A Fluorescent Sensor for Imaging Reversible Redox Cycles in Living Cells

Miller, Evan W.; Bian, Shelly X.; Chang, Christopher J.

doi:10.1021/ja0668973

Cited by 136 publications

(93 citation statements)

References 19 publications

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“…For example, reversible probes were developed [69][70][71][72][73] which can be oxidized and reduced in vivo enabling visualization of the cellular redox state. While this does not yield H 2 O 2 concentration data, it enables studies of the dynamic balance between oxidants and reductants.…”

Section: Oxidative Cleavage-based Probessupporting

confidence: 90%

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Possibilities and Challenges for Quantitative Optical Sensing of Hydrogen Peroxide

2017

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Abstract:Hydrogen peroxide (H 2 O 2 ) plays a key role in many biological processes spanning from coral bleaching, over cell signaling to aging. However, exact quantitative assessments of concentrations and dynamics of H 2 O 2 remain challenging due to methodological limitationsespecially at very low (sub µM) concentrations. Most published optical detection schemes for H 2 O 2 suffer from irreversibility, cross sensitivity to other analytes such as other reactive oxygen species (ROS) or pH, instability, temperature dependency or limitation to a specific medium. We review optical detection schemes for H 2 O 2 , compare their specific advantages and disadvantages, and discuss current challenges and new approaches for quantitative optical H 2 O 2 detection, with a special focus on luminescence-based measurements. We also review published concentration ranges for H 2 O 2 in natural habitats, and physiological concentrations in different biological samples to provide guidelines for future experiments and sensor development in biomedical and environmental science.

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Section: Oxidative Cleavage-based Probessupporting

confidence: 90%

“…However, the authors also state that this redox sensor can be re-oxidized even by air [71]. Another approach relies on the redox probe naphtopyran-benzothiazolium, which reacts with H 2 O 2 as well as bisulfite [139].…”

Section: Redox Systemsmentioning

confidence: 99%

Possibilities and Challenges for Quantitative Optical Sensing of Hydrogen Peroxide

2017

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“…For example, installation of boronic esters at the 3′ and 6′ positions of a xanthenone fluoran core produces Peroxyfluor-1 (PF1), where the boronates force this platform to adopt a closed, colorless, and non-fluorescent lactone form [34] and other ROS bursts by ratiometric imaging, indicators that can be targeted to specific subcellular regions to study localized signals, reagents that can respond to multiple oxidation and reduction cycles to visualize redox signaling and/or stress dynamics, and agents that can push toward imaging in whole organisms. We have made initial progress in the development of small-molecule ratiometric probes [37] and reversible redox sensors [38]. Finally, although this review has focused specifically on NO and H 2 O 2 indicators, new fluorogenic reagents for peroxynitrite [39], hypochlorous acid [40], superoxide [41], highly reactive oxygen species [42], and global nitrative stress [43] have also been reported recently.…”

Section: Small Molecule Fluorescent Probes For Hydrogen Peroxidementioning

confidence: 99%

Fluorescent probes for nitric oxide and hydrogen peroxide in cell signaling

Miller

Chang

2007

Current Opinion in Chemical Biology

160

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Nitric oxide (NO) and hydrogen peroxide (H 2 O 2 ) have emerged as essential small molecules for cellular signal transduction owing in large part to their ability to mediate oxidative posttranslational modifications (PTMs). Inventing new ways to track these small, diffusible, and reactive species with spatial and temporal resolution is a key challenge in elucidating their chemistry in living systems. Recent progress in the development of fluorescent probes that respond selectively to NO and H 2 O 2 produced at cell signaling levels offers a promising approach to interrogating their physiological production, accumulation, trafficking, and function.

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“…8 Thus, we anticipate widespread interest in a redoxreversible NIR fluorescent probe, which would exhibit much more value for visualizing cycles of redox signaling and stress caused by peroxynitrite. 9 Here we report a redox-responsive NIR fluorescent probe for continuous monitoring of ONOO À . ONOO À is modulated by cellular antioxidant defense systems, 1,10 in which selenium (Se) plays an important role as the active site of the antioxidant enzyme glutathione peroxidase (GPx).…”

mentioning

confidence: 99%

A Near-IR Reversible Fluorescent Probe Modulated by Selenium for Monitoring Peroxynitrite and Imaging in Living Cells

et al. 2011

J. Am. Chem. Soc.

542

265

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ABSTRACT:We have developed a near-IR reversible fluorescent probe containing an organoselenium functional group that can be used for the highly sensitive and selective monitoring of peroxynitrite oxidation and reduction events under physiological conditions. The probe effectively avoids the influence of autofluorescence in biological systems and gave positive results when tested in both aqueous solution and living cells. Real-time images of cellular peroxynitrite were successfully acquired. P eroxynitrite (ONOO À ) performs as a strong oxidizing agent in physiological and pathological processes. 1À3 In vivo, abnormally high concentrations of ONOO À are formed from the fast reaction between nitric oxide (NO) and superoxide anion (O 2 À ), which requires no enzymatic catalysis. 4 The peroxynitrite anion is relatively stable, but the acid form (ONOOH) rapidly decays to nitrate. Although the half-life of ONOOH is ∼1 s at pH 7.40, 5 the oxidative species contributes to signal transduction, homeostasis regulation, and oxidative damage, which forms a unique biological oxidationÀreduction cycle indicating human health and disease.6 Therefore, the development of reversible detection technology for peroxynitrite would have important biomedical significance. In comparison with other technologies, fluorescence microscopy provides greater sensitivity, less invasiveness, and more convenience.7 Especially the use of near-IR (NIR) light (650À900 nm) allows deep penetration into tissues and efficaciously avoids the influence of bioautofluorescence. However, there exists a major obstacle to the design of novel fluorescent probes for ONOO À , namely, the nitro group, which is considered to be a strong quencher for fluorophores.3 To date, only a few fluorescent probes for ONOO À detection have been reported. 8 Thus, we anticipate widespread interest in a redoxreversible NIR fluorescent probe, which would exhibit much more value for visualizing cycles of redox signaling and stress caused by peroxynitrite.9 Here we report a redox-responsive NIR fluorescent probe for continuous monitoring of ONOO À . ONOO À is modulated by cellular antioxidant defense systems, 1,10 in which selenium (Se) plays an important role as the active site of the antioxidant enzyme glutathione peroxidase (GPx).11 GPx can catalyze the reduction of ONOO À by glutathione (GSH) via a unique ping-pong mechanism.12 Taking the advantage of this, we mimicked the catalytic cycle and developed an NIR fluorescent probe containing an organoselenium moiety that can be used for reversible peroxynitrite detection.As an overall strategy, cyanine (Cy), an NIR fluorescent dye with a high extinction coefficient, 13 was selected as a signal transducer, while 4-(phenylselenyl)aniline (PSe) was selected as a modulator because it can respond sensitively to ONOO À . 11,14Following the ping-pong mechanism, 12 we designed and synthesized a new NIR reversible fluorescent probe (Cy-PSe) for detection of ONOO À in living cells through a fast photoinduced electron transfer (PET) process. ...

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A Fluorescent Sensor for Imaging Reversible Redox Cycles in Living Cells

Cited by 136 publications

References 19 publications

Possibilities and Challenges for Quantitative Optical Sensing of Hydrogen Peroxide

Possibilities and Challenges for Quantitative Optical Sensing of Hydrogen Peroxide

Fluorescent probes for nitric oxide and hydrogen peroxide in cell signaling

A Near-IR Reversible Fluorescent Probe Modulated by Selenium for Monitoring Peroxynitrite and Imaging in Living Cells

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