Urea transporter DUR3 gene in grasses: In silico characterization and relative expression in Megathyrsus maximus under different nitrogen sources

IF 2.2 Q3 GENETICS & HEREDITY
Juliana de Carvalho Ferreira , Lorrayne Guimarães Bavaresco , Mayara de Oliveira Vidotto Figueiredo , Tiago Benedito dos Santos , Alessandra Ferreira Ribas
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引用次数: 0

Abstract

Nitrogen (N) is an indispensable macronutrient for crop growth and yield. The N can be acquired and assimilated from a variety of sources such as nitrate (NO3), ammonium (NH4+), and urea [CO(NH2)2]. Due to its low cost, urea is a popular N source in pastures. The urea transporter DUR3 gene, which can mediate direct urea uptake by roots, has received little attention in grasses. The purpose of the current study was to identify and characterize in silico the DUR3 gene in 29 grass species in comparison to Arabidopsis thaliana. Physicochemical properties, gene structure, motifs, and phylogenetic tree relationships were predicted. Furthermore, the relative expression patterns of the DUR3 gene were evaluated in two commercial cultivars (Mombaça and Aruana) of Megathyrsus maximus. Plants were grown in a nutritive solution containing 2 mM of N supplied as NO3, NH4+, or [CO(NH2)2]. To investigate the relative expression of the DUR3 gene in leaves and roots we used the 2-ΔΔCt method. The in silico characterization revealed that the DUR3 gene is highly conserved among grasses. Plants were submitted to 3 days of N starvation and the tissue was harvested 3 h after transfer to ammonium or urea solution. In general, the DUR3 gene was down-regulated in leaves and up-regulated in roots for both cultivars. Twenty-four hours after transfer, only the Mombaça cultivar showed a significant decrease of DUR3 mRNA levels in leaves and an increase in roots under urea, demonstrating that the DUR3 gene expression pattern is variable between cultivars of M. maximus. Characterizing of the DUR3 gene in grasses is the first step toward biotechnological approaches aiming to improve urea uptake in pastures.

禾本科植物中的尿素转运体 DUR3 基因:不同氮源条件下禾本科牧草中尿素转运体 DUR3 基因的硅学表征和相对表达
氮(N)是作物生长和产量不可或缺的主要营养元素。氮可以从硝酸盐(NO3-)、铵(NH4+)和尿素[CO(NH2)2]等多种来源获得和同化。由于成本低廉,尿素是牧场中常用的氮源。尿素转运体 DUR3 基因可介导根系直接吸收尿素,但在禾本科植物中却很少受到关注。本研究的目的是对 29 种禾本科植物的 DUR3 基因进行识别和特征描述,并与拟南芥进行比较。研究人员预测了 DUR3 基因的理化性质、基因结构、结构式和系统发生树关系。此外,还评估了 DUR3 基因在 Megathyrsus maximus 的两个商业栽培品种(Mombaça 和 Aruana)中的相对表达模式。植物在营养液中生长,营养液中含有以 NO3-、NH4+ 或 [CO(NH2)2] 形式提供的 2 mM N。为了研究 DUR3 基因在叶片和根部的相对表达量,我们使用了 2-ΔΔCt 方法。硅学特性分析表明,DUR3 基因在禾本科植物中高度保守。将植物置于氮饥饿状态 3 天,并在转入铵溶液或尿素溶液 3 小时后收获组织。一般来说,两个栽培品种的 DUR3 基因在叶片中下调,而在根中上调。转移 24 小时后,只有 Mombaça 栽培品种在尿素条件下叶片中的 DUR3 mRNA 水平显著下降,而根中的 DUR3 mRNA 水平显著上升,这表明 DUR3 基因的表达模式在 M. maximus 不同栽培品种之间存在差异。鉴定牧草中 DUR3 基因的特征是采用生物技术方法提高牧草吸收尿素能力的第一步。
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来源期刊
Plant Gene
Plant Gene Agricultural and Biological Sciences-Plant Science
CiteScore
4.50
自引率
0.00%
发文量
42
审稿时长
51 days
期刊介绍: Plant Gene publishes papers that focus on the regulation, expression, function and evolution of genes in plants, algae and other photosynthesizing organisms (e.g., cyanobacteria), and plant-associated microorganisms. Plant Gene strives to be a diverse plant journal and topics in multiple fields will be considered for publication. Although not limited to the following, some general topics include: Gene discovery and characterization, Gene regulation in response to environmental stress (e.g., salinity, drought, etc.), Genetic effects of transposable elements, Genetic control of secondary metabolic pathways and metabolic enzymes. Herbal Medicine - regulation and medicinal properties of plant products, Plant hormonal signaling, Plant evolutionary genetics, molecular evolution, population genetics, and phylogenetics, Profiling of plant gene expression and genetic variation, Plant-microbe interactions (e.g., influence of endophytes on gene expression; horizontal gene transfer studies; etc.), Agricultural genetics - biotechnology and crop improvement.
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