Assembly of a glucocorticoid receptor complex prior to DNA binding enhances its specific interaction with a glucocorticoid response element

Gel retardation analysis with full- and half-palindromic sequences using partially purified glucocorticoid receptor (GR) resulted in GR-glucocorticoid response element (GRE) species of identical mobilities, suggesting that formation of the dimeric GR protein complex is not catalyzed by DNA binding. These results are in contrast to the behavior of the isolated DNA binding domain of the glucocorticoid receptor where dimerization occurred on the GRE. Density gradient centrifugation of cytosolic GR resulted in two forms, a 4 S peak characteristic of the monomeric GR and a fraction which sediments at 6 S which is consistent with the observed size of the dimeric GR. These two forms were found to differ in their ability to bind to specific DNA sequences with the 6 S species having a higher affinity for a GRE. Taken together our results are consistent with a two-step model for hormone-induced transformation of GR: dissociation of the multimeric untransformed complex and dimerization of the GR to yield a high affinity DNA binding species.     

1H NMR studies of DNA recognition by the glucocorticoid receptor: complex of the DNA binding domain with a half-site response element.

The complex of the rat glucocorticoid receptor (GR) DNA binding domain (DBD) and half-site sequence of the consensus glucocorticoid response element (GRE) has been studied by two-dimensional 1H NMR spectroscopy. The DNA fragment is a 10 base-pair oligonucleotide, 5'd(GCTGTTCTGC)3'.5'd-(GCAGAACAGC)3', containing the stronger binding GRE half-site hexamer, with GC base pairs at each end. The 93-residue GR-DBD contains an 86-residue segment corresponding to residues 440-525 of the rat GR. Eleven NOE cross peaks between the protein and DNA have been identified, and changes in the chemical shift of the DNA protons upon complex formation have been analyzed. Using these protein-DNA contact points, it can be concluded that (i) the "recognition helix" formed by residues C460-E469 lies in the major groove of the DNA; (ii) the GR-DBD is oriented on the GRE half-site such that residues A477-D481, forming the so-called D-loop, are available for protein-protein interaction in the GR-DBD dimer on the intact consensus GRE; and (iii) the 5-methyl of the second thymine in the half-site and valine 462 interact, confirming indirect evidence [Truss et al. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 7180-7184; Mader et al. (1989) Nature 338, 271-274] that both play an important role in GR-DBD DNA binding. These findings are consistent with the model proposed by H?rd et al. [(1990) Science 249, 157-160] and the X-ray crystallographic complex structure determined by Luisi et al. [(1991) Nature 352, 497-505].     

Molecular dynamics simulations of the glucocorticoid receptor DNA-binding domain in complex with DNA and free in solution.

Molecular dynamics simulations have been performed on the glucocorticoid receptor DNA binding domain (GR DBD) in aqueous solution as a dimer in complex with DNA and as a free monomer. In the simulated complex, we find a slightly increased bending of the DNA helix axis compared with the crystal structure in the spacer region of DNA between the two half-sites that are recognized by GR DBD. The bend is mainly caused by an increased number of interactions between DNA and the N-terminal extended region of the sequence specifically bound monomer. The recognition helices of GR DBD are pulled further into the DNA major groove leading to a weakening of the intrahelical hydrogen bonds in the middle of the helices. Many ordered water molecules with long residence times are found at the intermolecular interfaces of the complex. The hydrogen-bonding networks (including water bridges) on either side of the DNA major groove involve residues that are highly conserved within the family of nuclear receptors. Very similar hydrogen-bonding networks are found in the estrogen receptor (ER) DBD in complex with DNA, which suggests that this is a common feature for proper positioning of the recognition helix in ER DBD and GR DBD.     

Decreased glucocorticoid receptor activity following glucocorticoid receptor antisense RNA gene fragment transfection.

Depression is often characterized by increased cortisol secretion caused by hyperactivity of the hypothalamic-pituitary-adrenal axis and by nonsuppression of cortisol secretion following dexamethasone administration. This hyperactivity of the hypothalamic-pituitary-adrenal axis could result from a reduced glucocorticoid receptor (GR) activity in neurons involved in its control. To investigate the effect of reduced neuronal GR levels, we have blocked cellular GR mRNA processing and/or translation by introduction of a complementary GR antisense RNA strand. Two cell lines were transfected with a reporter plasmid carrying the chloramphenicol acetyltransferase (CAT) gene under control of the mouse mammary tumor virus long terminal repeat (a glucocorticoid-inducible promoter). This gene construction permitted assay of the sensitivity of the cells to glucocorticoid hormones. Cells were also cotransfected with a plasmid containing 1,815 bp of GR cDNA inserted in the reverse orientation downstream from either a neurofilament gene promoter element or the Rous sarcoma virus promoter element. Northern (RNA) blot analysis demonstrated formation of GR antisense RNA strands. Measurement of the sensitivity of CAT activity to exogeneous dexamethasone showed that although dexamethasone increased CAT activity by as much as 13-fold in control incubations, expression of GR antisense RNA caused a 2- to 4-fold decrease in the CAT response to dexamethasone. Stable transfectants bearing the GR antisense gene fragment construction demonstrated a 50 to 70% decrease of functional GR levels compared with normal cells, as evidenced by a ligand-binding assay with the type II glucocorticoid receptor-specific ligand [3H]RU 28362. These results validate the use of antisense RNA to GR to decrease cellular response to glucocorticoids.     

DNA binding analysis of glucocorticoid receptor specificity mutants.

The glucocorticoid receptor (GR) DNA binding domain consists of several conserved amino acids and folds into two zinc finger-like structures. Previous transactivation experiments indicated that three amino acids residing in this region, Gly, Ser and Val, appear to be critical for target-site discrimination. Based on the solved crystal structure, these residues are at the beginning of an amphipathic alpha-helix that interacts with the DNA's major groove; of these, only valine, however, contacts DNA. In order to examine their functional role directly, we have substituted these residues for the corresponding amino acids from the estrogen receptor (ER), overexpressed and purified the mutant proteins, and assayed their binding specificity and affinity by gel mobility shifts using glucocorticoid or estrogen response elements (GRE or ERE, respectively) as DNA probes. We find that all three residues are indeed required to fully switch GR's specificity to an ERE. The contacting valine in GR is of primary importance. The corresponding residue in ER, alanine, is less important for specificity, while glutamic acid, four amino acids towards the N-terminus, is most critical for ER discrimination. Finally, we show that the GR DNA binding domain carrying all three ER-specific mutations has a significantly higher affinity for an ERE than the ER DNA binding domain itself. We interpret these results in the context of both the data presented here and the crystal structure of the GR DNA binding domain complexed to a GRE.     

Polarity of the ecdysone receptor complex interaction with the palindromic response element from the hsp27 gene promoter.

The functional 20-hydroxyecdysone (20E) receptor is a heterodimer of two members of the nuclear hormone receptors superfamily; the product of the EcR (EcR) and of the ultraspiracle (Usp) genes. As most of the natural 20E-response elements are highly degenerated palindromes, we were interested in determining whether or not such asymmetric elements could dictate the defined orientation of the Usp/EcR complex. We have investigated interaction of EcR and Usp DNA-binding domains (EcRDBD and UspDBD, respectively) with the palindromic response element from the hsp27 gene promoter (hsp27pal). The hsp27pal half-sites contribute differently to the binding of the heterodimer components; the 5' half-site exhibits higher affinity for both DBDs than the 3' half-site. This observation, along with data demonstrating that UspDBD exhibits approximate fourfold higher affinity to the 5' half-site than EcRDBD, suggest that UspDBD locates the EcRDBD/UspDBD heterocomplex in the defined orientation (5'-UspDBD-EcRDBD-3') on the hsp27pal sequence. The binding polarity onto hsp27pal is accompanied by different contribution of the UspDBD and EcRDBD C-terminal sequences to the DNA-binding and heterocomplex formation. This is supported by finding that deletion of the C-terminal of EcRDBD region corresponding to the putative A-helix severely decreased binding of the EcRDBD to the hsp27pal. In contrast, UspDBD in which corresponding residues were deleted exhibited the same hsp27pal binding pattern as the wild type UspDBD. Additional truncation comprising the putative T-box, resulted in a reduced binding of the mutated UspDBD. This truncation however, still allowed effective EcRDBD/UspDBD heterodimer formation. Finally we demonstrated that perfect palindromes, composed of two hsp27pal 5' half-sites (or of the related sequence) contain all of the structural information necessary for the anisotropic UspDBD/EcRDBD heterocomplex formation. However, the perfect palindromes bind isolated homomeric DBDs as well as their heterocomplex with higher affinity than imperfect hsp27pal. This is the first report indicating that natural 20E response elements, which with one exception are degenerated palindromes, may act as functionally asymmetric elements in a manner similar to the action of direct repeats in vertebrates.     

Association of the transformed glucocorticoid receptor with a cytoskeletal protein complex

In a recent paper we described a system in which glucocorticoid receptors associate with particulate complexes containing tubulin [Cancer Res. 49 (1989) 2222s–2229s]. When L cell cytosol is mixed with a microtubule stabilizing buffer and heated to 37°C, the receptor becomes associated with a complex that can be centrifuged out of solution at 150,000 g. In this work we show that the glucocorticoid receptor—cytoskeletal protein complex forms in a temperature and glutamate-dependent manner. Molybdate does not affect generation of the cytoskeletal protein complex but it inhibits association of the receptor with the complex. This suggests that transformation of the receptor to its DNA-binding form is required for interaction with the cytoskeletal complex. Colchicine has no effect on generation of the particulate complex or on the association of receptor with it, suggesting that formation of the complex does not represent a classic in vitro process of tubulin polymerization.     

FMS-like tyrosine kinase 3 interacts with the glucocorticoid receptor complex and affects glucocorticoid dependent signaling

The glucocorticoid receptor (GR) forms part of a multiprotein complex consisting of chaperones and proteins active in glucocorticoid signaling and other pathways. By immunoaffinity purification of GR, followed by Edman sequencing and Western blotting, we identified the FMS-like tyrosine kinase 3 (Flt3) as a GR-interacting protein in rat liver and hepatoma cells. Flt3 interacts with both non-liganded and liganded GR. The DNA-binding domain of GR is sufficient for Flt3 interaction as shown by GST-pull down experiments. Studies of the effects of Flt3 and its ligand FL in glucocorticoid-driven reporter-gene assays in Cos7 cells, show that co-transfection with Flt3 and FL potentiates glucocorticoid effects. Treatment with FL had no effect on GR location and Dex induced translocation of GR was unaffected by FL. In summary, GR and Flt3 interact, affecting GR signaling. This novel cross-talk between GR and a hematopoietic growth factor might also imply glucocorticoid effects on Flt3-mediated signaling.     

Structural determinants of a glucocorticoid receptor recognition element

Analysis of the relative inducibility of an extensive series of mutant glucocorticoid response elements (GREs) defines features critical to the constitution of an active GRE. Assuming that function as a GRE reflects binding of glucocorticoid receptor, our activity data are consistent with the recognition of the GRE as two hexamer half-sites, each half-site recognized by a single subunit of a receptor dimer, probably in a cooperative fashion. Integrity of both half-sites is necessary for an active element, and spacing of the half-sites is critical. The identity of 1 basepair within the hexamer half-site is unconstrained; the receptor probably makes no base-specific contacts at this position. In contrast, at other positions within the half-site, limited substitutions (if any) can be tolerated. These results along with data from certain insertion mutations suggest that the receptor recognizes each hexamer half-site as two separable subelements. A further implication is that the DNA-binding domain of the glucocorticoid receptor is composed of distinct subdomains, which interact with the subelements of the recognition sequence.     

Stoichiometric analysis of the specific interaction of the glucocorticoid receptor with DNA

Purified preparations of activated glucocorticoid X receptor complex (GR) contain a Mr 94,000 hormone-binding polypeptide co-purifying together with a Mr 72,000 non-hormone-binding polypeptide (Wrange, O., Okret, S., Radojcic, M., Carlstedt-Duke, J., and Gustafsson, J.-A. (1984) J. Biol. Chem. 259, 4534-4541). GR binds selectively to discrete regions of DNA in mouse mammary tumor virus (Payvar, F., DeFranco, D., Firestone, G.L., Edgar, B., Wrange, O., Okret, S., Gustafsson, J.-A., and Yamamoto, K. R. (1983) Cell 35, 381-392). Such GR-binding DNA fragments were used to measure the stoichiometry of GR to DNA. Quantitative DNaseI protection "footprinting" analysis was used to ensure that saturation conditions for specific DNA-binding were achieved. Glycerol density gradient centrifugation was used to quantitate Mr 94,000 binding to specific and nonspecific DNA sites. One Mr 94,000 entity was bound per specific DNA site. A modified GR purification procedure resulted in increased amounts of Mr 72,000 polypeptide (1.6:1, 94,000:72,000 molar ratio), compared to previous GR preparations. Glycerol gradient centrifugation followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the specific GR X DNA complex contained similar amounts of Mr 94,000 and Mr 72,000 polypeptide. It is as yet uncertain if the Mr 72,000 polypeptide is a functional subunit of GR or a co-purifying contaminant only.     

Thymocyte circular DNA excised from T cell receptor alpha-delta gene complex.

We have characterized thymocyte circular DNA excised from the T cell receptor alpha-delta gene complex. Some delta gene clones contained unusual recombinant structures derived from V-(D)-J joining: (i) a reciprocal joint of direct V to J delta joining, skipping the D delta segment; (ii) a V-D delta coding joint lacking an adjacent D delta-J delta coding joint; (iii) a V- D structure containing two D delta segments. Many of the alpha gen clones contained both coding and reciprocal joints of V alpha-to-J alpha joining on the same structure. Most of these coding joints were out of phase; however, in one clone there was an in-phase V-J alpha structure. Interestingly, some alpha gene clones contained the same V gene sequence as rearranged in the delta gene clone, indicating that the same V gene family, at least in part, could be utilized for both the alpha and delta gene systems.     

Analysis of Usp DNA binding domain targeting reveals critical determinants of the ecdysone receptor complex interaction with the response element.

The steroid hormone, 20-hydroxyecdysone (20E), directs Drosophila metamorphosis via a heterodimeric receptor formed by two members of the nuclear hormone receptors superfamily, the product of the EcR (EcR) and of the ultraspiracle (Usp) genes. Our previous study [Niedziela-Majka, A., Kochman, M., Ozyhar, A. (2000) Eur. J. Biochem. 267, 507-519] on EcR and Usp DNA-binding domains (EcRDBD and UspDBD, respectively) suggested that UspDBD may act as a specific anchor that preferentially binds the 5' half-site of the pseudo-palindromic response element from the hsp27 gene promoter and thus locates the heterocomplex in the defined orientation. Here, we analyzed in detail the determinants of the UspDBD interaction with the hsp27 element. The roles of individual amino acids in the putative DNA recognition alpha helix and the roles of the base pairs of the UspDBD target sequence have been probed by site-directed mutagenesis. The results show how the hsp27 element specifies UspDBD binding and thus the polar assembly of the UspDBD/EcRDBD heterocomplex. It is suggested how possible nucleotide deviations within the 5' half-site of the element may be used for the fine-tuning of the 20E-response element specificity and consequently the physiological response.     

Polymorphisms in the glucocorticoid receptor gene that modulate glucocorticoid sensitivity are associated with rheumatoid arthritis

Introduction  

The glucocorticoid receptor (GR) plays an important regulatory role in the immune system. Four polymorphisms in the GR gene are associated with differences in glucocorticoid (GC) sensitivity; the minor alleles of the polymorphisms N363 S and BclI are associated with relative hypersensitivity to GCs, while those of the polymorphisms ER22/23EK and 9β are associated with relative GC resistance. Because differences in GC sensitivity may influence immune effector functions, we examined whether these polymorphisms are associated with the susceptibility to develop Rheumatoid Arthritis (RA) and RA disease severity.     

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

Steroid-receptor complexes formed at low temperature and ionic strength do not bind to nuclei or chromatin. After a temporary exposure to high temperature, or ionic strength, or both, a fraction of them becomes activated (able to bind to nuclei). An assay of the activated form of the complex based upon titration with nuclei in excess was established. This assay was used to perform kinetic and equilibrium studies of the thermal activation of glucocorticoid-receptor complex in order to elucidate its mechanism. It was found that the reaction is of apparent first order and yields a monomolecular product. It thus probably consists of a conformational change in the steroid-receptor complex. The rate of activation is 1.37 +/- 0.06 X 10(-3) S-1 at 25 degrees. The free energy of thermodynamic activation (The word activation is used here in its usual thermodynamic meaning and not in the sense of receptor modification) of this reaction is greater than G = 21.3 Kcal. The corresponding enthalpy and entropy are respectively greater than H = 31.4 kcal and greater than S = 4 cal/degree. These positive and high values of greater than H and greater than S are very similar to those described for denaturation reactions of proteins suggesting that breakage of some noncovalent bonds could take place during activation. The reaction proceeds until approximately 60% of the complexes are activated. It was shown that this corresponds to an equilibrium between activated and nonactivated forms and not to the presence of a population of complexes unable to undergo activation. This equilibrium is not modified by temperature variations between 10 degrees and 30 degrees. It is possible to activate over 80% of the complexes when the activation is performed in the presence of excess acceptor, thus shifting the equilibrium. A similar situation is probably observed in situ in cells since 90% of the complexes are found in the nuclei when liver slices are incubated with hormone.     

Interaction of the activated cytoplasmic glucocorticoid hormone receptor complex with the nuclear envelope

Highly purified activated cytoplasmic glucocorticoid hormone receptor binds with high affinity to sites in the nuclear envelope. Nuclear envelope fragments can be isolated from purified chromatin. They bind activated cytoplasmic glucocorticoid receptor with the same equilibrium constant as nuclear envelopes. The presence of envelope components in chromatin is confirmed by the virtual identity of the gel electrophoretic glycoprotein pattern of nuclear envelope, chromatin nonhistones, and nuclear envelope fragments from chromatin.