Development of stable isotope and selenomethionine labeling methods for proteins expressed in Pseudomonas fluorescens.

Pseudomonas fluorescens is a robust protein expression system that is very well suited for high throughput protein expression for structural genomics studies. Since NMR spectroscopy and X-ray crystallography are both used by various investigators in structure elucidation studies, the availability of target proteins labeled with stable isotopes or selenomethionine is essential for the determination of protein structures. A completely defined medium for the expression and stable isotope labeling of proteins in P. fluorescens has been developed. The expression level of Bacillus thuringiensis Cry34 in the modified medium is comparable to that obtained in the original medium. In addition, more than 95% incorporation of 15N was obtained in Cry34 using 15N ammonium sulfate and the quality of the protein, as assessed by NMR analysis, is comparable to that made using commercial medium. High levels of selenomethionine (SeMet) incorporation in the Xenorhabdus nematophilus insecticidal protein XptA2 were also obtained in P. fluorescens using the defined medium, allowing development of a method for obtaining highly purified XptA2. The following observations were made when inhibitors of endogenous methionine biosynthesis were used in P. fluorescens culture when SeMet was substituted in XptA2: (I) there is little inhibition of cell growth or recombinant XptA2 expression in the presence of SeMet concentrations up to 300 mg/L in cell culture, (II) there was greater than 95% SeMet incorporation ratio in recombinant SeMet-labeled XptA2 (SeMet-XptA2) and the incorporation ratio is consistent and reproducible and (III) finally, purified SeMet-XptA2 possesses similar protein structure and insecticidal activity relative to the unlabeled counterpart XptA2 as shown by bioassay and differential scanning calorimetric analysis. The high SeMet incorporation should provide high accuracy and resolution in XptA2 phase determination by multiwavelength anomalous diffraction (MAD), indicating that P. fluorescens is an excellent expression host to produce SeMet-labeled proteins for structural study.

A photoaffinity, non-steroidal, ecdysone agonist, bisacylhydrazine compound, RH-131039: characterization of binding and functional activity.

In this paper we describe the synthesis, ligand-binding and functional activity characteristics of the photoaffinity, non-steroidal, ecdysone agonist, bisacylhydrazine compound, 3-benzoyl-benzoic acid N-tert-butyl-N'-(2-ethyl-3-methoxy-benzoyl)-hydrazide (RH-131039). Tritiated RH-131039 is the first non-steroidal photoaffinity compound that was shown to bind specifically to ecdysone receptors (EcRs) from insects belonging to the orders Diptera and Lepidoptera. The spruce budworm (Choristoneura fumiferana) ecdysone receptor (CfEcR) bound with high affinity (K(d)=2.23+/-0.27 nM) to this compound. When irradiated with UV light (lambda=350 nm) under equilibrium ligand-binding conditions, RH-131039 attached specifically and covalently to the CfEcR ligand-binding domain (LBD). RH-131039 also bound to cloned ecdysone receptor proteins from three dipteran insects, Drosophila melanogaster, Aedes aegypti and Chironomous tentans. This paper also describes and invokes caution in interpretation of ligand-binding results obtained using crude cellular extracts containing target receptors, as illustrated with the use of Drosophila Kc cells that have functional EcR and L57 cells (derivatives of Kc cells in which EcR-B isoforms have been knocked out by "parahomologous" recombination). Tritiated RH-131039 is a useful tool to dissect ligand-binding and functional differences for EcRs from different arthropod species.

Identification of a putative azadirachtin-binding complex from Drosophila Kc167 cells.

Cell-proliferation in Drosophila Kc167 cells was inhibited by 50% when cell cultures contained 1.7 x 10(-7) M azadirachtin for 48 h (a tertranortriterpenoid from the neem tree Azadirachta indica). Drosophila Kc167 cells exhibited direct nuclear damage within 6-h exposure to azadirachtin (5 x 10(-7) M and above) or within 24 h when lower concentrations were used (1 x 10(-9) M). Fractionation of an extract of Drosophila Kc167 cells combined with ligand overlay technique resulted in the identification of a putative azadirachtin binding complex. Identification of the members of this complex by Peptide Mass Fingerprinting (PMF) and N-terminal sequencing identified heat shock protein 60 (hsp60) as one of its components.

Ligand specificity and developmental expression of RXR and ecdysone receptor in the migratory locust.

The ecdysone receptor(1), which is a heterodimer of EcR and the retinoic acid receptor (RXR) homolog, Ultraspiracle (USP), has been well studied in the evolutionarily advanced and derived insects, the flies and moths. It is less well characterized in more primitive insect orders such as the Orthoptera, which include the grasshoppers and locusts. Following our previous isolation from Locusta migratoria (Lm) of a shorter RXR isoform (now called LmRXR-S), the isolation of a second, longer isoform (LmRXR-L) that appears to have characteristics of a ligand-modulated nuclear receptor is reported here. Transcripts for both isoforms, as well as LmEcR, were detected in embryos and in females during oocyte maturation. After expression in E. coli, both LmRXR-S and LmRXR-L form heterodimers with recombinant LmEcR in vitro which bind the active ecdysteroid, ponasterone A. Binding was only weakly competed for by ecdysone agonists that are known to be toxic to more advanced insects, suggesting functionally significant divergence in EcR ligand binding domains. In contrast, the DNA binding domain of LmEcR is less divergent and a protein complex, presumably LmEcR/LmRXR, that bound the ecdysone response element, IR-1, was detected in locust nuclear extracts. Because of reports of juvenile hormone (JH III) binding to Drosophila USP and the observed in silico RXR-like ligand-binding site in LmRXR-L, the recombinant proteins were also tested for binding to JH III. Neither LmRXR isoform, alone or in combination with LmEcR, bound JH III at nanomolar concentrations.

Synthesis and biological activities of turkesterone 11alpha-acyl derivatives.

Turkesterone is a phytoecdysteroid possessing an 11alpha-hydroxyl group. It is an analogue of the insect steroid hormone 20-hydroxyecdysone. Previous ecdysteroid QSAR and molecular modelling studies predicted that the cavity of the ligand binding domain of the ecdysteroid receptor would possess space in the vicinity of C-11/C-12 of the ecdysteroid. We report the regioselective synthesis of a series of turkesterone 11alpha-acyl derivatives in order to explore this possibility. The structures of the analogues have been unambiguously determined by spectroscopic means (NMR and low-resolution mass spectrometry). Purity was verified by HPLC. Biological activities have been determined in Drosophila melanogaster B(II) cell-based bioassay for ecdysteroid agonists and in an in vitro radioligand-displacement assay using bacterially-expressed D. melanogaster EcR/USP receptor proteins. The 11alpha-acyl derivatives do retain a significant amount of biological activity relative to the parent ecdysteroid. Further, although activity initially drops with the extension of the acyl chain length (C2 to C4), it then increases (C6 to C10), before decreasing again (C14 and C20). The implications of these findings for the interaction of ecdysteroids with the ecdysteroid receptor and potential applications in the generation of affinity-labelled and fluorescently-tagged ecdysteroids are discussed.

Ecdysteroid 7,9(11)-dien-6-ones as potential photoaffinity labels for ecdysteroid binding proteins.

Three ecdysteroid 7,9(11)-dien-7-ones (dacryhainansterone, 25-hydroxydacryhainansterone and kaladasterone) were prepared by dehydration of the corresponding 11a-hydroxy ecdysteroids (ajugasterone C, turkesterone and muristerone A, respectively). The biological activities of the dienones in the Drosophila melanogaster B(II) cell bioassay, which reflect the affinity for the ecdysteroid receptor complex, showed that the dienones retain high biological activity. Irradiation at 350 nm of the ecdysteroid dienones (100 nM) with bacterially-expressed dipteran and lepidopteran ecdysteroid receptor proteins (DmEcR/DmUSP or CfEcR/CfUSP), followed by loading with [(3)H]ponasterone A revealed that irradiation of dacryhainansterone or kaladasterone resulted in blocking of >70% of the specific binding sites. Thus, ecdysteroid dienones show considerable potential as photoaffinity analogues for ecdysteroid binding proteins.