AraRoot - 拟南芥根系基因组尺度的综合代谢模型

Lohani Esterhuizen, Nicholas Ampimah, Marna Yandeau-Nelson, Basil J. Nikolau, Erin E Sparks, Rajib Saha
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摘要

拟南芥(Arabidopsis thaliana,简称 "拟南芥")是第一个对其基因组进行测序的植物,也是一个成熟的遗传模式植物系统。对拟南芥的研究使我们对植物的生理和生化本质有了更深入的了解。利用基因组尺度代谢模型(GEM)等方法,我们可以对生物体的新陈代谢进行计算研究。拟南芥根系是面对土壤中的压力条件并做出反应的器官,尽管它很受欢迎,但目前还没有一个 GEM 能够映射拟南芥根系的代谢活动。我们开发了拟南芥根系统的综合 GEM - AraRoot。最终模型包括 2,682 个反应、2,748 个代谢物和 1,310 个基因。通过分析模型中的代谢途径,发现了 158 个可能影响生物量生产的瓶颈基因,其中大部分与含磷和能量相关的途径有关。对组织特异性代谢重编程的进一步研究得出结论,根部皮层可能负责在长期暴露于高盐条件下的根系生长,而内皮层和表皮层则负责产生增加细胞壁生物合成的代谢物。研究发现,表皮在暴露于高浓度盐时调节新陈代谢的能力很差。总之,AraRoot 是第一个能准确捕捉拟南芥根系中各组织的综合生物量形成和应激反应的 GEM。
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AraRoot - A Comprehensive Genome-Scale Metabolic Model for the Arabidopsis Root System.
Being the first plant to have its genome sequenced, Arabidopsis thaliana (Arabidopsis) is a well-established genetic model plant system. Studies on Arabidopsis have provided major insights into plants' physiological and biochemical nature. Methods that allow us to computationally study the metabolism of organisms include the use of genome-scale metabolic models (GEMs). Despite its popularity, currently no GEM maps the metabolic activity in the roots of Arabidopsis, which is the organ that faces and responds to stress conditions in the soil. We've developed a comprehensive GEM of the Arabidopsis root system - AraRoot. The final model includes 2,682 reactions, 2,748 metabolites, and 1,310 genes. Analyzing the metabolic pathways in the model identified 158 possible bottleneck genes that impact biomass production, most of which were found to be related to phosphorous-containing- and energy-related pathways. Further insights into tissue-specific metabolic reprogramming conclude that the cortex layer in the roots is likely responsible for root growth under prolonged exposure to high salt conditions, while the endodermis and epidermis are responsible for producing metabolites responsible for increased cell wall biosynthesis. The epidermis was found to have a very poor ability to regulate its metabolism during exposure to high salt concentrations. Overall, AraRoot is the first GEM that accurately captures the comprehensive biomass formation and stress responses of the tissues in the Arabidopsis root system.
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