Cady Field, Qian Hong
Department of Applied Mathematics, University of Washington, Seattle, 98195, USA.
Phys Biol. 2009 Jun 5;6(3):036011. doi: 10.1088/1478-3975/6/3/036011.
Replication inside a living cell, carried out by DNA polymerase, has an error rate far below that predicted by equilibrium thermodynamics from the affinities between nucleotides and a polymerase complex. The high fidelity is achieved through several distinctly different molecular mechanisms that include a nucleotide insertion checkpoint and 3'-5' exonuclease activity. The checkpoint mechanism has recently been articulated as a new paradigm for high specificity. A rigorous thermodynamic analysis of the bare DNA polymerization reaction, i.e., in the absence of exonuclease activity and proofreading, is developed in this paper. The analysis (a) reveals the important role of nonequilibrium steady-state (NESS) flux that drives high fidelity, (b) quantifies the error rate of the polymerization reaction as a function of free energy input through sustained non-equilibrium between chemical species, (c) bridges the 'thermodynamic' and 'kinetic' views of specificity and (d) generalizes the theory of kinetic checkpoints and provides it with a sound thermodynamic basis. The underlying mechanism again calls attention to the energy expenditure in heightened biomolecular specificity, a concept first developed by Hopfield and Ninio in the mid-1970s. The mechanism discussed in the present paper is not limited to DNA replication alone; it may be applicable to other biochemical systems.
由DNA聚合酶在活细胞内进行的复制,其错误率远低于根据核苷酸与聚合酶复合物之间的亲和力通过平衡热力学预测的错误率。高保真度是通过几种截然不同的分子机制实现的,这些机制包括核苷酸插入检查点和3'-5'核酸外切酶活性。检查点机制最近已被阐明为一种高特异性的新范式。本文对单纯的DNA聚合反应(即不存在核酸外切酶活性和校对的情况下)进行了严格的热力学分析。该分析(a)揭示了驱动高保真度的非平衡稳态(NESS)通量的重要作用,(b)将聚合反应的错误率量化为化学物种之间持续非平衡导致的自由能输入的函数,(c)弥合了特异性的“热力学”和“动力学”观点,(d)推广了动力学检查点理论并为其提供了坚实的热力学基础。其潜在机制再次引起人们对提高生物分子特异性过程中能量消耗的关注,这一概念最早由霍普菲尔德和尼尼奥在20世纪70年代中期提出。本文讨论的机制不仅限于DNA复制;它可能适用于其他生化系统。
