Peroxiredoxin 2, glutathione peroxidase,and catalase in the cytosol and membrane of erythrocytes under H2O2-induced oxidative stress

Abstract

Erythrocytes are continuously exposed to risk of oxidative injury due to oxidant oxygen species. To prevent damage, they have antioxidant agents namely, catalase (Cat), glutathione peroxidase (GPx), and peroxiredoxin 2 (Prx2). Our aim was to contribute to a better understanding of the interplay between Prx2, Cat, and GPx under H₂O₂-induced oxidative stress, by studying their changes in the red blood cell cytosol and membrane, in different conditions. These three enzymes were quantified by immunoblotting. Malondialdehyde, that is, lipoperoxidation (LPO) in the erythrocyte membrane, and membrane-bound hemoglobin (MBH) were evaluated, as markers of oxidative stress. We also studied the erythrocyte membrane protein profile, to estimate how oxidative stress affects the membrane protein structure. We showed that under increasing H₂O₂ concentrations, inhibition of the three enzymes with or without metHb formation lead to the binding of Prx2 and GPx (but not Cat) to the erythrocyte membrane. Prx2 was detected mainly in its oxidized form and the linkage of metHb to the membrane seems to compete with the binding of Prx2. Catalase played a major role in protecting erythrocytes from high exogenous flux of H₂O₂, since whenever Cat was active there were no significant changes in any of the studied parameters. When only Cat was inhibited, Prx2 and GPx were unable to prevent H₂O₂-induced oxidative stress resulting in increasing MBH and membrane LPO. Additionally, the inhibition of one or more of these enzymes induced changes in the anchor/linker proteins of the junctional complexes of the membrane cytoskeleton–lipid bilayer, which might lead to membrane destabilization.     

Characterization of recombinant human gastrointestinal glutathione peroxidase mutant produced in Escherichia coli

Abstract

Gastrointestinal glutathione peroxidase (GI-GPx, GPx2) is a selenium-dependent enzyme and regarded as the first line of defense against oxidative stress caused by ingested pro-oxidants or gut microbes. As the essential part of the catalytic site of GPx2, selenocysteine (Sec) is encoded by an in-frame UGA stop codon, which makes the expression of human GPx2 (hGPx2) using traditional recombinant DNA technology difficult. In order to produce bioactive recombinant hGPx2, the gene of hGPx2 was designed with the conversion of the codons for four cysteine (Cys) residues to the codons for serine (Ser) residues and the codon for Sec-40 was changed to the codon for Cys. This recombinant seleno-hGPx2 mutant was obtained using a single protein production system in a cysteine (Cys) auxotrophic strain, in which Sec was introduced into the protein via tRNA^Cys misleading. The activity of this mutant was in the same order of magnitude as that of hGPx4, but about one order of magnitude lower than that of hGPx1 and hGPx3. Further study showed that the mutant exhibited pH and temperature optima of 7.4 and 25°C, respectively. The results obtained from the kinetic analysis demonstrated that it followed a typical ping-pong mechanism similar to native GPx. As there was no report on the activity of purified GPx2, this research was valuable in recognizing native GPx2. In addition, a three-dimensional structure of seleno-hGPx2 mutant was constructed, which could facilitate further analysis of the role and the catalytic mechanism of native GPx2.     

Oxidative Glycation and Free Radical Production: A Causal Mechanism of Diabetic Complications

Glucose may oxidise under physiological conditions and lead to the production of protein reactive ketoaldehydes, hydrogen peroxide and highly reactive oxidants. Glucose is thus able to modify proteins by the attachment of its oxidation derived aldehydes, leading to the development of novel protein fluoro-phores, as well as fragment protein via free radical mechanisms.

The fragmentation of protein by glucose is inhibitable by metal chelators such as diethylenetriamine pentaacetic acid (DETAPAC) and free radical scavengers such as benzoic acid, and sorbitol. The enzymic antioxidant, catalase, also inhibits protein fragmentation.

Protein glycation and protein oxidation are inextricably linked. Indeed, using boronate affinity chromatography to separate glycated from non-glycated material, we demonstrate that proteins which arc glycated exhibit an enhanced tryptophan oxidation. Our observation that both glycation and oxidation occur simultaneously further supports the hypothesis that tissue damage associated with diabetes and ageing has an oxidative origin.     

Effect of copper on callus growth and gene expression of in vitro-cultured pith explants of Nicotiana glauca

Abstract

Copper is a vital component of electron transfer reactions mediated by proteins such as superoxide dismutase, cytochrome c oxidase and plastocyanin, but its concentrations in the cells needs to be maintained at low levels. In fact, the same ability of this essential metal ion to transfer electrons can also make it toxic to cells when present in excess. In vitro cultured explants of Nicotiana have been extensively used as a model to analyse metal-DNA interactions. In this report, we examined the effect of copper (1, 10 and 100 μM CuSO₄) on callus growth and protein synthesis of in vitro-cultured pith explants of Nicotiana glauca. In addition, a N. glauca cDNA library from Cu-treated (100 μM CuSO₄) pith explants cultured in vitro for 24 h was analysed by mRNA differential screening. The copper treatments inhibited callus growth of pith explants. The extent of inhibition was directly correlated to metal concentration. One and 10 μM CuSO₄ induced a notable increase of proteins synthesis relative to control explants. By contrast, 100 μM CuSO₄ inhibited protein synthesis relative to control extracts. The SDS-PAGE fluorography of pith proteins revealed, in Cu-treated extracts qualitative and/or quantitative differences in the synthesis of some polypeptides compared with control explants. Copper-modulated patterns of gene expression were also analysed by mRNA differential screening. The N. glauca genes isolated from Cu-treated pith explants shared common identities with other genes known to be elicited by diverse stresses, including pathogenesis and abiotic stress. In particular, the cDNAs were homologues to genes encoding cell wall proteins (i.e., extensin, and arabinogalactan-protein) and pathogenesis-related proteins (i.e., osmotin, endochitinase and a member of the Systemic Acquired Resistance gene family). In addition, an MD-2-related lipid-recognition (ML) domain protein and the enzyme S-adenosyl-L-homocysteine (AdoHcy) hydrolase appeared involved in the response to copper stress. In animal cells, AdoHcy hydrolase is a copper binding protein in vivo, which suggests that, also in plant tissues, this enzyme may play an important role in regulating the levels and intracellular distribution of copper.     

Biochemical regulation of the initiation of DNA replication

Abstract

The initiation of DNA replication is a key step in the cell division cycle and in DNA endoreduplication. Initiation of replication takes place at specific places in chromosomes known as replication origins. These are subject to temporal regulation within the cell cycle and may also be regulated as a function of plant development. In yeast, replication origins are recognised and bound by three different groups of proteins at different stages of the cell cycle. Of these, the MCM proteins are the most likely to be involved in activating the origins in order to facilitate initiation. MCM-like proteins also occur in plants, but have not been characterised in detail. Other proteins which bind to origins have been identified, as has a protein with a strong affinity for ds-ss junctions in DNA molecules.     

Lipid and protein oxidation in hepatic homogenates and cell membranes exposed to bile acids

Cholestasis occurs in a variety of hepatic diseases and causes damage due to accumulation of bile acids in the liver. The aim was to investigate the effect of several bile acids, i.e. chenodeoxycholic, taurochenodeoxycholic, deoxycholic, taurodeoxycholic, ursodeoxycholic, lithocholic and taurolithocholic (TLC), in inducing oxidative damage. Hepatic tissue of male Sprague-Dawley rats was incubated with or without 1 mM of each bile acid, with or without 0.1 mM FeCl₃ and 0.1 mM ascorbic acid for the purpose of generating free radicals. Several bile acids increased lipid and protein oxidation, with TLC being the most pro-oxidative (657% and 175% in homogenates and 350% and 311% in membranes, respectively). TLC also enhanced iron-induced oxidative stress to lipids (21% in homogenates and 29% in membranes) and to proteins (74% in membranes). This enhancement was dose- and time-dependent and was reduced by melatonin. These results suggest that bile acids differentially mediate hepatic oxidative stress and may be involved in the physiopathology of cholestasis.     

Patterns of RNA and Protein Synthesis in Post-Ischemic Livers

The re-establishment of the blood supply to a formerly ischemic liver lobe, before the “point of no return” of the tissue is reached, induces a series of changes in protein and RNA metabolism that are functional to the repair of the damage suffered by the cells. Among these events there is the increase, in synthesis of a group of proteins known as heat-shock (or stress) proteins, which are also induced in liver cells by different kinds of oxidative stress. The increase in synthesis of these proteins is largely due to the activation of their genes: some of these genes are also activated in cells stimulated to grow.

These observations suggest a link between oxidative stress, repair of cell damage and cell multiplication.     

The role of protein kinase C in the increased generation in isolated rat hepatocytes of the hydroxyl radical by puromycin aminonucleoside

Puromycin aminonucleoside (PAN) has been known to induce proteinuria. The increased generation of reactive oxygen species (ROS) has been implicated in this toxicity of PAN. We have reported that PAN increases the synthesis of methylguanidine (MG) and creatol which are the products of the reaction of creatinine and the hydroxyl radical in isolated rat hepatocytes. However, the mechanism for the increased ROS induced by PAN is still unclear. In this paper, we investigate the role of protein kinase C (PKC) on the PAN induced reactive oxygen generation in isolated rat hepatocytes. Isolated hepatocytes were incubated in Krebs-Henseleit bicarbonate buffer containing 3% BSA, 16.6 mM creatinine and tested reagents. MG and creatol were determined by high-performance liquid chromatography using 9,10-phenanthrenequinone for the post-labeling. PAN increased MG and creatol synthesis in isolated rat hepatocytes by 60%. 1-(5-Isoquinolinesulfonyl)-2-methylpiperazine dihydrochloride (H-7), a PKC inhibitor, at 10 and 100 μM significantly inhibited MG and creatol synthesis with or without PAN. The inhibition rate is dose dependent from 10 to 100 μM. H1004, a reagent used as control for H-7, did not affect (at 10 μM) or increased little (at 100 μM) the synthesis of MG and creatol. Ro31-8425, a potent PKC inhibitor, significantly inhibited (at 10 μM) MG synthesis in the presence of PAN. PKC in the membrane fraction, a marker of PKC activation, increased over the initial concentration by a factor of 1.65-fold at 60 min incubation and 2.16-fold at 120 min with PAN, while it changed little without PAN. These results indicate that PAN activates PKC resulting in increased hydroxyl radical generation in isolated rat hepatocytes.     

Accumulation of the hydroxyl free radical markers meta-, ortho-tyrosine and DOPA in cataractous lenses is accompanied by a lower protein and phenylalanine content of the water-soluble phase

Post-translational modifications of lens proteins play a crucial role in the formation of cataract during ageing. The aim of our study was to analyze protein composition of the cataractous lenses by electrophoretic and high-performance liquid chromatographic (HPLC) methods.

Samples were obtained after extracapsular cataract surgery performed by phacoemulsification technique from cataract patients with type 2 diabetes mellitus (DM CAT, n = 22) and cataract patients without diabetes (non-DM CAT, n = 20), while non-diabetic non-cataractous lenses obtained from cadaver eyes served as controls (CONTR, n = 17). Lens fragments were derived from the surgical medium by centrifugation. Samples were homogenized in a buffered medium containing protease inhibitor. Soluble and insoluble protein fractions were separated by centrifugation. The electrophoretic studies were performed according to Laemmli on equal amounts of proteins and were followed by silver intensification. Oxidized amino acid and Phe content of the samples were also analyzed by HPLC following acid hydrolysis of proteins.

Our results showed that soluble proteins represented a significantly lower portion of the total protein content in cataractous lenses in comparison with the control group (CONTR, 71.25%; non-DM CAT, 32.00%; DM CAT, 33.15%; p < 0.05 vs CONTR for both). Among the proteins, the crystallin-like proteins with low-molecular weight can be found both in the soluble and insoluble fractions, and high-molecular weight aggregates were found mainly in the total homogenates. In our HPLC analysis, oxidatively modified derivatives of phenylalanine were detected in cataractous samples. We found higher levels of m-Tyr, o-Tyr and DOPA in the total homogenates of cataractous samples compared to the supernatants. In all three groups, the median Phe/protein ratio of the total homogenates was also higher than that of the supernatants (total homogenates vs supernatants, in the CONTR group 1102 vs 633 μmol/g, in the DM CAT group 1187 vs 382 μmol/g and in the non-DM CAT group 967 vs 252 μmol/g; p < 0.05 for all).

In our study we found that oxidized amino acids accumulate in cataractous lenses, regardless of the origin of the cataract. The accumulation of the oxidized amino acids probably results from oxidation of Phe residues of the non-water soluble lens proteins. We found the presence of high-molecular weight protein aggregates in cataractous total homogenates, and a decrease of protein concentration in the water-soluble phase of cataractous lenses. The oxidation of lens proteins and the oxidative modification of Phe residues in key positions may lead to an altered interaction between protein and water molecules and thus contribute to lens opacification.