A set of thirty-two natural and ten semisynthetic ecdysteroids was assayed in murine 3T3 cells across ten different ecdysteroid receptor (EcR) ligandbinding domains derived from nine arthropod species in an engineered gene switch format. Among the ecdysteroids tested, the most biologically widespread ecdysteroid, 20-hydroxyecdysone (20E), was moderately and consistently potent across the tested EcRs. The most potent ligand-receptor combination (EC 50 = 0.3 nm) was ponasterone A (PoA) actuating the Nephotettix cincticeps EcR switch. The most robust ligand-receptor combination, as measured by potency and efficacy, was PoA actuating either the Bombyx mori EcR or a 'VY' (E274V ⁄ V390I ⁄ Y410E) mutant of Choristoneura fumiferana EcR. Parallel ecdysteroid structure-activity relationships were observed across species; addition of hydroxyl groups at positions 2, 3, 14, 20 and 22 incrementally enhanced potency, whereas hydroxylation at position 25 retarded potency. Nevertheless, several outlier ligand-EcR combinations, such as cyasterone actuating the VY C. fumiferana EcR mutant and canescensterone activating Bemisia argentifolii EcR, exhibited an inversion of relative potency, and therefore lend themselves to construction of orthogonal duplex gene switches. The potency inversion between these two ligand-receptor pairs can be accounted for by steroid-tail contact residues Tyr411 and Met502 in VY C. fumiferana EcR corresponding to two threonines in B. argentifolii EcR. Another potency inversion was also observed with cyasterone operating on the VY mutant of C. fumiferana EcR and polypodine B activating Aedes aegypti EcR. The ecdysteroid-EcR dataset, generated in a non-natural system, nevertheless invites conjecture regarding relative ecdysteroid potencies, plant species distribution of certain phytoecdysteroids, and the role of phytoecdysteroids as chemodefense against relevant insect herbivores.
Gene expression can be controlled in genetically modified cells by employing an inducer/promoter system where presence of the inducer molecule regulates the timing and level of gene expression. By applying the principles of controlled release, it should be possible to control gene expression on a biomaterial surface by the presence or absence of inducer release from the underlying material matrix, thus avoiding alternative techniques that rely upon uptake of relatively labile DNA from material surfaces. To evaluate this concept, a modified ecdysone-responsive gene expression system was transfected into B16 murine cells and the ability of an inducer ligand, which was released from elastomeric poly(ester urethane) urea (PEUU), to initiate gene expression was studied. The synthetic inducer ligand was first loaded into PEUU to demonstrate extended release of the bioactive molecule at various loading densities over a one year period in vitro. Patterning films of PEUU variably-loaded with inducer resulted in spatially controlled cell expression of the gene product (green fluorescent protein, GFP). In porous scaffolds made from PEUU by salt leaching, where the central region was exclusively loaded with inducer, cells expressed GFP predominately in the loaded central regions whereas expression was minimal in outer regions where ligand was omitted. This scaffold system may ultimately provide a means to precisely control progenitor cell commitment in a spatially-defined manner in vivo for soft tissue repair and regeneration.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.