Effect of thiol redox state modulators on oxidative stress and sclerotial differentiation of the phytopathogenic fungus <Emphasis Type="Italic">Rhizoctonia solani</Emphasis>

This study showed that sclerotial differentiation in the filamentous phytopathogenic fungus Rhizoctonia solani is directly related to oxidative stress and thiol redox state (TRS). Sclerotial differentiation is modulated by the availability of non-cytotoxic −SH groups as was shown by the inhibition of sclerorial differentiation by the TRS modulator N-acetyl cysteine (AcCSH), and not necessarily with those of the TRS reduced components glutathione (GSH) and its precursor cysteine (CSH) as indicated by the GSH-biosynthesis inducer and inhibitor l-2–oxo-thiazolidine-4-carboxylate and l-buthionine-S,R-sulfoximine, respectively. Moreover, inhibition of sclerotial differentiation was accompanied by decrease of the high oxidative stress indicators, lipid peroxidation and DNA damage in the mycelial substrate where sclerotia initials are formed, which suggests that this phenomenon is related to oxidative stress as it is predicted by our theory on sclerotial differentiation.     

Generator-specific targets of mitochondrial reactive oxygen species

To understand the role of reactive oxygen species (ROS) in oxidative stress and redox signaling it is necessary to link their site of generation to the oxidative modification of specific targets. Here we have studied the selective modification of protein thiols by mitochondrial ROS that have been implicated as deleterious agents in a number of degenerative diseases and in the process of biological aging, but also as important players in cellular signal transduction. We hypothesized that this bipartite role might be based on different generator sites for “signaling” and “damaging” ROS and a directed release into different mitochondrial compartments. Because two main mitochondrial ROS generators, complex I (NADH:ubiquinone oxidoreductase) and complex III (ubiquinol:cytochrome c oxidoreductase; cytochrome bc₁ complex), are known to predominantly release superoxide and the derived hydrogen peroxide (H₂O₂) into the mitochondrial matrix and the intermembrane space, respectively, we investigated whether these ROS generators selectively oxidize specific protein thiols. We used redox fluorescence difference gel electrophoresis analysis to identify redox-sensitive targets in the mitochondrial proteome of intact rat heart mitochondria. We observed that the modified target proteins were distinctly different when complex I or complex III was employed as the source of ROS. These proteins are potential targets involved in mitochondrial redox signaling and may serve as biomarkers to study the generator-dependent dual role of mitochondrial ROS in redox signaling and oxidative stress.     

Ablation of the mammalian methionine sulfoxide reductase A affects the expression level of cysteine deoxygenase

Methionine sulfoxide reductases (Msrs) are able to reduce methionine sulfoxide to methionine both in proteins and free amino acids. By their action it is possible to regulate the function of specific proteins and the cellular antioxidant defense against oxidative damage. Similarly, cysteine deoxygenase (CDO) may be involved in the regulation of protein function and antioxidant defense mechanisms by its ability to oxidized cysteine residues. The two enzymes' involvement in sulfur amino-acids metabolism seems to be connected. Lack of methionine sulfoxide reductase A (MsrA) in liver of MsrA-/- led to a significant drop in the cellular level of thiol groups and lowered the CDO level of expression. Moreover, following selenium deficient diet (applied to decrease the expression levels of selenoproteins like MsrB), the latter effect was maintained while the basal levels of thiol decreased in both mouse strains. We suggest that both enzymes are working in coordination to balance cellular antioxidant defense.     

Phosphoryl Group Transfer by a Fraction of the Soluble Proteins of Catecholamine Storage Vesicles

Abstract: The terminal phosphate group of ATP was transferred to ADP by an enzyme present in the soluble core proteins of adrenal medulla catecholamine storage vesicles. It was purified 10–30-fold by DEAE Sephadex chromatography (Fraction I). The enzyme required divalent metal ions for activation; Mn²⁺ was almost as effective as Mg²⁺, but Ca²⁺ was only a weak activator. Activation by Mg²⁺ took place over a very narrow concentration range (0.5–3 m m ). The specificity of the enzyme activity to nucleoside triphosphates was broad, to the nucleoside diphosphates narrow, favouring adenosine diphosphate. In dependence on the pH the activity increased from pH 4 to pH 7 and remained constantly high between pH 7 and 9. The Arrhenius plot was linear between 5 and 70°C, with an activation energy of 11.1 kcal/mol. The phosphoryl group transfer reaction depended on the function of thiol groups; p -hydroxymercuribenzoate inhibited 50% of the enzyme activity; dithioerythritol reactivated it completely. Gel electrophoresis revealed that in Fraction I, a protein of molecular weight about 45,000, was enriched compared with the total soluble proteins. The enzyme-enriched Fraction I differed significantly in its relative amino acid composition from that of the total soluble proteins; in general, the acidic amino acids were reduced and the more basic acids enhanced.     

Redox Proteomics Uncovers Peroxynitrite-sensitive Proteins That Help Escherichia coli to Overcome Nitrosative Stress

Peroxynitrite is a highly reactive chemical species with antibacterial properties that are synthesized in immune cells. In a proteomic approach, we identified specific target proteins of peroxynitrite-induced modifications in Escherichia coli. Although peroxynitrite caused a fairly indiscriminate nitration of tyrosine residues, reversible modifications of protein thiols were highly specific. We used a quantitative redox proteomic method based on isotope-coded affinity tag chemistry and identified four proteins consistently thiol-modified in cells treated with peroxynitrite as follows: AsnB, FrmA, MaeB, and RidA. All four were required for peroxynitrite stress tolerance in vivo. Three of the identified proteins were modified at highly conserved cysteines, and MaeB and FrmA are known to be directly involved in the oxidative and nitrosative stress response in E. coli. In in vitro studies, we could show that the activity of RidA, a recently discovered enamine/imine deaminase, is regulated in a specific manner by the modification of its single conserved cysteine. Mutation of this cysteine 107 to serine generated a constitutively active protein that was not susceptible to peroxynitrite.     

Thiol/disulphide homeostasis in pregnant women with Familial Mediterranean fever

Objective: To investigate the presence of oxidative stress (OS) in pregnant women with Familial Mediterranean fever (FMF) in the first trimester by evaluating thiol/disulphide homeostasis.

Study design: A total of 31 pregnant women with a diagnosis of FMF, between 11⁰ and 13⁶ weeks of gestation, were compared with 51 healthy pregnant controls at the same gestational weeks. A recently defined method was used to measure plasma native thiol, total thiol and disulphide levels.

Results: There were no differences between groups in terms of maternal age, body mass index and numbers of gravida and parity. Antenatal complications (45.2% vs. 9.8%, P?=?0.001) and primary caesarean section (22.6% vs. 5.9%, P?=?0.037) were higher in the FMF group. Pregnant women with FMF had significantly lower first trimester serum levels of native thiol (297.5?μmol/l (153.2–441.8) vs. 366.1?μmol/l (288.7–432.4), P?=?0.000), total thiol (327.2?μmol/l (171.0–471.0) vs. 389.9?μmol/l (317.1–449.8), P?=?0.000) and higher levels of disulphide (14.2?±?4.5?μmol/l vs. 12.4?±?3.4?μmol/l, P?=?0.045). No differences were found in these parameters among FMF patients with and without antenatal complications.

Conclusions: The main outcome demonstrates a relation between OS and pregnant women with FMF in the first trimester of gestation. OS in the first trimester may be a major aetiological factor of unfavourable pregancy outcomes in this group of patients.     

Reductive activation of type 2 ribosome-inactivating proteins is promoted by transmembrane thioredoxin-related protein

Members of the type 2 ribosome-inactivating proteins (RIPs) family (e.g. ricin, abrin) are potent cytotoxins showing a strong lethal activity toward eukaryotic cells. Type 2 RIPs contain two polypeptide chains (usually named A, for "activity", and B, for "binding") linked by a disulfide bond. The intoxication of the cell is a consequence of a reductive process in which the toxic domain is cleaved from the binding domain by oxidoreductases located in the lumen of the endoplasmic reticulum (ER). The best known example of type 2 RIPs is ricin. Protein disulfide isomerase (PDI) was demonstrated to be involved in the process of ricin reduction; however, when PDI is depleted from cell fraction preparations ricin reduction can still take place, indicating that also other oxidoreductases might be implicated in this process. We have investigated the role of TMX, a transmembrane thioredoxin-related protein member of the PDI family, in the cell intoxication operated by type 2 RIPs ricin and abrin. Overexpressing TMX in A549 cells resulted in a dramatic increase of ricin or abrin cytotoxicity compared with control mock-treated cells. Conversely, no difference in cytotoxicity was observed after treatment of A549 cells or control cells with saporin or Pseudomonas exotoxin A whose intracellular mechanism of activation is not dependent upon reduction (saporin) or only partially dependent upon it (Pseudomonas exotoxin A). Moreover, the silencing of TMX in the prostatic cell line DU145 reduced the sensitivity of the cells to ricin intoxication further confirming a role for this enzyme in intracellular ricin activation.     

Probing conformational changes in human DNA topoisomerase IIα by pulsed alkylation mass spectrometry

Type II topoisomerases are essential enzymes for solving DNA topological problems by passing one segment of DNA duplex through a transient double-strand break in a second segment. The reaction requires the enzyme to precisely control DNA cleavage and gate opening coupled with ATP hydrolysis. Using pulsed alkylation mass spectrometry, we were able to monitor the solvent accessibilities around 13 cysteines distributed throughout human topoisomerase IIα by measuring the thiol reactivities with monobromobimane. Most of the measured reactivities are in accordance with the predicted ones based on a homology structural model generated from available crystal structures. However, these results reveal new information for both the residues not covered in the structural model and potential differences between the modeled and solution holoenzyme structures. Furthermore, on the basis of the reactivity changes of several cysteines located at the N-gate and DNA gate, we could monitor the movement of topoisomerase II in the presence of cofactors and detect differences in the DNA gate between two closed clamp enzyme conformations locked by either 5'-adenylyl β,γ-imidodiphosphate or the anticancer drug ICRF-193.