The small engineered luciferase NanoLuc has rapidly become a powerful tool in the fields of biochemistry, chemical biology, and cell biology due to its exceptional brightness and stability. The continuously expanding NanoLuc toolbox has been employed in applications ranging from biosensors to molecular and cellular imaging, and currently includes split complementation variants, engineering techniques for spectral tuning, and bioluminescence resonance energy transfer-based concepts. In this review, we provide an overview of state-of-the-art NanoLuc-based sensors and switches with a focus on the underlying protein engineering approaches. We discuss the advantages and disadvantages of various strategies with respect to sensor sensitivity, modularity, and dynamic range of the sensor and provide a perspective on future strategies and applications.
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December 2020
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Cover Image
Cover Image
The plasma membrane of lymphocytes is highly compartmentalized in so-called nanodomains or protein islands. Proteins such as Caveolin-1 (pink), tetraspanins (blue) or flotillins (violet) define these protein islands and thereby regulate the functioning of the immune system. In this issue (see pages 2387–2397), Schaffer and Minguet discuss the importance of these protein islands regarding lymphocyte activation and the development of immunopathologies. This cover artwork has been created by Susana Minguet.
Review Article|
November 26 2020
Engineering with NanoLuc: a playground for the development of bioluminescent protein switches and sensors
Biochem Soc Trans (2020) 48 (6): 2643–2655.
Article history
Received:
September 17 2020
Revision Received:
October 21 2020
Accepted:
October 26 2020
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