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Chemical Probes for Imaging Reactive Sulfur, Oxygen, and Nitrogen Species in Living Cells and Clinical Samples

$333,375R15FY2015GMNIH

Southern Methodist University, Dallas TX

Investigators

Linked publications & trials

Abstract

? DESCRIPTION (provided by applicant): Reactive sulfur, oxygen, and nitrogen (RSON) species are endogenous small molecules that play fundamental roles in cellular signaling and are misregulated in diseases ranging from cancer to neurodegeneration to diabetes. This super-family of signaling molecules includes nitric oxide, hydrogen sulfide, hydrogen peroxide, and many others. Despite being involved in nearly all physiological processes, our understanding of their complex and intertwined roles remains in its infancy due, in large part, to a lack of methods to monitor these transient species in living cells and human clinical samples. This project aims to use highly innovative chemistry to develop responsive fluorescent dyes for the precise real-time tracking of specific RSON species, including hydrogen sulfide, peroxynitrite, and nitroxyl, and to use these probes to investigate their production in cellular models of lung cancer and in human saliva/exhaled breath condensates. Specifically, we aim to: 1. Develop reaction-based probes to detect and image RSON species in cells and clinical samples. There is a lack of biologically compatible methods for the detection of certain RSON species, particularly hydrogen sulfide, peroxynitrite, and nitroxyl. Leveraging our expertise in synthetic organic chemistry, we will bridge this gap by inventing new reaction-based probes to detect and image these species using fluorescence, chemiluminescence, and nuclear magnetic resonance techniques. 2. Investigate the role of RSON species in cellular models of disease. Although the ubiquitous signaling molecule nitric oxide has been well studied in cancer models, the production and roles of other RSON species remain incompletely understood. We will use newly developed and state-of-the-art reaction-based probes to characterize the complex cellular chemistry of RSON species in a cellular model of airway inflammation. 3. Develop and validate point-of-care diagnostics for the detection and management of disease. RSON chemistry has the potential to be a powerful diagnostic and prognostic marker. Indeed, exhaled nitric oxide and H2O2 are established biomarker for monitoring asthma and other respiratory ailments, but home and point-of-care monitoring remains a significant obstacle. We will develop innovative point-of-care smartphone-based RSON detection techniques for monitoring the levels of these species in the saliva and exhaled breath condensates.

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