Molecular evidences on transport of thiocyanate into rice seedlings and assimilation by 13 C and 15 N labelling and gene expression analyses

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Authors

  • Xiao Zhang Yu
  • Yu Juan Lin
  • Ping Ping Shen
  • Qing Zhang
  • Dharmendra K. Gupta

External Research Organisations

  • Guilin University of Technology
  • South China Seas Institute of Oceanography Chinese Academy of Sciences
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Details

Original languageEnglish
Pages (from-to)11-17
Number of pages7
JournalInternational Biodeterioration and Biodegradation
Volume139
Early online date27 Feb 2019
Publication statusPublished - Apr 2019

Abstract

Thiocyanate (SCN ) can be naturally produced by some plant species during assimilation of endogenous cyanide at very low levels, but higher concentration is detected in the environment from various industrial activities, which poses a potential threat to living organisms. In this study, uptake, transport, subcellular distribution and assimilation of SCN were investigated using rice seedlings exposed to 13 C- and 15 N-labbled potassium thiocyanate. Our results showed that rice seedlings had a higher potential for SCN uptake, and more was recovered in roots than shoots. Analysis of subcellular partition revealed that SCN were mainly deposited in cell wall, and followed by cytosol and organelle fractions. Analysis of stable isotopes in rice tissues showed that the molar ratios of 13 C to 15 N content were inconsistent in roots (0.66) and shoots (0.98). PCR analysis revealed different expression arrangements to 20 selected genes in rice tissues, suggesting that involvements of genes encoding with different enzymes in SCN assimilation are tissue specific. These unique genes should regulate and determine degradation pathway of SCN . Data from stable isotopes and PCR analysis suggests that “TMT (thiol methylation) pathway”, “COS (carbonyl sulfide) pathway” and “CNO (cyanate) pathway” are involved in detoxification of SCN in rice tissues concurrently at the first-degradation phase; Rice seedlings are also able to degrade both CNO and COS in roots effectively, while innate pools of enzymes cyanase (CYN) and carbonyl sulfide hydrolase (COSase) are non-sufficient for further degrade both intermediates in shoots. Our results presented here provide convincing evidence to clarify transport and detoxification pathways of SCN in rice seedlings.

Keywords

    Cyanase, Metabolism, PCR, Rhodanese, Rice, Stable isotope, Thiocyanate

ASJC Scopus subject areas

Cite this

Molecular evidences on transport of thiocyanate into rice seedlings and assimilation by 13 C and 15 N labelling and gene expression analyses. / Yu, Xiao Zhang; Lin, Yu Juan; Shen, Ping Ping et al.
In: International Biodeterioration and Biodegradation, Vol. 139, 04.2019, p. 11-17.

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@article{c32c3e49c0854283accd19935a41fa30,
title = "Molecular evidences on transport of thiocyanate into rice seedlings and assimilation by 13 C and 15 N labelling and gene expression analyses",
abstract = " Thiocyanate (SCN − ) can be naturally produced by some plant species during assimilation of endogenous cyanide at very low levels, but higher concentration is detected in the environment from various industrial activities, which poses a potential threat to living organisms. In this study, uptake, transport, subcellular distribution and assimilation of SCN − were investigated using rice seedlings exposed to 13 C- and 15 N-labbled potassium thiocyanate. Our results showed that rice seedlings had a higher potential for SCN − uptake, and more was recovered in roots than shoots. Analysis of subcellular partition revealed that SCN − were mainly deposited in cell wall, and followed by cytosol and organelle fractions. Analysis of stable isotopes in rice tissues showed that the molar ratios of 13 C to 15 N content were inconsistent in roots (0.66) and shoots (0.98). PCR analysis revealed different expression arrangements to 20 selected genes in rice tissues, suggesting that involvements of genes encoding with different enzymes in SCN − assimilation are tissue specific. These unique genes should regulate and determine degradation pathway of SCN − . Data from stable isotopes and PCR analysis suggests that “TMT (thiol methylation) pathway”, “COS (carbonyl sulfide) pathway” and “CNO (cyanate) pathway” are involved in detoxification of SCN − in rice tissues concurrently at the first-degradation phase; Rice seedlings are also able to degrade both CNO and COS in roots effectively, while innate pools of enzymes cyanase (CYN) and carbonyl sulfide hydrolase (COSase) are non-sufficient for further degrade both intermediates in shoots. Our results presented here provide convincing evidence to clarify transport and detoxification pathways of SCN − in rice seedlings. ",
keywords = "Cyanase, Metabolism, PCR, Rhodanese, Rice, Stable isotope, Thiocyanate",
author = "Yu, {Xiao Zhang} and Lin, {Yu Juan} and Shen, {Ping Ping} and Qing Zhang and Gupta, {Dharmendra K.}",
note = "Funding information: This work was financially supported by the National Natural Science Foundation of China (No: 41761094 ) and The Guangxi Talent Highland for Hazardous Waste Disposal Industrialization. This work was financially supported by the National Natural Science Foundation of China (No: 41761094 ).",
year = "2019",
month = apr,
doi = "10.1016/j.ibiod.2019.02.003",
language = "English",
volume = "139",
pages = "11--17",
journal = "International Biodeterioration and Biodegradation",
issn = "0964-8305",
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TY - JOUR

T1 - Molecular evidences on transport of thiocyanate into rice seedlings and assimilation by 13 C and 15 N labelling and gene expression analyses

AU - Yu, Xiao Zhang

AU - Lin, Yu Juan

AU - Shen, Ping Ping

AU - Zhang, Qing

AU - Gupta, Dharmendra K.

N1 - Funding information: This work was financially supported by the National Natural Science Foundation of China (No: 41761094 ) and The Guangxi Talent Highland for Hazardous Waste Disposal Industrialization. This work was financially supported by the National Natural Science Foundation of China (No: 41761094 ).

PY - 2019/4

Y1 - 2019/4

N2 - Thiocyanate (SCN − ) can be naturally produced by some plant species during assimilation of endogenous cyanide at very low levels, but higher concentration is detected in the environment from various industrial activities, which poses a potential threat to living organisms. In this study, uptake, transport, subcellular distribution and assimilation of SCN − were investigated using rice seedlings exposed to 13 C- and 15 N-labbled potassium thiocyanate. Our results showed that rice seedlings had a higher potential for SCN − uptake, and more was recovered in roots than shoots. Analysis of subcellular partition revealed that SCN − were mainly deposited in cell wall, and followed by cytosol and organelle fractions. Analysis of stable isotopes in rice tissues showed that the molar ratios of 13 C to 15 N content were inconsistent in roots (0.66) and shoots (0.98). PCR analysis revealed different expression arrangements to 20 selected genes in rice tissues, suggesting that involvements of genes encoding with different enzymes in SCN − assimilation are tissue specific. These unique genes should regulate and determine degradation pathway of SCN − . Data from stable isotopes and PCR analysis suggests that “TMT (thiol methylation) pathway”, “COS (carbonyl sulfide) pathway” and “CNO (cyanate) pathway” are involved in detoxification of SCN − in rice tissues concurrently at the first-degradation phase; Rice seedlings are also able to degrade both CNO and COS in roots effectively, while innate pools of enzymes cyanase (CYN) and carbonyl sulfide hydrolase (COSase) are non-sufficient for further degrade both intermediates in shoots. Our results presented here provide convincing evidence to clarify transport and detoxification pathways of SCN − in rice seedlings.

AB - Thiocyanate (SCN − ) can be naturally produced by some plant species during assimilation of endogenous cyanide at very low levels, but higher concentration is detected in the environment from various industrial activities, which poses a potential threat to living organisms. In this study, uptake, transport, subcellular distribution and assimilation of SCN − were investigated using rice seedlings exposed to 13 C- and 15 N-labbled potassium thiocyanate. Our results showed that rice seedlings had a higher potential for SCN − uptake, and more was recovered in roots than shoots. Analysis of subcellular partition revealed that SCN − were mainly deposited in cell wall, and followed by cytosol and organelle fractions. Analysis of stable isotopes in rice tissues showed that the molar ratios of 13 C to 15 N content were inconsistent in roots (0.66) and shoots (0.98). PCR analysis revealed different expression arrangements to 20 selected genes in rice tissues, suggesting that involvements of genes encoding with different enzymes in SCN − assimilation are tissue specific. These unique genes should regulate and determine degradation pathway of SCN − . Data from stable isotopes and PCR analysis suggests that “TMT (thiol methylation) pathway”, “COS (carbonyl sulfide) pathway” and “CNO (cyanate) pathway” are involved in detoxification of SCN − in rice tissues concurrently at the first-degradation phase; Rice seedlings are also able to degrade both CNO and COS in roots effectively, while innate pools of enzymes cyanase (CYN) and carbonyl sulfide hydrolase (COSase) are non-sufficient for further degrade both intermediates in shoots. Our results presented here provide convincing evidence to clarify transport and detoxification pathways of SCN − in rice seedlings.

KW - Cyanase

KW - Metabolism

KW - PCR

KW - Rhodanese

KW - Rice

KW - Stable isotope

KW - Thiocyanate

UR - http://www.scopus.com/inward/record.url?scp=85061983260&partnerID=8YFLogxK

U2 - 10.1016/j.ibiod.2019.02.003

DO - 10.1016/j.ibiod.2019.02.003

M3 - Article

AN - SCOPUS:85061983260

VL - 139

SP - 11

EP - 17

JO - International Biodeterioration and Biodegradation

JF - International Biodeterioration and Biodegradation

SN - 0964-8305

ER -