Hydrogen sulfide (H2S) is an important reactive sulfur species that is involved in many biological functions, and H2S imbalances have been indicated as a potential biomarker for various diseases. Different H2S donors have been developed to deliver H2S directly to biological systems, but few reports include donors with optical responses that allow for tracking of H2S release. Moreover, donor systems that use the same chemistry to deliver H2S across a palette of fluorescent responses remain lacking. Here we report five thiol‐activated fluorescence turn‐on COS/H2S donors that utilize blue, yellow, orange, red, and near infrared‐emitting dyes functionalized with an H2S‐releasing sulfenyl thiocarbonate scaffold. Upon treatment with thiols, each donor provides a fluorescence turn‐on response (3–310‐fold) and high H2S release efficiencies (>60 %). Using combined electrode and fluorescence experiments, we directly correlate the measured H2S release with the fluorescence response. All donors are biocompatible and release H2S in live cell environments. In addition, we demonstrate that the NIR donor allows for imaging H2S release in live rats via subcutaneous injection of the donor loaded into an alginate gel, which to the best of our knowledge is the first in vivo tracking of H2S release from a fluorogenic donor in non‐transparent organisms.
- Award ID(s):
- 1625529
- PAR ID:
- 10309022
- Date Published:
- Journal Name:
- Chemical Science
- Volume:
- 10
- Issue:
- 6
- ISSN:
- 2041-6520
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Abstract Hydrogen sulfide (H2S) is an important reactive sulfur species that is involved in many biological functions, and H2S imbalances have been indicated as a potential biomarker for various diseases. Different H2S donors have been developed to deliver H2S directly to biological systems, but few reports include donors with optical responses that allow for tracking of H2S release. Moreover, donor systems that use the same chemistry to deliver H2S across a palette of fluorescent responses remain lacking. Here we report five thiol‐activated fluorescence turn‐on COS/H2S donors that utilize blue, yellow, orange, red, and near infrared‐emitting dyes functionalized with an H2S‐releasing sulfenyl thiocarbonate scaffold. Upon treatment with thiols, each donor provides a fluorescence turn‐on response (3–310‐fold) and high H2S release efficiencies (>60 %). Using combined electrode and fluorescence experiments, we directly correlate the measured H2S release with the fluorescence response. All donors are biocompatible and release H2S in live cell environments. In addition, we demonstrate that the NIR donor allows for imaging H2S release in live rats via subcutaneous injection of the donor loaded into an alginate gel, which to the best of our knowledge is the first in vivo tracking of H2S release from a fluorogenic donor in non‐transparent organisms.
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Abstract Hydrogen sulfide (H2S) is a biologically active molecule that exhibits protective effects in a variety of physiological and pathological processes. Although several H2S‐related biological effects have been discovered by using H2S donors, knowing how much H2S has been released from donors under different conditions remains challenging. Now, a series of γ‐ketothiocarbamate (γ‐KetoTCM) compounds that provide the first examples of colorimetric H2S donors and enable direct quantification of H2S release, were reported. These compounds are activated through a pH‐dependent deprotonation/β‐elimination sequence to release carbonyl sulfide (COS), which is quickly converted into H2S by carbonic anhydrase. The
p ‐nitroaniline released upon donor activation provides an optical readout that correlates directly to COS/H2S release, thus enabling colorimetric measurement of H2S donation. -
Similar to hydrogen sulfide (H 2 S), its chalcogen congener, Hydrogen selenide (H 2 Se), is an emerging molecule of interest given its endogenous expression and purported biological activity. However, unlike H 2 S, detailed investigations into the chemical biology of H 2 Se are limited and little is known about its innate physiological functions, cellular targets, and therapeutic potential. The obscurity surrounding these fundamental questions is largely due to a lack of small molecule donors that can effectively increase the bioavailability of H 2 Se through their continuous liberation of the transient biomolecule under physiologically relevant conditions. Driven by this unmet demand for H 2 Se-releasing moieties, we report that γ-keto selenides provide a useful platform for H 2 Se donation via an α-deprotonation/β-elimination pathway that is highly dependent on both pH and alpha proton acidity. These attributes afforded a small library of donors with highly variable rates of release (higher alpha proton acidity = faster selenide liberation), which is accelerated under neutral to slightly basic conditions—a feature that is unique and complimentary to previously reported H 2 Se donors. We also demonstrate the impressive anticancer activity of γ-keto selenides in both HeLa and HCT116 cells in culture, which is likely to stimulate additional interest and research into the biological activity and anticancer effects of H 2 Se. Collectively, these results indicate that γ-keto selenides provide a highly versatile and effective framework for H 2 Se donation.more » « less
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Abstract Hydrogen sulfide (H2S) is a gaseous molecule that has received attention for its role in biological processes and therapeutic potential in diseases, such as ischemic reperfusion injury. Despite its clinical relevance, delivery of H2S to biological systems is hampered by its toxicity at high concentrations. Herein, we report the first metal‐based H2S donor that delivers this gas selectively to hypoxic cells. We further show that H2S release from this compound protects H9c2 rat cardiomyoblasts from an in vitro model of ischemic reperfusion injury. These results validate the utility of redox‐activated metal complexes as hypoxia‐selective H2S‐releasing agents for use as tools to study the role of this gaseous molecule in complex biological systems.
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Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.1039/c8sc05200j
