Transport and intracellular distribution of components of the cortisol-asialotranscortin complex in the liver

The effect of desialation of human transcortin on the transcortin-cortisol complex transport into hepatocytes and on subsequent intracellular distribution of the complex components was studied in model experiments with perfused rat liver. It was demonstrated that in the presence of desialated transcortin the time of [3H]cortisol incubation in the perfusion medium decreased more than 200 times as compared with the native protein. [3H]cortisol and [131I]asialotranscortin trapping by hepatocytes occurs simultaneously. The content of the [3H]cortisol--[131I]asialotranscortin complex in rat liver plasma membranes reaches a maximum 3 min after beginning of perfusion. Then the intact complex is transported into lysosomes, where it dissociates with a subsequent release of asialotranscortin and cortisol metabolites into the cytoplasm.     

Cortisol 17 beta acid, transcortin, and the heterogeneity of rat brain glucocorticoid receptors

Binding of tracer or competing steroids to transcortin can compromise specificity studies on receptors for adrenal steroids. Recently Alexis et al. have used cortisol 17 beta acid at high concentrations to prevent steroid binding to any transcortin possibly contaminating rat brain cytosol preparations. On the basis of limited specificity studies of [3H]dexamethasone and [3H]corticosterone binding under such conditions, it was claimed that binding sites for the two steroids are indistinguishable, and it is thus unnecessary to invoke distinct binding sites for each glucocorticoid. We have extended these competition studies in the presence of cortisol 17 beta acid, and shown that in rat hippocampus Type I, corticosterone-preferring glucocorticoid receptors can be clearly distinguished both from transcortin and from Type II, dexamethasone-binding glucocorticoid receptors.     

Evidence for the presence of specific binding sites for transcortin in human liver plasma membranes

Binding sites which recognize and bind specifically asialotranscortin and the native transcortin-cortisol complex have been found in plasma membranes of human liver cells. The native conformation of transcortin is an absolute requirement for the binding reaction of the transcortin-hormone complex. Sex-hormone-binding globulin and thyroxine-binding globulin from human serum do not bind to this binding sites.     

Transcortin in rat kidney: subcellular distribution of transcortin-synthesizing polyribosomes

The [3H]corticosterone-transcortin complexes from kidney cytosol show elution positions on DEAE-cellulose identical to serum transcortin. The incorporation of 14C-labeled amino acids into anti-transcortin-precipitable material of kidney slices has been measured and compared with that of serum transcortin. It was established that kidney synthesized transcortin with an apparent molecular weight of 66 kDa on SDS-electrophoresis which resembles serum corticosteroid-binding globulin. Studies on the binding of [125I]anti-transcortin-IgG to membrane-bound rat kidney polyribosomes revealed an association of [125I]anti-transcortin-IgG with a discrete polyribosome fraction in the heavy polyribosome region; free polyribosomes were devoid of antigenic material able to bind antibodies to transcortin.     

Transcortin in rat kidney tissue: distribution in microsomal fractions

During chromatography of renal tissue cytosolic proteins on DEAE-cellulose the protein specifically binding [3H]corticosterone is eluted within the potassium phosphate concentration range of 0.08-0.10 M. Analysis of kidney slices revealed the synthesis of [3H]transcortin whose electrophoretic mobility was close to that of the blood plasma protein. Using radioimmunochemical methods, it has been found that transcortin-specific [125I]IgG antibodies interact with growing polypeptide chains of membrane-bound polyribosomes. Free polyribosomes do not bind antibodies against transcortin.     

Characterization of an antiserum against the glucocorticoid receptor

An immunoglobulin (IgG) fraction from serum of a rabbit immunized with a highly purified preparation of glucocorticoid receptor from rat liver cytosol contained specific antibodies to glucocorticoid receptor. This was shown following incubation of the [³H]triamcinolone acetonide-glucocorticoid receptor (TA-GR) complex with the IgG fraction by (I) adsorption of the [³H]TA-GR-antibody complex to protein A linked to Sepharose, (II) an increased sedimentation rate of the [³H]TA-GR-antibody complex compared to that of the [³H]TA-GR complex, and (III) an increased molecular size of the [³H]TA-GR-antibody complex when compared to that of the [³H]TA-GR complex as judged from gel filtration. The antibody fraction was characterized with regard to titer, cross-reactivity and specificity. The antibodies cross-reacted with the glucocorticoid receptor from various rat tissues (liver, thymus and hippocampus), as well as with the glucocorticoid receptor from human normal lymphocytes, chronic lymphatic leukemia cells and human hippocampus. In the rat liver, the antibody bound to both the nuclear and the cytosolic glucocorticoid receptor (Stokes radius 6.1 nm). It did not cross-react with the proteolytic fragments of the glucocorticoid receptor, the 3.6 nm complex or the 1.9 nm complex. Binding of the antibodies was not seen to the androgen, estrogen or progestin receptors in rat to rat serum transcortin. With an indirect competitive ELISA (enzyme-linked immunosorbent assay) combined with various separation techniques, based on different physiocochemical principles, it was shown that the glucocorticoid receptor was the only detectable antibody binding protein from rat liver cytosol using this assay system. These findings also indicate an immunochemical similarity between glucocorticoid receptors in different tissues as well as in different species, but not between glucocorticoid receptors and other steroid hormone receptor proteins. The cytosolic and nuclear glucocorticoid receptors in rat liver were shown to be immunochemically similar.     

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.     

Affinity labelling of human transcortin

The binding site of transcortin has been studied by using bromoacetyltestosterone and bromoacetylated derivatives of progesterone which were monohydroxylated at different positions of the steroid nucleus. Specificity of affinity labelling was demonstrated by the displad cortisol analog was added to a [3H]cortisol-transcortin complex solution. The binding site crevice was found to be very narrow in the vicinity of the A and B rings of steroid since 2alpha-hydroxyprogesterone, 6alpha- or 6beta-bromoacetoxyprogesterone and dexamethasone could not displace bound cortisol. A specific affinity labelling was obtained with 11alpha-bromoacetoxyprogesterone, 16alpha-bromoacetoxyprogesterone and 17beta-bromoacetyltestosterone. The results of the affinity labelling by these hormone analogs suggested that one methionine and one histidine residues were located within the active site:methionine might interact with the 11beta-hydroxyl group and histidine with the 20 keto group of cortisol.     

Influence of starvation,Triton WR-1339 and [131I]-human serum albumin on rat liver lysosomes

The response of rat liver lysosomes to starvation and administration of lysosomotropic agentsviz. Triton WR-1339 and [¹³¹I]-human serum albumin, was assessed in terms of their distribution pattern after isopycnic sucrose density gradient centrifugation. Starvation induced changes in lysosomes appeared to be similar to that produced by the detergent uptake. Both the treatments caused a distinct decline in the equilibration densities of the organelles. On the other hand, injected labelled protein failed to comigrate with the lysosomal markers in starved as well as Triton treated rats and conspicuously remained in a region of high specific gravity in the gradient. These findings indicate retarded fusion between secondary lysosomes and [¹³¹I]-human serum albumin containing phagosomes in the livers of rats subjected to starvation or detergent treatment     

Equivalent affinity of aldosterone and corticosterone for type I receptors in kidney and hippocampus: direct binding studies

In studies from several laboratories evidence has been adduced that renal Type I (mineralocorticoid) receptors and hippocampal "corticosterone-preferring" high affinity glucocorticoid receptors have similar high affinity for both aldosterone and corticosterone. In all these studies the evidence for renal mineralocorticoid receptors is indirect, inasmuch as the high concentrations of transcortin (CBG) in renal cytosol make studies with [3H]corticosterone as a probe difficult to interpret, given its high affinity for CBG. We here report direct binding studies, with [3H]aldosterone and [3H]corticosterone as probes, on hippocampal and renal cytosols from adrenalectomized rats, in which tracer was excluded from Type II dexamethasone binding glucocorticoid receptors with excess RU26988, and from CBG by excess cortisol 17 beta acid. In addition, we have compared the binding of [3H]aldosterone and [3H]corticosterone in renal cytosols from 10-day old rats, in which CBG levels in plasma and kidney are extremely low. Under conditions where neither tracer binds to type II sites or CBG, they label an equal number of sites (kidney 30-50 fmol/mg protein, hippocampus approximately 200 fmol/mg protein) with equal, high affinity (Kd 4 degrees C 0.3-0.5 nM). Thus direct tracer binding studies support the identity of renal Type I mineralocorticoid receptors and hippocampal Type I (high affinity, corticosterone preferring) glucocorticoid receptors.     

Human transcortin synthesis by a cell-free translation of hepatic mRNA

To evaluate the site of synthesis and to characterize the translated transcortin, poly (A)-containing RNA (mRNA) from human liver was translated in a cell-free system derived from rabbit reticulocyte lysate. The in vitro synthesized product was identified as transcortin by immuno-precipitation with its specific antiserum. This translated transcortin could be displaced from the antibody by unlabeled purified transcortin obtained from plasma. Furthermore, when the translation mixture was applied to a cortisol-Sepharose column, the translated transcortin was bound to the matrix in a specific manner, indicating that this product binds to cortisol. The molecular weight of the translated transcortin was estimated to be 45,700 by its mobility in sodium dodecyl sulfate polyacrylamide gel electrophoresis, while that of plasma transcortin was 53,800. The difference in molecular weight between the translated transcortin and plasma transcortin was probably due to the presence of pre-sequence (signal peptide) in addition to the absence of carbohydrate moiety in the former. In conclusion, human liver mRNA directed the synthesis of transcortin, and the translated transcortin binds to cortisol in spite of the absence of carbohydrate moiety.     

The role of sialic acid in determining the survival of transcortin in the circulation

The effect of desialylation on the survival of human transcortin and of its ligand cortisol has been investigated using the isolated perfused rat liver preparation. In contrast with native transcortin, sialic acid-free transcortin was promptly cleared from the perfusate. The hepatic uptake was accompanied by a significant reduction of the cortisol half-life.     

In vitro metabolism of adrenocortical hormones by mammary glands of lactating rats. A comparative study

A comparative study was made of the metabolism of tritium-labeled corticosterone, cortisol and aldosterone on incubation with minced mammary glands of lactating rats. The yield of total nonpolar (acylated) radiometabolites was highest for [3H]corticosterone, lowest for [3H]cortisol and intermediate for [3H]aldosterone. Unlike [3H]corticosterone, [3H]aldosterone yielded two 21-acyl derivatives (Metabolites I and II) in comparable amounts. Metabolite I (39%) was identified as [3H]aldosterone 21-oleate by isotope dilution analysis. Metabolite II (54%) could not be identified: it is intermediate in polarity between corticosterone 21-oleate and the less polar, corticosterone 21-stearate, and is distinctly less polar than the 21-palmityl, linoleoyl (and presumably also less polar than the arachidonyl) derivatives of aldosterone. The [3H]cortisol metabolites were not further investigated.     

A putative glucocorticoid receptor and a transcortin-like macromolecule in pituitary cytosol.

This study describes the binding of [3H]corticosterone and [3H] dexamethasone to soluble macromolecules in the pituitaries of adrenalectomized rats perfused at sacrifice to remove blood contamination. (1) Unlabeled dexamethasone competes only slightly for [3H] corticosterone binding when the steroids are added to cytosol as well as when the steroids are present from the time of disruption of the tissue. In the latter case, corticosterone is as good a competitor as dexamethasone for [3H]dexamethasone binding. (2) Gel permeation chrmatography with BioRad A-5M reveals the presence of a [3H] corticosterone-macromolecular complex with an elution volume comparable to transcortin as well as a very large hormone-binding complex eluting in the void volume of the column...     

Sugar transport in rat liver lysosomes. Direct demonstration by using labelled sugars.

Purified rat liver lysosomes ('tritosomes') were prepared from rats injected with Triton WR-1339. 2. The water space of tritosomes, measured by using [3H]water and [14C]sucrose, was 2.15 +/- 0.72 microliter/mg of protein (mean +/- S.E.M., n = 12). 3. Tritosomes, when compared with a crude preparation of normal lysosomes by an indirect method of study, showed sugar specificity but decreased stereospecificity of sugar uptake. 4. At 125 mM the relative rates of net uptake of D-[14C]ribose, D-[14C]- or D-[3H]glucose and 2-deoxy-D-[3H]glucose were the same as that inferred from the indirect study. 5. The entry of D-[3H]glucose into tritosomes showed concentration-dependence suggestive of saturation, with a Km of 48 +/- 18 mM (4). 6. D- and L-glucose, D-ribose, 2-deoxy-D-glucose and D-mannose competed with D-[14C]glucose or D-[14C]ribose for uptake. 7. Cytochalasin B inhibited D-[3H]glucose uptake. 8. Uptake of 1 mM-L-[14C]glucose was slower than for 1 mM-D-[14C]glucose. 9. It is concluded that a facilitated-diffusion transport system is present in purified rat liver lysosomes.     

Human liver nuclear transcortin its postulated role in glucocorticoid regulation of genetic activity

Highly purified human transcortin was injected into rabbits, and the antibody subsequently obtained was employed for the demonstration of transcortin-like molecules within various subcellular fractions of the human liver cell. Results obtained via quantitative double diffusion ouchterlony procedures indicate that proteins extracted from the nucleus or from chromatin form continuous precipitin lines of identity with those of transcortin. Fluorescein-tagged anti-transcortin permitted the visual localization of this molecule within isolated nuclei. Cortisol binding studies of all the subcellular fractions, particularly that extracted from the chromatin, suggest that such proteins do indeed bind cortisol specifically, as well as responding to exogeneous additions to the buffer (sulfhydryl reagents) as does purified transcortin. Purified transcortin when dialyzed exhaustively loses its cortisol binding ability, although the latter can be restored after its incubation with chromatin at 4°C. The restoration of such activity is dependent upon a dialyzable, heat-resistant chromatin component which itself lacks cortisol binding activity and which increases the sedimentation characteristics of dialyzed transcortin. The effect of transcortin on the in vitro synthesis of RNA in an Escherichia coli RNA polymerase human liver chromatin system is also presented. All of the above results are interpreted to indicate that transcortin is involved directly in the regulation of that genetic activity observed subsequent to the administration of cortisol.     

Cortisol binding in rat skeletal muscle.

Studies of the reversible binding of [3H]cortisol by rat gastrocnemius muscle cytoplasm in vitro reveal specific binding in the 27,000 times g supernatant fraction at 0 degrees. The [3H]cortisol-binding molecule had an apparant Kd value of 1.7 times 10-7 M and the number of binding sites was 0.99 pmol per mg of cytosol protein. Only a single class of [3H]cortisol-binding sites could be detected, whose protein nature was suggested by its susceptibility to nagarse. The [3H]cortisol-protein complex sedimented at similar to 4 S in a 5 to 20% sucrose gradient either in the presence or absence of 0.3 M KCl. Binding increased more than 2-fold in adrenalectomized rats and was markedly reduced in the muscle of rats pretreated with cortisol. In contrast to the binding of [3H]dexamethasone and [3H]triamcinolone acetonide to receptor proteins in muscle, no correlation was found between the ability of various steroids to complete wtth [3H]cortisol binding and their glucocorticoid potency: [3H]cortisol binding was inhibited by a 1000-fold higher concentration of unlabeled cortisol and progesterone but not by dexamethasone or triamcinolone acetonide. It is therefore suggested that the [3H]cortisol-binding reaction is not directly involved in the biological effects of all potent glucocorticoids in skeletal muscle. The [3H]cortisol-binding protein in muscle cytosol could not be unequivocally distinguished from rat plasma corticosteroid-binding globulin, because both had similar steroid specificity and temperature stability, were not markedly affected by--SH reagents, and displayed similar sedimentation properties.     

Binding of acetylated low density lipoprotein and maleylated bovine serum albumin to the rat liver: one or two receptors?

The liver is the major organ involved in clearance of acetylated low density lipoprotein (acetyl-LDL) and maleylated serum albumin (Mal-BSA). Quantitative analysis of the hepatic uptake by sequential scintigraphy in rats shows that the hepatic uptake capacity for Mal-BSA is at least 15 times larger than for acetyl-LDL particles. A membrane-associated M approximately 250,000 daltons hepatic receptor for acetyl-LDL and Mal-BSA was 1450-fold purified from total membrane by Triton X-114 solubilization, chromatography on polyethylenimine cellulose and gel filtration. This receptor incorporated into liposomes displayed a saturable binding of [131I]Mal-BSA with a dissociation constant Kd = 15 nM and to [131I]acetyl-LDL with a dissociation constant Kd = 0.9 nM. The binding of both ligands was sensitive to poly(vinyl sulfate). The purified scavenger receptor system has a binding capacity for [131I]Mal-BSA 20 times larger than for [131I]acetyl-LDL. This is similar to the maximal removal capacity of the rat liver for both ligands in vivo. Binding studies with Mal-BSA, acetyl-LDL and anti-idiotypic receptor antibodies as competitors for [131I]Mal-BSA and [131I]acetyl-LDL binding demonstrate that [131I]Mal-BSA and [131I]acetyl-LDL compete for a common binding site. However, not all of the Mal-BSA binding sites are capable of interacting with acetyl-LDL.     

Intra- and extra-cellular sources of T3 binding to putative thyroid hormone receptors in liver, kidney, and gill nuclei of immature rainbow trout, Oncorhynchus mykiss.

The sources of extracellular and intracellular 3,5,3'-triiodo-L-thyronine (T3) binding to putative thyroid hormone receptors in liver, kidney, and gill nuclei were determined in vivo for immature rainbow trout at 12 degrees C. Both [131I]T3 and [125I]T4 were injected intraperitoneally, the plasma and tissues were examined at isotopic equilibrium at 20 h, and the proportions of intracellular [125I]T3 and extracellular [131I]T3 saturably bound in the nucleus were determined. Comparable total amounts of T3 were saturably bound in the nuclei of liver (7.2), kidney (8.0), and gill (9.7 moles x 10(-13) .mg DNA-1), but the percentage of nuclear T3 generated within the target cell was greater for gill (76%) than for liver (50%) and kidney (28%). Both gill and liver possess a low Km T4 5'monodeiodinase which could be responsible for the high proportion of the nuclear T3 generated within those tissues.     

Investigation of the corticosteroid receptor system in rat hippocampus by ion exchange fast protein liquid chromatography

In order to study the receptor system for adrenocortical steroids, hippocampal cytosolic preparations--containing both type I and type II receptors--were subjected to anion exchange fast protein liquid chromatography (FPLC). With running buffer containing Tris, EDTA, and glycerol three peaks (1-3) were eluted from the column at 220, 400 and 560 mM NaCl respectively regardless of whether [3H]corticosterone or [3H]RU 28362 had been used as radiotracer. None of the peaks was caused by serum transcortin as revealed by control studies. However, the sequestering influence of transcortin on receptor binding of corticosterone could be demonstrated by the FPLC technique with mixtures containing serum and hippocampus cytosol. Competition experiments with cytosolic samples revealed that type I receptor was present only in peaks 2 and 3 while type II was found in all three peaks in variable amounts, depending on the presence of molybdate. When molybdate was added to the running buffer only two peaks (2 and 3) were eluted, both containing type I and type II receptors. Peak 1 was attributed to the activated type II receptor while peak 2 represented nonactivated receptors. The origin of peak 3 remains uncertain. The data indicate that molybdate must be present in the cytosolic preparation and in the running buffer to keep type II receptor in its nonactivated form. Type I receptor was probably not transformed into the activated form in the absence of molybdate but lost binding capacity and/or affinity for corticosterone.