DNA
等离子体子
动力学
生物物理学
计算生物学
受体-配体动力学
纳米-
化学
多路复用
纳米技术
细胞生物学
生物
材料科学
计算机科学
物理
生物化学
光电子学
电信
量子力学
复合材料
作者
Shuo‐Hui Cao,Zijian Wan,Eric Johansen,Guangzhong Ma,Prashant Desai,Heng Zhu,Shaopeng Wang
标识
DOI:10.1002/anie.202506464
摘要
Abstract A high‐density nano‐oscillator platform using self‐assembled DNA‐barcoded virion sensors is developed to address the critical need for high‐throughput label‐free measurement of small‐molecule binding to membrane proteins. By integrating virion display technology with charge‐sensitive plasmonic detection, our platform enables robust, label‐free quantification of small‐molecule binding kinetics to membrane proteins. Gold nanoparticle‐virion conjugates are self‐assembled onto a plasmonic sensor chip via a flexible molecular linker to form high‐density nano‐oscillators. Driven by an alternating electric field, the oscillation amplitudes of the nano‐oscillators are precisely measured via widefield plasmonic imaging. This charge‐sensitive mechanism can sensitively detect the binding of small‐molecule ligands to the membrane proteins displayed on the virions at single‐nanosensor resolution, overcoming the sensitivity limit of conventional mass‐sensitive techniques. More importantly, the platform employs novel affinity‐discriminated DNA barcodes for multistate decoding with exponential multiplexing capacity, enabling high‐throughput screening of a library of membrane proteins. For a proof‐of‐concept demonstration, binding kinetics of five pairs of G‐protein‐coupled receptors and their corresponding small molecule ligands are measured on a single sensor chip, with all individual nano‐oscillators identified by just two affinity‐discriminated, quadra‐state DNA decoders. This technology advances membrane protein research and drug screening capabilities, offering a practical solution for biomolecular interaction studies and biosensing applications.
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