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Application Techniques of Electron Spin Resonance

DIVISION OF INTRAMURAL RESEARCH. Laboratory of Pharmacology and Chemistry. Application Techniques of Electron Spin Resonance. Ronald P. Mason and JinJie Jiang National Institute of Environmental Health Sciences, NIH Research Triangle Park, NC 27709. Methods Direct ESR Spin-Trapping.

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Application Techniques of Electron Spin Resonance

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  1. DIVISION OF INTRAMURAL RESEARCH Laboratory of Pharmacology and Chemistry Application Techniques of Electron Spin Resonance Ronald P. Mason and JinJie Jiang National Institute of Environmental Health Sciences, NIH Research Triangle Park, NC 27709

  2. Methods • Direct ESR • Spin-Trapping • Techniques • Freeze Quench • Snap Freeze • Flat Cells • AquaX • Steady-State • Fast-Flow • Stopped-Flow • Rapid Sampling • Folch Extraction • Bile Cannulation • Other Techniques • Applications • In Vivo • In Vitro • In Situ

  3. Direct ESR • “Freeze” the reaction • freeze quench (in vitro) • snap freeze (in vitro,ex vivo) • Steady-State • Rapid sampling (in vitro ) • Fast-flow (in vitro)

  4. Freeze Quench: O-17 Hyperfine Splitting in Electron Paramagnetic Resonance Spectrum of Enzymically Generated Superoxide The electron paramagnetic resonance spectrum of 17O in O2.- generated during steady-state oxidation of xanthine catalyzed by xanthine oxidase. Both the 11-line spectrum from 17O17O.- and the six-line spectrum from 17O16O.- were detected. The results provide final confirmation that one-electron reduction of oxygen can occur in biological systems Bray, R.C., Pick, F.M. and Samuel, D., Eur J. Biochem, 15 352-355, 1970

  5. Snap Freeze: Detection of Nitrosyl Hemoglobin in Venous Blood in the Treatment of Sickle Cell Anemia with Hydroxyurea The nitrosyl hemoglobin complex could bedetected as early as 30 min after administration of hydroxyurea and persistedup to 4 h. Our observations support the hypothesis that the abilityof hydroxyurea to ease the vaso-occlusive phenomena may, in part, be attributedto vasodilation and/or decreased platelet activation induced bynitric oxide. Glover RE, Ivy ED, Orringer EP, Maeda H, Mason RP, Mol. Pharm., 55 1006-1010, 1999

  6. 10 2 mMs-1 R. X R.+ R. 1 R. (mM) 8 X 105 M -1s-1 R-R 0.1 0 200 400 600 800 1000 1200 Time (S) 1.2 1.0 100 0.8 R-R (mM) 0.6 X (mM) 0.4 10 0.2 0.0 0 200 400 600 800 1000 1200 1 Time (S) 0 200 400 600 800 1000 1200 Time (S) Steady-State Condition Is When the Rate of Formation Is Equal to the Rate of Decay Mendes, P. Mendes, P., GEPASI: A software package for modeling the dynamics, steady states and control of biochemical and other systems. Comput. Applic. Biosci. 9, 563-571, 1993

  7. NADP+ Glucose-6-phosphate Glucose-6-phosphate dehydrogenase KCl-Tris-MgCl2 buffer: 150 mM KCl, 20 mM Tris (pH7.4), and 5 mM MgCl2 Nitrobenzene Detection of Nitrobenzene Anion Radical in An Anaerobic Microsomal Incubation Protocol 1. Equipment and reagents • Fresh rat liver microsomes (40 mg protein/ml) • Rubber stopped serum bottle • Nitrogen tank (oxygen-free) • ESR spectrometer • A. Preparation of incubation mixture • Mix nitrobenzene (2 mM) and an NADPH-generating system consisting of NADP+ (0.8 mM), glucose-6-phosphate (11 mM), and 4 units of glucose-6-phosphate dehydrogenase in 3 ml of KCl-Tris-MgCl2 buffer. • Add to rubber-stopped serum bottle. • Bubble nitrogen gas into solutions for 5 min with the only exit being through the aqueous flat cell. • Add 12 mg of rat hepatic microsomal protein through the rubber stopper with a syringe. • Continue bubbling with nitrogen gas for 20 sec.

  8. Apparatus for Filling The ESR Flat Cell under A Nitrogen Atmosphere Mason, R.P.: Assay of in situ radicals by electron spin resonance. Meth. Enzymol. 105:416‑422, 1984

  9. Protocol 1. (continue) • B. Sample handling • Lower the stainless-steel needle tubing below the surface of the solution. • Force solution into the aqueous flat cell with pressure of the nitrogen gas until full. • Close ground glass cap and vent nitrogen pressure by inserting a second needle into the rubber stopper. • Remove needle tubing from the force-fitted septum in the bottom of the flat cell. • Mount the flat cell in the microwave cavity with aqueous cell holders. • Tune and operate ESR spectrometer to obtain spectrum of nitrobenzene anion radical. Mason, R.P.: In vitro and in vivo detection of free radical metabolites with electron spin resonance. In: Punchard, N.A. and Kelly, F.J. (Eds.), Free Radicals: A Practical Approach. IRL Press at Oxford University Press, New York, pp. 11-24, 1996.

  10. Apparatus for Filling The ESR Flat Cell under A Nitrogen Atmosphere Mason, R.P.: Assay of in situ radicals by electron spin resonance. Meth. Enzymol. 105:416‑422, 1984

  11. Electron Spin Resonance Evidence for Nitroaromatic Free Radical Intermediates Spectrum a is of 1.1 mM p-nitrobenzoate dianion radical formed in a microsomal incubation. Spectrum b is nitrobenzene anion radical under the same conditions as spectrum a. Spectrum c is of 0.2 mM nitrobenzene anion radical formed in a mitochondrial incubation. Mason, R.P. and Holtzman, J.L., Biochemistry 14:1626‑1632, 1975.

  12. 0.1 R. 2 mMs-1 X R.+ R. R. (mM) 5 X 109 M -1s-1 R-R 0.01 0 200 400 600 800 1000 1200 Time (S) 100 X (mM) 10 1 0 200 400 600 800 1000 1200 Time (S) Nearly Undetectable Radical Formation When Radical Decay Is Diffusion Limited 1.2 1.0 0.8 R-R (mM) 0.6 0.4 0.2 0.0 0 200 400 600 800 1000 1200 Time (S)

  13. R. 200 mMs-1 X R.+ R. 5 X 109 M-1s-1 R-R 5 10 4 8 3 6 X (mM) R-R (mM) 2 4 1 2 0 0 0 200 400 600 800 1000 1200 0 200 400 600 800 1000 1200 Time (S) Time (S) Steady-State Condition Is Unsustainable with Rapid Substrate Depletion 0.14 0.12 0.10 R. (mM) 0.08 0.06 0.04 0.02 0 0 200 400 600 800 1000 1200 Time (S)

  14. Fast-Flow Technique for Obtaining Steady-State Condition with Rapid Substrate Depletion

  15. ESR Spectroscopy Employing A Millisecond Time Scale Fast-Flow Method Has Revealed the Formation of a Transient Phenoxyl Radical in the Reaction of Acetaminophen with Horseradish Peroxidase/H2O2 and Bovine Lactoperoxidase/H2O2 Fischer, V., Harman L.S., West P.R., and R.P. Mason, Chem.-Biol. Interactions, 60, 115-127, 1986

  16. Spin-Trapping • Selecting the spin trap (stability, adduct stability, distributions, toxicity, trapping efficiency, solubility, structure information, etc.) • Artifacts and control experiments • Increase the spin adduct concentration: extraction • Identify the radicals • Increase sensitivity: flat cells, etc.

  17. Protocol 2. In Vivo Spin Trapping of the Trichloromethyl Radical Metabolite of Carbon Tetrachloride Equipment and reagents • Male, Sprague-Dawley rats: 250-300 g • Phenyl-tert-butylnitrone (PBN): 1 ml of a 140 mM solution in 20 mM phosphate buffer, pH 7.4 • Carbon tetrachloride: 1.2 ml/kg body weight • Corn oil • Chloroform • Methanol • Anhydrous sodium sulfate • Nitrogen tank • No plasticware (will leach nitroxides into organic solvents) • A. Administration of spin trap and CCl4 • Fast the rats for 20 h. • Homogenize CCl4, PBN, or both with corn oil. • Administer by stomach tube. • with nitrogen gas for 20 sec.

  18. Protocol 2. (continue) • B. Folch extraction and sample handling • Kill treated rats after 2 h. • Immediately remove livers and homogenize in chloroform-methanol (2:1, v/v) in glass according to reference. • Dry sample with anhydrous sodium sulfate. • Remove chloroform layer and evaporate solvent under nitrogen gas until volume is reduced to 0.5 ml. • Transfer sample to 3 mm quartz tube and slowly bubble with nitrogen gas for 3 min using long needle or tubing. • Mount sample and tune and operate ESR spectrometer to obtain six-line spectrum of the PBN-trichloromethyl radical adduct.

  19. Spin Trapping in Vivo of the Trichloromethyl Radical Metabolite of CCl4 Hanna, P.M., Kadiiska, M.B., Jordan, S.J., and Mason, R.P., Chem. Res. Toxicol., 6, 711-717, 1993.

  20. Protocol 3. Biliary Detection of Radical Adduct of Halothane-Derived Free Radical Metabolite Equipment and reagents • Male rats: 350-400 g • Halothane • PBN: 50 mg/kg dissolved in deionized water at 140 mM • Oxygen and nitrogen tanks • Eppendorf tubes • Dry ice • Potassium ferricyanide • Polyethylene tubing (0.28 mm i.d. and 0.61 mm o.d.) • ESR spectrometer • A. Administration of spin trap and BrClCHCF3 • Fast the rats for 20 h. • Anaesthetize rat with Nembutal. • Cannulate bile duct with a segment of polyethylene tubing. • Inject PBN i.p. and BrClCHCF3 i.g.

  21. Protocol 3. (continue) • B. Collection and treatment of bile • Collect bile every 15 min into plastic Eppendorf tubes. • Freeze immediately on dry ice and store at –70oC until ESR analysis (within a few days). • Thaw bile and transfer to quartz flat cell. • Bubble with oxygen to oxidize reduced radical adducts and then with nitrogen to narrow the spectral line width (or add 0.1-1 mM potassium ferricyanide). • Mount the flat cell in the microwave cavity with aqueous cell holders. • Tune and operate ESR spectrometer to obtain spectrum of two BrClCHCF3-derived radical adducts.

  22. Bile samples collected every 20 min for 2 h in tube containing DP and BC

  23. Free Radical Metabolism of Halothane in Vivo: Radical Adducts Detected in Bile Knecht, K.T., DeGray, J.A., and Mason, R.P., Mol. Pharmacol. 41: 943-949, 1992.

  24. Rapid Sampler Technique with Gilford Rapid Sampler Mason, R.P.: Assay of in situ radicals by electron spin resonance. Meth. Enzymol. 105:416‑422, 1984

  25. Rapid Sampler Technique with Commercial Bruker Auto-Sampler and AquaX

  26. Metronidazole Anion Radical O2.- NADP+ FH2 RNO2 FH. . RNO2- NADPH F O2 Perez-Reyes, E., Kalyanaraman, B., and Mason, R.P., Mol. Pharmacol. 17:239‑244, 1980

  27. 10 2 mMs-1 R. X R.+ R. 1 R. (mM) 8 X 105 M -1s-1 R-R 0.1 0 200 400 600 800 1000 1200 Time (S) 1.2 1.0 100 0.8 R-R (mM) 0.6 X (mM) 0.4 10 0.2 0.0 0 200 400 600 800 1000 1200 1 Time (S) 0 200 400 600 800 1000 1200 Time (S) Steady-State Metronidazole Anion Radical under Anaerobic Conditions

  28. ESR Spectrum of Metronidazole Anion Radical and Computer Simulation

  29. DMPO Superoxide Radical Adduct Formed by Futile (Redox) Cycling of Metronidazole Anion Radical

  30. Time Course of DMPO Superoxide Adduct and Metronidazole Anion Radical B0

  31. Kinetic Simulation of DMPO Superoxide Adduct and Metronidazole Anion Radical Appearance and Disappearance 60 200 40 O2 (mM) DMPO/O2.- (mM) 100 20 0 0 0 200 400 600 800 1000 1200 600 0 200 400 800 1000 1200 Time (s) Time (s) 80 mMs-1 0.8 R. X 0.6 8 X 105 M -1s-1 R. +R. R-R 0.4 R. (mM) 7.8 X 106 M -1s-1 0.2 X + O2.- R.+ O2 0.0 2 X 105 M -1s-1 O2.- + O2.- 0 200 400 600 800 1000 1200 O2 + H2O2 Time (s) 1.7 X 102 M -1s-1 DMPO + O2.- DMPO/O2.- 1.2 X 10-2 s-1 DMPO/O2.- DMPOx

  32. Summary of How to Catch A Radical • Stop decay by freezing • Freeze quench (millisecond) • Snap freeze (seconds) • Steady-state by continuous generation • Flat cells with ample substrates • Rapid sampling for kinetics on second time scale • Fast-flow for radicals with diffusion-limited second-order decay • Spin trapping • Has a higher steady-state concentration than direct ESR because of the slower decay rate of the radical adduct • In vivo spin trapping is possible for extremely stable radical adducts

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