{"title":"植物病原真菌 Gaeumannomyces tritici 的次生代谢物基因簇","authors":"","doi":"10.1007/s42161-024-01605-3","DOIUrl":null,"url":null,"abstract":"<h3>Abstract</h3> <p>The take-all disease is one of the most important maladies in cereals and grasses, being caused by the fungus <em>Gaeumannomyces tritici</em>. Secondary metabolites are known to perform critical functions during the infection process of various phytopathogens. However, the current understanding of the biosynthesis of secondary metabolites in <em>G. tritici</em> is limited. Similarly, comprehensive analyses of the expression, conservation, and evolution of these biosynthesis-related genes are crucial for enhancing our knowledge of the molecular mechanisms that drive the development of the take-all disease. Here we have performed a deep survey and description of secondary metabolite biosynthetic gene clusters in <em>G. tritici</em>, analyzed a previously published RNA-seq of a mimicked infection condition, and assessed the conservation among 10 different Magnaporthales order members. Notably, the majority of the 35 putative gene clusters identified were conserved among these species, with GtPKS1, GtPKS3, and GtTERP4 uniquely identified in <em>G. tritici</em>. In the mimicked infection condition, seven gene clusters, including the GtPKS1 cluster, exhibited upregulated expression. Through comparative genomic analysis, GtPKS1 was associated with the production of dichlorodiaporthin, a metabolite with cytotoxic and antifungal activity. In addition, GtPKS10 and GtPKSNRPS3 showed similarities to already characterized biosynthetic pathways involved in the synthesis of ACR-toxin (phytotoxic) and trichosetin (phytotoxic and antibiotic), respectively. These three gene clusters were further scrutinized through phylogenetic inference, which revealed the distribution of orthologous sequences across various plant-associated fungi. Finally, the detailed identification of several genes enrolled in secondary metabolite biosynthesis provides the foundation for future in-depth research, supporting the potential impact of several small molecules on <em>G. tritici</em> lifecycle and host interactions.</p>","PeriodicalId":16837,"journal":{"name":"Journal of Plant Pathology","volume":"84 1","pages":""},"PeriodicalIF":2.2000,"publicationDate":"2024-03-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Secondary metabolite gene clusters from the phytopathogenic fungus Gaeumannomyces tritici\",\"authors\":\"\",\"doi\":\"10.1007/s42161-024-01605-3\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<h3>Abstract</h3> <p>The take-all disease is one of the most important maladies in cereals and grasses, being caused by the fungus <em>Gaeumannomyces tritici</em>. Secondary metabolites are known to perform critical functions during the infection process of various phytopathogens. However, the current understanding of the biosynthesis of secondary metabolites in <em>G. tritici</em> is limited. Similarly, comprehensive analyses of the expression, conservation, and evolution of these biosynthesis-related genes are crucial for enhancing our knowledge of the molecular mechanisms that drive the development of the take-all disease. Here we have performed a deep survey and description of secondary metabolite biosynthetic gene clusters in <em>G. tritici</em>, analyzed a previously published RNA-seq of a mimicked infection condition, and assessed the conservation among 10 different Magnaporthales order members. Notably, the majority of the 35 putative gene clusters identified were conserved among these species, with GtPKS1, GtPKS3, and GtTERP4 uniquely identified in <em>G. tritici</em>. In the mimicked infection condition, seven gene clusters, including the GtPKS1 cluster, exhibited upregulated expression. Through comparative genomic analysis, GtPKS1 was associated with the production of dichlorodiaporthin, a metabolite with cytotoxic and antifungal activity. In addition, GtPKS10 and GtPKSNRPS3 showed similarities to already characterized biosynthetic pathways involved in the synthesis of ACR-toxin (phytotoxic) and trichosetin (phytotoxic and antibiotic), respectively. These three gene clusters were further scrutinized through phylogenetic inference, which revealed the distribution of orthologous sequences across various plant-associated fungi. 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引用次数: 0
摘要
摘要 全蚀病是谷物和禾本科植物最重要的病害之一,由三尖杉属真菌(Gaeumannomyces tritici)引起。众所周知,次生代谢物在各种植物病原菌的感染过程中发挥着关键作用。然而,目前对 G. tritici 中次生代谢物生物合成的了解还很有限。同样,对这些生物合成相关基因的表达、保存和进化进行全面分析,对于增进我们对驱动三尖杉属植物全爪病发展的分子机制的了解至关重要。在此,我们对 G. tritici 的次生代谢物生物合成基因簇进行了深入调查和描述,分析了之前发表的模拟感染条件的 RNA-seq,并评估了 10 个不同 Magnaporthales 目成员之间的保守性。值得注意的是,所发现的 35 个假定基因簇中的大多数在这些物种中是保守的,其中 GtPKS1、GtPKS3 和 GtTERP4 在 G. tritici 中是唯一被发现的。在模拟感染条件下,包括 GtPKS1 基因簇在内的七个基因簇表现出表达上调。通过比较基因组分析,GtPKS1 与具有细胞毒性和抗真菌活性的代谢物二氯二硼酸的产生有关。此外,GtPKS10 和 GtPKSNRPS3 与已经确定的生物合成途径有相似之处,它们分别参与了 ACR-毒素(植物毒素)和三代霉素(植物毒素和抗生素)的合成。通过系统发育推断对这三个基因簇进行了进一步研究,发现了各种植物相关真菌中同源序列的分布情况。最后,对参与次生代谢物生物合成的几个基因的详细鉴定为今后的深入研究奠定了基础,证明了几种小分子化合物对 G. tritici 生命周期和宿主相互作用的潜在影响。
Secondary metabolite gene clusters from the phytopathogenic fungus Gaeumannomyces tritici
Abstract
The take-all disease is one of the most important maladies in cereals and grasses, being caused by the fungus Gaeumannomyces tritici. Secondary metabolites are known to perform critical functions during the infection process of various phytopathogens. However, the current understanding of the biosynthesis of secondary metabolites in G. tritici is limited. Similarly, comprehensive analyses of the expression, conservation, and evolution of these biosynthesis-related genes are crucial for enhancing our knowledge of the molecular mechanisms that drive the development of the take-all disease. Here we have performed a deep survey and description of secondary metabolite biosynthetic gene clusters in G. tritici, analyzed a previously published RNA-seq of a mimicked infection condition, and assessed the conservation among 10 different Magnaporthales order members. Notably, the majority of the 35 putative gene clusters identified were conserved among these species, with GtPKS1, GtPKS3, and GtTERP4 uniquely identified in G. tritici. In the mimicked infection condition, seven gene clusters, including the GtPKS1 cluster, exhibited upregulated expression. Through comparative genomic analysis, GtPKS1 was associated with the production of dichlorodiaporthin, a metabolite with cytotoxic and antifungal activity. In addition, GtPKS10 and GtPKSNRPS3 showed similarities to already characterized biosynthetic pathways involved in the synthesis of ACR-toxin (phytotoxic) and trichosetin (phytotoxic and antibiotic), respectively. These three gene clusters were further scrutinized through phylogenetic inference, which revealed the distribution of orthologous sequences across various plant-associated fungi. Finally, the detailed identification of several genes enrolled in secondary metabolite biosynthesis provides the foundation for future in-depth research, supporting the potential impact of several small molecules on G. tritici lifecycle and host interactions.
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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