光学镊子和TIRF显微镜用于RNA/DNA纳米结构的单分子操作,包括其橡胶性质和单分子计数。

Chiran Ghimire, Peixuan Guo
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引用次数: 0

摘要

生命科学通常关注微观层面。单分子技术已被用于在微或纳米尺度上观察成分。单分子成像提供了关于单个分子行为的前所未有的信息,这与集合方法的信息不同,集合方法是将许多分子在不同状态下的信息平均起来。生命系统的一个典型特征是运动。在生命系统中,运动生物机器缺乏同步性,这给运动过程的高分辨率成像带来了挑战。因此,单分子技术对于实时研究生物机器(如病毒DNA包装马达或其他atp酶)的运动机制特别有用。单分子研究中最常用的光学仪器是光镊和单分子全内反射荧光显微镜。光镊是基于力的技术。利用光学镊子对RNA进行分析,发现RNA纳米颗粒具有橡胶或变形虫的特性,可以强制血管外渗,增强肿瘤靶向性和快速肾排泄。RNA的橡胶性质为RNA作为治疗癌症的理想试剂提供了机制证据。单分子光漂白允许生物分子的直接计数。该技术用于phi29 DNA包装马达中RNA的单分子计数,以解决马达中RNA的5拷贝和6拷贝之争。这项技术随后扩展到计算由蛋白质、DNA和其他大分子组成的生物机器中的成分。结合统计分析,它详细揭示了生物分子机制,并导致超灵敏传感器在诊断和法医领域的发展。本文综述了光镊和荧光技术作为单分子技术在解决RNA和DNA纳米结构相关机制问题中的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Optical tweezer and TIRF microscopy for single molecule manipulation of RNA/DNA nanostructures including their rubbery property and single molecule counting.

Life science is often focused on the microscopic level. Single-molecule technology has been used to observe components at the micro- or nanoscale. Single-molecule imaging provides unprecedented information about the behavior of individual molecules in contrast to the information from ensemble methods that average the information of many molecules in various states. A typical feature of living systems is motion. The lack of synchronicity of motion biomachines in living systems makes it challenging to image the motion process with high resolution. Thus, single-molecule technology is especially useful for real-time study on motion mechanism of biomachines, such as viral DNA packaging motor, or other ATPases. The most common optical instrumentations in single-molecule studies are optical tweezers and single molecule total internal refection fluorescence microscopy (smTIRF). Optical tweezers are the force-based technique. The analysis of RNA using optical tweezer has led to the discovery of the rubbery or amoeba property of RNA nanoparticles for compelling vessel extravasation to enhance tumor targeting and fast renal excretion. The rubbery property of RNA lends mechanistic evidence for RNAs use as an ideal reagent in cancer treatment with undetectable toxicity. Single molecule photobleaching allows for the direct counting of biomolecules. This technique was invented for single molecule counting of RNA in the phi29 DNA packaging motor to resolve the debate between five and six copies of RNA in the motor. The technology has subsequently extended to counting components in biological machines composed of protein, DNA, and other macromolecules. In combination with statistical analysis, it reveals biomolecular mechanisms in detail and leads to the development of ultra-sensitive sensors in diagnosis and forensics. This review focuses on the applications of optical tweezers and fluorescence-based techniques as single-molecule technologies to resolve mechanistic questions related to RNA and DNA nanostructures.

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