14 research outputs found
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Overexpression of OsIRO2 improves both iron uptake and translocation to seeds in rice
Iron deficiency is a worldwide agricultural problem on calcareous soils with low iron (Fe) availability and also poses a major human nutritional problem. Plants induce Fe-acquisition systems under conditions of low Fe availability. Previously, we reported that an Fe deficiency-inducible bHLH transcription factor, OsIRO2, is responsible for regulating the genes involved in Fe homeostasis in rice. Here, we show that OsIRO2 overexpression results in improved tolerance to low Fe availability in calcareous soil. In addition to increased Fe content in shoots, rice overexpressing OsIRO2 accumulates more Fe in seeds than non-transformant rice when grown on calcareous soil. OsIRO2 promoter–GUS analysis revealed that OsIRO2 expression could be detected in developing seeds. These results suggest that OsIRO2 plays a crucial role in regulating both Fe uptake from soil and Fe translocation to grain. Improved uptake and translocation of Fe in the OsIRO2-overexpressing rice under low Fe availability provides an approach for producing graminaceous crops that are tolerant to Fe deficiency and have Fe-rich seeds to enhance production and the nutritional quality of food
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The novel transcription factor IDEF1 regulates iron-deficiency response and tolerance
Iron is essential for most living organisms and is required for normal plant growth. Plants induce iron utilization systems under conditions of low iron availability, but the molecular mechanisms of this gene regulation system remain largely unknown. We identified the rice transcription factor IDEF1, which specifically binds the iron-deficiency-responsive cis-acting element IDE1. IDEF1 belongs to an uncharacterized branch of the plant-specific transcription factor family ABI3/VP1 and efficiently binds to the CATGC sequence within IDE1. IDEF1 transcripts are constitutively present in rice roots and leaves. Transgenic tobacco plants expressing IDEF1 under the control of the constitutive cauliflower mosaic virus 35S promoter transactivate IDE1-mediated expression only in iron-deficient roots. Transgenic rice plants expressing IDEF1 under the control of the iron-deficiency-inducible IDS2 promoter tolerate iron deficiency in hydroponic culture and calcareous soil. Conversely, transgenic rice plants with repressed IDEF1 expression are susceptible to early stage iron deficiency in hydroponic culture. Expression analysis of these transgenic plants revealed that IDEF1 positively regulates iron-deficiency-induced genes, including the ferrous iron transporter gene OsIRT1 and the iron-deficiency-induced transcription factor gene OsIRO2. These data suggest the presence of a sequential gene regulatory network that functions via novel cis element/trans factor interactions to promote the iron-deficiency response
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The novel transcription factor IDEF1 regulates iron-deficiency response and tolerance
Iron is essential for most living organisms and is required for normal plant growth. Plants induce iron utilization systems under conditions of low iron availability, but the molecular mechanisms of this gene regulation system remain largely unknown. We identified the rice transcription factor IDEF1, which specifically binds the iron-deficiency-responsive cis-acting element IDE1. IDEF1 belongs to an uncharacterized branch of the plant-specific transcription factor family ABI3/VP1 and efficiently binds to the CATGC sequence within IDE1. IDEF1 transcripts are constitutively present in rice roots and leaves. Transgenic tobacco plants expressing IDEF1 under the control of the constitutive cauliflower mosaic virus 35S promoter transactivate IDE1-mediated expression only in iron-deficient roots. Transgenic rice plants expressing IDEF1 under the control of the iron-deficiency-inducible IDS2 promoter tolerate iron deficiency in hydroponic culture and calcareous soil. Conversely, transgenic rice plants with repressed IDEF1 expression are susceptible to early stage iron deficiency in hydroponic culture. Expression analysis of these transgenic plants revealed that IDEF1 positively regulates iron-deficiency-induced genes, including the ferrous iron transporter gene OsIRT1 and the iron-deficiency-induced transcription factor gene OsIRO2. These data suggest the presence of a sequential gene regulatory network that functions via novel cis element/trans factor interactions to promote the iron-deficiency response
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A novel NAC transcription factor, IDEF2, which recognizes the iron deficiency-responsive element 2, regulates genes involved in iron homeostasis
Iron (Fe) is essential for most living organisms, and thus Fe deficiency poses a major abiotic stress in crop production. Plants induce Fe utilization systems under conditions of low-Fe availability, but the molecular mechanisms of gene regulation under Fe deficiency remain largely unknown. We identified a novel transcription factor in rice and barley, IDEF2, which specifically binds to the Fe deficiency-responsive cis-acting element 2 (IDE2), using yeast one-hybrid screening. IDEF2 belongs to an uncharacterized branch of the NAC transcription factor family and exhibits novel properties of sequence recognition. An electrophoretic mobility shift assay and cyclic amplification and selection of targets (CASTing) experiment revealed that IDEF2 predominantly recognizes CA[A/C]G[T/C][T/C/A][T/C/A] within IDE2 as the core binding site. IDEF2 transcripts are constitutively present in rice roots and leaves. Repression of the function of IDEF2 by RNA interference (RNAi) and chimeric repressor gene-silencing technology (CRES-T) caused aberrant Fe distribution between shoots and roots in rice grown hydroponically under Fe-sufficient or deficient conditions. These results reveal novel cis-element/trans-factor interactions that are functionally associated with iron homeostasis