比较转录组分析揭示了抗性基因型G.935在没有病原体的情况下在苹果根部形成了预先防御系统。

International journal of plant genomics Pub Date : 2017-01-01 Epub Date: 2017-03-30 DOI:10.1155/2017/8950746
Yanmin Zhu, Jonathan Shao, Zhe Zhou, Robert E Davis
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引用次数: 18

摘要

两种苹果砧木基因型G.935和B.9最近被证明在受最后草霉感染后表现出明显的抗性反应。为了阐明苹果根系对土传病原体抗性的遗传调控,假设这两种苹果砧木基因型的根接种前转录组变异有助于观察到的抗病表型。目前比较转录组分析的结果表明,抗性基因型G.935的根组织中许多在全系统防御反应中起作用的基因的转录丰度高于易感基因型B.9。根据功能注释,这些差异表达的基因编码的蛋白质在多层防御反应中起作用,如用于病原体检测和随后的信号转导的模式识别受体、防御激素的生物合成和信号传导、在防御激活中起已知作用的转录因子、次生代谢酶和各种类型的抗性蛋白。数据表明,抗性基因型G.935的根组织比易感基因型B.9的根组织处于更稳定的状态,可以防御病原体感染。讨论了在无病原菌条件下预先防御对苹果根系整体抗性表型的意义,以及防御系统过度激活所带来的潜在适应度代价。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Comparative Transcriptome Analysis Reveals a Preformed Defense System in Apple Root of a Resistant Genotype of G.935 in the Absence of Pathogen.

Comparative Transcriptome Analysis Reveals a Preformed Defense System in Apple Root of a Resistant Genotype of G.935 in the Absence of Pathogen.

Comparative Transcriptome Analysis Reveals a Preformed Defense System in Apple Root of a Resistant Genotype of G.935 in the Absence of Pathogen.

Comparative Transcriptome Analysis Reveals a Preformed Defense System in Apple Root of a Resistant Genotype of G.935 in the Absence of Pathogen.

Two apple rootstock genotypes G.935 and B.9 were recently demonstrated to exhibit distinct resistance responses following infection by Pythium ultimum. As part of an effort to elucidate the genetic regulation of apple root resistance to soilborne pathogens, preinoculation transcriptome variations in roots of these two apple rootstock genotypes are hypothesized to contribute to the observed disease resistance phenotypes. Results from current comparative transcriptome analysis demonstrated elevated transcript abundance for many genes which function in a system-wide defense response in the root tissue of the resistant genotype of G.935 in comparison with susceptible B.9. Based on the functional annotation, these differentially expressed genes encode proteins that function in several tiers of defense responses, such as pattern recognition receptors for pathogen detection and subsequent signal transduction, defense hormone biosynthesis and signaling, transcription factors with known roles in defense activation, enzymes of secondary metabolism, and various classes of resistance proteins. The data set suggested a more poised status, which is ready to defend pathogen infection, in the root tissues of resistant genotype of G.935, compared to the susceptible B.9. The significance of preformed defense in the absence of a pathogen toward overall resistance phenotypes in apple root and the potential fitness cost due to the overactivated defense system were discussed.

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