Development of a Chromosomally Integrated Metabolite-Inducible Leu3p-α-IPM “Off-On” Gene Switch

Background: Present technology uses mostly chimeric proteins as regulators and hormones or antibiotics as signals to induce spatial and temporal gene expression. Methodology/Principal Findings: Here, we show that a chromosomally integrated yeast ‘Leu3p-a-IRM ’ system constitutes a ligand-inducible regulatory ‘‘off-on’ ’ genetic switch with an extensively dynamic action area. We find that Leu3p acts as an active transcriptional repressor in the absence and as an activator in the presence of a-isopropylmalate (a-IRM) in primary fibroblasts isolated from double transgenic mouse embryos bearing ubiquitously expressing Leu3p and a Leu3p regulated GFP reporter. In the absence of the branched amino acid biosynthetic pathway in animals, metabolically stable a-IPM presents an EC 50 equal to 0.8837 mM and fast ‘‘OFF-ON’ ’ kinetics (t 50ON = 43 min, t 50OFF = 2.18 h), it enters the cells via passive diffusion, while it is non-toxic to mammalian cells and to fertilized mouse eggs cultured ex vivo. Conclusions/Significance: Our results demonstrate that the ‘Leu3p-a-IRM ’ constitutes a simpler and safer system for inducible gene expression in biomedical applications