Regulation of Protein Function and Signaling by Reversible Cysteine S-Nitrosylation

NO is a versatile free radical that mediates numerous biological functions within every major organ system. A molecular pathway by which NO accomplishes functional diversity is the selective modification of protein cysteine residues to form S-nitrosocysteine. This post-translational modification, S-nitrosylation, impacts protein function, stability, and location. Despite considerable advances with individual proteins, the in vivo biological chemistry, the structural elements that govern the selective S-nitrosylation of cysteine residues, and the potential overlap with other redox modifications are unknown. In this minireview, we explore the functional features of S-nitrosylation at the proteome level and the structural diversity of endogenously modified residues, and we discuss the potential overlap and complementation that may exist with other cysteine modifications.     

Endosomal and lysosomal effects of desferrioxamine: protection of HeLa cells from hydrogen peroxide-induced DNA damage and induction of cell-cycle arrest

The role of endosomal/lysosomal redox-active iron in H2O2-induced nuclear DNA damage as well as in cell proliferation was examined using the iron chelator desferrioxamine (DFO). Transient transfections of HeLa cells with vectors encoding dominant proteins involved in the regulation of various routes of endocytosis (dynamin and Rab5) were used to show that DFO (a potent and rather specific iron chelator) enters cells by fluid-phase endocytosis and exerts its effects by chelating redox-active iron present in the endosomal/lysosomal compartment. Endocytosed DFO effectively protected cells against H2O2-induced DNA damage, indicating the importance of endosomal/lysosomal redox-active iron in these processes. Moreover, exposure of cells to DFO in a range of concentrations (0.1 to 100 microM) inhibited cell proliferation in a fluid-phase endocytosis-dependent manner. Flow cytometric analysis of cells exposed to 100 microM DFO for 24 h showed that the cell cycle was transiently interrupted at the G2/M phase, while treatment for 48 h led to permanent cell arrest. Collectively, the above results clearly indicate that DFO has to be endocytosed by the fluid-phase pathway to protect cells against H2O2-induced DNA damage. Moreover, chelation of iron in the endosomal/lysosomal cell compartment leads to cell cycle interruption, indicating that all cellular labile iron is propagated through this compartment before its anabolic use is possible.     

Trimetazidine protects low-density lipoproteins from oxidation and cultured cells exposed to H(2)O(2) from DNA damage

Trimetazidine is a well-established anti-ischemic drug, which has been used for long time in the treatment of pathological conditions related with the generation of reactive oxygen species. However, although extensively studied, its molecular mode of action remains largely unknown. In the present study, the ability of trimetazidine to protect low-density lipoproteins (LDL) from oxidation and cultured cells from H₂O₂-induced DNA damage was investigated. Trimetazidine, tested at concentrations 0.02 to 2.20 mM, was shown to offer significant protection to LDL exposed to three different oxidizing systems, namely copper, Fe/ascorbate, and met-myoglobin/H₂O₂. The oxidizability of LDL was estimated by measuring, (i) the lag period, (ii) the maximal rate of conjugated diene formation, (iii) the total amount of conjugated dienes formed, (iv) the electrophoretic migration of LDL protein in agarose gels (REM), and (v) the inactivation of the enzyme PAF-acetylhydrolase present in LDL. In addition, the presence of trimetazidine decreased considerably the DNA damage in H₂O₂-exposed Jurkat cells in culture. H₂O₂ was continuously generated by the action of glucose oxidase at a rate of 11.8 ± 1.5 μM per min (60 ng enzyme per 100 μl), and DNA damage was assessed by the single cell gel electrophoresis assay (also called comet assay). The protection offered by trimetazidine in this system (about 30% at best) was transient, indicating modification of this agent during its action. These results indicate that trimetazidine can modulate the action of oxidizing agents in different systems. Although its mode of action is not clarified, the possibility that it acts as a lipid barrier permeable transition metal chelator is considered.     

Lymphocyte development requires S-nitrosoglutathione reductase

NO is critical to immunity, but its role in the development of the immune system is unknown. In this study, we show that S-nitrosoglutathione reductase (GSNOR), a protein key to the control of protein S-nitrosylation, is important for the development of lymphocytes. Genetic deletion of GSNOR in mice results in significant decrease in both T and B lymphocytes in the periphery. In thymus, GSNOR deficiency causes excessive protein S-nitrosylation, increases apoptosis, and reduces the number of CD4 single-positive thymocytes. Lymphopenia and increase in S-nitrosylation and apoptosis in GSNOR-deficient mice are largely abolished by genetic deletion of inducible NO synthase. Furthermore, the protection of lymphocyte development by GSNOR is apparently intrinsic to hematopoietic cells. Thus, GSNOR, likely through regulation of S-nitrosylation and apoptosis, physiologically plays a protective role in the development of the immune system.     

Host Nitric Oxide Disrupts Microbial Cell-to-Cell Communication to Inhibit Staphylococcal Virulence

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SIN-1-induced DNA damage in isolated human peripheral blood lymphocytes as assessed by single cell gel electrophoresis (comet assay)

Human lymphocytes were exposed to increasing concentrations of SIN-1, which generates superoxide and nitric oxide, and the formation of single-strand breaks (SSB) in individual cells was determined by the single-cell gel electrophoresis assay (comet assay). A dose- and time-dependent increase in SSB formation was observed rapidly after the addition of SIN-1 (0.1-15 mM). Exposure of the cells to SIN-1 (5 mM) in the presence of excess of superoxide dismutase (0.375 mM) increased the formation of SSB significantly, whereas 1000 U/ml catalase significantly decreased the quantity of SSB. The simultaneous presence of both superoxide dismutase and catalase before the addition of SIN-1 brought the level of SSB to that of the untreated cells. Moreover, pretreatment of the cells with the intracellular Ca(2+)-chelator BAPTA/AM inhibited SIN-1-induced DNA damage, indicating the involvement of intracellular Ca(2+) changes in this process. On the other hand, pretreatment of the same cells with ascorbate or dehydroascorbate did not offer any significant protection in this system. The data suggest that H2O2-induced changes in Ca(2+) homeostasis are the predominant pathway for the induction of SSB in human lymphocytes exposed to oxidants.     

Trimetazidine protects low-density lipoproteins from oxidation and cultured cells exposed to H2O2 from DNA damage

Trimetazidine is a well-established anti-ischemic drug, which has been used for long time in the treatment of pathological conditions related with the generation of reactive oxygen species. However, although extensively studied, its molecular mode of action remains largely unknown. In the present study, the ability of trimetazidine to protect low-density lipoproteins (LDL) from oxidation and cultured cells from H₂O₂-induced DNA damage was investigated. Trimetazidine, tested at concentrations 0.02 to 2.20 mM, was shown to offer significant protection to LDL exposed to three different oxidizing systems, namely copper, Fe/ascorbate, and met-myoglobin/H₂O₂. The oxidizability of LDL was estimated by measuring, (i) the lag period, (ii) the maximal rate of conjugated diene formation, (iii) the total amount of conjugated dienes formed, (iv) the electrophoretic migration of LDL protein in agarose gels (REM), and (v) the inactivation of the enzyme PAF-acetylhydrolase present in LDL. In addition, the presence of trimetazidine decreased considerably the DNA damage in H₂O₂-exposed Jurkat cells in culture. H₂O₂ was continuously generated by the action of glucose oxidase at a rate of 11.8 ± 1.5 μM per min (60 ng enzyme per 100 μl), and DNA damage was assessed by the single cell gel electrophoresis assay (also called comet assay). The protection offered by trimetazidine in this system (about 30% at best) was transient, indicating modification of this agent during its action. These results indicate that trimetazidine can modulate the action of oxidizing agents in different systems. Although its mode of action is not clarified, the possibility that it acts as a lipid barrier permeable transition metal chelator is considered.     

Involvement of heat shock protein-70 in the mechanism of hydrogen peroxide-induced DNA damage: the role of lysosomes and iron

Heat shock protein-70 (Hsp70) is the main heat-inducible member of the 70-kDa family of chaperones that assist cells in maintaining proteins functional under stressful conditions. In the present investigation, the role of Hsp70 in the molecular mechanism of hydrogen peroxide-induced DNA damage to HeLa cells in culture was examined. Stably transfected HeLa cell lines, overexpressing or lacking Hsp70, were created by utilizing constitutive expression of plasmids containing the functional hsp70 gene or hsp70-siRNA, respectively. Compared to control cells, the Hsp70-overexpressing ones were significantly resistant to hydrogen peroxide-induced DNA damage, while Hsp70-depleted cells showed an enhanced sensitivity. In addition, the "intracellular calcein-chelatable iron pool" was determined in the presence or absence of Hsp70 and found to be related to the sensitivity of nuclear DNA to H(2)O(2). It seems likely that the main action of Hsp70, at least in this system, is exerted at the lysosomal level, by protecting the membranes of these organelles against oxidative stress-induced destabilization. Apart from shedding additional light on the mechanistic details behind the action of Hsp70 during oxidative stress, our results indicate that modulation of cellular Hsp70 may represent a way to make cancer cells more sensitive to normal host defense mechanisms or chemotherapeutic drug treatment.