Comparative analysis of estrogen receptors covalently labeled with an estrogen and an antiestrogen in several estrogen target cells as studied by limited proteolysis

Estrogen receptors covalently labeled with the estrogen affinity label [3H]ketononestrol aziridine (KNA) or with the antiestrogen affinity label [3H]tamoxifen aziridine (TAZ) were subjected to limited proteolysis with trypsin, alpha-chymotrypsin, and Staphylococcus aureus V8 protease and then analyzed on 10-20% sodium dodecyl sulfate-polyacrylamide gradient gels followed by fluorography. The similar molecular weights of intact receptors (Mr 66,000 daltons) and the proteolytic digest patterns indicate extensive homology among estrogen receptors from MCF-7 human breast cancer cells, GH4 rat pituitary cells and rat uterus when liganded with estrogen or antiestrogen. Each protease generated a distinctive ladder of estrogen receptor fragments, and the fragmentation patterns were virtually identical for estrogen receptors labeled with estrogen (KNA) or antiestrogen (TAZ). Each protease yielded a relatively "resistant" receptor fragment of about 28,000-35,000 daltons. Trypsin and chymotrypsin at higher concentrations generated a much smaller 6,000-8,000 dalton digest product that still contained the [3H]KNA- or [3H]TAZ-labeled receptor binding site. Moreover, the receptor digest patterns were similar for estrogen receptors from the three different target cells. Our studies suggest considerable structural relatedness among these three estrogen receptors and also indicate that these two affinity labels bind to a similar, perhaps identical, region of the receptor molecule.     

Identification of covalent attachment site of antiestrogenic estradiol 11 beta-derivatives on human estrogen receptor alpha ligand-binding domain

Affinity labeling of human estrogen receptor alpha (ERalpha) by high affinity and antiestrogenic estradiol (E(2)) 11 beta-derivatives, 11 beta-bromoacetamidoethoxyphenylE(2) (11BAEOPE(2)) and 11 beta-bromoacetamidopentoxyphenylE(2) (11BAPOPE(2)) was studied using glutathione-S-transferase (GST) fused to the ligand-binding domain (LBD) of human ERalpha. To identify and quantify the electrophile covalent attachment sites on LBD, [(14)C]11BAEOPE(2)- and [(14)C]11BAPOPE(2)-alkylated LBD were separated from GST, purified, and then trypsinized. HPLC of LBD tryptic fragments afforded one and two radioactive peaks (the ratio of the two latter peaks was 84/16) in the chromatograms related to LBD alkylated by 11BAEOPE(2) and 11BAPOPE(2), respectively. Mass spectrometry (MS) analyses of the fractions related to the single peak and to the major one of the two peaks showed signals which accurately matched the mass of electrophile-alkylated Cys(530)Lys(531) LBD tryptic peptide, whereas no signal compatible with an alkylated form of an LBD tryptic peptide was detected in the MS analysis of the minor peak-related fractions. MS/MS analysis of alkylated CysLys dipeptide revealed the presence of fragments that unambiguously designated the Cys S as the covalent attachment site of the electrophiles. We attempted to interpret the biochemical data by molecular modeling using various crystallographic structures of human LBD-ligand complexes. In agreement with the endocrine properties of electrophiles, labeling at Cys(530) could be accounted for by a LBD structure derived from LBD bound to 4-hydroxytamoxifen, a triphenylethylene antiestrogen. The common attachment to Cys(530) of estrogenic E(2) 17 alpha-derivatives [H. Mattras, S. Aliau, E. Demey, J. Poncet, J.L. Borgna, Mass spectrometry identification of covalent attachment sites of two related estrogenic ligands on human estrogen receptor alpha, J. Steroid Biochem. Mol. Biol. 98 (4-5), in press] and antiestrogenic E(2) 11 beta-derivatives suggests that the LBD portion encompassing this amino acid possesses a marked plasticity.     

The interaction site for tamoxifen aziridine with the bovine estrogen receptor

Calf uterine estrogen receptor was covalently labeled with [3H]tamoxifen aziridine during affinity chromatography purification. After carboxymethylation, affinity labeled receptor was digested with trypsin under limit conditions and the labeled peptides were fractionated by reversed-phase high performance liquid chromatography into one major and two minor components. Sequence analysis of the dominant labeled fragment indicated the facile cleavage of label during Edman degradation but identified two peptides, both derived from the extreme carboxyl terminus of the steroid-binding domain. The 17 residues of one peptide were fully conserved in all estrogen receptors. This fragment contained five nucleophilic amino acids and was considered as the more favored interaction site for tamoxifen aziridine. A corresponding region of the glucocorticoid receptor has recently been identified as one of three major contact sites for glucocorticoids (Carlstedt-Duke, J., Str?mstedt, P.-E., Persson, B., Cederlund, E., Gustafsson, J.-A., and J?rnvall, H. (1988) J. Biol. Chem. 263, 6842-6846). A comparison of amino acid physical characteristics in the hormone-binding domains of human estrogen and glucocorticoid receptors demonstrated an excellent structural correlation between the two regions and delineated elements in the estrogen receptor which may be directly involved in estradiol binding.     

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.     

125I]iododesethyl tamoxifen aziridine: synthesis and covalent labeling of the estrogen receptor with an iodine-labeled affinity label

Iododesethyl tamoxifen aziridine (I-Tam-Az), an analog of the estrogen receptor-affinity label tamoxifen aziridine (Tam-Az) in which the ethyl group has been replaced by an iodine, has been prepared by two routes: (a) metallation of a bromotriarylethylene system, followed by reaction with iodine, and aziridinylation, and (b) direct iodination of a trimethylstannyl triarylethylene system that is the immediate precursor of I-Tam-Az. The latter method can be used to prepare [125I]I-Tam-Az rapidly and in good yield, both at carrier-added and no-carrier-added levels; specific activities greater than 200 Ci/mmol have been obtained. In competitive radiometric binding assays with the estrogen receptor, I-Tam-Az has an apparent affinity of ca. 20%, equivalent to that of Tam-Az. It also undergoes rapid and selective time-dependent, irreversible binding to the estrogen receptor. [125I]I-Tam-Az reacts covalently with estrogen receptor in uterine cytosol preparations; its attachment is rapid and efficient, but somewhat less selective than that of Tam-Az. Estrogen receptor in intact MCF-7 human breast cancer cells can also be labeled with [125I]I-Tam-Az, and autoradiographic analysis of salt extracts of labeled nuclear estrogen receptor on SDS-polyacrylamide slab gels shows highly selective labeling of a 65K protein. [125I]I-Tam-Az is an efficient, selective affinity label for the estrogen receptor, available at high specific activity, and should be useful in studies on estrogen receptor structure, dynamics, and chromatin interactions.     

Desmethylnafoxidine aziridine: an electrophilic affinity label for the estrogen receptor with high efficiency and selectivity

Desmethylnafoxidine aziridine (Naf-Az), an affinity label for the estrogen receptor based structurally on the antiestrogen nafoxidine, has been prepared in unlabeled and in high specific activity, tritium-labeled form and has been evaluated for its apparent competitive binding, and time-dependent irreversible, covalent attachment to the estrogen receptor. Naf-Az was synthesized through a key 1,2-diaryl-3,4-dihydronaphthalene intermediate that was prepared from 6-methoxy-1-tetralone by two routes involving alternate strategies for arylation. Conversion of the diaryldihydronaphthalene to Naf-Az through a series of deprotection-activation reactions culminated in ethyleneimine displacement of a methanesulfonate. The tritium-labeled material was prepared by tritium-iodine exchange on an iodinated methanesulfonate precursor, followed by ethyleneimine displacement. Compared to our previously-prepared reagent tamoxifen aziridine (Tam-Az), Naf-Az has a higher apparent competitive binding affinity, and it reacts with the estrogen receptor in cytosol preparations and in intact MCF-7 breast cancer cells rapidly and with at least comparable efficiency and selectivity. SDS-polyacrylamide gel electrophoretic analysis confirms its selective labeling of the Mr 66,000 estrogen receptor. Naf-Az should prove to be useful in studies aimed at characterizing the properties and structure of estrogen receptors.     

Unique molecular properties of a urea- and salt-stable DNA-binding estrogen receptor dimer covalently labeled with the antiestrogen [3H]desmethylnafoxidine aziridine. A comparison with the estrogen-receptor complex

A new antiestrogen affinity ligand for the covalent labeling of estrogen receptors, [3H]desmethylnafoxidine aziridine, has been used to investigate the salt- and temperature-independent formation of DNA-binding estrogen receptor forms from untransformed (300 kilodaltons) receptor. Calf uterine estrogen receptor proteins labeled with [3H]estradiol or [3H]desmethylnafoxidine aziridine were quantitatively transformed (greater than 90%) to their DNA-binding configuration in low ionic strength buffers by brief exposure to 3 M urea at 0 C. The urea effect was hormone-dependent and partially reversible. The transformed receptors were purified (ca 250-fold) by affinity chromatography on single-stranded DNA-agarose in the continued presence of 3 M urea to prevent transformation reversal. Scatchard analyses revealed a single class of high affinity radioligand binding sites (Kd = 0.34 nM) unchanged by urea-induced transformation and purification. The DNA-binding receptor form labeled with [3H]desmethylnafoxidine aziridine was stable as a probable dimer in 3 M urea with 0.4 M KCl and displayed no evidence of size (Stokes radius 7.3 to 7.5 nm; 4.2 to 4.3 S; Mr = 136,800) heterogeneity. Sodium dodecyl sulfate-polyacrylamide gradient gel electrophoresis indicated the presence of an intact 67 kDa steroid-binding receptor subunit. Reverse-phase chromatography of the covalently labeled receptor on C4 and phenyl stationary phases revealed no evidence of structural heterogeneity. The surface charge of the estrogen- and antiestrogen-receptor complexes, however, was distinctly different in both the presence and absence of 3 M urea. Thus, exposure to urea was an effective salt- and temperature-independent means for achieving the complete transformation of receptor to its stable DNA-binding dimer configuration. The ligand-induced differences in receptor surface charge and the urea effects on DNA-binding (but not hormone-binding) suggest that both electrostatic and hydrophobic or hydrogen bonding receptor domains are influenced by ligand binding.     

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.     

Structural analysis of covalently labeled estrogen receptors by limited proteolysis and monoclonal antibody reactivity

We have used limited proteolysis of affinity-labeled estrogen receptors (ER), coupled with antireceptor antibody immunoreactivity, to assess structural features of ER and the relatedness of ER from MCF-7 human breast cancer and rat uterine cells. MCF-7 ER preparations covalently labeled with [3H]tamoxifen aziridine [( 3H]TAZ) were treated with trypsin (T), alpha-chymotrypsin (C), or Staphylococcus aureus V8 protease prior to electrophoresis on sodium dodecyl sulfate gels. Fluorography revealed a distinctive ladder of ER fragments containing TAZ for each protease generated from the Mr 66,000 ER: for T, fragments of 50K, 38K, 36K, 31K, 29K, and 28K that with longer exposure generated a 6K fragment; for C, fragments of 50K, 38K, 35K, 33K, 31K, 19K, and 18K that with longer exposure generated 14K and 6K fragments; and for V8, ca. 10 fragments between 62K and 28K. Two-dimensional gels revealed charge heterogeneity (two to three spots between pI 5.5 and 6.2) of the 66K ER and the T-generated 28K meroreceptor form. Immunoblot detection with the primate-specific antibody D75P3 gamma revealed that all immunoreactive fragments corresponded to TAZ-labeled fragments but that some small TAZ-labeled fragments (V8-generated forms less than 47K and T-generated forms less than 31K) were no longer immunoreactive. In contrast, use of the antibody H222Sp gamma revealed a correspondence between TAZ-labeled and immunoreactive fragments down to the smallest fragments generated, ca. 6K for T and C and 28K for V8. MCF-7 nuclear and cytosol ER showed very similar digest patterns, and there was a remarkable similarity in the TAZ-labeled and H222-immunoreactive fragments generated by proteolysis of both MCF-7 and rat uterine ER. These findings reveal great structural similarities between the human (breast cancer) and rat (uterine) ER and between nuclear and cytosol ER, indicate charge heterogeneity of ER, and allow a comparison of the immunoreactive and hormone attachment site domains of the ER. The observation that T and C generate a ca. 6K TAZ-labeled fragment that is also detectable with the H222 antibody should be of interest in studies determining the hormone binding domain of the ER and in amino acid sequencing of this region.     

Localization of the estrogen receptor in uterine cells by affinity labeling with [3H]tamoxifen aziridine

The possibility that estrogen receptors may exist in uterine plasma membranes was investigated by covalent labeling of estrogen receptors in mouse uterine cells with [3H]tamoxifen aziridine (TA). Isolated epithelial and stromal cells of immature mice were incubated with [3H]TA in the presence or absence of unlabeled tamoxifen, homogenized and separated into nuclear, cytosolic and microsomal fractions by differential centrifugation. These fractions were subjected to SDS-polyacrylamide gel electrophoresis and the proteins labeled covalently with TA were visualized by autoradiography. Proteins labeled specifically with [3H]TA were observed almost exclusively in the nuclear fraction of both epithelial and stromal cells. In contrast, very little labeled protein was detected in the cytosolic or microsomal fraction. Although these data do not preclude the possibility that estrogen binding sites are present in plasma membranes of uterine cells, this cellular fraction is definitely not labeled to a significant extent by [3H]TA. Thus, if membrane estrogen binding sites exist, their structural conformations may be different from that of nuclear estrogen receptors.     

Identification of an interaction between residue 6 of the natural peptide ligand and a distinct residue within the amino-terminal tail of the secretin receptor.

Photoaffinity labeling is a powerful tool for the characterization of the molecular basis of ligand binding. We recently used this technique to demonstrate the proximity between a residue within the carboxyl-terminal half of a secretin-like ligand and the amino-terminal domain of the secretin receptor (Dong, M., Wang, Y., Pinon, D. I., Hadac, E. M., and Miller, L. J. (1999) J. Biol. Chem. 274, 903-909). In this work, we have developed another novel radioiodinatable secretin analogue ([Bpa6,Tyr10]rat secretin-27) that incorporates a photolabile p-benzoyl-L-phenylalanine (Bpa) residue into position 6 of the amino-terminal half of the ligand and used this to identify a specific receptor residue proximate to it. This probe specifically bound to the secretin receptor with high affinity (IC50 = 13.2 +/- 2.5 nM) and was a potent stimulant of cAMP accumulation in secretin receptor-bearing Chinese hamster ovary-SecR cells (EC50 = 720 +/- 230 pM). It covalently labeled the secretin receptor in a saturable and specific manner. Cyanogen bromide cleavage of this molecule yielded a single labeled fragment that migrated on an SDS-polyacrylamide gel at Mr = 19,000 that shifted to 10 after deglycosylation, most consistent with either of two glycosylated fragments within the amino-terminal tail. By immunoprecipitation with antibody directed to epitope tags incorporated into each of the two candidate fragments, the most distal fragment at the amino terminus was identified as the domain of labeling. The labeled domain was further refined to the first 16 residues by endoproteinase Lys-C cleavage and by cyanogen bromide cleavage of another receptor construct in which Val16 was mutated to Met. Radiochemical sequencing of photoaffinity-labeled secretin receptor fragments established that Val4 was the specific site of covalent attachment. This provides the first residue-residue contact between a secretin ligand and its receptor and will contribute substantially to the molecular understanding of this interaction.     

The steroid binding domain of porcine estrogen receptor

For the purpose of characterizing the estrogen binding domain of porcine estrogen receptor (ER), we have made use of affinity labeling of partially purified ER with [3H]tamoxifen aziridine. The labeling is very efficient and selective particularly after partial purification of ER. A 65,000-dalton (65-kDa) band was detected on the fluorogram of a sodium dodecyl sulfate-polyacrylamide gel, together with a 50-kDa band and a few more smaller bands. The 50-kDa protein appears to be a degradation product of the 65-kDa protein in view of the similar peptide map. ER was affinity labeled before or after controlled limited proteolysis with either trypsin, papain, or alpha-chymotrypsin. The labeling patterns of limited digests indicate that a fragment of about 30 kDa is relatively resistant to proteases and has a full and specific binding activity to estrogen, whereas smaller fragments have lost much of the binding activity. This fragment is very hydrophobic and probably corresponds to the carboxy half of ER.     

Mass spectrometry identification of covalent attachment sites of two related estrogenic ligands on human estrogen receptor alpha

A purified preparation of human estrogen receptor alpha (hERalpha) ligand-binding domain (LBD) involving mainly the Ser(309)Ala(569) (approximately 30%) and Ser(309)Ala(571) (approximately 63%) ER portions was used to identify the covalent attachment sites of two closely related estrogenic ER affinity labels 17alpha-bromoacetamidopropylestradiol (17BAPE(2)) and 17alpha-bromoacetamidomethylestradiol (17BAME(2)). To identify and quantify the electrophile covalent attachment sites, [(14)C]17BAPE(2)- and [(14)C]17BAME(2)-alkylated hLBD preparations were trypsinized and submitted to HPLC. In each case, two radioactive fractions were obtained. Mass spectrometry analyses of the two fractions showed signals, which closely matched the molecular masses of alkylated Cys(530)Lys(531) and Cys(417)Arg(434) hLBD tryptic peptides. The covalent attachment of the two electrophiles on hLBD was assigned to the S atoms of Cys(530) and Cys(417). However, the balance between Cys(530) and Cys(417) labeling markedly differed according to the affinity label used, with the Cys(530)/Cys(417) ratio being 2.1 for 17BAPE(2), and 20 for 17BAME(2). We attempted to interpret the covalent attachment of electrophiles by molecular modeling using the crystallographic structure of LBD bound to E(2). In agreement with the different levels of Cys(417) alkylation, the LBD model with unchanged helices could not easily account for Cys(417) labeling by 17BAME(2), whereas favorable results were obtained through 17BAPE(2) docking. Moreover, labeling at Cys(530) by the two electrophiles could not be interpreted using the LBD model. This indicates that some states of solute LBD bound to the estrogenic E(2) 17alpha-derivatives differ from the structure of crystallized LBD bound to E(2).     

Spatial approximation between two residues in the mid-region of secretin and the amino terminus of its receptor. Incorporation of seven sets of such constraints into a three-dimensional model of the agonist-bound secretin receptor

Photoaffinity labeling of receptors by bound agonists can provide important spatial constraints for molecular modeling of activated receptor complexes. Secretin is a 27-residue peptide hormone with a diffuse pharmacophoric domain that binds to the secretin receptor, a prototypic member of the Class B family of G protein-coupled receptors. In this work, we have developed, characterized, and applied two new photolabile probes for this receptor, with sites for covalent attachment in peptide positions 12 and 14, surrounding the previously most informative site of affinity labeling of this receptor. The [Tyr10,(BzBz)Lys12]rat secretin-27 probe covalently labeled receptor residue Val6, whereas the [Tyr10,(BzBz)Lys14]rat secretin-27 probe labeled receptor residue Pro38. When combined with previous photoaffinity labeling data, there are now seven independent sets of constraints distributed throughout the peptide and receptor amino-terminal domain that can be used together to generate a new molecular model of the ligand-occupied secretin receptor. The amino-terminal domain of this receptor presented a stable platform for peptide ligand interaction, with the amino terminus of the peptide hormone extended toward the transmembrane helix domain of the receptor. This provides clear insights into the molecular basis of natural ligand binding and supplies testable hypotheses regarding the molecular basis of activation of this receptor.     

Selective covalent labeling of cysteines in bovine serum albumin and in hepatoma tissue culture cell glucocorticoid receptors by dexamethasone 21-mesylate

The specificity of protein labeling by an affinity label of glucocorticoid receptors, dexamethasone 21-mesylate (Dex-Mes), was investigated using bovine serum albumin (BSA) as a model. During the early stages of [3H]Dex-Mes labeling at pH 8.8, approximately 90% of the covalent bond formation occurred at the one non-oxidized cysteine (Cys-34) of BSA. The nonspecific labeling was equally distributed over the rest of the BSA molecule. [3H]Dex-Mes labeling of Cys-34 was totally, and specifically inhibited by nearly stoichiometric amounts of the thiol-specific reagent methyl methanethiolsulfonate (MMTS). Thus both Dex-Mes and MMTS appear to react very selectively with thiols under our conditions. In reactions with hepatoma tissue culture (HTC) cell glucocorticoid receptors, MMTS was equally efficient in preventing [3H]dexamethasone binding to receptors and [3H]Dex-Mes labeling of the 98-kDa receptor protein. These results indicate that Dex-Mes labeling of the glucocorticoid receptor involves covalent reaction with at least one cysteine in the steroid binding site of the receptor. Small (approximately 1600-dalton) fragments of the [3H]Dex-Mes-labeled 98-kDa receptor were generated by limit proteolysis with trypsin, chymotrypsin, and Staphylococcus aureus V8 protease under denaturing conditions. Data from these fragments on 15% sodium dodecyl sulfate-polyacrylamide gels were consistent with all of the covalent [3H] Dex-Mes being located on one or a few cysteines in one approximately 15-residue stretch of the receptor. Further studies revealed no differences in the limit protease digestion patterns of activated and unactivated [3H]Dex-Mes-labeled receptors with trypsin, chymotrypsin, or V8 protease under denaturing conditions. These data suggest that activation does not cause any major covalent modifications of the amino acids immediately surrounding the affinity-labeled cysteine(s) of the steroid binding site.     

Refinement of the structure of the ligand-occupied cholecystokinin receptor using a photolabile amino-terminal probe

Affinity labeling is a powerful tool to establish spatial approximations between photolabile residues within a ligand and its receptor. Here, we have utilized a cholecystokinin (CCK) analogue with a photolabile benzoylphenylalanine (Bpa) sited in position 24, adjacent to the pharmacophoric domain of this hormone (positions 27-33). This probe was a fully efficacious agonist that bound to the CCK receptor saturably and with high affinity (K(i) = 8.9 +/- 1.1 nm). It covalently labeled the CCK receptor either within the amino terminus (between Asn(10) and Lys(37)) or within the third extracellular loop (Glu(345)), as demonstrated by proteolytic peptide mapping, deglycosylation, micropurification, and Edman degradation sequencing. Truncation of the receptor to eliminate residues 1-30 had no detrimental effect on CCK binding, stimulated signaling, or affinity labeling through a residue within the pharmacophore (Bpa(29)) but resulted in elimination of the covalent attachment of the Bpa(24) probe to the receptor. Thus, the distal amino terminus of the CCK receptor resides above the docked ligand, compressing the portion of the peptide extending beyond its pharmacophore toward the receptor core. Exposure of wild type and truncated receptor constructs to extracellular trypsin damaged the truncated construct but not the wild type receptor, suggesting that this domain also may play a protective role. Use of these additional insights into molecular approximations provided key constraints for molecular modeling of the peptide-receptor complex, supporting the counterclockwise organization of the transmembrane helical domains.