Identification of two serine residues involved in agonist activation of the beta-adrenergic receptor

Pharmacophore mapping of the ligand binding domain of the beta-adrenergic receptor has revealed specific molecular interactions which are important for agonist and antagonist binding to the receptor. Previous site-directed mutagenesis experiments have demonstrated that the binding of amine agonists and antagonists to the receptor involves an interaction between the amine group of the ligand and the carboxylate side chain of Asp113 in the third hydrophobic domain of the receptor (Strader, C. D., Sigal, I. S., Candelore, M. R., Rands, E., Hill, W. S., and Dixon, R. A. F. (1988) J. Biol. Chem. 263, 10267-10271). We have now identified 2 serine residues, at positions 204 and 207 in the fifth hydrophobic domain of the beta-adrenergic receptor, which are critical for agonist binding and activation of the receptor. These serine residues are conserved with G-protein-coupled receptors which bind catecholamine agonists, but not with receptors whose endogenous ligands do not have the catechol moiety. Removal of the hydroxyl side chain from either Ser204 or Ser207 by substitution of the serine residue with an alanine attenuates the activity of catecholamine agonists at the receptor. The effects of these mutations on agonist activity are mimicked selectively by the removal of the catechol hydroxyl moieties from the aromatic ring of the agonist. The data suggest that the interaction of catecholamine agonists with the beta-adrenergic receptor involves two hydrogen bonds, one between the hydroxyl side chain of Ser204 and the meta-hydroxyl group of the ligand and a second between the hydroxyl side chain of Ser207 and the para-hydroxyl group of the ligand.     

Mechanisms of ligand binding and efficacy at the human D2(short) dopamine receptor

Mechanisms of ligand binding and receptor activation for the human D2(short) dopamine receptor have been probed using two homologous series of monohydroxylated and dihydroxylated agonists (phenylethylamines and 2-dipropylaminotetralins). In ligand binding studies, the majority of compounds exhibited competition curves versus [3H]spiperone that were best fitted using a two site binding model. The compounds had different abilities (potencies and maximal effects) to stimulate [35S]GTPgammaS binding and to inhibit forskolin-stimulated cAMP accumulation. From the data it can be concluded that: (i) the ability of an agonist to stabilize receptor/G protein coupling can be used to predict agonist efficacy for some groups of compounds (2-dipropylaminotetralins) but not for others (phenylethylamines); (ii) the receptor may be activated by unhydroxylated compounds; (iii) single hydroxyl groups or pairs of hydroxyl groups on the agonist may contribute to binding affinity, potency and efficacy; and (iv) for the 2-dipropylaminotetralin series two modes of agonist/receptor interaction have been identified associated with different relative efficacy.     

Intestinal 1,25-dihydroxyvitamin D3 binding protein: Specificity of binding

The binding of metabolites of vitamin D and their analogs to the 3.7S chick intestinal cytosol receptor protein has been specifically studied by competitive binding techniques and polyethylene glycol precipitation of the complex. The structural requirements for the interaction between the vitamin D molecule and the receptor could be assessed without the nuclear chromatin binding step. These measurements have shown that 1,25-dihydroxyvitamin D₃ and 1,25-dihydroxyvitamin D₂ are equally competitive and are the most active. Of the structural features of the compounds, the 1α-hydroxyl is most important followed by the 25-hydroxyl and the 3β-hydroxyl. The addition of a second hydroxyl near carbon 25 markedly reduces binding whether on the 26 carbon or the 24 carbon. A hydroxyl on C-24 could substitute to some degree for the 25-hydroxyl inasmuch as 24-hydroxyvitamin D₃ was much more effective than vitamin D₃ but less effective than 25-hydroxyvitamin D₃. In general the patterns of binding affinities correlated well with the biological activity of the various analogs strongly supporting a physiological role for the 1,25-dihydroxyvitamin D₃ binding protein. It also suggests that of the two-step receptor mechanism, the structural specificity is located in the initial interaction of the 1,25-dihydroxyvitamin D₃ and the cytosol receptor.     

Study of the specificity of the estradiol-binding system in the uteri of guinea pigs]

The authors analyzed the affinity of the steroids belonging to the estran series to the estradiol-binding system of the guinea pig uteri. The presence of free hydroxyl groups in positions 3 (phenol) and 17beta and their interorientation proved to determine the interaction with the recptor system of the guinea pig uterus. The data obtained indicated that the biological activity of the steroids was determined by the peculiarities of their structural interaction with the receptor systems of the uteri.     

Characterization of an interaction between insulin receptor substrate 1 and the insulin receptor by using the two-hybrid system.

Insulin receptor substrate 1 (IRS-1) is a major substrate of the insulin receptor and has been implicated in insulin signaling. Although IRS-1 is thought to interact with the insulin receptor, the nature of the interaction has not been defined. In this study, we used the two-hybrid assay of protein-protein interaction in the yeast Saccharomyces cerevisiae to study the interaction between human IRS-1 and the insulin receptor. We demonstrate that IRS-1 forms a specific complex with the cytoplasmic domain of the insulin receptor when both are expressed as hybrid proteins in yeast cells. We show that the interaction is strictly dependent upon receptor tyrosine kinase activity, since IRS-1 shows no interaction with a kinase-inactive receptor hybrid containing a mutated ATP-binding site. Furthermore, mutation of receptor tyrosine 960 to phenylalanine eliminates IRS-1 interaction in the two-hybrid assay. These data suggest that the interaction between IRS-1 and the receptor is direct and provide evidence that the juxtamembrane domain of the receptor is involved. Furthermore, we show that a 356-amino-acid region encompassed by amino acids 160 through 516 of IRS-1 is sufficient for interaction with the receptor in the two-hybrid assay. Lastly, in agreement with our findings for yeast cells, we show that the insulin receptor is unable to phosphorylate an IRS-1 protein containing a deletion of amino acids 45 to 516 when expressed in COS cells. The two-hybrid assay should provide a facile means by which to pursue a detailed understanding of this interaction.     

Effects of replacement of the hydroxyl group of cholesterol and tocopherol on the thermotropic behavior of phospholipid membranes

The role of the hydroxyl groups of cholesterol and tocopherol in mediating their interaction with phospholipid bilayers has been a subject of considerable interest. We have examined this question by using derivatives of cholesterol and tocopherol in which the hydroxyl group is esterified to succinate. The hemisuccinate esters of cholesterol and alpha-tocopherol can be readily incorporated into phospholipid membranes and in fact can by themselves form closed membrane vesicles as demonstrated by the encapsulation of [3H]sucrose. The thermotropic behavior of mixtures containing each succinate ester and phospholipid was studied by differential scanning calorimetry. The effect of cholesteryl hemisuccinate on the thermotropic properties of dipalmitoylphosphatidylcholine and dimyristoylphosphatidylethanolamine is very similar to that of cholesterol. This indicates that the 3 beta-OH is not required for the formation of a cholesterol-phospholipid complex. In mixtures of tocopherol acid succinate and phospholipids the peak transition temperature is progressively shifted to lower temperatures as the mole fraction of alpha-tocopherol succinate is increased, while the enthalpy of the transition is only slightly affected. At a tocopherol succinate/phospholipid molar ratio of 9/1 a phase transition is still detectable. A comparison between tocopherol succinate and tocopherol indicates that the substitution of the hydroxyl group reduces the interaction of tocopherol with phospholipids to a small but measurable extent. Thus, the hydroxyl group of tocopherol is more important than the hydroxyl group of cholesterol in influencing their interactions with phospholipids.     

Molecular mechanism underlying inverse agonist of angiotensin II type 1 receptor

To delineate the molecular mechanism underlying the inverse agonist activity of olmesartan, a potent angiotensin II type 1 (AT1) receptor antagonist, we performed binding affinity studies and an inositol phosphate production assay. Binding affinity of olmesartan and its related compounds to wild-type and mutant AT1 receptors demonstrated that interactions between olmesartan and Tyr113, Lys199, His256, and Gln257 in the AT1 receptor were important. The inositol phosphate production assay of olmesartan and related compounds using mutant receptors indicated that the inverse agonist activity required two interactions, that between the hydroxyl group of olmesartan and Tyr113 in the receptor and that between the carboxyl group of olmesartan and Lys199 and His256 in the receptor. Gln257 was found to be important for the interaction with olmesartan but not for the inverse agonist activity. Based on these results, we constructed a model for the interaction between olmesartan and the AT1 receptor. Although the activation of G protein-coupled receptors is initiated by anti-clockwise rotation of transmembrane (TM) III and TM VI followed by changes in the conformation of the receptor, in this model, cooperative interactions between the hydroxyl group and Tyr113 in TM III and between the carboxyl group and His256 in TM VI were essential for the potent inverse agonist activity of olmesartan. We speculate that the specific interaction of olmesartan with these two TMs is essential for stabilizing the AT1 receptor in an inactive conformation. A better understanding of the molecular mechanisms of the inverse agonism could be useful for the development of new G protein-coupled receptor antagonists with inverse agonist activity.     

Hydroxylated triphenylacrylonitriles adopt a unique orientation within the binding site of the estrogen receptor

The relative binding affinities of a series of twelve para-hydroxylated triphenylethylenes (TPEs) for the estradiol receptor (ER) of calf uterus cytosol were measured by a competition method. The results obtained under equilibrium conditions support the hypothesis of the additivity of the energies corresponding to each of the hydrogen-bond type interactions of di- or tri-hydroxylated TPEs with the estradiol binding site of ER and strongly suggest that, whichever ring is hydroxylated, the orientation of the TPE in the steroid binding site is always the same. A hydroxyl group in a given position always interacts with the same location within the site. Mono-hydroxylation of the highly hydrophobic non-substituted TPE skeleton led to a large increase in relative binding affinity for ER which could be explained by a dual mechanism whereby the interaction specific to the hydroxyl is accompanied by a temperature- or time-dependent binding process that is not related to the hydroxylation position.     

Evidence for a direct manganese-oxygen ligand in water binding to the S2 state of the photosynthetic water oxidation complex

The interaction of water with the water oxidizing Mn complex of photosystem II has been investigated using electron spin-echo envelope modulation spectroscopy in the presence of H(2)(17)O. The spectra show interaction of the (17)O with the preparation in the S(2) state induced by 200 K illumination. The modulation is observed only in the center of the multiline spectrum. The inferred hyperfine coupling terms are compatible with water (not hydroxyl) oxygen bound to a particular quasi-axial Mn(III) center in a coupled Mn cluster.     

In vitro interaction of estradiol receptor with Ca2+-calmodulin

Estradiol receptor (ER) activity requires interaction with hormone and specific DNA sequence. We now report that this receptor also interacts with calmodulin (CaM), the major intracellular mediator of Ca2+ action in eucaryotic cells. This interaction has been observed using both CaM-Sepharose and [125I]CaM. Crude and purified [3H]ER complex show high affinity interaction with CaM-Sepharose [dissociation constant (Kd) 0.12 and 0.16 nM, respectively]. Unoccupied receptor shows a similar high affinity interaction. Tamoxifen-ER complex also binds to CaM-Sepharose. Several findings show that this CaM-ER interaction is very specific: lack of this interaction has been observed in the presence of trifluoperazine, an inhibitor of protein binding to CaM; the receptor binds neither Sepharose, nor parvalbumin-Sepharose; competition of interaction of [3H]ER complex with CaM-Sepharose is observed by cold ER complex; rat liver glucocorticoid receptor does not bind to CaM-Sepharose. The interaction of purified receptor with 125I-labeled CaM has been detected by various techniques: centrifugation through sucrose gradient of CaM incubated with receptor shows that CaM binds to a protein forming a complex sedimenting at 5 S. This complex is shifted to the 7.5 S region by a monoclonal antireceptor antibody. Incubation of CaM with receptor followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis fluorography of the immunoprecipitated receptor shows that [125I]CaM coprecipitates with the receptor. Competition of this interaction by an excess of cold CaM is observed. Interaction of the receptor with CaM is also observed by the overlay technique.(ABSTRACT TRUNCATED AT 250 WORDS)     

Formation of alpha-tocopherol complexes with fatty acids. Nature of complexes

Using ultraviolet spectrophotometry and 1H-NMR high-resolution spectroscopy, it has been demonstrated that the formation of alpha-tocopherol complexes with free fatty acids occurs via two types of interaction, namely formation of a hydrogen bond between the alpha-tocopherol chromanol nucleus hydroxyl and the carboxyl group of a fatty acid, and interaction of the fatty acid acyl chains with the chromanol nucleus methyl groups. The second interaction is significantly enhanced by an increase in the number of double bonds in the fatty acid molecule, which results in restriction of the molecular mobility of alpha-tocopherol. The proposed structural model of alpha-tocopherol-fatty acid complexes has been confirmed by the use of molecular models. It has been assumed that the efficiency of complex formation of natural tocopherols with fatty acids is correlated with their biological activity.     

Ab initio calculations on hidden modulators of theta class glutathione transferase activity

The glutathione transferases decrease the pKa of glutathione, allowing its deprotonation and the formation of the more reactive thiolate anion. The thiolate is maintained in the active site through a weak conventional hydrogen bond first sphere interaction donated by a Tyr hydroxyl in the Alpha, Mu, Pi, and Sigma glutathione transferase classes that can be modified by other second sphere or indirect thiolate contacts. However, the Theta and Delta class isoforms use a Ser hydroxyl for stabilizing the GSH thiolate, and as such, have a different chemical system compared with that of the Tyr possessed by other classes. We have used high level ab initio methods to investigate this interaction by using a simple methanol methanethiol system as a model. The hydrogen bond strength of this initial first sphere interaction was calculated to be less than that of the Tyr interaction. A putative second sphere interaction exists in the Theta and Delta class structures between Cys or Ser-14 and Ser-11 in the mammalian Theta subclass 1 and 2, respectively. The effect of this interaction on the first sphere interaction has also been investigated and found to significantly increase the energy of the bond.     

pKa and volume of residue one influence delta/mu opioid binding: QSAR analysis of tyrosine replacement in a nonselective deltorphin analogue

[Gly(4)]deltorphin (Tyr-D-Ala-Phe-Gly-Val-Val-Gly-NH(2)) is a nonselective analogue of the opioid heptapeptides isolated from Phyllomedusa amphibian skin. Its nonselective nature allows for simultaneous characterization of the effects of sequence modification on both delta (delta) and mu (mu) receptor binding. The N-terminal regions of opioid peptides are considered to be responsible for receptor recognition, and the tyrosine at position one is relatively intolerant to alteration. In order to further investigate the role of the phenolic hydroxyl group in receptor interaction, a series of peptides was synthesized in which the position-one tyrosine residue was replaced with analogues of varying electronic, steric, and acid/base character, including ring-substituted tyrosines, para-substituted phenylalanines, and other nonaromatic and heterocyclic amino acids. The effects of these replacements on delta and mu receptor affinities were measured and then analyzed through quantitative structure-activity relationship (QSAR) calculations. Results support a dual hydrogen bond donor/acceptor role for the Tyr(1) hydroxyl moiety, with less acidic hydroxyl groups exhibiting stronger binding to opioid receptors. In addition, steric bulk in the Tyr(1) position independently strengthens mu and possibly delta binding, presumably by either a ligand conformational effect or enhanced van der Waals interactions with a 'loose' receptor site. The pK(a) effect is stronger on delta than on mu binding, generating an increase in delta selectivity with increasing residue-one pK(a).     

Structure and activity of membrane receptors: Modeling and computational simulation of ligand recognition in a three-dimensional model of the 5-hydroxytryptamine1A receptor

A three-dimensional molecular model of the transmembrane domain of the 5-HT_1A receptor (5-HT_1AR) is presented in the context of a general strategy for modeling the macromolecular structure of a guanine nucleotide binding, regulatory protein coupled receptor (GPCR). The model of the 5-HT_1AR rests on the definition of the putative residues of the ligand-binding site guided by criteria based on specific models proposed from structure-activity studies and on published results of modifications of GPCRs using methods of molecular biology. The resulting requirements for matching recognition sites in the agonist-binding pocket define the molecular details of the interaction between the agonist 5-HT and the human 5-HT_1AR that includes: (1) the interaction between the protonated amine moiety and the conserved negative Asp-116, located in TMH 3; (2) the hydrogen bond between the hydroxyl group and Thr-199, located in TMH 5; and (3) the interaction complex between the aromatic ring portion of the ligand and the neutral form of His-192, located in TMH 5. Results from quantum mechanical calculations of the interaction between an agonist and the proposed recognition pocket of the 5-HT_1AR model suggest a trigger of the receptor activation mechanism resulting from ligand binding. The antagonist-binding pocket of the human 5-HT_1AR is inferred from the interaction sites of pindolol with the receptor model: (1) the ionic interaction between the protonated amine of the ligand and the side chain of the conserved Asp-116, located in TMH 3; and (2) the hydrogen bonds between the ether oxygen and the hydroxyl group of the ligand and Asn-385, located in TMH 7. Use of the model is proposed to facilitate the identification of the structural elements of agonists and antagonists that are key for their specific functions, in order to achieve the design of new compounds with predetermined pharmacological properties.     

Binding, X-ray and NMR studies of the three A-ring isomers of natural estradiol

The effect of the position of the phenolic hydroxyl on the conformations of the three A-ring isomers of estradiol, namely, estra-1,3,5(10)-trien-1,17 beta-diol (10), estra-1,3,5(10)-trien-2,17 beta-diol (3), and estra-1,3,5(10)-trien-4,17 beta-diol (6), has been analyzed by X-ray crystallography. The results of these analyses were correlated with the absorptions of the angular methyl groups in the [1H]NMR spectra of these isomers and natural estradiol (E2). It was observed that the changes in chemical shift of protons at C18 corresponded to skeletal modifications in the steroid structure which changed the anisotropic effect of the hydroxyl group at C17. Examination of the affinity of these A-ring isomers of E2 for the estrogen receptor has shown the 2-hydroxylated isomer 3 to retain 1/5th the affinity of E2 for its binding protein. The 1- and 4-hydroxylated derivatives (10 and 6, respectively) bound to a much lesser extent. The receptor affinities of these estrogen analogues may be related to the angle between the 18-methyl and the 17 beta-hydroxyl groups (or the dihedral angle between the planar A-ring and the angular C18 methyl) as well as the position of the A-ring hydroxyl group.     

The nature of heme—aniline interactions during hemin-mediated oxygen activation and insertion reactions

The interaction of aniline with hemin during oxygen activation and insertion mediated by the metalloporphyrin has been studied by a combined theoretical, semiempirical, and experimental approach. Results indicate that association is via a planar π bonding interaction between the aromatic π electrons of the amine and tetrapyrrole ring system. The effect of very high concentrations of hydroxyl radical scavengers on the system is discussed.     

X-ray crystal structure of the liver X receptor beta ligand binding domain: regulation by a histidine-tryptophan switch

The x-ray crystal structures of the human liver X receptor beta ligand binding domain complexed to sterol and nonsterol agonists revealed a perpendicular histidinetryptophan switch that holds the receptor in its active conformation. Hydrogen bonding interactions with the ligand act to position the His-435 imidazole ring against the Trp-457 indole ring, allowing an electrostatic interaction that holds the AF2 helix in the active position. The neutral oxysterol 24(S),25-epoxycholesterol accepts a hydrogen bond from His-435 that positions the imidazole ring of the histidine above the pyrrole ring of the tryptophan. In contrast, the acidic T0901317 hydroxyl group makes a shorter hydrogen bond with His-435 that pulls the imidazole over the electron-rich benzene ring of the tryptophan, possibly strengthening the electrostatic interaction. Point mutagenesis of Trp-457 supports the observation that the ligand-histidine-tryptophan coupling is different between the two ligands. The lipophilic liver X receptor ligand-binding pocket is larger than the corresponding steroid hormone receptors, which allows T0901317 to adopt two distinct conformations. These results provide a molecular basis for liver X receptor activation by a wide range of endogenous neutral and acidic ligands.     

Interaction between dinitrosyl iron complexes and intermediate products of oxidative stress

The interaction between glutathione-containing dinitrosyl iron complexes and superoxide radicals has been studied under the conditions of superoxide radical generation in mitochondria and in a model system xanthine-xanthine oxidase. It has been shown that both superoxide radical and hydroxyl radical are involved in the destruction of dinitrosyl iron complexes. At the same time, iron contained in dinitrosyl iron complex, apparently, does not catalyze the decomposition of hydrogen peroxide with the formation of hydroxyl radical. It has been found that dinitrosyl iron complexes with different anion ligands inhibit effectively the formation of phenoxyl probucol radical in a hemin-H2O2 a system. In this process, different components of the dinitrosyl iron complexes take part in the antioxidant action of these complexes.