水稻根中的腐霉物种在毒力、宿主定殖和营养谱方面存在差异。

Pythium species from rice roots differ in virulence, host colonization and nutritional profile.

机构信息

Laboratory of Phytopathology, Department of Crop Protection, Faculty of Bioscience Engineering, Ghent University, Coupure Links 653, B-9000 Ghent, Belgium.

出版信息

BMC Plant Biol. 2013 Dec 5;13:203. doi: 10.1186/1471-2229-13-203.

DOI:10.1186/1471-2229-13-203

PMID:24314036

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3878986/

Abstract

BACKGROUND

Progressive yield decline in Philippine aerobic rice fields has been recently associated with three closely related Pythium spp., P. arrhenomanes, P. graminicola and P. inflatum. To understand their differential virulence towards rice seedlings, we conducted a comparative survey in which three isolates each of P. arrhenomanes, P. graminicola and P. inflatum were selected to investigate host colonization, host responses and carbon utilization profiles using histopathological analyses, phenoarrays, DNA quantifications and gene expression studies.

RESULTS

The isolate of the most virulent species, P. arrhenomanes, quickly colonized the outer and inner root tissues of rice seedlings, including the xylem, by which it possibly blocked the water transport and induced severe stunting, wilting and seedling death. The lower virulence of the tested P. graminicola and P. inflatum isolates seemed to be reflected in slower colonization processes, limited invasion of the vascular stele and less systemic spread, in which cell wall fortification appeared to play a role. Progressive hyphal invasions triggered the production of reactive oxygen species (ROS) and phenolic compounds, which was the strongest for the P. arrhenomanes isolate and was delayed or much weaker upon inoculation with the P. inflatum isolate. The necrosis marker OsJamyb seemed faster and stronger induced by the most virulent isolates. Although the isolate of P. inflatum was nutritionally the most versatile, the most virulent Pythium isolate appeared physiologically more adapted to its host, evidenced by its broad amino acid utilization profile, including D-amino acids, L-threonine and hydroxyl-L-proline. The latter two compounds have been implicated in plant defense and their use by P. arrhenomanes could therefore represent a part of its virulence strategy.

CONCLUSIONS

This study illustrates that the differential virulence of rice-pathogenic P. arrhenomanes, P. graminicola and P. inflatum isolates is related to their root colonization capacity, the intensity of induced root responses and their ability to utilize amino acids in their colonization niche. Accordingly, this paper presents important knowledge concerning rice root infections by oomycetes, which could be helpful to further disentangle virulence tactics of soil-borne pathogens.

摘要

背景

菲律宾有氧稻田的生产力逐渐下降，最近与三种密切相关的节旋体属真菌（Pythium arrhenomanes、P. graminicola 和 P. inflatum）有关。为了了解它们对水稻幼苗的不同致病力，我们进行了一项比较调查，选择了每种 P. arrhenomanes、P. graminicola 和 P. inflatum 的三个分离株，以通过组织病理学分析、表型阵列、DNA 定量和基因表达研究来研究宿主定殖、宿主反应和碳利用谱。

结果

最具毒力的物种 P. arrhenomanes 的分离株迅速定殖于水稻幼苗的外根和内根组织，包括木质部，这可能阻止了水的运输并导致严重的矮化、萎蔫和幼苗死亡。测试的 P. graminicola 和 P. inflatum 分离株的较低毒力似乎反映在较慢的定殖过程中，维管束茎的入侵有限，系统传播较少，细胞壁加固似乎起作用。渐进性菌丝入侵引发活性氧 (ROS) 和酚类化合物的产生，P. arrhenomanes 分离株的产生最强，而接种 P. inflatum 分离株时则延迟或较弱。坏死标记物 OsJamyb 似乎更快更强地被最具毒力的分离株诱导。尽管 P. inflatum 分离株在营养上最具多功能性，但最具毒力的节旋体分离株在生理上似乎更适应其宿主，这表现在其广泛的氨基酸利用谱上，包括 D-氨基酸、L-苏氨酸和羟基-L-脯氨酸。后两种化合物与植物防御有关，因此 P. arrhenomanes 的利用可能代表其毒力策略的一部分。

结论

本研究表明，水稻病原性 P. arrhenomanes、P. graminicola 和 P. inflatum 分离株的差异致病力与其根定殖能力、诱导根反应的强度以及在定殖位利用氨基酸的能力有关。因此，本文提供了有关卵菌引起水稻根感染的重要知识，这有助于进一步阐明土壤传播病原体的毒力策略。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3302/3878986/62fb5aad93f2/1471-2229-13-203-1.jpg

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水稻根中的腐霉物种在毒力、宿主定殖和营养谱方面存在差异。

Pythium species from rice roots differ in virulence, host colonization and nutritional profile.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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