Resveratrol is a natural organic compound, polyphenol, produced naturally by some plants in response to several harmful factors such as attack by pathogens, UV radiation, or increased oxidative stress. Many experiments suggest that it triggers mechanisms that counteract aging-related effects and plays a role in insulin resistance as well. It also possesses beneficial properties such as anti-cancer, anti-inflammatory, blood-sugar-lowering and cardiovascular effects. It is supposed to exhibit an interesting activity in neuroprotection -mainly through activation of sirtuins and counteraction in forming peptide aggregates. Still research is needed to evaluate exactly how resveratrol protects neurons, and to develop new, potential, therapeutic drugs.List of abbreviations: Aβ -beta amyloid, ADAM 10 -protein belonging to the family of alpha-secretases, AKT -serine/threonine kinase Akt, AMPK -AMP-dependent kinase, ARE -the antioxidant response element, BDNF -brain derived neurotrophic factor, CaMKKβ -calmodulin-dependent protein kinase kinase β, cAMP -adenosine 3',5'-cyclic monophosphate, COX1 -cyclooxygenase 1, DRP1 -dynamin-related protein, Epac1 -guanine nucleotide exchange factor, F 2α (8-iso-PGF 2α ) -8-iso-prostaglandin F 2α , GSK-3β-β -glycogen synthase kinase 3, HD -Huntington's disease, HSF1 -heat shock factor, HSP-70 -heat shock protein, LDL -low density lipoproteins, MeCP2 -transcriptional protein, MFN1 -mitofusin 1, MFN2 -mitofusin 2, mPGES-1 -microsomal prostaglandin E synthase 1, MPTP-1 -methyl-4-phenyl-1,2,3,6-tetrahydropyridine, MsrA -methionine sulfoxide reductase, NEP -neprilysin, MyoD -myoblast determination protein 1, NF -kB -nuclear transcription factor, Nrf2 -nuclear factor 2, OH -1 -heme oxygenase 1, OPA1 -optic atrophy 1, PD -Parkinson's disease, PDE -phosphodiesterase cyclic nucleotides, PI3K -phosphatidylinositol 3-kinase, PGC-1α -proliferator peroxisome-activated receptor gamma coactivator 1-alpha , PGE 2 -prostaglandin E 2 , RAR -retinoic acid receptor β, RNS -reactive nitrogen species, ROCK -Rho-dependent kinase, ROS -reactive oxygen species, RSV -resveratrol, SIRT1 -sirtuin 1, SIRT3 -sirtuin 3, SOD -superoxide dismutase, TMS -2,3',4,5' tetramethylstilbene, TORC1 -target-of-rapamycin complex 1, YY1 -transcription factor Yin Yang 1 Brought to you by | CAPES Authenticated Download Date | 10/5/15 2:17 PM98 J. GERSZON, A. RODACKA, M. PUCHAŁA
The present study was aimed at investigating the effect of fullerenol C60(OH)36 on chosen parameters of the human erythrocyte membrane and the preliminary estimation of the properties of fullerenol as a potential linking agent transferring the compounds (e.g., anticancer drugs) into the membrane of erythrocytes. The results obtained in this study confirm the impact of fullerenol on erythrocyte cytoskeletal transmembrane proteins, particularly on the band 3 protein. The presence of fullerenol in each of the concentrations used prevented degradation of the band 3 protein. The results show that changes in the morphology of red blood cells caused by high concentrations of fullerenol (up to 150mg/L) did not lead to increased red blood cell hemolysis or the leakage of potassium. Moreover, fullerenol slightly prevented hemolysis and potassium efflux. The protective effect of fullerenol at the concentration of 150mg/L was 20.3%, and similar results were obtained for the efflux of potassium. The study shows that fullerenol slightly changed the morphology of the cells and, therefore, altered the intracellular organization of erythrocytes through the association with cytoskeletal proteins.
The influence of fullerenol on the activities of human erythrocyte membrane ATPases and the fluidity of the plasma membrane as well as the possibility of fullerenol incorporation into the plasma membrane were investigated. Fullerenol at concentrations up to 150 μg/mL induced statistically significant decreases in the anisotropy of 1-anilino-8-naphthalene sulfonate (ANS) (14%), N,N,N-trimethyl-4-(6-phenyl-1,3,5,-hexatrien-1-yl)phenylammonium p-toluenesulfonate (TMA-DPH) (7.5%) and 1,6-diphenyl-1,3,5-hexatriene (DPH) (9.5%) after a 1-hour incubation at 37°C. The effect disappeared for ANS and TMA-DPH, but not for DPH, after washing out the fullerenol. Incubation of erythrocyte membranes with fullerenol led to decreases in the activities of Na(+),K(+)-ATPase (to 23% of the control value), Ca(2+)-ATPase (to 16% of control) and Mg(2+)-ATPase (to 22% of control). Washing out the fullerenol lessened the inhibition of the Na(+),K(+)-ATPase (37% of control) and Ca(2+)-ATPase (23.5% of control); however, it did not influence Mg(2+)-ATPase activity. Furthermore, fullerenol could associate with erythrocyte plasma membranes. Our results suggest that fullerenol associates primarily with the surface of the plasma membrane; however, it can also migrate deeper inside the membrane. Moreover, fullerenol influences membrane ATPases so that it may modulate ion transport across membranes.
Human erythrocytes were exposed to gamma-rays and alpha-particles to assess radiation-induced membrane damage and hemoglobin oxidation and denaturation. With all parameters measured, the alpha-particles proved to be less efficient than the gamma-rays. The time-dependence of hemolysis showed also clear differences: with the gamma-rays the process was faster, reaching saturation after 40-90 min (depending on dose), but with the alpha-particles the final level was attained only after about 3-7 h. Hemoglobin oxidation and denaturation could be measured only after gamma-exposure, but they were negligible with the alpha-particles when comparable doses were applied. These results are interpreted by proposing that OH-radicals, whose yields are smaller with densely ionizing radiation, play a crucial role in the induction of the processes for radiation-induced erythrocyte damage.
Radiolysis of haemoglobin was carried out in phosphate buffer under air, N2 or N2O and with and without ethanol. Radiation products were separated by SDS-PAGE. The loss of subunits and simultaneous aggregation and fragmentation of haemoglobin was measured, if OH-radicals were unscavenged. There was no sensitizing effect of oxygen on the degradation process. Radiation-induced fragmentation was not a random process, but produced specific fragments. The estimated molecular weights of these fragments gave further support to the assumption that the aminoacyl-proline peptide group is the preferential breaking site if OH radicals react with proteins in the presence of oxygen. In contrast with lactate dehydrogenase and bovine serum albumin such fragmentation was observed not only after aerobic radiolysis but also under anaerobic conditions. This difference must be caused by the Feporphyrin system which reacts with H2O2 under release of oxygen. If haemoglobin was irradiated under air the yield of aggregates was much lower than under N2O or N2.
The aim of the study was to examine and compare the effects of methemoglobin (metHb) and ferrylhemoglobin (ferrylHb) on the erythrocyte membrane. Kinetic studies of the decay of ferrylhemoglobin (*HbFe(IV)=O denotes ferryl derivative of hemoglobin present 5 min after initiation of the reaction of metHb with H(2)O(2); ferrylHb) showed that autoredecay of this derivative is slower than its decay in the presence of whole erythrocytes and erythrocyte membranes. It provides evidence for interactions between ferrylHb and the erythrocyte membrane. Both hemoglobin derivatives induced small changes in the structure and function of the erythrocyte membrane which were more pronounced for ferrylHb. The amount of ferrylHb bound to erythrocyte membranes increased with incubation time and, after 2 h, was twice that of membrane-bound metHb. The incubation of erythrocytes with metHb or ferrylHb did not influence osmotic fragility and did not initiate peroxidation of membrane lipids in whole erythrocytes as well as in isolated erythrocyte membranes. Membrane acetylcholinesterase activity increased by about 10% after treatment of whole erythrocytes with both metHb and ferrylHb. ESR spectra of membrane-bound maleimide spin label demonstrated minor changes in the conformation of label-binding proteins in ferrylHb-treated erythrocyte membranes. The fluidity of the membrane surface layer decreased slightly after incubation of erythrocytes and isolated erythrocyte membranes with ferrylHb and metHb. In whole erythrocytes, these changes were not stable and disappeared during longer incubation.
The effectiveness of radiation-generated HO* radicals in initiating erythrocyte hemolysis in the presence of oxygen and under anaerobic conditions and prehemolytic structural changes in the plasma-erythrocyte membrane were studied. Under anaerobic conditions the efficacy of HO* radicals in induction of hemolysis was 16-fold lower than under air. In both conditions, hemolysis was the final consequence of changes of the erythrocyte membrane. Preceding hemolysis, the dominating process under anaerobic conditions was the aggregation of membrane proteins. The aggregates were principally formed by -S-S- bridges. A decrease in spectrin and protein of band 3 content suggests their participation in the formation of the aggregates. These processes were accompanied by changes in protein conformation determined by means of 4-maleimido-2,2,6,6-tetramethylpiperidine-N-oxyl (MSL) spin label attached to membrane proteins. Under anaerobic conditions, in the range of prehemolytical doses, the reaction of HO* with lipids caused a slight (10-16%) increase in fluidity of the lipid bilayer in its hydrophobic region with a lack of lipid peroxidation. However, in the presence of oxygen, hemolysis was preceded by intense lipid peroxidation and by profound changes in the conformation of membrane proteins. At the radiation dose that normally initiates hemolysis a slight aggregation of proteins was observed. Changes were not observed in particular protein fractions. It can be suggested the cross-linking induced by HO* radicals under anaerobic conditions and a lack of lipid peroxidation are the cause of a decrease in erythrocyte sensitivity to hemolysis. Contrary, under aerobic conditions, molecular oxygen suppresses cross-linking, catalysing further steps of protein and lipid oxidation, which accelerate hemolysis.
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