Protection of crystal-induced polymorphonuclear leukocyte membranolysis by phosphocitrate

The protection afforded by phosphocitrate, a phosphorylated polycarboxylic acid, against crystal-induced membrane damage to polymorphonuclear leukocytes was studied in vitro. Membranolysis was assessed by nitro blue tetrazolium salt reduction, lactate dehydrogenase release, and scanning electron microscopy. Phosphocitrate protected strongly against hydroxyapatite crystal-induced damage, an action attributable to crystal surface binding of phosphocitrate rather than to the membrane. The ability of phosphocitrate to prevent hydroxyapatite crystallization, together with its membrane protective effect against preformed crystals, would suggest that the compound might have a useful future role against crystal-induced arthropathies.     

Ferriprotoporphyrin IX and cell lysis: a protective role for hydrogen peroxide

Two potentially lytic substances, ferriprotoporphyrin IX (FP) and hydrogen peroxide, may coexist and partially detoxify each other in sickle cells and in erythrocytes infected with malaria parasites. Since hydrogen peroxide can decompose FP, its effect on hemolysis induced by FP and by the complex of FP with chloroquine was investigated. Human erythrocytes suspended at a concentration of 0.5% in a 50 microM solution of FP underwent approximately 42% hemolysis during the course of 2 hours. Twenty-five micromolar chloroquine potentiated hemolysis to 99%, and preincubation of 50 microM FP with 25 microM hydrogen peroxide for 5 minutes reduced hemolysis to 4%. Mixing either FP or hydrogen peroxide first with chloroquine abolished the effect of hydrogen peroxide. Detoxification of FP by hydrogen peroxide may be an important protective mechanism in certain hemolytic anemias, and inhibition of detoxification could account for the effectiveness of chloroquine in malaria.     

Characterization of acatalasemic erythrocytes treated with low and high dose hydrogen peroxide. Hemolysis and aggregation

The effects of hydrogen peroxide on normal and acatalasemic erythrocytes were examined. Severe hemolysis of acatalasemic erythrocytes and a small tyrosine radical signal (g = 2.005) associated with the formation of ferryl hemoglobin were observed upon the addition of less than 0.25 mM hydrogen peroxide. However, when the concentration of hydrogen peroxide was increased to 0.5 mM, acatalasemic erythrocytes became insoluble in water and increased the tyrosine radical signal. Polymerization of hemoglobin and aggregation of the erythrocytes were observed. On the other hand, normal erythrocytes exhibited only mild hemolysis by the addition of hydrogen peroxide under similar conditions. From these results, the scavenging of hydrogen peroxide by hemoglobin generates the ferryl hemoglobin species (H-Hb-Fe(IV)=O) plus protein-based radicals (*Hb-Fe(IV)=O). These species induce hemolysis of erythrocytes, polymerization of hemoglobin, and aggregation of the acatalasemic erythrocytes. A mechanism for the onset of Takarara disease is proposed.     

Inhibition of monosodium urate monohydrate-mediated hemolysis by vitamin E

Microcrystals of monosodium urate monohydrate(MSUM)induce cytolysis and hemolysis inerythrocytes.In this report,we studied the effect of vitamin E on MSUM-mediated hemolysis in humanerythrocytes.Vitamin E significantly inhibited hemolysis induced by MSUM.The hydroxyl group in thechromanol ring of vitamin E is dispensable for protecting erythrocytes against hemolysis induced by MSUM,indicating that the inhibitory effect of vitamin E is not due to its antioxidant properties.However,both thechromanol ring and the isoprenoid side chain are important for vitamin E to suppress MSUM-induced hemolysis.Our current study suggests that vitamin E inhibits hemolysis induced by MSUM as a membrane stabilizer.     

Glucose-6-phosphate dehydrogenase deficiency: a novel role for thyroxine in peroxide-induced hemolysis

G-6-PD deficient erythrocytes undergo hemolysis during exposure to hydrogen peroxide and thyroxine. Normal erythrocytes do not show this effect unless incubated in the absence of glucose. The inability of G-6-PD deficient cells to detoxify hydrogen peroxide apparently exposes them to the cytotoxic actions of thyroxine. It is suggested that the hemolysis and anemia associated with this genetic disorder is a consequence of the actions of both peroxide and thyroxine on erythrocyte membranes.     

Freeze-fracture and etching studies on membrane damage on human erythrocytes caused by formation of intracellular ice

The present study examined the damaging effect of intracellular ice on plasma membranes of human erythrocytes. Ice crystals of 0.2–2.0 μm in diameter were formed within the cells as the result of rapid freezing of erythrocytes at the cooling rates around 8000 °C/min. Freeze-fracture and etching studies revealed the ultrastructural alterations of membranes caused by the formation of intracellular ice.In the membrane regions which were in direct contact with intracellular ice, depressions resembling “worm-eaten spots” ranging from 400 to 3000 Å in diameter were observed both on the etched protoplasmic fracture faces (PF) and the exoplasmic surfaces (ES); no perforations were detected in the worm-eaten spots as visualized by slight etching, but artificial destructions occurred on these worm-eaten spots following the increase of etching. The most important phenomenon concerning membrane damage was that in the worm-eaten spots the fracture did not occur along the inner hydrophobic plane of membrane.It was suggested that the formation of intracellular ice in direct contact with a membrane brought about molecular disorganization of bilayer membrane. The presence of these altered membrane regions seems to be responsible for the postthawed hemolysis of the intracellularly frozen erythrocytes.     

Fragility of Erythrocytes from Chicks and Rats Fed Dilauryl Succinate and Related Compounds

Susceptibility to hydrogen peroxide of the erythrocytes from chicks and rats fed dilauryl succinate and related compounds with and without supplementation of dl-α-tocopheryl acetate was determined.

Dilauryl succinate, lauryl alcohol, n-decyI alcohol, myristyl alcohol, and lauraldehyde were confirmed to make the erythrocytes from the chicks fragile. Supplemented dl-α-tocopheryl acetate of 200 mg per kg of diet completely prevented the hemolysis induced by these compounds. Dilauryl succinate also makes the rat’s erythrocytes fragile and supplemented dl-α-tocopheryl acetate prevented the hemolysis of the rats, but ethoxyquin was not. The symptoms of encephalomalacia in the chick is preceded by increased hemolysis value of the erythrocytes, and this hemolysis value dropped after the appearance of encephalomalacia.     

High-pressure-induced hemolysis in papain-digested human erythrocytes is suppressed by cross-linking of band 3 via anti-band 3 antibodies

Upon exposure of human erythrocytes to a high pressure of 200 mPa, both hemolysis and vesiculation occur. The hemolysis of erythrocytes at 200 mPa was enhanced by removal of sialic acids from the membrane surface with papain. However, such enhancement was suppressed by cross-linking of band 3 via an anti-band 3 antibody (AB3A), which recognizes the exofacial domain of band 3, or by clustering of band 3 via Zn2+. On the other hand, the size of high-pressure-induced vesicles increased from 423 to 525 nm in diameter upon exposure to papain of erythrocytes, but decreased to 444 nm with following treatment with AB3A. In these vesicles, the content of spectrin relative to band 3 was almost the same. Furthermore, the band 3-cytoskeleton interactions in erythrocyte membranes remained unaltered upon treatment with papain and AB3A. Flow cytometric analysis demonstrated that papain-pretreated erythrocytes mainly produce open ghosts at 200 mPa and that the production of such open ghosts is suppressed by AB3A. Thus, upon removal of negative charges from the membrane surface, open ghosts are readily produced due to the release of larger vesicles under pressure. Upon cross-linking of band 3 via AB3A, however, the release of smaller vesicles at 200 mPa is facilitated so that high-pressure-induced hemolysis is suppressed.     

Acidic amino acid-rich sequences as binding sites of osteonectin to hydroxyapatite crystals

Osteonectin, an acidic noncollagenous protein of bone and dentin, has affinity to hydroxyapatite crystals. Binding sites to hydroxyapatite of this protein were determined by a proteolytic experiment and an in vitro binding experiment using synthetic peptide analogues. Osteonectin was adsorbed on hydroxyapatite crystals and digested with trypsin. A peptide was left adsorbed on the crystal even after the digestion. The peptide was identified as an amino terminal peptide containing glutamic acid-rich sequences, which have been assumed to be possible hydroxyapatite-binding sites. Poly glutamic acid sequences were synthesized as models of the binding sites. Glu₆ peptide was bound to the hydroxyapatite with a dissociation constant of 2.4 μM. Peptides containing fewer glutamic acids had lower affinity to the crystal. Effects of these peptides on in vitro mineralization were examined by a gel system in microtiter plates. The Glu₆ peptide had a positive effect on the mineralization in this system, whereas Asp₆ peptide had a negative effect. These effects indicate the presence of an interaction between these peptides and mineral crystals.     

Aged garlic extract inhibits peroxynitrite-induced hemolysis

Nitric oxide (NO), which is synthesized by constitutive NO synthase (cNOS), plays important roles in physiological functions of the cardiovascular system. However, NO, which is synthesized by inducible NOS, is detrimental when it reacts with superoxide to form peroxynitrite. Peroxynitrite is recognized as a powerful oxidant, and results in vascular or tissue damage. We have previously reported that aged garlic extract (AGE) enhances NO production through cNOS stimulation. In the present study, we determined the effect of AGE, its fractions or constituents on peroxynitrite-induced hemolysis using rat erythrocytes. Incubation of rat erythrocytes with peroxynitrite (300 microM) for 30 min at 37 degrees C caused 4-fold hemolysis. AGE (0.14-0.57 %w/v) added to an erythrocyte suspension was found to reduce peroxynitrite-induced hemolysis in a concentration-dependent manner. Of the AGE fractions, a polar fraction and a low-molecular-weight fraction both suppressed the hemolysis to the same degree as that seen with AGE. S-allylcysteine, one of the major compounds in AGE, also reduced hemolysis at 1-10 mM dose-dependently. These data indicate that AGE and its compounds protect erythrocytes from membrane damage induced by peroxynitrite, suggesting that AGE could be useful for prevention of cardiovascular diseases associated with oxidative stress or dysfunction of NO production.     

Clostridium perfringens alpha-toxin-induced hemolysis of horse erythrocytes is dependent on Ca2+ uptake

Clostridium perfringens alpha-toxin is able to lyse various erythrocytes. Exposure of horse erythrocytes to alpha-toxin simultaneously induced hot-cold hemolysis and stimulated production of diacylglycerol and phosphorylcholine. When A23187-treated erythrocytes were treated with the toxin, these events were dependent on the concentration of extracellular Ca2+ . Incubation with the toxin of BAPTA-AM-treated horse erythrocytes caused no hemolysis or production of phosphorylcholine, but that of the BAPTA-treated erythrocytes did. When Quin 2-AM-treated erythrocytes were incubated with the toxin in the presence of 45Ca2+, the cells accumulated 45Ca2+ in a dose- and a time-dependent manner. These results suggest that the toxin-induced hemolysis and hydrolysis of phosphatidylcholine are closely related to the presence of Ca2+ in the cells. Flunarizine, a T-type Ca2+ channel blocker, and tetrandrine, an L- and T-type Ca2+ channel blocker, inhibited the toxin-induced hemolysis and Ca2+ uptake. However, L-type Ca2+ channel blockers, nifedipine, verpamil and diltiazem, an N-type blocker, omega-conotoxin SVIB, P-type blockers, omega-agatoxin TK and omega-agatoxin IVA, and a Q-type blocker, omega-conotoxin MVII C, had no such inhibitory effect. The observation suggests that Ca2+ taken up through T-type Ca2+ channels activated by the toxin plays an important role in hemolysis induced by the toxin.     

Inhibition of oxidative hemolysis in erythrocytes by mitochondria-targeted antioxidants of SkQ series

In the present work we studied the effect of antioxidants of the SkQ1 family (10-(6′-plastoquinonyl)decyltriphenylphosphonium) on the oxidative hemolysis of erythrocytes induced by a lipophilic free radical initiator 2,2′-azobis(2,4-dimethylvaleronitrile) (AMVN) and a water-soluble free radical initiator 2,2′-azobis(2-methylpropionamidine) dihydrochloride (AAPH). SkQ1 was found to protect erythrocytes from hemolysis, 2 μM being the optimal concentration. Both the oxidized and reduced SkQ1 forms exhibited protective properties. Both forms of SkQ1 also inhibited lipid peroxidation in erythrocytes induced by the lipophilic free radical initiator AMVN as detected by accumulation of malondialdehyde. However, in the case of induction of erythrocyte oxidation by AAPH, the accumulation of malondialdehyde was not inhibited by SkQ1. In the case of AAPH-induced hemolysis, the rhodamine-containing analog SkQR1 exerted a comparable protective effect at the concentration of 0.2 μM. At higher SkQ1 and SkQR1 concentrations, the protective effect was smaller, which was attributed to the ability of these compounds to facilitate hemolysis in the absence of oxidative stress. We found that plastoquinone in the oxidized form of SkQ1 could be reduced by erythrocytes, which apparently accounted for its protective action. Thus, the protective effect of SkQ in erythrocytes, which lack mitochondria, proceeded at concentrations that are two to three orders of magnitude higher than those that were active in isolated mitochondria.     

Lidocaine: An inhibitor in the free‐radical‐induced hemolysis of erythrocytes

Lidocaine was reported to protect erythrocytes from hemolysis induced by 2,2′‐azobis(2‐amidinopropane) dihydrochloride (AAPH). Since AAPH‐induced hemolysis was a convenient in vitro experimental system to mimic erythrocytes undergoing peroxyl radicals attack, the aim of this work was to investigate the antioxidant effect of lidocaine on AAPH‐induced hemolysis by chemical kinetics. As a result, one molecule of lidocaine can only trap 0.37 radical, much lower than melatonin. Meanwhile, lidocaine cannot protect erythrocytes from hemolysis induced by hemin, which the mechanism of hemolysis was due to the erythrocyte membrane destroyed by hemin. Accordingly, lidocaine protected erythrocytes by scavenging radicals preferentially rather than by stabilizing membrane. Moreover, the interactions of lidocaine with two radical species, including 2,2′‐azinobis(3‐ethylbenzothiazoline‐6‐sulfonate) radical cation (ABTS^+?) and 2,2′‐diphenyl‐1‐picrylhydrazyl (DPPH), indicated that lidocaine can reduce ABTS^+? with 260 µM as the 50% inhibition concentration (IC₅₀) and cannot react with DPPH. Thus, lidocaine served as a reductant rather than a hydrogen donor to interact with radicals. Finally, the quantum calculation proved that, compared with the melatonin radical, the stabilization of N‐centered radical of lidocaine was higher than the amide‐type N‐centered radical but lower than the indole‐type N‐centered radical in melatonin. These results provided basic information for lidocaine to be an antiradical drug. © 2009 Wiley Periodicals, Inc. J Biochem Mol Toxicol 23:81–86, 2009; Published online in Wiley InterScience ( www.interscience.wiley.com ). DOI 10.1002/jbt.20267     

Exploring the antibacterial and hemolytic activity of shorter- and longer-chain beta-, alpha,beta-, and gamma-peptides, and of beta-peptides from beta2-3-aza- and beta3-2-methylidene-amino acids bearing proteinogenic side chains--a survey

The antibacterial activities of 31 different beta-, mixed alpha/beta-, and gamma-peptides, as well as of beta-peptides derived from beta2-3-aza- and beta3-2-methylidene-amino acids were assayed against six pathogens (Enterococcus faecalis, Staphylococcus aureus, Streptococcus pneumoniae, Escherichia coli, Klebsiella pneumoniae, and Pseudomonas aeruginosa), and the results were compared with literature data. The interaction of these peptides with mammalian cells, as modeled by measuring the hemolysis of human erythrocytes, was also investigated. In addition to those peptides designed to fold into amphiphilic helical conformations with positive charges on one face of the helix, one new peptide with hemolytic activity was detected within the sample set. Moreover, it was demonstrated that neither cationic peptides used for membrane translocation (beta3-oligoarginines), nor mixed alpha/beta- or gamma-peptides with somatostatin-mimicking activities display unwanted hemolytic activity.     

HEMOLYSIS OF CHICKEN BLOOD

1. The time-dilution curves are given for the hemolytic action of saponin, sodium taurocholate, and sodium oleate on nucleated chicken erythrocytes. 2. Saponin and sodium taurocholate cause hemolysis but leave the nuclei and ghosts in suspension, thereby making the end-point of hemolysis more arbitrary than the clear end-point for non-nucleated cell hemolysis. 3. The curves of hemolysis by saponin and taurocholate are shown to be of the same nature as are found in the hemolysis of non-nucleated cells. 4. Sodium oleate causes first hemolysis and then, in the stronger solutions, causes karyolysis. Two pairs of values for κ and c = ∞ are thus obtainable for the same reaction, one pair for the destruction of corpuscular membrane, the other pair for the destruction of the nucleus. 5. Viscosity changes are found in the lysin-cell system with strong concentrations of sodium taurocholate and sodium oleate. Time-viscosity curves are given for these changes. 6. Microscopically, the action of these lysins on the nucleated chicken red cell appears to be similar to their action on the non-nucleated erythrocytes.     

Bradykinin receptor 2 extends inflammatory cell recruitment in a model of acute gouty arthritis

The aim of this study was determine the effect of bradykinin receptor antagonism on MSU crystal-induced chemokine production and leukocyte recruitment. Mice were injected intraperitoneally with monosodium urate (MSU) crystals ± bradykinin B1- or B2 receptor antagonists, Des-Arg-HOE-140 and HOE-140, respectively. MSU crystal-induced chemokine production and leukocyte recruitment in the peritoneum were measured over 24h and B1 and B2 receptor expression on leukocytes and peritoneal membrane was determined by flow cytometry and fluorescence microscopy. Data analysis showed that only B2 receptor antagonism decreased monocyte and neutrophil infiltration 24 h post MSU crystal administration. Decreased leukocyte infiltration was associated with reduced monocyte (CCL2) chemokine levels. MSU crystal-induced damage to the surrounding visceral membrane was also attenuated in the presence of B2 receptor antagonism. Together, these data show that bradykinin receptor 2 plays a role in maintaining MSU crystal-induced leukocyte infiltration and membrane permeability and identify the B2 receptor as a potential therapeutic target for managing inflammation in gout.     

Hemolysis of rabbit erythrocytes induced by cigarette smoke

Cigarette smoke has been found to induce the hemolysis of rabbit erythrocytes. The particulate phase had more profound effect than the gas phase. Neither free radical scavengers such as ascorbic acid, uric acid and water-soluble vitamin E analogue nor antioxidant enzymes such as catalase and superoxide dismutase suppressed the cigarette smoke-induced hemolysis, suggesting that free radicals, hydrogen peroxide, and superoxide were not the active species.     

Effect of retinol on the hemolysis and lipid peroxidation in vitamin E deficiency

A study on the effect of retinolin vitro on the hemolysis of vitamin E deficient rat red blood cells showed that retinol enhanced the lysis of the E deficient cells as compared to the lysis of normal cells. The lipid peroxidation present during hydrogen peroxide induced lysis of E deficient cells was however markedly inhibited in the presence of retinol without affecting the rate of lysis. In an actively peroxidising system of non-enzymatic lipid peroxidation of rat liver or brain homogenates and of brain lysosomes incubated with human erythrocytes, no lysis was obtained; incorporation of retinol in such systems resulted in lysis but no peroxidation. Hydrogen peroxide generating substances almost completely inhibited the lysis of normal human erythrocytes by retinol, but linoleic acid hydroperoxide and auto-oxidised liver or brain homogenates and ox-brain liposomes increased the lysis. It is concluded that vitamin E deficient erythrocyte hemolysis may be augmented by retinol, an anti-oxidant, having a lytic function without the peroxidation of stromal lipids