Quantum Dot Peptide Biosensors for Monitoring Caspase 3 Proteolysis and Calcium Ions

Quantum Dot Peptide Biosensors for Monitoring Caspase 3 Proteolysis and Calcium Ions

The nanoscale size and unique optical properties of semiconductor quantum dots (QDs) have made them attractive as central photoluminescent scaffolds for a variety of biosensing platforms. In this report we functionalize QDs with dye-labeled peptides using two different linkage chemistries to yield F...

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Bibliographic Details
Published in:ACS nano Vol. 4; no. 9; pp. 5487 - 5497
Main Authors: Prasuhn, Duane E., Feltz, Anne, Blanco-Canosa, Juan B., Susumu, Kimihiro, Stewart, Michael H., Mei, Bing C., Yakovlev, Aleksey V., Loukou, Christina, Mallet, Jean-Maurice, Oheim, Martin, Dawson, Philip E., Medintz, Igor L.
Format: Journal Article
Language:English
Published: United States American Chemical Society 28-09-2010
Subjects:
Amino Acid Sequence
Biosensing Techniques - methods
Calcium - analysis
Caspase 3 - metabolism
Chemical Sciences
Engineering
Fluorescence Resonance Energy Transfer
Fluorescent Dyes - chemistry
Humans
Molecular Sequence Data
Organic chemistry
Peptides - chemistry
Quantum Dots
protease
indicator
nanocrystal
dye
biosensor
calcium
fluorescence
quantum dot
energy transfer
FRET
caspase 3
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Summary:The nanoscale size and unique optical properties of semiconductor quantum dots (QDs) have made them attractive as central photoluminescent scaffolds for a variety of biosensing platforms. In this report we functionalize QDs with dye-labeled peptides using two different linkage chemistries to yield Förster resonance energy transfer (FRET)-based sensors capable of monitoring either enzymatic activity or ionic presence. The first sensor targets the proteolytic activity of caspase 3, a key downstream effector of apoptosis. This QD conjugate utilized carbodiimide chemistry to covalently link dye-labeled peptide substrates to the terminal carboxyl groups on the QD’s surface hydrophilic ligands in a quantitative manner. Caspase 3 cleaved the peptide substrate and disrupted QD donor-dye acceptor FRET providing signal transduction of enzymatic activity and allowing derivation of relevant Michaelis−Menten kinetic descriptors. The second sensor was designed to monitor Ca2+ ions that are ubiquitous in many biological processes. For this sensor, Cu+-catalyzed [3 + 2] azide−alkyne cycloaddition was exploited to attach a recently developed azide-functionalized CalciumRuby-Cl indicator dye to a cognate alkyne group present on the terminus of a modified peptide. The labeled peptide also expressed a polyhistidine sequence, which facilitated its subsequent metal-affinity coordination to the QD surface establishing the final FRET sensing construct. Adding exogenous Ca2+ to the sensor solution increased the dyes fluorescence, altering the donor−acceptor emission ratio and manifested a dissociation constant similar to that of the native dye. These results highlight the potential for combining peptides with QDs using different chemistries to create sensors for monitoring chemical compounds and biological processes.
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ISSN:1936-0851
1936-086X
DOI:10.1021/nn1016132