Abstract
Biofortification (increasing the contents of vitamins and minerals through plant breeding or biotechnology) of food crops with micronutrient elements has the potential to combat widespread micronutrient deficiencies in humans. Rice (Oryza sativa L.) feeds more than half of the world’s population and is used as a staple food in many parts of Asia. As in other plants, micronutrient transport in rice is controlled at several stages, including uptake from soil, transport from root to shoot, careful control of subcellular micronutrient transport, and finally, and most importantly, transport to seeds. To enhance micronutrient accumulation in rice seeds, we need to understand and carefully regulate all of these processes. During the last decade, numerous attempts such as increasing the contents/expression of genes encoding metal chelators (mostly phytosiderophores) and metal transporters; Fe storage protein ferritin and phytase were successfully undertaken to significantly increase the micronutrient content of rice. However, despite the rapid progress in biofortification of rice, the commercialization of biofortified crops has not yet been achieved. Here, we briefly review the progress in biofortification of rice with micronutrient elements (Fe, Zn, and Mn) and discuss future prospects to mitigate widespread micronutrient deficiencies in humans.
Highlights
Micronutrients are essential for plant growth and development but are integral to human and animal health
The micronutrients iron (Fe), zinc (Zn), and manganese (Mn) are of particular interest, given that all three are essential micronutrients for all higher organisms and we will focus on these three micronutrients in this review
The overexpression of transporter of mugineic acid 1 (TOM1) slightly increased seed Fe, Zn, and Cu concentrations (Nozoye et al, 2011), and the overexpression of barley iron deficiency-specific clone 3 (IDS3), whose product converts DMA to mugineic acid family phytosiderophores (MAs) and 3-epihydroxy2 -deoxymugineic acid to 3-epihydroxymugineic acid (Nakanishi et al, 2000), increased Fe accumulation in rice grains (Masuda et al, 2008). These results suggest that an increase in NA and/or DMA/MA synthesis could increase Fe and Zn translocation to rice grains and that the increase in Fe is positively correlated with the accumulation of NA or DMA (Johnson et al, 2011; Masuda et al, 2012)
Summary
Micronutrients are essential for plant growth and development but are integral to human and animal health. BIOFORTIFICATION THROUGH INCREASING THE AMOUNT OF METAL CHELATORS Graminaceous plants, which include rice, have sophisticated mechanisms for acquiring micronutrients from soil and transporting them from roots to shoots and grains by secreting small molecules called mugineic acid family phytosiderophores (MAs).
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