Oxidative damage induced by the fullerene C60 on photosensitization in rat liver microsomes

We have examined the ability of a commonly used fullerene, C60, to induce oxidative damage on photosensitization using rat liver microsomes as model membranes. When C60 was incorporated into rat liver microsomes in the form of its cyclodextrin complex and exposed to UV or visible light, it induced significant oxidative damage in terms of (1) lipid peroxidation as assayed by thiobarbituric acid reactive substances (TBARS), lipid hydroperoxides and conjugated dienes, and (2) damage to proteins as assessed by protein carbonyls and loss of the membrane-bound enzymes. The oxidative damage induced was both time- and concentration-dependent. C60 plus light-induced lipid peroxidation was significantly inhibited by the quenchers of singlet oxygen ((1)O2), beta-carotene and sodium azide, and deuteration of the buffer-enhanced peroxidation. These observations indicate that C60 is an efficient inducer of peroxidation and is predominantly due to (1)O2. Biological antioxidants such as glutathione, ascorbic acid and alpha-tocopherol significantly differ in their ability to inhibit peroxidation induced by C60. Our studies, hence, indicate that C60, on photosensitization, can induce significant lipid peroxidation and other forms of oxidative damage in biological membranes and that this phenomenon can be greatly modulated by endogenous antioxidants and scavengers of reactive oxygen species.     

Influence of DNA binding on the degradation of oxidized histones by the 20S proteasome

The 20S proteasome is localized in the cytosol and nuclei of mammalian cells. Previous work has shown that the cytosolic 20S proteasome is largely responsible for the selective recognition and degradation of oxidatively damaged cytosolic proteins. Since nuclear proteins are also susceptible to oxidative damage (e.g., from metabolic free radical production, ionizing radiation, xenobiotics, chemotherapy) we investigated the degradation of oxidatively damaged histones, in the presence and in the absence of DNA, by the 20S proteasome. We find that both soluble histones and DNA-bound histones are susceptible to selective proteolytic degradation by the 20S proteasome following mild oxidative damage. In contrast, more severe oxidative damage actually decreases the proteolytic susceptibility of histones. Soluble H1 showed the highest basal and maximal absolute proteolytic rates. Histone fraction H4 exhibited the greatest relative increase in proteolytic susceptibility following oxidation, almost 14-fold, and this occurred at a peroxide exposure of 5 mM. At the other end of the spectrum, histone H2A exhibited a maximal proteolytic response to H2O2 of only 6-fold, and this required an H2O2 exposure of 15 mM. An oxidation of reconstituted linear DNA plasmid-histone complex makes up to 95% of the histones bound to DNA susceptible to degradation, whereas undamaged protein-DNA complexes are not substrates for the proteasome. Severe oxidation by high concentrations of H2O2 appears to decreases the proteolytic susceptibility of histones due to the formation of cross-linked histone-DNA aggregates which appear to inhibit the proteasome. We conclude that the degradation of nuclear proteins is highly selective and requires prior damage of the substrate protein, such as that caused by oxidation.     

Effect of active oxygen radicals on protein and carbohydrate moieties of recombinant human erythropoietin

Our previous study showed that active oxygen radicals generated from a Fenton system and a xanthine plus xanthine oxidase system caused serious loss of in vivo bioactivity of recombinant human erythropoietin (EPO), a highly glycosylated protein. In the present study, we characterized the oxidative modifications to the protein and carbohydrate moiety of EPO, which lead to a reduction of its bioactivity. In vitro bioactivity was reduced when EPO was treated with oxygen radicals generated from a Fenton system in the presence of 0.016 mM H2O2, and the reduction was directly proportional to the loss of in vivo bioactivity. SDS-PAGE analysis showed that dimer formation and degradation was observed under more severe conditions (Fenton reaction with 0.16 mM H2O2). The tryptophan destruction was detected at 0.016 mM H2O2 and well correlated with the loss of in vitro bioactivity, whereas loss of other amino acids were occurred under more severe conditions. Treatment with the Fenton system did not result in any specific damage on the carbohydrate moiety of EPO, except a reduction of sialic acid content under severe condition. These results suggest that active oxygen radicals mainly react with the protein moiety rather than the carbohydrate moiety of EPO. Destruction of tryptophan residues is the most sensitive marker of oxidative damage to EPO, suggesting the importance of tryptophan in the active EPO structure. Deglycosylation of EPO caused an increased of susceptibility to oxygen radicals compared to intact EPO. The role of oligosaccharides in EPO may be to protect the protein structure from active oxygen radicals.     

A prospective analysis of the recovery of attention following pediatric head injury

Free radical-mediated oxidation of proteins results in the formation of carbonyl groups in quantities that reflect the intensity of the oxidative stress. We have developed an immunochemical technique for the quantification of carbonyl groups in protein samples prepared from small tissue samples and cell cultures. Protein samples were slot-blotted onto a polyvinylidene difluoride membrane, which was sequentially treated with 2,4-dinitrophenylhydrazine (DNPH), a primary antibody specific for the 2,4-dinitrophenol group, and a peroxidase-labeled second antibody. After the blots were developed with a chemiluminescent substrate and exposed to X-ray film, the level of immunostaining was quantitated by densitometry. Using oxidized bovine serum albumin as a standard and loading 5 microg of protein per slot, the minimum detectable carbonyl content was approximately 60 pmol carbonyl/mg protein. When necessary, nonspecific staining by noncarbonyl constituents in complex sample matrices was accounted for by using sodium borohydride-treated blanks. Results by the new method were highly correlated (r = 0.932, P < 0.0001) with those of the standard DNPH-based spectrophotometric technique. The coefficient of variation at a carbonyl level of 1.5 nmol/mg protein was 9.7%. The utility of this new method was demonstrated by measuring protein oxidation in cultured human colon cells (SW620) that were briefly exposed to H2O2.     

Historical aspects of the study of malformations in The Netherlands

The oxidative damage of proteins and lipid peroxidation of membrane lipoproteins has already been described as a possible pathogenic mechanism for liver injury. The aim of the present study was to examine the mechanism that could be responsible for the oxidative modification of rat liver 5'-nucleotidase during exposure to different free radical generating systems: FeCl2/ascorbate, xanthine/xanthine oxidase and H2O2. The level of lipid peroxidation products malondialdehyde (MDA), as well as the level of protein carbonyl groups formation was measured in cells and extracellular medium. The activity of 5'-nucleotidase was linearly decreased in both hepatocytes and extracellular medium after exposure to the FeCl2/ascorbate system indicating that the possible mechanism for oxidative modification could be a metal-binding site of the enzyme. In xanthine/xanthine oxidase system the enzyme activity of hepatocytes had decreased in hepatocytes but increased in the extracellular medium indicating that proteolysis of membrane proteins could he responsible for enzyme release in the extracellular medium. When hepatocytes were exposed to a H2O2 free-radical generating system, the activity of 5'-nucleotidase tended to be decreased in cells and decreased in extracellular medium too, indicating that H2O2 could be less reactive in producing an oxidative modification of the enzyme. In order to support the hypothesis that the cation-binding site can be responsible for oxidative modification of the enzyme, the isolated hepatocytes were preincubated with a Ca(2+)-channel blocker (Verapamil) and then exposed to different radical-generating systems. Verapamil had only a slight effect in potentiating the inhibition in the FeCl2/ascorbate system. This probably means that the cellular cation flux and cation binding may be included as a vulnerable site with the greatest importance in the oxidative modification of 5'-nucleotidase.     

Hydrogen peroxide oxidation induces the transfer of phospholipids from the membrane into the cytosol of human erythrocytes

The effects of oxidative damage on membrane phospholipid organization were examined in human erythrocytes. Exposure to H2O2 induced shape changes in these cells; normal discocytes became echinocytic, and stomatocytes generated by foreign phosphatidylserine incorporation reverted to discoid morphology. H2O2 treatment also inhibited phosphatidylserine transport from the outer to inner membrane monolayer, consistent with earlier reports on oxidative sensitivity of the aminophospholipid translocator. The morphological changes are consistent with movement of inner monolayer lipids to the outer monolayer, as might be expected if aminophospholipid sequestration is compromised. However, lipid extraction and prothrombinase activation assays showed no increased exposure of phosphatidylserine on the cell surface. Instead, phosphatidylserine was found associated with the cytosolic fraction of H2O2-treated cells. These observations suggest that oxidative damage alters the lipid organization of erythrocyte membranes, not by randomizing the lipid classes within the bilayer, but by inducing extraction of inner monolayer components into the cytosol.     

Alpha-tubulin missense mutations correlate with antimicrotubule drug resistance in Eleusine indica

The primary leaves of young barley seedlings contain two major, extracellular, acid-soluble proteins of ca. 22 and 23 kDa apparent molecular mass. These proteins disappeared from the intercellular washing fluid upon stress treatments that enhanced H2O2 levels and that induced resistance to subsequent challenge by the powdery mildew fungus Erysiphe graminis f. sp. hordei. A partial peptide sequence of the 22 kDa protein was determined, and a cDNA clone was isolated. The 22 kDa protein belongs the the group of germin-like proteins (GLPs) and was designated HvGLP1. Despite its similarity to germin, i.e. oxalate oxidase, no oxalate oxidase activity of HvGLP1 could be detected. The RNA and soluble protein of HvGLP1 was highly abundant in young leaves, less abundant in older leaves and absent in roots. HvGLP1 RNA oscillated with a circadian rhythm, the minimum and maximum of RNA abundance being at the end of the dark and light periods, respectively. Heat and H2O2 treatment as well as pathogen infection caused disappearance of HvGLP1 protein from the fraction of soluble proteins of the intercellular space. HvGLP1 protein could be re-solubilized from cell walls of heat- or H2O2-treated leaves by boiling in SDS suggesting non-covalent cross linking. Although a physiological role of HvGLP1 insolubilization is still open, the protein may serve as marker for oxidative stress in cereals.     

Changes of the expression of protein substrates of Ca2+/calmodulin-dependent protein kinase II in neonate and adult rats

We studied the expression of whole protein substrates of Ca2+/calmodulin-dependent protein kinase II (CaM kinase II) in the forebrain of neonate and adult rats. Protein substrates were determined by phosphorylation of the soluble and particulate fractions by CaM kinase II with [gamma-33P]ATP. Phosphorylated proteins were analyzed by SDS-PAGE and two-dimensional gel electrophoresis. More than 50 endogenous proteins were found to be phosphorylated by CaM kinase II in both soluble and particulate fractions. The expression of about 15 protein substrates increased in the particulate fraction from neonate to adult rats, and that of several proteins also changed in the soluble fraction. These findings suggest that the expression of protein substrates was regulated during development as well as that of CaM kinase II itself.     

Association between HLA class II genotype and spontaneous clearance of hepatitis C viraemia

The efficiency and reliability of radioactive fucose as a specific label for newly synthesized glycoproteins were investigated. Young adult male rabbits were injected intravitreally with [3H]-fucose, [3H]-galactose. [3H]-mannose, N-acetyl-[3H]-glucosamine or N-acetyl-[3H]-mannosamine, and killed 40 h after injection. In another series of experiments rabbits were injected with either [3H]-fucose or several tritiated amino acids and the specific activity of the vitreous proteins was determined. Vitreous samples were also processed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and histological sections of retina, ciliary body and lens (the eye components around the vitreous body) were processed for radioautography. The specific activity (counts per minute per microgram of protein) of the glycoproteins labeled with [3H]-fucose was always much higher than that of the proteins labeled with any of the other monosaccharides or any of the amino acids. There was a good correlation between the specific activity of the proteins labeled by any of the above precursors and the density of the vitreous protein bands detected by fluorography. This was also true for the silver grain density on the radioautographs of the histological sections of retina, ciliary body and lens. The contribution of radioautography (after [3H]-fucose administration) to the elucidation of the biogenesis of lysosomal and membrane glycoproteins and to the determination of the intracellular process of protein secretion was reviewed. Radioactive fucose is the precursor of choice for studying glycoprotein secretion because it is specific, efficient and practical for this purpose.     

Enhanced oxidative damage in cystic fibrosis patients

Antioxidant depletion and increased free radical production by inflammatory cells have been described in cystic fibrosis (CF) patients. To evaluate oxidative damage intensity, we measured plasma concentrations of malondialdehyde, hydroperoxides and protein carbon groups as markers of oxidative injury to lipids and proteins in a group of 101 CF patients free of acute exacerbation, and in 43-112 controls. Moreover, we estimated antioxidant function by measuring activities of erythrocyte superoxide dismutase, glutathione reductase and vitamin E concentrations. In CF patients, malondialdehyde and hydroperoxide plasma levels were significantly higher than in controls (p < 0.001). Increased lipid peroxidation was documented by these two markers. Parallel rises in protein carbonyls in plasma of CF patients were observed (p < 0.0001). These patients presented biochemical but not clinical vitamin E deficiency. Glutathione reductase and superoxide dismutase activities were significantly higher than in controls. These results show a serious imbalance of CF patients between oxidant-antioxidant status leading to oxidative stress.     

Oxidative damage to proteins, lipids, and DNA in cortical brain regions from patients with dementia with Lewy bodies

Dementia with Lewy bodies (DLB) forms the second most common pathological subgroup of dementia after Alzheimer's disease. The present study compares the levels of oxidative damage to proteins, lipids, and DNA bases in cortical brain areas from patients with DLB with levels in matched control tissues. Overall, there was a trend for protein carbonyl levels to be increased in all areas, but a significant difference was found only in the parietal and temporal lobes. No differences were observed in the levels of lipid peroxidation. Measurement of products of damage to DNA bases showed increased levels of thymine glycol, 8-hydroxyguanine, 2,6-diamino-4-hydroxy-5-formamidopyrimidine, 5-hydroxycytosine, 5-hydroxyuracil, 5-hydroxymethyluracil, and xanthine. Xanthine levels were increased in the DLB group in the parietal, occipital, and temporal lobes, indicating that peroxynitrite or other deaminating species may be involved. The finding of increased protein carbonyls and increased DNA base products in cortical regions from DLB patients indicates that oxidative stress may play a role in DLB.     

Developmental expression of thrombin in zebrafish embryos: a novel model to study hemostasis

Oxidative stress causes modification of cellular macromolecules and leads to cell damage. The objective of this study was to identify protein modifications that relate to thiol groups in human red blood cells under oxidative stress. With t-butyl hydroperoxide (t-BH) treatment, results of isoelectric focusing (IEF) analysis showed that two dithiothreitol-reversible modifications are observed, one toward the cathode and the other to the anode. Protein change toward the cathode was demonstrated to be hemoglobin oxidation, which gains a net positive charge, based on the same focus on IEF gels as hemoglobin and methemoglobin and molecular weight analysis by SDS-polyacrylamide gel electrophoresis (SDS-PAGE). Otherwise, the change toward the anode was the result of mixed disulfide formation between GSH and protein thiols. Based on the results of molecular weight analysis and its reversion from methemoglobin, protein formed mixed disulfides with GSH were also regarded as hemoglobin. As red blood samples were treated with diamide or GSSG, in addition to the mixed disulfides observed in t-BH-treated cells, additional hemoglobin-GSH mixed disulfide appeared. But the disappearance of this diamide-induced additional mixed disulfide by treating cells with t-BH after diamide treatment suggests that the increase of negative charges from GSH are offset by ferrohemoglobin oxidation to ferrihemoglobin. Additionally, other dithiothreitol-reversible modifications of one cell membrane protein, spectrin, were also observed from the formation of high molecular weight molecules as detected by SDS-PAGE. Results indicate that protein thiols in human red blood cells are susceptible to modification under oxidative stress. IEF analysis provides a useful tool to measure methemoglobin and hemoglobin GSH mixed disulfide formation.     

Heat shock provides delayed protection against oxidative injury in cultured human umbilical vein endothelial cells

During both mild and severe ischemia, vascular endothelial cells lining large and small vessels of the ischemic organ are exposed to oxygen-derived free radicals resulting in oxidative damage to the organ. Heat shock has been shown to induce thermotolerance and also protect against ischemic injury, possibly via increased synthesis of heat shock proteins (HSPs). We hypothesized that heat shock preconditioning may protect human endothelial cells against oxidative damage. Cultured human umbilical vein endothelial cells (HUVEC) were subjected to heat shock (42 degrees C, 1 h) and allowed to recover for 2 or 20 h, at which times the cells were oxidatively stressed for 1 h by exposing them to 100-200 mumol/l of hydrogen peroxide (H2O2). Cellular damage was assessed immediately and 18 h later by morphology and release of lactate dehydrogenase (LDH). No protection of HUVEC was seen using the 2-hour recovery interval, but a significant protection (P < 0.05) was observed after the 20-hour delay. Northern blot analysis at 1 and 2 h after heating showed induction of HSP-70 mRNA. Western blot analysis demonstrated a significant increase in HSP-72 protein after 2 as well as 20 h of recovery from heat shock, although the amounts of protein at the two times were not significantly different. Furthermore, no differences in the activity of the antioxidant enzyme catalase were observed between heated and unheated HUVEC at 2 and 20 h after heat preconditioning. Thus, heat shock preconditioning induces delayed protection against oxidative injury in HUVEC, and the mechanism of protection appears to involve more than the expression of HSP-72 or activity of catalase.     

Chronic thromboembolic pulmonary hypertension: hemodynamic effects of selective pulmonary artery DSA with nonionic contrast media]

This paper examines the relationship in Escherichia coli between the in vivo content of 8-oxoguanine (8-oxoG) in chromosomal DNA and deficiencies of various key antioxidant defences. The structural genes for catalases (katG and katE), cytosolic superoxide dismutases (sodA and sodB) or formamidopyrimidine-DNA glycosylase (fpg) were inactivated to obtain bacterial strains lacking the scavenger enzymes for H2O2 or O2.- or the DNA repair protein for 8-oxoG. Wild-type bacteria showed 5-fold increased sensitivity to both lethality and mutagenesis by H2O2 in K medium (1% casamino acids and 1% glucose), as compared with nutrient broth. This higher sensitivity was associated with increased chromosomal oxidative damage, estimated as the 8-oxodG content, and with a marked decrease in both catalase and SOD activities. Bacteria lacking both cytosolic SODs (sodA sodB mutant) displayed increased 8-oxodG content in chromosomal DNA (2.8-fold that of the wild-type) when grown under standard aerated conditions. Comparatively, no significant difference in 8-oxodG content was observed in cells grown without aeration. Bacteria totally devoid of catalase activity (katG katE mutant) showed wild-type contents of 8-oxodG in chromosomal DNA when grown under aerated conditions. Nevertheless, the protective role of catalase in preventing formation of 8-oxodG in chromosomal DNA became evident under oxidative stress conditions: growth under hyperoxygenation and, particularly, following H2O2 exposure. Catalase deficiency resulted in a dramatic decrease in viability after H2O2 exposure. A deficiency of Fpg protein also sensitized E.coli to H2O2 lethality, though to lesser extent than a deficiency of catalase activity. However, the scavenger enzyme and the DNA repair protein protected equally against 8-oxoG formed in vivo upon H2O2 treatment.     

Severe energy impairment consequent to inactivation of mitochondrial ATP synthase as an early event in cell death: a mechanism for the selective sensitivity to H2O2 of differentiating erythroleukemia cells

Irreversible damage to Friend's erythroleukemia cells was caused by induction of endogenous heme biosynthesis with the differentiating agent N,N'-hexamethylene bisacetamide followed by a 30-min exposure to 0.25 mM H2O2. Early irreversible ATP depletion was observed concomitant with oxidative inactivation of the mitochondrial ATP synthase. Cell proliferative capacity was also impaired within 2 h of the treatment, and progressive delayed cell lethality, starting 2 h after the insults, was also found. Based on the prevention provided by specific antioxidants and on the absence of malodialdehyde production, all the effects were ascribed to the oxidant action of .OH radicals, or closely related species, generated through iron-catalyzed reactions of H2O2, which apparently caused site-directed oxidative modifications of iron-binding proteins, in particular mitochondrial ATP synthase, rather than peroxidation of membrane lipids. Similar effects were mimicked even in the parental cell line when oligomycin was used to inhibit selectively mitochondrial ATP synthase activity, thereby lowering the enzyme activity to a level similar to that found in H2O2-damaged differentiating cells. Hence, induction of erythroid differentiation makes the mitochondrial ATP synthase a major target of H2O2 by enhancing the availability of redox-active iron in the local environment of the enzyme. Subsequent oxidative inactivation of the mitochondrial ATP synthase, resulting in severe energy impairment, leads to loss of cell growth capacity. Erythroleukemia cells may serve as a model system for the combination of two selective properties: (1) the capacity for carrying out efficient heme synthesis and/or for undergoing iron overload-like state; and (2) subsequent enhanced sensitivity to reactive oxygen species generators. Early severe mitochondrial dysfunction and energy impairment may be a major part of the mechanism of the sensitivity.     

Clustered organization of S100 genes in human and mouse

Hydrogen peroxide (H2O2) has been reported to be present at significant levels in the lens and aqueous humor in some cataract patients and suggested as a possible source of chronically inflicted damage to lens epithelial (LE) cells. We measured H2O2 effects on bovine and mouse LE cells and determined whether LE cells from old calorically restricted mice were more resistant to H2O2-induced cellular damage than those of same age ad libitum fed (AL) mice. Bovine lens epithelial cells were exposed to H2O2 at 40 or 400 microM for 2 h and then allowed to recover from the stress. The cells were assayed for DNA damage, DNA synthesis, cell viability, cell morphology, response to growth stimuli, and proliferation potential. Hydrogen peroxide-treated cells showed an increased DNA unwinding 50% greater than that for untreated controls. These DNA strand breaks appeared to be almost completely rejoined by 30 min following removal of the cells from a 2-h exposure. The 40 microM exposure did not produce a significantly lower DNA synthesis rate than the control, it responded to growth factor stimuli, and it replicated as did the control cells after removal of H2O2. The 400 microM H2O2 severely affected DNA synthesis and replication, as shown by increased cell size and by markedly reduced clonal cell growth. The cells did not respond to growth stimulation by serum or growth factors and lost irreversibly the capacity to proliferate. The responses of LE cells from old adlib diet (AL) and calorically restricted (CR) mice to H2O2 were significantly different. Exposure of LE cells to 20, 40, or 100 microM H2O2 for 1 h induces a significant loss of cellular proliferation in cells from old AL mice. LE cells from long-term CR mice of the same strain and age were more resistant to oxidative damage at all three concentrations of H2O2 than those of both old and young AL mice and showed a significantly higher proliferation potential following treatment. It is concluded that CR results in superior resistance to reactive oxygen radicals in the lens epithelium.     

Efficacy and complications of intraprostatic prosthesis in the treatment of benign hyperplasia of the prostate

Heat shock (HS) proteins (HSP) function as molecular chaperones and protect cells from thermal and oxidative injury. The signals leading to HSP synthesis, i.e. the "cellular thermometer(s)," are still a matter of debate. In the human premonocytic line U937, we investigated the effects of specific modification of membrane fatty acid (FA) composition by incubation with various saturated and unsaturated fatty acids (UFA) on the HS response and on hydrogen peroxide (H2O2)-induced cell death. FA readily incorporated into U937 cell membranes. UFA did not modulate the HS response but potentiated H2O2-mediated damage, while pre-exposure to HS protected the UFA-treated cells from this increased H2O2 toxicity.     

Identification of S100b protein as copper-binding protein and its suppression of copper-induced cell damage

We have isolated from bovine brain a protein with a high capacity to inhibit the copper ion-catalyzed oxidation of L-ascorbate and identified it as S100b protein, an EF-hand calcium-binding protein, by sequencing its proteolytic peptides. Copper binding studies showed that this protein has four copper-binding sites per dimeric protein molecule with a dissociation constant of 0.46 microM and that in the presence of L-ascorbate, copper ions bind to a total of six binding sites with a great increase in affinity. Furthermore, we examined whether S100b protein can prevent copper-induced cell damage. Bovine S100b protein was found to suppress dose-dependently the hemolysis of mouse erythrocytes induced by CuCl2. We transformed Escherichia coli cells with pGEX-5X-3 vector containing a cDNA for rat S100b protein, so that this protein could be expressed as a fusion protein with glutathione S-transferase. The transformed cells were demonstrated to be markedly resistant to a treatment with CuCl2 plus H2O2 as compared with the control cells expressing glutathione S-transferase alone. These results indicate that S100b protein does suppress oxidative cell damage by sequestering copper ions.     

Antioxidant properties of the triaminopyridine, flupirtine

Flupirtine is a triaminopyridine-derived centrally acting analgesic, which interacts with mechanisms of noradrenergic pain modulation. Recently, it has been found to display neuroprotective effects in various models of excitotoxic cell damage, global and focal ischemia. Although this profile suggests that flupirtine acts as an antagonist of the N-methyl-D-aspartate (NMDA) and glutamate-triggered Ca2+ channel, there is no direct interaction with the receptor. In this paper, we examined whether flupirtine can act as an antioxidant and prevent free radical-mediated structural damage. Flupirtine at 5-30 microM inhibited ascorbate/ Fe2+ (1-10 microM)-stimulated formation of thiobarbituric reactive substances, an indicator of lipid peroxidation, in rat brain mitochondria. Interestingly, we found an increasing effectiveness of the drug at higher iron concentrations. Additionally, higher concentrations of flupirtine also provided protection against protein oxidation, as demonstrated by a decrease in protein carbonyls formed after treatment of rat brain homogenates with ascorbate/Fe2+. In PC12 cell culture, flupirtine at 10-100 microM was able to attenuate H2O2-stimulated cell death and improve the survival by 33%.     

Preoperative bone mineral density of the proximal tibia and migration of the tibial component after uncemented total knee arthroplasty

BACKGROUND: It has been rarely reported that heat stress induces an early phase of protection against oxidative damage, whereas a delayed phase of protection is shown in heat stress. To explore the early effect of heat stress against oxidative damage, we evaluated the changes in contractility, lipid peroxidation, and ultrastructure induced by hydrogen peroxide (H2O2) with or without heat stress (HS) in human skeleton muscle. METHODS: Thirty-two muscle samples were obtained from the vastus lateralis muscle of 7 subjects. These specimens were divided into three groups based on form of treatment: HS (n = 13), non HS (n = 14), and control group (n = 5). The control group was performed under identical conditions without H2O2. Specimens in the HS group were incubated at 42 degrees C for 20 min, while those in the non-HS and control groups were maintained at 37 degrees C. RESULTS: The control group showed no significant change in contractile force. Although contractile force significantly decreased 30 min after H2O2 administration in both the HS and non-HS groups, only the HS group showed apparent recovery of contractile force 60 min after H2O2 administration. Lipid peroxidation was lower in the HS group than in the non-HS group. Ultrastructural examination revealed less mitochondrial damage in the HS group compared with the non-HS group. CONCLUSION: We found that human skeleton muscle escaped cellular damage induced by H2O2 in the early phase after heat stress. These data suggest evidence for an early effect of heat stress against ischemia/reperfusion injury in human muscle.