BdNRT2A and BdNRT3.2 Are the Major Components of the High-Affinity Nitrate Transport System in Brachypodium distachyon.

IF 2.3 3区生物学 Q2 PLANT SCIENCES

Plant Direct Pub Date : 2025-06-10 eCollection Date: 2025-06-01 DOI:10.1002/pld3.70075

Laure C David, Mathilde Grégoire, Patrick Berquin, Anne Marmagne, Marion Dalmais, Abdelhafid Bendahmane, Tony J Miller, Anne Krapp, Françoise Daniel-Vedele, Thomas Girin, Sylvie Ferrario-Méry

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引用次数: 0

Abstract

An efficient nitrate uptake system contributes to the improvement of crop nitrogen use efficiency under low nitrogen availability. The High Affinity nitrate Transport System (HATS) in plants is active in low range of external nitrate and is mediated by a two-component system (high affinity transporters NRT2 associated to a partner protein NRT3 (NAR2)). In Brachypodium, the model plant for C3 cereals, we investigated the role of BdNRT2A and BdNRT3.2 through various experimental approaches. Expression profile of BdNRT2.A and BdNRT3.2 genes in response to nitrate availability fits perfectly with the characteristics of the HATS components. ¹⁵Nitrate influx measurements decreased in bdnrt2a mutants (one NaN₃ induced mutant with a truncated NRT2A protein and two amiRNA mutants). In addition, the N limited phenotype of the mutant with a truncated NRT2A protein confirmed that BdNRT2A is a major contributor of the HATS in Brachypodium. An effective nitrate transport in the heterologous expression system Xenopus oocytes required the coexpression of BdNRT2A and BdNRT3.2 that characterizes two-component system of the HATS. Functional interaction between BdNRT2A-GFP and BdNRT3.2-RFP fusion proteins was observed at the plasma membrane in Arabidopsis protoplasts in transient expression experiments with BdNRT3.2 being necessary for the plasma membrane localization of BdNRT2A. The role of a conserved Ser residue in BdNRT2A (S461) specific to monocotyledons was evaluated in the BdNRT2A and BdNRT3.2 interaction leading to plasma membrane targeting. Assuming that S461 could be regulated by phosphorylation, a directed mutagenesis was performed to mimic a nonphosphorylated (S461A) or a constitutively phosphorylated (S461D), However, the mimicking the phosphorylation status of S461 by mutagenesis did not modify the BdNRT2A and BdNRT3.2 interaction, suggesting a more complex regulating mechanism. In conclusion, our data show that BdNRT2A and BdNRT3.2 are the main components of the nitrate HATS activity in Brachypodium (Bd21-3) and allow an optimal growth in low N conditions.

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BdNRT2A和BdNRT3.2是短柄茅高亲和硝酸盐转运系统的主要组成部分。

高效的硝态氮吸收系统有助于在低氮有效度条件下提高作物氮素利用效率。植物高亲和硝酸盐运输系统（HATS）在低范围的外部硝酸盐中活跃，由一个双组分系统（高亲和转运体NRT2与伴侣蛋白NRT3 （NAR2）相关）介导。以C3谷物的模式植物短柄藓为研究对象，通过多种实验方法研究了BdNRT2A和BdNRT3.2的作用。BdNRT2的表达谱。A和BdNRT3.2基因对硝酸盐有效性的响应完全符合HATS组分的特征。15在bdnrt2a突变体（一个NaN3诱导的NRT2A蛋白截断突变体和两个amiRNA突变体）中，硝酸盐内流测量值下降。此外，截断NRT2A蛋白的突变体的N限制表型证实了BdNRT2A是短柄植物HATS的主要贡献者。异种表达系统中硝酸盐的有效转运需要具有双组分系统特征的BdNRT2A和BdNRT3.2的共同表达。BdNRT2A- gfp和BdNRT3.2- rfp融合蛋白在拟南芥原生质体质膜上的瞬时表达实验中观察到功能相互作用，BdNRT3.2是BdNRT2A质膜定位所必需的。在BdNRT2A和BdNRT3.2相互作用导致质膜靶向的过程中，对单子叶植物特异性BdNRT2A （S461）中一个保守的Ser残基的作用进行了评估。假设S461可以通过磷酸化调控，我们进行了定向诱变来模拟非磷酸化（S461A）或组成性磷酸化（S461D），然而，通过诱变模拟S461的磷酸化状态并没有改变BdNRT2A和BdNRT3.2的相互作用，这表明调控机制更为复杂。综上所述，BdNRT2A和BdNRT3.2是短柄茅（Bd21-3）硝酸盐HATS活性的主要组成部分，在低氮条件下生长最佳。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Plant Direct Environmental Science-Ecology

CiteScore

5.00

自引率

3.30%

发文量

101

审稿时长

14 weeks

期刊介绍： Plant Direct is a monthly, sound science journal for the plant sciences that gives prompt and equal consideration to papers reporting work dealing with a variety of subjects. Topics include but are not limited to genetics, biochemistry, development, cell biology, biotic stress, abiotic stress, genomics, phenomics, bioinformatics, physiology, molecular biology, and evolution. A collaborative journal launched by the American Society of Plant Biologists, the Society for Experimental Biology and Wiley, Plant Direct publishes papers submitted directly to the journal as well as those referred from a select group of the societies’ journals.