Tan H B, Swann P F, Chance E M
Department of Biochemistry and Molecular Biology, University College London, United Kingdom.
Biochemistry. 1994 May 3;33(17):5335-46. doi: 10.1021/bi00183a042.
Production by N-nitroso compounds of O6-alkylguanine (O6-alkylG) in DNA directs the misincorporation of thymine during DNA replication, leading to G:C to A:T transition mutations, despite the fact that DNA containing O6-alkylG:T base pairs is less stable than that containing O6-alkylG:C pairs. We have examined the kinetics of incorporation by Klenow fragment (KF) of Escherichia coli DNA polymerase I of thymine (T) and of cytosine (C) opposite O6-MeG in the template DNA strand. Both T and C were incorporated opposite O6-MeG much slower than nucleotides forming regular A:T or G:C base pairs. Using various concentrations of dTTP, dCTP, or their phosphorothioate (Sp)-dNTP alpha S analogues, or a mixture of dTTP and dCTP, the progress of incorporation of a single nucleotide in a single catalytic cycle of a preformed KF-DNA complex was measured (pre-steady-state kinetics). The results were consistent with the kinetic scheme (Kuchta, R. D., Benkovic, P., & Benkovic, S. J. (1988) Biochemistry 27, 6716-6725): (1) binding of dNTP to polymerase-DNA; (2) conformational change in polymerase; (3) formation of phosphodiester between the dNTP and the 3'-OH of the primer; (4) conformational change of polymerase; (5) release of pyrophosphate. The results were analyzed mathematically to identify the steps at which the rate constants differ significantly between the incorporation of T and C. The only significant difference was the 5-fold difference in the rates of formation of the phosphodiester bond (for dTTP, kforward = 3.9 s-1 and kback = 1.9 s-1; for dCTP, kforward = 0.7 s-1 and kback = 0.9 s-1). These pre-steady-state progress curves were biphasic with a rapid initial burst followed by an apparently steady-state rise. Deconvolution of these curves gave direct evidence for the importance of the conformational change after polymerization by showing that the curves represented the sum of the rapid accumulation of the product of step 3 followed by the slow conversion of that to the product of step 5 (because of the rapidity of the release of pyrophosphate there was no significant accumulation of the product of step 4). The equilibrium constants for each step suggest that the greatest change in the Gibbs free energy occurs at the conformational change after polymerization and that while the formation of the phosphodiester bond to T is slightly exothermic, that to C is slightly endothermic.(ABSTRACT TRUNCATED AT 400 WORDS)
N-亚硝基化合物可使DNA中的O6-烷基鸟嘌呤(O6-alkylG)发生烷基化,这会在DNA复制过程中导致胸腺嘧啶错配掺入,进而引发G:C到A:T的转换突变,尽管含有O6-烷基G:T碱基对的DNA比含有O6-烷基G:C碱基对的DNA稳定性更低。我们研究了大肠杆菌DNA聚合酶I的Klenow片段(KF)将胸腺嘧啶(T)和胞嘧啶(C)掺入模板DNA链中与O6-甲基鸟嘌呤(O6-MeG)相对位置的动力学过程。与形成常规A:T或G:C碱基对的核苷酸相比,T和C掺入到与O6-MeG相对的位置都要慢得多。使用不同浓度的dTTP、dCTP或它们的硫代磷酸酯(Sp)-dNTPαS类似物,或dTTP和dCTP的混合物,测量了预先形成的KF-DNA复合物在单个催化循环中单个核苷酸掺入的进程(预稳态动力学)。结果与动力学方案一致(库奇塔,R.D.,本科维奇,P.,&本科维奇,S.J.(1988年)《生物化学》27卷,6716 - 6725页):(1)dNTP与聚合酶-DNA结合;(2)聚合酶构象变化;(3)dNTP与引物的3'-OH之间形成磷酸二酯键;(4)聚合酶构象变化;(5)焦磷酸释放。对结果进行数学分析,以确定T和C掺入过程中速率常数有显著差异的步骤。唯一显著的差异是磷酸二酯键形成速率的5倍差异(对于dTTP,正向速率常数kforward = 3.9 s-1,反向速率常数kback =
