Identification of stomatal-regulating molecules from de novo arylamine collection through aromatic C–H amination
Identification of stomatal-regulating molecules from de novo arylamine collection through aromatic C–H amination
Stomata—small pores generally found on the leaves of plants—control gas exchange between plant and the atmosphere. Elucidating the mechanism that underlies such control through the regulation of stomatal opening/closing is important to understand how plants regulate photosynthesis and tolerate against drought. However, up-to-date, molecular components and their function involved in stomatal regulation are not fully understood. We challenged such problem through a chemical genetic approach by isolating and characterizing synthetic molecules that influence stomatal movement. Here, we describe that a small chemical collection, prepared during the development of C–H amination reactions, lead to the discovery of a Stomata Influencing Molecule (SIM); namely, a sulfonimidated oxazole that inhibits stomatal opening. The starting molecule SIM1 was initially isolated from screening of compounds that inhibit light induced opening of dayflower stomata. A range of SIM molecules were rapidly accessed using our state-of-the-art C–H amination technologies. This enabled an efficient structure–activity relationship (SAR) study, culminating in the discovery of a sulfonamidated oxazole derivative (SIM*) having higher activity and enhanced specificity against stomatal regulation. Biological assay results have shed some light on the mode of action of SIM molecules within the cell, which may ultimately lead to drought tolerance-conferring agrochemicals through the control of stomatal movement.
Toda, Yosuke
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Perry, Gregory J.P.
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Inoue, Shimpei
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Ito, Eri
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Kawakami, Takahiro
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Narouz, Mina R.
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Takahashi, Koji
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Aihara, Yusuke
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Maeda, Bumpei
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Kinoshita, Toshinori
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Itami, Kenichiro
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Murakami, Kei
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18 January 2022
Toda, Yosuke
b06c5eae-145a-4f0a-bc31-dd64bb33b76a
Perry, Gregory J.P.
766e7fc8-abf3-4d1e-9949-c1b3439a2185
Inoue, Shimpei
4b94d201-3112-4c5c-9c62-7e48db9343a5
Ito, Eri
8a754b68-c4bb-4b7d-ae85-72681ccdd3c3
Kawakami, Takahiro
d4eb5daa-d3bf-462f-9259-777af771d762
Narouz, Mina R.
9a62940f-a756-49ca-91d5-afcc56dfd98d
Takahashi, Koji
1f1f31bd-5830-4441-885f-e4cb26268eed
Aihara, Yusuke
e7de3eda-cab9-4de9-81dd-0a762995fdf7
Maeda, Bumpei
43f44b51-3015-42d5-abae-307b25b7b468
Kinoshita, Toshinori
cbcd6991-e6c8-47f9-aea1-60b81c5a6311
Itami, Kenichiro
9b72935e-9ec7-4f27-802e-22d649c0d7e7
Murakami, Kei
d7cf6fde-2ead-4855-b524-80c84e19e266
Toda, Yosuke, Perry, Gregory J.P., Inoue, Shimpei, Ito, Eri, Kawakami, Takahiro, Narouz, Mina R., Takahashi, Koji, Aihara, Yusuke, Maeda, Bumpei, Kinoshita, Toshinori, Itami, Kenichiro and Murakami, Kei
(2022)
Identification of stomatal-regulating molecules from de novo arylamine collection through aromatic C–H amination.
Scientific Reports, 12, [949].
(doi:10.1038/s41598-022-04947-z).
Abstract
Stomata—small pores generally found on the leaves of plants—control gas exchange between plant and the atmosphere. Elucidating the mechanism that underlies such control through the regulation of stomatal opening/closing is important to understand how plants regulate photosynthesis and tolerate against drought. However, up-to-date, molecular components and their function involved in stomatal regulation are not fully understood. We challenged such problem through a chemical genetic approach by isolating and characterizing synthetic molecules that influence stomatal movement. Here, we describe that a small chemical collection, prepared during the development of C–H amination reactions, lead to the discovery of a Stomata Influencing Molecule (SIM); namely, a sulfonimidated oxazole that inhibits stomatal opening. The starting molecule SIM1 was initially isolated from screening of compounds that inhibit light induced opening of dayflower stomata. A range of SIM molecules were rapidly accessed using our state-of-the-art C–H amination technologies. This enabled an efficient structure–activity relationship (SAR) study, culminating in the discovery of a sulfonamidated oxazole derivative (SIM*) having higher activity and enhanced specificity against stomatal regulation. Biological assay results have shed some light on the mode of action of SIM molecules within the cell, which may ultimately lead to drought tolerance-conferring agrochemicals through the control of stomatal movement.
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Accepted/In Press date: 4 January 2022
Published date: 18 January 2022
Additional Information:
Funding Information:
This work was supported by JST ERATO Grant Numbers JPMJER1302 (K.I.), Japan, JSPS KAKENHI Grant Number JP19H05463 (K.I.), JP19K22251 (K.M.), Japan Science and Technology Agency (JST) PRESTO Grant No. JPMJPR17O5 (Y.T.), the Naito Foundation (K.M.), Wakashachi Young Scientists’ Award (K.M.), CASIO Science Promotion Foundation (K.M.). We thank Dr. Issey Takahashi for his help in preparing the figures. We appreciate the ITbM award grant to support our collaborative research. ITbM is supported by the World Premier International Research Center Initiative (WPI), Japan.
Publisher Copyright:
© 2022, The Author(s).
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Local EPrints ID: 477101
URI: http://eprints.soton.ac.uk/id/eprint/477101
ISSN: 2045-2322
PURE UUID: 2df8f1b6-8883-41ef-9e00-a772947d20bf
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Date deposited: 26 May 2023 16:34
Last modified: 18 Mar 2024 04:11
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Contributors
Author:
Yosuke Toda
Author:
Gregory J.P. Perry
Author:
Shimpei Inoue
Author:
Eri Ito
Author:
Takahiro Kawakami
Author:
Mina R. Narouz
Author:
Koji Takahashi
Author:
Yusuke Aihara
Author:
Bumpei Maeda
Author:
Toshinori Kinoshita
Author:
Kenichiro Itami
Author:
Kei Murakami
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