Cysteine 530 of the human estrogen receptor alpha is the main covalent attachment site of 11beta-(aziridinylalkoxyphenyl)estradiols.

The efficiency of 11beta-[p(aziridinylethoxy)phenyl]estradiol 1 and 11beta-[p(aziridinylpentoxy)phenyl]estradiol 2 affinity labeling of the estrogen receptor alpha (ERalpha) was evaluated on the basis of their capacity to inhibit [(3)H]estradiol binding to lamb and human ERalphas. Relative to RU 39 411 (11beta-[p(dimethylaminoethoxy)phenyl]estradiol), the most closely related and chemically inert analogue of 1, the two electrophiles irreversibly inhibited [(3)H]estradiol binding to the lamb ERalpha. The fact that the compound effects were prevented (i) when the ERalpha hormone-binding site was occupied by estradiol and (ii) when the ERalpha-containing extracts were pretreated with methyl methanethiosulfonate (an SH-specific reagent) suggested that the compounds specifically alkylated ERalpha at cysteine residues. Wild-type human ERalpha was alkylated as efficiently as lamb ER, whereas the quadruple cysteine --> alanine mutant, in which all cysteines of the hormone-binding domain (residues 381, 417, 447, and 530) were changed to alanines, showed no significant electrophile labeling. The single C530A mutant was much less sensitive to the action of the electrophiles than the three other single mutants (C381A, C417A, and C447A). Moreover, analysis of the three double mutants (C381A/C530A, C417A/C530A, and C447A/C530A) showed that only the C381A/C530A mutant was less susceptible to electrophile labeling than the single C530A mutant. We concluded that in the hormone-binding pocket C530 was the main covalent attachment site of aziridines 1 and 2, whereas C381 could be a secondary site. These results agreed with the crystal structure of the hormone-binding domain of the human ERalpha bound to estrogen or antiestrogen, since C381 and C530 appeared to be (i) located in structural elements involved in delineating the hormone-binding pocket and (ii) in spatial proximity to each other, which was closer in the crystal structure of the ER:antiestrogen complex than in that of the ER:estrogen complex. Since C530 and C381 were also the main and secondary covalent attachment sites of tamoxifen aziridine (a nonsteroidal affinity-labeling agent), we propose a selective mode of superimposition of tamoxifen-class antiestrogens with RU 39 411-class antiestrogens, which could account for the relative positioning of the two types of ligands in the ERalpha hormone-binding pocket.     

Identification of cysteine 530 as the covalent attachment site of an affinity-labeling estrogen (ketononestrol aziridine) and antiestrogen (tamoxifen aziridine) in the human estrogen receptor

Radiosequence analysis of peptide fragments of the estrogen receptor (ER) from MCF-7 human breast cancer cells has been used to identify cysteine 530 as the site of covalent attachment of an estrogenic affinity label, ketononestrol aziridine (KNA), and an antiestrogenic affinity label, tamoxifen aziridine (TAZ). ER from MCF-7 cells was covalently labeled with [3H]TAZ or [3H]KNA and purified to greater than 95% homogeneity by immunoadsorbent chromatography. Limit digest peptide fragments, generated by prolonged exposure of the labeled receptor to trypsin, cyanogen bromide, or Staphylococcus aureus V8 protease, were purified to homogeneity by high performance liquid chromatography (HPLC), and the position of the labeled residue was determined by sequential Edman degradation. With both aziridines, the labeled residue was at position 1 in the tryptic peptide, position 2 in the cyanogen bromide peptide, and position 7 in the V8 protease peptide. This localizes the site of labeling to a single cysteine at position 530 in the receptor sequence. The identity of cysteine as the site of labeling was confirmed by HPLC comparison of the TAZ-labeled amino acid (as the phenylthiohydantoin and phenylthiocarbamyl derivatives) and the KNA-labeled amino acid (as the phenylthiocarbamyl derivative) with authentic standards prepared by total synthesis. Cysteine 530 is located in the hormone binding domain of the receptor, near its carboxyl terminus. This location is consistent with earlier studies using sodium dodecyl sulfate-polyacrylamide gel electrophoresis to analyze the size of the proteolytic fragments containing the covalent labeling sites for TAZ and KNA and the antigen recognition sites for monoclonal antibodies. The fact that both the estrogenic and antiestrogenic affinity labeling agents react covalently with the same cysteine indicates that differences in receptor-agonist and receptor-antagonist complexes do not result in differential covalent labeling of amino acid residues in the hormone binding domain.     

Estrogen pyrazoles: defining the pyrazole core structure and the orientation of substituents in the ligand binding pocket of the estrogen receptor

Previously, we reported that certain tetrasubstituted 1,3,5-triaryl-4-alkyl-pyrazoles bind to the estrogen receptor (ER) with high affinity (Fink, B. E.; Mortenson, D. S.; Stauffer, S. R.; Aron, Z. D.; Katzenellenbogen, J. A. Chem. Biol. 1999, 6, 205-219; Stauffer, S. R.; Katzenellenbogen, J. A. J. Comb/. Chem. 2000, 2. 318 329; Stauffer, S. R.: Coletta, C. J.: Sun, J.; Tedesco, R., Katzenellenbogen, B. S.; Katzenellenbogen, J. A. J. Med. Chem. 2000, submitted). To investigate how cyclic permutation of the two nitrogen atoms of a pyrazole might affect ER binding affinity, we prepared a new pyrazole core isomer, namely a 1,3,4-triaryl-5-alkyl-pyrazole (2), to compare it with our original pyrazole (1). We also prepared several peripherally matched core pyrazole isomer sets to investigate whether the two pyrazole series share a common binding orientation. Our efficient, regioselective synthetic route to these pyrazoles relies on the acylation of a hydrazone anion, followed by cyclization, halogenation, and Suzuki coupling. We found that the ER accommodates 1,3,4-triaryl-pyrazoles of the isomeric series only somewhat less well than the original 1,3,5-triaryl series, and it appears that both series share a common binding mode. This preferred orientation for the 1,3,5-triaryl-4-alkyl-pyrazoles is supported by binding affinity measurements of analogues in which the phenolic hydroxyl groups were systematically removed from each of the three aryl groups, and the orientation is consistent, as well, with molecular modeling studies. These studies provide additional insight into the design of heterocyclic core structures for the development of high affinity ER ligands by combinatorial methods.     

Site-directed mutagenesis of beta-adrenergic receptors. Identification of conserved cysteine residues that independently affect ligand binding and receptor activation

Using site-directed mutagenesis of the human beta 2-adrenergic receptor and continuous expression in B-82 cells, the role of 3 conserved cysteines in transmembrane domains and 2 conserved cysteines in the third extracellular domain in receptor function was examined. Cysteine was replaced with serine in each mutant receptor as this amino acid is similar to cysteine in size but it cannot form disulfide linkages. Replacement of cysteine residues 77 and 327, in the second and seventh transmembrane-spanning domains, respectively, had no effect on ligand binding or the ability of the receptor to mediate isoproterenol stimulation of adenylate cyclase. Substitution of cysteine 285, in the sixth transmembrane domain of the receptor, produced a mutant receptor with normal ligand-binding properties but a significantly attenuated ability to mediate stimulation of adenylate cyclase. Mutation of cysteine residues 190 and 191, in the third extracellular loop of the beta 2 receptor, had qualitatively similar effects on ligand binding and isoproterenol-mediated stimulation of adenylate cyclase. Replacement of either of these residues with serine produced mutant receptors that displayed a marked loss in affinity for both beta-adrenergic agonists and antagonists. Replacement of both cysteine 190 and 191 with serine had an even greater effect on the ability of the receptor to bind ligands. Consistent with the loss of Ser190 and/or Ser191 mutant receptor affinity for agonists was a corresponding shift to the right in the dose-response curve for isoproterenol-induced increases in intracellular cyclic AMP concentrations in cells expressing the mutant receptors. These data implicate one of the conserved transmembrane cysteine residues in the human beta 2-adrenergic receptor in receptor activation by agonists and also suggest that conserved cysteine residues in an extracellular domain of the receptor may be involved in ligand binding.     

The estrogen receptor binds tightly to its responsive element as a ligand-induced homodimer

Extracts containing wild-type or mutant human estrogen receptor (ER) have been used to study the binding of ER to its responsive element (ERE). Estradiol (E2) or the antiestrogen hydroxytamoxifen is required for ER binding as assayed by gel retardation. The DNA binding domain (DBD) encompasses the highly conserved region C. Both intact ER-E2 complexes and ER mutants truncated for the hormone binding domain (HBD) bind as dimers to an ERE. However, an HBD-truncated ER binds less tightly to an ERE than an intact ER-E2 complex. The DBD and HBD contain a constitutive and a stronger ER-induced dimerization function, respectively. Thus, in addition to inducing the activation function associated with the HBD, estrogen plays a crucial role in the formation of stable ER dimers that bind tightly to ERE.     

Regulation of pS2 gene expression by affinity labeling and reversibly binding estrogens and antiestrogens: comparison of effects on the native gene and on pS2-chloramphenicol acetyltransferase fusion genes transfected into MCF-7 human breast cancer cells

We have examined the effects of reversibly and irreversibly binding estrogenic and antiestrogenic ligands for the estrogen receptor on pS2 RNA accumulation in MCF-7 human breast cancer cells and on pS2-chloramphenicol acetyl transferase (CAT) fusion gene expression in transfected MCF-7 cells. In MCF-7 cells grown in the absence of estrogens, the reversibly binding estrogen, estradiol, and the affinity labeling estrogen, ketononestrol aziridine, KNA, evoked a 13-fold increase in pS2 RNA level. The reversibly binding antiestrogen trans-hydroxytamoxifen and the affinity labeling antiestrogens tamoxifen aziridine or desmethylnafoxidine aziridine behaved as partial agonists/antagonists. In thymidine kinase-chloramphenicol acetyltransferase (tk-CAT) fusion genes containing a 1000 base pair fragment of the pS2 5'-flanking region encompassing the estrogen responsive element of the gene [pS2 (-1100/-90) tk-CAT], estradiol and ketononestrol aziridine evoked a marked stimulation of CAT activity and, in transfected cells grown in both the presence or absence of the weak estrogen phenol red, the antiestrogens behaved as partial agonists/antagonists. This pS2 5'-flanking region displayed both estrogen-dependent and estrogen-independent enhancer activity as monitored by stimulation of CAT activity. Hormonal regulation of the transfected pS2 fusion gene was similar to that observed in the native pS2 gene of MCF-7 cells; however, antiestrogens, while still partial agonists-antagonists, were relatively more agonistic on the transfected fusion gene than on the native gene. One antiestrogen (ICI 164,384) that behaved as a pure estrogen antagonist on the native gene was a partial agonist-antagonist of pS2 gene expression in the plasmid. This study illustrates that the hormonal regulation of the pS2 gene, as characterized by the agonist-antagonist balance of estrogens and antiestrogens, is influenced by the DNA context of the pS2 estrogen responsive element. Also, the fact that estrogens and antiestrogens that form covalent bonds with the estrogen receptor modulate activity of the native pS2 gene and the pS2-tk-CAT fusion gene in a manner similar to that of their reversibly binding counterparts suggests that it may be possible to use these irreversibly binding ligands to follow the interaction of hormone-receptor complexes with regions regulating estrogenic stimulation of the pS2 gene.     

Opioid receptor pharmacological chaperones act by binding and stabilizing newly synthesized receptors in the endoplasmic reticulum

Accumulating evidence has indicated that membrane-permeable G protein-coupled receptor ligands can enhance cell surface targeting of their cognate wild-type and mutant receptors. This pharmacological chaperoning was thought to result from ligand-mediated stabilization of immature receptors in the endoplasmic reticulum (ER). In the present study, we directly tested this hypothesis using wild-type and mutant forms of the human delta-opioid receptor as models. ER-localized receptors were isolated by expressing the receptors in HEK293 cells under tightly controlled tetracycline induction and blocking their ER export with brefeldin A. The ER-retained delta-opioid receptor precursors were able to bind [(3)H]diprenorphine with high affinity, and treatment of cells with an opioid antagonist naltrexone led to a 2-fold increase in the number of binding sites. After removing the transport block, the antagonist-mediated increase in the number of receptors was detectable at the cell surface by flow cytometry and cell surface biotinylation assay. Importantly, opioid ligands, both antagonists and agonists, were found to stabilize the ER-retained receptor precursors in an in vitro heat inactivation assay and the treatment enhanced dissociation of receptor precursors from the molecular chaperone calnexin. Thus, we conclude that pharmacological chaperones facilitate plasma membrane targeting of delta-opioid receptors by binding and stabilizing receptor precursors, thereby promoting their release from the stringent ER quality control.     

Differential interactions of estrogens and antiestrogens at the 17 beta-hydroxyl or counterpart hydroxyl with histidine 524 of the human estrogen receptor alpha

We investigated the role of H524 of the human estrogen receptor alpha (ERalpha) for the binding of various estrogens [estradiol (E(2)), 3-deoxyestradiol (3-dE(2)), and 17beta-deoxyestradiol (17beta-dE(2))] and antiestrogens [4-hydroxytamoxifen (OHT), RU 39 411 (RU), and raloxifene (Ral)], which possess the 17beta-hydroxyl or counterpart hydroxyl (designated: 17beta/c-OH), with the exception of 17beta-dE(2) and OHT. The work involved a comparison of the binding affinities of these ligands for wild-type and H524 mutant ERs, modified or not with diethyl pyrocarbonate (DEPC), a selective histidine reagent. Alanine substitution of H524 did not significantly change the association affinity constant (relative to OHT) of 17beta-dE(2), whereas those of RU, Ral, E(2), and 3-dE(2) were decreased 3-fold, 14-fold, 24-fold, and 49-fold, respectively. Values of the two ligands available in radiolabeled form (E(2) and OHT) were correlated with the dissociation rate constants, which were increased 250-fold and 2-fold, respectively. The action of DEPC on wild-type ER led to a homogeneous ER population which still bound antiestrogens and 17beta-dE(2) with practically unchanged affinities (less than 4-fold decreases in relative affinity constants), while E(2) and 3-dE(2) displayed markedly decreased affinities (56-fold decrease for E(2)). Conversely, DEPC treatment of H524A mutant ER did not induce marked decreases in the relative affinities of any of the checked compounds (decreases wild-type ER) and very weakly protected H524A ER. Molecular modeling was tentatively used to interpret the biochemical results.     

Conserved Cysteines of the Human Immunodeficiency Virus Type 1 Protease Are Involved in Regulation of Polyprotein Processing and Viral Maturation of Immature Virions

We investigated the role of the two highly conserved cysteine residues, cysteines 67 and 95, of the human immunodeficiency virus type 1 (HIV-1) protease in regulating the activity of that protease during viral maturation. To this end, we generated four HIV-1 molecular clones: the wild type, containing both cysteine residues; a protease mutant in which the cysteine at position 67 was replaced by an alanine (C67A); a C95A protease mutant; and a double mutant (C67A C95A). When immature virions were produced in the presence of an HIV-1 protease inhibitor, KNI-272, and the inhibitor was later removed, limited polyprotein processing was observed for wild-type virion preparations over a 20-h period. Treatment of immature wild-type virions with the reducing agent dithiothreitol considerably improved the rate and extent of Gag processing, suggesting that the protease is, in part, reversibly inactivated by oxidation of the cysteine residues. In support of this, C67A C95A virions processed Gag up to fivefold faster than wild-type virions in the absence of a reducing agent. Furthermore, oxidizing agents, such as H₂O₂ and diamide, inhibited Gag processing of wild-type virions, and this effect was dependent on the presence of cysteine 95. Electron microscopy revealed that a greater percentage of double-mutant virions than wild-type virions developed a mature-like morphology on removal of the inhibitor. These studies provide evidence that under normal culture conditions the cysteines of the HIV-1 protease are susceptible to oxidation during viral maturation, thus preventing immature virions from undergoing complete processing following their release. This is consistent with the cysteines being involved in the regulation of viral maturation in cells under oxidative stress.     

Identification of determinants of ligand binding affinity and selectivity in the prostaglandin D2 receptor CRTH2

The chemoattractant receptor-homologous molecule expressed on Th2 cells (CRTH2) is a G protein-coupled receptor that mediates the pro-inflammatory effects of prostaglandin D(2) (PGD(2)) generated in allergic inflammation. The CRTH2 receptor shares greatest sequence similarity with chemoattractant receptors compared with prostanoid receptors. To investigate the structural determinants of CRTH2 ligand binding, we performed site-directed mutagenesis of putative mCRTH2 ligand-binding residues, and we evaluated mutant receptor ligand binding and functional properties. Substitution of alanine at each of three residues in the transmembrane (TM) helical domains (His-106, TM III; Lys-209, TM V; and Glu-268, TM VI) and one in extracellular loop II (Arg-178) decreased PGD(2) binding affinity, suggesting that these residues play a role in binding PGD(2). In contrast, the H106A and E268A mutants bound indomethacin, a nonsteroidal anti-inflammatory drug, with an affinity similar to the wild-type receptor. HEK293 cells expressing the H106A, K209A, and E268A mutants displayed reduced inhibition of intracellular cAMP and chemotaxis in response to PGD(2), whereas the H106A and E268A mutants had functional responses to indomethacin similar to the wild-type receptor. Binding of PGE(2) by the E268A mutant was enhanced compared with the wild-type receptor, suggesting that Glu-268 plays a role in determining prostanoid ligand selectivity. Replacement of Tyr-261 with phenylalanine did not affect PGD(2) binding but decreased the binding affinity for indomethacin. These results provided the first details of the ligand binding pocket of an eicosanoid-binding chemoattractant receptor.     

Evaluation of cysteine 283 and glutamic acid 284 in the coenzyme binding site of Salmonella typhimurium glutamate dehydrogenase by site-directed mutagenesis and reaction with the nucleotide analogue 2-[4-bromo-2,3-dioxobutyl)thio)-1,N6-ethenoadenosine 2',5'-bisphosphate.

NADP(+)-specific glutamate dehydrogenase of Salmonella typhimurium was previously shown to react irreversibly at the coenzyme site with the nucleotide analogue 2-((4-bromo-2,3-dioxobutyl)thio)-1,N6-ethenoadenosine 2',5'-bisphosphate (2-BDB-T epsilon A 2',5'-DP) yielding a partially active enzyme, and inactivation was attributed to modification of the peptide Leu282-Cys-Glu-Ile-Lys286 (Bansal, A., Dayton, M.A., Zalkin, H., and Colman, R.F. (1989) J. Biol. Chem. 264, 9827-9835). Three mutant enzymes have now been engineered, expressed in Escherichia coli, and purified: the single mutants C283I and E284Q and the double mutant C283I:E284Q. The wild-type and mutant enzymes have similar specific activities and Km values for alpha-ketoglutarate, ammonium ion, and NADPH, indicating that neither cysteine 283 nor glutamic acid 284 is essential for activity. The mutant enzyme E284Q, like wild-type glutamate dehydrogenase, is substantially inactivated by 2-BDB-T epsilon A 2',5'-DP. In contrast, the two cysteine mutant enzymes, C283I and C283I:E284Q, are not inactivated by 2-BDB-T epsilon A 2',5'-DP. Modified tryptic peptides with the sequence Leu-X-Glu(Gln)-Ile-Lys were isolated from wild-type or E284Q enzymes inactivated by 2-BDB-T epsilon A 2',5'-DP. This peptide was absent from digests of active wild-type enzyme modified in the presence of the protectant NADPH and from digests of active C283I enzyme after incubation with 2-BDB-T epsilon A 2',5'-DP. Although it is not required for catalytic activity, cysteine 283 is implicated by the results of the affinity labeling experiments as the reaction target of the nucleotide analogue and is located in the region of the coenzyme binding site.     

Cross-linking of glycine receptor transmembrane segments two and three alters coupling of ligand binding with channel opening

Contact points between transmembrane segments (TMs) two and three of the glycine receptor are undefined and may play an important role in channel gating. We tested whether two amino acids in TM2 (S267) and TM3 (A288), known to be critical for alcohol and volatile anesthetic action, could cross-link by mutating both to cysteines and expressing the receptors in Xenopus laevis oocytes. In contrast with the wild-type receptor and single cysteine mutants, the S267C/A288C double mutant displayed unusual responses, including a tonic leak activity that was closed by strychnine and a run-down of the response upon repeated applications of glycine. We hypothesized that these characteristics were due to cross-linking of the two cysteines on opposing faces of these adjacent, alpha helical TMs. This would alter the movement of these two regions required for normal gating. To test this hypothesis, we used dithiothreitol to reduce the putative S267C-A288C disulfide bond. Reduction abolished the leak current and provided normal responses to glycine. Subsequent application of the cross-linking agent mercuric chloride caused the initial characteristics to return. These data demonstrate that S267 and A288 are near-neighbors and provide insight towards the location and role of the TM2-TM3 interface in ligand-gated ion channels.     

Role of cysteines 640, 656, and 661 in steroid binding to rat glucocorticoid receptors.

The involvement of a vicinally spaced dithiol group in steroid binding to the glucocorticoid receptor has been deduced from experiments with the thiol-specific reagent methyl methanethiolsulfonate and the vicinal dithiol-specific reagent sodium arsenite. The vicinally spaced dithiol appears to reside in the 16-kDa trypsin fragment of the receptor, which is thought to contain 3 cysteines (Cys-640, -656, and -661 of the rat receptor) and binds hormone with an approximately 23-fold lower affinity than does the intact 98-kDa receptor. We now report that the steroid binding specificity of preparations of this 16-kDa fragment and the intact receptor are virtually identical. This finding supports our designation of the 16-kDa fragment as a steroid-binding core domain and validates our continued use of this tryptic fragment in studies of steroid binding. To identify the cysteines which comprise the vicinally spaced dithiol group, and to examine further the role of cysteines in steroid binding, a total of five point mutant receptors were prepared: cysteine-to-serine for each suspected cysteine, cysteine-to-glycine for Cys-656, and the C656,661S double mutant. Unexpectedly, each receptor with a single point mutation still bound steroid. Even the double mutant (C656,661S) bound steroid with wild type affinity. These results suggest that none of these cysteines are directly required either for steroid binding to the glucocorticoid receptor or for heat shock protein 90 association with the receptor. However, the presence of Cys-656 was obligatory for covalent labeling of the receptor by [3H]dexamethasone 21-mesylate. Studies with preparations of the 98 and 16 kDa forms of these mutant receptors revealed both that Cys-656 and -661 comprise the vicinally spaced dithiols reacting with arsenite and that any two of the three thiols could form an intramolecular disulfide after treatment with low concentrations of methyl methanethiolsulfonate. These data, in conjunction with those from experiments on the effects of steric bulk on various receptor functions, support a model for the ligand binding cavity of the receptor that involves all three thiols in a flexible cleft but where thiol-steroid interactions are not essential for binding.     

Reaction of oxidized dopamine with endogenous cysteine residues in the human dopamine transporter

There is evidence to suggest that dopamine (DA) oxidizes to form dopamine ortho-quinone (DAQ), which binds covalently to nucleophilic sulfhydryl groups on protein cysteinyl residues. This reaction has been shown to inhibit dopamine uptake, as well as other biological processes. We have identified specific cysteine residues in the human dopamine transporter (hDAT) that are modified by this electron-deficient substrate analog. DAQ reactivity was inferred from its effects on the binding of [(3)H]2-beta-carbomethoxy-3-beta-(4-fluorophenyl)tropane (beta-CFT) to hDAT cysteine mutant constructs. One construct, X5C, had four cysteines mutated to alanine and one to phenylalanine (Cys(90)A, Cys(135)A, C306A, C319F and Cys(342)A). In membrane preparations 1 mM DAQ did not affect [(3)H]beta-CFT binding to X5C hDAT, in contrast to its effect in wild-type hDAT in which it reduced the B:(max) value by more than half. Wild-type cysteines were substituted back into X5C, one at a time, and the ability of DAQ to inhibit [(3)H]beta-CFT binding was assessed. Reactivity of DAQ with Cys(90) increased the affinity of [(3)H]beta-CFT for the transporter, whereas reactivity with Cys(135) decreased the affinity of [(3)H]beta-CFT. DAQ did not change the K:(D) for [(3)H]beta-CFT binding to wild-type. The reactivity of DAQ at Cys(342) decreased B:(max) to the same degree as wild-type. The latter result suggests that Cys(342) is the wild-type residue most responsible for DAQ-induced inhibition of [(3)H]beta-CFT binding.