Can higher aggressiveness effectively compensate for a virulence deficiency in plant pathogen? A case study of Puccinia triticina’s fitness evolution in a diversified varietal landscape

IF 2.2 4区 农林科学 Q2 PLANT SCIENCES
Cécilia Fontyn, Kevin JG Meyer, Anne-Lise Boixel, Corentin Picard, Adrien Destanque, Thierry C Marcel, Frédéric Suffert, Henriette Goyeau
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Abstract

Plant resistances impose strong selective pressure on plant pathogen populations through the deployment of resistance genes, which leads to the emergence of new virulences. The pathogen adaptation also involves other parasitic fitness traits, especially aggressiveness components. A previous study on Puccinia triticina, the causal agent of wheat leaf rust, revealed that the distribution frequency of virulences in the French pathogen population cannot be fully explained by the major resistance genes deployed in the landscape. From 2012 to 2015, two dominant pathotypes (distinguished by their combination of virulences) were equally frequent despite the theoretical advantage conferred to one pathotype (166 317 0) by its virulence to Lr3, frequent in the cultivated landscape, whereas the other (106 314 0) is avirulent to this gene. To explain this apparent contradiction, we assessed three components of aggressiveness — infection efficiency, latency period and sporulation capacity — for 23 isolates representative of the most frequent genotype within each pathotype (106 314 0-G2 and 166 317 0-G1, identified by their combination of microsatellite markers). We tested these isolates on seedlings of Michigan Amber, a ‘naive’ wheat cultivar that has never been grown in the landscape, Apache, a ’neutral‘ cultivar with no selection effect on the landscape-pathotype pattern, and several cultivars that were frequently grown. We found that 106 314 0-G2 was more aggressive than 166 317 0-G1, with a consistency for the three components of aggressiveness. Our results show that aggressiveness plays a significant role in driving evolution in pathogen populations by acting as a selective advantage, even offsetting the disadvantage of lacking virulence towards a major Lr gene. Higher aggressiveness represents a competitive advantage that is likely even more pronounced when exhibited at the landscape scale as the expression of its multiple components is amplified by the polycyclic nature of epidemics.

Abstract Image

较强的攻击性能否有效弥补植物病原体的毒力缺陷?三尖杉球孢菌在多样化品种景观中的适应性进化案例研究
植物抗性通过抗性基因的调配对植物病原体种群施加了强大的选择压力,从而导致新毒力的出现。病原体的适应还涉及其他寄生性状,特别是侵袭性成分。此前对小麦叶锈病病原菌三尖杉核菌(Puccinia triticina)的研究表明,法国病原菌种群中毒力的分布频率不能完全用景观中部署的主要抗性基因来解释。从2012年到2015年,尽管理论上一种病原型(166 317 0)对Lr3具有致病力,而另一种病原型(106 314 0)对该基因无致病力,但两种优势病原型(根据其致病力组合而区分)的出现频率相同。为了解释这种明显的矛盾,我们评估了每种病原型中最常见基因型(106 314 0-G2 和 166 317 0-G1,通过微卫星标记组合确定)的 23 个分离株的侵染能力的三个组成部分:侵染效率、潜伏期和孢子繁殖能力。我们在密歇根琥珀(一种从未在景观中种植过的 "天真 "小麦栽培品种)、阿帕奇(一种对景观-路径模式没有选择影响的 "中性 "栽培品种)和几种经常种植的栽培品种的幼苗上测试了这些分离株。我们发现,106 314 0-G2 比 166 317 0-G1 更具攻击性,攻击性的三个组成部分具有一致性。我们的研究结果表明,攻击性作为一种选择性优势,在驱动病原体种群进化方面发挥着重要作用,甚至可以抵消对主要 Lr 基因缺乏毒力的劣势。较高的攻击性代表了一种竞争优势,当在景观尺度上表现出来时,这种优势可能会更加明显,因为流行病的多环性放大了其多种成分的表达。
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来源期刊
Journal of Plant Pathology
Journal of Plant Pathology 生物-植物科学
CiteScore
3.10
自引率
4.50%
发文量
218
审稿时长
6-12 weeks
期刊介绍: The Journal of Plant Pathology (JPP or JPPY) is the main publication of the Italian Society of Plant Pathology (SiPAV), and publishes original contributions in the form of full-length papers, short communications, disease notes, and review articles on mycology, bacteriology, virology, phytoplasmatology, physiological plant pathology, plant-pathogeninteractions, post-harvest diseases, non-infectious diseases, and plant protection. In vivo results are required for plant protection submissions. Varietal trials for disease resistance and gene mapping are not published in the journal unless such findings are already employed in the context of strategic approaches for disease management. However, studies identifying actual genes involved in virulence are pertinent to thescope of the Journal and may be submitted. The journal highlights particularly timely or novel contributions in its Editors’ choice section, to appear at the beginning of each volume. Surveys for diseases or pathogens should be submitted as "Short communications".
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