生物化学网络中的有限时间热力学耦合。

Systems and Synthetic Biology Pub Date : 2014-03-01 Epub Date: 2014-01-11 DOI:10.1007/s11693-014-9130-1
Anjan Kr Dasgupta
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引用次数: 2

摘要

本文描述了生化或代谢网络中的一些热力学约束和关系,为熵焓补偿提供了依据。宏观力和通量的传统定义导致了一个悖论,即化学驱动过程不存在正效率。利用局部平衡方程推导出宏观力的适当定义,解决了这一矛盾。熵焓补偿,其热力学基础到目前为止还不清楚,也遵循。该方法提供了反应途径如何耦合的说明,途径对之间的耦合强度取决于它们各自的焓的乘积。在定义耦合时,共同化学中间体的强制性作用变得不必要;这种无中间耦合是代谢能量转导的关键特征。重新定义的通量和力也可以用来解释耦合网络的表面体积比依赖性。最后,Bergman生态地理规则的热力学原理,即大型动物避免应力的能力降低,遵循耦合系数的广义表达式。较高的表面体积比表明,使生物体抵抗外部扰动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Finite time thermodynamic coupling in a biochemical network.

The paper describes some thermodynamic constrains and relations in biochemical or metabolic network and provides a basis for entropy enthalpy compensation. Conventional definition of macroscopic forces and fluxes leads to a paradox namely, non-existence of positive efficiency of a chemically driven process. This paradox is resolved by deriving an appropriate definition of macroscopic force using the local balance equations. Entropy enthalpy compensation, whose thermodynamic basis is so far unclear, also follows. The method provides an account of how reactive pathways are coupled, the strength of coupling between a pathway pair depending on the product of their respective enthalpies. The obligatory role of the presence of a common chemical intermediate in defining coupling becomes unnecessary; such intermediate-free coupling being a key feature of metabolic energy transduction. The redefined flux and force can also be exploited to explain surface to volume ratio dependence of coupled networks. Lastly, the thermodynamic rationale for the Bergman's eco-geographic rule, namely the reduced ability of larger animals to avoid stress follows from the generalized expression for coupling coefficients. Higher surface to volume ratio is shown to make the organism resistant to external perturbations.

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