Multiple thyroid hormone binding sites on rat liver nuclear envelopes

Nuclear envelopes relatively free of plasma membrane contamination were isolated from the male rat liver. Equilibrium binding of T3 to nuclear envelopes occurred after incubation for 3 h at 20 degrees C. Scatchard analysis revealed two classes of binding sites; a high affinity site having a KD of 1.8 nM with a maximum binding capacity of 14.5 pmol/mg protein and a low affinity site having a KD of 152.1 nM with a maximum binding capacity of 346.8 pmol/mg protein. No degradation of the radioligand occurred during incubation with the nuclear envelope. T4, rT3 and Triac competed effectively for the binding of T3 to the high affinity site whereas only T4 competed well for binding to the lower affinity site. The binding site was protease sensitive but not salt extractable. Multiple T3 binding sites having similar affinities have been reported on plasma membranes. An intriguing possibility is that membrane binding sites may be involved in translocation of thyroid hormone across membrane barriers.     

Binding properties of thyroxine to nuclear extract from sea urchin larvae

We previously reported that thyroid hormones are involved in the formation of the adult rudiment and adult-type skeleton in sea urchin larvae, as well as in the resorption of larval tissues. In the present study, to search for the presence of thyroid hormone receptor in sea urchin larvae, we performed a ligand-binding assay between radiolabeled thyroid hormones and nuclear extracts from the larvae of the sea urchin Hemicentrotus pulcherrimus. The presence of binding sites with a high affinity to thyroxine (T4) was detected in the nuclear extract, but not in the cytoplasmic fraction. The dissociation constants for the T4 binding to the nuclear extracts were estimated to be about 18 pM from the mesenchyme-blastula stage to the four-armed pluteus stage. The quantity of T4 binding sites in the nuclear extracts increased during larval development. These results suggest that the binding affinity to T4 in the nuclear extracts was caused by a putative nuclear thyroid hormone receptor in sea urchin larvae.     

Specific receptors for triiodothyronine in nuclei isolated from normal human polynuclear neutrophils

In normal subjects, nuclei isolated and purified from circulating granulocytes bound 125I-T3. Binding was reversible and inhibited by unlabelled hormone. Scatchard plots showed a single class of high affinity sites (Kd: approximately 1,5 nM) with a high maximal binding capacity (MBC: approximately 400 fmol of T3 bound/100 micrograms of DNA). Structural analogs partially competed with 125I-T3 binding. These data suggest that human normal polymorphonuclear neutrophils possess specific nuclear receptors for triiodothyronine.     

Characterization of a thyroid-hormone-binding site on nuclear envelopes and nuclear matrices of the male-rat liver

Nuclear envelopes and nuclear matrices were isolated from the male-rat liver. Incubation of 125I-labelled 3,3',5-tri-iodothyronine (T3) with the nuclear-envelope fraction resulted in specific binding of T3 to the membranes. Maximum specific binding occurred at 30 degrees C after 2h incubation. Storage for 1 week at -80 degrees C resulted in no loss of binding. Scatchard analysis revealed a class of binding sites with KD 86 nM. 3,3',5'-Tri-iodothyronine was as effective a competitor of [125I]T3 binding to nuclear envelopes as was L-T3 itself, and tri-iodothyroacetic acid was 70% as potent as T3. L- and D-thyronine did not compete for [125I]T3 binding. Incubation of nuclear envelopes with 0.6 M-NaCl before addition of T3 resulted in the complete loss of specific binding sites, whereas exposure of the membranes to 2.0 M-NaCl after incubation with T3 did not extract binding sites. Nuclear matrices, after incubation with [125I]T3 under the same conditions, were shown to possess a class of binding sites with a similar KD but with approx. 30% of the maximum binding capacity. Nuclear envelopes from hypothyroid animals may possess slightly lower numbers of binding sites compared with nuclear envelopes from the intact animal, whereas nuclear matrices from hypothyroid animals have the same number of binding sites as do nuclear envelopes from the intact animal. In conclusion, nuclear envelopes and nuclear matrices have a class of binding sites with relatively high affinity for T3. It is distinct from nuclear and cytosolic binding sites.     

Fatty acyl-CoAs are potent inhibitors of the nuclear thyroid hormone receptor in vitro

We report that long-chain fatty acyl-CoAs are potent inhibitors of the thyroid hormone (T3) receptor isolated from rat liver nuclei. Both saturated and unsaturated fatty acyl-CoAs were similarly potent. Fifty per cent inhibition of T3 binding by the receptor was observed at an oleoyl-CoA concentration as low as 1.3 microM, and the affinity of oleoyl-CoA for the receptor (Ki) was estimated to be 0.45 microM. Fatty acyl-CoAs also promoted dissociation of the hormone bound to the receptor. The action of fatty acyl-CoAs was competitive for the hormone binding site, resulting in a reduction in the receptor's affinity for T3. These observations suggest that fatty acyl-CoAs modulate the binding of the thyroid hormone to its nuclear receptor, in vitro. Whether or not such events occur in vivo remains to be determined.     

Thyroid Hormone Receptors in the Developing Rat Brain

It is widely believed that the adult mammalian brain is insensitiveto thyroid hormones unlike the neonatal brain which is criticallydependent on these hormones for the development of normal structureand function. Recent studies have demonstrated the presenceof limited capacity, high affinity, triiodothyronine (T3) bindingnuclear sites in tissues that are considered responsive to thyroidhormones. Furthermore, there is evidence from studies on peripheraltissues that these T3 binding sites act as true receptors ininitiating thyroid hormone action. This report examines whetherthe higher sensitivity of neonatal brain to thyroid hormonesand the purported decline in sensitivity in adulthood are relatedto changes in the concentration and affinity characteristicsof thyroid hormone receptors in rat cerebral nuclei. Analysisof Scatchard plots of in vitro T3 binding data indicate thatcerebral nuclei from adult rats contain T3 specific nuclearbinding sites at a concentration comparable to that presentduring the period when the brain is critically dependent onthe presence of thyroid hormones and exceed that in the liver,a tissue generally considered thyroid sensitive. Neonatal thyroidectomysignificantly increased the number of binding sites. The resultsshow that the apparent unresponsiveness of the cerebral cortexof adult rats to thyroid hormones is not due to the absenceor a low density of T3 nuclear binding sites. The significanceof these results is discussed.     

Unesterified long-chain fatty acids inhibit thyroid hormone binding to the nuclear receptor. Solubilized receptor and the receptor in cultured cells

Unesterified long-chain fatty acids strongly inhibited thyroid hormone (T3) binding to nuclear receptors extracted from rat liver, kidney, spleen, brain, testis and heart. Oleic acid was the most potent inhibitor, attaining 50% inhibition at 2.8 microM. Oleic acid similarly inhibited the partially purified receptor and enhanced dissociation of the preformed T3-receptor complex. The fatty acid acted in a soluble form and in a competitive manner for the T3-binding sites, thereby reducing the affinity of the receptor for T3. The affinity of the receptor for oleic acid (Ki) was 1.0 microM. In HTC rat hepatoma cells in culture, fatty acids added to the medium reached the nucleus and inhibited nuclear T3 binding; oleic acid being the most potent. T3 binding of the cells was reversibly restored in fresh medium free of added fatty acids. Oleic acid did not affect all the T3-binding sites in the HTC cells: one form (80%) was inhibited and the other was not and these two forms were commonly present in all rat tissues examined. Thus, fatty acids inhibited the solubilized nuclear receptor as well as a class of nuclear T3-binding sites in cells in culture.     

A novel T-cell protein which recognizes a palindromic sequence in the negative regulatory element of the human immunodeficiency virus long terminal repeat

Two major protein-binding sites within the negative regulatory element of the human immunodeficiency virus type 1 long terminal repeat have been identified. One (site B) contained a palindromic sequence with homology to steroid/thyroid hormone response elements but was distinct from previously described binding sites of this class. A novel T-cell protein recognized the palindromic sequence within site B and also bound estrogen- or thyroid hormone-response elements with lower affinity. A 7-base-pair mutation in the site B palindrome, which destroyed protein binding, resulted in increased expression from the human immunodeficiency virus type 1 long terminal repeat in T cells.     

Antibodies to nuclear thyroid hormone-binding proteins. Antibody characterization and immunofluorescent localization

To further investigate the mechanism by which thyroid hormones regulate target cell function, we have prepared and partially characterized antibodies to highly purified nuclear thyroid hormone-binding proteins (NTBP). NTBPs were prepared from bovine liver nuclear extracts by bio-specific elution from an affinity gel containing immobilized 3,5,3'-triiodo-L-thyronine (T3). Antibodies (Ab) raised to NTBP in BALB/c mice were assayed for Ab-NTBP complex formation on HPLC TSK SW3000 molecular exclusion gels and found to be species-specific and non-cross-reactive with serum thyroid hormone-binding proteins. Most of the antibody activity was directed against two fractions of molecular weight (MW) 89 000 and 53 000, which were associated with thyroxine (T4)-binding activity. The 89 000 D T4-binding activity was shifted to a higher MW complex when incubated with specific antibody. Indirect immunofluorescence showed antibody activity against discrete, clumped chromatin sites, nuclear envelope and plasma membrane in hepatocytes. Intense fluorescence was also observed in the cells lining the hepatic sinusoids and in the cytoskeleton of bovine aortic endothelial cells in culture. The data suggest that thyroid hormone target cells contain extranuclear loci that share antigenic sites with NTBP and may also represent specific NTBP-like sites of thyroid hormone binding.     

Glutathione-S-transferases are major cytosolic thyroid hormone binding proteins

Thyroid hormone binding proteins of rat liver cytosol were characterized. Glutathione-S-transferases were identified among major cytosolic proteins adsorbed by thyroxine affinity matrices. The Ya and Yb subunits of the glutathione-S-transferases were also principal proteins of cytosol covalently labeled with 3,3',5-triiodo-L-thyronine (T3) or 3,3',5,5'-tetraiodo-L-thyronine (T4) by photoaffinity methods. T3 and T4, but not L-thyronine or iodinated tyrosines, were bound with high affinity to purified glutathione-S-transferases and were potent inhibitors of their enzymatic activities. These results suggest that glutathione-S-transferases have the potential to function in the intracellular binding and transport of thyroid hormones. The proteins provide a means for regulating the action and metabolism of thyroid hormones by acting as high capacity binding components.     

Solubilization and characterization of a membrane 3, 3', 5-triiodo-L-thyronine binding protein from rat pituitary tumor GH3 cells

To understand the mechanism by which T3 enters cells and carries out its biological functions membrane binding sites for 3, 3', 5-triiodo-L-thyronine were solubilized from rat pituitary tumor GH3 cells by detergents. Among three detergents tested, CHAPS is the best in preserving hormonal binding affinity and specificity. Least square analysis of the binding data show one class of binding site with a Kd of (6.35 +/- 1.27) nM and Bmax of (0.84 +/- 0.056) pmoles/50 micrograms protein. Hormone binding activity is lost by heating, pronase digestion and in the absence of NaCl. The pH optimum for binding is 7.0 and the binding activity is enhanced by dithiothreitol. The solubilization of membrane-associated thyroid hormone binding proteins will facilitate further characterization and exploration of their biological functions.     

Vitamin A and thyroxine carrier proteins in chicken plasma: steady-state control of the plasma level of free retinol-binding protein and free thyroxine.

1. The binding parameters of prealbumin-2 with retinol-binding protein and thyroxine (T4) revealed the existence of distinct and multiple sites for both retinol-binding protein and T4. 2. From the analysis of binding parameters of retinol-binding protein with prealbumin-2 it is clear that under steady-state conditions about 99% of the holo-retinol-binding protein remains bound to prealbumin-2. 3. Equilibrium dialysis studies on binding properties of thyroid hormones with prealbumin-2 revealed that it has a single high affinity site and three low affinity sites. 4. The occurrence of three carrier proteins for thyroid hormones, thyroxine-binding globulin, prealbumin-2 and albumin has been demonstrated. However, the chicken thyroxine-binding globulin differs from human thyroxine-binding globulin by being relatively less acidic and occurring at a two-fold lower concentration. But the thyroid hormone binding parameters are comparable. 5. Highly sensitive methods were developed for determination of T4 binding capacities of the various proteins and plasma level of total T4 by fractionation of carrier proteins and further quantitatively employing in electrophoresis and equilibrium dialysis. 6. The thyroxine-binding proteins were found to be of two types, one (viz., thyroxine-binding globulin) of great affinity but of low binding capacity, which mainly acts as reservoir of T4, and another (viz., prealbumin-2) of low affinity but of high binding capacity, which can participate predominantly in the control of the free T4 pool.     

Decrease in triiodothyronine binding sites in chick embryo erythrocytes during early development

Specific thyroid hormone (TH) binding sites have been detected in nuclei of erythrocytes obtained from developing chick embryos. The binding characteristics and relative affinities for TH analogs were those expected of TH receptors. Nuclear triiodothyronine (T3) saturation analysis was carried out in vitro by incubating intact erythrocytes in M199 medium with 3-200 pM [125I]T3 for 1 hr at 37 degrees C or 20-24 hr at 21 degrees C. Nuclei were obtained by centrifugation after lysing the erythrocytes in a stabilizing buffer containing 0.3% saponin, followed by addition of Triton X-100 (final concentration 0.2%) to minimize the nonspecific binding. Scatchard analysis of equilibrium binding data suggested that the nuclei possess a single class of binding sites. The binding is reversible and the rate of dissociation is temperature dependent. T3 and T4 appear to bind to the same sites, but the affinity of T3 was 16 times greater. Among TH analogs tested, Triac had the highest affinity followed by L-T3, D-T3, Tetrac, L-T4, D-T4, T2, and rT3. Serial studies performed on different days of chick embryogenesis demonstrated a rapid and significant decrease of the erythrocyte nuclear T3 receptor. On Day 5, the number of T3 binding sites was maximal at 1600 +/- 100 per nucleus. The number declined steadily until, by Day 20, it had reached about 60 +/- 10 sites/nucleus. RBC from adult and baby chickens had less than 1% as many binding sites as those from Day 5 embryos. There was no significant change in the affinity of the sites (Kd approximately equal to 20 pM at 37 degrees C). The reason for the loss of T3 binding sites during embryogenesis is not known. Since the plasma level of the TH increases during embryogenesis, this may reflect down regulation. Another possibility is that the change in erythrocyte population which occurs during this period involves production of erythrocytes which contain fewer T3 binding sites.     

A high affinity thyroid hormone binding protein in the cytosol of embryonic rat brain cells in primary cultures

A thyroid hormone binding protein(s) has been characterized in the cytosol of fetal rat brain cells in primary cultures. This protein is closely related to the one described in brain supernatants with respect to its electrophoretic mobility, binding kinetic parameters and estimated molecular weight (65 000 daltons). However, in contrast to the brain cytosolic binding protein, two classes of affinity sites for triiodothyronine (T3) and thyroxine (T4) have been demonstrated: a high affinity site (KA = 1.2-3.7(3) X 10(9) M-1 for T3 and KA = 3.7-5 X 10(8) M-1 for T4) and a low affinity site (KA = 0.8-1.4 X 10(8) M-1 for T3 and 1.6-2.9 X 10(7) M-1 for T4). The results are discussed with respect to their cellular significance.     

Identification of thyroid hormone receptors in rat liver nuclei by photoaffinity labeling with L-thyroxine and triiodo-L-thyronine

Photoaffinity labeling of rat liver nuclear extract with underivatized thyroid hormones was performed after incubation with 1 nM [3',5'-125I]thyroxine ([125I]T4) or [3'-125I]triiodothyronine [( 125I]T3) by irradiation with light above 300 nm. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the covalently photolabeled nuclear extract revealed four distinct hormone binding proteins of molecular masses 96, 56, 45, and 35 kilodaltons (kDa), respectively. Distribution of the hormone among these proteins was similar for T4 and T3. The 56- and 45-kDa proteins were the most prominently labeled. The specificity of the photoattachment of thyroid hormones to these nuclear proteins was verified by the irradiation of eight randomly chosen proteins and two proteins known to have thyroid hormone binding sites, human thyroxine binding globulin and bovine serum albumin. Only the latter two were photolabeled with [125I]T4. Competition studies performed by incubating nuclear extracts with [125I]T4 or [125I]T3 in the presence of increasing amounts of the corresponding unlabeled hormone (10-, 100-, and 1000-fold molar excess) demonstrated that (1) photoattachment of labeled T3 or T4 to the 56- and 45-kDa proteins was inhibited by 67-78% and 73-85%, respectively, after incubation with a 1000-fold molar excess of unlabeled hormone, (2) in the presence of lower molar excesses of the corresponding competitor (10- and 100-fold), photoattachment of labeled T3 or T4 to the 56- and 45-kDa receptors was gradually inhibited to a similar extent on both proteins, and (3) the 35- and 96-kDa proteins, although having thyroid hormone binding sites, display lower binding activities since the inhibition of photoattachment of labeled T3 or T4 by a 1000-fold molar excess of unlabeled hormone did not exceed 30-42% and 26-49%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

High affinity thyroid hormone binding sites on purified rat liver plasma membranes.

Two orders of saturable binding sites for L-T₃ were detected on purified rat liver plasma membranes--a high affinity, low capacity binding site with a Kd of 3.2 ± 0.5 nM, and a lower affinity, higher capacity site with a Kd of 220 ± 50 nM. Competition-inhibition studies revealed that both D-T₃ and L-T₄ (two compounds with lower biological potencies than L-T₃) were also less potent than L-T₃ in competing for these binding sites. The present studies demonstrate, therefore, the presence of specific thyroid hormone binding sites on rat liver plasma membranes. In addition, they suggest that these sites may have a role both in mediating the known effects of thyroid hormones on membrane functions, and in regulating the entry of thyroid hormones into target cells.     

A nuclear protein is required for thyroid hormone receptor binding to an inhibitory half-site in the epidermal growth factor receptor promoter.

The epidermal growth factor (EGF) receptor (EGFR) promoter is negatively regulated by thyroid hormone and retinoic acid. This regulation can be mapped to a 36-basepair GC-rich region of the promoter (EGFR P/E) that functions autonomously as a promoter and an enhancer when placed in front of the thymidine kinase gene TATA element. Direct high affinity binding of the thyroid hormone receptor (T3R) to this element requires a nuclear protein. Through ion exchange chromatography and gel filtration of HeLa nuclear extract, this activity was identified as a protein of approximately 67 kilodaltons. This protein did not bind to DNA alone, but greatly augmented T3R binding to the EGFR P/E sequence in gel mobility shift and DNA precipitation assays. When combined with the T3R auxillary protein (TRAP), the T3R migrated as a larger complex on the DNA. Chemical cross-linking identified this complex as a heterodimer between T3R and TRAP. T3R-TRAP binds to a 7-basepair site in the EGFR P/E (GGGACTC) that has weak homology to a consensus thyroid response element half-site. Thus, on this element, T3R-TRAP heterodimers contact the DNA primarily on a single site that comprises an inhibitory thyroid response element.