Abstract
Cells engineered to express bioluminescence generate photons through a biochemical reaction catalyzed by a luciferase enzyme and a luciferin substrate. Conventional bioluminescent imaging approaches require that the luciferin substrate be added to the cell externally since it cannot be generated intracellularly. Thus, these cells remain “dark,” only emitting their bioluminescent signal in concert with the extracellular addition of the chemical substrate. Autobioluminescence represents an alternative signaling strategy whereby a synthetic bacterial luciferase, optimized for expression in eukaryotic cells, is used to sustain continuous photon emission without the necessary external addition of a substrate to drive reaction kinetics. This substrate-independent generation of light thereby allows autobioluminescent cells to be imaged at any longitudinal time scale desired to generate real-time metabolic data under both high-throughput in vitro and small animal in vivo experimental set-ups for applications ranging from environmental monitoring to preclinical biomedical imaging.
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Acknowledgments
The authors acknowledge research funding support by the US National Institutes of Health, National Institute of Environmental Health Sciences, under award numbers NIEHS-1R15ES023979-01, NIEHS-1R43ES022567-01, and NIEHS-2R44ES022567-02, the US Department of Agriculture under award number 2015-33610-23598, the University of Tennessee Institute for a Secure and Sustainable Environment (ISSE), and the International Research Support Initiative Program of the Higher Education Commission of Pakistan.
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Xu, T., Close, D., Ud Din, G., Sayler, G., Ripp, S. (2019). Engineering Autobioluminescent Eukaryotic Cells as Tools for Environmental and Biomedical Surveillance. In: Thouand, G. (eds) Handbook of Cell Biosensors. Springer, Cham. https://doi.org/10.1007/978-3-319-47405-2_117-1
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