Mutants created by site-directed mutagenesis were used to elucidate the function of amino acids involved in ligand binding to ecdysteroid receptor (EcR) and heterodimer formation with ultraspiracle (USP). The results demonstrate the importance of the C-terminal part of the D-domain and helix 12 of EcR for hormone binding. Some amino acids are involved either in ligand binding to EcR (E476, M504, D572, I617, N626) or ligand-dependent heterodimerization as determined by gel mobility shift assays (A612, L615, T619), while others are involved in both functions (K497, E648). Some amino acids are suboptimal for ligand binding (L615, T619), but mediate ligand-dependent dimerization. We conclude that the enhanced regulatory potential by ligand-dependent modulation of dimerization in the wild type is achieved at the expense of optimal ligand binding. Mutation of amino acids (K497, E648) involved in the salt bridge between helix 4 and 12 impair ligand binding to EcR more severely than hormone binding to the heterodimer, indicating that to some extent heterodimerization compensates for the deleterious effect of certain mutations. Different effects of the same point mutations on ligand binding to EcR and EcR/USP (R511, A612, L615, I617, T619, N626) indicate that the ligand-binding pocket is modified by heterodimerization.
The insect ecdysteroid receptor consists of a heterodimer between EcR and the RXR-orthologue, USP. We addressed the question of whether this heterodimer, like all other RXR heterodimers, may be formed in the absence of ligand and whether ligand promotes dimerization. We found that C-terminal protein fragments that comprised the ligand binding, but not the DNA binding domain of EcR and USP and which were equipped with the activation or DNA binding region of GAL4, respectively, exhibit a weak ability to interact spontaneously with each other. Moreover, the heterodimer formation is greatly enhanced upon administration of active ecdysteroids in a dose-dependent manner. This was shown in vivo by a yeast two-hybrid system and in vitro by a modified electromobility shift assay. Furthermore, the EcR fragment expressed in yeast was functional and bound radioactively labelled ecdysteroid specifically. Ligand binding was greatly enhanced by the presence of a USP ligand binding domain. Therefore, ecdysteroids are capable of inducing heterodimer formation between EcR and USP, even when the binding of these receptor proteins to cognate DNA response elements does not occur. This capability may be a regulated aspect of ecdysteroid action during insect development.Keywords: Drosophila melanogaster; yeast; two-hybrid; ecdysone receptor; dimerization; ultraspiracle.Ecdysteroids are widespread steroid hormones found in invertebrates [1] and plants [2,3] that regulate a variety of developmental, physiological, and reproductive processes [1,3]. Among insects, these hormones regulate the expression of genes through a highly orchestrated and coordinated transcriptional network [4][5][6]. The widespread and diverse effects of ecdysteroids on transcriptional regulation have served as a powerful model for investigating the diverse mechanisms by which steroid hormones, acting via nuclear receptors, exert their effects on a variety of life processes [4,7].The ecdysone receptor (EcR) [8], responsible for mediating these responses, occupies a special position among nuclear hormone receptors because it shows a unique combination of characteristics [9]. Unlike the vertebrate steroid receptors [10][11][12], EcR heterodimerizes with the insect RXR orthologue, ultraspiracle (USP) [13][14][15]. Nevertheless, while other nuclear receptors that dimerize with RXR normally are bound to DNA response elements already in their nonliganded state [11,16], this apparently is not true for the EcR/USP heterodimer (see however, [17]). Immunostaining has shown that the polytene chromosomes of a Chironomid or Sciarid are devoid of EcR/USP signals when prepared from developmental stages associated with low ecdysteroid titers [18,19]. A short in vitro incubation of the tissues with 20-hydroxyecdysone, however, is followed by the appearance of immunostaining signals at known ecdysteroid-responsive gene loci [18,19]. The affinity of EcR/USP dimers for ecdysone response elements (EcREs) clearly increases in the presence of the ecdysteroid muristerone A as demonstrated...
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.
The ultraspiracle (usp) gene encodes a nuclear receptor that forms a heterodimer with the ecdysone receptor (EcR) to mediate transcriptional responses to the insect steroid hormone, 20-hydroxyecdysone (20HE). The responses ultimately elicit changes associated with molting and metamorphosis. Although Ultraspiracle (USP) is required at several developmental times, it is unclear whether USP plays stage-specific roles in Drosophila. A chimeric transgene (d/cusp), produced by replacing the ligand-binding domain (LBD) of Drosophila USP with the equivalent domain from another Diptera, Chironomus tentans, was tested for its ability to rescue Drosophila usp mutants from early larval lethality. A single copy of the d/cusp was sufficient to rescue transformants from several lines through larval development but they died suddenly during the late third instar. Additional doses of d/cusp were required to allow survival through the adult stage, but they did not restore a normal prepupal contraction. Thus, the arrest at the onset of metamorphosis apparently is caused by the impaired ability of the chimeric USP to mediate a stage-specific function associated with the LBD.
The ultraspiracle (usp) gene encodes a nuclear receptor that forms a heterodimer with the ecdysone receptor (EcR) to mediate transcriptional responses to the insect steroid hormone, 20-hydroxyecdysone (20HE). The responses ultimately elicit changes associated with molting and metamorphosis. Although Ultraspiracle (USP) is required at several developmental times, it is unclear whether USP plays stage-specific roles in Drosophila. A chimeric transgene (d/cusp), produced by replacing the ligand-binding domain (LBD) of Drosophila USP with the equivalent domain from another Diptera, Chironomus tentans, was tested for its ability to rescue Drosophila usp mutants from early larval lethality. A single copy of the d/cusp was sufficient to rescue transformants from several lines through larval development but they died suddenly during the late third instar. Additional doses of d/cusp were required to allow survival through the adult stage, but they did not restore a normal prepupal contraction. Thus, the arrest at the onset of metamorphosis apparently is caused by the impaired ability of the chimeric USP to mediate a stage-specific function associated with the LBD.
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