Life in aerobic environments requires organisms to maintain strict control over their internal redox status. At the cellular level, aerobic respiration poses a particularly unique challenge for living systems, as the energy-releasing reduction of oxygen to water generates partially reduced reactive oxygen species (ROS) intermediates that can exert widely divergent physiological and/or pathological effects. 1 Unregulated production of ROS results in oxidative stress, and subsequent buildup of free radical damage to proteins, lipids, and nucleic acids is connected to serious human diseases where age is a risk factor. 2,3 However, emerging evidence suggests that controlled production of one ROS in particular, hydrogen peroxide, can mediate cellular signal transduction through reversible oxidation and reduction of cysteine thiols and other redox-active groups. 4-8The complex, reversible oxidation biology of the cell and its broad implications in human health and disease provide motivation for developing new ways to study dynamic redox chemistry in living systems. In this regard, fluorescence imaging with redox-responsive chemosensors is a potentially powerful approach to probe various stages of oxidative signaling, stress, or repair in real time in living cells. Traditional fluorescent probes for redox activity, including dichlorodihydrofluorescein or dihydrorhodamine 123, are useful for cellular studies but can only respond irreversibly to a single initial oxidation event. 9-11 In contrast, fluorophores that can respond reversibly to changes in oxidation or reduction events would be much more valuable for visualizing cycles of redox signaling, stress, or repair and their dynamic interconversion. A few redox-sensitive fluorescent reporters based on protein 12,13 or peptide 14,15 scaffolds have been described, but no small molecules have been reported to date for imaging reversible oxidation and reduction events in living biological systems. We now present the synthesis, properties, and live-cell imaging applications of Redoxfluor-1 (RF1), a new type of fluorescent sensor for detecting reversible redox cycles in aqueous solution and in living cells. RF1 features a dual colorimetric/fluorimetric readout for oxidation-reduction events, a >50-fold fluorescence dynamic range, and visible wavelength excitation and emission profiles to minimize cellular damage and autofluorescence. In addition, RF1 can be loaded into living cells and image multiple, reversible cycles of oxidative stress and reductive repair.Our design strategy for fluorescence detection of reversible oxidation-reduction events is inspired by the extensive use of disulfides as redox resevoirs in biology. We anticipated that integrating this unit into a fluorescein scaffold would provide a small-molecule redox reporter with desirable optical properties and biological compatibility. Along these lines, the synthesis of RF1 proceeds in three steps as shown in Scheme 1. Lithiation of naphthalene in the presence of TMEDA and quenching with sulfur affords disulfid...
