Strategy for Dual-Analyte Luciferin Imaging: In Vivo Bioluminescence Detection of Hydrogen Peroxide and Caspase Activity in a Murine Model of Acute Inflammation

In vivo molecular imaging holds promise for understanding the underlying mechanisms of health, injury, aging, and disease, as it can detect distinct biochemical processes such as enzymatic activity, reactive small-molecule fluxes, or post-translational modifications. Current imaging techniques often...

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Bibliographic Details
Published in:Journal of the American Chemical Society 2013-02, Vol.135 (5), p.1783-1795
Main Authors: Van de Bittner, Genevieve C, Bertozzi, Carolyn R, Chang, Christopher J
Format: Article
Language:English
Subjects:
Acute Disease
Animals
Benzothiazoles - analysis
Benzothiazoles - metabolism
Caspase 8 - analysis
Caspase 8 - metabolism
Cell Line
Disease Models, Animal
Enzyme Activation
Hydrogen Peroxide - analysis
Hydrogen Peroxide - metabolism
Inflammation - enzymology
Inflammation - metabolism
Luminescence
Luminescent Measurements
Mice
Mice, Transgenic
Molecular Imaging
Molecular Structure
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Summary:In vivo molecular imaging holds promise for understanding the underlying mechanisms of health, injury, aging, and disease, as it can detect distinct biochemical processes such as enzymatic activity, reactive small-molecule fluxes, or post-translational modifications. Current imaging techniques often detect only a single biochemical process, but, within whole organisms, multiple types of biochemical events contribute to physiological and pathological phenotypes. In this report, we present a general strategy for dual-analyte detection in living animals that employs in situ formation of firefly luciferin from two complementary caged precursors that can be unmasked by different biochemical processes. To establish this approach, we have developed Peroxy Caged Luciferin-2 (PCL-2), a H2O2-responsive boronic acid probe that releases 6-hydroxy-2-cyanobenzothiazole (HCBT) upon reacting with this reactive oxygen species, as well as a peptide-based probe, z-Ile-Glu-ThrAsp-d-Cys (IETDC), which releases d-cysteine in the presence of active caspase 8. Once released, HCBT and d-cysteine form firefly luciferin in situ, giving rise to a bioluminescent signal if and only if both chemical triggers proceed. This system thus constitutes an AND-type molecular logic gate that reports on the simultaneous presence of H2O2 and caspase 8 activity. Using these probes, chemoselective imaging of either H2O2 or caspase 8 activity was performed in vitro and in vivo. Moreover, concomitant use of PCL-2 and IETDC in vivo establishes a concurrent increase in both H2O2 and caspase 8 activity during acute inflammation in living mice. Taken together, this method offers a potentially powerful new chemical tool for studying simultaneous oxidative stress and inflammation processes in living animals during injury, aging, and disease, as well as a versatile approach for concurrent monitoring of multiple analytes using luciferin-based bioluminescence imaging technologies.
ISSN:0002-7863
1520-5126
DOI:10.1021/ja309078t