2020 Fiscal Year Annual Research Report
Dissecting role of sucrose and GA recognition in SWEET transporters
Project/Area Number |
19H00932
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Research Institution | Nagoya University |
Principal Investigator |
Frommer Wolf 名古屋大学, トランスフォーマティブ生命分子研究所, 客員教授 (70795575)
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Project Period (FY) |
2019-04-01 – 2022-03-31
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Keywords | Phytohormone / Gibberellic acid / Sugar / SWEETs / Transporter |
Outline of Annual Research Achievements |
SWEETs play essential roles through the transport activity for sucrose and/or glucose. In addition to sugars, SWEETs can transport gibberellic acid (GA). Sugars and phytohormones are essential to the fundamental processes of plant development and growth. It has remained unclear, however, which spectrum of substrates SWEETs can transport, and how SWEETs can transport substrates. To understand the molecular mechanisms of substrate selectivity of plant transporters, we studied the substrate recognition of SWEETs using molecular docking and molecular dynamics. The docking studies have revealed residues of AtSWEET13 involved in binding GA and/or sucrose. In this fiscal year, through the in-cell transporter activity assay using mammalian cells, we identified the residue which is required for substrate selectivity. Currently, we are investigating how the identified residues of transporter function in plants.
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Current Status of Research Progress |
Current Status of Research Progress
2: Research has progressed on the whole more than it was originally planned.
Reason
The docking studies have revealed residues of AtSWEET13 involved in binding GA and/or sucrose. Through the in-cell transporter activity assay using mammalian cells, we identified the residue which is required for substrate selectivity.
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Strategy for Future Research Activity |
The substrate selectivity of transporters is critical to accomplish the complex systems in biological processes. However, the molecular mechanisms of the substrate selectivity of transporters have not been fully elucidated. SWEETs play essential roles through the transport activity for sucrose and/or glucose. In addition to sugars, SWEETs can transport GA. The docking studies and in-cell transporter activity assay have revealed residues of AtSWEET13 involved in binding GA and sucrose. We will investigate how the residues we identified as being involved in substrate selectivity function in plants. In addition, we have established a screening system to identify small molecules selectively inhibiting the SWEET transport activity. The screen is being performed in 96-well format with 70,000 compounds from ITbM chemical library.
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Research Products
(1 results)