Rational design of novel fluorescent enzyme biosensors for direct detection of strigolactones

Abstract

AbstractStrigolactones are plant hormones and rhizosphere signalling molecules with key roles in plant development, mycorrhizal fungal symbioses, and plant parasitism. Currently, sensitive, specific, and high-throughput methods of detecting strigolactones are limited. Here, we developed genetically encoded fluorescent strigolactone biosensors based on the strigolactone receptors DAD2 from Petunia hybrida, and HTL7 from Striga hermonthica via domain insertion of circularly permuted GFP. The DAD2 biosensor exhibited loss of cpGFP fluorescence in vitro upon treatment with the strigolactones 5-deoxystrigol and orobanchol, or the strigolactone analogue GR24. The biosensor likewise responded to strigolactones in an in vivo protoplast system, and retained strigolactone hydrolysis activity. The ShHTL7 biosensor exhibited loss of cpGFP fluorescence upon GR24 treatment in vitro, and responded to a specific inhibitor of ShHTL7 but not DAD2, indicating that the biosensors retained the specificity of their parent receptors. These biosensors have applications in high-throughput screening, and may also have utility for studying strigolactone biology.