"Using this reporter, we directly observed long distance ABA movements from the stem of a germinating seedling to the leaves and roots of the growing plant and, for the first time, we were able to determine the rate of ABA movement within the growing plant," says Schroeder.
"Using this tool, we now can detect ABA in live plants and see how it is distributed," says Rainer Waadt, a postdoctoral associate in Schroeder's laboratory and the first author of the paper. "We are also able to directly see that environmental stress causes an increase in the ABA concentration in the stomatal guard cells that surround each stomatal pore. In the future, our sensors can be used to study ABA distribution in response to different stresses, including CO2 elevations, and to identify other molecules and proteins that affect the distribution of this hormone. We can also learn how fast plants respond to stresses and which tissues are important for the response."
The researchers demonstrated that their new ABA nanosensors also function effectively as isolated proteins. This means that the sensors could be directly employed using state-of-the-art high-throughput screening platforms to screen for chemicals that could activate or enhance a drought resistance response. The scientists say such chemicals could become useful in the future for enhancing a drought resistance response, when crops experience a severe drought, like the one that occurred in the Midwest in the summer of 2012.
|Contact: Kim McDonald|
University of California - San Diego