Baek You Soon, Goodrich Loren V, Brown Patrick J, James Brandon T, Moose Stephen P, Lambert Kris N, Riechers Dean E
Department of Crop Sciences, University of Illinois at Urbana-Champaign, Urbana, IL, United States.
Jerseyville Research Center, Monsanto Company, Jerseyville, IL, United States.
Front Plant Sci. 2019 Mar 8;10:192. doi: 10.3389/fpls.2019.00192. eCollection 2019.
Herbicide safeners protect cereal crops from herbicide injury by inducing genes and proteins involved in detoxification reactions, such as glutathione -transferases (GSTs) and cytochrome P450s (P450s). Only a few studies have characterized gene or protein expression profiles for investigating plant responses to safener treatment in cereal crops, and most transcriptome analyses in response to safener treatments have been conducted in dicot model species that are not protected by safener from herbicide injury. In this study, three different approaches were utilized in grain sorghum ( (L.) Moench) to investigate mechanisms involved in safener-regulated signaling pathways. An initial transcriptome analysis was performed to examine global gene expression in etiolated shoot tissues of hybrid grain sorghum following treatment with the sorghum safener, fluxofenim. Most upregulated transcripts encoded detoxification enzymes, including P450s, GSTs, and UDP-dependent glucosyltransferases (UGTs). Interestingly, several of these upregulated transcripts are similar to genes involved with the biosynthesis and recycling/catabolism of dhurrin, an important chemical defense compound, in these seedling tissues. Secondly, 761 diverse sorghum inbred lines were evaluated in a genome-wide association study (GWAS) to determine key molecular-genetic factors governing safener-mediated signaling mechanisms and/or herbicide detoxification. GWAS revealed a significant single nucleotide polymorphism (SNP) associated with safener-induced response on chromosome 9, located within a phi-class gene and about 15-kb from a different phi-class . Lastly, the expression of these two candidate was quantified in etiolated shoot tissues of sorghum inbred BTx623 in response to fluxofenim treatment. and transcripts increased within 12-hr after fluxofenim treatment but the level of safener-induced expression differed between the two genes. In addition to identifying specific GSTs potentially involved in the safener-mediated detoxification pathway, this research elucidates a new direction for studying both constitutive and inducible mechanisms for chemical defense in cereal crop seedlings.
除草剂安全剂通过诱导参与解毒反应的基因和蛋白质(如谷胱甘肽-S-转移酶(GSTs)和细胞色素P450s(P450s))来保护谷类作物免受除草剂伤害。只有少数研究对用于研究谷类作物对安全剂处理反应的基因或蛋白质表达谱进行了表征,并且大多数针对安全剂处理的转录组分析是在双子叶模式物种中进行的,这些物种不能通过安全剂免受除草剂伤害。在本研究中,对粒用高粱((L.) Moench)采用了三种不同方法来研究安全剂调控信号通路的相关机制。进行了初步转录组分析,以检测用高粱安全剂氟咯草酮处理后杂交粒用高粱黄化茎组织中的全局基因表达。大多数上调的转录本编码解毒酶,包括P450s、GSTs和UDP-依赖性葡糖基转移酶(UGTs)。有趣的是,这些上调转录本中的几个与这些幼苗组织中参与重要化学防御化合物蜀黍氰苷生物合成和循环利用/分解代谢的基因相似。其次,在全基因组关联研究(GWAS)中评估了761个不同的高粱自交系,以确定控制安全剂介导的信号机制和/或除草剂解毒的关键分子遗传因素。GWAS揭示了与9号染色体上安全剂诱导反应相关的一个显著单核苷酸多态性(SNP),该SNP位于一个phi类基因内,距离另一个不同的phi类基因约15 kb。最后,在高粱自交系BTx623的黄化茎组织中,对这两个候选基因响应氟咯草酮处理后的表达进行了定量。氟咯草酮处理后12小时内, 和 转录本增加,但两个基因的安全剂诱导表达水平不同。除了鉴定可能参与安全剂介导解毒途径的特定GSTs外,本研究还阐明了研究谷类作物幼苗化学防御组成型和诱导型机制的新方向。
