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The fungal pathogens exhibit diverse genome architecture, which facilitates the host adaptation. Although increasing high-quality genomic data enable insights into the genome architecture of many fungal pathogens during the last decades, genomic features of many fungal species are still not fully characterized. Here, we identified a family fungal strain JB-1 causing the leaf spot disease on and revealed its distinct genome compartment features. The fungal strain JB-1 was identified as based on the Koch's postulate, conidial morphology, and phylogenetic analysis. Using 2.51 Gb PacBio HiFi sequencing data, the JB-1 genome was assembled into nine contigs, five of which contain telomeric repeats at both ends. The genome size is 40,888,459 bp with an N50 of 6,431,016 bp, and a total of 9,894 protein-coding genes were predicted. BUSCO assessment demonstrated high completeness, with 754 (99.47%) of the 758 BUSCO orthologs identified as complete. The absence of both repeat-rich regions at chromosome ends and preferential residing of pathogenicity-associated genes (PAGs) in the repeat-rich regions indicated a genome compartment dissimilar to the "two-speed genome" commonly observed in , indicating a distinct evolution drive of the PAGs in strain JB-1. Additionally, the JB-1 genome encodes fewer PAGs compared to other members of family . These findings provide valuable genomic resources of family and will facilitate future studies on host-pathogen interactions and the development of effective disease management strategies for .IMPORTANCEThe family includes notorious pathogens that annually result in significant agricultural losses. The genome architecture of plant fungal pathogens reflects their evolutionary adaptation to host-pathogen interactions. However, limited knowledge exists regarding the genomic features of other species within family , particularly those associated with the economically important crop . In this study, we assembled the first high-quality genome of strain JB-1, which infects , and revealed its distinct genome architecture. We provide evidence that the distribution pattern of pathogenicity-associated genes in strain JB-1 closely resembles the "one-speed genome" structure, which contrasts with . Our findings provide valuable resources for genomic studies within family and contribute to our understanding of the adaptive evolution of pathogens to their hosts.

真菌病原体呈现出多样的基因组结构，这有利于它们适应宿主。尽管在过去几十年里，越来越多的高质量基因组数据使人们能够深入了解许多真菌病原体的基因组结构，但许多真菌物种的基因组特征仍未得到充分表征。在这里，我们鉴定出一种引起叶斑病的科真菌菌株JB-1，并揭示了其独特的基因组区室特征。基于柯赫氏法则、分生孢子形态和系统发育分析，真菌菌株JB-1被鉴定为。利用2.51 Gb的PacBio HiFi测序数据，JB-1基因组被组装成9个重叠群，其中5个在两端都含有端粒重复序列。基因组大小为40,888,459 bp，N50为6,431,016 bp，共预测到9894个蛋白质编码基因。BUSCO评估显示完整性很高，758个BUSCO直系同源基因中有754个（99.47%）被鉴定为完整。染色体末端不存在富含重复序列的区域，且致病相关基因（PAGs）也不在富含重复序列的区域中优先存在，这表明该基因组区室与中常见的“双速基因组”不同，表明菌株JB-1中PAGs有独特的进化驱动力。此外，与科的其他成员相比，JB-1基因组编码的PAGs较少。这些发现提供了科有价值的基因组资源，并将促进未来关于宿主-病原体相互作用的研究以及针对的有效病害管理策略的开发。

重要性

科包括臭名昭著的病原体，每年都会导致重大的农业损失。植物真菌病原体的基因组结构反映了它们对宿主-病原体相互作用的进化适应。然而，关于科内其他物种的基因组特征，尤其是与经济上重要的作物相关的那些特征，我们了解有限。在这项研究中，我们组装了感染的菌株JB-1的首个高质量基因组，并揭示了其独特的基因组结构。我们提供的证据表明，菌株JB-1中致病相关基因的分布模式与“单速基因组”结构非常相似，这与形成对比。我们的发现为科内的基因组研究提供了有价值的资源，并有助于我们理解病原体对宿主的适应性进化。