Ammonium transporter genes in millets: insights into structure, function, evolutionary conservation, divergence, and phylogenetic analysis

IF 1.6 3区农林科学 Q2 AGRONOMY

Genetic Resources and Crop Evolution Pub Date : 2024-08-26 DOI:10.1007/s10722-024-02092-2

Tanushree Sarkar, Suman Bakshi

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Abstract

Millets, resilient and nutritionally rich crops, are increasingly recognized for their potential in sustainable agriculture. Ammonium transporter (AMTs) gene family significantly contribute to the absorption and transport of NH₄⁺ form of nitrogen in plants. The information about the structure and function of ammonium transporter genes in millet species is lacking. The millet crops such as pearl millet, proso millet, finger millet, sorghum, foxtail millet and green foxtail millet exhibit genetic variation in AMTs, which can be harnessed to improve NUE. Thus, genomic sequences of the six millet species were used and a total of 53 AMT genes were identified. Further, comprehensive analysis of chromosomal distribution, transmembrane structure prediction, presence of exons and introns, domain and motif organization, phylogeny, and synteny analysis were carried out. The phylogenetic analysis illustrated that millet AMTs belong to two subfamilies AMT1 and AMT2 (AMT2/AMT3/AMT4). Ka/Ks analysis showed that segmental duplications have contributed considerably in the evolution of millet AMTs. Phylogenetic classification of members of Poaceae using the amino acid sequences of AMT1.1 genes confirms the speciation patterns shown by matK gene sequence. Promoter analysis of millet AMTs showed presence of cis-elements related to light response, anaerobic induction, growth hormones, drought stress, biotic stress and several endogenous signals related to plant growth and development. This research provides insights into the structural and functional aspects of ammonium transporter genes in millets, and will serve as a foundation for utilizing AMTs for devising NUE strategies.

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黍铵转运体基因：对结构、功能、进化保护、分化和系统发育分析的见解

黍是一种生命力顽强、营养丰富的作物，其在可持续农业中的潜力日益得到认可。铵转运体（AMTs）基因家族对植物吸收和转运 NH4+ 形式的氮做出了重要贡献。有关粟类铵转运体基因的结构和功能的信息还很缺乏。珍珠粟、稗、指粟、高粱、狐尾粟和绿狐尾粟等粟作物的氨转运体基因表现出遗传变异，可以利用这些变异改善氮利用效率。因此，我们使用了这六种小米的基因组序列，共鉴定出 53 个 AMT 基因。此外，还对AMT基因的染色体分布、跨膜结构预测、外显子和内含子的存在、结构域和基序组织、系统发育和同源关系分析进行了综合分析。系统进化分析表明，小米 AMTs 属于 AMT1 和 AMT2（AMT2/AMT3/AMT4）两个亚家族。Ka/Ks分析表明，节段重复在小米AMTs的进化过程中起到了重要作用。利用 AMT1.1 基因的氨基酸序列对 Poaceae 植物进行系统发育分类，证实了 matK 基因序列所显示的物种分化模式。对小米 AMTs 的启动子分析表明，存在与光反应、厌氧诱导、生长激素、干旱胁迫、生物胁迫以及与植物生长发育有关的几种内源信号相关的顺式元件。这项研究有助于深入了解黍铵转运体基因的结构和功能，并为利用黍铵转运体设计氮利用效率战略奠定基础。

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来源期刊

Genetic Resources and Crop Evolution 农林科学-农艺学

CiteScore

4.10

自引率

10.00%

发文量

178

审稿时长

3 months

期刊介绍： Genetic Resources and Crop Evolution is devoted to all aspects of plant genetic resources research. It publishes original articles in the fields of taxonomical, morphological, physiological, biochemical, genetical, cytological or ethnobotanical research of genetic resources and includes contributions to gene-bank management in a broad sense, that means to collecting, maintenance, evaluation, storage and documentation. Areas of particular interest include: -crop evolution -domestication -crop-weed relationships -related wild species -history of cultivated plants including palaeoethnobotany. Genetic Resources and Crop Evolution also publishes short communications, e.g. newly described crop taxa, nomenclatural notes, reports of collecting missions, evaluation results of gene-bank material etc. as well as book reviews of important publications in the field of genetic resources. Every volume will contain some review articles on actual problems. The journal is the internationalized continuation of the German periodical Die Kulturpflanze, published formerly by the Institute of Plant Genetics and Crop Plant Research at Gatersleben, Germany. All contributions are in the English language and are subject to peer reviewing.