The retinoid-X receptor ortholog, ultraspiracle, binds with nanomolar affinity to an endogenous morphogenetic ligand

The in vivo ligand-binding function and ligand-binding activity of the Drosophila melanogaster retinoid-X receptor (RXR) ortholog, ultraspiracle, toward natural farnesoid products of the ring gland were assessed. Using an equilibrium fluorescence-binding assay, farnesoid products in the juvenile hormone (JH) biosynthesis pathway, and their epoxy derivatives, were measured for their affinity constant for ultraspiracle (USP). Farnesol, farnesal, farnesoic acid and juvenile hormone III exhibited high nanomolar to low micromolar affinity, which in each case decreased upon addition of an epoxide across a double bond of the basic farnesyl structure. Similar analysis of the substitution on C1 of methyl ether, alcohol, aldehyde, and carboxylic acid showed that each conferred weaker affinity than that provided by the methyl ester. Attention was thus focused for a ring-gland farnesoid product that possesses the features of methyl ester and lack of an epoxide. A secreted product of the ring gland, methyl farnesoate, was identified possessing these features and exhibited an affinity for ultraspiracle (K(d) = 40 nm) of similar strength to that of RXR for 9-cis retinoic acid. Mutational analysis of amino acid residues with side chains extending into the ligand-binding pocket cavity (and not interacting with secondary receptor structures or extending to the receptor surface to interact with coactivators, corepressors or receptor dimer partners) showed that the mutation C472A/H475L strongly reduced USP binding to this ring gland product and to JH III, with less effect on other ring-gland farnesoids and little effect on binding by (the unnatural to Drosophila) JH I. Along with the ecdysone receptor, USP is now the second arthropod nuclear hormone receptor for which a secreted product of an endocrine gland that binds the receptor with nanomolar affinity has been identified.     

Using nondenaturing mass spectrometry to detect fortuitous ligands in orphan nuclear receptors

Nondenaturing electrospray mass spectrometry (ESI-MS) has been used to reveal the presence of potential ligands in the ligand-binding domain (LBD) of orphan nuclear receptors. This new approach, based on supramolecular mass spectrometry, allowed the detection and identification of fortuitous ligands for the retinoic acid-related orphan receptor beta (RORbeta) and the ultraspiracle protein (USP). These fortuitous ligands were specifically captured from the host cell with the proper stoichiometry. After organic extraction, these molecules have been characterized by classic analytical methods and identified as stearic acid for RORbeta and a phosphatidylethanolamine (PE) for USP, as confirmed by crystallography. These molecules act as "fillers" and may not be the physiological ligands, but they prove to be essential to stabilize the active conformation of the LBD, enabling its crystallization. The resulting crystal structures provide a detailed picture of the ligand-binding pocket, allowing the design of highly specific synthetic ligands that can be used to characterize the function of orphan nuclear receptors. An additional advantage of this new method is that it is not based on a functional test and that it can detect low-affinity ligands.     

Crystal structure of the ligand-binding domain of the ultraspiracle protein USP, the ortholog of retinoid X receptors in insects

The major postembryonic developmental events happening in insect life, including molting and metamorphosis, are regulated and coordinated temporally by pulses of ecdysone. The biological activity of this steroid hormone is mediated by two nuclear receptors: the ecdysone receptor (EcR) and the Ultraspiracle protein (USP). The crystal structure of the ligand-binding domain from the lepidopteran Heliothis virescens USP reported here shows that the loop connecting helices H1 and H3 precludes the canonical agonist conformation. The key residues that stabilize this unique loop conformation are strictly conserved within the lepidopteran USP family. The presence of an unexpected bound ligand that drives an unusual antagonist conformation confirms the induced-fit mechanism accompanying the ligand binding. The ligand-binding pocket exhibits a retinoid X receptor-like anchoring part near a conserved arginine, which could interact with a USP ligand functional group. The structure of this receptor provides the template for designing inhibitors, which could be utilized as a novel type of environmentally safe insecticides.     

Functional studies on the ligand-binding domain of Ultraspiracle from Drosophila melanogaster

The functional insect ecdysteroid receptor is comprised of the ecdysone receptor (EcR) and Ultraspiracle (USP). The ligand-binding domain (LBD) of USP was fused to the GAL4 DNA-binding domain (GAL4-DBD) and characterized by analyzing the effect of site-directed mutations in the LBD. Normal and mutant proteins were tested for ligand and DNA binding, dimerization, and their ability to induce gene expression. The presence of helix 12 proved to be essential for DNA binding and was necessary to confer efficient ecdysteroid binding to the heterodimer with the EcR (LBD), but did not influence dimerization. The antagonistic position of helix 12 is indispensible for interaction between the fusion protein and DNA, whereas hormone binding to the EcR (LBD) was only partially reduced if fixation of helix 12 was disturbed. The mutation of amino acids, which presumably bind to a fatty acid evoked a profound negative influence on transactivation ability, although enhanced transactivation potency and ligand binding to the ecdysteroid receptor was impaired to varying degrees by mutation of these residues. Mutations of one fatty acid-binding residue within the ligand-binding pocket, 1323, however, evoked enhanced transactivation. The results confirmed that the LBD of Ultraspiracle modifies ecdysteroid receptor function through intermolecular interactions and demonstrated that the ligand-binding pocket of USP modifies the DNA-binding and transactivation abilities of the fusion protein.