An approach to learn regulation to maximize growth and entropy production rates in metabolism

Ethan King, Jesse T. Holzer, J. North, W. Cannon
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Abstract

Elucidating cell regulation remains a challenging task due to the complexity of metabolism and the difficulty of experimental measurements. Here we present a method for prediction of cell regulation to maximize cell growth rate while maintaining the solvent capacity of the cell. Prediction is formulated as an optimization problem using a thermodynamic framework that can leverage experimental data. We develop a formulation and variable initialization procedure that allows for computing solutions of the optimization with an interior point method. The approach is applied to photoheterotrophic growth of Rhodospirilium rubrum using ethanol as a carbon source, which has applications to biosynthesis of ethylene production. Growth is captured as the rate of synthesis of amino acids into proteins, and synthesis of nucleotide triphoshaptes into RNA and DNA. The method predicts regulation that produces a high rate of protein and RNA synthesis while DNA synthesis is reduced close to zero in agreement with production of DNA being turned off for much of the cell cycle.
一种学习调节的方法,以最大限度地提高新陈代谢的生长和熵产率
由于代谢的复杂性和实验测量的难度,阐明细胞调控仍然是一项具有挑战性的任务。在这里,我们提出了一种预测细胞调节的方法,以最大限度地提高细胞的生长速度,同时保持细胞的溶剂容量。预测是制定为一个优化问题,使用热力学框架,可以利用实验数据。我们开发了一个公式和变量初始化过程,允许用内点法计算优化的解。该方法应用于以乙醇为碳源的红红螺旋藻的光异养生长,在乙烯生产的生物合成中具有应用价值。生长被捕获为氨基酸合成蛋白质的速率,以及核苷酸三磷酸体合成RNA和DNA的速率。该方法预测了产生高蛋白质和RNA合成率的调节,而DNA合成减少到接近于零,这与DNA生产在细胞周期的大部分时间被关闭一致。
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