Light-Up Sensing Citrate Using a Capture-Selected DNA Aptamer

Advanced Sensor Research Pub Date : 2024-02-22 DOI:10.1002/adsr.202300167

Lide Gu, Yao Zhang, Deli Wang, Juewen Liu

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Abstract

Citrate is a key metabolite and nutrient in humans. Its level is associated with many diseases from tumor growth to bone diseases. Detection of citrate has relied on its high negative charge, metal chelating properties and as an enzyme substrate. In this work, the capture-selection method is used to isolate DNA aptamers for citrate. After 18 rounds of selection, a highly converged library is obtained and the first two sequences reached 99.6% of the library. Using the most abundant sequence named CA1, thioflavin T fluorescence spectroscopy and isothermal titration calorimetry show dissociation constants of 7.4 and 4.4 µm citrate, respectively. CA1 does not require sodium for binding but requires 1.0 mm magnesium. Among the tested carboxylate molecules, only citrate can bind to the aptamer. A light-up fluorescence strand displacement biosensor is developed and it can detect citrate in simulated urine with a detection limit of 1.1 µm. This short 42-nucleotide aptamer can be readily adapted to other types of sensing mechanisms for the detection of citrate.

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利用捕获选择的 DNA 短链簇发光传感柠檬酸盐

柠檬酸盐是人体的一种重要代谢物和营养物质。从肿瘤生长到骨骼疾病，柠檬酸盐的含量与许多疾病有关。柠檬酸盐的检测依赖于它的高负电荷、金属螯合特性和酶底物。在这项研究中，我们采用捕获-选择法来分离柠檬酸盐的DNA适配体。经过 18 轮筛选后，得到了一个高度收敛的文库，其中前两个序列占文库的 99.6%。利用名为 CA1 的最丰富序列，硫黄素 T 荧光光谱法和等温滴定量热法显示柠檬酸盐的解离常数分别为 7.4 和 4.4 µm。CA1 的结合不需要钠，但需要 1.0 毫米的镁。在测试的羧酸盐分子中，只有柠檬酸盐能与适配体结合。我们开发了一种发光荧光链位移生物传感器，它可以检测模拟尿液中的柠檬酸盐，检测限为 1.1 微米。这种短的 42 核苷酸适配体可以很容易地适用于其他类型的柠檬酸盐检测传感机制。

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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Advanced Sensor Research

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