Yu Han, Li Dong, Lu-Yao Zhu, Chun-Rui Hu, Hang Li, Yang Zhang, Chao Zhang, Yao Zhang, Zhen-Chao Dong
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引用次数: 0
摘要
解析 DNA 等柔性生物大分子的序列和结构对于了解其生物机制和功能至关重要。传统的结构生物学方法对于分析小分子和无序生物大分子,尤其是那些难以标记或结晶的生物大分子仍然具有挑战性。最近开发的单分子尖端增强拉曼光谱(TERS)为识别单个 DNA 链中的核碱基提供了一种无标记方法。然而,由于微弱的拉曼信号和 DNA 分子的灵活性所带来的挑战,以单碱基分辨率进行空间和光谱测序的清晰演示仍然难以实现。在此,我们报告了为此目的进行的原理验证,即在实际空间中通过光谱解析人工设计的短单链 DNA 分子中的单个核碱基及其序列结构。这一突破是通过为这种热不稳定的柔性生物分子开发亚纳米分辨低温 TERS 方法实现的。对单个核碱基的进一步 TERS 图谱提供了有关分子构型甚至功能基团位置的额外结构信息,为跟踪生物大分子中的修饰类型和结合位点提供了一种方法。
Real-Space Spectral Determination of Short Single-Stranded DNA Sequence Structures.
Resolving the sequence and structure of flexible biomolecules such as DNA is crucial to understanding their biological mechanisms and functions. Traditional structural biology methods remain challenging for the analysis of small and disordered biomolecules, especially those that are difficult to label or crystallize. Recent development of single-molecule tip-enhanced Raman spectroscopy (TERS) offers a label-free approach to identifying nucleobases in a single DNA chain. However, a clear demonstration of sequencing both spatially and spectrally at single-base resolution is still elusive due to the challenges caused by weak Raman signals and the flexibility of DNA molecules. Here, we report a proof-of-principle demonstration to this end, spectrally resolving in real space individual nucleobases and their sequence structures within a short, single-stranded DNA molecule artificially designed. This breakthrough is achieved through the development of subnanometer-resolved low-temperature TERS methodology for such thermally unstable flexible biomolecules. Further TERS mapping over individual nucleobases provides additional structural information about the molecular configurations and even the locations of functional groups, offering a way to track modification types and binding sites in biomolecules.
期刊介绍:
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