Genetically Encoded Fluorogenic DNA Aptamers for Imaging Metabolite in Living Cells

Yuting Wu; Wentao Kong; Jacqueline Van Stappen; Linggen Kong; Zhimei Huang; Zhenglin Yang; Yu An Kuo; Yuan I. Chen; Yujie He; Hsin Chih Yeh; Ting Lu; Yi Lu

doi:10.1021/jacs.4c09855

Genetically Encoded Fluorogenic DNA Aptamers for Imaging Metabolite in Living Cells

Yuting Wu, Wentao Kong, Jacqueline Van Stappen, Linggen Kong, Zhimei Huang, Zhenglin Yang, Yu An Kuo, Yuan I. Chen, Yujie He, Hsin Chih Yeh, Ting Lu, Yi Lu

Research output: Contribution to journal › Article › peer-review

Abstract

Genetically encoded fluorescent protein and fluorogenic RNA sensors are indispensable tools for imaging biomolecules in cells. To expand the toolboxes and improve the generalizability and stability of this type of sensor, we report herein a genetically encoded fluorogenic DNA aptamer (GEFDA) sensor by linking a fluorogenic DNA aptamer for dimethylindole red with an ATP aptamer. The design enhances red fluorescence by 4-fold at 650 nm in the presence of ATP. Additionally, upon dimerization, it improves the signal-to-noise ratio by 2-3 folds. We further integrated the design into a plasmid to create a GEFDA sensor for sensing ATP in live bacterial and mammalian cells. This work expanded genetically encoded sensors by employing fluorogenic DNA aptamers, which offer enhanced stability over fluorogenic proteins and RNAs, providing a novel tool for real-time monitoring of an even broader range of small molecular metabolites in biological systems.

Original language	English (US)
Pages (from-to)	1529-1541
Number of pages	13
Journal	Journal of the American Chemical Society
Volume	147
Issue number	2
Early online date	Dec 31 2024
DOIs	https://doi.org/10.1021/jacs.4c09855
State	Published - Jan 15 2025

ASJC Scopus subject areas

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

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10.1021/jacs.4c09855

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title = "Genetically Encoded Fluorogenic DNA Aptamers for Imaging Metabolite in Living Cells",

abstract = "Genetically encoded fluorescent protein and fluorogenic RNA sensors are indispensable tools for imaging biomolecules in cells. To expand the toolboxes and improve the generalizability and stability of this type of sensor, we report herein a genetically encoded fluorogenic DNA aptamer (GEFDA) sensor by linking a fluorogenic DNA aptamer for dimethylindole red with an ATP aptamer. The design enhances red fluorescence by 4-fold at 650 nm in the presence of ATP. Additionally, upon dimerization, it improves the signal-to-noise ratio by 2-3 folds. We further integrated the design into a plasmid to create a GEFDA sensor for sensing ATP in live bacterial and mammalian cells. This work expanded genetically encoded sensors by employing fluorogenic DNA aptamers, which offer enhanced stability over fluorogenic proteins and RNAs, providing a novel tool for real-time monitoring of an even broader range of small molecular metabolites in biological systems.",

author = "Yuting Wu and Wentao Kong and {Van Stappen}, Jacqueline and Linggen Kong and Zhimei Huang and Zhenglin Yang and Kuo, {Yu An} and Chen, {Yuan I.} and Yujie He and Yeh, {Hsin Chih} and Ting Lu and Yi Lu",

note = "This material is based on work supported by the US National Institute of Health (GM141931 to Y.L.) and the US National Science Foundation (CBET2235455 to H.-C.Y. and Y.L.). The Lu group research is supported by the Robert A. Welch Foundation (grant F-0020). W.K. and T.L. were supported by the DOE Center for Advanced Bioenergy and Bioproducts Innovation (U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Number DE-SC0018420). H.-C.Y. was supported by the National Science Foundation (CHE2404334) and the National Institutes of Health (DA060543).",

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AU - Wu, Yuting

AU - Kong, Wentao

AU - Van Stappen, Jacqueline

AU - Kong, Linggen

AU - Huang, Zhimei

AU - Yang, Zhenglin

AU - Kuo, Yu An

AU - Chen, Yuan I.

AU - He, Yujie

AU - Yeh, Hsin Chih

AU - Lu, Ting

AU - Lu, Yi

N1 - This material is based on work supported by the US National Institute of Health (GM141931 to Y.L.) and the US National Science Foundation (CBET2235455 to H.-C.Y. and Y.L.). The Lu group research is supported by the Robert A. Welch Foundation (grant F-0020). W.K. and T.L. were supported by the DOE Center for Advanced Bioenergy and Bioproducts Innovation (U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under Award Number DE-SC0018420). H.-C.Y. was supported by the National Science Foundation (CHE2404334) and the National Institutes of Health (DA060543).

PY - 2025/1/15

Y1 - 2025/1/15

N2 - Genetically encoded fluorescent protein and fluorogenic RNA sensors are indispensable tools for imaging biomolecules in cells. To expand the toolboxes and improve the generalizability and stability of this type of sensor, we report herein a genetically encoded fluorogenic DNA aptamer (GEFDA) sensor by linking a fluorogenic DNA aptamer for dimethylindole red with an ATP aptamer. The design enhances red fluorescence by 4-fold at 650 nm in the presence of ATP. Additionally, upon dimerization, it improves the signal-to-noise ratio by 2-3 folds. We further integrated the design into a plasmid to create a GEFDA sensor for sensing ATP in live bacterial and mammalian cells. This work expanded genetically encoded sensors by employing fluorogenic DNA aptamers, which offer enhanced stability over fluorogenic proteins and RNAs, providing a novel tool for real-time monitoring of an even broader range of small molecular metabolites in biological systems.

AB - Genetically encoded fluorescent protein and fluorogenic RNA sensors are indispensable tools for imaging biomolecules in cells. To expand the toolboxes and improve the generalizability and stability of this type of sensor, we report herein a genetically encoded fluorogenic DNA aptamer (GEFDA) sensor by linking a fluorogenic DNA aptamer for dimethylindole red with an ATP aptamer. The design enhances red fluorescence by 4-fold at 650 nm in the presence of ATP. Additionally, upon dimerization, it improves the signal-to-noise ratio by 2-3 folds. We further integrated the design into a plasmid to create a GEFDA sensor for sensing ATP in live bacterial and mammalian cells. This work expanded genetically encoded sensors by employing fluorogenic DNA aptamers, which offer enhanced stability over fluorogenic proteins and RNAs, providing a novel tool for real-time monitoring of an even broader range of small molecular metabolites in biological systems.

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Genetically Encoded Fluorogenic DNA Aptamers for Imaging Metabolite in Living Cells

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