Evolution of sympatric host-specialized lineages of the fungal plant pathogen Zymoseptoria passerinii in natural ecosystems

IF 8.3 1区 生物学 Q1 PLANT SCIENCES
New Phytologist Pub Date : 2024-12-16 DOI:10.1111/nph.20340
Idalia C. Rojas-Barrera, Victor M. Flores-Núñez, Janine Haueisen, Alireza Alizadeh, Fatemeh Salimi, Eva H. Stukenbrock
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Current evidence supports that crop wild relatives (CWRs) might serve as reservoirs for domesticated plant pathogens (Monteil <i>et al</i>., <span>2013</span>, <span>2016</span>), although still few studies are focused on wild pathogen population processes and dynamics (Rouxel <i>et al</i>., <span>2013</span>; Penczykowski <i>et al</i>., <span>2015</span>; Eck <i>et al</i>., <span>2022</span>; Treindl <i>et al</i>., <span>2023</span>). CWRs hold higher levels of genetic diversity and have coevolved in sympatry with plant pathogens in natural ecosystems. Moreover, the centers of diversity and domestication of crop plants harbor a wealth of species (Harlan, <span>1971</span>) that could serve as hosts for plant pathogens (Vavilov, <span>1992</span>). Despite the latter, natural ecosystems are undervalued economically, which limits funding for studies (Fisher <i>et al</i>., <span>2012</span>). Furthermore, having access to wild species found in remote locations or immersed in complex geopolitical contexts adds another layer of difficulty, generating a geographical bias toward high-income regions at the expense of exploring the remaining biodiversity (Marks <i>et al</i>., <span>2023</span>). One way to overcome this is to prioritize neglected areas by collaborating with scientific communities situated in less-represented regions of the globe (Marks <i>et al</i>., <span>2023</span>), and promoting research on nonmodel species and dynamics in natural ecosystems.</p>\n<p>Cumulative evidence supports that ecological divergence of plant pathogens is driven by host specialization. As proposed by Crous &amp; Groenewald (<span>2005</span>) and exemplified by multiple studies (Steenkamp <i>et al</i>., <span>2002</span>; Choi <i>et al</i>., <span>2011</span>; Rouxel <i>et al</i>., <span>2013</span>; Faticov <i>et al</i>., <span>2022</span>), plant pathogens phylogenies frequently represent multiple closely related sister or cryptic species. In this regard, the <i>Zymoseptoria</i> genus comprises eight ascomycete species, only two of them, <i>Zymoseptoria tritici</i> and <i>Zymoseptoria passerinii</i> (Sacc.) Quaedvlieg &amp; Crous, have been reported to infect domesticated hosts (Quaedvlieg <i>et al</i>., <span>2011</span>; Stukenbrock <i>et al</i>., <span>2012b</span>). The origin, population genetics, and plant–pathogen dynamics of the wheat fungal pathogen <i>Z. tritici</i> have been extensively investigated in an agricultural context (Linde <i>et al</i>., <span>2002</span>; Stukenbrock <i>et al</i>., <span>2011</span>; McDonald <i>et al</i>., <span>2022</span>; Orellana-Torrejon <i>et al</i>., <span>2022</span>; Feurtey <i>et al</i>., <span>2023</span>). <i>Zymseptoria tritici</i> and <i>Z. passerinii</i> share overlapping geographic ranges and have diversified in sympatry at their center of origin (Rojas-Barrera <i>et al</i>., <span>2023</span>). However, our understanding of their population genetics and the influence of multiple sympatric hosts on pathogen prevalence in natural ecosystems remain limited (Stukenbrock <i>et al</i>., <span>2011</span>, <span>2012a</span>). Population genetic studies on <i>Z. tritici</i> support that the center of diversity of the <i>Zymoseptoria</i> genus is located in the Middle East (Banke <i>et al</i>., <span>2004</span>), in proximity to the Fertile Crescent recognized as a center of crop domestication (Harlan, <span>1971</span>), where several CWRs are abundant and naturally distributed (Harlan &amp; Zohary, <span>1966</span>).</p>\n<p>The hemibiotrophic fungus <i>Z. passerinii</i>, which causes the sporadic disease Septoria speckled leaf blotch (SSLB), became significant during its last major outbreak in the late 1990s to early 2000s, in the Upper Midwest of the United States and neighbor provinces in Canada (Toubia-Rahme &amp; Steffenson, <span>2004</span>). During that period, an extensive study with 309 isolates collected in North Dakota and Western Minnesota in 2003 and 2004 revealed a high genetic diversity, and a shallow population structure for <i>Z. passerinii</i> (Lee &amp; Neate, <span>2007b</span>), which is supported by an equilibrated frequency of both mating types (Lee &amp; Neate, <span>2007a</span>), suggesting sexual reproduction. However, the teleomorphic stage of this pathogen has only been reported under experimental conditions and has not been described in the field (Ware <i>et al</i>., <span>2006</span>). Interestingly, despite the relevance of SSLB in the early 2000s, there are, to our knowledge, no current reports of SSLB outbreaks in North America or elsewhere, including the Middle East.</p>\n<p>The disease triangle states that favorable climatic variables are as important as plant characteristics in determining the severity of disease epidemics (Stevens, <span>1960</span>). Thus, the sporadic nature of SSLB has been attributed to the requirement of &gt; 48 h of continuous moisture for spore germination (Green &amp; Dickson, <span>1957</span>) and a long period of incubation (16–19 d) (Koble <i>et al</i>., <span>1959</span>; Cunfer, <span>2000</span>), suggesting a strong dependence on weather conditions.</p>\n<p>Additionally, the development of resistant cultivars with durable resistance traits (Toubia-Rahme &amp; Steffenson, <span>2004</span>) has been related to the abrupt disappearance of SSLB during recent decades. In contrast to agricultural environments, our sampling of wild grasses during 2018 and 2020 revealed the persistence of SSLB in multiple <i>Hordeum</i> sp. in northwest Iran, which overlaps with the Fertile Crescent region, and the center of origin and diversity for fungal plant pathogens and their wild host species (Harlan &amp; Zohary, <span>1966</span>; Banke <i>et al</i>., <span>2004</span>). Although we recovered only a few <i>Z. passerinii</i> isolates from wild hosts, this pathogen has not been reported in North America or Iran since 2004 (Lee &amp; Neate, <span>2007b</span>). Thus, this dataset provides valuable insights into <i>Z. passerinii</i> populations within a natural ecosystem located at the origin center for both the pathogen and its hosts.</p>\n<p>In this work, we aimed to answer the following questions: Have the barley-infecting lineages o<i>f Z. passerinii</i> arisen through host tracking, similar to <i>Z. tritici</i> (Stukenbrock <i>et al</i>., <span>2011</span>) or through host range expansion? If <i>Z. passerinii</i> evolved by host tracking, the pathogen is likely younger than its barley host (Stukenbrock &amp; McDonald, <span>2008</span>) and may have lost its capacity to infect the wild ancestor of barley (<i>H. spontaneum</i>). By contrast, during host range expansion, the pathogen retains its ability to infect the primary host, and no significant changes in the pathogen's gene pool are expected (Thines, <span>2019</span>). However, no large-scale study has tested the last condition for host range expansion.</p>\n<p>Given our observation of symptoms in what were identified as different <i>Hordeum</i> species, we speculate whether host specificity in sympatric populations has led to population divergence in the center of diversity of the <i>Zymoseptoria</i> genus. Lastly, we ponder whether the persistence of SSLB in natural ecosystems is linked to a shorter disease onset observed in wild-host-infecting lineages compared with the domesticated host. We address these questions using population genomic datasets of host-specialized populations of <i>Z. passerinii</i>.</p>\n<p>In addition to the mentioned inquiries, we evaluated the host range of <i>Z. passerinii</i>, establishing a pathosystem in domesticated barley and three of their CWR. An advantageous perspective is that barley is diploid and provides an alternative host model system to study <i>Zymoseptoria</i>-caused diseases in cereals and examining candidate resistance traits in a diploid genome background.</p>","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"54 1","pages":""},"PeriodicalIF":8.3000,"publicationDate":"2024-12-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"New Phytologist","FirstCategoryId":"99","ListUrlMain":"https://doi.org/10.1111/nph.20340","RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"PLANT SCIENCES","Score":null,"Total":0}
引用次数: 0

Abstract

Introduction

The increasing emergence and severity of infectious fungal diseases threaten food security and natural ecosystems (Fisher et al., 2012; Stukenbrock & Gurr, 2023). Continuous monitoring, prediction modeling of disease spread, and deeper comprehension of fungal pathogens in wild plant hosts have been largely neglected. This is crucial to profile the impact of fungal pathogens on the context of climate change and independent of agricultural environments (Fisher et al., 2012). Current evidence supports that crop wild relatives (CWRs) might serve as reservoirs for domesticated plant pathogens (Monteil et al., 2013, 2016), although still few studies are focused on wild pathogen population processes and dynamics (Rouxel et al., 2013; Penczykowski et al., 2015; Eck et al., 2022; Treindl et al., 2023). CWRs hold higher levels of genetic diversity and have coevolved in sympatry with plant pathogens in natural ecosystems. Moreover, the centers of diversity and domestication of crop plants harbor a wealth of species (Harlan, 1971) that could serve as hosts for plant pathogens (Vavilov, 1992). Despite the latter, natural ecosystems are undervalued economically, which limits funding for studies (Fisher et al., 2012). Furthermore, having access to wild species found in remote locations or immersed in complex geopolitical contexts adds another layer of difficulty, generating a geographical bias toward high-income regions at the expense of exploring the remaining biodiversity (Marks et al., 2023). One way to overcome this is to prioritize neglected areas by collaborating with scientific communities situated in less-represented regions of the globe (Marks et al., 2023), and promoting research on nonmodel species and dynamics in natural ecosystems.

Cumulative evidence supports that ecological divergence of plant pathogens is driven by host specialization. As proposed by Crous & Groenewald (2005) and exemplified by multiple studies (Steenkamp et al., 2002; Choi et al., 2011; Rouxel et al., 2013; Faticov et al., 2022), plant pathogens phylogenies frequently represent multiple closely related sister or cryptic species. In this regard, the Zymoseptoria genus comprises eight ascomycete species, only two of them, Zymoseptoria tritici and Zymoseptoria passerinii (Sacc.) Quaedvlieg & Crous, have been reported to infect domesticated hosts (Quaedvlieg et al., 2011; Stukenbrock et al., 2012b). The origin, population genetics, and plant–pathogen dynamics of the wheat fungal pathogen Z. tritici have been extensively investigated in an agricultural context (Linde et al., 2002; Stukenbrock et al., 2011; McDonald et al., 2022; Orellana-Torrejon et al., 2022; Feurtey et al., 2023). Zymseptoria tritici and Z. passerinii share overlapping geographic ranges and have diversified in sympatry at their center of origin (Rojas-Barrera et al., 2023). However, our understanding of their population genetics and the influence of multiple sympatric hosts on pathogen prevalence in natural ecosystems remain limited (Stukenbrock et al., 2011, 2012a). Population genetic studies on Z. tritici support that the center of diversity of the Zymoseptoria genus is located in the Middle East (Banke et al., 2004), in proximity to the Fertile Crescent recognized as a center of crop domestication (Harlan, 1971), where several CWRs are abundant and naturally distributed (Harlan & Zohary, 1966).

The hemibiotrophic fungus Z. passerinii, which causes the sporadic disease Septoria speckled leaf blotch (SSLB), became significant during its last major outbreak in the late 1990s to early 2000s, in the Upper Midwest of the United States and neighbor provinces in Canada (Toubia-Rahme & Steffenson, 2004). During that period, an extensive study with 309 isolates collected in North Dakota and Western Minnesota in 2003 and 2004 revealed a high genetic diversity, and a shallow population structure for Z. passerinii (Lee & Neate, 2007b), which is supported by an equilibrated frequency of both mating types (Lee & Neate, 2007a), suggesting sexual reproduction. However, the teleomorphic stage of this pathogen has only been reported under experimental conditions and has not been described in the field (Ware et al., 2006). Interestingly, despite the relevance of SSLB in the early 2000s, there are, to our knowledge, no current reports of SSLB outbreaks in North America or elsewhere, including the Middle East.

The disease triangle states that favorable climatic variables are as important as plant characteristics in determining the severity of disease epidemics (Stevens, 1960). Thus, the sporadic nature of SSLB has been attributed to the requirement of > 48 h of continuous moisture for spore germination (Green & Dickson, 1957) and a long period of incubation (16–19 d) (Koble et al., 1959; Cunfer, 2000), suggesting a strong dependence on weather conditions.

Additionally, the development of resistant cultivars with durable resistance traits (Toubia-Rahme & Steffenson, 2004) has been related to the abrupt disappearance of SSLB during recent decades. In contrast to agricultural environments, our sampling of wild grasses during 2018 and 2020 revealed the persistence of SSLB in multiple Hordeum sp. in northwest Iran, which overlaps with the Fertile Crescent region, and the center of origin and diversity for fungal plant pathogens and their wild host species (Harlan & Zohary, 1966; Banke et al., 2004). Although we recovered only a few Z. passerinii isolates from wild hosts, this pathogen has not been reported in North America or Iran since 2004 (Lee & Neate, 2007b). Thus, this dataset provides valuable insights into Z. passerinii populations within a natural ecosystem located at the origin center for both the pathogen and its hosts.

In this work, we aimed to answer the following questions: Have the barley-infecting lineages of Z. passerinii arisen through host tracking, similar to Z. tritici (Stukenbrock et al., 2011) or through host range expansion? If Z. passerinii evolved by host tracking, the pathogen is likely younger than its barley host (Stukenbrock & McDonald, 2008) and may have lost its capacity to infect the wild ancestor of barley (H. spontaneum). By contrast, during host range expansion, the pathogen retains its ability to infect the primary host, and no significant changes in the pathogen's gene pool are expected (Thines, 2019). However, no large-scale study has tested the last condition for host range expansion.

Given our observation of symptoms in what were identified as different Hordeum species, we speculate whether host specificity in sympatric populations has led to population divergence in the center of diversity of the Zymoseptoria genus. Lastly, we ponder whether the persistence of SSLB in natural ecosystems is linked to a shorter disease onset observed in wild-host-infecting lineages compared with the domesticated host. We address these questions using population genomic datasets of host-specialized populations of Z. passerinii.

In addition to the mentioned inquiries, we evaluated the host range of Z. passerinii, establishing a pathosystem in domesticated barley and three of their CWR. An advantageous perspective is that barley is diploid and provides an alternative host model system to study Zymoseptoria-caused diseases in cereals and examining candidate resistance traits in a diploid genome background.

引言传染性真菌疾病的出现和严重程度不断增加,威胁着粮食安全和自然生态系统(Fisher 等人,2012 年;Stukenbrock &amp; Gurr,2023 年)。对野生植物寄主中真菌病原体的持续监测、疾病传播预测建模和深入了解在很大程度上被忽视了。这对于剖析真菌病原体对气候变化的影响以及独立于农业环境的影响至关重要(Fisher 等人,2012 年)。目前有证据表明,作物野生近缘种(CWRs)可作为驯化植物病原体的贮藏库(Monteil 等人,2013 年,2016 年),但有关野生病原体种群过程和动态的研究仍然很少(Rouxel 等人,2013 年;Penczykowski 等人,2015 年;Eck 等人,2022 年;Treindl 等人,2023 年)。CWRs 具有更高水平的遗传多样性,并在自然生态系统中与植物病原体共同进化。此外,作物植物的多样性和驯化中心蕴藏着丰富的物种(Harlan,1971 年),可作为植物病原体的宿主(Vavilov,1992 年)。尽管如此,自然生态系统的经济价值却被低估,这限制了研究资金的投入(Fisher 等人,2012 年)。此外,在偏远地区或复杂的地缘政治背景下获取野生物种又增加了一层困难,这就造成了对高收入地区的地理偏向,从而牺牲了对剩余生物多样性的探索(Marks 等人,2023 年)。克服这一问题的方法之一是通过与全球代表性较低地区的科学界合作,优先考虑被忽视的领域(Marks 等人,2023 年),并促进对自然生态系统中的非模式物种和动态的研究。正如 Crous &amp; Groenewald(2005 年)所提出并在多项研究(Steenkamp 等人,2002 年;Choi 等人,2011 年;Rouxel 等人,2013 年;Faticov 等人,2022 年)中例证的那样,植物病原体系统发育经常代表多个密切相关的姊妹种或隐蔽种。在这方面,Zymoseptoria 属由 8 个子囊菌种组成,其中只有两个,即 Zymoseptoria tritici 和 Zymoseptoria passerinii (Sacc.) Quaedvlieg &amp; Crous,被报道感染驯化宿主(Quaedvlieg 等人,2011 年;Stukenbrock 等人,2012 年 b)。在农业背景下,对小麦真菌病原体 Z. tritici 的起源、种群遗传学和植物病原体动力学进行了广泛研究(Linde 等人,2002 年;Stukenbrock 等人,2011 年;McDonald 等人,2022 年;Orellana-Torrejon 等人,2022 年;Feurtey 等人,2023 年)。Zymseptoria tritici 和 Z. passerinii 的地理范围相互重叠,并在其原产地中心发生了共生多样化(Rojas-Barrera 等人,2023 年)。然而,我们对它们的种群遗传学以及多个同域宿主对自然生态系统中病原体流行的影响的了解仍然有限(Stukenbrock 等人,2011 年,2012a)。对 Z. tritici 的种群遗传学研究表明,Zymoseptoria 属的多样性中心位于中东地区(Banke et al、2004),毗邻被公认为作物驯化中心的新月沃地(Harlan,1971),那里有大量的 CWRs 自然分布(Harlan &amp; Zohary, 1966)。在 20 世纪 90 年代末到 21 世纪初,半生真菌 Z. passerinii 在美国上中西部和加拿大邻近省份的最后一次大爆发中变得非常重要(Toubia-Rahme &amp; Steffenson, 2004)。在此期间,对 2003 年和 2004 年在北达科他州和明尼苏达州西部采集的 309 株分离株进行了广泛研究,结果显示 Passerinii 的遗传多样性很高,种群结构较浅(Lee &amp; Neate, 2007b),两种交配类型的频率均衡(Lee &amp; Neate, 2007a),表明其为有性生殖。然而,这种病原体的远缘阶段只在实验条件下报道过,在野外还没有描述过(Ware 等人,2006 年)。有趣的是,尽管 SSLB 在本世纪初很重要,但据我们所知,目前还没有关于 SSLB 在北美或其他地区(包括中东)爆发的报道。病害三角区指出,在决定病害流行的严重程度方面,有利的气候变量与植物特征同样重要(Stevens,1960 年)。因此,SSLB 的零星发生归因于孢子萌发需要 48 小时的持续湿度(Green &amp; Dickson, 1957)和较长的潜伏期(16-19 d)(Koble 等人,1959;Cunfer, 2000),这表明它对天气条件有很强的依赖性。
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来源期刊
New Phytologist
New Phytologist 生物-植物科学
自引率
5.30%
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期刊介绍: New Phytologist is an international electronic journal published 24 times a year. It is owned by the New Phytologist Foundation, a non-profit-making charitable organization dedicated to promoting plant science. The journal publishes excellent, novel, rigorous, and timely research and scholarship in plant science and its applications. The articles cover topics in five sections: Physiology & Development, Environment, Interaction, Evolution, and Transformative Plant Biotechnology. These sections encompass intracellular processes, global environmental change, and encourage cross-disciplinary approaches. The journal recognizes the use of techniques from molecular and cell biology, functional genomics, modeling, and system-based approaches in plant science. Abstracting and Indexing Information for New Phytologist includes Academic Search, AgBiotech News & Information, Agroforestry Abstracts, Biochemistry & Biophysics Citation Index, Botanical Pesticides, CAB Abstracts®, Environment Index, Global Health, and Plant Breeding Abstracts, and others.
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