Yu Hang, Zhang Chao, Lu Chuang, Wang Yana, Ge Congcong, Huang Guixiang, Wang Haifeng
State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources, Guangxi Key Lab of Sugarcane Biology, College of Agriculture, Guangxi University, Nanning, Guangxi 530004, China.
Key Laboratory of Crop Cultivation and Physiology, Education Department of Guangxi Zhuang Autonomous Region, Guangxi University, Nanning 530004, China.
Hortic Res. 2024 Jan 5;11(3):uhae005. doi: 10.1093/hr/uhae005. eCollection 2024 Mar.
Citric acid gives lemons their unique flavor, which impacts their sensory traits and market value. However, the intricate process of citric acid accumulation during lemon fruit growth remains incompletely understood. Here, we achieved a chromosomal-level genome assembly for the 'Xiangshui' lemon variety, spanning 364.85 Mb across nine chromosomes. This assembly revealed 27 945 genes and 51.37% repetitive sequences, tracing the divergence from citron 2.85 million years ago. DNA methylome analysis of lemon fruits across different developmental stages revealed significant variations in DNA methylation. We observed decreased CG and CHG methylation but increased CHH methylation. Notably, the expression of RdDM pathway-related genes increased with fruit development, suggesting a connection with elevated CHH methylation, which is potentially influenced by the canonical RdDM pathway. Furthermore, we observed that elevated CHH DNA methylation within promoters significantly influenced the expression of key genes, critically contributing to vital biological processes, such as citric acid accumulation. In particular, the pivotal gene (), which regulates the tricarboxylic acid cycle, was strikingly upregulated during fruit development, concomitant with increased CHH methylation in its promoter region. Other essential genes associated with citric acid accumulation, such as the MYB transcription factor () and (), were strongly correlated with DNA methylation levels. These results strongly indicate that DNA methylation crucially orchestrates the metabolic synthesis of citric acid. In conclusion, our study revealed dynamic changes in DNA methylation during lemon fruit development, underscoring the significant role of DNA methylation in controlling the citric acid metabolic pathway.
柠檬酸赋予柠檬独特的风味,这影响着它们的感官特性和市场价值。然而,柠檬果实生长过程中柠檬酸积累的复杂过程仍未完全被理解。在这里,我们完成了‘香水’柠檬品种的染色体水平基因组组装,跨越九条染色体,长度为364.85 Mb。该组装揭示了27945个基因和51.37%的重复序列,追溯到285万年前与枸橼的分化。对不同发育阶段柠檬果实的DNA甲基化组分析揭示了DNA甲基化的显著变化。我们观察到CG和CHG甲基化减少,但CHH甲基化增加。值得注意的是,RdDM途径相关基因的表达随着果实发育而增加,表明与CHH甲基化升高有关,这可能受经典RdDM途径影响。此外,我们观察到启动子内CHH DNA甲基化升高显著影响关键基因的表达,对柠檬酸积累等重要生物学过程至关重要。特别是,调节三羧酸循环的关键基因()在果实发育过程中显著上调,同时其启动子区域的CHH甲基化增加。其他与柠檬酸积累相关的重要基因,如MYB转录因子()和(),与DNA甲基化水平密切相关。这些结果有力地表明DNA甲基化在柠檬酸的代谢合成中起着关键作用。总之,我们的研究揭示了柠檬果实发育过程中DNA甲基化的动态变化,强调了DNA甲基化在控制柠檬酸代谢途径中的重要作用。
