Robert C. Monsen, T. Michael Sabo, Robert D. Gray, Jesse B. Hopkins, Jonathan B. Chaires
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引用次数: 0
摘要
本文报告的时间分辨小角 X 射线实验(TR-SAXS)捕获并量化了之前未知的未折叠寡核苷酸的快速塌缩,这是杂交 1 号和杂交 2 号端粒 G-四重结构 G4 折叠的早期步骤。由 pH 值跃迁引发的快速塌缩以回旋半径从 20.6 Å 到 12.6 Å 的指数下降为特征。其他手工混合 pH 值跳跃动力学研究表明,塌缩后会出现较慢的动力学步骤。通过 SAXS 研究和其他生物物理工具对平衡状态下的折叠和展开状态进行了进一步的表征,结果表明 G4 在碱性 pH 值下完全展开,而不是像通常所说的那样在氯化锂溶液中完全展开。SAXS 组合优化法(EOM)分析揭示了折叠状态的模型,即具有各种瞬时发夹结构的柔性寡核苷酸链的动态组合。这些结果表明了一种 G4 折叠路径,其中的快速塌缩类似于蛋白质中的熔融球形成,随后在塌缩颗粒内进行封闭的构象搜索,以形成最终在稳定折叠形式中发现的原生接触。
Early Events in G-quadruplex Folding Captured by Time-Resolved Small-Angle X-Ray Scattering
Time-resolved small-angle X-ray experiments (TR-SAXS) are reported here that capture and quantify a previously unknown rapid collapse of the unfolded oligonucleotide as an early step in G4 folding of hybrid 1 and hybrid 2 telomeric G-quadruplex structures. The rapid collapse, initiated by a pH jump, is characterized by an exponential decrease in the radius of gyration from 20.6 to 12.6 Å. The collapse is monophasic and is complete in less than 600 ms. Additional hand-mixing pH-jump kinetic studies show that slower kinetic steps follow the collapse. The folded and unfolded states at equilibrium were further characterized by SAXS studies and other biophysical tools, to show that G4 unfolding was complete at alkaline pH, but not in LiCl solution as is often claimed. The SAXS Ensemble Optimization Method (EOM) analysis reveals models of the unfolded state as a dynamic ensemble of flexible oligonucleotide chains with a variety of transient hairpin structures. These results suggest a G4 folding pathway in which a rapid collapse, analogous to molten globule formation seen in proteins, is followed by a confined conformational search within the collapsed particle to form the native contacts ultimately found in the stable folded form.