Characterization of the Radical Trapping Activity of a Novel Series of Cyclic Nitrone Spin Traps (∗)

• Published in: The Journal of biological chemistry Vol. 271; no. 6; pp. 3097 - 3104
• Main Authors: Thomas, Craig E., Ohlweiler, David F., Carr, Albert A., Nieduzak, Thaddeus R., Hay, David A., Adams, Ginette, Vaz, Roy, Bernotas, Ronald C.
• Format: Journal Article
• Language: English
• Published: United States Elsevier Inc 09.02.1996; American Society for Biochemistry and Molecular Biology
• Subjects: Animals; Cyclic N-Oxides - chemical synthesis; Cyclic N-Oxides - chemistry; Cyclic N-Oxides - pharmacology; Electron Spin Resonance Spectroscopy; Free Radicals - analysis; Hydroxyl Radical; Iron - toxicity; Isoquinolines - pharmacology; Lipid Peroxidation - drug effects; Liposomes; Mice; Models, Molecular; Models, Structural; Nitrogen Oxides - chemical synthesis; Nitrogen Oxides - chemistry; Nitrogen Oxides - pharmacology; Oxidative Stress; Spin Labels; Structure-Activity Relationship; Superoxides; Xanthine Oxidase - metabolism
• ISSN: 0021-9258; 1083-351X
• DOI: 10.1074/jbc.271.6.3097

α-Phenyl-tert-butyl nitrone (PBN) is a nitrone spin trap, which has shown efficacy in animal models of oxidative stress, including stroke, aging, sepsis, and myocardial ischemia/reperfusion injury. We have prepared a series of novel cyclic variants of PBN and evaluated them for radical trapping activity in vitro. Specifically, their ability to inhibit iron-induced lipid peroxidation in liposomes was assessed, as well as superoxide anion (O∸2) and hydroxyl radical (•OH) trapping activity as determined biochemically and using electron spin resonance (ESR) spectroscopy. All cyclic nitrones tested were much more potent as inhibitors of lipid peroxidation than was PBN. The unsubstituted cyclic variant MDL 101,002 was approximately 8-fold more potent than PBN. An analysis of the analogs of MDL 101,002 revealed a direct correlation of activity with lipophilicity. However, lipophilicity does not solely account for the difference between MDL 101,002 and PBN, inasmuch as the calculated octanol/water partition coefficient for MDL 101,002 is 1.01 as compared to 1.23 for PBN. This indicated the cyclic nitrones are inherently more effective radical traps than PBN in a membrane system. The most active compound was a dichloro analog in the seven-membered ring series (MDL 104,342), which had an IC50 of 26 μM, which was 550-fold better than that of PBN. The cyclic nitrones were shown to trap •OH with MDL 101,002 being 20-25 times more active than PBN as assessed using 2-deoxyribose and p-nitrosodimethylaniline as substrates, respectively. Trapping of •OH by MDL 101,002 was also examined by using ESR spectroscopy. When Fenton's reagent was used, the •OH adduct of MDL 101,002 yielded a six-line spectrum with hyperfine coupling constants distinct from that of PBN. Importantly, the half-life of the adduct was nearly 5 min, while that of PBN is less than 1 min at physiologic pH. MDL 101,002 also trapped the O∸2 radical to yield a six-line spectrum with coupling constants very distinct from that of the •OH adduct. In mice, the cyclic nitrones ameliorated the damaging effects of oxidative stress induced by ferrous iron injection into brain tissue. Similar protection was not afforded by the lipid peroxidation inhibitor U74006F, thus implicating radical trapping as a unique feature in the prevention of cell injury. Together, the in vivo activity, the stability of the nitroxide adducts, and the ability to distinguish between trapping of •OH and O∸2 suggest the cyclic nitrones to be ideal reagents for the study of oxidative cell injury.