在根中更大的形态和初级代谢适应有助于提高小麦品种垦农 199 的耐低磷能力。

Greater morphological and primary metabolic adaptations in roots contribute to phosphate-deficiency tolerance in the bread wheat cultivar Kenong199.

机构信息

State Key Laboratory of Soil and Sustainable Agriculture, Institute of Soil Science, Chinese Academy of Sciences, Nanjing, 210008, China.

University of Chinese Academy of Sciences, Beijing, 100049, China.

出版信息

BMC Plant Biol. 2021 Aug 19;21(1):381. doi: 10.1186/s12870-021-03164-6.

DOI:10.1186/s12870-021-03164-6

PMID:34412589

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8375062/

Abstract

BACKGROUND

Phosphate (Pi) deficiency severely affects crop growth and productivity, including wheat, therefore it is necessary to develop cultivars with enhanced Pi-deficiency tolerance. However, the underlying mechanism of Pi-deficiency tolerance in wheat is still elusive. Two contrasting wheat cultivars, low-Pi tolerant Kenong199 (KN199) and low-Pi sensitive Chinese Spring (CS) were used to reveal adaptations in response to Pi deficiency at the morphological, physiological, metabolic, and molecular levels.

RESULTS

KN199 was more tolerant to Pi deficiency than CS with significantly increased root biomass and R/S ratio. Root traits, the total root length, total root surface area, and total root volume, were remarkably enhanced by Pi deficiency in KN199. The shoot total P and soluble Pi concentrations of KN199 were significantly higher than those of CS, but not in roots. In KN199, high Pi level in shoots is a higher priority than that in roots under Pi deficiency. It was probably due to differentially regulation in the miR399-mediated signaling network between the shoots of the two cultivars. The Pi deficiency-induced root architecture adaptation in KN199 was attributed to the regulation of the hormone-mediated signaling (ethylene, gibberellin, and jasmonates). The expression of genes associated with root development and Pi uptake was enhanced in KN199. Some primary metabolites (amino acids and organic acids) were significantly accumulated in roots of KN199 under Pi deficiency.

CONCLUSIONS

The low-Pi tolerant wheat cultivar KN199 possessed greater morphological and primary metabolic adaptations in roots than CS under Pi deficiency. The adaption and the underlying molecular mechanisms in wheat provide a better understanding of the Pi-deficiency tolerance and the strategies for improving Pi efficiency in wheat.

摘要

背景

磷酸盐（Pi）缺乏严重影响作物生长和生产力，包括小麦，因此有必要开发具有增强的 Pi 缺乏耐受性的品种。然而，小麦对 Pi 缺乏耐受性的潜在机制仍不清楚。本研究使用两种具有对比性的小麦品种，低 Pi 耐受 Kenong199（KN199）和低 Pi 敏感 Chinese Spring（CS），以揭示它们在形态、生理、代谢和分子水平上对 Pi 缺乏的适应机制。

结果

与 CS 相比，KN199 对 Pi 缺乏更具耐受性，根生物量和根冠比显著增加。在 KN199 中，Pi 缺乏显著增加了根总长度、总根表面积和总根体积等根性状。KN199 的地上部总 P 和可溶性 Pi 浓度显著高于 CS，但根部则不然。在 Pi 缺乏条件下，KN199 地上部对 Pi 的需求优先于根部。这可能是由于两个品种的 miR399 介导的信号网络的差异调控所致。KN199 在 Pi 缺乏条件下诱导的根构型适应归因于激素介导的信号（乙烯、赤霉素和茉莉酸）的调节。与根发育和 Pi 吸收相关的基因在 KN199 中表达增强。一些初级代谢物（氨基酸和有机酸）在 KN199 的根中在 Pi 缺乏条件下显著积累。

结论

与 CS 相比，低 Pi 耐受小麦品种 KN199 在 Pi 缺乏条件下具有更大的形态和初级代谢适应能力。小麦的适应及其潜在的分子机制为更好地理解 Pi 缺乏耐受性和提高小麦 Pi 效率的策略提供了依据。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/89c2/8375062/650c5764d381/12870_2021_3164_Fig1_HTML.jpg

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在根中更大的形态和初级代谢适应有助于提高小麦品种垦农 199 的耐低磷能力。

Greater morphological and primary metabolic adaptations in roots contribute to phosphate-deficiency tolerance in the bread wheat cultivar Kenong199.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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