Iyer Vidya V, Sriram Ganesh, Fulton D Bruce, Zhou Ruilian, Westgate Mark E, Shanks Jacqueline V
Department of Chemical and Biological Engineering, 3031 Sweeney Hall, Iowa State University, Ames, IA 50011, USA.
Plant Cell Environ. 2008 Apr;31(4):506-17. doi: 10.1111/j.1365-3040.2008.01781.x. Epub 2008 Jan 9.
Metabolic flux maps developed from 13C metabolic flux analysis (13C MFA) are effective tools for assessing the response of biological systems to genetic or environmental perturbations, and for identifying possible metabolic engineering targets. Experimental treatments were designed to distinguish between temperature effects prior to, and during incubation in vitro, on primary metabolism in developing soybeans. Biomass accumulation increased with temperature as did carbon partitioning into lipids. The flux through the plastidic oxidative pentose phosphate pathway (pgl(P)) relative to sucrose intake remained fairly constant [ approximately 56% (+/-24%)] when cotyledons were transferred from an optimum growth temperature to varying temperatures in in vitro culture, signifying a rigid node under these conditions. However, pgl(P) flux ranged from 57 to 77% of sucrose intake when growth temperature in planta varied and were cultured in vitro at the same temperature (as the plant), indicating a flexible node for this case. The carbon flux through the anaplerotic reactions catalysed by plastidic malic enzyme (me(P)), cytosolic phosphoenolpyruvate (PEP) carboxylase and the malate (Mal) transporter from the cytosol to mitochondrion varied dramatically with temperature and had a direct influence on the carbon partitioning into protein and oil from the plastidic pyruvate (Pyr) pool. These results of the in vitro culture indicate that temperature during early stages of development has a dominant effect on establishing capacity for flux through certain components of central carbon metabolism.
通过13C代谢通量分析(13C MFA)绘制的代谢通量图是评估生物系统对基因或环境扰动的响应以及确定可能的代谢工程靶点的有效工具。实验处理旨在区分体外培养前和培养期间温度对发育中的大豆初级代谢的影响。生物量积累随温度升高而增加,碳分配到脂质中的情况也是如此。当子叶从最佳生长温度转移到体外培养的不同温度时,相对于蔗糖摄入量,通过质体氧化戊糖磷酸途径(pgl(P))的通量保持相当恒定[约56%(±24%)],这表明在这些条件下存在一个刚性节点。然而,当植株生长温度变化并在相同温度(与植株相同)下进行体外培养时,pgl(P)通量占蔗糖摄入量的比例在57%至77%之间,表明这种情况下存在一个灵活节点。通过质体苹果酸酶(me(P))、胞质磷酸烯醇丙酮酸(PEP)羧化酶以及从胞质溶胶到线粒体的苹果酸(Mal)转运体催化的回补反应的碳通量随温度变化显著,并且直接影响从质体丙酮酸(Pyr)库向蛋白质和油脂的碳分配。体外培养的这些结果表明,发育早期的温度对建立通过中心碳代谢某些组分的通量能力具有主导作用。