拟南芥糖代谢的改变影响渗出、免疫反应和植物与微生物的相互作用

Alexandra Siffert, Joelle Schlaepfer Sasse
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摘要

糖类对植物的生长、发育和环境互动至关重要。它们作为植物的营养物质、相关有益微生物和病原微生物以及免疫信号化合物具有多重作用。我们通过分析糖代谢和转运体突变株,确定了这些功能之间的相互联系。我们发现,在这些品系中,与野生型相比,根衍生化合物(渗出物)不仅在碳水化合物方面发生了显著变化,而且在脂质、有机酸和防御化合物方面也发生了显著变化。对糖渗出量的定量分析显示,白天比夜间释放更多的碳,突变株系的糖渗出量发生了变化,而淀粉合成缺陷株系pgm1的渗出模式则相反,夜间渗出量增加。渗出物和组织中的糖含量并不相关,这表明糖的渗出模式是受控的。糖分水平的改变会产生功能性后果:突变株系对病原体丁香假单胞菌(Pseudomonas syringae)的抗性增强,根上的微生物数量也会改变。突变株的昼夜渗出物会影响单一微生物的生长,如枯草芽孢杆菌无法生长。外源糖以依赖植物发育的方式改变活性氧的产生,在9天和14天时产生相反的影响。RNAseq 实验揭示了可能参与这种调控的候选基因。我们的数据突显了糖代谢与其他代谢物途径之间错综复杂的联系。改变碳代谢中心的单个基因会深刻改变植物的免疫反应和植物与微生物的相互作用。
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Altered Arabidopsis thaliana sugar metabolism affects exudation, immune responses, and plant-microbe interactions
Sugars are critical for plant growth, development, and environmental interactions. They have multiple roles as nutrients for plants, associated beneficial and pathogenic microbes, and as signaling compounds for immunity. We characterize the interconnectedness of these functions by analyzing sugar metabolism and transporter mutant lines. We find that in these lines, root-derived compounds, exudates, are significantly altered in comparison with wild-type not only for carbohydrates, but also for lipids, organic acids, and defense compounds. Quantification of sugar exudation reveals more carbon release during the day than at night, altered sugar exudation in mutant lines, and an opposite exudation pattern with elevated exudation at night for pgm1, a line deficient in starch synthesis. Sugar levels in exudates and tissues did not correlate, suggesting a controlled mode of exudation for sugars. Altered sugar levels have functional consequences: mutant lines exhibit increased resistance against the pathogen Pseudomonas syringae and harbor altered numbers of microbes on roots. Day- and nighttime exudates of mutant lines impact the growth of single microbes such as an inability to grow for Bacillus subtilis. Exogenous sugar alters the production of reactive oxygen species in a plant development-dependent manner with opposite effects at 9 days and 14 days. An RNAseq experiment reveals candidate genes potentially involved in this regulation. Our data highlight that sugar metabolism is intricately linked with other metabolite pathways. Alteration of single genes in central carbon metabolism profoundly alters plant immune responses and plant-microbe interactions.
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