Steven Y. Qian

IRON AND DIOXYGEN CHEMISTRY IS AN IMPORTANT ROUTE TO INITIATION OF BIOLOGICAL FREE RADICAL OXIDATIONS: AN ELECTRON PARAMAGNETIC RESONANCE SPIN TRAPPING STUDY

Iron can be a detrimental catalyst in biological free radical oxidations. Because of the high physiological ratio of [O2]/[H2O2] (> or = 10(3)), we hypothesize that the Fenton reaction with pre-existing H2O2 is only a minor initiator of free radical oxidations and that the major initiators of biological free radical oxidations are the oxidizing species formed by the reaction of Fe2+ with dioxygen. We have employed electron paramagnetic resonance spin trapping to examine this hypothesis. Free radical oxidation of: 1) chemical (ethanol, dimethyl sulfoxide); 2) biochemical (glucose, glyceraldehyde); and 3) cellular (L1210 murine leukemia cells) targets were examined when subjected to an aerobic Fenton (Fe2+ + H2O2 + O2) or an aerobic (Fe2+ + O2) system. As anticipated, the Fenton reaction initiates radical formation in all the above targets. Without pre-existing H2O2, however, Fe2+ and O2 also induce substantial target radical formation. Under various experimental ratios of [O2]/[H2O2] (1-100 with [O2] approximately 250 microM), we compared the radical yield from the Fenton reaction vs. the radical yield from Fe2+ + O2 reactions. When [O2]/[H2O2] < 10, the Fenton reaction dominates target molecule radical formation; however, production of target-molecule radicals via the Fenton reaction is minor when [O2]/[H2O2] > or = 100. Interestingly, when L1210 cells are the oxidation targets, Fe2+ + O2 is observed to be responsible for formation of nearly all of the cell-derived radicals detected, no matter the ratio of [O2]/[H2O2]. Our data demonstrate that when [O2]/[H2O2] > or = 100, Fe2+ + O2 chemistry is an important route to initiation of detrimental biological free radical oxidations.

Neuromelanin Activates Microglia and Induces Degeneration of Dopaminergic Neurons: Implications for Progression of Parkinson’s Disease

In Parkinson’s disease (PD), there is a progressive loss of neuromelanin (NM)-containing dopamine neurons in substantia nigra (SN) which is associated with microgliosis and presence of extracellular NM. Herein, we have investigated the interplay between microglia and human NM on the degeneration of SN dopaminergic neurons. Although NM particles are phagocytized and degraded by microglia within minutes in vitro, extracellular NM particles induce microglial activation and ensuing production of superoxide, nitric oxide, hydrogen peroxide (H2O2), and pro-inflammatory factors. Furthermore, NM produces, in a microglia-depended manner, neurodegeneration in primary ventral midbrain cultures. Neurodegeneration was effectively attenuated with microglia derived from mice deficient in macrophage antigen complex-1, a microglial integrin receptor involved in the initiation of phagocytosis. Neuronal loss was also attenuated with microglia derived from mice deficient in phagocytic oxidase, a subunit of NADPH oxidase, that is responsible for superoxide and H2O2 production, or apocynin, an NADPH oxidase inhibitor. In vivo, NM injected into rat SN produces microgliosis and a loss of tyrosine hydroxylase neurons. Thus, these results show that extracellular NM can activate microglia, which in turn may induce dopaminergic neurodegeneration in PD. Our study may have far-reaching implications, both pathogenic and therapeutic.

Manganese superoxide dismutase protects mouse cortical neurons from chronic intermittent hypoxia-mediated oxidative damage

Obstructive sleep apnea (OSA) syndrome has been recognized as a highly prevalent public health problem and is associated with major neurobehavioral morbidity. Chronic intermittent hypoxia (CIH), a major pathological component of OSA, increases oxidative damage to the brain cortex and decreases neurocognitive function in rodent models resembling human OSA. We employed in vitro and in vivo approaches to identify the specific phases and subcellular compartments in which enhanced reactive oxygen species (ROS) are generated during CIH. In addition, we utilized the cell culture and animal models to analyze the consequences of enhanced production of ROS on cortical neuronal cell damage and neurocognitive dysfunction. In a primary cortical neuron culture system, we demonstrated that the transition phase from hypoxia to normoxia (NOX) during CIH generates more ROS than the transition phase from NOX to hypoxia or hypoxia alone, all of which generate more ROS than NOX. Using selective inhibitors of the major pathways underlying ROS generation in the cell membrane, cytosol, and mitochondria, we showed that the mitochondria are the predominant source of enhanced ROS generation during CIH in mouse cortical neuronal cells. Furthermore, in both cell culture and transgenic mice, we demonstrated that overexpression of MnSOD-decreased CIH-mediated cortical neuronal apoptosis, and reduced spatial learning deficits measured with the Morris water maze assay. Together, the data from the in vitro and in vivo experiments indicate that CIH-mediated mitochondrial oxidative stress may play a major role in the neuronal cell loss and neurocognitive dysfunction in OSA. Thus, therapeutic strategies aiming at reducing ROS generation from mitochondria may improve the neurobehavioral morbidity in OSA.

PHOSPHOLIPID HYDROPEROXIDE GLUTATHIONE PEROXIDASE PROTECTS AGAINST SINGLET OXYGEN-INDUCED CELL DAMAGE OF PHOTODYNAMIC THERAPY

Phospholipid hydroperoxide glutathione peroxidase (PhGPx) is an important enzyme in the removal of lipid hydroperoxides (LOOHs) from cell membranes. Cancer treatments such as photodynamic therapy (PDT) induce lipid peroxidation in cells as a detrimental action. The photosensitizers used produce reactive oxygen species such as singlet oxygen ((1)O(2)). Because singlet oxygen introduces lipid hydroperoxides into cell membranes, we hypothesized that PhGPx would provide protection against the oxidative stress of singlet oxygen and therefore could interfere with cancer treatment. To test this hypothesis, human breast cancer cells (MCF-7) were stably transfected with PhGPx cDNA. Four clones with varying levels of PhGPx activity were isolated. The activities of other cellular antioxidant enzymes were not influenced by the overexpression of PhGPx. Cellular PhGPx activity had a remarkable inverse linear correlation to the removal of lipid hydroperoxides in living cells (r = -0.85), and correlated positively with cell survival after singlet oxygen exposure (r = 0.94). These data demonstrate that PhGPx provides significant protection against singlet oxygen-generated lipid peroxidation via removal of LOOH and suggest that LOOHs are major mediators in this cell injury process. Thus, PhGPx activity could contribute to the resistance of tumor cells to PDT.

Separation and identification of DMPO adducts of oxygen-centered radicals formed from organic hydroperoxides by HPLC-ESR, ESI-MS and MS/MS

Many electron spin resonance (ESR) spectra of 5,5-dimethyl-1-pyrroline N-oxide (DMPO) radical adducts from the reaction of organic hydroperoxides with heme proteins or Fe2+ were assigned to the adducts of DMPO with peroxyl, alkoxyl, and alkyl radicals. In particular, the controversial assignment of DMPO/peroxyl radical adducts was based on the close similarity of their ESR spectra to that of the DMPO/superoxide radical adduct in conjunction with their insensitivity to superoxide dismutase, which distinguishes the peroxyl adducts from the DMPO/superoxide adduct. Although recent reports assigned the spectra suggested to be DMPO/peroxyl radical adducts to the DMPO/methoxyl adduct based on independent synthesis of the adduct and/or 17O-labeling, 17O-labeling is extremely expensive, and both of these assignments were still based on hyperfine coupling constants, which have not been confirmed by independent techniques. In this study, we have used online high performance liquid chromatography (HPLC or LC)/ESR, electrospray ionization-mass spectrometry (ESI-MS) and tandem mass spectrometry (MS/MS) to separate and directly characterize DMPO oxygen-centered radical adducts formed from the reaction of Fe2+ with t-butyl or cumene hydroperoxide. In each reaction system, two DMPO oxygen-centered radical adducts were separated and detected by online LC/ESR. The first DMPO radical adduct from both systems showed identical chromatographic retention times (tR=9.6 min) and hyperfine coupling constants (aN=4.51 G, aHβ=10.71 G, and aHγ=1.32 G). The ESI-MS and MS/MS spectra demonstrated that this radical was the DMPO/methoxyl radical adduct, not the peroxyl radical adduct as was thought at one time, although its ESR spectrum is nearly identical to that of the DMPO/superoxide radical adduct. Similarly, based on their MS/MS spectra, we verified that the second adducts (aN=14.86 G and aHβ=16.06 G in the reaction system containing t-butyl hydroperoxide and aN=14.60 G and aHβ=15.61 G in the reaction mixture containing cumene hydroperoxide), previously assigned as DMPO adducts of t-butyloxyl and cumyloxyl radical, were indeed from trapping t-butyloxyl and cumyloxyl radicals, respectively.

Cadmium generates reactive oxygen- and carbon-centered radical species in rats: insights from in vivo spin-trapping studies.

Cadmium (Cd) is a known industrial and environmental pollutant. In the present work, an in vivo spin-trapping technique was used in conjunction with electron spin resonance (ESR) spectroscopy to investigate free radical generation in rats following administration of cadmium chloride (CdCl2, 40 micromol/kg) and the spin trapping agent alpha-(4-pyridyl-1-oxide)-N-tert-butylnitrone (POBN, 1 g/kg). In Cd-treated rats, POBN radical adducts were formed in the liver, were excreted into the bile, and exhibited an ESR spectrum consistent with a carbon-centered radical species probably derived from endogenous lipids. Isotope substitution of dimethyl sulfoxide [(CH3)2SO] with 13C demonstrated methyl radical formation (POBN/*13CH3). This adduct indicated the production of hydroxyl radical, which reacted with [(13CH3)2SO] to form *13CH3, which then reacted with POBN to form POBN/*13CH3. Depletion of hepatic glutathione by diethyl maleate significantly increased free radical production, whereas inactivation of Kupffer cells by gadolinium chloride and chelation of iron by desferal inhibited it. Treatment with the xanthine oxidase inhibitor allopurinol, the catalase inhibitor aminobenzotriazole, or the cytochrome P450 inhibitor 3-amino-1,2,4-triazole had no effect. This is the first study to show Cd generation of reactive oxygen- and carbon-centered radical species by involvement of both iron mediation through iron-catalyzed reactions and activation of Kupffer cells, the resident liver macrophages.

Identification of protein-derived tyrosyl radical in the reaction of cytochrome c and hydrogen peroxide: characterization by ESR spin-trapping, HPLC and MS.

The reaction of cytochrome c and H(2)O(2) is known to form a protein-centred radical that can be detected with the spin trap 2-methyl-2-nitrosopropane (MNP). To characterize the MNP/tyrosyl adduct structure that had previously been determined incorrectly [Barr, Gunther, Deterding, Tomer and Mason (1996) J. Biol. Chem. 271, 15498-15503], we eliminated unreasonable structure models by ESR studies with a series of (13)C-labelled tyrosines, and photochemically synthesized an authentic MNP/tyrosyl adduct that has its trapping site on the C-3 position of the tyrosine phenyl ring. The observation of the identical ESR spectra for this radical adduct from the UV irradiation of 3-iodo-tyrosine and the adduct from the cytochrome c reaction demonstrated that the radical trapping site of MNP/tyrosyl is located on the equivalent C-3/C-5 positions instead of the C-1 position, as was proposed by Barr et al. In an on-line HPLC/ESR system, an identical retention time (17.7 min) was observed for the ESR-active HPLC peak of the MNP/tyrosyl adduct from the following three reactions: (i) the tyrosine oxidation via horseradish peroxidase/H(2)O(2); (ii) UV irradiation of 3-iodo-tyrosine and (iii) the reaction of cytochrome c with H(2)O(2). This result demonstrated that the radical adducts of all three reactions are most probably the same. The mass spectrometric analysis of the HPLC fractions from reactions (i) and (ii) showed an ion at m/z 267 attributed to the MNP/tyrosyl adduct. We conclude that the cytochrome c-derived tyrosyl radical was trapped by MNP, leading to a persistent radical adduct at the C-3/C-5 positions of the tyrosine phenyl ring.

EPR detection of lipid-derived free radicals from PUFA, LDL, and cell oxidations

We have used the spin trap 5,5-dimethyl-pyrroline-1-oxide (DMPO) and EPR to detect lipid-derived radicals (Ld*) during peroxidation of polyunsaturated fatty acids (PUFA), low-density lipoprotein (LDL), and cells (K-562 and MCF-7). All oxygen-centered radical adducts of DMPO from our oxidizable targets have short lifetimes (<20 min). We hypothesized that the short lifetimes of these spin adducts are due in part to their reaction with radicals formed during lipid peroxidation. We proposed that stopping the lipid peroxidation processes by separating oxidation-mediator from oxidation-substrate with an appropriate extraction would stabilize the spin adducts. To test this hypothesis we used ethyl acetate to extract the lipid-derived radical adducts of DMPO (DMPO/Ld*) from an oxidizing docosahexaenioc acid (DHA) solution; Folch extraction was used for LDL and cell experiments. The lifetimes of DMPO spin adducts post-extraction are much longer (>10 h) than the spin adducts detected without extraction. In iron-mediated DHA oxidation we observed three DMPO adducts in the aqueous phase and two in the organic phase. The aqueous phase contains DMPO/HO* aN approximately aH approximately 14.8 G) and two carbon-centered radical adducts (aN1 approximately 15.8 G, aH1 approximately 22.6 G; aN2 approximately 15.2 G, aH2 approximately 18.9 G). The organic phase contains two long-chain lipid radical adducts (aN approximately 13.5 G, aH approximately 10.2 G; and aN approximately 12.8 G; aH approximately 6.85 G, 1.9 G). We conclude that extraction significantly increases the lifetimes of the spin adducts, allowing detection of a variety of lipid-derived radicals by EPR.

Identification of all classes of spin-trapped carbon-centered radicals in soybean lipoxygenase-dependent lipid peroxidations of ω-6 polyunsaturated fatty acids via LC/ESR, LC/MS, and tandem MS

Using the combined techniques of on-line high performance liquid chromatography/electron spin resonance (LC/ESR) and mass spectrometry (MS), we previously identified spin-trapped adducts of all expected carbon-centered lipid-derived radicals ((*)L(d)) formed in linoleic acid peroxidation. In the present study, spin trapped lipid-derived carbon-centered radicals formed from the reactions of two omega-6 polyunsaturated fatty acids (PUFAs: linoleic and arachidonic acids) with soybean lipoxygenase in the presence of alpha-[4-pyridyl 1-oxide]-N-tert-butyl nitrone (POBN) were identified using a combination of LC/ESR and LC/MS. All expected lipid-derived carbon-centered radicals in lipoxygenase-dependent peroxidations of linoleic acid and arachidonic acid were detected and identified by the combination of LC/ESR and LC/MS with confirmation by tandem mass spectrometry (MS/MS). The five classes of (*)L(d) formed from both omega-6 PUFAs including lipid alkyl radicals (L(*)), epoxyallyic radicals (OL(*)), dihydroxyallyic radicals ((*)L(OH)(2)), and a variety of R(*) and (*)RCOOH from beta-scission of lipid alkoxyl radicals, gave distinct retention times: POBN/(*)L(OH)(2) approximately 4-6 min, POBN/R(*) and POBN/(*)RCOOH approximately 8-22 min, POBN/L(*) and PBON/OL(*) approximately 25-36 min. The major beta-scission products in peroxidations of omega-6 PUFAs were the pentyl radicals. The ratio of beta-scission products, however, varied significantly depending on pH, [PUFA], as well as [O(2)].

Autistic Children Exhibit Decreased Levels of Essential Fatty Acids in Red Blood Cells

Omega-6 (n-6) and omega-3 (n-3) polyunsaturated fatty acids (PUFA) are essential nutrients for brain development and function. However, whether or not the levels of these fatty acids are altered in individuals with autism remains debatable. In this study, we compared the fatty acid contents between 121 autistic patients and 110 non-autistic, non-developmentally delayed controls, aged 3–17. Analysis of the fatty acid composition of red blood cell (RBC) membrane phospholipids showed that the percentage of total PUFA was lower in autistic patients than in controls; levels of n-6 arachidonic acid (AA) and n-3 docosahexaenoic acid (DHA) were particularly decreased (p < 0.001). In addition, plasma levels of the pro-inflammatory AA metabolite prostaglandin E2 (PGE2) were higher in a subset of the autistic participants (n = 20) compared to controls. Our study demonstrates an alteration in the PUFA profile and increased production of a PUFA-derived metabolite in autistic patients, supporting the hypothesis that abnormal lipid metabolism is implicated in autism.