Martina Engels

Tau protein degradation is catalyzed by the ATP/ubiquitin-independent 20S proteasome under normal cell conditions.

Tau is the major protein exhibiting intracellular accumulation in Alzheimer disease. The mechanisms leading to its accumulation are not fully understood. It has been proposed that the proteasome is responsible for degrading tau but, since proteasomal inhibitors block both the ubiquitin-dependent 26S proteasome and the ubiqutin-independent 20S proteasome pathways, it is not clear which of these pathways is involved in tau degradation. Some involvement of the ubiquitin ligase, CHIP in tau degradation has also been postulated during stress. In the current studies, we utilized HT22 cells and tau-transfected E36 cells in order to test the relative importance or possible requirement of the ubiquitin-dependent 26S proteasomal system versus the ubiquitin-independent 20S proteasome, in tau degradation. By means of ATP-depletion, ubiquitinylation-deficient E36ts20 cells, a 19S proteasomal regulator subunit MSS1-siRNA approaches, and in vitro ubiquitinylation studies, we were able to demonstrate that ubiquitinylation is not required for normal tau degradation.

Irradiation of GAPDH: a model for environmentally induced protein damage.

Abstract Environmental factors, including sunlight, are able to induce severe oxidative protein damage. The modified proteins are either repaired, degraded or escape from degradation and aggregate. In the present study we tested the effect of different sunlight components such as UV-A, UV-B, and infrared radiation on protein oxidation in vitro. We chose glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as a model enzyme and analyzed the irradiation-induced enzyme activity loss, fragmentation and aggregation, and quantified various oxidative amino acid modifications. Since γ-irradiation was used in numerous studies before, we used it for comparative purposes. Infrared radiation was unable to damage GAPDH in the dose range tested (0–1000 J/cm2). UV-A led to a decrease in free thiol content, which was connected with a loss in enzyme activity, while only at very high doses could moderate protein aggregation and fragmentation be observed. UV-B (0–2 J/cm2) and γ-irradiation (0–500 Gy) led to a dose-dependent increase in protein modification. Interestingly, UV-B acted on specific amino acids, such as arginine, proline, and tyrosine, whereas γ-irradiation acted more randomly. The possibility of using the amino acid oxidation pattern as a biomarker of the source of damage is discussed.

Protective effect of antioxidants against sarcoplasmic reticulum (SR) oxidation by Fenton reaction, however without prevention of Ca-pump activity

The Ca(2+)-ATPase of the sarcoplasmic reticulum (SERCA) of rabbit skeletal muscle was oxidized by Fe2+/H2O2/ascorbic acid (AA), a system which generates HO(.) radicals according to the Fenton reaction: (Fe2(+)+H2O2-->HO(.)+OH(-)+Fe(3+)) under conditions similar to the pathological state of inflammation. Under these conditions, when hydroxyl-radicals and/or ferryl-radicals are generated, a 50% decrease of the SERCA activity was observed, a significant decrease of SH groups and an increase of protein carbonyl groups and lipid peroxidation were identified. Two new bands, time dependent in density, appeared in the SERCA protein electrophoresis after incubation with the Fenton system (at approximately 50 and 75kDa), probably due to structural changes as supported also by trypsin digestion. Immunoblotting of DNPH derivatized protein bound carbonyls detected a time dependent increase after incubation of SERCA with the Fenton system. Trolox and the pyridoindole stobadine (50microM) protected SR against oxidation induced via the Fenton system by preventing SH group oxidation and lipid peroxidation. Pycnogenol((R)) and EGb761 (40microg/ml) protected SERCA in addition against protein bound carbonyl formation. In spite of the antioxidant effects, trolox and stobadine were not able to prevent a decrease in the SERCA Ca(2+)-ATPase activity. Pycnogenol and EGb761 even enhanced the decrease of the Ca(2+)-ATPase activity induced by the Fenton system, probably by secondary oxidative reactions.

Postanoxic damage of microglial cells is mediated by xanthine oxidase and cyclooxygenase

Brain ischemia and the following reperfusion are important causes for brain damage and leading causes of brain morbidity and human mortality. Numerous observations exist describing the neuronal damage during ischemia/reperfusion, but the outcome of such conditions towards glial cells still remains to be elucidated. Microglia are resident macrophages in the brain. In this study, we investigated the anoxia/reoxygenation caused damage to a microglial cell line via determination of energy metabolism, free radical production by dichlorofluorescein fluorescence and nitric oxide production by Griess reagent. Consequences of oxidant production were determined by measurements of protein oxidation and lipid peroxidation, as well. By using site-specific antioxidants and inhibitors of various oxidant-producing pathways, we identified major sources of free radical production in the postanoxic microglial cells. The protective influences of these compounds were tested by measurements of cell viability and apoptosis. Although, numerous free radical generating systems may contribute to the postanoxic microglial cell damage, the xanthine oxidase- and the cyclooxygenase-mediated oxidant production seems to be of major importance.

Limited degradation of oxidized calmodulin by proteasome: formation of peptides.

Oxidized proteins are recognized and degraded preferentially by the proteasome. This is true for numerous proteins including calmodulin (CaM). The degradation of CaM was investigated in a human fibroblast cell line under conditions of oxidative stress. Low molecular CaM fragments or peptides were found under such conditions. In in vitro experiments it was investigated whether this CaM breakdown product formation is induced by protein oxidation or is due to a limited proteolysis-derived degradation by the 20S proteasome. Native unoxidized CaM was not degraded by 20S proteasome, oxidized CaM was degraded in a time- and H2O2 concentration-dependent manner. Peptides of similar molecular weight were detected in isolated calmodulin as in oxidatively stressed fibroblasts. The peptides were identified using isolated calmodulin. Therefore, in oxidatively stressed fibroblasts and in vitro CaM is forming oxidation-driven fragments and proteasomal cleavage peptides of approximately 30 amino acids which undergo a slow or no degradation.