适体
巨量平行
大规模并行测序
计算机科学
计算生物学
并行计算
DNA测序
纳米技术
分布式计算
生物
DNA
材料科学
遗传学
作者
Kuo Yuan,Yuan-I Chen,Yanxing Wang,Zeynep Korkmaz,Siem Yonas,Yujie He,Trung D. Nguyen,Soonwoo Hong,Thu Anh Nguyen,Sohyun Kim,Saeed Seifi,Po‐Hsun Fan,Yuting Wu,Zhenglin Yang,Hung‐wen Liu,Yi Lu,Pengyu Ren,Hsin-Chih Yeh
出处
期刊:
[Cold Spring Harbor Laboratory]
日期:2024-07-10
标识
DOI:10.1101/2024.07.07.602435
摘要
Abstract F luorogenic ap tamers (FAPs) have become an increasingly important tool in cellular sensing and pathogen diagnostics. However, fine-tuning FAPs for enhanced performance remains challenging even with the structural details provided by X-ray crystallography. Here we present a novel approach to optimize a DNA-based FAP (D-FAP), Lettuce, on repurposed Illumina next-generation sequencing (NGS) chips. When substituting its cognate chromophore, DFHBI-1T, with TO1-biotin, Lettuce not only shows a red-shifted emission peak by 53 nm (from 505 to 558 nm), but also a 4-fold bulk fluorescence enhancement. After screening 8,821 Lettuce variants complexed with TO1-biotin, the C14T mutation is found to exhibit an improved apparent dissociated constant ( vs. 0.82 µM), an increased quantum yield (QY: 0.62 vs. 0.59) and an elongated fluorescence lifetime (τ: 6.00 vs. 5.77 ns), giving 45% more ensemble fluorescence than the canonical Lettuce/TO1-biotin complex. Molecular dynamic simulations further indicate that the π-π stacking interaction is key to determining the coordination structure of TO1-biotin in Lettuce. Our screening-and-simulation pipeline can effectively optimize FAPs without any prior structural knowledge of the canonical FAP/chromophore complexes, providing not only improved molecular probes for fluorescence sensing but also insights into aptamer-chromophore interactions.
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