On the use of peroxy-caged luciferin (PCL-1) probe for bioluminescent detection of inflammatory oxidants in vitro and in vivo – Identification of reaction intermediates and oxidant-specific minor products

Zielonka, Jacek; Podsiadly, Radosław; Zielonka, Monika; Hardy, Micaël; Kalyanaraman, Balaraman

doi:10.1016/j.freeradbiomed.2016.07.023

Cited by 46 publications

(45 citation statements)

References 30 publications

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“…Boronates are oxidized more than a thousand times faster by HOCl than by H2O2 at neutral pH (44). The product of the reaction is a phenol (or alcohol), which may undergo chlorination in the presence of excess HOCl (47,51,57). To determine the source of the oxygen atom during the conversion of oMitoPhB(OH)2 into oMitoPhOH, we generated H 16 OCl and H 18 OCl in situ from myeloperoxidase (MPO)-catalyzed oxidation of chloride anions by H2 16 O2 and H2 18 O2, respectively (Fig.…”

Section: Hypochloritementioning

confidence: 99%

“…The omission of KCl or MPO resulted in a significantly lower yield of the product. Also, addition of small amounts of dimethyl sulfoxide (DMSO), known to rapidly scavenge HOCl (47,58), led to a significant attenuation of the formation of the phenolic product. Formation of HOCl was further confirmed by the detection of 2-Cl-E + in analogous systems, using the HE probe instead of the boronate (Fig.…”

Section: Hypochloritementioning

confidence: 99%

“…8), formed in 10% and 0.5% yields, respectively (51). Although the mechanism of the oxidation of boronates by ONOOhas been extensively studied, both experimentally and using theoretical calculations (44,45,47,49), the isotopelabeling studies have not been performed. We decided to test the proposed reaction mechanism by reacting oMitoPhB(OH)2 with 18 O-labeled ONOO -, produced in situ from co-generated fluxes of nitric oxide ( • NO) and 18 O2 •-(7,8).…”

Section: Peroxynitritementioning

confidence: 99%

“…In the presence of excess HOCl or ONOO -, the phenolic product may undergo chlorination or nitration, respectively, providing an opportunity to identify the oxidant by profiling the products formed (14,44). As an example, in the presence of HOCl, the peroxy-caged luciferin probe is converted not only to luciferin but also to chloroluciferin (47). The reaction of boronate probes with ONOOis of special interest, as this reaction typically proceeds via two pathways of the decomposition of peroxynitrite adduct to the boronate: (i) major pathway (~85%-90%) involving heterolytic cleavage of the peroxyl bond, leading to the formation the phenolic product; and (ii) minor pathway (10%-15%), involving a homolytic cleavage of the peroxyl bond, with the formation of phenyl-type radical and • NO2, which upon recombination form nitrobenzene-type product (Fig.…”

Section: New Insights Into the Selective Detection Of Peroxynitritementioning

confidence: 99%

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Tracking isotopically labeled oxidants using boronate-based redox probes

Ríos

Radí

Kalyanaraman

et al. 2020

Journal of Biological Chemistry

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Reactive oxygen and nitrogen species have been implicated in many biological processes and diseases, including immune responses, cardiovascular dysfunction, neurodegeneration, and cancer. These chemical species are short-lived in biological settings, and detecting them in these conditions and diseases requires the use of molecular probes that form stable, easily detectable, products. The chemical mechanisms and limitations of many of the currently used probes are not well-understood, hampering their effective applications. Boronates have emerged as a class of probes for the detection of nucleophilic two-electron oxidants. Here, we report the results of an oxygen-18–labeling MS study to identify the origin of oxygen atoms in the oxidation products of phenylboronate targeted to mitochondria. We demonstrate that boronate oxidation by hydrogen peroxide, peroxymonocarbonate, hypochlorite, or peroxynitrite involves the incorporation of oxygen atoms from these oxidants. We therefore conclude that boronates can be used as probes to track isotopically labeled oxidants. This suggests that the detection of specific products formed from these redox probes could enable precise identification of oxidants formed in biological systems. We discuss the implications of these results for understanding the mechanism of conversion of the boronate-based redox probes to oxidant-specific products.

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Section: Hypochloritementioning

confidence: 99%

Section: Hypochloritementioning

confidence: 99%

Section: Peroxynitritementioning

confidence: 99%

Section: New Insights Into the Selective Detection Of Peroxynitritementioning

confidence: 99%

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Tracking isotopically labeled oxidants using boronate-based redox probes

Ríos

Radí

Kalyanaraman

et al. 2020

Journal of Biological Chemistry

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“…5-40 K) is eminently suitable for detecting and investigating redox-active mitochondrial iron-sulfur proteins (aconitase and mitochondrial respiratory chain complexes) (7)(8)(9). During the last decade, much progress has been made with respect to understanding the mechanisms of ROS-induced oxidation of fluorescent, chemiluminescent, and bioluminescent probes (10,11). A comprehensive understanding of the kinetics, stoichiometry, and intermediate and product analyses of several ROS probes in various ROS-generating systems makes it possible to investigate these species in cells and tissues (12)(13)(14)(15).…”

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confidence: 99%

Detection of mitochondria-generated reactive oxygen species in cells using multiple probes and methods: Potentials, pitfalls, and the future

Cheng¹,

Zielonka²,

Dranka³

et al. 2018

Journal of Biological Chemistry

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Reactive oxygen and nitrogen species (ROS/RNS) such as superoxide (O), hydrogen peroxide, lipid hydroperoxides, peroxynitrite, and hypochlorous and hypobromous acids play a key role in many pathophysiological processes. Recent studies have focused on mitochondrial ROS as redox signaling species responsible for promoting cell division, modulating and regulating kinases and phosphatases, and activating transcription factors. Many ROS also stimulate cell death and senescence. The extent to which these processes occur is attributed to ROS levels (low or high) in cells. However, the exact nature of ROS remains unknown. Investigators have used redox-active probes that, upon oxidation by ROS, yield products exhibiting fluorescence, chemiluminescence, or bioluminescence. Mitochondria-targeted probes can be used to detect ROS generated in mitochondria. However, because most of these redox-active probes (untargeted and mitochondria-targeted) are oxidized by several ROS species, attributing redox probe oxidation to specific ROS species is difficult. It is conceivable that redox-active probes are oxidized in common one-electron oxidation pathways, resulting in a radical intermediate that either reacts with another oxidant (including oxygen to produce O) and forms a stable fluorescent product or reacts with O to form a fluorescent marker product. Here, we propose the use of multiple probes and complementary techniques (HPLC, LC-MS, redox blotting, and EPR) and the measurement of intracellular probe uptake and specific marker products to identify specific ROS generated in cells. The low-temperature EPR technique developed to investigate cellular/mitochondrial oxidants can easily be extended to animal and human tissues.

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N‐Heterocyclic Carbene Boranes as Reactive Oxygen Species‐Responsive Materials: Application to the Two‐Photon Imaging of Hypochlorous Acid in Living Cells and Tissues

Pak

Park

et al. 2018

Angewandte Chemie

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N‐Heterocyclic carbene (NHC) boranes undergo oxidative hydrolysis to give imidazolium salts with excellent kinetic selectivity for HOCl over other reactive oxygen species (ROS), including peroxides and peroxynitrite. Selectivity for HOCl results from the electrophilic oxidation mechanism of NHC boranes, which stands in contrast to the nucleophilic oxidation mechanism of arylboronic acids with ROS. The change in polarity that accompanies the conversion of NHC boranes to imidazolium salts can control the formation of emissive excimers, forming the basis for the design of the first fluorescence probe for ROS based on the oxidation of B−H bonds. Two‐photon microscope (TPM) ratiometric imaging of HOCl in living cells and tissues is demonstrated.

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On the use of peroxy-caged luciferin (PCL-1) probe for bioluminescent detection of inflammatory oxidants in vitro and in vivo – Identification of reaction intermediates and oxidant-specific minor products

Cited by 46 publications

References 30 publications

Tracking isotopically labeled oxidants using boronate-based redox probes

Tracking isotopically labeled oxidants using boronate-based redox probes

Detection of mitochondria-generated reactive oxygen species in cells using multiple probes and methods: Potentials, pitfalls, and the future

N‐Heterocyclic Carbene Boranes as Reactive Oxygen Species‐Responsive Materials: Application to the Two‐Photon Imaging of Hypochlorous Acid in Living Cells and Tissues

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