Carel Fijen, Cristian Chavira, Khadijeh Alnajjar, Danielle L. Sawyer, Joann B. Sweasy
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引用次数: 0
Abstract
DNA polymerase β (Pol β) fills single nucleotide gaps during base excision repair. Deficiencies in Pol β can lead to increased mutagenesis and genomic instability in the cell, resulting in cancer. Our laboratory has previously shown that the I260 M somatic mutation of Pol β, which was first identified in prostate cancer, has reduced nucleotide discrimination in a sequence context-dependent manner. I260 M incorporates the incorrect G opposite A in this context more readily than WT. To identify the molecular mechanism of the reduced fidelity of I260M, we studied incorporation using single turnover kinetics and the nature and rates of conformational changes using steady-state fluorescence and Förster resonance energy transfer (FRET). Our data indicate that the I260 M mutation affects the fingers region of rat Pol β by creating a “collapsed” state in both the open (in the absence of nucleotide) and closed (prior to chemistry) states. I260 M is a temperature-sensitive mutator and binds nucleotides tighter than the WT protein, resulting in reduced fidelity compared to the WT. Additionally, we have generated a kinetic model of WT and I260 M using FRET and single turnover data, which demonstrates that I260 M precatalytic conformation changes differ compared to the WT as it is missing a precatalytic noncovalent step. Taken together, these results suggest that the collapsed state of I260 M may decrease its ability for nucleotide discrimination, illustrating the importance of the “fingers closing” conformational change for polymerase fidelity and accurate DNA synthesis.
DNA 聚合酶 β(Pol β)可在碱基切除修复过程中填补单核苷酸缺口。Pol β的缺陷会导致细胞内突变和基因组不稳定性增加,从而引发癌症。我们的实验室先前已经证明,首次在前列腺癌中发现的 Pol β I260 M 体细胞突变会以序列上下文依赖的方式降低核苷酸的识别能力。在这种情况下,I260 M 比 WT 更容易将不正确的 G 与 A 相反结合。为了确定 I260M 保真度降低的分子机制,我们利用单次周转动力学研究了掺入情况,并利用稳态荧光和佛斯特共振能量转移(FRET)研究了构象变化的性质和速率。我们的数据表明,I260 M 突变会影响大鼠 Pol β 的手指区,在开放(无核苷酸时)和封闭(化学反应前)状态下产生一种 "塌陷 "状态。I260 M是一种温度敏感突变体,与核苷酸的结合比WT蛋白更紧密,导致保真度比WT蛋白低。此外,我们还利用 FRET 和单次周转数据生成了 WT 和 I260 M 的动力学模型,结果表明 I260 M 的前催化构象变化与 WT 蛋白不同,因为它缺少一个前催化非共价步骤。综上所述,这些结果表明,I260 M 的塌缩状态可能会降低它对核苷酸的辨别能力,这说明了 "手指闭合 "构象变化对聚合酶保真度和准确 DNA 合成的重要性。