A kinetic model of the branch-point between the methionine and threonine biosynthesis pathways in Arabidopsis thaliana.

Gilles Curien, Stéphane Ravanel, Renaud Dumas
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引用次数: 69

Abstract

This work proposes a model of the metabolic branch-point between the methionine and threonine biosynthesis pathways in Arabidopsis thaliana which involves kinetic competition for phosphohomoserine between the allosteric enzyme threonine synthase and the two-substrate enzyme cystathionine gamma-synthase. Threonine synthase is activated by S-adenosylmethionine and inhibited by AMP. Cystathionine gamma-synthase condenses phosphohomoserine to cysteine via a ping-pong mechanism. Reactions are irreversible and inhibited by inorganic phosphate. The modelling procedure included an examination of the kinetic links, the determination of the operating conditions in chloroplasts and the establishment of a computer model using the enzyme rate equations. To test the model, the branch-point was reconstituted with purified enzymes. The computer model showed a partial agreement with the in vitro results. The model was subsequently improved and was then found consistent with flux partition in vitro and in vivo. Under near physiological conditions, S-adenosylmethionine, but not AMP, modulates the partition of a steady-state flux of phosphohomoserine. The computer model indicates a high sensitivity of cystathionine flux to enzyme and S-adenosylmethionine concentrations. Cystathionine flux is sensitive to modulation of threonine flux whereas the reverse is not true. The cystathionine gamma-synthase kinetic mechanism favours a low sensitivity of the fluxes to cysteine. Though sensitivity to inorganic phosphate is low, its concentration conditions the dynamics of the system. Threonine synthase and cystathionine gamma-synthase display similar kinetic efficiencies in the metabolic context considered and are first-order for the phosphohomoserine substrate. Under these conditions outflows are coordinated.

拟南芥蛋氨酸和苏氨酸生物合成途径分支点的动力学模型。
本研究提出了拟南芥中甲硫氨酸和苏氨酸生物合成途径之间的代谢分支点模型,该模型涉及变构酶苏氨酸合酶和双底物酶半胱硫氨酸γ合酶对磷高丝氨酸的动力学竞争。苏氨酸合成酶由s -腺苷甲硫氨酸激活,AMP抑制。半胱甘氨酸-合成酶通过乒乓机制将磷酸高丝氨酸凝聚成半胱氨酸。这些反应是不可逆的,并且受到无机磷酸盐的抑制。建模过程包括对动力学环节的检查,叶绿体中操作条件的确定以及使用酶速率方程建立计算机模型。为了验证模型的有效性,用纯化酶重构了分支点。计算机模型与体外实验结果部分吻合。随后对模型进行了改进,发现模型在体内和体外均符合通量分配。在接近生理条件下,s -腺苷蛋氨酸而不是AMP调节磷高丝氨酸稳态通量的分配。计算机模型表明,半胱硫氨酸通量对酶和s -腺苷甲硫氨酸浓度有很高的敏感性。胱氨酸通量对苏氨酸通量的调节敏感,反之则不敏感。半胱甘氨酸-合成酶的动力学机制有利于对半胱氨酸通量的低敏感性。虽然对无机磷酸盐的敏感性较低,但其浓度决定了体系的动力学。苏氨酸合成酶和半胱硫氨酸-合成酶在代谢环境中表现出相似的动力学效率,并且是磷同源丝氨酸底物的一级酶。在这些条件下,流出是协调的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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