Evidence that the endogenous heat-stable glucocorticoid receptor-activating factor is thioredoxin

Extraction of rat liver cytosol with 10% charcoal at 4 degrees C inactivates specific glucocorticoid-binding capacity. The steroid-binding capacity of extracted cytosol can be restored by adding dithiothreitol or by incubating with boiled liver cytosol at 20 degrees C in the presence of 10 mM sodium molybdate. Two components of boiled cytosol are required for receptor activation: NADPH and an endogenous heat-stable protein with an apparent Mr of 12,300 by Sephadex G-50 chromatography. This endogenous receptor-activating protein coelutes on Sephadex G-50 chromatography with endogenous thioredoxin activity, and it can be replaced in the activating system by purified Escherichia coli thioredoxin. These observations suggest that glucocorticoid receptors in cytosol preparations are maintained in a reduced, steroid-binding state by a NADPH-dependent, thioredoxin-mediated reducing system.     

A low molecular weight inhibitor of steroid receptor activation.

Dilution at 0 degrees of rat liver cytosol incubated with [3H]triamcinolone acetonide provoked an enhanced binding of steroid-receptor complexes to nuclei. The explanation of this phenomenon was found to be an "activation" of the complexes. Dilution acted by decreasing the concentration of a cytosol inhibitor. This reaction was irreversible at 0 degrees: once activated the complexes could not be reversed to the nonactivated state by the addition of inhibitor. The presence of hormone was necessary, since hormone-free receptor molecules could not be activated by dilution. Removal of the inhibitor did not lead to activation of all complexes: after 24 h a "plateau" was attained where 55 to 70% of the complexes were activated. The inhibitor was shown to be a low molecular weight molecule by dialysis, Sephadex G-25 chromatography, ammonium sulfate precipitation, and ultrafiltration. Thus [3H]triamcinolone acetonide-receptor complexes present in a cytosol from which the inhibitor had been removed by Sephadex G-25 chromatography became spontaneously activated at low ionic strength and at 0 degrees. The inhibitor is not a steroid (at least of usual polarity) since it cannot be extracted by methylene chloride or adsorbed by activated charcoal. It is thermostable (resists to 30 min at 100 degrees). Its removal by incubation with a cation exchange resin suggests that it may be positively charged, however it is not complexed by EDTA. This inhibitor must be distinguished from a previously described inhibitor of steroid-receptor complexes binding to nuclei. The latter compound has been shown in various systems to be responsible for an artifactual saturation of nuclear acceptor by steroid-receptor complexes. It inhibits the binding to nuclear acceptors of already activated complexes and is probably a macromolecule. It is thus different from the low molecular weight activation inhibitor described in the present paper.     

Effect of dextran-charcoal treatment on the dissociation kinetics of glucocorticoid-receptor complexes: possible involvement of lipid

Dissociation kinetics were determined at 0 degrees C for molybdate-stabilized glucocorticoid-receptor complexes in rat thymus cytosol. Exposure of complexes to dextran-coated charcoal had no effect on their chromatographic properties or transformation status, but dissociation rates measured after charcoal treatment were significantly lower than those determined by displacement with excess competing steroid. The dissociation rate of the [2,4,6,7-3H]prednisolone-receptor complex was similarly modified by chromatography on Lipidex 1000, but not by chromatography on Sephadex G-25 or G-75. It is concluded that treatment of glucocorticoid-receptor complexes with dextran-charcoal or Lipidex 1000 brings about a change in dissociation rate as a consequence of the removal of a lipid component from the complex.     

Transformation of the 8-9 S molybdate-stabilized estrogen receptor from low-affinity to high-affinity state without dissociation into subunits

The rate of dissociation of labeled estradiol from [3H] estradiol-8-9 S receptor complexes ([3H]E2-8-9 S ER) molybdate-stabilized was determined in the presence of either an excess of unlabeled hormone ("chase") or of charcoal/dextran suspension ("stripping"). Biphasic dissociation of the hormone was observed in both cases, but the fraction of the fast-dissociating component was dramatically reduced (5% instead of 60%) when stripping was used. As the dissociation patterns were independent of the degree of saturation of the receptor, the results do not favor the possibility of cooperative effects between binding sites in the 8-9 S ER. After pretreatment of cytosol by charcoal at 28 degrees C for 15 min, the dissociation studied by chase displayed only the slowly dissociating component (t1/2 approximately 65 min). This effect was dependent on temperature and influenced by the ligand bound to 8-9 S ER, being pronounced with estradiol (E2) and absent with [3H]4-hydroxytamoxifen. The slow-dissociating component obtained after charcoal treatment was reconverted to fast-dissociating state by adding dithiothreitol or by incubation with cytosol at 20 degrees C. The charcoal treatment did not change the sedimentation coefficient (approximately 9 S) and the Stokes radius (approximately 7 nm) of the [3H]E2-8-9 S ER, and the slow-dissociating form obtained did not bind to DNA-cellulose either in the presence or absence of molybdate ions. Thus there are likely small but functionally significant changes of structure in the 8-9 S ER which remain in a non-DNA-binding form, whereas the rate of estradiol dissociation is modified.     

High affinity estrogen binding by rabbit liver

Macromolecular binding components for [3H]estradiol-17beta are present to cytosol prepared from rabbit liver. When cytosol from sexually mature male liver was incubated with [3H]estradiol and analyzed for binding on low ionic strength sucrose gradients, two peaks of binding activity were detected. One peak had a sedimentation coefficient of 4--5 S and the other had a sedimentation coefficient of 8--9 S. The two components differed from each other regarding steroid specificity and various physiocochemical parameters. [3H]estradiol binding to the 4--5 S component was not inhibited by estrogens, 5alpha-dihydrotestosterone, progesterone or cortisol. Binding to this component did not appear to be saturable and label was rapidly stripped from it by charcoal. Estradiol binding to the 8--9 S component was estrogen specific, saturable and of high affinity. The specific binder dissociates on high ionic strength sucrose gradients and sediments as a 4--5 S moiety. The specific binding protein has a Kd of 3.05 . 10(-10) M and a dissociation half-time of 33 h and there are 35.2 fmol of binding sites/mg cytosol protein. Estrogen binders are also present in liver cytosol from sexually mature female and sexually immature male rabbits. During prolonged incubation of [3H]estradiol with mature male liver cytosol at 0--5 degrees C polar metabolites of estradiol are produced.     

The effect of ether on formation and dissociation of rat uterine estradiol-receptor complex

The addition of 2% v/v ethyl ether to uterine cytosol incubation mixtures produced a 25% increase in the rat of association of 0 degrees with 3H-estradiol and almost a 3-fold increase in the rate of exchange of estradiol-receptor complex with 3H-estradiol at 20 degrees. Uterine cytosol saturated with non-radioactive estradiol required over 8 hours for complete exchange with 3H-estradiol at 20 degrees while in the presence of 2% ether exchange was complete in 2 hours and revealed about 15% more specific binding sites. The presence of ether in reaction mixtures had no effect on dextran coated charcoal separation on bound from free 3H-estradiol nor on the stability of the receptor on uterine cytosol.     

The formation at 37 C of a nondissociable receptor-estradiol complex

The receptor-estradiol complex formed in rat uterine cytosol when heated at 37 C converts from a dissociable to a nondissociable form. The conversion is best observed in cytosols pretreated with charcoal at 0 C which renders the subsequently formed receptor-estradiol complexes thermostable at 37 C. In the presence of dithiothreitol the heated complex remains dissociable. Tamoxifen does not form nondissociable complexes with the estradiol receptor. It is proposed that the nondissociable form of the receptor complex is a required phase in the mechanism of estradiol action.     

Radiochemical determination of estrogen receptors in cryostat sections of target tissues

A radioreceptor assay on unfixed cryostat sections has been developed. Mounted and dried sections were incubated with radiolabeled estradiol in the absence and presence of an excess of diethylstilbestrol and washed with buffer. Binding of radiolabel to sections was measured by direct liquid scintillation counting. Also protein-bound radioactivity which eluted from the sections was determined with a dextran-coated charcoal assay. Parallel sections were used for histological staining and protein determination. Scatchard analysis showed the presence of specific saturable binding sites for estradiol with dissociation constants in the 0.1-1.5 nM range. It is concluded that these high affinity and limited capacity (type I) binding sites represent estrogen receptors. The ligand-binding activity of section-bound estrogen receptors did not decrease upon dry storage up to 20 h at 4 or 23 degrees C prior to assay. During aqueous incubation a significant amount of receptor, representing about 40-60% of the total tissue content, elutes from the sections. Steroid specificity was proven by incubation with excess androgen, progestogen or corticoid instead of diethylstilbestrol or estradiol. With these ligands no significant competition was found. Tissue specificity was demonstrated by a very low level of specific estradiol binding to cryostat sections of rat skeletal muscle, spleen and intestine and by a moderate level in rat liver.     

Mouse lymphotoxin.

The addition of PHA to C3H mouse spleen cells in tissue culture led to the production of lymphotoxin (LT). Cytotoxicity was assayed by addition of the culture fluids to syngeneic target cells labeled with tritiated thymidine; after an incubation period of 72 hr the amount of radioactivity released into the supernatant was measured. The LT activity in unfractionated culture fluids survived lyophilization, remained unchanged for many weeks at 4 degrees C, and progressively decreased on heating at 56 degrees C for periods from 1 to 9 hr. Based on the G-200 Sephadex distribution coefficients for several preparations, the m.w. of mouse lymphotoxin was about 41,000 daltons. Lymphotoxin from three different spleen cell production runs was recovered from isoelectric focusing columns in sharply focused peaks, the pH of which ranged from 4.4 to 4.8.     

Rat ovary glucocorticoid receptor: Identification and characterization

A soluble, thermolabile protein with characteristics typical of glucocorticoid receptors has been identified in the ovaries of estrogenstimulated hypophysectomized immature rats. After the incubation of ³H-dexamethasone with ovarian cytosol, fractionation on a Sephadex G-200 column reveals a peak of radioactivity which elutes at the void volume. This peak, which represents saturable ³H-dexamethasone binding, disappears following heating (4 ° C × 15 min) or treatment of the cytosol with pronase. Scatchard analysis of the ³H-dexamethasone binding to cytosol shows it to be high affinity (Kd=5.1 nM) and saturable, with 327 fmol binding sites/mg cytosol protein. Binding site number rises linearly with increasing cytosol protein concentrations. The relative abilities of various steroids to inhibit ³H-dexamethasone binding are: triamcinolone acetonide ≥ dexamethasone > cortisol = progesterone > dihydrotestosterone > estradiol. This binding protein sediments at 9 S on a sucrose gradient, has a mean Stokes radius of 105 Å on gel exclusion chromatography, and has a calculated molecular weight of 388, 000 daltons and a frictional ratio of 2.1. ³H-Dexamethasone is not metabolized and does not bind specifically to serum. We have identified a protein in the rat ovary with characteristics of a glucocorticoid receptor and propose that this protein may be responsible for mediating direct effects of glucocorticoids on the ovary.     

Prostatic binding protein. A steriod-binding protein secreted by rat prostate.

Rat prostatic cytosol contains a high concentration of a prostatic binding protein with peculiar steroid-binding properties. Indeed, in spite of a relatively low affinity, charcoal adsorption can be used for its measurement. Furthermore, the binding is not specific for particular steroids and increases very strongly after delipidation. In delipidated cytosol the concentration of the binding site is 3.1 micronmol/g protein and the apparent affinity for pregenolone 1.7 X 10(6) M-1. The high concentration of prostatic binding protein in prostatic fluid shows that this substance is secreted by the prostate. Prostatic binding protein has the following physicochemical characteristics: it is precipitated by ammonium sulfate between 50 and 70% saturation; the elution position from a Sephadex G-100 column corresponds to a molecular weight of 51000; it sediments in sucrose density gradients at 3.7 S and is eluted from DEAE-cellulose columns at about 0.25 M KCl. On polyacrylamide gel electrophoresis the binding activity coincides with the major cytosolic protein band. This band has the same mobility as serum albumin in 7% gels, but a higher mobility in more concentrated gels.     

The use of dextran-coated charcoal for kinetic measurements: Interaction between rifampicin and DNA-dependent RNA polymerase ofEscherichia coli

Rifampicin inhibits bacterial DNA-dependent RNA polymerase by forming a 1:1 complex with the enzyme. In previous studies the extent of this binding was determined by chromatographic isolation of the complex on Sephadex columns with¹⁴C-labeled rifampicin as tracer. To measure the kinetics of the enzyme-antibiotic interaction, however, this procedure is too slow and laborious. In this paper we describe the use of dextran-coated charcoal, which proved to be ideal for isolating the complex rapidly and quantitatively. The free [¹⁴C]rifampicin is adsorbed on the charcoal and can be removed by centrifugation, whereas the [¹⁴C]rifampicin-enzyme complex remains in the supernatant and can be easily measured. An account is given of the application of this procedure in measuring the dissociation and association kinetics of the RNA polymerase-rifampicin complex.     

Copper and the estradiol receptor

Copper is an essential element in living organisms and it appears to be involved in estrogen action. This study bears on the manner in which the metal may be linked to the mechanism of this action. Divalent copper was found to induce at 37 degrees C a several fold increase in estradiol binding to the receptors in rat uterine cytosols. An endogenous substance present in the uterine cytosol and separated from it by fractionation on a hydroxylapatite column was found to function as a potent inhibitor of the copper effect. This substance has been found so far also in human breast tissue and in some human breast tumors.     

Transformation and phosphorylation of purified molybdate-stabilized chicken oviduct progesterone receptor

The non-transformed, molybdate-stabilized chick oviduct cytosol progesterone receptor was purified approx. 7000-fold using biospecific affinity resin (NADAC-Sepharose), DEAE-Sephacel chromatography and gel filtration on Bio-Gel A-0.5m agarose. The purified preparation contained progesterone receptor which sedimented as a 7.9S molecule, had a Stokes' radius of 7.5 nm, was composed of three major peptides corresponding to Mr 108,000, 90,000 and 79,000. Upon removal of molybdate, the purified [3H]progesterone-receptor complex could be transformed from the 8S form to a 4S form by exposure to 23 degrees C or by an incubation with 10 mM ATP at 0 degrees C. The purified thermally transformed receptor could be adsorbed to columns of ATP-Sepharose. No cytosol factor(s) appeared to be required for the 8S to 4S transformation of purified receptor or for its subsequent binding to ATP-Sepharose. Incubation of purified non-transformed receptor preparation with [gamma-32P]ATP and cAMP-dependent protein kinase led to incorporation of radioactivity in all the three major peptides at serine residues. The results of this study show for the first time that purified 8S progesterone receptor can be phosphorylated in vitro by a cAMP-dependent protein kinase, and that it can be transformed to a 4S form by 0 degrees C incubation with 10 mM ATP.     

Bis(L-cysteinato)gold(I): chemical characterization and identification in renal cortical cytoplasm.

L-Cysteinatogold(I) was prepared by the reaction of L-cysteine with KAuBr4 in acidic media and its solubility determined from pH 4 to 10. The solubility at pH 7.4 and 37 degrees C is 1 microM. In the presence of excess cysteine, the solubility increases because of formation of bis(L-cysteinato)gold(I). The equilibrium-constant for formation of the bis complex is 2.1 +/- 0.4 X 10(-3), which at pH 7.4 CORRESPONDs to an apparant formation constant of 4.4 X10(4). The formation of the bis adduct was confirmed by chromatographic separation of the products of the reaction between [35S]-L-cysteine and Na2AuTM. This complex elutes with Kav = 1.15 which allows it to be distinguished from other gold thiolates that might form in vivo. The bis(cysteinato)gold(I) complex is shown to be present in kidney cytosol isolated from rats given Na2AuTM in vivo. When additional cysteine is added to the cytosol in vitro, the peak at 1.15 is increased, but if glutathione is added, the low molecular weight gold elutes at Kav = 1.00, which is taken as evidence for the existence of bis(cysteinato)gold(I) in the cytosol preparation. The amount of gold present as bis(cysteinato)gold(I) after 4 different dose schedules has been measured and found to increase with the total cytosol gold concentration. L-Cysteinatogold(I) does not dissolve in the presence of bovine serum albumin to form an adduct.     

Nuclear uptake of oestradiol-17 beta in human mammary tumour tissue.

An in vitro study of the nuclear uptake of estradiol 17 beta (E2) in mammary tumor tissue utilized 16 specimens taken at mastectomy. Dextran/charcoal assay of cytosol receptor was used in this tissue slice technique, based on uptake of tritiated E2. 9 tumors had receptor concentrations from 7.3-496 fmol/mg of cytosol protein. No nuclear uptake was detected in 4 of these tumors, in spite of the fact that 1 of these had the highest concentration of cytosol receptor measured. The remaining 7 tumors contained no cytosol receptor and showed no detectable nuclear uptake of E2. 3 cases yielded protein-bound radioactivity in the column eluate (Sephadex) sufficient to allow sucrose gradient analysis. The major radioactive peak of 1 of these moved slightly faster than bovine serum albumin, i.e., in the 5S region charactersitic of the nuclear receptor found in other estrogen-sensitive tissues. It is conclded that hormone independency in mammary tumors containing E2 cytosol receptor may be caused by failure of translocation or binding of E2-receptor complex to the cell nucleus.     

Purification of monomeric agmatine iminohydrolase from soybean

Agmatine iminohydrolase (EC 3.5.3.12) was purified to homogeneity from the cytosol of soybean (Glycine max) axes by chromatographic separations on Sephadex G-25, Bio-rex 70, and agmatine-affinity columns. The enzyme was homogeneous by the criteria of analytical gel electrophoresis. Molecular weights estimated by Sephadex G-100 gel and sodium dodecyl sulfate polyacrylamide gel electrophoresis were 70,000, indicating that the soybean axes enzyme is a monomer, in contrast to the dimeric enzymes from corn and rice. The isoelectric point determined by gel electrofocusing was 7.5, higher than that of the corn enzyme (4.7). The optimal pH and temperature for activity were 6.5 and 50 degrees C, respectively. The enzyme has high specificity for agmatine, and the Km for agmatine was 2.5 x 10(-3) molar. The enzyme was sensitive to Cu2+ and also was inhibited by p-hydroxymercuribenzoate.     

Reduction and activity of cytochrome c in the cytochrome c-cytochrome aa3 complex.

An interaction between rat liver glucocorticoid--receptor complex and immobilized ATP was identified. Rat liver cytosol preparations were incubated with [3H]triamcinolone acetonide for 4 h at 4 degrees C and partially purified by precipitation with (NH4)2SO4 before use. The resulting glucocorticoid--receptor complex could be selectively adsorbed on to columns of ATP--Sepharose. The freshly prepared cytosol [3H]triamcinolone acetonide--receptor complex had very little affinity for binding to the ATP--Sepharose column, but acquired this ability on temperature- or salt-activation. The presence of 10 mM-sodium molybdate during this salt- or temperature-dependent activation blocked the binding of the receptor complex to ATP--Sepharose. The interaction is reversible, since it can be disrupted by high-salt conditions. A competitive binding assay, using free nucleotides in samples to be chromatographed, revealed a preferential interaction between ATP and the glucocorticoid--receptor complex. Buffer containing ATP was also used to elute the glucocorticoid--receptor complex from ATP--Sepharose columns successfully. When ATP was added to the preparations containing [3H]triamcinolone acetonide--receptor complexes, the steroid specificity or sedimentation properties of the complex remained unaltered. Our results demonstrate an interaction between rat liver glucocorticoid--receptor complex and immobilized ATP and suggest a role of this nucleotide in receptor function.     

Physicochemical factors affecting ethanol adsorption by activated carbon

Powder and granular activated charcoal were evaluated for ethanol adsorptivity from aqueous mixtures using an adsorption isotherm. Ethanol adsorption capacity was more pronounced at 25 degrees C as compared to 5, 15, and 40 degrees C. When pH of the ethanol-buffer mixture (0.09 ionic strength) was changed from acidic (2.3) to neutral and then to alkaline (11.2), ethanol adsorption was decreased. Increasing ionic strength of the ethanol-buffer mixtures from 0.05 to 0.09 enhanced ethanol adsorption but a further increase to 0.14 showed no significant effect. Ethanol adsorption was more efficient from an aqueous ethanol mixture as compared to semidefined and nondefined fermentation worts, respectively. Heating granular charcoal to 400 degrees C for 1 h and 600 degrees C for 3 h in N(2) increased ethanol adsorptivity and heating to 1000 degrees C (1 h) in CO(2) decreased it when ethanol was removed from dilute solutions by simple pass adsorption in a carbon packed column. Granular charcoal was superior to powdered charcoal and an inverse relationship was noted between the weight of the granular carbon bed in the column and ethanol adsorbed/g carbon. Decreasing the column feed flow rate from 7.5 to 2.0 L aqueous ethanol/min increased the adsorption rate.     

Effector controlling accumulation of N-acetylglucosaminidase during development of Dictyostelium discoideum

The accumulation of N-acetylglucosaminidase, an early developmentally regulated enzyme in Dictyostelium discoideum, is dependent upon the action of a heat-stable effector molecule secreted by the cells. Stimulation of enzyme accumulation is inhibited by cycloheximide and actinomycin, suggesting that it requires concomitant RNA and protein synthesis. The effector elutes from Sephadex columns as a molecule of 300 to 1000 daltons. It is stable to treatment with a variety of proteolytic enzymes and mild acid hydrolysis but can be inactivated by prolonged acid hydrolysis.