Boron Toxicity in Higher Plants: an Update

Overview

Journal Planta

Specialty Biology

Date 2019 Jun 26

PMID 31236697

Citations 30

Authors

Marco Landi

Theoni Margaritopoulou

Ioannis E Papadakis

Fabrizio Araniti

Affiliations

Soon will be listed here.

Abstract

In this review, emphasis is given to the most recent updates about morpho-anatomical, physiological, biochemical and molecular responses adopted by plants to cope with B excess. Boron (B) is a unique micronutrient for plants given that the range of B concentration from its essentiality to toxicity is extremely narrow, and also because it occurs as an uncharged molecule (boric acid) which can pass lipid bilayers without any degree of controls, as occurs for other ionic nutrients. Boron frequently exceeds the plant's requirement in arid and semiarid environments due to poor drainage, and in agricultural soils close to coastal areas due to the intrusion of B-rich seawater in fresh aquifer or because of dispersion of seawater aerosol. Global releases of elemental B through weathering, volcanic and geothermal processes are also relevant in enriching B concentration in some areas. Considerable progress has been made in understanding how plants react to B toxicity and relevant efforts have been made to investigate: (I) B uptake and in planta partitioning, (II) physiological, biochemical, and molecular changes induced by B excess, with particular emphasis to the effects on the photosynthetic process, the B-triggered oxidative stress and responses of the antioxidant apparatus to B toxicity, and finally (III) mechanisms of B tolerance. Recent findings addressing the effects of B toxicity are reviewed here, intending to clarify the effect of B excess and to propose new perspectives aimed at driving future researches on the topic.

Citing Articles

Excessive boron fertilization-induced toxicity is related to boron transport in field-grown pomelo trees.

Luo Z, Zhang L, Hu W, Wang Y, Tao J, Jia Y Front Plant Sci. 2024; 15:1438664.

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Foliar applications of zinc oxide nanoparticles and boric acid affect leaf oxidative metabolism and productivity in young pecan trees.

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Integrative analysis of the transcriptome and proteome reveals the molecular responses of tobacco to boron deficiency.

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Zinc Oxide Nanoparticles and Zinc Sulfate Alleviate Boron Toxicity in Cotton ( L.).

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Casparian strips prevent apoplastic diffusion of boric acid into root steles for excess B tolerance.

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