Picomolar Biosensing and Conformational Analysis Using Artificial Bidomain Proteins and Terbium-to-Quantum Dot Förster Resonance Energy Transfer

Although antibodies remain a primary recognition element in all forms of biosensing, functional limitations arising from their size, stability, and structure have motivated the development and production of many different artificial scaffold proteins for biological recognition. However, implementing...

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Bibliographic Details
Published in:ACS nano 2020-05, Vol.14 (5), p.5956-5967
Main Authors: Léger, Corentin, Yahia-Ammar, Akram, Susumu, Kimihiro, Medintz, Igor L, Urvoas, Agathe, Valerio-Lepiniec, Marie, Minard, Philippe, Hildebrandt, Niko
Format: Article
Language:English
Subjects:
Biosensing Techniques
Chemical Sciences
Fluorescence Resonance Energy Transfer
Life Sciences
Physics
Quantum Dots
Semiconductors
Terbium
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Summary:Although antibodies remain a primary recognition element in all forms of biosensing, functional limitations arising from their size, stability, and structure have motivated the development and production of many different artificial scaffold proteins for biological recognition. However, implementing such artificial binders into functional high-performance biosensors remains a challenging task. Here, we present the design and application of Förster resonance energy transfer (FRET) nanoprobes comprising small artificial proteins (αRep bidomains) labeled with a Tb complex (Tb) donor on the C-terminus and a semiconductor quantum dot (QD) acceptor on the N-terminus. Specific binding of one or two protein targets to the αReps induced a conformational change that could be detected by time-resolved Tb-to-QD FRET. These single-probe FRET switches were used in a separation-free solution-phase assay to quantify different protein targets at sub-nanomolar concentrations and to measure the conformational changes with sub-nanometer resolution. Probing ligand-receptor binding under physiological conditions at very low concentrations in solution is a special feature of FRET that can be efficiently combined with other structural characterization methods to develop, understand, and optimize artificial biosensors. Our results suggest that the αRep FRET nanoprobes have a strong potential for their application in advanced diagnostics and intracellular live-cell imaging of ligand-receptor interactions.
ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.0c01410