Himeoka Yusuke, Kaneko Kunihiko
Department of Basic Science, University of Tokyo, Komaba, Meguro-ku, Tokyo 153-8902, Japan.
Phys Biol. 2016 Apr 5;13(2):026002. doi: 10.1088/1478-3975/13/2/026002.
Cells generally convert nutrient resources to products via energy transduction. Accordingly, the thermodynamic efficiency of this conversion process is one of the most essential characteristics of living organisms. However, although these processes occur under conditions of dynamic metabolism, most studies of cellular thermodynamic efficiency have been restricted to examining steady states; thus, the relevance of dynamics to this efficiency has not yet been elucidated. Here, we develop a simple model of metabolic reactions with anabolism-catabolism coupling catalyzed by enzymes. Through application of external oscillation in the enzyme abundances, the thermodynamic efficiency of metabolism was found to be improved. This result is in strong contrast with that observed in the oscillatory input, in which the efficiency always decreased with oscillation. This improvement was effectively achieved by separating the anabolic and catabolic reactions, which tend to disequilibrate each other, and taking advantage of the temporal oscillations so that each of the antagonistic reactions could progress near equilibrium. In this case, anti-phase oscillation between the reaction flux and chemical affinity through oscillation of enzyme abundances is essential. This improvement was also confirmed in a model capable of generating autonomous oscillations in enzyme abundances. Finally, the possible relevance of the improvement in thermodynamic efficiency is discussed with respect to the potential for manipulation of metabolic oscillations in microorganisms.
细胞通常通过能量转导将营养资源转化为产物。因此,这种转化过程的热力学效率是生物体最基本的特征之一。然而,尽管这些过程发生在动态代谢条件下,但大多数关于细胞热力学效率的研究都局限于稳态研究;因此,动力学与这种效率的相关性尚未阐明。在这里,我们构建了一个由酶催化的合成代谢 - 分解代谢偶联的简单代谢反应模型。通过对酶丰度施加外部振荡,发现代谢的热力学效率得到了提高。这一结果与在振荡输入中观察到的结果形成了强烈对比,在振荡输入中效率总是随着振荡而降低。通过分离往往相互失衡的合成代谢和分解代谢反应,并利用时间振荡,使得每个拮抗反应都能在接近平衡的状态下进行,从而有效地实现了这种提高。在这种情况下,通过酶丰度的振荡实现反应通量和化学亲和力之间的反相振荡是至关重要的。在一个能够在酶丰度中产生自主振荡的模型中也证实了这种提高。最后,就微生物中代谢振荡的操纵潜力而言,讨论了热力学效率提高的可能相关性。