Role of a vacuolar iron transporter OsVIT2 in the distribution of iron to rice grains

Che, Jianfei; Yamaji, Naoki; Feng, Jian

doi:10.1111/nph.17219

Cited by 57 publications

(32 citation statements)

References 56 publications

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“…Thus, OsYSL9 is a good target gene for bioreinforcement. In rice, regulating Fe intracellular transport by decreasing OsVIT1 or OsVIT2 expression can promote inter-tissue Fe transport from flag leaves to grains, eventually increasing the endosperm Fe concentration [118][119][120]. Fe accumulation in polished rice can be altered by regulating the stem vacuolar mugineic acid transporter gene OsVMT, which is a vacuole membrane protein responsible for DMA transport into vacuoles.…”

Section: Genetic Engineering Technology Improves Fe Capacity In Rice ...mentioning

confidence: 99%

Research and Progress on the Mechanism of Iron Transfer and Accumulation in Rice Grains

Wang

Chen

Hao

et al. 2021

Plants

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Iron (Fe) is one of the most important micronutrients for organisms. Currently, Fe deficiency is a growing nutritional problem and is becoming a serious threat to human health worldwide. A method that could help alleviate this “hidden hunger” is increasing the bioavailable Fe concentrations in edible tissues of major food crops. Therefore, understanding the molecular mechanisms of Fe accumulation in different crop tissues will help to develop crops with higher Fe nutritional values. Biofortification significantly increases the concentration of Fe in crops. This paper considers the important food crop of rice (Oryza sativa L.) as an example and highlights recent research advances on the molecular mechanisms of Fe uptake and allogeneic uptake in different tissues of rice. In addition, different approaches to the biofortification of Fe nutrition in rice and their outcomes are described and discussed. To address the problems that occur during the development and application of improving nutritional Fe in rice, technical strategies and long-term solutions are also proposed as a reference for the future improvement of staple food nutrition with micronutrients.

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Section: Genetic Engineering Technology Improves Fe Capacity In Rice ...mentioning

confidence: 99%

Research and Progress on the Mechanism of Iron Transfer and Accumulation in Rice Grains

Wang

Chen

Hao

et al. 2021

Plants

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“…Disrupting the vacuolar iron transporter OsVIT2 has been shown to increase iron in the rice grain. Therefore there is a potential to knock-down the OsVIT2 gene by Crispr-Cas9 (Che et al, 2021).…”

Section: Increase In Rice Iron Contentmentioning

confidence: 99%

Remodelling of a bacterial immune system as the simple gene editing tool, Crispr-Cas, for food security and human health

Seraj¹,

Hque²

2022

J Bangladesh Acad Sci

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The CRISPR system consists of a guide RNA (gRNA) complementary to a target editable DNA sequence and a CRISPR-associated endonuclease (Cas). The gRNA and Cas together form a ribonucleoprotein (RNP) complex. The gRNA guides the Cas enzyme to the precise site for cutting the target DNA. In bacteria, the gRNA leads the endonuclease to the viral DNA for destruction. This ingenious bacterial immune principle has been used to design gRNA to target an organism’s genome at precise locations for gene editing purposes. Gene edits may include deletion or insertion, repression or activation, base, and epigenome editing, or nucleotide replacement. Therefore the CRISPR-Cas system has created the potential for altering genomes of microbes, plants, and animals. The CRISPR-Cas system has now been developed for use in many applications like finding functions of genes, searching for drug targets, diagnostics, crop improvement, and gene therapy. J. Bangladesh Acad. Sci. 45(2); 131-145: December 2021

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“…Even if plants acquire metal nutrients efficiently from the soil, a major share of them is retained in the vacuoles of root and/or vegetative shoot tissues (Ricachenevsky et al ., 2018). Knocking out transporters that sequester metals in vacuoles has increased micronutrient levels in grains (Huang et al ., 2016; Che et al ., 2019, 2021). However, under some circumstances, this brings about negative effects.…”

Section: How Foods May Be Safely Biofortified – Discrimination Of Nutrients Over Cadmiummentioning

confidence: 99%

“…transporters that sequester metals in vacuoles has increased micronutrient levels in grains (Huang et al, 2016;Che et al, 2019Che et al, , 2021. However, under some circumstances, this brings about negative effects.…”

Section: New Phytologistmentioning

confidence: 99%

A path toward concurrent biofortification and cadmium mitigation in plant‐based foods

Kailasam

Peiter

2021

New Phytologist

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Millions of people are anemic due to inadequate consumption of foods rich in iron and zinc. Plantbased foods provide most of our dietary nutrients but may also contain the toxic heavy metal cadmium (Cd). A low level of Cd silently enters the body through the diet. Once ingested, Cd may remain for decades. Hence, prolonged intake of Cd-containing foods endangers human health.Research that leads towards micronutrient enrichment and mitigation of Cd in foods has therefore dual significance for human health. The breeding of Cd-tolerant cultivars may enable them to grow on Cd-polluted soils; however, they may not yield Cd-free foods. Conversely, sequestration of Cd in roots can prevent its accumulation in grains, but this mechanism also retains nutrients, hence counteracting biofortification efforts. A specific restriction of the Cd absorption capacity of crops would prevent Cd entry into the plant system while maintaining micronutrient accumulation and may thus be a solution of the dilemma. After recapitulating existing strategies employed for the development of Cd-tolerant and biofortified cultivars, this viewpoint elaborates alternative approaches based on directed evolution and genome editing strategies for excluding Cd while enriching Accepted ArticleThis article is protected by copyright. All rights reserved micronutrients in plant foods, which will concurrently help to eradicate malnutrition and prevent Cd intoxication.

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Role of a vacuolar iron transporter OsVIT2 in the distribution of iron to rice grains

Cited by 57 publications

References 56 publications

Research and Progress on the Mechanism of Iron Transfer and Accumulation in Rice Grains

Research and Progress on the Mechanism of Iron Transfer and Accumulation in Rice Grains

Remodelling of a bacterial immune system as the simple gene editing tool, Crispr-Cas, for food security and human health

A path toward concurrent biofortification and cadmium mitigation in plant‐based foods

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