结合对 RIL 亲本基因组的深度重测序和默观 GWAS 分析,挖掘控制玉米低磷响应基因的 QTL。

IF 4.4 1区 农林科学 Q1 AGRONOMY Theoretical and Applied Genetics Pub Date : 2024-07-24 DOI:10.1007/s00122-024-04696-9
Bowen Luo, Peng Ma, Chong Zhang, Xiao Zhang, Jing Li, Junchi Ma, Zheng Han, Shuhao Zhang, Ting Yu, Guidi Zhang, Hongkai Zhang, Haiying Zhang, Binyang Li, Jia Guo, Ping Ge, Yuzhou Lan, Dan Liu, Ling Wu, Duojiang Gao, Shiqiang Gao, Shunzong Su, Shibin Gao
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引用次数: 0

摘要

关键信息:我们利用低Pi和正常Pi处理下玉米RIL群体的广泛而全面的表型数据进行了QTL图谱绘制。此外,我们还整合了来自RIL群体的亲本重测序数据、GWAS结果和转录组数据,以确定与玉米低Pi胁迫相关的候选基因。磷(Pi)是影响玉米产量的重要营养元素之一。然而,控制玉米低磷响应的 QTL 基因在很大程度上仍然未知。本研究利用 X178(耐钾)和 9782(敏感)构建的 RIL 群体,在低钾和正常钾条件下评估了玉米幼苗期和成熟期的 38 个性状。在排除了低∏条件和正常∏条件下具有共同区间的 QTLs 后,确定了 29 个低∏条件下特有的 QTLs。此外,还根据每个性状的指数值((低π条件下的性状-正常π条件下的性状)/正常π条件下的性状)确定了另外 45 个 QTL。这 74 个 QTL 被统称为 Pi- 依赖性 QTL。此外,39 个 Pi- 依赖性 QTL 聚类在 9 个热点 QTL 中。Pi- 依赖性 QTL 区间包含 19,613 个独特基因,其中 6,999 个基因在 X178 和 9782 之间的非同义突变位点表现出序列差异。结合硅学 GWAS 结果,确定了 277 个一致的候选基因,其中 124 个基因位于热点 QTL 区间内。转录组分析表明,包括π转运体 ZmPT7 和芪内酯通路相关基因 ZmPDR1 在内的 21 个基因在不同的玉米近交系或组织中表现出一致的低π胁迫响应模式。值得注意的是,玉米根中的 ZmPDR1 在低 Pi 胁迫下会急剧上调,这表明它可能是通过糙伏内酯途径响应低 Pi 胁迫的一个候选基因。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Mining for QTL controlling maize low-phosphorus response genes combined with deep resequencing of RIL parental genomes and in silico GWAS analysis.

Key message: Extensive and comprehensive phenotypic data from a maize RIL population under both low- and normal-Pi treatments were used to conduct QTL mapping. Additionally, we integrated parental resequencing data from the RIL population, GWAS results, and transcriptome data to identify candidate genes associated with low-Pi stress in maize. Phosphorus (Pi) is one of the essential nutrients that greatly affect the maize yield. However, the genes underlying the QTL controlling maize low-Pi response remain largely unknown. In this study, a total of 38 traits at both seedling and maturity stages were evaluated under low- and normal-Pi conditions using a RIL population constructed from X178 (tolerant) and 9782 (sensitive), and most traits varied significantly between low- and normal-Pi treatments. Twenty-nine QTLs specific to low-Pi conditions were identified after excluding those with common intervals under both low- and normal-Pi conditions. Furthermore, 45 additional QTLs were identified based on the index value ((Trait_under_LowPi-Trait_under_NormalPi)/Trait_under_NormalPi) of each trait. These 74 QTLs collectively were classified as Pi-dependent QTLs. Additionally, 39 Pi-dependent QTLs were clustered in nine HotspotQTLs. The Pi-dependent QTL interval contained 19,613 unique genes, 6,999 of which exhibited sequence differences with non-synonymous mutation sites between X178 and 9782. Combined with in silico GWAS results, 277 consistent candidate genes were identified, with 124 genes located within the HotspotQTL intervals. The transcriptome analysis revealed that 21 genes, including the Pi transporter ZmPT7 and the strigolactones pathway-related gene ZmPDR1, exhibited consistent low-Pi stress response patterns across various maize inbred lines or tissues. It is noteworthy that ZmPDR1 in maize roots can be sharply up-regulated by low-Pi stress, suggesting its potential importance as a candidate gene for responding to low-Pi stress through the strigolactones pathway.

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来源期刊
CiteScore
9.60
自引率
7.40%
发文量
241
审稿时长
2.3 months
期刊介绍: Theoretical and Applied Genetics publishes original research and review articles in all key areas of modern plant genetics, plant genomics and plant biotechnology. All work needs to have a clear genetic component and significant impact on plant breeding. Theoretical considerations are only accepted in combination with new experimental data and/or if they indicate a relevant application in plant genetics or breeding. Emphasizing the practical, the journal focuses on research into leading crop plants and articles presenting innovative approaches.
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