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中国西南和西北地区 f. sp. 的遗传关系。

Genetic Relationships of f. sp. in Southwestern and Northwestern China.

机构信息

Ministry of Agriculture Key Laboratory of Pest Monitoring and Green Management, Department of Plant Pathology, China Agricultural Universitygrid.22935.3f, Beijing, China.

Shandong Provincial University Laboratory for Protected Horticulture, Shandong Facility Horticulture Bioengineering Research Center, Weifang University of Science and Technology, Weifang, China.

出版信息

Microbiol Spectr. 2022 Aug 31;10(4):e0153022. doi: 10.1128/spectrum.01530-22. Epub 2022 Jul 27.

DOI:10.1128/spectrum.01530-22
PMID:35894618
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9430570/
Abstract

Wheat stripe rust, caused by Puccinia striiformis f. sp. (), is a crucial disease for wheat worldwide and constantly threatens wheat production in southwestern and northwestern China, where the environment is a good fit for oversummering and overwintering. However, the underlying genetic dynamics of spring epidemic populations across large areas of continuous planting in the southwestern and northwestern regions are poorly understood. A total of 2,103 isolates were sampled in the spring of 2019 from the two agroecosystems and grouped into three horizontal spatial scales (countywide, provincial, and regional subpopulations) and two vertical spatial scales that consisted of elevational and geomorphic subpopulations. A total of 776 multilocus genotypes were identified, with the highest genetic diversity found in the northern and Sichuan populations, particularly in the Ningxia and Sichuan Basins, while the lowest genetic diversity was found in the Yunnan and Guizhou populations. Multivariate discriminant analysis of principal components (DAPC) and STRUCTURE (STRUCTURE 2.3.4) analyses revealed variation in the genotypic compositions of the molecular groups on horizontal and vertical dimensions from north to south or vice versa and from low to high or vice versa, respectively. The regional neighbor-joining tree revealed three large spatial structures consisting of the southwestern, the northwestern, and the Xinjiang regions, while the Tibetan population connected the southwestern and northwestern regions. The isolates of the Sichuan Basin were scattered over the four quartiles by principal coordinate analysis, which indicated frequent genotype interchange with others. Greater genetic differentiation was observed between the southwestern and northwestern regions. Linkage equilibrium (0.05) was detected on different spatial scales, suggesting that populations are using sexual reproduction or mixed reproduction (sexual and clonal reproduction) in southwestern and northwestern China. Understanding the epidemiology and population genetics of plant pathogens is crucial to formulate efficient predictions of disease outbreaks and achieve sustainable integrated disease management, especially for pathogens with migratory capability. Here, this study covers the genetic homogeneity and heterogeneity of different geographical populations on broad to fine spatial scales from the key epidemic regions of the two agroecosystems in China, where wheat stripe rust occurs annually. We provide knowledge of the population genetics of and reveal that, for instance, there is greater genetic diversity in northwestern China, there are close genetic relationships between Yunnan and Guizhou and between Gansu-Ningxia and Qinghai, and there are effects of altitude on genetic compositions, etc. All of these findings clarify the genetic relationships and expand the insights into the population dynamics and evolutionary mechanisms of in southwestern and northwestern China, providing a theoretical basis for achieving sustainable control of wheat stripe rust in key epidemic regions.

摘要

小麦条锈病由条形柄锈菌小麦专化型引起,是一种全球性的重要小麦病害,不断威胁着中国西南和西北地区的小麦生产,这些地区的环境有利于越夏和越冬。然而,西南和西北地区大面积连片种植的春季流行种群的遗传动态基础仍不清楚。2019 年春季,从两个农业生态系统共采集了 2103 个分离株,按水平空间尺度(全县、全省和区域亚种群)和垂直空间尺度(海拔和地形亚种群)分为三个水平空间尺度和两个垂直空间尺度。共鉴定出 776 个多基因座基因型,发现北部和四川种群的遗传多样性最高,尤其是宁夏和四川盆地,而云南和贵州种群的遗传多样性最低。主成分判别分析(DAPC)和 STRUCTURE(STRUCTURE 2.3.4)分析表明,南北或反之,高低或反之,分子群体的基因型组成在水平和垂直维度上存在变化。区域邻接树揭示了由西南、西北和新疆三个大区组成的三个大的空间结构,而西藏种群连接了西南和西北地区。四川盆地的分离株通过主坐标分析散落在四个四分位数中,这表明与其他分离株的基因型频繁交换。西南和西北地区之间观察到更大的遗传分化。在不同的空间尺度上检测到连锁平衡(0.05),表明在中国西南和西北地区,种群正在使用有性繁殖或混合繁殖(有性和无性繁殖)。了解植物病原菌的流行病学和种群遗传学对于制定有效的疾病爆发预测和实现可持续的综合疾病管理至关重要,特别是对于具有迁移能力的病原菌。在这里,本研究涵盖了来自中国两个农业生态系统关键流行区不同地理种群的广泛到精细空间尺度上的遗传同质性和异质性,这些地区每年都会发生小麦条锈病。本研究提供了关于条锈菌种群遗传学的知识,并揭示了例如在中国西北地区存在更大的遗传多样性,云南和贵州以及甘肃-宁夏和青海之间存在密切的遗传关系,以及海拔对遗传组成的影响等。所有这些发现都阐明了遗传关系,并扩展了对西南和西北地区条锈菌种群动态和进化机制的认识,为在关键流行地区实现小麦条锈病的可持续控制提供了理论依据。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6156/9430570/107036b99c76/spectrum.01530-22-f006.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6156/9430570/6db78ffdbef1/spectrum.01530-22-f001.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6156/9430570/575bfc2e15f5/spectrum.01530-22-f002.jpg
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Gene flow between island populations of the malaria mosquito, , may have contributed to the spread of divergent host preference phenotypes.
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