The group continued to implement and validate the technique called immuno-spin trapping, which combines the specific free radical reactivity of the DMPO (5,5-dimethyl-1-pyrroline N-oxide) spin trap with nitrone-antibody sensitivity. Anti-DMPO has proven itself to be a highly specific antibody with the no-DMPO control easily identifying any non specificity issues. This type of control is uncommon among antibody work, but is of great utility. Unlike electron spin resonance (ESR) detection of radical intermediates, anti-DMPO immuno-spin trapping is not dependent on transient free radical intermediates and is about 10,000 times more sensitive than ESR and 100 times more sensitive than MS. In the last four years we have continued using the immuno-spin trapping approach to investigate the formation of protein-centered free radicals in vitro, in cells, and in vivo. The immunoassay has many advantages compared to ESR spin-trapping: 1) immuno-spin trapping requires much less material (micrograms of protein rather than milligrams); 2) the stability of the final oxidation product, the DMPO-nitrone adduct (a stable non-radical species), is much greater than that of the paramagnetic DMPO-radical adducts (t1/2 = sec-min) required for ESR, resulting in greatly enhanced sensitivity, and 3) immuno-spin trapping can be performed using standard ELISA, Western blotting techniques, and immuno-histological techniques, making immuno-spin trapping far more accessible and versatile than ESR spin trapping. This advance greatly expanded the utility of the spin-trapping technique, freeing it from the quantum mechanical complexity of ESR spectroscopy. The major limitation of the anti-DMPO methodology is the inability to identify the low abundance site(s) of protein radical formation even with MS in any sample other than purified proteins. As an alternative approach to this problem, we have decided to try to develop amino acid-specific anti-DMPO antibodies. Oxidative stress-related damage to the DNA macromolecule produces a multitude of lesions that are implicated in mutagenesis, carcinogenesis, reproductive cell death, and aging. Recently we have measured DNA damage induced by a Cu(II)-H2O2 oxidizing system using not only immuno-spin trapping, but ESR, MS, and MS/MS. The LC-MS/MS analysis of total DNA digests characterized an adenosine-DMPO adduct in both calf thymus and cellular DNA. The MS detection of this nucleoside nitrone adduct from cells is notable because we have always failed in attempting to identify protein nitrone adducts from cells. The ease of purification of DNA in contrast to a specific protein and the fact that DNA has only four components are major advantages in the MS investigation of DNA products. We are narrowing our MS search for nucleoside nitrone adducts by using competitive ELISA to identify the HPLC fractions containing the DMPO nitrone adducts. Once this method is perfected we will search for nucleoside nitrone adducts in a cell model of arsenic carcinogenicity, which is thought to have multiple but poorly defined modes of action. DMPO does not generally form adducts with tryptophan radicals. To address this problem, we have developed immuno-detection of oxidatively modified tryptophan residues in proteins, comparable to anti-DMPO immuno-spin trapping of radicals, with the aim of providing a more accessible means for localizing radical and singlet oxygen post-translational protein modifications. The initial study describing the development and validation antiserum to the tryptophan oxidation product N-formylkynurenine (NFK) showed that the antiserum was specific for detection of proteins containing tryptophan residues with cleaved indole rings and that it is sensitive enough to detect NFK in proteins with as few as one or two tryptophan residues and in mixtures of proteins. Subsequent work has used the anti-NFK antiserum to study subcellular localization of NFK-containing proteins in cultured skin cells, photosensitization in human lens epithelial cells, and oxidation of proteins in mice. Other work has led to the publication of two papers detailing the effects on acetylcholinesterase of oxidation of site-specific residues of tryptophan to NFK.

Project Start
Project End
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Budget End
Support Year
21
Fiscal Year
2015
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Indirect Cost
Name
U.S. National Inst of Environ Hlth Scis
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van 't Erve, Thomas J; Lih, Fred B; Kadiiska, Maria B et al. (2018) Elevated plasma 8-iso-prostaglandin F2? levels in human smokers originate primarily from enzymatic instead of non-enzymatic lipid peroxidation. Free Radic Biol Med 115:105-112
Kumar, Ashutosh; Triquigneaux, Mathilde; Madenspacher, Jennifer et al. (2018) Sulfite-induced protein radical formation in LPS aerosol-challenged mice: Implications for sulfite sensitivity in human lung disease. Redox Biol 15:327-334
Ganini, Douglas; Santos, Janine H; Bonini, Marcelo G et al. (2018) Switch of Mitochondrial Superoxide Dismutase into a Prooxidant Peroxidase in Manganese-Deficient Cells and Mice. Cell Chem Biol 25:413-425.e6
Muñoz, M D; Della Vedova, M C; Bushel, P R et al. (2018) The nitrone spin trap 5,5-dimethyl-1-pyrroline N-oxide dampens lipopolysaccharide-induced transcriptomic changes in macrophages. Inflamm Res 67:515-530
Sinha, Birandra K; van 't Erve, Thomas J; Kumar, Ashutosh et al. (2017) Synergistic enhancement of topotecan-induced cell death by ascorbic acid in human breast MCF-7 tumor cells. Free Radic Biol Med 113:406-412
Sinha, Birandra K; Kumar, Ashutosh; Mason, Ronald P (2017) Nitric oxide inhibits ATPase activity and induces resistance to topoisomerase II-poisons in human MCF-7 breast tumor cells. Biochem Biophys Rep 10:252-259
Ganini, Douglas; Leinisch, Fabian; Kumar, Ashutosh et al. (2017) Fluorescent proteins such as eGFP lead to catalytic oxidative stress in cells. Redox Biol 12:462-468
van 't Erve, Thomas J; Kadiiska, Maria B; London, Stephanie J et al. (2017) Classifying oxidative stress by F2-isoprostane levels across human diseases: A meta-analysis. Redox Biol 12:582-599
Kumar, Ashutosh; Ehrenshaft, Marilyn; Tokar, Erik J et al. (2016) Nitric oxide inhibits topoisomerase II activity and induces resistance to topoisomerase II-poisons in human tumor cells. Biochim Biophys Acta 1860:1519-27
Mason, Ronald Paul (2016) Imaging free radicals in organelles, cells, tissue, and in vivo with immuno-spin trapping. Redox Biol 8:422-9

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