Trends in photochemistry & photobiology最新文献

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Site-specific investigation of DNA Holliday Junction dynamics and structure with 6-Methylisoxanthopterin, a fluorescent guanine analog. 利用荧光鸟嘌呤类似物 6-甲基异黄蝶呤对 DNA 霍利迪接合点动力学和结构进行特定位点研究。

Trends in photochemistry & photobiology

Pub Date : 2023-01-01

Zane Lombardo, Ishita Mukerji

DNA Holliday Junction (HJ) formation and resolution is requisite for maintaining genomic stability in processes such as replication fork reversal and double-strand break repair. If HJs are not resolved, chromosome disjunction and aneuploidy result, hallmarks of tumor cells. To understand the structural features that lead to processing of these four-stranded joint molecule structures, we seek to identify structural and dynamic features unique to the central junction core. We incorporated the fluorescent guanine analog 6-methylisoxanthopterin (6-MI) at ten different locations throughout a model HJ structure to obtain site-specific information regarding the structure and dynamics of bases relative to those in a comparable sequence context in duplex DNA. These comparisons were accomplished through measuring fluorescence lifetime, relative brightness, fluorescence anisotropy, and quenching assays. These time-resolved and steady-state fluorescence measurements demonstrate that the structural distortions imposed by strand crossing result in increased solvent exposure, less stacking of bases and greater extrahelical nature of bases within the junction core. The 6-MI base analogs in the junction reflect these structural changes through an increase in intensity relative to those in the duplex. Molecular dynamics simulations performed using a model HJ indicate that the primary sources of deformation are in the shift and twist parameters of the bases at the central junction step. These results suggest that junction-binding proteins may use the unique structure and dynamics of the bases at the core for recognition.

在复制叉逆转和双链断裂修复等过程中，DNA Holliday Junction（HJ）的形成和解析是维持基因组稳定性的必要条件。如果 HJ 无法解决，就会导致染色体脱节和非整倍体，这也是肿瘤细胞的特征。为了了解导致处理这些四链连接分子结构的结构特征，我们试图找出中央连接核心特有的结构和动态特征。我们在整个模型 HJ 结构的十个不同位置加入了荧光鸟嘌呤类似物 6-甲基异黄蝶呤（6-MI），以获得有关碱基结构和动态的特定位点信息，并与双链 DNA 中类似序列上下文中的碱基进行比较。这些比较是通过测量荧光寿命、相对亮度、荧光各向异性和淬灭试验完成的。这些时间分辨和稳态荧光测量结果表明，链交叉造成的结构扭曲导致溶剂暴露增加、碱基堆叠减少以及连接核心内碱基的螺旋外性质增强。交界处的 6-MI 碱基类似物通过相对于双链中碱基类似物的强度增加来反映这些结构变化。使用 HJ 模型进行的分子动力学模拟表明，变形的主要来源是连接中心步骤碱基的移位和扭曲参数。这些结果表明，连接结合蛋白可能会利用核心碱基的独特结构和动态来进行识别。

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