The mouse salivary androgen-binding protein (ABP) alpha subunit closely resembles chain 1 of the cat allergen Fel dI

Androgen-binding protein (ABP) is found in the salivas of a wide variety of rodents and it has been proposed that ABP functions in sex and/or subspecies recognition (Karn and Dlouhy,J. Hered. 82, 453, 1991). This is a report of significant identity between the alpha subunit of mouse salivary ABP and Chain 1 of cat allergen Fel dI (50% identity), as well as with two other proteins that share identity with Chain 1 of Fel dI, rabbit uteroglobin (27% identity with ABP alpha) and human lung Clara 10 (27% identity with ABP alpha). The secondary structure predicted for the mouse ABP alpha subunit is a very good fit with the secondary structure determined by X-ray crystallography for rabbit uteroglobin, a protein that shares with mouse ABP the capability of binding steroid. Fel dI is found in cat saliva, sebaceous glands, and pelt. Its function is not known but it has been proposed to be involved in protecting dry epithelia, a parallel to uteroglobin protecting wet epithelia. Since mice, like cats, lick themselves and each other extensively, coating their pelts with ABP may be part of this or another biological function.     

A recognition system for sex-hormone-binding protein-estradiol complex in human decidual endometrium plasma membranes

We have studied the specific binding of human serum sex-hormone-binding protein and its complexes with estradiol and testosterone to an enriched membrane fraction isolated from human decidual endometrium. The specific binding of sex-hormone-binding protein to these membranes has been found to be dependent on it being bound with estradiol. When estradiol concentration in the medium is high enough to provide for the saturation of sex-hormone-binding protein with the steroid, the protein exhibits specific binding to the membranes with an apparent equilibrium constant, Kd = (3.5 +/- 2.0) X 10(-12) M. In the absence of estradiol, the binding protein devoid of steroid or complexed with testosterone does not interact with the membranes. At low concentrations of sex-hormone-binding protein and estradiol, when their complex is almost completely dissociated in solution, it can be reconstituted on the membranes with the optimum estradiol to binding protein ratio being 1:1 (mol/mol). It is proposed that, in plasma membranes of the estradiol target cells, there is a recognition system for the sex-hormone-binding protein-estradiol complex which may allow these cells to take up from blood not only free estradiol, but also estradiol complexed with the binding protein.     

A recognition system for sex-hormone-binding protein-estradiol complex in human decidual endometrium plasma membranes

We have studied the specific binding of human serum sex-hormone-binding protein and its complexes with estradiol and testosterone to an enriched membrane fraction isolated from human decidual endometrium. The specific binding of sex-hormone-binding protein to these membranes has been found to be dependent on it being bound with estradiol. When estradiol concentration in the medium is high enough to provide for the saturation of sex-hormone-binding protein with the steroid, the protein exhibits specific binding to the membranes with an apparent equilibrium constant, K_d = (3.5 ± 2.0) · 10⁻¹² M. In the absence of estradiol, the binding protein devoid of steroid or complexed with testosterone does not interact with the membranes. At low concentrations of sex-hormone-binding protein and estradiol, when their complex is almost completely dissociated in solution, it can be reconstituted on the membranes with the optimum estradiol to binding protein ratio being 1:1 (mol/mol). It is proposed that, in plasma membranes of the estradiol target cells, there is a recognition system for the sex-hormone-binding protein-estradiol complex which may allow these cells to take up from blood not only free estradiol, but also estradiol complexed with the binding protein.     

Comparison of rabbit androgen binding protein with testosterone estradiol binding globulin--I. Physical and chemical properties

Rabbit epididymal androgen binding protein (rbABP) and serum testosterone estradiol binding globulin (rbTeBG) were purified and their physicochemical properties compared. Both proteins bound dihydrotestosterone (DHT) with high affinity. Both contained two components, Heavy (H) and Light (L), and their molecular weights and pI values were comparable. rbABP and rbTeBG were different with regard to their ConA-Sepharose binding property. rbABP was not bound by ConA-Sepharose while rbTeBG was found and retained by this lectin; thus, rbABP and rbTeBG differed in their carbohydrate structure. Peptide mapping on SDS-PAGE indicated that the H components of rbABP and rbTeBG were distinct even though they showed a high degree of homology. By contrast, the L components of these two proteins appeared to be identical. The structure of the steroid binding sites of these two proteins was analyzed by peptide mapping of [1,2(3)H]17 beta hydroxy-androsta-4,6-dien-3-one photoaffinity labeled protein. The size distribution of radioactive peptide fragments generated appeared to be identical for these two proteins. However, the distribution of labeled peptides was slightly different when examined by high pressure liquid chromatography (HPLC). The observations suggest that the differences between rbABP and rbTeBG might reside not only in carbohydrate moieties but also in their amino acid sequences.     

Identification of an estrogen-binding protein in Pseudomonas aeruginosa.

A constitutive estrogen-binding protein (EBP) has been identified in the cytosol of Pseudomonas aeruginosa, a Gram-negative bacterium. All 14 strains tested contained the EBP. Estradiol binding was rapid and maximal binding occurred by 90 min at 0 degrees C. Dissociation of estradiol from the binding protein occurred at a rate of 4.6 fmol/min with a t1/2 of 42 min. EBP binding was destroyed by protease treatment and at high temperature. Sodium molybdate had no effect on binding. The Kd determined by Scatchard analysis was 3.9 nM and the Bmax was 323 fmol/mg protein. The EBP sedimented at 8.9 S on sucrose density gradients. The presence of 0.4 M KCl increased estradiol binding 6-fold but did not cause a shift in the sedimentation value. Gel filtration of the native protein gave an estimated molecular weight of 215,000 and a Stokes radius of 50.2 A. Steroid binding specificity, in order of decreasing affinity, was estradiol, estrone, dihydrotestosterone, estriol, testosterone, progesterone and promegestone. Other steroid hormones tested did not compete for estradiol binding. Identification of an EBP in a bacterium allows a comparative analysis of other steroid-binding proteins in unicellular microorganisms.     

Regulation and ligand-binding specificities of two sex-specific bile acid-binding proteins of rat liver cytosol

Rat liver cytosolic proteins were photoaffinity labeled with the synthetic steroid [3H]methyltrienolone in order to identify and characterize hepatic proteins that may participate in the intracellular binding and transport of steroid hormones and other sterols. A male-specific and a female-specific sterol-binding protein (SBP) that migrated to the 4 S region of a sucrose gradient and had similar molecular weights (male-specific 34-kDa protein (SBP34), female-specific 31-kDa protein (SBP31] were thus identified. Experiments were undertaken to determine the biochemical basis for the sex-specific expression of these two proteins. In vivo hormonal manipulations established that the female-specific expression of SBP31 could, in part, be accounted for by the suppressive effects of androgen on SBP31 levels in male rats. In contrast, androgen stimulated expression of the male-specific SBP34, while estrogen and the estrogen-regulated continuous plasma growth hormone profile that is characteristic of adult female rats were suppressive toward this protein. Unlike several other androgen-dependent hepatic proteins, however, SBP34 did not require an intact pituitary for androgen-stimulated expression, nor was its expression stimulated by the intermittent pulses of plasma growth hormone that are characteristic of adult male rats. SBP34 and SBP31 were not induced but were suppressed to various extents by dexamethasone, phenobarbital, and clofibrate, drugs that are known to induce other hepatic proteins involved in steroid binding and metabolism. Competition experiments revealed that SBP31 has a relatively broad ligand specificity, with significant competition for [3H]methyltrienolone binding exhibited by bile acids (chenodeoxycholic acid and lithocholic acid) and a range of steroid hormones (progesterone, estradiol, testosterone, and 5 alpha-dihydrotestosterone) when present in the low micromolar range. No binding was detected with this protein toward cholesterol, triamcinolone acetonide, 5 alpha-androstan-3 alpha,17 beta-diol, cholic acid, and deoxycholic acid. In contrast, SBP34 exhibited greater binding specificity, with competition for [3H]methyltrienolone binding observed only with primary bile acids (cholic acid and chenodeoxycholic acid) and their metabolites (deoxycholic acid and lithocholic acid). On the basis of these binding specificities and the relatively high concentration of bile acids found in the liver, it is proposed that SBP31 and SBP34 function in the intracellular binding and/or transport of bile acids.     

The amino acid sequence of the alpha subunit of mouse salivary androgen-binding protein (ABP), with a comparison to the partial sequence of the beta subunit and to other ligand-binding proteins

It has been suggested that three distinct genes,Abpa, Abpb, andAbpg, determine the three subunits of mouse salivary androgen-binding protein (ABP) (Dlouhy, S. R.,et al., Genetics 115, 535, 1987). We report the putative amino acid sequence of the subunit common to all forms of ABP, the Alpha subunit, and the partial amino acid sequence of the Beta subunit. These sequences have little in common, supporting the notion of at least two distinct genes coding for the subunits of the most common form of salivary ABP, the A:B dimer. A search of GenBank showed that these sequences have not been reported previously. The Beta subunit shows significant homology with helospectin, a member of the glucagon superfamily, but not enough homology to assign it to the family. No homology exists between ABP subunits and members of the ligand-binding carrier family of proteins nor does ABP show homology with other androgen-binding proteins. Particularly interesting is the observation that there is no relationship to rat prostatic steroid binding protein (PBP), given the similarities in protein tertiary structure, the numbers of subunits and their genes, and the earlier observation of ABP cross-reactive material in mouse prostate.Partial support for this work was provided by a PHS AREA award and by the Butler Academic Grants program. Both sources of support are greatly appreciated.A portion of this work constituted partial fulfillment of the honors thesis requirement for Butler University.     

Interaction of non-histone proteins with DNA and chromatin from Drosophila and mouse cells. Specificity, isolation and analysis of complexes.

The specificity of the binding of purified non-histone proteins to DNA has been investigated through two types of experiments. Using a nitrocellulose filter assay at a low protein/DNA ratio, the binding of mouse non-histone proteins to mouse DNA was twice as great as the binding of mouse non histone protein to Drosophila DNA. The reverse experiment using Drosophila non-histone protein confirmed the interpretation that some protein . DNA complexes were specific. Protein . DNA complexes isolated by gel filtration chromatography indicated that 20% or 10% of the non-histone protein was bound to homologous or heterologous DNA respectively. Purified non-histone proteins bound with lower efficiency (15%) than unpurified but with higher specificity to soluble chromatin than to naked DNA. This binding did not result from an exchange between chromatin non-histone proteins and purified non-histone proteins added in excess. DNA-bound and chromatin-bound proteins were analysed on polyacrylamide gels. Whereas no major qualitative differences were observed with DNA-bound proteins, some proteins bound to homologous mouse chromatin were different from those bound to heterologous Drosophila chromatin. These results suggest a possible role of DNA-bound non-histone proteins in the regulation of gene expression.     

Reversible interaction between androgen binding protein and testicular macromolecules causing inhibition of androgen binding activity.

Sertoli cells in culture isolated from immature rat testes secrete androgen binding protein (ABP) in the culture medium. Binding activity of ABP in concentrated medium was estimated with equilibrium dialysis against 1 nM dihydrotestosterone at 4 degrees C. The ABP protein activity was inhibited approximately 50% through addition of cytosol preparations from testis or liver, but not from brain tissue, to the concentrated culture medium; this inhibition remained constant for at least two days. The inhibitor is probably a macromolecule, because the activity could not be removed by charcoal treatment and dialysis. The percent inhibition of ABP binding activity was increased when increasing amounts of cytosol were added, it decreased in the presence of increased concentrations of androgens, but it was not influenced by variations of the concentration of ABP. Inhibition of androgen binding to ABP by cytosols in the presence of 1 nM testosterone could be reversed after dialysis in the presence of 10 nM testosterone. These results suggest a reversible competition between testosterone and the testicular macromolecule for ABP. The occurrence of this interaction between ABP and a testicular macromolecule can explain the variable results of estimated ABP binding activity in testis cytosol preparations.     

Characterization of an androgen binding protein (ABP) in rat testis and epididymis

An androgen binding protein (ABP) was demonstrated in the 105,000 g supernatant of rat testis homogenate after charcoal extraction of endogenous steroids. Testis ABP proved to be identical to an ABP previously described in rat epididymis. It contained saturable high-affinity sites which exhibited binding specificity for dihydrotestosterone (6) and testosterone when measured by polyacrylamide gel electrophoresis or by competitive binding using charcoal adsorption. Binding to ABP was not affected by ribonuclease or neuraminidase but was decreased by the disulfide reducing agent, dithiothreitol and the sulfhydryl reagent, N-ethylmaleimide. Binding was abolished by treatment with proteolytic enzyme. The mean molecular radius of ABP was 2.92 nm as determined by the retardation of electrophoretic mobility in polyacrylamide gels of decreasing pore size. Assuming a partial specific volume of 0.66–0.74 the molecular weight was 86,000–91,000 for a spherical molecule. ABP binding was stable after treating at 45° C for 20 min. but was destroyed at 60° C. Binding was maximal between pH 7.5 and 9.0 and decreased at pH below 7.0.     

Effects of transdermal application of 7-oxo-DHEA on the levels of steroid hormones, gonadotropins and lipids in healthy men

The aim of this study was to investigate the effect of 7-oxo-DHEA (dehydroepiandrosterone) on the serum levels of steroid sexual hormones, gonadotropins, lipids and lipoproteins in men. 7-oxo-DHEA was applied onto the skin as a gel to 10 volunteers aged 27 to 72 years for 5 consecutive days. The single dose contained 25 mg 7-oxo-DHEA. Serum concentrations of testosterone, estradiol, cortisol, androstenedione, luteinizing hormone (LH), follicle-stimulating hormone (FSH), sex hormone binding globulin (SHBG), total cholesterol, HDL- and LDL-cholesterol, triglycerides, apolipoprotein A-I and B and lipoprotein(a) were measured before the beginning and shortly after the end of the steroid application. After the treatment, we noted the following significant changes: a decline of testosterone and estradiol levels, increase of LH, HDL-cholesterol and apolipoprotein A-I levels. The decrease of total cholesterol levels was of the borderline significance. A slight but significant increase was found in apolipoprotein B and lipoprotein(a). The most expressive was the fall of the atherogenic index. We suggest that the gel containing 7-oxo-DHEA might be a suitable drug for improving the composition of the steroid and lipid parameters in elderly men.     

Photoaffinity Labeling with Progesterone-11α-Hemisuccinate-(2-[125I]Iodohistamine) Identifies Four Protein Bands in Mouse Brain Membranes

Abstract: The radiolabeled progesterone (PG) analogue progesterone-11α-hemisuccinate-(2-[¹²⁵I]iodohistamine) was used to label PG binding proteins in brain membranes from mouse cerebellum. Photoaffinity labeling and sodium dodecyl sulfate-polyacrylamide gel electrophoresis identified specific PG binding protein bands 1–4 of 64−29 kDa. Bands 1 and 4 were well resolved on the gel and easily quantified. Preincubation with PG inhibited photolabeling in a dose-dependent manner. The labeling was specific with respect to steroid structure. For band 1, the extent of inhibition of labeling by PG and 3α,5α-pregnanolone (3α) was pronounced. Other steroids such as testosterone (Tes), estradiol (Est), and corticosterone (Cor) were less effective, whereas pregnenolone sulfate (PS) and cholesterol (Cho) were ineffective. With respect to band 4, Est was the most effective; PG, 3α, and Tes were intermediate; and PS, Cho, and Cor were ineffective. The results describe specific membrane proteins that bind PG (band 1) and Est (band 4).     

In vitro evolution of the binding specificity of neocarzinostatin,an enediyne-binding chromoprotein

Neocarzinostatin is the most studied member of the enediyne-chromoprotein family, and is clinically used as an antitumoral agent. Neocarzinostatin could be a promising drug delivery vehicle if new binding specificities could be conferred to its protein scaffold. We used in vitro evolution methods to demonstrate that this approach is feasible. We created large libraries containing between 1.7 x 10(8) and 1.4 x 10(9) independent clones, where up to 13 side chains pointing toward the binding crevice were randomly substituted. We then used phage display to select variants that bind to a model ligand (testosterone) which is unrelated to the natural ligand of neocarzinostatin. Several different binders were selected from each library. The corresponding proteins were expressed in Escherichia coli and their affinities and specificities were characterized in detail. K(D) values of about 20 nM were obtained for streptavidin-bound testosterone. The K(D) of selected proteins for free soluble testosterone are between 7 and 55 microM and therefore higher than the K(D) for streptavidin-bound testosterone. The spacer and streptavidin used during selection contributed to the high affinity of the selected binders for the target. Binding studies of 15 different steroids related to testosterone allowed us to determine that C3, 4, 5, 6, and 7 on cycles A and B and the conjugated 3 oxo group of the steroid molecule were essential for molecular recognition. Other testosterone analogues substituted on C1, 2, 9, 11, 15, and 17 were not discriminated from testosterone. These results demonstrate that the binding specificity of this protein family can be extended to compounds that are completely unrelated to the natural enediyne chromophore family. This type of highly expressed, stable proteins with tailored binding properties have a wide potential range of applications.     

Binding characteristics of [3H]delta(5)-androstene-3beta,17beta-diol to a nuclear protein in the rabbit vagina

In this study, we investigated the binding characteristics of [3H]Delta(5)-androstene-3beta,17beta-diol to rabbit vaginal cytosolic and nuclear extracts and in freshly excised intact tissue strips. [3H]delta(5)-Androstene-3beta,17beta-diol bound to a protein(s) in the vaginal nuclear extract with high affinity (K(d)=3-5 nM) and limited capacity (50-100 fmol/mg protein). No specific binding was detected in the cytoplasmic extracts. Competitive binding studies showed that binding of [3H]delta(5)-androstene-3beta,17beta-diol was effectively displaced with unlabeled delta(5)-androstene-3beta,17beta-diol but not with dehydroepiandrosterone, testosterone, dihydrotestosterone, triamcinolone acetonide, or progesterone. However, estradiol at high concentrations partially displaced bound [3H]delta(5)-androstene-3beta,17beta-diol. Incubation of freshly excised vaginal tissue strips with [3H]delta(5)-androstene-3beta,17beta-diol in the absence or presence of excess unlabeled delta(5)-androstene-3beta,17beta-diol for 1h at 37 degrees C resulted in specific binding to a soluble macromolecule in the nuclear KCl extracts. In addition, quantitative measurement of estrogen receptor, androgen receptor and delta(5)-androstene-3beta,17beta-diol binding protein was performed by equilibrium ligand binding assays using extracts of distal vaginal tissue from intact animals or ovariectomized animals treated for 2 weeks with vehicle, estradiol, testosterone, or estradiol plus testosterone. These changes in steroid hormone levels resulted in opposing trends between the estrogen receptor and delta(5)-androstene-3beta,17beta-diol binding protein, suggesting that delta(5)-androstene-3beta,17beta-diol binding protein is regulated differently by the hormonal milieu than the estrogen receptor. These data suggest that rabbit vaginal tissue expresses a novel binding protein which specifically binds delta(5)-androstene-3beta,17beta-diol and is distinct from the androgen and estrogen receptors.     

Correlation between PAP-dependent steroid binding activity and substrate specificity of mouse and human estrogen sulfotransferases

Estrogen sulfotransferase (EST) is a cytosolic enzyme that catalyzes the sulfoconjugation and inactivation of estrogens using 3'-phosphoadenosine-5'-phosphosulfate (PAPS) as an activated sulfate donor. A finding of undetermined significance in the study of EST has been that the guinea pig EST is able to bind pregnenolone and estradiol with high affinity in the presence of PAP, the reaction by-product of the sulfate donor PAPS. This finding has raised the possibility that EST may have other physiological functions independent of its enzymatic activity as a sulfotransferase. To determine if the PAP-dependent steroid binding activity is a common property shared by other estrogen sulfotransferases, we have expressed the mouse and human EST in bacteria and used the purified protein to address this question. We found that, in the presence of PAP, both recombinant mouse and human EST were able to bind estradiol with high affinity but only the human EST was able to bind pregnenolone. In addition, we show that human but not the mouse EST was also able to bind dehydroepiandrosterone, a property that was not described for the guinea pig EST. Furthermore, we demonstrate that the promiscuity of human EST in steroid binding is mirrored by a correspondingly low substrate specificity in its enzymatic activity as a sulfotransferase. Reversely, the lack of stable binding of pregnenolone and dehydroepiandrosterone by the mouse EST is paralleled by a lack of sulfotransferase activity of this enzyme toward these two steroids. Mutagenesis of mouse EST within a domain critical for PAPS binding abolished both its sulfotransferase and PAP-dependent estrogen binding activity. These data suggest that stable binding of steroids such as pregnenolone or estrogen is not an independent property of estrogen sulfotransferases but rather is related to their catalytic activity.     

Interaction of sex steroids with proteins from the soluble fraction of swine and cattle liver (a preliminary analysis)]

The interactions of [3H]estradiol, [3H]testosterone and [3H]progesterone with soluble proteins from porcine and calf liver were studied. The specific binding of [3H]progesterone and [3H]testosterone in calf liver cytosol seems to be due to serum transcortin or its intracellular precursor (analog). Contrariwise, the specific binding of [3H]progesterone observed in porcine liver cytosol was absent in the serum. This binding was characterized by slow association and dissociation dynamics, moderate affinity for the [3H]-ligand and a high binding capacity. The structural determinants of the ligands were studied by competitive inhibition of the [3H]-ligand binding. The delta 4-3-keto group in the steroid A-ring was found to be the most important determinant. An intensive metabolism of [3H]progesterone was observed during its incubation with cytosol (data from thin-layer chromatography). A 3H-metabolite (presumably, 20 beta-dihydroprogesterone) was predominant in the bound ligand fraction. The data obtained suggest that proteins of a steromodulin type are widely distributed in the mammalian liver.     

A specific glucocorticoid binding macromolecule of rabbit uterine cytosol

A high affinity (K_d=2.7 × 10^?10M at 0°) dexamethasone binding macro-molecule has been identified in the cytosol fraction of rabbit uteri. Competition studies show high specificity for glucocorticoids since binding of labeled dexamethasone is inhibited by cortisol and corticosterone but not by progesterone, testosterone, or estradiol 17β. The binding component has a sedimentation coefficient of 8S and its concentration in uterine cytosol is about 0.2 pmoles per mg protein. Uptake of labeled dexamethasone by isolated uterine nuclei requires the presence of cytosol and is temperature dependent. The KCl-extractable nuclear complex sediments at 4S. Thus the dexamethasone binding components of the rabbit uterus have properties similar to those described for steroid hormone receptors present in target tissues. Specific dexamethasone binding could not be demonstrated in rat uterine cytosol.     

An androgen binding protein in the testis cytosol fraction of adult rats. Comparison with the androgen binding protein in the epididymis

The cytosol fraction of rat testicular homogenates contained a specific androgen binding protein (t-ABP), indistinguishable from, the androgen binding protean in. the epididymis(e-ABP) in terms of its chromatographic behaviour by gel filtration, sedimentation rate, mobility on polyacrylamide electrophoresis and steroid specificity(5α-diaydrotestosterone(DHT) > testosterone > estradiol-17β > parogesterone and estradiol-17α).The stability of t-ABP as well was similar to that of e-ABP. The aBP-DHT complexes were stable between pH 6.5–10, exhibiting the highest degree of binding between pH 8–9. The binding activity persisted after heating at 50°C for 30 min., whereas heating at 60°C for 30 min. completely destroyed the binding. DHT did not significantly increase the stability towards pH and temperature denaturation. Binding activity was not reduced by 1 mM p-chloro-mercuri-phenyl-sulphonate (PCMPS), whereas similar treatment with 1 nM N-ethyl-maleimide(NEM) or 1 mM Ellman's reagent reduced it by some 10–50 per cent. Exposure to 10 mM β-mercaptoethanol(βME) reduced the binding by 60–70 per cent. These studies strongly indicate that t-ABP and e-ABP are identical proteins.Hemicastration for 4 weeks eliminated the ABP from the epididymal cytosol fraction on the castrated side, indicating that this protein is produced by the testis.     

A male specific hepatic estrogen binding protein: characteristics and binding properties

Mammalian liver is a sex-steroid responsive tissue in that androgen and estrogen receptors are present and mediate differential hepatic hormonal effects. Further, we and others have found a sexual dimorphism in the hepatic cytosolic content of estrogen binding proteins. In addition to the estrogen receptor, the male has a high-capacity (12.0-15.0 pmol/mg protein) estrogen binding protein (MEB) which demonstrates a moderate affinity for estradiol (Kd = 31.0-43.2 nM) if estradiol metabolizing enzymes are first precipitated with protamine sulfate. This protein exhibits a unique specificity for steroidal estrogens: 2-methoxyestriol greater than estradiol greater than estriol = 2-methoxyestradiol greater than 2-hydroxyestradiol greater than estrone greater than 2-methoxyestrone greater than estriol 3-glucuronide greater than 2-hydroxyestrone = 3-methoxyestriol greater than androstanediol greater than dihydrotestosterone greater than testosterone. Other androgens such as androstenedione and methyltrienolone, nonsteroidal estrogens such as diethylstilbestrol, and the antiestrogens tamoxifen and 4-hydroxytamoxifen do not compete for [3H]estradiol ([3H]E2) binding. MEB is a relatively small-molecular-weight protein with a Sr of 20.4 A as determined by gel filtration on Sephadex G-100. The kinetics of [3H]E2 association and dissociation at 4 degrees C are very rapid, with t1/2 values of less than 5 s. Sodium molybdate, generally used to stabilize steroid receptors, inhibits MEB-[3H]estradiol binding activity in cytosol in a time- and dose-dependent manner, an effect not observed with partially purified MEB. Magnesium chloride inhibits binding activity of the Sephadex G-100 MEB pool, an effect reversed by EDTA. Other divalent cations also inhibit binding: Mn2+ greater than Mg2+ greater than Ca2+. Furthermore, EDTA complexes of these cations slightly enhance binding relative to EDTA alone: Ca2+ EDTA greater than Mg2+ EDTA greater than Mn2+ EDTA. These results demonstrate that MEB is a unique sex-steroid binding protein, albeit of unknown function, which is distinct from hepatic steroid receptors.     

Steroid induction of low-affinity glucocorticoid binding sites in rat liver microsomes

Rat liver contains two glucocorticoid binding sites: the high-affinity or glucocorticoid receptor (GR) and the low-affinity glucocorticoid binding sites, or LAGS. The Kd of LAGS predicts that they can be half-saturated by plasma corticosteroids in some physiological circumstances and, therefore, that they can play relevant roles in the rat liver. [3H]dexamethasone was used as a ligand in exchange assays, to study the relative abundance of GR and LAGS in cell fractions of rat liver. GR were found in the cytosol, but not in the purified nuclei, the mitochondria, or the microsomes. LAGS were found in all the particulate fractions, being more abundant in the smooth-surfaced microsomes, but they were not found in the cytosol. The LAGS of microsomes and purified nuclei showed the same Kd and also the same broad range of steroid competition with [3H]dexamethasone (cortisol = progesterone greater than dexamethasone greater than or equal to corticosterone greater than R5020 greater than DHEA greater than testosterone = estradiol). LAGS were found in liver, placenta and kidney, but not in other GR-containing organs. This suggests that the LAGS could be involved in physiological functions related to the metabolism of steroid hormones. The liver microsome LAGS were undetectable at rat birth, and became present in the 25-day-old rat. The level of LAGS then increased progressively, reaching its maximum level in the 2-3-month-old rats (10 pmol/mg protein), and declining afterwards to reach the adulthood level (5 pmol/mg protein) in 6-month-old rats. LAGS are mainly controlled by the corticoadrenal steroids, which is shown by their dramatic decrease after adrenalectomy, and especially after hypophysectomy. Many steroid hormones, like estradiol, testosterone, and corticosterone (but not progesterone) induce LAGS, estradiol being the most effective. A combination of T4 and corticosterone was more effective in inducing LAGS than when the two hormones were injected separately. It is possible to conclude that rat liver LAGS are mainly microsomal proteins, whose concentration is regulated by a multihormone system under pituitary control.