Detection and Characterization of Reactive Oxygen and Nitrogen Species in Biological Systems by Monitoring Species-Specific Products
Micael Hardy, Jacek Zielonka, Hakim Karoui, Adam Sikora, Radoslaw Michalski, Radoslaw Podsiadly, Marcos Lopez, Jeannette Vasquez-Vivar, Balaraman Kalyanaraman, Olivier Ouari
Antioxidants & Redox Signaling, (2018)
Detection and Characterization of Reactive Oxygen and Nitrogen Species in Biological Systems by Monitoring Species-Specific Products
Micael Hardy, Jacek Zielonka, Hakim Karoui, Adam Sikora, Radoslaw Michalski, Radoslaw Podsiadly, Marcos Lopez, Jeannette Vasquez-Vivar, Balaraman Kalyanaraman, Olivier Ouari
Antioxidants & Redox Signaling, (2018)
Significance: Since the discovery of the superoxide dismutase enzyme, the generation and fate of short-lived oxidizing, nitrosating, nitrating, and halogenating species in biological systems has been of great interest. Despite the significance of reactive oxygen species (ROS) and reactive nitrogen species (RNS) in numerous diseases and intracellular signaling, the rigorous detection of ROS and RNS has remained a challenge. Recent Advances: Chemical characterization of the reactions of selected ROS and RNS with electron paramagnetic resonance (EPR) spin traps and fluorescent probes led to the establishment of species-specific products, which can be used for specific detection of several forms of ROS and RNS in cell-free systems and in cultured cells in vitro and in animals in vivo. Profiling oxidation products from the ROS and RNS probes provides a rigorous method for detection of those species in biological systems. Critical Issues: Formation and detection of species-specific products from the probes enables accurate characterization of the oxidative environment in cells. Measurement of the total signal (fluorescence, chemiluminescence, etc.) intensity does not allow for identification of the ROS/RNS formed. It is critical to identify the products formed by using chromatographic or other rigorous techniques. Product analyses should be accompanied by monitoring of the intracellular probe level, another factor controlling the yield of the product(s) formed. Future Directions: More work is required to characterize the chemical reactivity of the ROS/RNS probes, and to develop new probes/detection approaches enabling real-time, selective monitoring of the specific products formed from the probes.
Photogenerated Radical in Phenylglyoxylic Acid for in Vivo Hyperpolarized C-13 MR with Photosensitive Metabolic Substrates
Irene Marco-Rius, Tian Cheng, Adam P. Gaunt, Saket Patel, Felix Kreis, Andrea Capozzi, Alan J. Wright, Kevin M. Brindle, Olivier Ouari, Arnaud Comment,
Journal of the American Chemical Society, 140 14455-14463 (2018)
Photogenerated Radical in Phenylglyoxylic Acid for in Vivo Hyperpolarized C-13 MR with Photosensitive Metabolic Substrates
Irene Marco-Rius, Tian Cheng, Adam P. Gaunt, Saket Patel, Felix Kreis, Andrea Capozzi, Alan J. Wright, Kevin M. Brindle, Olivier Ouari, Arnaud Comment,
Journal of the American Chemical Society, 140 14455-14463 (2018)
Whether for C-13 magnetic resonance studies in chemistry, biochemistry, or biomedicine, hyperpolarization methods based on dynamic nuclear polarization (DNP) have become ubiquitous. DNP requires a source of unpaired electrons, which are commonly added to the sample to be hyperpolarized in the form of stable free radicals. Once polarized, the presence of these radicals is unwanted. These radicals can be replaced by nonpersistent radicals created by the photoirradiation of pyruvic acid (PA), which are annihilated upon dissolution or thermalization in the solid state. However, since PA is readily metabolized by most cells, its presence may be undesirable for some metabolic studies. In addition, some C-13 substrates are photosensitive and therefore may degrade during the photogeneration of a PA radical, which requires ultraviolet (UV) light. We show here that the photoirradiation of phenylglyoxylic acid (PhGA) using visible light produces a nonpersistent radical that, in principle, can be used to hyperpolarize any molecule. We compare radical yields in samples containing PA and PhGA upon photoirradiation with broadband and narrowband UV-visible light sources. To demonstrate the suitability of PhGA as a radical precursor for DNP, we polarized the gluconeogenic probe C-13-dihydroxyacetone, which is UV-sensitive, using a commercial 3.35 T DNP polarizer and then injected this into a mouse and followed its metabolism in vivo.