Cell-trappable fluorescent probes for endogenous hydrogen sulfide signaling and imaging H
 2
 O
 2
 -dependent H
 2
 S production

In comparison with other biological detection technologies, fluorescence bioimaging technology has become a powerful supporting tool for intracellular detection, and can provide attractive facilities for investigating physiological and pathological processes of interest with high spatial and temporal resolution, less invasiveness, and a rapid response. Due to the versatile roles of hydrogen sulfide (H 2 S) in cellular signal transduction and intracellular redox status regulation, fluorescent probes for the detection of this third signalling gasotransmitter have rapidly increased in number in recent years. These probes can offer powerful means to investigate the physiological actions of H 2 S in its native environments without disturbing its endogenous distribution. In this feature article, we address the synthesis and design strategies for the development of fluorescent probes for H 2 S based on the reaction type between H 2 S and the probes. Moreover, we also highlight fluorescent probes for other reactive sulfur species, such as sulfane sulfurs and SO 2 derivatives.

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“…8,9 The fluorophores of these probes were based on Rhodamine 110. The detection mechanism was illustrated in Fig.…”

Section: Fluorescent Probes Based On Reducing Azides To Aminesmentioning

confidence: 99%

Fluorescent probes for hydrogen sulfide detection and bioimaging

2014

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“…Numerous cellular functions are closely correlated with small molecules, such as O 2 , 4 glucose, 5 glutathione, 6 NO, 7 CO 8 and H 2 O 2 , 9 for enzymatic co-factors, signaling and expression. Among them, H 2 O 2 is an important reactive oxygen species that can diffuse across cell membranes and lead to oxidative protein modification.…”

Section: Introductionmentioning

confidence: 99%

Bio-inspired porous antenna-like nanocube/nanowire heterostructure as ultra-sensitive cellular interfaces

Kong

Tang

et al. 2014

NPG Asia Mater

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In this study, an unconventional antenna-like heterostructure comprised of arrays of nanoporous Prussian blue (PB) nanocube heads/TiO 2 nanowire (NW) arms (PB-TiO 2 ) is developed for efficient three-dimensional interfacial sensing of small molecules and cellular activities. Inspired by insect tentacles, which are comprised of both target recognition and signal transduction units, one-dimensional TiO 2 NW arrays are grown, followed by selective growth of nanoporous PB nanocubes on the tips of the NW arrays. Due to their high selectivity and bioaffinity toward cells, long biostability under a cell culture adhesion condition (up to 108 h) is obtained, and with its inherent bio-mimetic enzymatic activity, the obtained nanoporous PB nanocubes (head segment) serve as robust substrates for site-selective cell adhesion and culture, which allows for sensitive detection of H 2 O 2 . Simultaneously, the single-crystalline TiO 2 NWs (arm segment) provide efficient charge transport for electrode substrates. Compared with PB-functionalized planar electrochemical interfaces, the PB-TiO 2 antenna NW biointerfaces exhibit a substantial enhancement in electrocatalytic activity and sensitivity for H 2 O 2 , which includes a low detection limit (B20 nM), broad detection range (10 À8 to 10 À5 M), short response time (B5 s) and long-term biocatalytic activity (up to 6 months). The direct cultivation of HeLa cells is demonstrated on the PB-TiO 2 antenna NW arrays, which are capable of sensitive electrochemical recording of cellular activity in real time, where the results suggest the uniqueness of the biomimic PB-TiO 2 antenna NWs for efficient cellular interfacing and molecular recognition.

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“…Recently, they further reported a novel possible pathway for the production of H 2 S from D-cysteine in mammalian cells 12 . As new biogenesis and biological functions of H 2 S continue to emerge [12][13][14][15] , new biocompatible tools to selectively visualize cellular H 2 S in real-time at its site of release are urgently needed 11 .Fluorescent probes could be used for H 2 S detection in a non-invasive manner in living systems [13][14][15][16][17] . The probebased tools have been successfully used to image endogenous H 2 S production from thiol substrates including LCys and glutathione (GSH) 13 or by vascular endothelial growth factor stimulation 17 .…”

mentioning

confidence: 99%

“…The probebased tools have been successfully used to image endogenous H 2 S production from thiol substrates including LCys and glutathione (GSH) 13 or by vascular endothelial growth factor stimulation 17 . Inspired by these work 13,17 , we are interested to image endogenous H 2 S production of all possible pathways in living cells semi-quantitatively or quantitatively, based on ratiometric probes rather than intensity-based probes, in view of that ratiometric measurements can cancel out variability caused by uneven loading and distribution of fluorescence probes in cells 18 .…”

mentioning

confidence: 99%

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FRET ratiometric probes reveal the chiral-sensitive cysteine-dependent H2S production and regulation in living cells

Song

et al. 2014

Sci Rep

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Hydrogen sulfide (H 2 S) is an endogenously produced gaseous signalling molecule with multiple biological functions. In order to visualize and quantify the endogenous in situ production of H 2 S in living cells, here we developed two new sulphide ratiometric probes (SR400 and SR550) based on fluorescence resonance energy transfer (FRET) strategy for live capture of H 2 S. The FRET-based probes show excellent selectivity toward H 2 S in a high thiol background under physiological buffer. The probe can be used to in situ visualize cysteine-dependent H 2 S production in a chiral-sensitive manner in living cells. The ratiometric imaging studies indicated that D-Cys induces more H 2 S production than that of L-Cys in mitochondria of human embryonic kidney 293 cells (HEK293). The cysteine mimics propargylglycine (PPG) has also been found to inhibit the cysteine-dependent endogenous H 2 S production in a chiral-sensitive manner in living cells. D-PPG inhibited D-Cys-dependent H 2 S production more efficiently than L-PPG, while, L-PPG inhibited L-Cys-dependent H 2 S production more efficiently than D-PPG. Our bioimaging studies support Kimura's discovery of H 2 S production from D-cysteine in mammalian cells and further highlight the potential of D-cysteine and its derivatives as an alternative strategy for classical H 2 S-releasing drugs.H ydrogen sulfide (H 2 S) is an important endogenous signalling molecule along with nitric oxide (NO) and carbon monoxide (CO) 1-3 . H 2 S has also been demonstrated to exert protective effects such as preservation of mitochondrial function, protection of neurons from oxidative stress, inhibition of apoptosis, intervention of neuronal transmission, regulation of inflammation, stimulation of angiogenesis, reduce blood pressure, etc 4-7 . The deregulation of endogenous H 2 S is correlated with the symptoms of Alzheimer's disease, Down syndrome, diabetes and liver cirrhosis [8][9][10] . Kimura et al. indicated that H 2 S is enzymatic generated from L-cysteine (L-Cys) and its derivatives in vivo 7,11 . Recently, they further reported a novel possible pathway for the production of H 2 S from D-cysteine in mammalian cells 12 . As new biogenesis and biological functions of H 2 S continue to emerge [12][13][14][15] , new biocompatible tools to selectively visualize cellular H 2 S in real-time at its site of release are urgently needed 11 .Fluorescent probes could be used for H 2 S detection in a non-invasive manner in living systems [13][14][15][16][17] . The probebased tools have been successfully used to image endogenous H 2 S production from thiol substrates including LCys and glutathione (GSH) 13 or by vascular endothelial growth factor stimulation 17 . Inspired by these work 13,17 , we are interested to image endogenous H 2 S production of all possible pathways in living cells semi-quantitatively or quantitatively, based on ratiometric probes rather than intensity-based probes, in view of that ratiometric measurements can cancel out variability caused by uneven loading and distribution of...

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Cell-trappable fluorescent probes for endogenous hydrogen sulfide signaling and imaging H ₂ O ₂ -dependent H ₂ S production

Cited by 343 publications

References 64 publications

Fluorescent probes for hydrogen sulfide detection and bioimaging

Fluorescent probes for hydrogen sulfide detection and bioimaging

Bio-inspired porous antenna-like nanocube/nanowire heterostructure as ultra-sensitive cellular interfaces

FRET ratiometric probes reveal the chiral-sensitive cysteine-dependent H2S production and regulation in living cells

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Cell-trappable fluorescent probes for endogenous hydrogen sulfide signaling and imaging H 2 O 2 -dependent H 2 S production

Cited by 343 publications

References 64 publications

Fluorescent probes for hydrogen sulfide detection and bioimaging

Fluorescent probes for hydrogen sulfide detection and bioimaging

Bio-inspired porous antenna-like nanocube/nanowire heterostructure as ultra-sensitive cellular interfaces

FRET ratiometric probes reveal the chiral-sensitive cysteine-dependent H2S production and regulation in living cells

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Product

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Cell-trappable fluorescent probes for endogenous hydrogen sulfide signaling and imaging H ₂ O ₂ -dependent H ₂ S production