Tingdong Fu National Key Laboratory of Crop Genetic Improvement, National Center of Rapeseed Improvement in Wuhan, College of Plant Science and Technology, Huazhong Agricultural University, Wuhan 430070, PR China.
Plant Sci. 2018 May;270:97-113. doi: 10.1016/j.plantsci.2018.01.021. Epub 2018 Feb 15.
Plant height is a key trait of plant architecture, and is responsible for both yield and lodging resistance in Brassica napus. A dwarf mutant line (bnaC.dwf) was obtained by chemical mutagenesis of an inbred line T6. However, the molecular mechanisms and changed biological processes of the dwarf mutant remain to be determined. In this study, a comparative transcriptome analysis between bnaC.dwf and T6 plants was performed to identify genome-wide differentially expressed genes (DEGs) and possible biological processes that may explain the phenotype variations in bnaC.dwf. As a result of this analysis, 60,134,746-60,301,384 clean reads were aligned to 60,074 genes in the B. napus genome, and accounted for 60.03% of the annotated genes. In total, 819 differentially expressed genes were used for GO (Gene Ontology) term and KEGG (Kyoto Encyclopedia of Genes and Genomes) pathway enrichment analyses with a FDR (false discovery rate) criterion of <0.001, |logRatio| ≥ 1. We focused on plant hormone signal transduction pathways, plant-pathogen interaction pathway, protein phosphorylation and degradation pathways and sugar metabolism pathways. Taken together, the decrease in local auxin (IAA) levels, the variation in BnTCH4, BnKAN1, BnERF109, COI1-JAZ9-MYC2, auxin response genes (BnGH3.11, BnSAUR78, and AUX/IAA19), and ABA (abscisic acid) signaling genes (BnADP5, BnSnRK2.1, BnABF3.1) partially accounted for variations of cell proliferation in internodes, shoot and root apical meristem maintenance, abiotic and biotic stress resistance, and pre-harvest sprouting. As a comprehensive consequence of the cross-talk between plant hormones, sugar metabolism, plant-pathogen interactions and protein metabolism, bnaC.dwf presents distinct phenotypes from T6. These results will be helpful for shedding light on molecular mechanisms in the dwarf mutant, and give insight into further molecular breeding of semi-dwarf B. napus.
植物高度是植物结构的一个关键特征,它决定了油菜的产量和抗倒伏能力。通过对自交系 T6 进行化学诱变,获得了一个矮秆突变体系(bnaC.dwf)。然而,矮秆突变体的分子机制和改变的生物学过程仍有待确定。在这项研究中,对 bnaC.dwf 和 T6 植株之间的比较转录组分析,以鉴定全基因组差异表达基因(DEGs)和可能解释 bnaC.dwf 表型变异的生物学过程。该分析共得到 60,134,746-60,301,384 条清洁读取序列,与油菜基因组中的 60,074 个基因相匹配,占注释基因的 60.03%。总共使用了 819 个差异表达基因进行 GO(基因本体论)术语和 KEGG(京都基因与基因组百科全书)途径富集分析,FDR(假发现率)标准为 <0.001,|logRatio|≥1。我们重点关注植物激素信号转导途径、植物-病原体相互作用途径、蛋白质磷酸化和降解途径以及糖代谢途径。总之,局部生长素(IAA)水平的降低、BnTCH4、BnKAN1、BnERF109、COI1-JAZ9-MYC2、生长素响应基因(BnGH3.11、BnSAUR78 和 AUX/IAA19)和 ABA(脱落酸)信号基因(BnADP5、BnSnRK2.1、BnABF3.1)的变化部分解释了节间细胞增殖、茎和根顶端分生组织维持、非生物和生物胁迫抗性以及收获前发芽的变化。作为植物激素、糖代谢、植物-病原体相互作用和蛋白质代谢之间相互作用的综合结果,bnaC.dwf 呈现出与 T6 不同的表型。这些结果将有助于阐明矮秆突变体的分子机制,并为油菜半矮化的进一步分子育种提供参考。
