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小麦磷酸盐转运蛋白基因 TaPHT2;1 在充分和有限磷供应条件下对磷的转运和植物生长的调节功能。

Function of wheat phosphate transporter gene TaPHT2;1 in Pi translocation and plant growth regulation under replete and limited Pi supply conditions.

机构信息

College of Agronomy, Agricultural University of Hebei, Baoding, 071001, China.

出版信息

Planta. 2013 Apr;237(4):1163-78. doi: 10.1007/s00425-012-1836-2. Epub 2013 Jan 12.

DOI:10.1007/s00425-012-1836-2
PMID:23314830
Abstract

Several phosphate transporters (PTs) that belong to the Pht2 family have been released in bioinformatics databases, but only a few members of this family have been functionally characterized. In this study, we found that wheat TaPHT2;1 shared high identity with a subset of Pht2 in diverse plants. Expression analysis revealed that TaPHT2;1 was strongly expressed in the leaves, was up-regulated by low Pi stress, and exhibited a circadian rhythmic expression pattern. TaPHT2;1-green fluorescent protein fusions in the leaves of tobacco and wheat were specifically detected in the chloroplast envelop. TaPHT2;1 complemented the Pi transporter activities in a yeast mutant with a defect in Pi uptake. Knockdown expression of TaPHT2;1 significantly reduced Pi concentration in the chloroplast under sufficient (2 mM Pi) and deficient Pi (100 μM Pi) conditions, suggesting that TaPHT2;1 is crucial in the mediation of Pi translocation from the cytosol to the chloroplast. The down-regulated expression of TaPHT2;1 resulted in reduced photosynthetic capacities, total P contents, and accumulated P amounts in plants under sufficient and deficient Pi conditions, eventually leading to worse plant growth phenotypes. The TaPHT2;1 knockdown plants exhibited pronounced decrease in accumulated phosphorus in sufficient and deficient Pi conditions, suggesting that TaPHT2;1 is an important factor to associate with a distinct P signaling that up-regulates other PT members to control Pi acquisition and translocation within plants. Therefore, TaPHT2;1 is a key member of the Pht2 family involved in Pi translocation, and that it can function in the improvement of phosphorus usage efficiency in wheat.

摘要

几种属于 Pht2 家族的磷酸盐转运蛋白(PTs)已在生物信息学数据库中发布,但该家族的少数成员已被功能表征。在这项研究中,我们发现小麦 TaPHT2;1 与多种植物中的一组 Pht2 具有高度的同源性。表达分析表明,TaPHT2;1 在叶片中强烈表达,受低磷胁迫上调,并表现出昼夜节律表达模式。TaPHT2;1-绿色荧光蛋白融合在烟草和小麦叶片中的特异性检测到在叶绿体包膜中。TaPHT2;1 在酵母突变体中补充了 Pi 转运体活性,该突变体在 Pi 摄取方面存在缺陷。TaPHT2;1 的敲低表达显着降低了在充足(2 mM Pi)和缺乏 Pi(100 μM Pi)条件下叶绿体中的 Pi 浓度,表明 TaPHT2;1 在介导 Pi 从细胞质转运到叶绿体中至关重要。在充足和缺乏 Pi 条件下,TaPHT2;1 的下调表达导致植物的光合能力、总磷含量和积累量降低,最终导致植物生长表型恶化。在充足和缺乏 Pi 条件下,TaPHT2;1 敲低植物的磷积累量明显减少,表明 TaPHT2;1 是与特定 P 信号相关的重要因素,该信号上调其他 PT 成员以控制植物内 Pi 的获取和转运。因此,TaPHT2;1 是参与 Pi 转运的 Pht2 家族的关键成员,它可以在提高小麦磷利用效率方面发挥作用。

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