Iron and Zinc in the Embryo and Endosperm of Rice ( L.) Seeds in Contrasting 2'-Deoxymugineic Acid/Nicotianamine Scenarios

Overview

Journal Front Plant Sci

Date 2018 Sep 7

PMID 30186295

Citations 20

Authors

Pablo Diaz-Benito

Raviraj Banakar

Sara Rodriguez-Menendez

Teresa Capell

Rosario Pereiro

Paul Christou

Javier Abadia

Beatriz Fernandez

Ana Alvarez-Fernandez

Affiliations

Soon will be listed here.

Abstract

Iron and Zn deficiencies are worldwide nutritional disorders that can be alleviated by increasing the metal concentration of rice ( L.) grains bio-fortification approaches. The overproduction of the metal chelator nicotianamine (NA) is among the most effective ones, but it is still unclear whether this is due to the enrichment in NA itself and/or the concomitant enrichment in the NA derivative 2'-deoxymugineic acid (DMA). The endosperm is the most commonly consumed portion of the rice grain and mediates the transfer of nutrients from vegetative tissues to the metal rich embryo. The impact of contrasting levels of DMA and NA on the metal distribution in the embryo and endosperm of rice seeds has been assessed using wild-type rice and six different transgenic lines overexpressing nicotianamine synthase () and/or barley nicotianamine amino transferase (). These transgenic lines outlined three different DMA/NA scenarios: (i) in a first scenario, an enhanced NA level ( overexpression of ) would not be fully depleted because of a limited capacity to use NA for DMA synthesis (lack of -or low- expression of ), and results in consistent enrichments in NA, DMA, Fe and Zn in the endosperm and NA, DMA and Fe in the embryo; (ii) in a second scenario, an enhanced NA level ( overexpression of ) would be depleted by an enhanced capacity to use NA for DMA synthesis ( expression of ), and results in enrichments only for DMA and Fe, both in the endosperm and embryo, and (iii) in a third scenario, the lack of sufficient NA replenishment would limit DMA synthesis, in spite of the enhanced capacity to use NA for this purpose ( expression of ), and results in decreases in NA, variable changes in DMA and moderate decreases in Fe in the embryo and endosperm. Also, quantitative LA-ICP-MS metal map images of the embryo structures show that the first and second scenarios altered local distributions of Fe, and to a lesser extent of Zn. The roles of DMA/NA levels in the transport of Fe and Zn within the embryo are thoroughly discussed.

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