Amplification-Free Electrochemiluminescent Biosensor for Ultrasensitive Detection of Fusobacterium nucleatum Using Tetrahedral DNA-Based CRISPR/Cas12a.

IF 10.5 Q1 ENGINEERING, BIOMEDICAL

Cyborg and bionic systems (Washington, D.C.) Pub Date : 2025-05-01 eCollection Date: 2025-01-01 DOI:10.34133/cbsystems.0266

Xindan Zhang, Minkang Wu, Haoran Shi, Soochan Kim, Shixiang Lu, Ping Wang, Jieling Qin

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Abstract

Fusobacterium nucleatum, a bacterium linked to colorectal cancer, possesses a specific gene called fadA that serves as an early diagnostic biomarker. The CRISPR/Cas12a system has demonstrated marked potential for nucleic acid detection due to its satisfactory selectivity and trans-cleavage ability. However, most CRISPR/Cas-based sensors suffer from problems such as probe entanglement or local aggregation, reducing the Cas enzyme efficiency. In this study, an amplification-free biosensing platform for ultrasensitive detection of F. nucleatum was developed by integrating the highly specific CRISPR/AsCas12a with an improved electrochemiluminescence (ECL) biosensor. Different from the conventional 1- or 2-dimensional probes, the platform was constructed by tetrahedral DNA nanostructure (TDN) probes conjugated with quenchers and coralliform gold (CFAu) functionalized with luminescent agents. The TDN serves as an exceptional scaffold to modulate the recognition unit, substantially enhancing the recognition and cleavage efficiency of AsCas12a toward the probes. Furthermore, the high surface area of CFAu provides extensive landing sites for the luminescent agents, thereby improving the detection sensitivity. The prepared ECL biosensor exhibited a wider linear range (10 fM to 100 nM) and was capable of detecting F. nucleatum down to 1 colony-forming unit/ml. Additionally, the high mismatch sensitivity of AsCas12a to protospacer adjacent motifs and nearby areas provides a strategy for distinguishing mutant from wild-type sequences. Finally, by designing CRISPR RNA (crRNA), this diagnostic method can also be easily modified to detect other bacteria or biomarkers for the early diagnosis of various diseases.

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基于四面体dna的CRISPR/Cas12a超灵敏检测核梭杆菌的无扩增电化学发光生物传感器

核梭杆菌是一种与结直肠癌有关的细菌，它拥有一种名为fadA的特殊基因，可以作为早期诊断的生物标志物。由于其令人满意的选择性和反式切割能力，CRISPR/Cas12a系统在核酸检测方面显示出显著的潜力。然而，大多数基于CRISPR/Cas的传感器都存在探针纠缠或局部聚集等问题，从而降低了Cas酶的效率。本研究通过将高特异性CRISPR/AsCas12a与改进的电化学发光（ECL）生物传感器相结合，建立了一种无扩增的超灵敏检测核仁梭菌的生物传感平台。与传统的一维或二维探针不同，该平台是由四面体DNA纳米结构（TDN）探针与猝灭剂和荧光剂功能化的珊瑚金（CFAu）偶联构建的。TDN作为一个特殊的支架来调节识别单元，大大提高了AsCas12a对探针的识别和切割效率。此外，CFAu的高表面积为发光剂提供了广泛的着陆点，从而提高了探测灵敏度。所制备的ECL生物传感器具有较宽的线性范围（10 fM ~ 100 nM），能够检测到1个集落形成单位/ml的核梭菌。此外，AsCas12a对原间隔邻近基序和附近区域的高错配敏感性为区分突变体和野生型序列提供了一种策略。最后，通过设计CRISPR RNA (crRNA)，这种诊断方法也可以很容易地进行修改，以检测其他细菌或生物标志物，从而早期诊断各种疾病。

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