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基于基因组和转录组的印度腥黑粉菌比较分析,以破译引起小麦印度腥黑穗病的致病基因。

Genome and transcriptome based comparative analysis of Tilletia indica to decipher the causal genes for pathogenicity of Karnal bunt in wheat.

机构信息

Division of Agricultural Bioinformatics, ICAR-Indian Agricultural Statistics Research Institute, New Delhi, India.

Department of Bioinformatics, College of Animal Biotechnology, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, India.

出版信息

BMC Plant Biol. 2024 Jul 16;24(1):676. doi: 10.1186/s12870-024-04959-z.

DOI:10.1186/s12870-024-04959-z
PMID:39009989
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11251232/
Abstract

Tilletia indica Mitra causes Karnal bunt (KB) in wheat by pathogenic dikaryophase. The present study is the first to provide the draft genomes of the dikaryon (PSWKBGD-3) and its two monosporidial lines (PSWKBGH-1 and 2) using Illumina and PacBio reads, their annotation and the comparative analyses among the three genomes by extracting polymorphic SSR markers. The trancriptome from infected wheat grains of the susceptible wheat cultivar WL711 at 24 h, 48h, and 7d after inoculation of PSWKBGH-1, 2 and PSWKBGD-3 were also isolated. Further, two transcriptome analyses were performed utilizing T. indica transcriptome to extract dikaryon genes responsible for pathogenesis, and wheat transcriptome to extract wheat genes affected by dikaryon involved in plant-pathogen interaction during progression of KB in wheat. A total of 54, 529, and 87 genes at 24hai, 48hai, and 7dai, respectively were upregulated in dikaryon stage while 21, 35, and 134 genes of T. indica at 24hai, 48hai, and 7dai, respectively, were activated only in dikaryon stage. While, a total of 23, 17, and 52 wheat genes at 24hai, 48hai, and 7dai, respectively were upregulated due to the presence of dikaryon stage only. The results obtained during this study have been compiled in a web resource called TiGeR ( http://backlin.cabgrid.res.in/tiger/ ), which is the first genomic resource for T. indica cataloguing genes, genomic and polymorphic SSRs of the three T. indica lines, wheat and T. indica DEGs as well as wheat genes affected by T. indica dikaryon along with the pathogenecity related proteins of T. indica dikaryon during incidence of KB at different time points. The present study would be helpful to understand the role of dikaryon in plant-pathogen interaction during progression of KB, which would be helpful to manage KB in wheat, and to develop KB-resistant wheat varieties.

摘要

印度腥黑粉菌(Tilletia indica)通过有性双核期引起小麦的卡纳病(KB)。本研究首次利用 Illumina 和 PacBio 读数提供双核体(PSWKBGD-3)及其两个单核体系(PSWKBGH-1 和 2)的基因组草案,对三个基因组进行注释和比较分析,并提取多态性 SSR 标记。还从易感小麦品种 WL711 的受感染麦粒中分离了接种 PSWKBGH-1、2 和 PSWKBGD-3 后 24h、48h 和 7d 的转录组。此外,还利用 T. indica 转录组提取了与致病性有关的双核体基因,利用小麦转录组提取了在小麦 KB 进展过程中与双核体参与植物-病原体相互作用有关的受双核体影响的小麦基因,进行了两次转录组分析。在双核体阶段,分别有 54、529 和 87 个基因在 24hai、48hai 和 7dai 上调,而在 T. indica 中,分别有 21、35 和 134 个基因在 24hai、48hai 和 7dai 上调,仅在双核体阶段被激活。同时,在双核体阶段,分别有 23、17 和 52 个小麦基因在 24hai、48hai 和 7dai 上调。本研究获得的结果已汇编在一个名为 TiGeR(http://backlin.cabgrid.res.in/tiger/)的网络资源中,这是 T. indica 基因、三个 T. indica 系、小麦和 T. indica 的基因组和多态性 SSRs、小麦和受 T. indica 双核体影响的小麦基因以及 T. indica 双核体在不同时间点发病期间与致病性相关蛋白的第一个基因组资源。本研究有助于了解双核体在 KB 进展过程中植物-病原体相互作用中的作用,这将有助于在小麦中管理 KB,并开发 KB 抗性小麦品种。

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