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酶-酶相互作用对稳态酶动力学影响的理论研究

Theoretical study of the effect of enzyme-enzyme interactions on steady-state enzyme kinetics.

作者信息

Hill T L

出版信息

Proc Natl Acad Sci U S A. 1977 Sep;74(9):3632-6. doi: 10.1073/pnas.74.9.3632.

DOI:10.1073/pnas.74.9.3632
PMID:269419
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC431669/
Abstract

Equilibrium statistical mechanics is much concerned with problems involving intermolecularinteractions, either in lattices or in pure fluids or solutions. The possibility of enzyme-enzyme interactions suggests that the same problems might be studied profitably at steady state as well as at equilibrium. In the systems we consider, each of the identical enzyme molecules of the system undergoes steady-state stochastic cycling among states i equal 1,....,n. But the molecules do not cycle independently. Two neghboring molecules, in states i and j, interact with a free energy wij (a function of the distance r in the solution case). The instantaneous transition probabilities between states for a given molecule will depend on the instantaneous interactions between the molecule in question and its neighbors. The primary question of interest is how the enzyme flux is influenced by the interactions. The general problem is outlined here and some simple special cases are treated. The discussion will be continued in a following paper [Hill, T. L. (1977) Proc. Natl. Acad. Sci. USA 74, in press]

摘要

平衡统计力学非常关注涉及晶格、纯流体或溶液中分子间相互作用的问题。酶 - 酶相互作用的可能性表明,在稳态以及平衡态下,同样的问题可能值得研究。在我们所考虑的系统中,系统中每个相同的酶分子在状态(i = 1,\cdots,n)之间进行稳态随机循环。但分子并非独立循环。处于状态(i)和(j)的两个相邻分子以自由能(w_{ij})(在溶液情况下是距离(r)的函数)相互作用。给定分子状态之间的瞬时转变概率将取决于该分子与其邻居之间的瞬时相互作用。感兴趣的主要问题是相互作用如何影响酶通量。这里概述了一般问题,并处理了一些简单的特殊情况。后续论文[希尔,T. L.(1977年)《美国国家科学院院刊》74卷,即将发表]将继续进行讨论。

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