Determinants of target gene specificity for steroid/thyroid hormone receptors

The molecular specificity of the receptors for steroid and thyroid hormones is achieved by their selective interaction with DNA binding sites referred to as hormone response elements (HREs). HREs can differ in primary nucleotide sequence as well as in the spacing of their dyadic half-sites. The target gene specificity of the glucocorticoid receptor can be converted to that of the estrogen receptor by changing three amino acids clustered in the first zinc finger. Remarkably, a single Gly to Glu change in this region produces a receptor that recognizes both glucocorticoid and estrogen response elements. Further replacement of five amino acids in the stem of the second zinc finger transforms the specificity to that of the thyroid hormone receptor. These findings localize structural determinants required for discrimination of HRE sequence and half-site spacing, respectively, and suggest a simple pathway for the coevolution of receptor DNA binding domains and hormone-responsive gene networks.     

Thyroid hormone receptor dimerization function maps to a conserved subregion of the ligand binding domain.

Thyroid hormone receptors (TRs) bind as dimers to specific DNA response elements. We have used a genetic approach to identify amino acid sequences required for dimerization of the TR beta isoform. Bacteria expressing a chimeric repressor composed of the DNA binding domain of the bacteriophage lambda cl repressor fused to the TR beta ligand binding domain are immune to lambda infection as a consequence of homodimerization activity provided by the receptor sequences. The phenotypes of deletions and point mutations of the TR beta sequences map dimerization activity to a subregion of the ligand binding domain that is highly conserved among all members of the nuclear hormone receptor superfamily. These results confirm and extend previous findings indicating that this subregion plays an important role in the dimerization of TR beta and other superfamily members.     

An RNA-binding domain in the thyroid hormone receptor enhances transcriptional activation

Thyroid hormone plays important roles in development, differentiation, and metabolic homeostasis by binding to nuclear thyroid hormone receptors, which regulate target gene expression by interacting with DNA response elements and coregulatory proteins. We show that thyroid hormone receptors also are single-stranded RNA binding proteins and that this binding is functionally significant. By using a series of deletion mutants, a novel RNA-binding domain was localized to a 41-amino acid segment of thyroid hormone receptor alpha1 between the second zinc finger and the ligand-binding domain. This RNA-binding domain was necessary and sufficient for thyroid hormone receptor binding to the steroid receptor RNA activator (SRA). Although SRA does not bind directly to steroid receptors, it has been identified as a steroid receptor coactivator, and was thought not to be a coactivator for thyroid hormone receptors. However, transfection studies revealed that SRA enhances thyroid hormone induction of appropriate reporter genes and that the thyroid hormone receptor RNA-binding domain is important for this enhancement. We conclude that thyroid hormone receptors bind RNA through a novel domain and that the interaction of this domain with SRA, and perhaps other RNAs, enhances thyroid hormone receptor function.     

Half-site spacing and orientation determines whether thyroid hormone and retinoic acid receptors and related factors bind to DNA response elements as monomers, homodimers, or heterodimers.

The receptors for thyroid hormone (T3R) and retinoic acid (RAR) are members of a nuclear receptor subfamily that are capable of recognizing similar DNA sequences. Native response elements for T3R and RAR consist of two or more putative half-site binding motifs organized as imperfect direct or inverted repeats separated by different sized nucleotide gaps. To clarify how T3R, RAR, and related factors recognize DNA response elements, we analyzed the interaction of purified receptors with a series of inverted and direct repeats of an idealized AGGTCA half-site separated by different sized nucleotide gaps. Our results indicate that RAR and T3R can bind to half-sites as monomers and, depending on the orientation and distance between half-sites, also bind as homodimers or T3R-RAR heterodimers. T3R also binds to certain DNA elements as a heterodimer with one or more nuclear factors from eucaryotic cells. Thus, the orientation and spacing of half-sites play a central role in determining which configuration of receptors and nuclear factors will interact with a specific DNA element. This along with the ability of these factors to participate in reversible protein-protein interactions serve to broaden and diversify the responses mediated by T3R, RAR, and related members of this nuclear receptor subfamily.     

The orphan receptors NGFI-B and steroidogenic factor 1 establish monomer binding as a third paradigm of nuclear receptor-DNA interaction.

We examined in detail the DNA interaction of the nuclear receptors NGFI-B and steroidogenic factor 1 (SF-1) by using a series of gain-of-function domain swaps. NGFI-B bound with high affinity as a monomer to a nearly linear DNA molecule. The prototypic zinc modules interacted with a half-site of the estrogen receptor class, and a distinct protein motif carboxy terminal to the zinc modules (the A box) interacted with two A/T base pairs 5' to the half-site. SF-1 bound in the same manner as NGFI-B, with an overlapping but distinct sequence requirement 5' to the half-site. The key features that distinguished the NGFI-B and SF-1 interactions were an amino group in the minor groove of the SF-1 binding sequence and an asparagine in the SF-1 A box. These results define a common mechanism of NGFI-B and SF-1 DNA binding, which may underlie a competitive mechanism of gene regulation in steroidogenic tissues that express these proteins. This monomer-DNA interaction represents a third paradigm of DNA binding by nuclear receptors in addition to direct and inverted dimerization.     

The BTB domain of bric à brac mediates dimerization in vitro.

The gene bric à brac (bab) is required for the proper development of the limbs and ovary in Drosophila melanogaster. bab encodes a BTB domain (also called a POZ domain), an approximately 115-amino-acid conserved motif found primarily in the N termini of zinc finger proteins. In this paper, we show that the BTB domain of bab can mediate protein dimerization in vitro. In addition, we demonstrate that the first 51 amino acids of the bab BTB domain are sufficient for dimerization, and we identify amino acids within this region that are required for binding.     

DNA binding properties of the vitamin D3 receptor zinc finger region.

The DNA binding domains of the nuclear receptor superfamily are highly conserved and consist of residues that fold into two zinc finger-like motifs, suggesting that the structures of this region among the members of the superfamily are likely to be very similar. Furthermore, the response elements that these receptors bind to are similar in sequence and organization. Nevertheless, these receptors selectively recognize target response elements and differentially regulate linked genes. In order to study the details of receptor:DNA binding, we have overexpressed and purified the vitamin D3 receptor DNA binding domain (VDRF) and have begun characterizing its DNA binding properties. We find that the VDRF protein binds strongly and specifically to direct repeats constituting a vitamin D response element from the mouse osteopontin (Spp-1) promoter region but weakly to the human osteocalcin vitamin D response element. Unlike receptors that recognize hormone response elements oriented as inverted repeats, such as the glucocorticoid receptor (GR) and estrogen receptor, VDRF appears to bind half-sites noncooperatively, without the free energy contribution of dimerization seen when the glucocorticoid receptor DNA binding domain associates with a glucocorticoid response element. By comparing and contrasting the DNA binding properties of the vitamin D and glucocorticoid receptors, we suggest a model for how receptors that prefer direct repeats differ in their binding strategy from those that recognize inverted repeats.     

On the mechanism of DNA binding by nuclear hormone receptors: A structural and functional perspective

The nuclear hormone receptor DNA-binding domain consists of two zinc finger-like modules whose amino acids are highly conserved among the members of the receptor superfamily. In this review, we describe the various genetic, biochemical, and structural experiments that have been carried out primarily for the DNA-binding domains of the glucocorticoid and estrogen receptors. We describe how the structural and functional information have permitted us to predict properties of the DNA-binding domains of other nuclear receptors. We postulate how receptors discriminate closely related response elements through sequence-specific contacts and distinguish symmetry of target sites through protein-protein interactions. This mechanism explains in part how the receptors regulate diverse sets of genes from a limited repertoire of core response elements. Lastly, we describe the stereochemical basis of nuclear receptor dysfunction in certain clinical disorders. © 1993 Wiley-Liss, Inc.