactive conformations. Molecular modeling and mutagenesis data showed that Trp(256) and Tyr(295) constitute, together with Gln(288), receptor contact points with original nonpeptidic ligands. It provided an explanation for the ligand inverse agonist behavior on the WT receptor, with underlying restricted motions of TMs III, VI, and VII, and its agonist behavior on the Ala(113) and Phe(256) constitutively activated mutants. These data on the B2 receptor emphasize that conformational equilibria are controlled in a coordinated fashion by key residues which are located at strategic positions for several G protein-coupled receptors. They are discussed in comparison with the recently determined rhodopsin crystallographic structure.

Specific nonpeptide photoprobes as tools for the structural study of the angiotensin II AT(1) receptor.

The aim of this work was to obtain photoactivatable nonpeptide antagonists of the angiotensin II AT(1) receptor. Based on structure-function relationships, two chemical structures as well as appropriate synthetic schemes were chosen as a frame for the design of radiolabeled azido probes. The feasibility of the strategy was first assessed by the synthesis of two tritiated ligands 21 and 22 possessing a high affinity for the AT(1) receptor and a low nonspecific binding to membrane or cell preparations. We then prepared two unlabeled azido derivatives 7 and 14 which retained a fairly high affinity for the AT(1) receptor. The latter compound proved to be suitable for receptor irreversible labeling and was prepared in its tritiated form 28. This tritiated azido nonpeptide probe displayed a K(d) value of 11.8 nM and a low nonspecific binding. It was suitable for specific and efficient covalent labeling of the recombinant AT(1A) receptor stably expressed in CHO cells. The electrophoretic pattern of the specifically labeled entity was strictly identical to that of purified receptor photolabeled with a biotinylated peptidic photoactivatable probe. This new tool should be useful for the mapping of the nonpeptide receptor binding site. These potential applications are discussed in light of the current knowledge of molecular mechanisms of G-protein coupled receptor activation and inactivation.

N-glycosylation requirements for the AT1a angiotensin II receptor delivery to the plasma membrane.

The purpose of this work was to investigate the role of N-glycosylation in the expression and pharmacological properties of the the rat AT1a angiotensin II (AII) receptor. Glycosylation-site suppression was carried out by site-directed mutagenesis (Asn-->Gln) of Asn176 and Asn188 (located on the second extracellular loop) and by the removal of Asn4 at the N-terminal end combined with the replacement of the first four amino acids by a 10 amino acid peptide epitope (c-Myc). We generated seven possible N-glycosylation-site-defective mutants, all tagged at their C-terminal ends with the c-Myc epitope. This double-tagging strategy, associated with photoaffinity labelling, allowed evaluation of the molecular masses and immunocytochemical cellular localization of the various receptors transiently expressed in COS-7 cells. We showed that: (i) each of the three N-glycosylation sites are utilized in COS-7 cells; (ii) the mutant with three defective N-glycosylation sites was not (or was very inefficiently) expressed at the plasma membrane and accumulated inside the cell at the perinuclear zone; (iii) the preservation of two sites allowed normal receptor delivery to the plasma membrane, the presence of only Asn176 ensuring a behaviour similar to that of the wild-type receptor; and (iv) all expressed receptors displayed unchanged pharmacological properties (Kd for 125I-sarcosine1-AII; sarcosine1-AII-induced inositol phosphate production). These results demonstrate that N-glycosylation is required for the AT1 receptor expression. They are discussed in the light of current knowledge of membrane-protein maturation and future prospects of receptor overexpression for structural studies.

Constitutive activation of the human bradykinin B2 receptor induced by mutations in transmembrane helices III and VI.

We report that mutation of specific residues in the human B2 bradykinin (BK) receptor induces its marked constitutive activation, evaluated through inositol phosphate production in COS-7 cells expressing the wild-type or mutant receptors. We provide evidence for a strikingly high constitutive activation of the B2 receptor induced by alanine substitution of the Asn113 residue, located in the third transmembrane domain. These results are reminiscent of our previous finding that mutation of the homologous Asn111 residue induces constitutive activation of the AT1 angiotensin II receptor. BK overstimulation of the constitutively activated mutant N113A receptor was also observed. Phe replacement of the Trp256 residue, fairly conserved in transmembrane domain VI of G protein-coupled receptors, also induced a less prominent but significant constitutive activation. Interestingly, the peptidic HOE 140 compound and an original nonpeptidic compound LF 16 0335, which both behaved as inverse agonists of the wild-type receptor expressed in COS-7 cells, became potent and efficient agonists of the two constitutively activated mutant N113A and W256F receptors. These parallel changes observed for two chemically unrelated series can serve as a basis for future studies of structure-function relationships and modeling of activation processes, based on a detailed analysis of the network of helix-helix interactions, which stabilize the inactive receptor conformation and undergo rearrangements on transition to activated states.

Mutation of Asn111 in the third transmembrane domain of the AT1A angiotensin II receptor induces its constitutive activation.

A preliminary model of the rat AT1A angiotensin II (AII) receptor (Joseph, M. P., Maigret, B., Bonnafous J.-C., Marie, J., and Scheraga, H. A. (1995) J. Protein Chem. 14, 381-398) has predicted an interaction between Asn111 located in transmembrane domain (TM) III and Tyr292 (TM VII) in the nonactivated receptor; a disruption of this interaction upon AII activation would allow Tyr292 to interact with the conserved Asp74 (TM II). The previous verification that Tyr292 is essential for receptor coupling to phospholipase C (Marie, J., Maigret, B., Joseph, M. P., Larguier, R., Nouet, S., Lombard, C., and Bonnafous, J.-C. (1994) J. Biol. Chem. 269, 20815-20818) prompted us to check the possible alterations in receptor properties upon Asn111 --> Ala mutation. The mutated receptor (N111A) displayed: (i) strong constitutive activity, with amplification of the maximal phospholipase C response to AII; (ii) agonist behavior of the AT2-specific ligand CGP 42112A, [Sar1, Ile8]AII, and [Sar1,Ala8]AII, antagonists of the wild-type receptor; (iii) inverse agonism behavior of the non-peptide ligands DuP 753, LF 7-0156, and LF 8-0129. The results are discussed in the light of the allosteric ternary complex models and other described examples of constitutive activation of G protein-coupled receptors.

Amino acids of the third transmembrane domain of the AT1A angiotensin II receptor are involved in the differential recognition of peptide and nonpeptide ligands.

The differential role of amino acids of the third transmembrane domain on peptide and nonpeptide recognition by the AT1 angiotensin II receptor has been evidenced. The mutation of Ser105 into alanine completely abolished peptide agonist and antagonist binding, while the binding of nonpeptide ligands, including the original radioligands [3H] LF 7-0156 and [3H] LF 8-0129, was more moderately affected. Reverse pharmacological changes, i.e., unchanged affinities for peptide agonists or antagonists and drastically reduced affinities for nonpeptide antagonists, were observed upon alanine replacement of Asn111. These results confirm that the binding sites for peptide and nonpeptide molecules are not totally overlapping and delineate new amino acids as candidates for the selective receptor interaction with the two categories of ligands. Their integration in topographical studies is discussed.

Properties of [3H]LF 7-0156, a new nonpeptide antagonist radioligand for the type 1 angiotensin II receptor.

LF 7-0156 (2-[[[2-butyl-1-[(4-carboxyphenyl)methyl]-1H-imidazol- 5-yl]methyl]amino]benzoic acid) is a nonpeptide angiotensin II receptor antagonist selective for the type 1 angiotensin receptor. In rabbit aortic rings, LF 7-0156 competitively antagonized angiotensin II-induced contractile responses, with a pA2 value of 8.44. The synthesis of the radiolabeled compound [3H]LF 7-0156 has allowed direct binding studies with several membrane or cell preparations. Consistent with competition experiments, the binding of [3H]LF 7-0156 to purified rat liver membranes was characterized by a Kd value of 12.6 nM and very low pseudospecific or nonspecific binding; this latter characteristic confers to this compound an advantage over the structurally different compound [3H]DuP 753, which is the only commercially available nonpeptide radioligand. [3H]LF 7-0156 also bound to the type 1A angiotensin receptor expressed in Chinese hamster ovary cells, with high affinity (Kd = 3.5 nM) and a total absence of nonspecific binding. Functional antagonism in this cell system was assessed by the ability of LF 7-0156 to reverse angiotensin II-induced inositol phosphate production. These properties make [3H]LF 7-0156 an interesting pharmacological tool and should allow future evaluation of recognition of the nonpeptide ligand by mutated receptors expressed in Chinese hamster ovary cells; it will facilitate the analysis of possible differences in receptor amino acids involved in the binding of peptide and nonpeptide ligands, as well as the extent of spatial overlap between several nonpeptide antagonists displaying different structural properties.

Tyr292 in the seventh transmembrane domain of the AT1A angiotensin II receptor is essential for its coupling to phospholipase C.

An essential role of the conserved Asp74 in the coupling of the type 1 angiotensin II (AII) receptor (AT1) to phospholipase C has already been reported (Bihoreau, C., Monnot, C., Davies, E., Teutsch, B., Bernstein, K. B., Corvol, P., and Clauser, E. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 5133-5137). Moreover, preliminary modeling studies have shown that a spatial proximity exists between Asp74, located in transmembrane domain II, and Tyr292, located in transmembrane domain VII and conserved in many, but not all, G protein-coupled receptors. We mutated Tyr292 into Phe and evaluated the pharmacological and activation characteristics of the mutated receptor (Y292F) stably expressed in Chinese hamster ovary cells. This receptor possessed unchanged binding properties for agonist or antagonist peptide ligands compared to the wild-type receptor, while its coupling to phospholipase C was severely impaired. Interestingly, competition binding experiments, using 125I-[Sar1]AII as a tracer ligand, showed that the Y292F receptor displayed an increased Ki value for DuP 753, an AT1-specific nonpeptide antagonist and a greatly decreased Ki value for the AT2-specific ligand CGP 42112A. These pharmacological changes are similar to those observed for the previously reported mutation of Asp74 into Asn. This apparently symmetrical role of Asp74 and Tyr292 is consistent with the hypothesis that an interaction between these two amino acids could be a key event in the molecular processes linking AII recognition and AT1 receptor activation.

Deglycosylation and fragmentation of purified rat liver angiotensin II receptor: application to the mapping of hormone-binding domains.

We report new structural data about the rat liver angiotensin II receptor, which belongs to the AT1 subclass. This receptor has been purified at analytical or semi-preparative levels by a previously described strategy involving its photolabelling with a biotinylated azido probe and selective adsorption of the covalent probe-receptor complexes to immobilized streptavidin [Marie, Seyer, Lombard, Desarnaud, Aumelas, Jard and Bonnafous (1990) Biochemistry 29, 8943-8950]. Chemical or enzymic deglycosylation of the purified receptor has shown a shift in its molecular mass from 65 kDa to 40 kDa. Fragmentation of the purified receptor was carried out with V8 protease from Staphylococcus aureus, CNBr and trypsin. It was possible to find trypsin-treatment conditions which allowed production of a 6 kDa probe-fragment complex with a satisfactory yield. Attempts to localize this small fragment (5 kDa after subtraction of the probe contribution) in the recently published rat AT1 receptor sequence are reported. As expected, this fragment is not glycosylated; moreover, its further fragmentation by CNBr induces a very slight decrease in its size. These data support the hypothesis that a receptor sequence comprising the third transmembrane domain and adjacent portions of extra- and intracellular loops is involved in photolabelling by the C-terminal azidophenylalanine of the angiotensin-derived probe. These preliminary results are discussed in terms of future prospects for the characterization of hormone-binding domains of angiotensin II receptors.

Protein purification using combined streptavidin (or avidin)-Sepharose and thiopropyl-Sepharose affinity chromatography.

The major problem usually encountered in the application of the (strept)avidin-biotin system to the purification of proteins (or other biological molecules) lies in the difficult reversion of the interaction between immobilized (strept)avidin and the adsorbed biotinylated protein. Among the proposed solutions is the selective biotinylation of the entity to be purified by a disulphide-containing biotinylated reagent which allows its recovery from (strept)avidin gels by dithiothreitol (DTT) treatment. As emphasized by the example of angiotensin II receptor purification, achieved using this strategy, optimum reduction of this disulphide bridge may require improvement of its accessibility using denaturating agents such as sodium dodecyl sulphate or urea. However, these agents release important amounts of (strept)avidin. Two general ways of solving this problem are proposed. One solution takes advantage of the absence of cysteine in the streptavidin sequence: the protein to be purified is selectively readsorbed to thiopropyl-Sepharose through the thiol function generated on DTT cleavage of the biotinylated reagent. The other solution is an empirical approach to make possible the use of avidin, which possesses cysteine residues: combined avidin-Sepharose and thiopropyl-Sepharose chromatography proved efficient when carried out in the presence of urea as denaturing agent.

Lymphocyte mitogenesis and CD4 modulation induced by different phorbol esters: comparative studies.

Phorbol 12-myristate 13-acetate (PMA) can stimulate T-cells via its binding to protein kinase C (PKC). Such a phenomenon occurs when a threshold of concentration as low as 1 nM of PMA is reached. Other phorbol esters possess the ability to stimulate lymphocytes but at higher thresholds of concentration. We show here that the different phorbol ester concentrations needed to induce stimulation and proliferation, estimated by both interleukin-2 receptor (IL-2R) expression and DNA synthesis, correspond very closely to those inducing the modulation of CD4 antigen, confirming a direct relationship between CD4 down-regulation and cellular activation. We estimated the structural features of these different phorbol derivatives in relation to lymphocyte activation and CD4 modulation, and confirm that the ester side chains which give to the phorbol ester derivatives their lipophilic character, discriminate, according to their length, the ability of the different compounds to reach their receptor inside the cell membrane; we also brought some evidence that the polar phorbol nucleus of these compounds is probably responsible for their interaction with the membrane receptor mainly through the hydroxyl group in the C4 position.