Graduate School of Agricultural and Life Sciences, The University of Tokyo, Bunkyo-ku, Tokyo, Japan.
Plant Mol Biol. 2011 Apr;75(6):593-605. doi: 10.1007/s11103-011-9752-6. Epub 2011 Feb 18.
Iron (Fe) deficiency, a worldwide agricultural problem on calcareous soil with low Fe availability, is also a major human nutritional deficit. Plants induce Fe acquisition systems under conditions of low Fe availability. Previously, we reported that an Fe-deficiency-inducible basic helix-loop-helix (bHLH) transcription factor, OsIRO2, is responsible for regulation of the genes involved in Fe homeostasis in rice. Using promoter-GUS transformants, we showed that OsIRO2 is expressed throughout a plant's lifetime in a spatially and temporally similar manner to the genes OsNAS1, OsNAS2 and TOM1, which is involved in Fe absorption and translocation. During germination, OsIRO2 expression was detected in embryos. OsIRO2 expression in vegetative tissues was restricted almost exclusively to vascular bundles of roots and leaves, and to the root exodermis under Fe-sufficient conditions, and expanded to all tissues of roots and leaves in response to Fe deficiency. OsIRO2 expression was also detected in flowers and developing seeds. Plants overexpressing OsIRO2 grew better, and OsIRO2-repressed plants showed poor growth compared to non-transformant rice after germination. OsIRO2 overexpression also resulted in improved tolerance to low Fe availability in calcareous soil. In addition to increased Fe content in shoots, the overexpression plants accumulated higher amounts of Fe in seeds than non-transformants when grown on calcareous soil. These results suggest that OsIRO2 is synchronously expressed with genes involved in Fe homeostasis, and performs a crucial function in regulation not only of Fe uptake from soil but also Fe transport during germination and Fe translocation to grain during seed maturation.
缺铁(Fe)是在石灰性土壤上存在的一个全球性农业问题,该土壤中 Fe 的可利用性较低,也是人类营养缺乏的主要原因之一。植物在 Fe 供应不足的条件下会诱导 Fe 吸收系统。此前,我们曾报道过,一种缺铁诱导的碱性螺旋-环-螺旋(bHLH)转录因子 OsIRO2 负责调控水稻中与 Fe 稳态相关的基因。利用启动子-GUS 转化体,我们发现 OsIRO2 在植物的整个生命周期中以与 OsNAS1、OsNAS2 和 TOM1 基因相似的时空模式表达,这些基因参与 Fe 的吸收和转运。在萌发过程中,胚胎中检测到 OsIRO2 的表达。OsIRO2 在营养组织中的表达几乎完全局限于根和叶的维管束,以及在 Fe 充足条件下的根外表皮,而在响应 Fe 缺乏时则扩展到根和叶的所有组织中。OsIRO2 的表达也在花和发育中的种子中被检测到。过表达 OsIRO2 的植物生长得更好,而与非转化水稻相比,OsIRO2 抑制的植物在萌发后生长不良。OsIRO2 的过表达还导致对石灰性土壤中低 Fe 可用性的耐受性提高。除了地上部分 Fe 含量增加外,与非转化植株相比,过表达植株在石灰性土壤上生长时在种子中积累了更多的 Fe。这些结果表明,OsIRO2 与参与 Fe 稳态的基因同步表达,并在不仅调节从土壤中摄取 Fe,而且在萌发期间的 Fe 转运以及种子成熟期间向谷物的 Fe 转运方面发挥关键作用。
