Cooperative interaction of oestrogen receptor 'zinc finger' domain polypeptides on DNA binding

DNA recognition by the androgen receptor: evidence for an alternative DNA-dependent dimerization, and an active role of sequences flanking the response element on transactivation

The androgen receptor has a subset of target DNA sequences, which are not recognized by any other steroid receptors. The androgen selectivity of these sequences was proposed to be the consequence of the ability of the androgen receptor to dimerize on direct repeats of 5'-TGTTCT-3'-like sequences. This is in contrast with the classical non-selective elements consisting of inverted repeats of the 5'-TGTTCT-3' elements separated by three nucleotides and which are recognized by other steroid receptors in addition to the androgen receptor. We demonstrate that while the DNA-binding domain of the oestrogen receptor is unable to dimerize on direct repeats, dimeric binding can be rescued by replacing the second Zn finger and part of the hinge region by the corresponding fragment of the androgen receptor, but not the glucocorticoid receptor. In this study, we investigate the androgen receptor binding to all natural androgen-selective response elements described so far. We show that a 12-amino acid C-terminal extension of the DNA-binding domain is required for high-affinity binding of the androgen receptor to all these elements. For one androgen-specific low-affinity binding site, the flanking sequences do not contribute to the in vitro affinity of the androgen receptor DNA-binding domain. Surprisingly, however, they control the transcriptional activity of the androgen receptor in transient transfection experiments. In conclusion, we give evidence that the alternative DNA-dependent dimerization of the androgen receptor on direct repeats is a general mechanism for androgen specificity in which the second Zn finger and hinge region are involved. In addition, the sequences flanking an androgen-response element can control the activity of the androgen receptor.

Effect of redox conditions on the DNA-binding efficiency of the retinoic acid receptor zinc-finger

Retinoic acid and its derivatives are involved in many important biological processes. In the present study, we have shown that the DNA binding domain of the retinoic acid receptor, which contains two zinc fingers with the Zn(II) tetrahedrally coordinated by four Cys, is susceptible to intracellularly relevant oxidizing agents. In the presence of hydrogen peroxide or hypochlorite, the zinc-finger DNA binding activity was abolished in a concentration dependent manner. The loss of DNA binding activity was correlated with the release of Zn(II) from the zinc-finger motif as a consequence of Zn(II)-thiolate bond oxidation. A combination of glutathione and Zn(II) was able to restore the activity, suggesting that oxidation of the zinc-finger by hydrogen peroxide or hypochlorite resulted in the formation of disulfide bonds between the Cys present in the Zn(II)-binding motif. Our results indicate that in situations of oxidative-stress zinc-finger containing transcription factors may be particularly susceptible to oxidation, resulting in the disruption of control and regulation of gene expression.

Alteration of zif268 zinc-finger motifs gives rise to non-native zinc-co-ordination sites but preserves wild-type DNA recognition

Zinc fingers are among the major structural motifs found in proteins that are involved in eukaryotic gene regulation. Many of these zinc-finger domains are involved in DNA binding. This study investigated whether the zinc-co-ordinating (Cys)2(His)2 motif found in the three zinc fingers of zif268 could be replaced by a (Cys)4 motif while still preserving DNA recognition. (Cys)2(His)2-to-(Cys)4 mutations were generated in each of the three zinc fingers of zif268 individually, as well as in fingers 1 and 3, and fingers 2 and 3 together. Whereas finger 1 and finger 3 tolerate the switch, such an alteration in finger 2 renders the polypeptide incapable of DNA recognition. The protein-DNA interaction was examined in greater detail by using a methylation-interference assay. The mutant polypeptides containing the (Cys)4 motif in fingers 1 or 3 recognize DNA in a manner identical to the wild-type protein, suggesting that the (Cys)4 motif appears to give rise to a properly folded finger. Additional results indicate that a zif268 variant containing a (Cys)2(His)(Ala) arrangement in finger 1 is also capable of DNA recognition in a manner identical to the wild-type polypeptide. This appears to be the first time that such alterations, in the context of an intact DNA-binding domain, have still allowed for specific DNA recognition. Taken together, the work presented here enhances our understanding of the relationship between metal ligation and DNA-binding by zinc fingers.

Molecular and kinetic basis for the mixed agonist/antagonist activity of estriol

Estriol acts as a weak estrogen when administered in a single dose into immature or ovariectomized laboratory animals, but produces full estrogenic responses upon chronic administration. However, when estriol is injected together with estradiol it acts as an antiestrogen. We studied the dual agonist/antagonist properties of estriol, using recombinant human estrogen receptor (hER) in ligand-binding assay, cell-free transcription assay, electrophoretic mobility shift assay with cVitII estrogen response element (ERE), and ERE-Sepharose chromatography. We show that the weak estrogenic activity of estriol results from impaired hER-ERE interaction. The antiestrogenic activity of estriol was demonstrated in a cell-free transcription assay where it reduced estradiol-dependent transcription in a dose-dependent manner. Estriol interfered with estradiol-induced positive cooperative binding and receptor dimerization, and binding of hER complexes to ERE. These effects of estriol were maximal at a 10-fold molar excess over estradiol; under these conditions estradiol-dependent transcription was decreased by 85%, although [3H]estradiol binding was reduced by only 50%. We propose that when hER, estradiol, and estriol are coequilibrated, several receptor species are formed: unliganded hER monomers and dimers; estradiol-hER monomers and dimers, estriol-hER monomers and dimers; and presumably mixed estradiol-estriol dimers. Since estrogen-hER complexes bind cooperatively to ERE sequences, the concentrations of transcriptionally active complexes (estriol- and estradiol-hER dimers) are reduced to low levels that fail to bind cooperatively with ERE and initiate transcription. We discuss our results in relation to the massive estriol production during pregnancy and to the "Estriol Hypothesis" on the protective role for estriol in opposing carcinogenic effects of estradiol.

Retinoid X receptor alters the determination of DNA binding specificity by the P-box amino acids of the thyroid hormone receptor

Nuclear hormone receptors bind to hormone response elements in DNA consisting of two half-sites of 6 base pairs. The P-box amino acids of each receptor determine the identities of the central nucleotides of the half-site. 57 P-box variants of the human thyroid hormone receptor (hT3Rbeta) were used to demonstrate the relationship between P-box sequence and DNA binding specificity by homodimers and heterodimers formed with the retinoid X receptor (RXR). In general, the formation of heterodimers relieved many of the constraints on the compatibility of hT3Rbeta P-box sequences with DNA binding. Effects were most dramatic for heterodimers bound to a direct repeat spaced by four base pairs. RXR also overrides the P-box-derived DNA binding specificity of hT3Rbeta when heterodimers are bound to inverted or everted repeat elements. These effects of RXR are most pronounced on AGGTCA half-sites but are squelched when the RXR partner of the heterodimer is bound to an AGGACA half-site. The influence of RXR on hT3Rbeta DNA binding specificity varies with the orientation of half-sites in the element, the identity of the fourth base pair of the half-site, and the spacing between the half-sites of direct repeats. These differences suggest that the DNA binding domains of RXR-hT3Rbeta heterodimers are not positioned equivalently on the various elements, affecting the manner in which the P-box amino acids of hT3Rbeta interact with base pairs within the half-site.

Characterization of glucose dependent gel-sol phase transition of the polymeric glucose-concanavalin A hydrogel system

PURPOSE

The main goal of this study was to synthesize and characterize hydrogels which undergo reversible gel-sol phase transformation in response to changes in glucose concentration in the surrounding environment.

METHODS

The glucose-sensitive hydrogels were made by mixing the appropriate concentrations of acrylamide-allyl glucose copolymer and concanavalin A (Con A). To examine their phase reversibility, hydrogels in dialysis membranes were cycled between glucose-free and glucose-containing buffers. The binding affinity of allyl glucose (AG) to Con A was examined by using an equilibrium dialysis technique.

RESULTS

The synthesized hydrogels underwent phase transition to sol in the presence of free glucose in the environment. The concentration of external free glucose (Cf) had to be at least 4 times that of polymer-bound glucose (Cp) to induce phase transition from gel to sol. The binding affinity study showed that binding of AG to Con A was four times stronger than that of free glucose. When Cp in the gel was 0.42 mg/ml or higher, Cf had to be much higher than 4 times Cp to induce phase transition.

CONCLUSIONS

The synthesized hydrogels underwent phase transition in the presence of free glucose in the environment, but the phase transition was not linearly dependent on the concentration of free glucose. This non-linear dependence was explained by the increased binding affinity of AG over native glucose to Con A, and the cooperative interactions between polymer-bound glucose and Con A.