代谢无用循环及其功能:能量与控制的系统分析。

H Qian, D A Beard
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引用次数: 75

摘要

长期以来,人们一直假设细胞代谢中的无用循环参与了生化途径的调节。在Newsholme和Crabtree的工作之后,基于开放系统热力学和代谢控制分析的定量理论被发展出来。结果表明,中间代谢物浓度相对于稳态通量变化的化学计量敏感性是由中间产物的有效平衡常数决定的,平衡可以通过无效循环来调节。有效平衡常数的移动方向取决于无效循环的运行方向。高化学计量灵敏度对应于中间浓度对通过途径的净流量的超灵敏度;低化学计量灵敏度对应于浓度相对于通量变化的超稳健性。这两种情况都可能在代谢调节中发挥重要作用。无效循环通过消耗能量积极地改变有效平衡;有效平衡和灵敏度的变化幅度是无效循环所消耗的能量的函数。这种提出的由无效循环控制的机制与生物合成中的动态校对非常相似。该系统的灵敏度也与中间代谢物的浓度波动率密切相关。讨论了细胞生化调节中两种主要机制的不同作用的可能性,即通过无效循环的可逆化学修饰和通过大分子结合的转移平衡。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Metabolic futile cycles and their functions: a systems analysis of energy and control.

It has long been hypothesised that futile cycles in cellular metabolism are involved in the regulation of biochemical pathways. Following the work of Newsholme and Crabtree, a quantitative theory was developed for this idea based on open-system thermodynamics and metabolic control analysis. It is shown that the stoichiometric sensitivity of an intermediary metabolite concentration with respect to changes in steady-state flux is governed by the effective equilibrium constant of the intermediate formation, and the equilibrium can be regulated by a futile cycle. The direction of the shift in the effective equilibrium constant depends on the direction of operation of the futile cycle. High stoichiometric sensitivity corresponds to ultrasensitivity of an intermediate concentration to net flow through a pathway; low stoichiometric sensitivity corresponds to super-robustness of concentration with respect to changes in flux. Both cases potentially play important roles in metabolic regulation. Futile cycles actively shift the effective equilibrium by expending energy; the magnitude of changes in effective equilibria and sensitivities is a function of the amount of energy used by a futile cycle. This proposed mechanism for control by futile cycles works remarkably similar to kinetic proofreading in biosynthesis. The sensitivity of the system is also intimately related to the rate of concentration fluctuations of intermediate metabolites. The possibility of different roles for the two major mechanisms within cellular biochemical regulation, namely reversible chemical modifications via futile cycles and shifting equilibrium by macromolecular binding, are discussed.

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