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Free Radical Research Communications Volume 12, 1991 - Issue 1
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Original Article

Enhanced Electron Transfer by Unsaturated Fatty Acids and Superoxide Dismutase

Douglas A. Peterson Department of Medicine, V. A. Medical Center, Minneapolis, Minnesota, 55417, USA
Pages 161-166 | Published online: 07 Jul 2009

References

  • Peterson D. A., Gerrard J. M., Rao G. H. R., Krick T. P., White J. G. Ferrous iron mediated oxidation of arachidonic acid: studies employing nitroblue tetrazolium (NET). Pm.vtuRlundin.s and Medicine 1978; 1: 304–317
  • Peterson D. A., Gerrard J. M., Benton M. A. A hypothesis for the mechanism of superoxide production by phagocytic cells. Medical Hypothesis. 1981; 7: 1389–1395
  • Rao G. H. R., Gerrard J. M., Eaton J. W., White J. G. The role of iron in prostaglandin synthesis: ferrous iron mediated oxidation of arachidonic acid. Prostaglandins and Medicine. 1978; 1: 55–70
  • Peterson D. A., Gerrard J. M. A hvoothesis for a role for unsaturated fattv acids in electron transport and its potential application to understanding the mitochondria respiratory chain. Medical Hypothesis 1980; 6: 491–499
  • Purugganan M. D., Kumar C. V., Turro N. J., Barton J. K. Accelerated electron transfer between metal complexes mediated by DNA. Science 1988; 241: 1645–1649
  • Reid L. S., Lim A. R., Mauk A. G. Role of heme vinyl groups in cytochrome b, electron transfer. Journal of theAmerican Chemical Society 1986; 108: 8197–8201
  • Gingrich D. J., Nocek J. M., Natan M. J., Hoffman B. M. Porphyrin vinyl groups act as antennae for electron transfer within [Fe, Zn] hemoglobin hybrids. Journal of the American Chemical Socieiy 1987; 109: 7533–7534
  • Chen R. F. Removal of fatty acids from Serum albumin by charcoal treatment. Journal of Biological Chemistry 1967; 242: 173–181
  • McAdam M. E., Fox R. A., Lavelle F., Fielden E. M. A pulse-radiolysis study of the manganese containing superoxide dismutase form. Bacillus stearothermophilus. Biochemical Journal. 1976; 165: 71–79
  • Bull C., Fee J. A. Steady-state kinetic studies of superoxide dismutases: Properties of the iron containing protein form. Escherichia coli. Journal of theAmerican Chemical Society 1985; 107: 3295–3304
  • Carlioz A., Touati D. Isolation of superoxide dismutase mutants in Escherichia coli: Is superoxide dismutase necessary for aerobic life?. EMBO Journal 1986; 5: 623–630
  • Scott M. D., Meshnick S. R., Eaton J. W. Superoxide dismutase-rich bacteria: Paradoxical increase in oxidant toxicity. Journal of Biological Chemistry. 1987; 262: 3640–3645
  • Scott M. D., Eaton J. W. Superoxide disrnutase amplifies organismal sensitivity to ionizing radiation. Journal of Biological Chemistry 1989; 264: 2498–2502
  • Halliwell B., Gutteridge J. M. C. Free Radicals in Biology and Medicine. Clarendon Press. 1985; 94, Oxford
  • Peterson D. A., Gerrard J. M., Glover S. M., Rao G. H. R., White J. G. Epinephrine reduction of heme: Implication for understanding the transmission of an agonist stirnulous. Science 1982; 215: 71–73
  • Peterson D. A., Gerrard J. M. Reduction of a disulfide bond by b˜-adrenergic agonists: Evidence in support of a general “reductive activation” hypothesis for the mechanism of action of adrenergic agents. Medical Hypothesis 1987; 22: 45–49
  • Peterson D. A., Butterfield J., Gerrard J. M. The dopaminergic D, receptor: Another example of reductive activation. Medical Hypothesis. 1988; 26: 73–75
  • Peterson D. A., Kelly B., Mehta N., Gerrard J. M. Prostaglandins as reducing agents: A model of adenylate cyclase acrtivation. Prostaglandins. 1988; 26: 667–671
  • Peterson D. A., Kelly B., Butterfield J., Ashley J., Peterson R., Gerrard J. M. Phosphorylation of tyrosine enhances its electron transfer capability: A model of redox modulation as oncogene expression. Medical Hypothesis. 1988; 26: 271–273
  • Sterling K., Brenner M. A., Sakurada T. Rapid effect of triiodothyronine on the mitochondrial pathway in rat liver. in vivo. Science 1980; 210: 340–342
  • Peterson D. A. Cytochrome c reduction by truodothyronine (T3). Medical Hypothesis 1982; 9: 111–114
  • Marinov B. S., Saxon M. E. Dihydropyridine Ca2+ agonists and channel blockers interact in the opposite manner with photogenerated unpaired electrons. Federation of European Biological Societies Letters 1985; 186: 251–254
  • Marinov B. S. Na + channel antagonists act as electron donors while agonists act as electron acceptors in reactions with dye free radicals. Fderutiun of Eurupeun Biological Societies Letters. 1985; 191: 159–162
  • Archer S. L., Peterson D., Nelson D. P., DeMaster E. G., Kelly B., Eaton J. W., Weir E. K. Oxygen radicals and antioxidant enzymes alter pulmonary vascular reactivity in the rat lung. Journal of Applied Physiology. 1989; 66: 102–111
  • McSwigan J. D., Hanson D. R., Lubiniecki A. S., Heston L. L., Sheppard J. R. Down syndrome fibroblasts are hyperresponsive to b˜-adrenergic stimulation. Proceedings of the National Academy of Sciences USA. 1981; 18: 7670–7676
  • Werns S. W., Shea S., Driscoll E. M., Cohen C., Abrams T. D., Pitt B., Lucchcsi B. The independent etTccts of oxygen radical scavengers on canine infarct size: the reduction by superoxide dismutase but not catalase. Circulation Restarch 1985; 56: 895–898
  • Gallagher K. P., Buda A. J., Pace D., Gerren R. A., Shlafer M. failure of superoxide dismutax and catalase to alter size of infarction in conscious dogs after 3 hours of occlusion followed by reperfusion. Circularion 1986; 73: 1065–1076
  • Peterson D. A., Kelly B., Gerrard J. M. Allopurinol can act as an electron transfer agent. Is this relevant during reperfusion injury?. Biochemical Biophysical Research Communications 1986; 137: 76–79
  • Chambers D. E., Parks D. A., Patterson G., Roy R., McCord J. M., Yoshida S., Parmley L. F., M Downey J. Xanthine oxidase as a source of free radical damage in myocardial ischemia. Journal of Molecular and Cellular Cardiology 1985; 17: 145–152
  • Reimer K. A., Jennings R. B. Failure of the xanthine oxidase inhibitor allopurinol to limit infarct size after ischemia and reperfusion in dogs. Circulution. 1985; 71: 1069–1075
  • Okamoto F., Allen B. S., Briceberg G. D., Leaf J., Bugyi H. Reperfusate composition: supplemental role of intravenous and intracoronary coenzyme Q10 in avoiding reperfusion damage. Journal of Thoracic Cardiovascular Surgery 1986; 92: 573–582
  • Takada M., Ikenoya S., Yuzurika T., Katayama K. Studies on reduced and oxidized co-enzyme Q (ubiquinoncs) II. The determination of oxidation reduction levels of co-enzyme Q in mitochondria microsomes and plasma by high performance liquid chromatography. Biochimica Biophysica Acta. 1982; 679: 308–314

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