Department of Chemistry, Umeå University, 901 87, Umeå, Sweden.
Department of Medical Biochemistry and Biophysics, Umeå University, 901 87, Umeå, Sweden.
Chemistry. 2018 Jun 4;24(31):7926-7938. doi: 10.1002/chem.201800078. Epub 2018 May 9.
Small molecules that target G-quadruplex (G4) DNA structures are not only valuable to study G4 biology but also for their potential as therapeutics. This work centers around how different design features of small molecules can affect the interactions with G4 DNA structures, exemplified by the development of synthetic methods to bis-indole scaffolds. Our synthesized series of bis-indole scaffolds are structurally very similar but differ greatly in the flexibility of their core structures. The flexibility of the molecules proved to be an advantage compared to locking the compounds in the presumed bioactive G4 conformation. The flexible derivatives demonstrated similar or even improved G4 binding and stabilization in several orthogonal assays even though their entropic penalty of binding is higher. In addition, molecular dynamics simulations with the c-MYC G4 structure showed that the flexible compounds adapt better to the surrounding. This was reflected by an increased number of both stacking and polar interactions with both the residues in the G4 DNA structure and the DNA residues just upstream of the G4 structure.
小分子靶向 G-四链体 (G4) DNA 结构不仅对研究 G4 生物学具有重要价值,而且具有作为治疗剂的潜力。这项工作主要集中在小分子的不同设计特征如何影响与 G4 DNA 结构的相互作用,这可以通过开发双吲哚支架的合成方法来举例说明。我们合成的一系列双吲哚支架在结构上非常相似,但它们的核心结构的柔韧性却有很大的不同。与将化合物锁定在假定的生物活性 G4 构象相比,分子的柔韧性被证明是一个优势。尽管这些化合物的结合熵罚较高,但具有柔韧性的衍生物在几个正交测定中表现出相似甚至更好的 G4 结合和稳定作用。此外,与 c-MYC G4 结构的分子动力学模拟表明,柔性化合物能够更好地适应周围环境。这反映在与 G4 DNA 结构中的残基以及 G4 结构上游的 DNA 残基的堆积和极性相互作用的数量都增加了。
