A fluorescent supramolecular biosensor for bacterial detection via binding-induced changes in coiled-coil molecular assembly

[Display omitted] •The essential elements required for any sensors are a receptor, a signal converter, and a detector.•Bacteria binding-induced conformational changes in supramolecular state is translated into fluorescence emission.•Bacteria binding-induced conformational changes in supramolecular s...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Chemical, 2019-07, Vol.290, p.93-99
Main Authors: Jeong, Woo-jin, Choi, Se-Hwan, Lee, Hye-soo, Lim, Yong-beom
Format: Article
Language:English
Subjects:
Bacteria
Binding
Biosensor
Biosensors
Change detection
Chemical compounds
Coils
Converters
Denaturation
E coli
Escherichia coli
Fluorescence
High temperature
Object recognition
Peptide-based probe
Self-assembly
Supramolecule
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Summary:[Display omitted] •The essential elements required for any sensors are a receptor, a signal converter, and a detector.•Bacteria binding-induced conformational changes in supramolecular state is translated into fluorescence emission.•Bacteria binding-induced conformational changes in supramolecular state is translated into fluorescence emission.•fSBs were resistant to heat-induced denaturation and retained their bacterial-sensing capability even at high temperature. The essential elements required for any sensors are a receptor, a signal converter, and a detector. Here, we report the construction of bacterial biosensors in which all of the required biosensor elements are furnished in one supramolecular assembly. The supramolecular biosensor is based on a double-layered octa-helical coiled-coil peptide assembly that contains tetravalent bioreceptors on the outer surface and environment-sensitive fluorophores in the core. The signal conversion takes advantage of the noncovalent and reversible nature of the self-assembled system, i.e., the multivalent binding of bacteria induces conformational changes in the supramolecular state, which is translated into differential fluorescence emissions. We show that fluorescent supramolecular biosensors (fSBs) can selectively detect E. coli over other bacteria. Because the fSBs were resistant to heat-induced denaturation, they retained their bacterial-sensing capability even at an elevated temperature (50 ℃). Biosensors based on responsive supramolecular assemblies can be further developed to detect various large and flat biological objects and biomacromolecules.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2019.03.112