Transposable elements create distinct genomic niches for effector evolution among Magnaporthe oryzae lineages.

IF 4.5 1区生物学 Q1 BIOLOGY

BMC Biology Pub Date : 2025-09-26 DOI:10.1186/s12915-025-02385-7

Ana Margarida Sampaio, Daniel Croll

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引用次数: 0

Abstract

Background: Plant-pathogen interactions are characterized by evolutionary arms races. At the molecular level, fungal effectors can target important plant functions, while plants evolve to improve effector recognition. Rapid evolution in genes encoding effectors can be facilitated by transposable elements (TEs). In Magnaporthe oryzae, the causal agent of blast disease in several cereals and grasses, TEs play important roles in chromosomal evolution as well as the gain or loss of effector genes in host specialized lineages. However, a global understanding of TE dynamics driving effector evolution at population scale and across lineages is lacking.

Results: Here, we focus on 16 AVR effector loci assessed across a global sampling of 11 reference genomes and 447 newly generated draft genome assemblies from publicly available short-read sequencing data across all major M. oryzae lineages and outgroups. We classified each effector based on evidence for duplication, deletion and translocation processes among lineages. Next, we determined AVR gain and loss dynamics across lineages allowing for a broad categorization of effector dynamics. Each AVR was integrated in a distinct genomic niche determined by the TE activity profile contributing to the diversification at the locus. We quantified TE contributions to effector niches and found that TE identity helped diversify AVR loci. We used the large genomic dataset to recapitulate the evolution of the rice blast AVR1-CO39 locus.

Conclusions: Taken together, our work demonstrates how TE dynamics are an integral component of M. oryzae effector evolution, likely facilitating escape from host recognition. In-depth tracking of effector loci is a valuable tool to predict the durability of host resistance.

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转座元件在水稻大孔菌谱系中为效应进化创造了独特的基因组生态位。

背景：植物与病原体的相互作用以进化军备竞赛为特征。在分子水平上，真菌效应物可以靶向植物的重要功能，而植物也在进化以提高对效应物的识别。转座因子（te）可以促进编码效应子基因的快速进化。在稻瘟病病原稻瘟菌（Magnaporthe oryzae）中，TEs在寄主特化谱系的染色体进化和效应基因的获得或丧失中起着重要作用。然而，在种群规模和跨谱系的TE动力学驱动效应进化的全球理解是缺乏的。结果：在这里，我们重点评估了16个AVR效应位点，这些位点来自11个参考基因组的全球样本和447个新生成的草图基因组组装，这些基因组组装来自所有主要m.o ryzae谱系和外群体的公开短读测序数据。我们根据谱系中重复、删除和易位过程的证据对每个效应进行分类。接下来，我们确定了跨谱系的AVR增益和损失动态，允许对效应器动力学进行广泛的分类。每个AVR被整合到一个独特的基因组生态位中，这是由TE活性谱决定的，有助于基因座的多样化。我们量化了TE对效应位的贡献，发现TE的身份有助于AVR位点的多样化。我们利用大型基因组数据对稻瘟病基因AVR1-CO39位点的进化进行了概括。综上所述，我们的工作证明了TE动力学是m.o ryzae效应物进化的一个组成部分，可能有助于逃避宿主识别。深入跟踪效应位点是预测寄主抗性持久性的重要工具。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

BMC Biology 生物-生物学

CiteScore

7.80

自引率

1.90%

发文量

260

审稿时长

3 months

期刊介绍： BMC Biology is a broad scope journal covering all areas of biology. Our content includes research articles, new methods and tools. BMC Biology also publishes reviews, Q&A, and commentaries.