Different Impacts of Ni2+ and Li+ to Plants and Mycorrhiza Systems: Roles of Bioligands Forming Metal-Binding Complexes in Cells and Apoplasts

Research output: Chapter in book/report/conference proceedingContribution to book/anthologyResearchpeer review

Authors

  • Masahiro Inouhe
  • Yui Katsuta
  • Aki Kato
  • Hirotaka Kato
  • Yoh Sakuma
  • Clemens Walther
  • Veenu Joon
  • Dharmendra K. Gupta

Research Organisations

External Research Organisations

  • Ehime University
  • Ministry of Environment, Forest and Climate Change
  • Ministry of Environment, Forest and Climate Change India
View graph of relations

Details

Original languageEnglish
Title of host publicationLithium and Nickel Contamination in Plants and the Environment
PublisherWorld Scientific Publishing Co. Pte Ltd
Pages139-169
Number of pages31
ISBN (electronic)9789811283123
ISBN (print)9789811283116
Publication statusPublished - Mar 2024

Publication series

NameWorld Scientific Series on Advances in Environmental Pollution Management
PublisherWorld Scientific Publishing Co Pte Ltd
Volume1

Abstract

Water uptake and nutritious mineral utilisation via roots from the soil are the critical requirements for terrestrial plants that have evolved as the major host organisms on the grove of Earth, autotrophically nourishing animals, fungi and many other heterotrophic organisms and continuing to play a crucial role in forming the landscapes of the planet’s biosphere. Minerals taken up from the ground return to the earth via food chains and biome networks through the actions of consumers and decomposers. Through the cyclic usage of inorganic and organic resources, plants and their associates sustain and develop as whole communities. In this chapter, based on such a co-association, or co-evolution, concept, the important interactions between autotrophic plants and the coordinative or competitional fungi and microbes are discussed and emphasised, especially in relation to plant stresses caused by excess levels of Li+ and Ni2+ ions in land environments. Li and Ni are gathering more attention, as well as cobalt (Co), because of their importance as very useful elements in industrial activities and sustainable energy for people in the future; however, their use is also accompanied by the incidental threat and concern about their possible increases through release and contamination into land and other environments. Li belongs to the group of relatively abundant alkaline metals (light metals), and Ni is one of the rare and micro-elementary heavy metals. Although their differential and unique impacts on plants and fungi are known, their combinational effects are not well known, so it will be necessary to address the increasing risks in the near future. In this chapter, the existing evidence will be substantiated with details about their bindings and localisations with different bioligands and polymers in the cells of plants or fungi. Taken together, we discuss the importance of complex binding and detoxification systems in plants and the symbiotic associates under combined stresses caused by the two metals as well as others.

Keywords

    Alkaline metal, apoplast, arbuscular mycorrhizal fungus (AMF), cell wall polymer, ectomycorrhizal fungus (EMF), glutathione (GSH), heavy metal (HM), histidine (His), hyperaccumulation, lithium ion (Li), membrane transport, metal-binding complex, metal-binding ligand (N-, metallothionein (MT), mucigel, mycorrhiza, nickel ion (Ni), O-and S-ligands), organic acid (OA), pectin, phenolics, phosphate sugars, phytic acid, phytochelatin (PC), proline (Pro), rhizosphere, siderophore, silicate, symbiotic association, symplast, vacuole

ASJC Scopus subject areas

Cite this

Different Impacts of Ni2+ and Li+ to Plants and Mycorrhiza Systems: Roles of Bioligands Forming Metal-Binding Complexes in Cells and Apoplasts. / Inouhe, Masahiro; Katsuta, Yui; Kato, Aki et al.
Lithium and Nickel Contamination in Plants and the Environment. World Scientific Publishing Co. Pte Ltd, 2024. p. 139-169 (World Scientific Series on Advances in Environmental Pollution Management; Vol. 1).

Research output: Chapter in book/report/conference proceedingContribution to book/anthologyResearchpeer review

Inouhe, M, Katsuta, Y, Kato, A, Kato, H, Sakuma, Y, Walther, C, Joon, V & Gupta, DK 2024, Different Impacts of Ni2+ and Li+ to Plants and Mycorrhiza Systems: Roles of Bioligands Forming Metal-Binding Complexes in Cells and Apoplasts. in Lithium and Nickel Contamination in Plants and the Environment. World Scientific Series on Advances in Environmental Pollution Management, vol. 1, World Scientific Publishing Co. Pte Ltd, pp. 139-169. https://doi.org/10.1142/9789811283123_0006
Inouhe, M., Katsuta, Y., Kato, A., Kato, H., Sakuma, Y., Walther, C., Joon, V., & Gupta, D. K. (2024). Different Impacts of Ni2+ and Li+ to Plants and Mycorrhiza Systems: Roles of Bioligands Forming Metal-Binding Complexes in Cells and Apoplasts. In Lithium and Nickel Contamination in Plants and the Environment (pp. 139-169). (World Scientific Series on Advances in Environmental Pollution Management; Vol. 1). World Scientific Publishing Co. Pte Ltd. https://doi.org/10.1142/9789811283123_0006
Inouhe M, Katsuta Y, Kato A, Kato H, Sakuma Y, Walther C et al. Different Impacts of Ni2+ and Li+ to Plants and Mycorrhiza Systems: Roles of Bioligands Forming Metal-Binding Complexes in Cells and Apoplasts. In Lithium and Nickel Contamination in Plants and the Environment. World Scientific Publishing Co. Pte Ltd. 2024. p. 139-169. (World Scientific Series on Advances in Environmental Pollution Management). doi: 10.1142/9789811283123_0006
Inouhe, Masahiro ; Katsuta, Yui ; Kato, Aki et al. / Different Impacts of Ni2+ and Li+ to Plants and Mycorrhiza Systems : Roles of Bioligands Forming Metal-Binding Complexes in Cells and Apoplasts. Lithium and Nickel Contamination in Plants and the Environment. World Scientific Publishing Co. Pte Ltd, 2024. pp. 139-169 (World Scientific Series on Advances in Environmental Pollution Management).
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abstract = "Water uptake and nutritious mineral utilisation via roots from the soil are the critical requirements for terrestrial plants that have evolved as the major host organisms on the grove of Earth, autotrophically nourishing animals, fungi and many other heterotrophic organisms and continuing to play a crucial role in forming the landscapes of the planet{\textquoteright}s biosphere. Minerals taken up from the ground return to the earth via food chains and biome networks through the actions of consumers and decomposers. Through the cyclic usage of inorganic and organic resources, plants and their associates sustain and develop as whole communities. In this chapter, based on such a co-association, or co-evolution, concept, the important interactions between autotrophic plants and the coordinative or competitional fungi and microbes are discussed and emphasised, especially in relation to plant stresses caused by excess levels of Li+ and Ni2+ ions in land environments. Li and Ni are gathering more attention, as well as cobalt (Co), because of their importance as very useful elements in industrial activities and sustainable energy for people in the future; however, their use is also accompanied by the incidental threat and concern about their possible increases through release and contamination into land and other environments. Li belongs to the group of relatively abundant alkaline metals (light metals), and Ni is one of the rare and micro-elementary heavy metals. Although their differential and unique impacts on plants and fungi are known, their combinational effects are not well known, so it will be necessary to address the increasing risks in the near future. In this chapter, the existing evidence will be substantiated with details about their bindings and localisations with different bioligands and polymers in the cells of plants or fungi. Taken together, we discuss the importance of complex binding and detoxification systems in plants and the symbiotic associates under combined stresses caused by the two metals as well as others.",
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T2 - Roles of Bioligands Forming Metal-Binding Complexes in Cells and Apoplasts

AU - Inouhe, Masahiro

AU - Katsuta, Yui

AU - Kato, Aki

AU - Kato, Hirotaka

AU - Sakuma, Yoh

AU - Walther, Clemens

AU - Joon, Veenu

AU - Gupta, Dharmendra K.

PY - 2024/3

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N2 - Water uptake and nutritious mineral utilisation via roots from the soil are the critical requirements for terrestrial plants that have evolved as the major host organisms on the grove of Earth, autotrophically nourishing animals, fungi and many other heterotrophic organisms and continuing to play a crucial role in forming the landscapes of the planet’s biosphere. Minerals taken up from the ground return to the earth via food chains and biome networks through the actions of consumers and decomposers. Through the cyclic usage of inorganic and organic resources, plants and their associates sustain and develop as whole communities. In this chapter, based on such a co-association, or co-evolution, concept, the important interactions between autotrophic plants and the coordinative or competitional fungi and microbes are discussed and emphasised, especially in relation to plant stresses caused by excess levels of Li+ and Ni2+ ions in land environments. Li and Ni are gathering more attention, as well as cobalt (Co), because of their importance as very useful elements in industrial activities and sustainable energy for people in the future; however, their use is also accompanied by the incidental threat and concern about their possible increases through release and contamination into land and other environments. Li belongs to the group of relatively abundant alkaline metals (light metals), and Ni is one of the rare and micro-elementary heavy metals. Although their differential and unique impacts on plants and fungi are known, their combinational effects are not well known, so it will be necessary to address the increasing risks in the near future. In this chapter, the existing evidence will be substantiated with details about their bindings and localisations with different bioligands and polymers in the cells of plants or fungi. Taken together, we discuss the importance of complex binding and detoxification systems in plants and the symbiotic associates under combined stresses caused by the two metals as well as others.

AB - Water uptake and nutritious mineral utilisation via roots from the soil are the critical requirements for terrestrial plants that have evolved as the major host organisms on the grove of Earth, autotrophically nourishing animals, fungi and many other heterotrophic organisms and continuing to play a crucial role in forming the landscapes of the planet’s biosphere. Minerals taken up from the ground return to the earth via food chains and biome networks through the actions of consumers and decomposers. Through the cyclic usage of inorganic and organic resources, plants and their associates sustain and develop as whole communities. In this chapter, based on such a co-association, or co-evolution, concept, the important interactions between autotrophic plants and the coordinative or competitional fungi and microbes are discussed and emphasised, especially in relation to plant stresses caused by excess levels of Li+ and Ni2+ ions in land environments. Li and Ni are gathering more attention, as well as cobalt (Co), because of their importance as very useful elements in industrial activities and sustainable energy for people in the future; however, their use is also accompanied by the incidental threat and concern about their possible increases through release and contamination into land and other environments. Li belongs to the group of relatively abundant alkaline metals (light metals), and Ni is one of the rare and micro-elementary heavy metals. Although their differential and unique impacts on plants and fungi are known, their combinational effects are not well known, so it will be necessary to address the increasing risks in the near future. In this chapter, the existing evidence will be substantiated with details about their bindings and localisations with different bioligands and polymers in the cells of plants or fungi. Taken together, we discuss the importance of complex binding and detoxification systems in plants and the symbiotic associates under combined stresses caused by the two metals as well as others.

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