Plant Branching Chemical That Could Improve Crop Production
News Feb 12, 2018 | Original Story from the American Chemical Society.
A molecule, DL1, can spur plants such as the flower shown above to have more branches, which could make crops produce fruit more efficiently. Credit: American Chemical Society .
When it comes to agriculture from branched plants, such as apple trees, the more branches that bear fruit, the better. But in the real world, there’s a limit to the number of branches that plants make — a gene tends to put the brakes on this splitting process called shoot branching. Today in ACS Central Science, researchers reveal a chemical that can reverse this limitation, possibly leading to improved crop production.
Previous studies of a plant hormone that inhibits shoot branching resulted in the identification of a regulator gene called D14. Shinya Hagihara, Yuichiro Tsuchiya and colleagues reasoned that if they could inhibit this regulator, they could do the opposite and increase branching. Tsuchiya and Hagihara’s teams developed a screen in which they could monitor the shoot branching activity based on whether a reporter chemical called Yoshimulactone Green (YLG) glowed green. By screening a library of 800 compounds, the researchers found that 18 of them inhibited D14 by 70 percent or more. Of these, one called DL1 was particularly active and specific. This inhibitor could increase shoot branching in both a type of flower and in rice. In preparation for DL1’s use as a potential commercial agrochemical, the team is now testing how long the chemicals last in the soil and are investigating whether it is toxic to humans.
This article has been republished from materials provided by the American Chemical Society. Note: material may have been edited for length and content. For further information, please contact the cited source.
Discovery of shoot branching regulator targeting strigolactone receptor DWARF14. Masahiko Yoshimura, Ayato Sato, Keiko Kuwata, Yoshiaki Inukai, Toshinori Kinoshita, Kenichiro Itami, Yuichiro Tsuchiya, and Shinya Hagihara. ACS Central Science, DOI: 10.1021/acscentsci.7b00554.