The release of corticosterone and a corticosterone-binding protein by incubated rat adrenal slices

Stimulation of incubated rat adrenal slices with ACTH(1-24) resulted in an increase in the release of both corticosterone and specific corticosterone-binding protein into the incubation medium. The release of corticosterone and binding protein was dose and calcium dependent with adrenals from animals pretreated with betamethasone. While the secretion of corticosterone was continuous throughout the incubation period, there appeared to be a limit to the increase in binding capacity. The specificity of steroid binding to the adrenal protein showed a similar profile to that of corticosteroid-binding globulin (CBG) in rat serum. A Western blot analysis using anti-rat CBG as the primary antiserum, showed that the adrenal protein was not CBG. [3H]corticosterone binding with disc electrophoresis, run at 2 degrees C, gave a single peak with approximately the same Rf value for rat serum, purified CBG, and adrenal incubate; at 22 degrees C peaks were only seen for rat serum or purified CBG. The data presented provides further evidence for the existence of a specific corticosterone-binding protein of adrenal origin released in conjunction with corticosterone. The adrenal protein would appear to have a lower affinity for corticosterone than does CBG, and to be functionally more labile. It is possible that the adrenal protein may be CBG that has been internalized, modified and released with corticosterone.     

An amino acid substitution in biobreeding rat corticosteroid binding globulin results in reduced steroid binding affinity

BioBreeding (BB) rats are derived from an outbred colony of Wistar rats and are used as a model of autoimmune diabetes mellitus. A corticosteroid binding globulin (CBG) variant with reduced affinity for glucocorticoids has now been found in the blood of these animals. The dissociation rate constants of BB CBG for cortisol (4.42 nM) and corticosterone (1.43 nM) are both about 50% higher than those associated with Wistar CBG, but no obvious difference in the steroid binding specificity of BB and Wistar CBGs was detected. Purified BB and Wistar CBGs exhibit the same size heterogeneity when examined by polyacrylamide gel electrophoresis under denaturing conditions, and the sizes of their respective hepatic mRNAs are identical. The genetic basis for this abnormality was therefore determined by comparing the cDNA sequences for BB and Wistar CBG, and this revealed a point mutation that results in a single amino acid substitution at residue 276 (Ile in BB CBG and Met in Wistar CBG). To confirm that this mutation is responsible for the reduced steroid binding affinity associated with BB CBG, the cDNAs for rat CBG-Ile276 and CBG-Met276 were expressed in Chinese hamster ovary cells. The steroid binding affinities of the CBGs secreted by these cells were essentially identical with those observed in the corresponding serum samples from these two rat strains. The amino acid substitution identified in BB rat CBG therefore clearly accounts for the reduction in its steroid binding affinity, and further analysis of this and other natural CBG variants may reveal important information about the CBG steroid binding site. It is also possible that this mutation may contribute to the etiology of pathological abnormalities that are characteristic of the BB rat.     

The S-to-R transition of corticosteroid-binding globulin and the mechanism of hormone release

Corticosteroids are transported in the blood by a serpin, corticosteroid-binding globulin (CBG), and their normally equilibrated release can be further triggered by the cleavage of the reactive loop of CBG. We report here the crystal structures of cleaved human CBG (cCBG) at 1.8-Å resolution and its complex with cortisol at 2.3-Å resolution. As expected, on cleavage, CBG undergoes the irreversible S-to-R serpin transition, with the cleaved reactive loops being fully incorporated into the central β-sheet. A connecting loop of helix D, which is in a helix-like conformation in native CBG, unwinds and grossly perturbs the hormone binding site following β-sheet expansion in the cCBG structure but shifts away from the binding site by more than 8 Å following the binding of cortisol. Unexpectedly, on cortisol binding, the hormone binding site of cCBG adopts a configuration almost identical with that of the native conformer. We conclude that CBG has adapted an allosteric mechanism of the serpins to allow equilibrated release of the hormones by a flip-flop movement of the intact reactive loop into and out of the β-sheet. The change in the hormone binding affinity results from a change in the flexibility or plasticity of the connecting loop, which modulates the configuration of the binding site.     

Plasma sex steroid binding in Chiroptera

Plasma steroid binding was examined in samples obtained from seven species of bats representing four different families. A specific sex steroid-binding protein (SBP) was identified by steady-state polyacrylamide gel electrophoresis in representatives of two families, the phyllostomids and the vespertilionids. In these species, as in primates, SBP not only exhibited high affinity for the androgens testosterone and dihydrotestosterone (DHT), but also for estradiol. A specific SBP was not identified in the tropical American vampire bat or in the two species of pteropodids examined. In all species examined, except for the vampire bat, a specific corticosteroid-binding globulin (CBG) was also identified. In addition to binding glucocorticoids, CBG in these species appeared to bind androgens as well.     

Importance of arginine residues in the determination of the biological activity of human corticosteroid-binding globulin

The binding activity of human corticosteroid-binding globulin (CBG) is pH dependent and governed in alkaline pH ranges by the pK of arginine. No essential arginine residues is located in the binding site. The loss of biological activity is rapid and complete as soon as one arginine residue is modified by phenylglyoxal. There is also a transconformation of the CBG molecule. Therefore the surprising stability of CBG up to pH 11.5 may be explained by a large dependence of the CBG tertiary structure on the integrity of one arginine residue : as long as the ionized state of this single residue is not changed (pH less than pK of the guanidyl group) the tertiary structure of the biologically active CBG is maintained in alkaline pH ranges.     

A Leu----His substitution at residue 93 in human corticosteroid binding globulin results in reduced affinity for cortisol.

A steroid binding capacity assay and a radioimmunoassay were both used to measure corticosteroid binding globulin (CBG) in serum samples from 22 patients with sepsis. An approximately 50% discordancy between the two values in one patient suggested the presence of a CBG variant with reduced affinity for cortisol, and this was confirmed by Scatchard analysis. We therefore used the polymerase chain reaction to amplify exons that encode for human CBG from the genomic DNA of this patient. This revealed two mutations within the coding sequences: one of which results in a Leu----His substitution at residue 93 and another which encodes a Ser----Ala substitution at residue 224 of the human CBG polypeptide. To assess the impact of each substitution on the steroid binding affinity of CBG, each mutation was introduced separately into a normal human CBG cDNA, and the normal and mutated cDNAs were expressed in Chinese hamster ovary cells. Scatchard analysis of the CBG produced in culture indicated that the His93 mutation (Kd = 2.24 +/- 1.75 nM) reduced the cortisol binding affinity of CBG (mean +/- SD) significantly (P less than 0.024) when compared to normal CBG (Kd = 0.64 +/- 0.31 nM), while the Ala224 mutation (Kd = 0.63 +/- 0.33 nM) did not influence cortisol binding affinity. We therefore conclude that residue 93 may play an important role in determining the structure of the CBG steroid binding site.     

Expression of corticosteroid-binding protein in the human hypothalamus, co-localization with oxytocin and vasopressin.

Corticosteroid-binding globulin, a specific steroid carrier in serum with high binding affinity for glucocorticoids, is expressed in various tissues. In the present study, we describe the immunocytochemical distribution of this protein in neurons and nerve fibers in the human hypothalamus. CBG immunoreactive perikarya and fibers were observed in the paraventricular, supraoptic, and sexual dimorphic nuclei in the perifornical region, as well as in the lateral hypothalamic and medial preoptic areas, the region of the diagonal band, suprachiasmatic and ventromedial nuclei, bed nucleus of the stria terminalis and some epithelial cells from the choroid plexus and ependymal cells. Stained fibers occurred in the median eminence and infundibulum. Double immunostaining revealed a partial co-localization of corticosteroid-binding globulin with oxytocin and, to a lesser extent, with vasopressin in the paraventricular and the supraoptic nuclei. Double immunofluorescence staining showed coexistence of these substances in axonal varicosities in the median eminence. We conclude that neurons of the human hypothalamus are capable of expressing corticosteroid-binding globulin, in part co-localized with the classical neurohypophyseal hormones. The distribution of CBG immunoreactive neurons, which is widespread but limited to specific nuclei, indicates that CBG has many physiological functions that may include neuroendocrine regulation and stress response.     

Mineralcorticoid receptor from rat kidney. Interaction with heparin and purification to a CBG-free stage

Purification of the mineralcorticoid receptor is a particularly challenging problem. This receptor is present in target tissues at concentrations lower and is less stable than any other steroid receptor. Addition of molybdate ions (20 mM) to rat kidney cytosol enhances stability of mineralcorticoid-specific binding sites: the inactivation rate at 0 degrees C decreases from 7.2 to 1.7% per hour in the absence of aldosterone, and from 1.8 to 0.3% per hour in the presence of hormone. Rates of inactivation in the presence of molybdate are thus compatible with purification procedures. Also, the corticosteroid-binding globulin (CBG) is an important contaminating component of kidney cytosol because it cannot be specifically blocked preliminarily to affinity chromatography. We show that when kidney cytosol is incubated with heparin covalently linked to Sepharose (Sepharose-heparin), after 30 min at 0 degrees C more than 80% of the mineralcorticoid-specific binding sites interact strongly with Sepharose-heparin while CBG is not bound at all. The mineralcorticoid-specific binding sites can be recovered from Sepharose-heparin by washing with heparin (2 mg/ml; recovery up to 90%), KCl (0.3 M; recovery up to 90%); and, less efficiently, with total liver RNA (2 mg/ml; recovery up to 55%) and dextran sulfate (2 mg/ml; recovery up to 40%); little or no recovery is achieved with chondroitin sulfate, sonicated DNA, pyridoxal-5-phosphate, dextran, d-glucosamine and d-glucuronic acid. With demonstration that also the mineral-corticoid receptor binds to heparin, this property has become a general hallmark of steroid receptors. If the "heparin" binding site of steroid receptors is of physiological significance it remains to be established. By application of the newly found property of the mineralcorticoid receptor, an overall 10-fold purified, CBG-free preparation of this receptor can be obtained from kidney cytosol with a single chromatography on Sepharose-heparin.     

Interaction of human CBG with cell membranes

Specific binding sites for corticosteroid-binding globulin (CBG) and its pregnancy-associated variant (pCBG), having a modified carbohydrate moiety, were found in the plasma membranes of human liver, decidual endometrium and placental syncytiotrophoblast. The membrane binding was influenced by the conformation of the glycoprotein molecules and structure of their carbohydrate chains. CBG receptor was solubilized from the endometrium membrane and partially characterized. It was found to have a subunit structure, with a homooligomeric sialoglycoprotein consisting of four 20 kDa protomeric species being involved in the recognition of the CBG molecules complexed with progesterone or cortisol. A kinetic study using membrane microvesicles derived from the syncytiotrophoblast brush border revealed that neither CBG nor pCBG restricted cortisol accumulation in the intravesicular space, whereas only normal CBG could penetrate the syncytiotrophoblast membrane. Action of the CBG-cortisol complex on trophoblast cells resulted in the activation of membrane adenylate cyclase and growth of the cAMP accumulation within these cells. Collectively, these findings suggest that both normal CBG and pCBG are involved in the guided transport of steroid hormones to the target cells and transmembrane transfer of hormones and/or hormonal signals.     

Corticosteroid-binding globulin (CBG) in fetal development

In fetal sheep the prepartum increase in plasma cortisol concentration is associated with an increase in high affinity corticosteroid binding activity in plasma. This appears to reflect an increase in corticosteroid-binding globulin (CBG) biosynthesis from the fetal liver, and evidence is presented that hepatic CBG gene expression is increased by exposure to glucocorticoids in the fetus. Immunoreactive CBG is found in other fetal tissues, and CBG mRNA is present in fetal pituitary. CBG reduces the ability of cortisol to exert negative feedback on basal or CRH-stimulated ACTH output by fetal sheep pituitary cells in culture. We suggest that CBG interacts with cortisol in a manner that maintains a low negative feedback on the pituitary, and perhaps hypothalamus. This constitutes a component of the cascade of events that is associated with hypothalamic-pituitary-adrenal activation in the late gestation fetus, and with the onset of parturition.     

Interaction of testosterone, corticosterone and corticosterone binding globulin in the white-throated sparrow (Zonotrichia albicollis)

Plasma binding globulins bind steroid hormones and are thought to regulate hormone access to tissues. Mammals have both sex steroid binding globulin (SSBG) and corticosteroid binding globulin (CBG). Birds, however, have no detectable SSBG, leading to the early conclusion that birds have no plasma regulation of sex steroids. CBG, however, can bind androgens with relatively high affinity. In birds, therefore, the control of androgenic effects may be tightly regulated by glucocorticoid physiology because glucocorticoids compete with androgens for CBG binding sites. We report levels of total testosterone (T), total corticosterone, CBG, and estimated free T in the males, the more aggressive morph had higher levels of total T; female morphs did not differ. Approximately 96% of T was bound to CBG, but a lack of morph or sex-specific differences in corticosterone titers or CBG capacity caused patterns of free T to mirror those of total T. While CBG has the potential to greatly influence T availability to tissues, in this species interactions between T, CBG and corticosterone do not appear to alter general patterns of T availability to tissues.     

Elevation of corticosteroid-binding globulin in obese strain (OS) chickens: possible implications for the disturbed immunoregulation and the development of spontaneous autoimmune thyroiditis

Basal plasma levels of corticosterone and corticosteroid-binding globulin (CBG) have been investigated in Obese strain (OS) chickens afflicted with spontaneous autoimmune thyroiditis (SAT). Corticosterone was determined radioimmunologically, and CBG by using a highly sensitive radioligand saturation assay. OS chickens displayed total corticosterone levels not different from healthy normal White Leghorn (NWL) chickens. CBG, however, was found to be twice as high in OS chickens as compared with their healthy counterparts, irrespective of sex or age. This quantitative difference in the CBG level is not compensated for by either altered affinity or specificity of the molecule. Furthermore, no differences were found in the response of OS and NWL lymphocytes to the suppressive effect of glucocorticoids in vitro. We therefore assume that OS animals are deficient in free, hormonally active corticosterone. An additional indication for such a diminished glucocorticoid tonus was that in vivo treatment of OS chickens with glucocorticoid hormones, thus increasing the free and active hormone fraction, normalizes the T cell hyperreactivity and significantly reduces thyroid infiltration. Possible pathophysiological implications of a diminished glucocorticoid tonus for spontaneous autoimmunity, as well as possible explanations for the beneficial effects of glucocorticoid treatment on the development of SAT, are discussed.     

Modulation in Wistar Rats of Blood Corticosterone Compartmentation by Sex and a Cafeteria Diet

In the metabolic syndrome, glucocorticoid activity is increased, but circulating levels show little change. Most of blood glucocorticoids are bound to corticosteroid-binding globulin (CBG), which liver expression and circulating levels are higher in females than in males. Since blood hormones are also bound to blood cells, and the size of this compartment is considerable for androgens and estrogens, we analyzed whether sex or eating a cafeteria diet altered the compartmentation of corticosterone in rat blood. The main corticosterone compartment in rat blood is that specifically bound to plasma proteins, with smaller compartments bound to blood cells or free. Cafeteria diet increased the expression of liver CBG gene, binding plasma capacity and the proportion of blood cell-bound corticosterone. There were marked sex differences in blood corticosterone compartmentation in rats, which were unrelated to testosterone. The use of a monoclonal antibody ELISA and a polyclonal Western blot for plasma CBG compared with both specific plasma binding of corticosterone and CBG gene expression suggested the existence of different forms of CBG, with varying affinities for corticosterone in males and females, since ELISA data showed higher plasma CBG for males, but binding and Western blot analyses (plus liver gene expression) and higher physiological effectiveness for females. Good cross- reactivity to the antigen for polyclonal CBG antibody suggests that in all cases we were measuring CBG.The different immunoreactivity and binding affinity may help explain the marked sex-related differences in plasma hormone binding as sex-linked different proportions of CBG forms.     

Allosteric modulation of hormone release from thyroxine and corticosteroid-binding globulins

The release of hormones from thyroxine-binding globulin (TBG) and corticosteroid-binding globulin (CBG) is regulated by movement of the reactive center loop in and out of the β-sheet A of the molecule. To investigate how these changes are transmitted to the hormone-binding site, we developed a sensitive assay using a synthesized thyroxine fluorophore and solved the crystal structures of reactive loop cleaved TBG together with its complexes with thyroxine, the thyroxine fluorophores, furosemide, and mefenamic acid. Cleavage of the reactive loop results in its complete insertion into the β-sheet A and a substantial but incomplete decrease in binding affinity in both TBG and CBG. We show here that the direct interaction between residue Thr(342) of the reactive loop and Tyr(241) of the hormone binding site contributes to thyroxine binding and release following reactive loop insertion. However, a much larger effect occurs allosterically due to stretching of the connecting loop to the top of the D helix (hD), as confirmed in TBG with shortening of the loop by three residues, making it insensitive to the S-to-R transition. The transmission of the changes in the hD loop to the binding pocket is seen to involve coherent movements in the s2/3B loop linked to the hD loop by Lys(243), which is, in turn, linked to the s4/5B loop, flanking the thyroxine-binding site, by Arg(378). Overall, the coordinated movements of the reactive loop, hD, and the hormone binding site allow the allosteric regulation of hormone release, as with the modulation demonstrated here in response to changes in temperature.     

Functional implication of an Arg307Gly substitution in corticosteroid-binding globulin, a candidate gene for a quantitative trait locus associated with cortisol variability and obesity in pig

We previously reported that corticosteroid-binding globulin gene (Cbg) may be the causal gene of a quantitative trait locus associated with cortisol levels, fat deposition, and muscle content in a pig intercross. Sequence analysis of parental animals allowed us to identify four amino-acid substitutions. Here we have examined if any of these single amino acid substitutions could be responsible for the difference in CBG binding and affinity for cortisol between the parental breeds, using in vitro assays of Cbg variants after transfection of mammalian cells. Additionally, the Cbg coding region was analyzed in samples from a synthetic pig line to study association between polymorphism and CBG biochemical properties, carcass composition, and meat quality. Both in vitro transfection assays and the association studies suggest a role of the Arg307Gly mutation in increasing CBG capacity (by >70%) and decreasing CBG affinity for cortisol (by 30%). The Ile265Val substitution may also have an effect on decreasing CBG affinity for cortisol by 25%. The mutations Ser15Ile and Thr257Met do not seem to have an effect on CBG parameters. The Arg307Gly substitution was the only mutation associated with a parameter of meat quality and no mutation was linked to carcass composition.     

Purification and properties of squirrel monkey (Saimiri sciureus) corticosteroid binding globulin

Corticosteroid binding globulin (CBG), a serum glycoprotein which binds glucocorticoids and progestins with high affinity, is widely distributed throughout the animal world. Although its charge and size characteristics have largely been conserved across species, we found the behavior of CBG in squirrel monkey (Saimiri sciureus) serum during fractionation by polyacrylamide gel electrophoresis or Sephadex chromatography was consistent with a molecule about twice the size of that found in most species. To more fully understand the basis for this difference, we purified the protein by sequential affinity and DEAE-Sepharose chromatographies. The final product was obtained in greater than 60% yield and was found to migrate as a single homogeneous band when examined by electrophoresis at pH 8.3 in polyacrylamide gels varying total acrylamide concentration or under conditions of severe protein overload. The steroid binding specificity of the purified protein was identical with that of the protein in the starting serum. The ultraviolet absorption spectrum of the isolated CBG-steroid complexes revealed that the protein had no pyridine nucleotide cofactor or nucleic acid. Amino acid analyses showed that the composition of the squirrel monkey protein is quite similar to that of CBG molecules from other species but distinct from albumins, hemoglobin, or rabbit progesterone receptor. In contrast to the single protein band observed following electrophoresis under normal conditions, separations in the presence of sodium dodecyl sulfate (SDS) resolved the pure protein into two bands: one at 54,000 daltons and one at 57,000 daltons.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characteristics of glucocorticoid-binding by inflammatory tissue of rats

Glucocorticoid-binding activities of the granuloma cytosol were compared with those of the liver cytosol and of the serum in vitro. The granuloma cytosol bound cortisol (HC) about 4-fold higher than dexamethasone (DX) and triamcinolone acetonide (TA); the liver cytosol bound these two synthetic agonists more than HC. The kinetic parameters of the glucocorticoid-binding components of the granuloma and the liver cytosols were studied by the Scatchard method. The binding components of the granuloma cytosol had a single class of binding sites with high affinity for these three steroids, whereas the binding site of the liver cytosol had negative cooperativity or consisted of two distinct classes, because its Scatchard plot showed a hyperbolic curve. The granuloma glucocorticoid-binding components will be protein since their binding was prevented by a trypsin treatment and completely lost by heating at 60 C for 5 min. Heating at 25 or 37 degrees C for 30 min did not affect the HC-binding activity of the granuloma cytosol, regardless of prelabeling with the steroid. The binding activity for DX and TA were heat-labile and completely lost by heating the cytosol at 37 degrees C for 30 min without the respective steroid. The results of thermal inactivation and ammonium sulfate fractionation show the granuloma HC-binding protein closely resembles corticosteroid-binding globulin (CBG). From enzymatic determination of hemoglobin in tissue cytosols, attribution of the contaminating blood to the HC-binding activity of the cytosol is considered to be negligible.     

Structure and function of corticosteroid-binding globulin: Role of carbohydrates

To study the site-specificity of human corticosteroid-binding globulin (CBG) glycosylation and the functional significance of individual carbohydrate chains in its molecule, a panel of recombinant CBG mutants containing each of the six potential glycosylation sites alone and in various combinations has been expressed in Chinese hamster ovary (CHO) cells. Analyses of these mutant glycoproteins showed that three of the glycosylation sites are only partially utilized, and this may contribute to the production of glycoforms with distinct physiological functions. Processing of individual carbohydrate chains (branching and fucosylation) is site-specific and may, thus, account for the formation of structural determinants essential for the recognition of CBG by cell membranes. Glycosylation at the only phylogenetically conserved consensus site, Asn²³⁸-Gly²³⁹-Thr²⁴⁰, is essential for the biosynthesis of CBG with steroid-binding activity. Evidence has been obtained to support the hypothesis that transient carbohydrate-polypeptide interactions between Trp²⁶⁶ and the maturing carbohydrate chain at Asn²³⁸ occur during early stages of the CBG biosynthesis which affect protein folding and formation of the steroid-binding site. Another tryptophan residue, Trp³⁷¹, has been found to be critical for CBG-steroid interactions and is likely located in the steroid-binding site.