Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan

Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan

The 1,4-linked glucans such as xyloglucan and amylose are known to form a complex with iodine/iodide ions and to also be precipitated with CaCl<sub>2</sub> in the presence of iodine. Here, we show that iodine gas could be specifically incorporated into xyloglucan. Furthermore, we show th...

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Main Authors: Miki Nonaka, Chisato Yasukawa, Shoko Aoki, Masateru Itakura, Stefan Willför, Peter Capek, Oded Shoseyov, Masaharu Tsubokura, Kei’ichi Baba, Rumi Kaida, Teruaki Taji, Yoichi Sakata, Takahisa Hayashi
Format: Article
Language:English
Published: MDPI AG 2020-09-01
Series:Forests
Subjects:
radioiodine gas
forest function
1,4-linked glucans
poplar seedlings
xyloglucan
Online Access:https://www.mdpi.com/1999-4907/11/9/957
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spelling doaj-83e16938f3384a56a4960abc35c131622020-11-25T03:48:11ZengMDPI AGForests1999-49072020-09-011195795710.3390/f11090957Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to XyloglucanMiki Nonaka0Chisato Yasukawa1Shoko Aoki2Masateru Itakura3Stefan Willför4Peter Capek5Oded Shoseyov6Masaharu Tsubokura7Kei’ichi Baba8Rumi Kaida9Teruaki Taji10Yoichi Sakata11Takahisa Hayashi12Department of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanDepartment of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanDepartment of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanDepartment of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanJohan Gadolin Process Chemistry Centre, Åbo Akademi University, FI-20500 Turku, FinlandInstitute of Chemistry, Center for Glycomics, Slovak Academy of Sciences, SK-845 38 Bratislava, SlovakiaThe Robert H. Smith Institute of Plant Sciences and Genetics, The Hebrew University of Jerusalem, Rehovot 76100, IsraelDepartment of Radiation Protection, Minamisoma Municipal General Hospital, Minamisoma 975-0033, Fukushima, JapanResearch Institute for Sustainable Humanosphere, Kyoto University, Kyoto 611-0011, JapanDepartment of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanDepartment of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanDepartment of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanDepartment of Bioscience, Tokyo University of Agriculture, Tokyo 156-8502, JapanThe 1,4-linked glucans such as xyloglucan and amylose are known to form a complex with iodine/iodide ions and to also be precipitated with CaCl<sub>2</sub> in the presence of iodine. Here, we show that iodine gas could be specifically incorporated into xyloglucan. Furthermore, we show that [<sup>125</sup>I]I<sub>2</sub> gas is, over time, incorporated at high levels into the entire outer surface of poplar seedlings but that spraying seedlings with abscisic acid to close stomata decreases the incorporation of the gas. There was less incorporation of the gas in a transgenic poplar overexpressing xyloglucanase at the early stages when compared with a wild type. This shows that xyloglucan serves as a key absorber of iodine gas into a plant body. After individual leaves of cultured seedlings were exposed to the gas for 30 min, no radioiodine was emitted from those leaves over the following two weeks, indicating that no turnover occurs in radioiodine once it is bound to the polysaccharides in plant tissues. We conclude that forest trees could serve as one of the largest enormous capture systems for the radioiodine fallout following the nuclear power plant accident in Fukushima.https://www.mdpi.com/1999-4907/11/9/957radioiodine gasforest function1,4-linked glucanspoplar seedlingsxyloglucan
collection DOAJ
language English
format Article
sources DOAJ
author Miki Nonaka
Chisato Yasukawa
Shoko Aoki
Masateru Itakura
Stefan Willför
Peter Capek
Oded Shoseyov
Masaharu Tsubokura
Kei’ichi Baba
Rumi Kaida
Teruaki Taji
Yoichi Sakata
Takahisa Hayashi
spellingShingle Miki Nonaka
Chisato Yasukawa
Shoko Aoki
Masateru Itakura
Stefan Willför
Peter Capek
Oded Shoseyov
Masaharu Tsubokura
Kei’ichi Baba
Rumi Kaida
Teruaki Taji
Yoichi Sakata
Takahisa Hayashi
Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan
Forests
radioiodine gas
forest function
1,4-linked glucans
poplar seedlings
xyloglucan
author_facet Miki Nonaka
Chisato Yasukawa
Shoko Aoki
Masateru Itakura
Stefan Willför
Peter Capek
Oded Shoseyov
Masaharu Tsubokura
Kei’ichi Baba
Rumi Kaida
Teruaki Taji
Yoichi Sakata
Takahisa Hayashi
author_sort Miki Nonaka
title Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan
title_short Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan
title_full Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan
title_fullStr Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan
title_full_unstemmed Intake of Radionuclides in the Trees of Fukushima Forests 4. Binding of Radioiodine to Xyloglucan
title_sort intake of radionuclides in the trees of fukushima forests 4. binding of radioiodine to xyloglucan
publisher MDPI AG
series Forests
issn 1999-4907
publishDate 2020-09-01
description The 1,4-linked glucans such as xyloglucan and amylose are known to form a complex with iodine/iodide ions and to also be precipitated with CaCl<sub>2</sub> in the presence of iodine. Here, we show that iodine gas could be specifically incorporated into xyloglucan. Furthermore, we show that [<sup>125</sup>I]I<sub>2</sub> gas is, over time, incorporated at high levels into the entire outer surface of poplar seedlings but that spraying seedlings with abscisic acid to close stomata decreases the incorporation of the gas. There was less incorporation of the gas in a transgenic poplar overexpressing xyloglucanase at the early stages when compared with a wild type. This shows that xyloglucan serves as a key absorber of iodine gas into a plant body. After individual leaves of cultured seedlings were exposed to the gas for 30 min, no radioiodine was emitted from those leaves over the following two weeks, indicating that no turnover occurs in radioiodine once it is bound to the polysaccharides in plant tissues. We conclude that forest trees could serve as one of the largest enormous capture systems for the radioiodine fallout following the nuclear power plant accident in Fukushima.
topic radioiodine gas
forest function
1,4-linked glucans
poplar seedlings
xyloglucan
url https://www.mdpi.com/1999-4907/11/9/957
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