Role of Silicon in Plant Stress Tolerance: Opportunities to Achieve a Sustainable Cropping System

Overview

Journal 3 Biotech

Publisher Springer

Specialty Biotechnology

Date 2019 Feb 26

PMID 30800584

Citations 43

Authors

Sajad Majeed Zargar

Reetika Mahajan

Javaid A Bhat

Muslima Nazir

Rupesh Deshmukh

Affiliations

Soon will be listed here.

Abstract

Silicon (Si) being considered as a non-essential element for plant growth and development finds its role in providing several benefits to the plant, especially under stress conditions. Thus, Si can be regarded as "multi-talented" quasi-essential element. It is the most abundant element present in the earth's crust after oxygen predominantly as a silicon dioxide (SiO), a form plants cannot utilize. Plants take up Si into their root from the soil in the plant-available forms (PAF) such as silicic acid or mono silicic acid [Si(OH) or HSiO]. Nevertheless, besides being abundantly available, the PAF of Si in the soil is mostly a limiting factor. To improve Si-uptake and derived benefits therein in plants, understanding the molecular basis of Si-uptake and transport within the tissues has great importance. Numerous Si-transporters (influx and efflux) have been identified in both monocot and dicot plants. A difference in the root anatomy of both monocot and dicot plants leads to a difference in the Si-uptake mechanism. In the present review, Si-transporters identified in different species, their evolution and the Si-uptake mechanism have been addressed. Further, the role of Si in biotic and abiotic stress tolerance has been discussed. The information provided here will help to plan the research in a better way to develop more sustainable cropping system by harnessing Si-derived benefits.

Citing Articles

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Enhancing Salt Stress Tolerance in Tomato ( L.) through Silicon Application in Roots.

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