In vitro fluorescence anisotropy analysis of the interaction of full-length SRC1a with estrogen receptors alpha and beta supports an active displacement model for coregulator utilization

Binding of full-length P160 coactivators to hormone response element-steroid receptor complexes has been difficult to investigate in vitro. Here, we report a new application of our recently described fluorescence anisotropy microplate assay to investigate binding and dissociation of full-length steroid receptor coactivator-1a (SRC1a) from full-length estrogen receptor alpha (ERalpha) or estrogen receptor beta (ERbeta) bound to a fluorescein-labeled (fl) estrogen response element (ERE). SRC1a exhibited slightly higher affinity binding to flERE.ERbeta than to flERE.ERalpha. Binding of SRC1a to flERE.ERalpha and to flERE.ERbeta was 17beta-estradiol (E2)-dependent and was nearly absent when ICI 182,780, raloxifene, or 4-hydroxytamoxifen were bound to the ERs. SRC1a binds to flERE.E2-ERalpha and flERE.E2-ERbeta complexes with a t1/2 of 15-20 s. Short LXXLL-containing nuclear receptor (NR) box peptides from P160 coactivators competed much better for SRC1a binding to flERE.E2-ER than an NR box peptide from TRAP220. However, approximately 40-250-fold molar excess of the P160 NR box peptides was required to inhibit SRC1a binding by 50%. This suggests that whereas the NR box region is a primary site of interaction between SRC1a and ERE.E2-ER, additional contacts between the coactivator and the ligand-receptor-DNA complex make substantial contributions to overall affinity. Increasing amounts of NR box peptides greatly enhanced the rate of dissociation of SRC1a from preformed flERE.E2-ER complexes. The data support a model in which coactivator exchange is facilitated by active displacement and is not simply the result of passive dissociation and replacement. It also shows that an isolated coactivator exhibits an inherent capacity for rapid exchange.     

An extended LXXLL motif sequence determines the nuclear receptor binding specificity of TRAP220

The interaction of coactivators with the ligand-binding domain of nuclear receptors (NRs) is mediated by amphipathic alpha-helices containing the signature motif LXXLL. TRAP220 contains two LXXLL motifs (LXM1 and LXM2) that are required for its interaction with NRs. Here we show that the nuclear receptor interaction domain (NID) of TRAP220 interacts weakly with Class I NRs. In contrast, SRC1 NID binds strongly to both Class I and Class II NRs. Interaction assays using nine amino acid LXXLL core motifs derived from SRC1 and TRAP220 revealed no discriminatory NR binding preferences. However, an extended LXM1 sequence containing amino acids -4 to +9, (where the first conserved leucine is +1) showed selective binding to thyroid hormone receptor and reduced binding to estrogen receptor. Replacement of either TRAP220 LXXLL motif with the corresponding 13 amino acids of SRC1 LXM2 strongly enhanced the interaction of the TRAP220 NID with the estrogen receptor. Mutational analysis revealed combinatorial effects of the LXM1 core and flanking sequences in the determination of the NR binding specificity of the TRAP220 NID. In contrast, a mutation that increased the spacing between TRAP220 LXM1 and LXM2 had little effect on the binding properties of this domain. Thus, a 13-amino acid sequence comprising an extended LXXLL motif acts as the key determinant of the NR binding specificity of TRAP220. Finally, we show that the NR binding specificity of full-length TRAP220 can be altered by swapping extended LXM sequences.     

Inhibition of DNA binding by human estrogen-related receptor 2 and estrogen receptor alpha with minor groove binding polyamides

Human estrogen-related receptor 2 (hERR2, ESRRB, ERRbeta, NR3B2) belongs to a class of nuclear receptors that bind DNA through sequence-specific interactions with a 5'-AGGTCA-3' estrogen response element (ERE) half-site in the major groove and an upstream 5'-TNA-3' site in the minor groove. This minor groove interaction is mediated by a C-terminal extension (CTE) of the DNA binding domain and is unique to the estrogen-related receptors. We have used synthetic pyrrole-imidazole polyamides, which bind specific sequences in the minor groove, to demonstrate that DNA binding by hERR2 is sensitive to the presence of polyamides in both the upstream minor groove CTE site and the minor groove of the ERE half-site. Thus, polyamides can inhibit hERR2 by two mechanisms, by direct steric blockage of minor groove DNA contacts mediated by the CTE and by changing the helical geometry of DNA such that major groove interactions are weakened. To confirm the generality of the latter approach, we show that the dimeric human estrogen receptor alpha (hERalpha, ESR1, NR3A1), which binds in the major groove of the ERE, can be inhibited by a polyamide bound in the opposing minor groove of the ERE. These results highlight two mechanisms for inhibition of protein-DNA interactions and extend the repertoire of DNA recognition motifs that can be inhibited by polyamides. These molecules may thus be useful for controlling expression of hERR2- or hERalpha-responsive genes.     

Conformational adaptation of nuclear receptor ligand binding domains to agonists: potential for novel approaches to ligand design

Ligands occupy the core of nuclear receptor (NR) ligand binding domains (LBDs) and modulate NR function. X-ray structures of NR LBDs reveal most NR agonists fill the enclosed pocket and promote packing of C-terminal helix 12 (H12), whereas the pockets of unliganded NR LBDs differ. Here, we review evidence that NR pockets rearrange to accommodate different agonists. Some thyroid hormone receptor (TR) ligands with 5′ extensions designed to perturb H12 act as antagonists, but many are agonists. One mode of adaptation is seen in a TR/thyroxine complex; the pocket expands to accommodate a 5′ iodine extension. Crystals of other NR LBDs reveal that the pocket can expand or contract and some agonists do not fill the pocket. A TRβ structure in complex with an isoform selective drug (GC-24) reveals another mode of adaptation; the LBD hydrophobic interior opens to accommodate a bulky 3′ benzyl extension. We suggest that placement of extensions on NR agonists will highlight unexpected areas of flexibility within LBDs that could accommodate extensions; thereby enhancing the selectivity of agonist binding to particular NRs. Finally, agonists that induce similar LBD structures differ in their activities and we discuss strategies to reveal subtle structural differences responsible for these effects.     

Dissociation of steroid receptor coactivator 1 and nuclear receptor corepressor recruitment to the human glucocorticoid receptor by modification of the ligand-receptor interface: the role of tyrosine 735

Within the human glucocorticoid receptor (GR) steroid binding pocket, tyrosine 735 makes hydrophobic contact with the steroid D ring. Substitution of tyrosine735 selectively impairs glucocorticoid transactivation but not transrepression. We now show, using both mammalian two-hybrid and glutathione-S-transferase pull downs, that such substitutions reduce interaction with steroid receptor coactivator 1, both basally and in response to agonist binding. Using a yeast two-hybrid screen we identified one of the three nuclear receptor interacting domains (NCoR-N1) of nuclear receptor corepressor (NCoR) as interacting with the GR C terminus in an RU486-specific manner. This was confirmed in mammalian two-hybrid experiments, and so we used the NCoR-N1 peptide to probe the GR C-terminal conformation. Substitution of Tyr735phe, Tyr735val, and Tyr735 ser, which impaired steroid receptor coactivator 1 (SRC1) interaction, enhanced NCoR-N1 recruitment, basally and after RU486. RU486 did not direct SRC1 recruitment to any of the GR constructs, and dexamethasone did not allow NCoR-N1 recruitment. Using a glutathione-S-transferase pull-down approach, the NCoR-N1 peptide was found to bind the full-length GR constitutively, and no further induction was seen with RU486, but it was reduced by dexamethasone. As both SRC1 and NCoR are predicted to recognize a common hydrophobic cleft in the GR, it seems that changes favorable to one interaction are detrimental to the other, thus identifying a molecular switch.     

Klotho coreceptors inhibit signaling by paracrine fibroblast growth factor 8 subfamily ligands

It has been recently established that Klotho coreceptors associate with fibroblast growth factor (FGF) receptor tyrosine kinases (FGFRs) to enable signaling by endocrine-acting FGFs. However, the molecular interactions leading to FGF-FGFR-Klotho ternary complex formation remain incompletely understood. Here, we show that in contrast to αKlotho, βKlotho binds its cognate endocrine FGF ligand (FGF19 or FGF21) and FGFR independently through two distinct binding sites. FGF19 and FGF21 use their respective C-terminal tails to bind to a common binding site on βKlotho. Importantly, we also show that Klotho coreceptors engage a conserved hydrophobic groove in the immunoglobulin-like domain III (D3) of the "c" splice isoform of FGFR. Intriguingly, this hydrophobic groove is also used by ligands of the paracrine-acting FGF8 subfamily for receptor binding. Based on this binding site overlap, we conclude that while Klotho coreceptors enhance binding affinity of FGFR for endocrine FGFs, they actively suppress binding of FGF8 subfamily ligands to FGFR.     

Model structures of the N-methyl-D-aspartate receptor subunit NR1 explain the molecular recognition of agonist and antagonist ligands

Molecular models of the ligand-binding domain of N-methyl-d-aspartate subunit R1 (NR1) were made using the published crystal structures of rat glutamate receptor B (GluRB), the bacterial glutamate receptor (GluR0), and the glutamine-binding protein (QBP) of Escherichia coli. Separate models of NR1 were built to represent the ligand-binding conformation for agonist (glycine, d- and l-isomers of serine and alanine, and the partial agonist ligand d-cycloserine) and antagonist (5,7-dichloro-4-oxo-1,4-dihydroquinoline-2-carboxylic acid (DCKA) and E-3-(2-phenyl-2-carboxyethenyl)-4,6-dichloro-1-H-indole-2-carboxylic acid (MDL 105,519)) ligands. Side-chain conformations of residues within the NR1 ligand-binding site were selected that optimized the hydrophobic packing and hydrogen bonding among residues, while taking into account published data comparing receptor mutants with wild-type NR1. Ligands docked to the model structures provide a rational explanation for the observed differences in binding affinity and receptor activation among agonist and antagonist ligands. NR1 prefers smaller ligands (glycine, serine, and alanine) in comparison with GluRB and GluR0 that bind l-glutamate: the bulky side chain of W731 in NR1 dramatically reduces the size of the ligand-binding site, functioning to selectively restrict recognition to glycine and the d-isomers of serine and alanine. Nevertheless, many of the interactions seen for ligands bound to GluRB, GluR0, and periplasmic-binding proteins are present for the ligands docked to the model structures of NR1.     

Structural basis of presequence recognition by the mitochondrial protein import receptor Tom20

Most mitochondrial proteins are synthesized in the cytosol as precursor proteins with a cleavable N-terminal presequence and are imported into mitochondria. We report here the NMR structure of a general import receptor, rat Tom20, in a complex with a presequence peptide derived from rat aldehyde dehydrogenase. The cytosolic domain of Tom20 forms an all alpha-helical structure with a groove to accommodate the presequence peptide. The bound presequence forms an amphiphilic helical structure with hydrophobic leucines aligned on one side to interact with a hydrophobic patch in the Tom20 groove. Although the positive charges of the presequence are essential for import ability, presequence binding to Tom20 is mediated mainly by hydrophobic rather than ionic interactions.