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Annals of the New York Academy of Sciences 12/2006; 679(1):370 - 375. · 3.15 Impact Factor
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C C Chiueh
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ABSTRACT: Hallervorden-Spatz syndrome is an autosomal-recessive brain disorder with signs of extrapyramidal dysfunction and mental deterioration, which associate with iron accumulation in globus pallidus and substantia nigra pars reticulata. Studies of oxidant stress in parkinsonian animal models suggest a linkage of iron overload to axonal dystrophy. Redox cycling of iron complexes (i.e., ferrous citrate and hemoglobin) increases hydroxyl radicals, lipid peroxidation, axonal dystrophy, and necrotic or apoptotic cell death. An increase of oxidative stress in the basal ganglia because of redox cycling of iron complexes leads to dopamine overflow and psychomotor dysfunction. Iron overload-induced axonal dystrophy has been demonstrated consistently using in vitro and in vivo models with a prominent feature of lipid peroxidation. This iron-induced oxidative stress is often accentuated by ascorbate and oxidized glutathione, although it is suppressed by the following antioxidants: S-nitrosoglutathione or nitric oxide, MnSOD mimics, manganese, U-78517F, Trolox, and deferoxamine. Preconditioning induction of stress proteins (i.e., hemeoxygenase-1 and neuronal nitric oxide synthase) and hypothermia therapy suppress the generation of toxic reactive oxygen, lipid, and thiol species evoked by bioactive iron complexes in the brain. Finally, combined antioxidative therapeutics and gene induction procedures may prove to be useful for slowing progressive neurodegeneration caused by iron overload in the brain.
Pediatric Neurology 09/2001; 25(2):138-47. · 1.52 Impact Factor
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ABSTRACT: Preconditioning stress induced by a transient ischemia may increase brain tolerance to oxidative stress, and the underlying neuroprotective mechanisms are not well understood. In a series of experiments, we found that endogenous nitric oxide (NO), S-nitrosoglutathione (GSNO), and antioxidants blocked serum deprivation-induced oxidative stress and apoptosis in human neuroblastoma cells. Similar to nuclear redox factor-1 (Ref-1), mRNA of human neuronal nitric oxide synthase (hNOS1) was maximally up-regulated within 2 h after oxidative stress and down-regulated by NO/GSNO and hydroxyl radical (OH) scavenger. A brief preconditioning stress induced by serum deprivation for 2 h caused a delayed increase in the expression of hNOS1 protein and the associated formation of NO and cGMP, which in turn decreased OH generation and stress-related cell death. In addition to inhibiting caspase-3 through a dithiothreitol-sensitive S-nitrosylation process, preconditioning stress concomitantly up-regulated the expression of the anti-apoptotic bcl-2 protein and down-regulated the p66shc adaptor protein. This beneficial cytoprotective process of preconditioning stress is mediated by newly synthesized NO because it can be suppressed by the inhibition of hNOS1 and guanylyl cyclase. Therefore, the constitutive isoform of hNOS1 is dynamically redox-regulated to meet both functional and compensatory demands of NO for gene regulation, antioxidant defense, and tolerance to oxidative stress.
The FASEB Journal 12/2000; 14(14):2144-6. · 5.71 Impact Factor
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ABSTRACT: l-Deprenyl (Selegiline), a selective and irreversible type B monoamine oxidase inhibitor, has been used as an adjunct to levodopa therapy in Parkinson's disease. Recently, it is proposed as a putative neuroprotective agent in delaying the progression of cell death based on its capability of reducing the oxidative stress derived from the MAO-B dependent metabolism of dopamine, and blocking the development of MPTP-parkinsonism. However, a variety of experimental models suggest that l-deprenyl provides neuroprotection through multiple modes of mechanism other than the inhibition of MAO-B. We have previously shown that l-deprenyl protects midbrain dopamine neurons from MPP+ toxicity by a novel antioxidant effect. In the present study we examined whether the protection against MPP+ toxicity is also shared by other reversible or irreversible MAO-B inhibitors including (+)-deprenyl, Ro16-6491 and pargyline. Our data show that non of these MAO-B inhibitors changes the dopamine loss in the striatum induced by intranigral injection of MPP+. Our result suggests that l-deprenyl may possess a unique neuroprotective action on nigral neuron against MPP+ toxicity independent of the MAO-B inhibition.
Annals of the New York Academy of Sciences 02/2000; 899:255-61. · 3.15 Impact Factor
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ABSTRACT: Brain undergoes neurodegeneration when excess free radicals overwhelm antioxidative defense systems during senescence, head trauma and/or neurotoxic insults. A site-specific accumulation of ferrous citrate-iron complexes in the substantia nigra dopaminergic neurons could lead to exaggerated dopamine turnover, dopamine auto-oxidation, free radical generation, and oxidant stress. Eventually, this iron-catalyzed dopamine auto-oxidation results in the accumulation of neuromelanin, a progressive loss of nigral neurons, and the development of Parkinson's disease when brain dopamine depletion is greater than 80%. Emerging evidence indicates that free radicals such as hydroxyl radicals ((.-)OH) and nitric oxide ((.-)NO) may play opposite role in cell and animal models of parkinsonism. (.-)OH is a cytotoxic oxidant whereas oNO is an atypical neuroprotective antioxidant. (.-)NO and S-nitrosoglutathione (GSNO) protect nigral neurons against oxidative stress caused by 1-methyl-4-phenylpyridinium (MPP(+)), dopamine, ferrous citrate, hemoglobin, sodium nitroprusside and peroxynitrite. MPP(+), the toxic metabolite of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), increases the nigral uptake of iron complexes and dopamine overflow leading to the generation of (.-)OH, protein oxidation, lipid peroxidation, and associated retrograde degeneration. In addition to GSNO, MPP(+)-induced oxidative neurotoxicity can be prevented by antioxidants including selegiline, 7-nitroindazole, 17beta-estradiol, melatonin, alpha-phenyl-tert-butylnitrone and U78517F. Similar to selegiline, 7-nitroindazole is a MAO-B inhibitor, which blocks the bio-activation of MPTP and oxidative stress. Freshly prepared but not light exposed, (.-)NO-exhausted GSNO is about 100 times more potent than the classic antioxidant glutathione. Via S-nitrosylation, GSNO also inhibits proteolysis and cytotoxicity caused by caspases and HIV-1 protease. Furthermore, in addition to protection against serum deprivation stress, the induction of neuronal NOS1 in human cells increases tolerance to MPP(+)-induced neuro-toxicity since newly synthesized (.-)NO prevents apoptosis possibly through up-regulation of bcl-2 and down regulation of p66(shc). In conclusion, reactive oxygen species are unavoidable by-products of iron-catalyzed dopamine auto-oxidation, which can initiate lipid peroxidation, protein oxidation, DNA damage, and nigral loss, all of which can be prevented by endogenous and exogenous (.-)NO. Natural and man-made antioxidants can be employed as part of preventative or neuroprotective treatments in Parkinson's disease and perhaps dementia complexes as well. For achieving neuroprotection and neuro-rescue in early clinical parkinsonian stages, a cocktail therapy of multiple neuroprotective agents may be more effective than the current treatment with extremely high doses of a single antioxidative agent.
Neurotoxicity Research 02/2000; 2(2-3):293-310. · 3.51 Impact Factor
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ABSTRACT: A fluorescent assay of brain lipid peroxidation was used for screening new antioxidants for the prevention of neurodegeneration caused by free radicals. Incubation of rat brain homogenates led to a temperature-dependent increase in production of fluorescent adducts of peroxidized polyunsaturated fatty acids; it was inhibited completely by lowering the incubation temperature to 4 degrees C. This tissue disruption-induced brain lipid peroxidation at 37 degrees C was blocked by deferoxamine (IC50 = 0.3 microM) and EDTA; it was augmented by adding submicromolar iron and hemoglobin. Ferrous ion's pro-oxidative activities were five times more potent than ferric ion. Micromolar manganese completely inhibited lipid peroxidation, confirming earlier unexpected in vivo reports. Trolox and vitamin C suppressed brain lipid peroxidation with IC50 values of 20 and 500 microM, respectively. U-78517F was approximately 20 times more potent than Trolox. 17 beta-Estradiol, hydralazine, S-nitrosoglutathione and 3-hydroxybenzylhydrazine were as potent as Trolox. Melatonin, glutathione, alpha-lipoic acid and l-deprenyl were about 20 times less potent than Trolox. Surprisingly, N-tert-butyl-alpha-phenylnitrone was a weak antioxidant. Furthermore, this procedure can also detect pro-oxidative side effects of vitamin C, oxidized glutathione, penicillamine and Angeli's salt. The present results obtained from this selective fluorescent assay are consistent with earlier reports that iron complexes promote while manganese inhibits brain lipid peroxidation caused by cell disruption. S-Nitrosoglutathione, melatonin, 17 beta-estradiol, and manganese have been successfully tested in cell/animal models for their potential neuroprotective effects. In conclusion, monitoring fluorescent adducts of peroxidizing polyunsaturated fatty acids in brain homogenates is a simple, quantitative method for studying iron-dependent brain lipid peroxidation and for screening of potential neuroprotective antioxidants in both in vitro and in vivo preparations.
Annals of the New York Academy of Sciences 02/2000; 899:238-54. · 3.15 Impact Factor
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ABSTRACT: In the present in vitro and in vivo study we investigated the pro-oxidant effects of hemoglobin, as well as the antioxidant effects of its metabolites, in the brain. Incubation of rat brain homogenates with hemoglobin (0-10 microM) but not hemin induced lipid peroxidation up to 24 h (EC50 = 1.2 microM). Hemoglobin's effects were similar to ferrous ion (EC50 = 1.7 microM) and were blocked by the chelating agent deferoxamine (IC50 0.5 microM) and a nitric oxide-releasing compound S-nitrosoglutathione (IC50 = 40 microM). However, metabolites of hemoglobin - biliverdin and bilirubin - inhibited brain lipid peroxidation induced by cell disruption and hemoglobin (biliverdin IC50 = 12-30 and bilirubin IC50 = 75-170 microM). Biliverdin's antioxidative effects in spontaneous and iron-evoked lipid peroxidation were further augmented by manganese (2 microM) since manganese is an antioxidative transition metal and conjugates with bile pigments. Intrastriatal infusion of hemoglobin (0-24 nmol) produced slight, but significant 20-22% decreases in striatal dopamine levels. Whereas, intrastriatal infusion of ferrous citrate (0-24 nmol) dose-dependently induced a greater 66% depletion of striatal dopamine which was preceded by an acute increase of lipid peroxidation. In conclusion, contrary to the in vitro results hemoglobin is far less neurotoxic than ferrous ions in the brain. It is speculated that hemoglobin may be partially detoxified by heme oxygenase and biliverdin reductase to its antioxidative metabolites in the brain. However, in head trauma and stroke, massive bleeding could significantly produce iron-mediated oxidative stress and neurodegeneration which could be minimized by endogenous antioxidants such as biliverdin, bilirubin, manganese and S-nitrosoglutathione.
Free Radical Research 01/2000; 31(6):631-40. · 2.88 Impact Factor
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ABSTRACT: Recent results demonstrated that S-nitrosoglutathione (GSNO) and nitric oxide (*NO) protect brain dopamine neurons from hydroxyl radical (*OH)-induced oxidative stress in vivo because they are potent antioxidants. GSNO and *NO terminate oxidant stress in the brain by (i) inhibiting iron-stimulated hydroxyl radicals formation or the Fenton reaction, (ii) terminating lipid peroxidation, (iii) augmenting the antioxidative potency of glutathione (GSH), (iv) mediating neuroprotective action of brain-derived neurotrophin (BDNF), and (v) inhibiting cysteinyl proteases. In fact, GSNO--S-nitrosylated GSH--is approximately 100 times more potent than the classical antioxidant GSH. In addition, S-nitrosylation of cysteine residues by GSNO inactivates caspase-3 and HIV-1 protease, and prevents apoptosis and neurotoxicity. GSNO-induced antiplatelet aggregation is also mediated by S-nitrosylation of clotting factor XIII. Thus the elucidation of chemical reactions involved in this GSNO pathway (GSH GS* + *NO-->[GSNO]-->GSSG + *NO-->GSH) is necessary for understanding the biology of *NO, especially its beneficial antioxidative and neuroprotective effects in the CNS. GSNO is most likely generated in the endothelial and astroglial cells during oxidative stress because these cells contain mM GSH and nitric oxide synthase. Furthermore, the transfer of GSH and *NO to neurons via this GSNO pathway may facilitate cell to neuron communications, including not only the activation of guanylyl cyclase, but also the nitrosylation of iron complexes, iron containing enzymes, and cysteinyl proteases. GSNO annihilates free radicals and promotes neuroprotection via its c-GMP-independent nitrosylation actions. This putative pathway of GSNO/GSH/*NO may provide new molecular insights for the redox cycling of GSH and GSSG in the CNS.
Free Radical Research 01/2000; 31(6):641-50. · 2.88 Impact Factor
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ABSTRACT: A significant number of adult male patients with acquired immunodeficiency syndrome develop cerebral atrophy and progressive brain disorders such as dementia complex and neuropsychiatric problems. Upon entering the brain via activated macrophages or microglias, the human immunodeficiency type 1 virus (HIV-1) may produce cytotoxic factors such as HIV-1 envelope protein (gp120) and protease. Owing to significant proteolysis of nonviral proteins, the protease derived from HIV-1 may be detrimental to brain cells and neurons. Our results revealed that HIV-1 protease, at nanomolar concentrations, was as potent as gp120 in causing neurotoxicity in human neuroblastoma neurotypic SH-SY5Y cells. As shown by the Oncor ApopTag staining procedure, HIV-1 protease significantly increased the number of apoptotic cells over the serum-free controls. Moreover, HIV-1 protease-induced neurotoxicity was blocked by a selective protease inhibitor, kynostatin (KNI-272). Antioxidants such as 17beta-estradiol, melatonin, and S-nitrosoglutathione also prevented protease-induced neurotoxicity. These findings indicate that oxidative proteolysis may mediate HIV-1 protease-induced apoptosis and the degeneration of neurons and other brain cells. Centrally active protease inhibitors and antioxidants may play an important role in preventing cerebral atrophy and associated dementia complex caused by HIV-1.
Journal of Biomedical Science 01/1999; 6(6):433-8. · 2.01 Impact Factor
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C C Chiueh
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ABSTRACT: The discoveries of physiological roles of nitric oxide (.NO) as the mediator of endothelium-derived relaxing factor (EDRF) action and the activator of guanylyl cyclase to increase cyclic guanosine monophosphate (cGMP), which lead to vasorelaxation in the cardiovascular system, have been awarded with the 1998 Nobel Prize of Medicine. The present review discusses putative beneficial effects of .NO in the central nervous system (CNS). In addition to its prominent roles of the regulation of cerebral blood flow and the modulation of cell to cell communication in the brain, recent in vitro and in vivo results indicated that .NO is a potent antioxidative agent. .NO terminates oxidant stress in the brain by (i) suppressing iron-induced generation of hydroxyl radicals (.OH) via the Fenton reaction, (ii) interrupting the chain reaction of lipid peroxidation, (iii) augmenting the antioxidative potency of reduced glutathione (GSH) and (iv) inhibiting cysteine proteases. It is apparent that .NO--a relative long half-life nitrogen-centered weak radical--scavenges those short-lived, highly reactive free radicals such as superoxide anion (O2.-), .OH, peroxyl lipid radicals (LOO.) and thiyl radicals (i.e., GS.), yielding reactive nitrogen species including nitrites, nitrates, S-nitrosoglutathione (GSNO) and peroxynitrite (ONOO-). GSNO is 100-fold more potent than GSH; it completely inhibits the weak peroxidative effect of ONOO-. Moreover, CO2 and .NO neutralize prooxidative effects of ONOO-. CO2 prevents protein oxidation but not 3-nitrotyrosine formation caused by ONOO-. Finally, neuroprotective effects of GSNO and .NO have been demonstrated in brain preparations in vivo. These novel neuroprotective properties of .NO and GSNO may have their physiological significance, since oxidative stress depletes GSH while increasing GS. and .NO formation in astroglial and endothelial cells, resulting in the generation of a more potent antioxidant GSNO and providing additional neuro-protection at microM concentrations. This putative GSNO pathway (GSH-->GS.-->GSNO-->.NO + GSSG-->GSH) may be an important part of endogenous antioxidative defense system, which could protect neurons and other brain cells against oxidative stress caused by oxidants, iron complexes, proteases and cytokines. In conclusion, .NO is a potent antioxidant against oxidative damage caused by reactive oxygen species, which are generated by Fenton reaction or other mechanisms in the brain via redox cycling of iron complexes.
Annals of the New York Academy of Sciences 01/1999; 890:301-11. · 3.15 Impact Factor
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ABSTRACT: It has been suggested that transition metals such as iron and manganese produce oxidative injury to the dopaminergic nigrostriatal system. which may play a critical role in the pathogenesis of Parkinson's disease. Intranigral infusion of ferrous citrate (0 to 8.4 nmol, i.n.) acutely increased lipid peroxidation in the substantia nigra and dopamine turnover in the caudate nucleus. Subsequently, it caused a severe depletion of dopamine levels in the rat caudate nucleus. In contrast to iron's pro-oxidant effect, manganese (up to 30 nmol, i.n.) causes neither lipid peroxidation nor nigral injury/dopamine depletion. Manganese (1.05 to 4.2 nmol, i.n.) dose-dependently protected nigral neurons from iron-induced oxidative injury and dopamine depletion. Manganese also suppressed acute increase in dopamine turnover and contralateral turning behaviour induced by iron. In brain homogenates manganese (0 to 10 microM) concentration-dependently inhibited propagation of lipid peroxidation caused by iron (0 to 5 microM). Without the contribution of manganese-superoxide dismutase manganese was still effective in sodium azide and/or heat-pretreated brain homogenates. Surprisingly, iron but not manganese, catalysed the Fenton reaction or the conversion of hydrogen peroxide to hydroxyl radicals. The results indicate that iron and manganese are two transition metals mediating opposite effects in the nigrostriatal system, as pro-oxidant and antioxidant, respectively. In conclusion, intranigral infusion of iron, but not manganese, provides an animal model for studying the pathophysiological role of oxidant and oxidative stress in nigrostriatal degeneration and Parkinsonism. The present results further suggest that the atypical antioxidative properties of manganese may protect substantia nigra compacta neurons from iron-induced oxidative stress.
Neuroscience 09/1998; 85(4):1101-11. · 3.38 Impact Factor
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ABSTRACT: We investigated the effects of nitric oxide on an in vitro and in vivo generation of hydroxyl radicals, and in vivo neurotoxicity caused by intranigral infusion of ferrous citrate in rats. The formation of hydroxyl radicals in vitro, without exogenous hydrogen peroxide, was dose-dependent. Some nitric oxide donors (e.g. sodium nitroprusside) stimulated, while others (nitroglycerin, diethylamine/nitric oxide, nitric oxide in Ringer's solution) suppressed hydroxyl radical generation in vitro. A significant increase in extra-cellular hydroxyl radicals was detected in a brain microdialysis study. Intranigral infusion of ferrous citrate caused long-lasting lipid peroxidation and dopamine depletion in the ipsilateral nigral region and striatum, respectively. Sub-acute dopamine depletion in the striatum was positively correlated with acute lipid peroxidation in substantia nigra. Intranigral administration of nitric oxide did not affect striatal dopamine. Interestingly, nitric oxide in Ringer's protected nigral neurones against the oxidative injury. The results demonstrate that a regional increase in the levels of iron can result in hydroxyl radical generation and lipid peroxidation leading to neurotoxicity. It also demonstrates that exogenous nitric oxide can act as hydroxyl radical scavenger and protect neurones from oxidative injury.
Journal of Chemical Neuroanatomy 07/1998; 14(3-4):195-205. · 2.43 Impact Factor
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ABSTRACT: Sodium nitroprusside (disodium nitroferricyanide) has been suggested to cause cytotoxicity through either the release of cyanide and/or nitric oxide. The present study investigated a possible mechanism that after a brief release of nitric oxide, iron moiety of breakdown products of sodium nitroprusside could cause a long lasting oxidative stress, such as hydroxyl radical generation, lipid peroxidation and cytotoxicity. Intranigral administration of sodium nitroprusside (0-16.8 nmol) to rats induced an acute increase in lipid peroxidation in the substantia nigra and a chronic dopamine depletion in the caudate nucleus. Photodegraded (nitric oxide-exhausted) sodium nitroprusside, however, still produced lipid peroxidation and neurotoxicity in the midbrain. Moreover, non-iron containing nitric oxide-donor compounds, such as S-nitroso-N-acetylpenicillamine, did not cause oxidative brain injury in vivo suggesting that nitric oxide may not mediate neurotoxicity induced by sodium nitroprusside. Additional in vitro studies demonstrated that both freshly prepared (nitric oxide donor) and photodegraded (nitric oxide-exhausted) sodium nitroprusside generated hydroxyl radicals in the presence of ascorbate and also increased lipid peroxidation in brain homogenates. These pro-oxidative effects of sodium nitroprusside were blocked by nitric oxide, S-nitroso-N-acetylpenicillamine, oxyhemoglobin, and deferoxamine (iron chelator). The present results suggest that iron moiety, rather than nitric oxide, may mediate the pro-oxidative properties of sodium nitroprusside. With this new information in mind, the misuse of sodium nitroprusside as a selective nitric oxide donor in both basic and clinical uses should be urgently addressed.
Free Radical Biology and Medicine 06/1998; 24(7-8):1065-73. · 5.42 Impact Factor
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ABSTRACT: The proposed anti- and pro-oxidant effects of nitric oxide (NO) derivatives, such as S-nitrosoglutathione (GSNO) and peroxynitrite, were investigated in the rat nigrostriatal dopaminergic system. Intranigral infusion of freshly prepared GSNO (0-16.8 nmol, i.n.) prevented iron-induced (4.2 nmol, i.n.) oxidative stress and nigral injury, reflected by a decrease in striatal dopamine levels. This neuroprotective effect of GSNO was verified by ex vivo imaging of brain dopamine uptake sites using 125I-labeled RTI-55. In addition, in vitro data indicate that GSNO concentration-dependently inhibited iron-evoked hydroxyl radical generation and brain lipid peroxidation. In this iron-induced oxidant stress model, GSNO was approximately 100-fold more potent than the antioxidant glutathione (GSH). Light-exposed, NO-exhausted GSNO produced neither antioxidative nor neuroprotective effects, which indicates that NO may mediate at least part of GSNO's effects. Moreover, GSNO completely (and GSH only partially) inhibited the weak pro-oxidant effect of peroxynitrite, which produced little injury to nigral neurons in vivo. This study provides relevant in vivo evidence suggesting that nanomol GSNO can protect brain dopamine neurons from iron-induced oxidative stress and degeneration. In conclusion, S-nitrosylation of GSH by NO and oxygen may be part of the antioxidative cellular defense system.
The FASEB Journal 03/1998; 12(2):165-73. · 5.71 Impact Factor
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Advances in pharmacology (San Diego, Calif.) 02/1998; 42:796-800.
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ABSTRACT: The present study clearly demonstrated that l-deprenyl confers a substantial protective effect against MPP+ in the substantia nigra zona compacta in vivo. 32.39. The protection provided by l-deprenyl may not depend on its inhibition of type B monoamine oxidase. A unique antioxidant property of l-deprenyl by suppression of cycotoxic. OH formation and associated oxidative damage induced by MPP+ in the A9 melanized nigral neurons may contribute to the protection against MPP+ toxicity in the nigrostriatal system. The likelihood that l-deprenyl may confer neuroprotection against MPP+ toxicity through antioxidant effect is further strongly supported by our recent data that U-78517F (2-methlaminochromans) a potent inhibitor of ironcatalyzed lipid peroxidation, and DMSO an effective. OH scavenger also protect nigral neurons against MPP(+)-induced severe oxidative injury in the substantia nigra. This putative antioxidant effect of deprenyl may explore another mechanism which may in part contribute to its overt neuroprotection against several toxins, including 6-OHDA, DSP-4, and MPTP, and the possible clinical effects on slowing the neuronal degeneration in early Parkinson's disease, Alzheimer's disorder and even senescent changes.
Annals of the New York Academy of Sciences 07/1996; 786:379-90. · 3.15 Impact Factor
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ABSTRACT: Intranigral infusion of ferrous citrate (4.2 nmol) induced an acute lipid peroxidation in the substantia nigra and a chronic dopamine depletion in the striatum of rat nigrostriatal system. Coinfusion of 8.4 nmol nitric oxide donors such as S-nitrosoglutathione (GSNO) and S-nitroso-N-acetylpenicillamine (SNAP) or nitric oxide (approximately 2 nmol) protected nigrostriatal neurons against iron-induced lipid peroxidation and associated oxidative injury. However, sodium nitroprusside (SNP, 8.4 nmol) augmented dopamine depletion caused by ferrous citrate because SNP is a ferricyanide complex. The present in vivo results indicate that nitric oxide and S-nitrosothiols are antioxidants which can protect brain dopamine neurons against oxidant stress/damage.
Synapse 06/1996; 23(1):58-60. · 2.94 Impact Factor
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ABSTRACT: The pro-oxidant effects of hydroxyl radical (.OH, ferrous ammonium sulfate/Fe2+) or nitric oxide (NO., S-nitroso-N-acetylpenicillamine/SNAP) generating compounds were studied in rat brain homogenate preparations. Submicromolar concentrations of Fe2+, but not SNAP (up to 100 microM), increased the formation of fluorescent products of malondialdehyde in cortical homogenates. In fact, iron-catalyzed brain lipid peroxidation was inhibited by SNAP (100 microM), but not by light-exposed SNAP or its degradation product penicillamine (100 microM). This study provides relevant evidence to suggest that submicromolar concentrations of Fe2+ can potentiate lipid peroxidation in disrupted brain tissue. NO. released from SNAP did not stimulate, but rather inhibited brain lipid peroxidation. These results support the hypothesis that NO., as opposed to .OH radicals, is not a pro-oxidant but rather an antioxidant.
Free Radical Biology and Medicine 02/1996; 21(3):391-4. · 5.42 Impact Factor
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ABSTRACT: Earlier studies intranigrally infusing high doses of manganese (50-250 nmol) revealed a reversible oxidative injury to nigrostriatal dopaminergic neurons. In fact, intranigral infusion of lower dose manganese (4.2 nmol) in the present study did not significantly alter dopamine levels in rat striatum. Moreover, manganese completely suppressed both acute lipid peroxidation in substantia nigra and chronic degeneration of the nigrostriatal neurons induced by intranigral infusion of ferrous citrate (4.2 nmol). These in vivo data indicate that low dose manganese is a potent antioxidant which may activate antioxidative defense mechanisms to protect brain neurons against oxidative stress induced by iron complexes.
Brain Research 12/1995; 698(1-2):285-7. · 2.73 Impact Factor
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ABSTRACT: Treatment of neonatal female rats with androgen results not only in decreased female sexual behavior but also in enhanced male sexual behavior examined in adulthood. The effects of grafting fetal preoptic area (POA) neurons into the POA, and fetal hypothalamic (HPT) neurons into the ventromedial hypothalamus (VMH), were tested in neonatally androgen-sterilized rats (ASR). The rats were injected subcutaneously with 80 micrograms testosterone propionate within the 24 hours after birth to see if sexual behavior could be normalized by fetal brain grafts. In repeated tests on ASR grafted with fetal HPT into the VMH, the lordotic response was seen to increase to the level seen in non-ASR controls, while the increase in mounting behavior in ASR was suppressed following grafting of fetal POA or cerebral cortex into the POA. These results suggest that there are dysfunctions of POA and VMH in ASR, and that the dysfunctions revealed by sexual behavior can be overcome by fetal POA or HPT grafting.
Neuroscience Letters 06/1995; 190(2):97-100. · 2.11 Impact Factor
