Mechanism and kinetics of the thermal activation of glucocorticoid hormone receptor complex

DNA-binding properties of the ecdysteroid receptor-complex (EcR/USP) of the epithelial cell line from Chironomus tentans

DNA-binding features of EcR and USP were investigated using a 0.4 M NaCl extract of the epithelial cell line of Chironomus tentans by means of electrophoretic mobility shift assays (EMSAs). It is shown that the DNA-binding is enhanced by hormone administration and that in the hormone dependent shift, both EcR and USP, are present. Furthermore, we demonstrate that under these conditions, EcR/USP form a unique complex on inverted repeat elements (PAL1 and hsp27-EcRE), while on direct repeat elements (DR1-5), a second complex with higher mobility is formed. In this second complex, neither EcR nor USP are present. Thus, an additional difference between PAL1 and DR-elements is the competition of other factors for DR-elements, modulating its function as an EcRE. A competition EMSA, using PAL1 as radiolabeled probe, reveals the following order of binding strength: PAL1>DR4/5>DR1>DR2/3/hsp27. Surprisingly, using DR1 as radiolabeled probe, shows a different order of binding strength: DR1>DR2>DR3/4/5/PAL1>hsp27. This indicates that the complexes formed on PAL1 are not identical to the ones formed on DR1 and that both are not easily convertible. Furthermore, the affinity of the EcR/USP complex may be altered under various conditions or by interaction with cofactors. Upon hormone administration, DNA binding of the receptor complex is enhanced, but the difference to hormone-free binding reactions decreases in course of time, indicating an additional hormone independent activation. Arch.

Steroid receptor interactions with heat shock protein and immunophilin chaperones

We have provided a historical perspective on a body of steroid receptor research dealing with the structure and physiological significance of the untransformed 9S receptor that has often confused both novice and expert investigators. The frequent controversies and equivocations of earlier studies were due to the fact that the native, hormone-free state of these receptors is a large multiprotein complex that resisted description for many years because of its unstable and dynamic nature. The untransformed 9S state of the steroid and dioxin receptors has provided a unique system for studying the function of the ubiquitous, abundant, and conserved heat shock protein, hsp90. The hormonal control of receptor association with hsp90 provided a method of manipulating the receptor heterocomplex in a manner that was physiologically meaningful. For several steroid receptors, binding to hsp90 was required for the receptor to be in a native hormone-binding state, and for all of the receptors, hormone binding promoted dissociation of the receptor from hsp90 and conversion of the receptor to the DNA-binding state. Although the complexes between tyrosine kinases and hsp90 were discovered earlier, the hormonal regulation or steroid receptor association with hsp90 permitted much more rapid and facile study of hsp90 function. The observations that hsp90 binds to the receptors through their HBDs and that these domains can be fused to structurally different proteins bringing their function under hormonal control provided a powerful linkage between the hormonal regulation of receptor binding to hsp90 and the initial step in steroid hormone action. Because the 9S receptor hsp90 heterocomplexes could be physically stabilized by molybdate, their protein composition could be readily studied, and it became clear that these complexes are multiprotein structures containing a number of unique proteins, such as FKBP51, FKBP52, CyP-40, and p23, that were discovered because of their presence in these structures. Further analysis showed that hsp90 itself exists in a variety of native multiprotein heterocomplexes independent of steroid receptors and other 'substrate' proteins. Cell-free systems can now be used to study the formation of receptor heterocomplexes. As we outlined in the scheme of Fig. 1, the multicomponent receptor-hsp90 heterocomplex assembly system is being reconstituted, and the importance of individual proteins, such as hsp70, p60, and p23, in the assembly process is becoming recognized. It should be noted that our understanding of the mechanism and purpose of steroid receptor heterocomplex assembly is still at an early stage. We can now speculate on the roles of receptor-associated proteins in receptor action, both as individuals and as a group, but their actual functions are still vague or unknown. We can make realistic models about the chaperoning and trafficking of steroid receptors, but we don't yet know how these processes occur, we don't know where chaperoning occurs in the cell (e.g. Is it limited to the cytoplasm? Is it a diffuse process or does chaperoning occur in association with structural elements?), and, with the exception of the requirement for hormone binding, we don't know the extent to which the hsp90-based chaperone system impacts on steroid hormone action. It is not yet clear how far the discovery of this hsp90 heterocomplex assembly system will be extended to the development of a general understanding of protein processing in the cell. Because this assembly system is apparently present in all eukaryotic cells, it probably performs an essential function for many proteins. The bacterial homolog of hsp90 is not an essential protein, but hsp90 is essential in eukaryotes, and recent studies indicate that the development of the cell nucleus from prokaryotic progenitors was accompanied by the duplication of genes for hsp90 and hsp70 (698). (ABSTRACT TRUNCATED)

Characterization of non-liganded glucocorticoid receptor in rat liver cytosol using indirect competitive enzyme-linked immunosorbent assay

We have previously shown that the purified or unfractionated cytosolic, activated glucocorticoid receptor of rat liver consists of a polypeptide with a Stokes radius of approximately 6 nm, a sedimentation coefficient of 4S and a molecular mass of approximately 90,000 Daltons. We have confirmed previous observations by other authors that if sodium molybdate is introduced into the cytosol preparation buffer the non-activated glucocorticoid receptor appears as an 8 nm, 9S species with an apparent molecular mass of 330,000 Daltons. In order to study the physicochemical parameters of the glucocorticoid receptor prior to ligand binding, we have used an enzyme-linked immunosorbent assay (ELISA) based on antibodies raised in rabbits against the purified activated glucocorticoid receptor. In isotonic buffer, the non-liganded glucocorticoid receptor was shown to have a Stokes radius of 6 nm in the absence and 8 nm in the presence of molybdate. Furthermore, experimental conditions known to result in activation of the glucocorticoid receptor complex (increased ionic strength, increased temperature) did not lead to activation of the 6 nm non-liganded glucocorticoid receptor as judged from the lack of binding of the treated, non-liganded receptor to DNA-cellulose. The existence of both 6 and 8 nm forms of nonactivated, non-liganded glucocorticoid receptor in vitro suggests that dissociation of an 8 nm form to a 6 nm form, if it occurs in vivo, is probably not the only molecular event constituting the activation of the glucocorticoid receptor.

Cortisol receptors and inducibility of glutamine synthetase in embryonic retina

Glutamine synthetase (GS) is a marker enzyme for Müller glia cells in neural retina. In chick embryo retina GS begins to increase sharply on the 16th day of development, but can be precociously induced by premature supply of the inducer, cortisol, already on the 8th day. At this stage GS inducibility is low, but it increases progressively with embryonic age. We investigated whether there was a corresponding age-dependent increase of cortisol-binding molecules (cortisol receptors) and found that their level is highest in the early retina and decreases with development. In light of this inverse relationship, we examined whether functional characteristics of these receptors change with age, but detected no differences. In in vitro tests, receptors from older retina translocated cortisol into nuclei from young retina, and vice versa, with similar effectiveness. Also, cortisol receptors from liver cells (which differ from retina receptors) can translocate the hormone into retina nuclei, and vice versa. These findings indicate that translocation of cortisol receptors is neither tissue-specific or age-dependent, nor is it conditional on the total amount of receptors normally present in cells. Therefore, the age-dependent increase of GS inducibility in embryonic retina cannot be directly related to quantitative or functional differences of cortisol receptors and is evidently controlled primarily at the gene level. The very large amount of cortisol-binding molecules in early embryonic retina raises the possibility that they play some role in early differentiation of retina cells unrelated to hormone binding.

Salt-induced transformation of the glucocorticoid-receptor complex in the presence of molybdate

The glucocorticoid hormone-receptor complex has been shown to exist in several forms. The transformation status of various forms of the complex isolated from rat thymus cytosol in the presence of molybdate was determined. The non-transformed receptor had a higher affinity for DEAE-cellulose than the transformed receptor. The rate at which the non-transformed complex was transformed to a smaller form with a low affinity for DEAE-cellulose by exposure to salt was greater in the absence of molybdate than in its presence. We conclude that salt-induced transformation of the complex is retarded but not prevented by molybdate and is associated with subunit dissociation.

Transformed mouse glucocorticoid receptor: generation and interconversion of the 3.8S, monomeric and 5.2S, oligomeric species

Recent studies have implicated subunit dissociation as a possible mechanism of glucocorticoid receptor transformation [Vedeckis, W.V. (1983) Biochemistry 22, 1983-1989; Raaka, B.M., & Samuels, H.H. (1983) J. Biol. Chem. 258, 417-425]. While it is becoming increasingly evident that the untransformed (non-nuclear-binding and non-DNA-binding) glucocorticoid receptor from mouse AtT-20 cells is a 9.1S oligomeric species (Mr 290 000-360 000), two transformed species have been described for this receptor. One of these has a sedimentation coefficient of 5.2 S (on molybdate-containing gradients), while the smallest nonproteolyzed, monomeric subunit is 3.8 S. The present study was undertaken to determine which is the most common form generated both in vitro and in vivo and the structural relationship between these two forms. A wide variety of in vitro transformation protocols all yielded the 5.2S form when analyzed on molybdate-containing sucrose gradients by using a vertical tube rotor. Kinetic studies showed that the appearance of the 5.2S form coincided precisely with the appearance of transformed receptor, as defined by DEAE-cellulose elution. Furthermore, when the 3.8S and 5.2S peaks were collected from sucrose gradients directly, they were transformed receptors as defined by both DEAE-cellulose and DNA-cellulose chromatography, while the 9.1S sucrose gradient peak was untransformed when the same criteria were used. The 3.8S monomer, when isolated from high-salt sucrose gradients and then desalted, reverted to the 5.2S form (molybdate-containing gradients) or a 6.6S form (low-salt, molybdate-free gradients).(ABSTRACT TRUNCATED AT 250 WORDS)

Evidence that pH induced activation of the rat hepatic glucocorticoid-receptor complex is irreversible

The possible reversibility of pH induced activation of the glucocorticoid-receptor complex was studied. Generally, this was accomplished by activating rat liver cytosol at pH 8.5 (15 degrees C, 30 min), and then returning it to pH 6.5 for a second incubation (15 degrees C, 30 min). Activation was quantitated by measuring the binding of [3H]triamcinolone acetonide [( 3H]TA)-receptor complexes to DNA-cellulose. When cytosol was incubated at pH 6.5, only 4.1% of the [3H]TA-receptor complexes bound to DNA-cellulose. However, 39.2% of the complexes bound when the cytosol was pH activated. When pH activation was followed by a second incubation at pH 6.5, 47.0% of the steroid-receptor complexes bound. Thus, according to the DNA-cellulose binding assay, pH induced activation was irreversible. In order to visualize both activated and unactivated [3H]TA-receptor complexes during this process, diethylaminoethyl (DEAE)-cellulose chromatography was performed. When cytosol was incubated at pH 6.5, only 19.6% of the [3H]TA-receptor complexes were eluted in the activated form from DEAE-cellulose. However, 67.5% of the complexes were eluted in the activated form when cytosol was pH activated. When pH activation was followed by a second incubation at pH 6.5, 74.9% of the steroid-receptor complexes were eluted in the activated form. Thus, DEAE-cellulose chromatography also showed that pH induced activation was irreversible. This is the first known report that the combination of DNA-cellulose binding and DEAE-cellulose chromatography have been used to study pH induced activation of the glucocorticoid-receptor complex. By these criteria, we conclude that in vitro pH induced activation is irreversible.

Kinetic analyses of activation-induced changes in the hydrodynamic and surface properties of the glucocorticoid-receptor complex in mouse brain

Unactivated, molybdate-stabilized, [3H]triamcinolone acetonide-labeled, glucocorticoid receptors from mouse whole brain were activated by removal of the molybdate and incubation at 22 degrees C for 1.5 to 24 min and then rapidly quenched at 0 degrees C with molybdate. The loss of the 9.2 S (unactivated) form of the [3H]TA-receptor complex and the concomitant formation of the 3.8 S (activated) form displayed first-order kinetics with a half-time of less than two min. The increase in the 3.8 S form correlated nearly perfectly with an increased binding to DNA-cellulose, and with a decreased and increased adsorption to DEAE-cellulose and glass fiber filters, respectively. The changes in adsorption to these filters, which occurred at a faster rate than did the changes in binding to DNA-C, are thought to reflect an increase in the relative number of positive charges and hydrophobic groups on the surface of the activated complex.

Temperature-dependent kinetic correlates of the activation of the glucocorticoid-receptor complex

The effects of temperature on the kinetics of activation were studied in [3H]triamcinolone acetonide[( 3H]TA)-labeled cytosol preparations from mouse whole brain. After removal of unbound [3H]TA and molybdate (which prevents activation) from the unactivated steroid-receptor complex by gel exclusion chromatography, activation was initiated by incubation at 6-30 degrees C for 0.75-24 min and then rapidly quenched at -5 degrees C with Na2MoO4 (20 mM final concentration). The loss of the 9.2S (unactivated) form of the [3H]TA-receptor complex and the concomitant formation of the 3.8S (activated) form increased dramatically with increases in the activation temperature. These hydrodynamic changes were correlated directly with rapid time- and temperature-dependent increases in the binding of [3H]TA-labeled cytosol to DNA-cellulose (DNA-C). Further analyses of these data revealed a greater than 50-fold increase in the apparent first-order rate constant for the increased binding to DNA-C as the activation temperature was increased from 6 degrees C to 30 degrees C. An Arrhenius plot of these temperature-dependent kinetic constants revealed an energy of activation of 116 kJ. These data support a proposed model for activation of the glucocorticoid-receptor complex that includes the splitting of a 297 kDa, unactivated species into a 92 kDa, activated species.

Mechanisms of glucocorticoid hormone action

This work summarizes some of our studies of the mechanisms of glucocorticoid action, including aspects of steroid binding to receptors, the activation of glucocorticoid-receptor complexes and the regulation of expression of endogenous and transferred glucocorticoid-responsive genes. Studies of the receptor-steroid interaction support the notion that steroid entry is passive. A comparative analysis of binding in isolated cytosol and intact cells suggests that the initial receptor-steroid binding reaction and not subsequent steps such as activation and nuclear binding, is predominantly responsible for the high-affinity state that is generated. The binding is driven by entropy and enthalpy changes at low temperature; at higher temperatures it is driven by entropy changes, with enthalpy working against it. Studies of the activation of the receptor-glucocorticoid complex with the use of highly purified receptors suggest that this step is associated with a change in charge of the receptor-glucocorticoid complex (such as would occur with a dephosphorylation reaction), whereas the data do not support the notion that dissociation of a bound RNA or of receptor oligomers is responsible for generating the nuclear- and DNA-binding activity of the complex. Studies of the regulation by glucocorticoids of expression of the endogenous rat growth hormone (rGH) gene in cultured rat pituitary tumor (GC, GH3D6) cells suggest that glucocorticoids increase the expression of this gene by multiple mechanisms. First, there is a modest direct stimulation of transcription by a mechanism(s) that does not depend on protein synthesis; however, if the cells have been exposed to thyroid hormone for several hours, the steroid exerts a much greater increase in rGH pre-mRNA levels. Secondly, the steroid appears to stimulate some relatively stable function or functions that increase the ability of thyroid hormone to increase rGH levels. Thirdly, the steroid probably increases rGH mRNA stability, since the fold-increases in rGH mRNA exceed those of transcription. Finally, the steroid may, by unknown mechanisms, affect rGH mRNA polyadenylation. The gene transfer experiments utilized the rat and human (h) GH genes and hybrid genes containing either rGH and Herpes Simplex virus thymidine kinase (TK) gene sequences or the human metallothionein-IIA (hMT-IIA) and TK gene sequences. The steroid was found to regulate hMT-IIA gene expression in all glucocorticoid-responsive cell types tested by actions on its 5'-flanking DNA. By contrast, the glucocorticoid regulated GH gene expression in some but not all glucocorticoid-responsive cell types.(ABSTRACT TRUNCATED AT 400 WORDS)

Kinetic and thermodynamic evidence of a molybdate interaction with glucocorticoid receptor in calf thymus

The effect of molybdate on the kinetic and thermodynamic properties of the dexamethasone-receptor interaction was studied in calf thymus cytosol. In the presence of molybdate both the equilibrium binding studies and the association and dissociation experiments reveal a significantly lower affinity of the receptor for [3]dexamethasone. At 0 degrees C the equilibrium dissociation constant increases from 0.8 nM to 1.8 nM, the association rate constant shifts from 1.5 X 10(8) M-1 h-1 to 0.2 X 10(8) M-1 h-1, whereas the rate of dissociation of the untransformed receptor increases from 0.04 h-1 to 1.1 h-1 in the molybdate-containing buffer. All these effects appear dependent on the concentration of molybdate but the dissociation of the transformed receptor (0.01 h-1) is unaffected. The enthalpy for the association, delta H not equal to, increases at least twofold whereas the entropy, both for the association (delta S not equal to = -25 to +104 J K-1 mol-1) and for the equilibrium (delta S degrees = -100 to +38 J K-1 mol-1), is markedly influenced by the presence of molybdate. Taken all together these data suggest that molybdate interacts with the receptor molecule turning it into a form that displays low affinity for steroid, in addition to the well-documented incapacity to transform itself. This fact leads us to think that both the binding and the transformation are the expression of conformational modifications involving molybdate-sensitive groups.

Activation and changes in the sedimentation properties of rat liver glucocorticoid receptor

The glucocorticoid receptor in rat liver cytosol was studied by sucrose gradient sedimentation, DEAE-Sephadex A-50 column chromatography and DNA-cellulose binding in order to assign specific hydrodynamic properties to both the unactivated and the activated glucocorticoid--receptor complex with [3H]-dexamethasone. Activation was effected by heat, NaCl (0.4 M) or KSCN (0.1 M) treatment. The state of activation was judged by both DNA-cellulose binding and DEAE-Sephadex A-50 anion exchange chromatography. In isotonic phosphate buffer, unactivated and activated glucocorticoid--receptor complex sedimented as a 5 S and a 4 S peak, respectively. This 5 S-4 S transformation was blocked by sodium molybdate. In hypotonic phosphate buffer, both the unactivated and the activated glucocorticoid--receptor complex assumed higher s values due to aggregation. The activated complex (4 S) yielded aggregates of 5-6 S in a reversible manner, neither complex being affected by sodium molybdate. The unactivated complex was shown to assume two distinct aggregation states of 6 S and 8-9 S, which yielded a 10-11 S heavy aggregate upon addition of molybdate. This effect on the unactivated glucocorticoid--receptor complex was readily reversed by removing the molybdate. Aggregation at low ionic strength was promoted by a low mol. wt. component(s), separated from cytosol by gel filtration through Sephadex G-10. The state of aggregation had no pronounced effect on the DNA binding properties of the activated forms or on the sensitivity of the unactivated forms to molybdate.

Heterogeneity of the glucocorticoid receptors: molecular transformations during activation, detected by electrofocusing

Isoelectric focusing (IEF) of glucocorticoid receptor (GR) of the neural retina of the 14-day chick embryo was conducted under conditions that yielded quantitative recovery of binding activity. IEF of the cytosol, equilibrated with [3H]triamcinolone acetonide (TA) at 0-2 degrees C yielded three major TA-GR components with apparent isoelectric points (pI') of 5.4 +/- 0.3, 6.5 +/- 0.2, and 7.6 +/- 0.3, designated as I, II, and III, respectively. During temperature-induced activation (incubation at 30 degrees C for 60 min, in the presence of free [3H]TA and 0.15 M KCl), approximately 25% of the specifically bound TA was irreversibly lost. IEF reveals that this loss is accounted for by the complete loss of binding from I. During activation, II also decreases but correspondingly III increases, i.e., the sum of II and III remains unchanged. Only the bound TA of I is sensitive to the addition of KCl (a promoter of activation). This sensitivity of I is temperature dependent. Molybdate (an inhibitor of activation) protects the bound TA of I and suppresses the formation of III. These two effects of molybdate diminish simultaneously when the temperature is increased to 30 degrees C. III preferentially exhibits binding activity to nuclei. The data suggest that (i) the glucocorticoid-free cytosol contains two GRs, I and II, with possibly two different functions; (ii) activation involves the loss of bound TA from I and the transformation of II to III with increased pI; (iii) these two molecular events in GR activation are interdependent.

Activation and deactivation of the glucocorticoid hormone-receptor complex

Cytosol glucocorticoid receptors acquired the ability to bind to DNA-cellulose on incubation at 25-37 degrees C and/or in media of high ionic strength (0.3 M KCl). However, this activation was transient only. It was followed by deactivation whose rate was also dependent on incubation temperature and on the presence of potassium chloride. Deactivation resulted in a decreased but non-zero binding to DNA-cellulose. Specific triamcinolone acetonide binding to the receptor protein was not lost under the same conditions. Deactivation commenced before it became apparent, probably together with activation. Preactivated complex underwent deactivation even in conditions that would not allow significant decrease in DNA-cellulose binding without previous incubation at 37 degrees C. In contrast to previous reports it was found that fast activation/deactivation took place in the presence of 4 mM Ca2+. Molybdate ions slow down both activation and deactivation, but do not prevent activation by heat. Heat activated/deactivated complex differed in size from both non-activated and Ca2+-deactivated complexes. This finding suggests that heat and Ca2+-induced deactivation follow different mechanisms.

Changes in net charge of glucocorticoid receptors by activation, and evidence for a biphasic activation kinetics

The kinetics of glucocorticoid receptor activation and the changes in molecular properties of the receptors by the activation were studied, employing aqueous two-phase partitioning of rat thymocyte, rat liver and mouse S49.1 lymphoma cell cytosol labelled with tritiated glucocorticoid. By a mathematical analysis of the time-course of the receptor partition coefficient during activation, we demonstrate that at least two different receptor conversions take place during this process. Partitionings at conditions excluding receptor aggregation allowed an evaluation of differences in net charge between activated and non-activated forms of native and chymotrypsin-treated receptors. The net charge of the chymotrypsinized receptor changes little by the activation, being between 0 and -10 at pH 8 both in the non-activated and the activated state. In contrast, the activation changes the net charge of the native receptor from around -50 to around -10.

Transformation of the estrogen-receptor complex from chick oviduct in 2 steps

Salt treatment of the cytoplasmic estradiol-receptor complex from chick oviduct induces a strong affinity of the complex for DNA-cellulose and phenyl-sepharose. This process is called activation. Binding to heparin- and lysozyme-sepharose is also observed with the untreated complex. But, the salt treatment, additional binding of the complex to these adsorbents is seen. The increased ability of the complex to bind to polyanions and polycations is destroyed by mild trypsination. The binding to the hydrophobic adsorbent is not affected by this treatment. Neither a change of the sedimentation constant nor of the size of the receptor protein is observed after salt treatment in the cold. After binding of the salt-activated estradiol-receptor complex to DNA-cellulose in the cold, an increase of its sedimentation constant and its size, as measured by density-gradient centrifugation and agarose gel chromatography, resp., becomes apparent. A similar phenomenon is observed after binding to DEAE-cellulose and to some extent after binding to heparin-sepharose. The nuclear complex seems to have the same sedimentation constant as the cytoplasmic complex eluted from DNA-cellulose. The sedimentation constant of the nuclear complex is not changed after DNA-cellulose chromatography. The cytoplasmic progesterone-receptor complex from the same tissue, i.e. the oviduct, does not show any change of size. Thus the well-known process of transformation can now be separated into 2 steps. (1) Activation of the estradiol-receptor complex for its binding to various adsorbents in vitro and probably to its acceptor site(s) in vivo. (2) Increase of receptor size. This second step seems to be a special property of the estradiol-receptor complex. Its physiological significance is unclear.

Activated steroid-receptor complex. Comparison of assays using DNA-cellulose or homologous nuclei

When soluble steroid-receptor complexes are exposed to DNA-cellulose only activated complexes bind. The specificity of the binding was shown by its dependence on the presence of hormone during activation. However, prolonged incubation of non-activated steroid-receptor complexes with DNA-cellulose led to a progressive activation of these complexes. When the same hepatic cytosol containing heat-activated [3H]triamcinolone acetonide-receptor complexes was titrated by high concentrations of nuclei or DNA-cellulose the former bound 75% of the complexes, the later only 40%. This decreased binding was due on the one hand to a lower initial interaction between DNA-cellulose and activated complexes than between nuclei and these complexes and on the other hand to increased losses during washes when DNA-cellulose was used. For these reasons nuclei and not DNA-cellulose should be used when accurate measurements of the concentration of activated complexes are required. When only comparative data are needed DNA-cellulose may, however, be employed.

Competitive binding studies with glucocorticoid receptors from rat-thymus cells: differential temperature-dependence of steroid binding

Competitive steroid-binding studies were performed with intact rat thymus cells and with cytosol preparations at different temperatures using [1,2-3H]dexamethasone as the labelled ligand. Steroids lacking a 17 alpha-hydroxyl group, such as corticosterone, were better able to compete with [1,2-3H]dexamethasone for binding to glucocorticoid receptors at 0 degrees C than compounds containing a 17 alpha-hydroxyl substituent, such as cortisol. At 37 degrees C the reverse was true. This temperature-dependent change in relative affinities appeared to be unrelated to steroid metabolism or receptor activation, and to depend only on the thermodynamic parameters of the steroid--receptor interaction. Relative biological activities for different steroids agree more closely with the relative affinities determined at 37 degrees C than with those determined at lower temperatures.

Factors influencing association of glucocorticoid receptor-steroid complexes with nuclei, chromatin, and DNA: interpretation of binding data

Attempts to reconstruct, in a test tube, the steroid-hormone system of a responsive cell are fraught with enumerable difficulties. In this chapter I have attempted to point out some of the factors that affect receptor-steroid complexes and their interactions with acceptors. In most cases there is a quantitative influence of these factors on the level of steroid complex binding to acceptors. In some cases, selected experimental designs that neglect these factors and methods of presenting the observed data may lead to artifactual conclusions. Several of these problems should disappear when the prospect of pure receptor-steroid complexes [127, 147, 150, 181, 247, 248] becomes a common occurrence. Nevertheless much has already been learned about the interactions of complexes with acceptors, which in turn have been used to help formulate models of steroid-hormone action.

Comparison of glucocorticoid-receptor complex binding to nuclei and DNA cellulose. Evidence for different forms of interaction

Binding of dexamethasone . receptors with isolated nuclei, DNA-cellulose and cellulose has been compared with respect to dependence on salt concentration and resistance to KCl extraction and DNAse I digestion. A solution of cytoplasmic dexamethasone . receptor complexes was prepared by the incubation of rat thymus cells with steroid at 3 degrees C and breaking the cells by hypotonic lysis. Activation of the complexes was accomplished by warming the solution at 25 degrees C for 15 min. Activation significantly increased the ability of dexamethasone . receptors to bind to nuclei and DNA-cellulose but not to cellulose. Dexamethasone-receptor complexes bound to nuclei at 3 degrees C are completely resistant to extraction with 0.1 M KCl, 76% resistant to 0.2 M KCl and 20% resistant to 0.4 M KCl. Dexamethasone . receptors bound to DNA-cellulose are 45% resistant to extraction with 0.1 M and 0.2 M KCl and 29% resistant to 0.4 M KCl extraction. Cellulose-bound dexamethasone . receptors are not resistant to any of these extractions. DNAase I treatment releases 60% of the dexamethasone . receptors bound to DNA-cellulose but only 13% of those bound to nuclei, though at least 60% of the nuclear DNA is solubilized. The presence of 0.15 M KCl decreases binding of activated dexamethasone . receptors to nuclei by 73% but to DNA-cellulose by only 17%. Pretreatment of nuclei with 0.1--0.4 M KCl reduces their capacity to bind activated dexamethasone . receptors by 90% whereas similar treatment reduces the capacity of DNA-cellulose to bind dexamethasone . receptors by only 29%. Nuclei extracted with 0.1 M KCl appear to have a limited capacity to accept dexamethasone . receptors. These studies demonstrate that binding of dexamethasone . receptors to nuclei and DNA-cellulose differs by (a) the higher resistance of nuclear complexes to KCl and DNAase I treatment; (b) the much greater sensitivity of nuclei to KCl treatment.

Factors modifying equilibrium between activated and non-activated forms of steroid-receptor complexes

Steroid-receptor complexes formed in concentrated cytosol at low temperature, low ionic strength and neutral pH are unable to bind to nuclei. Various procedures are known to promote their 'activation'. In the present work it is shown that an increase in temperature only enhances the rate of the reaction whereas no change in the equilibrium between activated and non-activated complexes is observed. On the contrary an increase in ionic strength or pH, as well as a removal of a low-molecular-weight inhibitor, not only accelerate the reaction but also increase the concentration of activated complexes at equilibrium. Using two steroids differing 3-fold in their affinity for the receptor, no difference was seen in the effect of the bound steroid on receptor activation. When combining various activation procedures it was observed that they acted independently of each other and additively. In all cases they retained their property of either modifying only the rate of the reaction or both its rate and equilibrium. Using changes in pH, it was also possible to induce shifts in the equilibrium between activated and non-activated complexes. After activation at pH 6.5, a first equilibrium was attained. When the pH was increased to 8 the equilibrium was displaced towards higher concentrations of activated complexes. A lowering of the pH resulted in a reversal of steroid-receptor complexes from the activated to the non-activated state. To clearly establish that this was not due to irreversible damage of the receptor, which would render it unable to bind to nuclei, it was shown that the complexes which had reverted to the non-activated state were still susceptible to activation. Regulatory events may thus exist which, for a given level of hormone and receptor, modulate the concentration of activated steroid-receptor complexes.

Activation of the rat liver glucocorticoid--receptor complex

The rat liver glucorcorticoid receptor has been activated using three procedures: heat, gel filtration, and dilution. With time after heat activation the steroid--receptor complex loses its capacity to bind to DNA--cellulose, while receptor activated by Sephadex G-25 and by dilution maintains DNA--cellulose binding capacity. The rates of steroid dissociation from nonactivated and activated receptor and essentially identical. However, nonactivated receptor is capable of rebinding steroid, while activated receptor has a reduced capacity to rebind steroid. The results of the gel filtration and dilution studies suggest that a low-molecular-weight factor(s) exists in rat liver cytosol which is involved in the process of activation.