The special behavior of equine erythrocytes connected with the methemoglobin regulation

Erythrocytes from thoroughbred horses were submitted to total (80-90%) and partial (25-40%) oxidation of hemoglobin by sodium nitrite. The ability of these cells to reduce methemoglobin to hemoglobin in the presence of either glucose, glucose plus methylene blue or lactate was investigated. The results were compared with those ones obtained for human erythrocytes. Under total oxidation: the horse erythrocytes need longer incubation time with glucose or glucose plus methylene blue than human erythrocytes for reducing the methemoglobin; methylene blue did not enhance methemoglobin reduction in the equine erythrocytes, as occurred in human erythrocytes; for horses, lactate was a more efficient substrate in promoting methemoglobin reduction. The reduction of methemoglobin by equine erythrocytes under partial oxidation was very quick in any of the incubation media. The results can explain the incongruity between the previously reported inability of equine erythrocytes to reduce methemoglobin and the lack of methemoglobinemias in equine veterinary practice.     

Oxidation of iron-nitrosyl-hemoglobin by dehydroascorbic acid releases nitric oxide to form nitrite in human erythrocytes

The reaction of deoxyhemoglobin with nitric oxide (NO) or nitrite ions (NO 2 (-)) produces iron-nitrosyl-hemoglobin (HbNO) in contrast to the reaction with oxyhemoglobin, which produces methemoglobin and nitrate (NO 3 (-)). HbNO has not been associated with the known bioactivities of NO. We hypothesized that HbNO in erythrocytes could be an important source of bioactive NO/nitrite if its oxidation was coupled to the ascorbic acid (ASC) cycle. Studied by absorption and electron paramagnetic resonance (EPR) spectroscopy, DHA oxidized HbNO to methemoglobin and liberated NO from HbNO as determined by chemiluminescence. Both DHA and ascorbate free radical (AFR), the intermediate between ASC and DHA, enhanced NO oxidation to nitrite, but not nitrate; nor did either oxidize nitrite to nitrate. DHA increased the basal levels of nitrite in erythrocytes, while the reactions of nitrite with hemoglobin are slow. In erythrocytes loaded with HbNO, HbNO disappeared after DHA addition, and the AFR signal was detected by EPR. We suggest that the ASC-AFR-DHA cycle may be coupled to that of HbNO-nitrite and provide a mechanism for the endocrine transport of NO via hemoglobin within erythrocytes, resulting in the production of intracellular nitrite. Additionally, intracellular nitrite and nitrate seem to be largely generated by independent pathways within the erythrocyte. These data provide a physiologically robust mechanism for erythrocytic transport of NO bioactivity allowing for hormone-like properties.     

Stoichiometry of the reaction of oxyhemoglobin with nitrite.

During the reaction of oxyhemoglobin (HbO2) with nitrite, the concentration of residual nitrite, nitrate, oxygen, and methemoglobin (Hb+) was determined successively. The results obtained at various pH values indicate the following stoichiometry for the overall reaction: 4HbO2 + 4NO2- 4H+ leads to 4Hb+ + 4NO3- + O2 + 2H2 O (Hb denotes hemoglobin monomer). NO2- binds with methemoglobin noncooperatively with a binding constant of 340 M-1 at pH 7.4 and 25 degrees C. Thus, the major part of Hb+ produced is aquomethemoglobin, not methemoglobin nitrite, when less than 2 equivalents of nitrite is used for the oxidation.     

能量补充对红细胞膜通透性的影响

本文报道利用亚硝酸钠(NaNo_2)穿透红细胞膜与血红蛋白(Hb)作用生成高铁血红蛋白(MetHb),测定MetHb可作为红细胞膜通透性的指标,研究在红细胞悬液中补充葡萄糖,萄葡糖-6-磷酸(G-6-P),3-磷酸甘油(3-PG),ATP后红细胞膜通透性的变化。萄葡糖,G-6-P,ATP均可不同程度地提高通透性,而3-PG有一定的抑制作用,可改善由血卟啉衍生物或γ-线(1000 rad)照射小鼠后引起的红血球通透性增加的作用,使恢复到接近正常水平。     

Erythrocyte alterations in hemoglobin H disease

This study on erythrocytes in hemoglobin H (Hb H) disease reveals that unstable Hb H is bound to membranes to a greater extent, especially when it forms methemoglobin or is precipitated as inclusion body. The methemoglobin content of these erythrocytes is elevated in spite of a higher activity of NADH-methemoglobin reductase. The ATPase activity is doubled, and the ATP is presumably used for phosphorylation of membrane proteins, which leads to cross-linking of membrane proteins. This assumption could be supported by the observed decrease in non-electrolyte permeability, by increased binding of hemoglobin to the membrane and by polymerisation of membrane proteins detected by SDS-polyacrylamide gel electrophoresis. By means of electron microscopy, it could also be shown that the inclusion bodies are bound to the inner surface of membrane and cause its protrusion. This linkage might be responsible for the observed inhibition of the lateral movement of intramembrane particles.     

Transformation of hemoglobin a into methemoglobin by sesamol

Sesamol (3,4-methylenedioxyphenol), a monophenolic antioxidant in sesame iol, produced methemoglobin from hemoglobin A (oxyhemoglobin and deoxyhemoglobin) and from red cells. The activity of the compound was more extensive than the polyphenolic compounds. The profiles of the methemoglobin formation by the compound were compared with those by nitrite and hydroxylamine. The formation of methemoglobin from oxyhemoglobin by the compound was rather slowly progressed, but the amount of methemoglobin formed was proportional to the concentration of oxyhemoglobin even when the concentration of the compound was low. The sesamol-induced methemoglobin formation was influenced by inositol hexaphosphate, an allosteric effector of hemoglobin. Thus, the phosphate enhanced the transformation of oxyhemoglobin and inhibited the transformation of deoxyhemoglobin.     

Nitric oxide formation from the reaction of nitrite with carp and rabbit hemoglobin at intermediate oxygen saturations

The nitrite reductase activity of deoxyhemoglobin has received much recent interest because the nitric oxide produced in this reaction may participate in blood flow regulation during hypoxia. The present study used spectral deconvolution to characterize the reaction of nitrite with carp and rabbit hemoglobin at different constant oxygen tensions that generate the full range of physiological relevant oxygen saturations. Carp is a hypoxia-tolerant species with very high hemoglobin oxygen affinity, and the high R-state character and low redox potential of the hemoglobin is hypothesized to promote NO generation from nitrite. The reaction of nitrite with deoxyhemoglobin leads to a 1 : 1 formation of nitrosylhemoglobin and methemoglobin in both species. At intermediate oxygen saturations, the reaction with deoxyhemoglobin is clearly favored over that with oxyhemoglobin, and the oxyhemoglobin reaction and its autocatalysis are inhibited by nitrosylhemoglobin from the deoxyhemoglobin reaction. The production of NO and nitrosylhemoglobin is faster and higher in carp hemoglobin with high O(2) affinity than in rabbit hemoglobin with lower O(2) affinity, and it correlates inversely with oxygen saturation. In carp, NO formation remains substantial even at high oxygen saturations. When oxygen affinity is decreased by T-state stabilization of carp hemoglobin with ATP, the reaction rates decrease and NO production is lowered, but the deoxyhemoglobin reaction continues to dominate. The data show that the reaction of nitrite with hemoglobin is dynamically influenced by oxygen affinity and the allosteric equilibrium between the T and R states, and that a high O(2) affinity increases the nitrite reductase capability of hemoglobin.     

The effect of antioxidants on in vivo and in vitro methemoglobin formation in erythrocytes of patients with Parkinson’s disease

Methemoglobin formation was examined in erythrocytes of 16 patients with Parkinson’s disease (PD) (stage 3–4 by the Hoehn and Yahr scale). The patients receiving levodopa-containing drugs (madopar, nakom) were also treated with intramuscular injections of mexidol (daily dose 100 mg/day) for 14 days. Control group included 12 clinically healthy persons. The erythrocyte methemoglobin content was determined by electronic paramagnetic resonance (EPR) using the EPR signal intensity with the g-factor 6.0. The methemoglobin content was significantly higher in erythrocytes of PD patients than in healthy donors. The complex therapy with mexidol normalized the methemoglobin content in erythrocytes of PD patients. Incubation in vitro of erythrocytes of donors and PD patients with acrolein increased the methemoglobin content, while incubation with carnosine normalized the methemoglobin content in erythrocytes of PD patients. Prophylactic (i.e. before acrolein addition) and therapeutic administration of carnosine to the incubation system with acrolein decreased the methemoglobin content to its initial level. Results of this study suggest that inclusion of the antioxidants mexidol and carnosine in the scheme of basic therapy of PD may reduce side effects associated with methemoglobinemia.     

The kinetic differences between sodium nitrite, amyl nitrite and nitroglycerin oxidation of hemoglobin

The effect of sodium nitrite, amyl nitrite and nitroglycerin (glyceryl trinitrate) on the hemoglobin of adult erythrocytes was examined in vitro. Both amyl nitrite and nitroglycerin reacted immediately with oxyhemoglobin to effect oxidation into methemoglobin while sodium nitrite required an inductionary period (lag phase) prior to the reaction. Kinetic studies of the biomolecular rate law for each of the preceding reaction's reactionary periods (log phases) allowed rate constant calculations to be made. The values are 1.14 x 10(4) M-1 min-1, 7.45 x 10(4) M-1 min-1, and 3.50 x 10(1) M-1 min-1 for sodium nitrite, amyl nitrite and nitroglycerin, respectively. A comparison of the amyl nitrite and nitroglycerin rate constants reveals that amyl nitrite is approximately 2000-fold more toxic to oxyhemoglobin than nitroglycerin. These oxidant's effect on in vitro hemoglobin solutions are comparable since both reactions approximate to rectangular hyperbolae. Sodium nitrite reacts about 300-fold faster with oxyhemoglobin than does nitroglycerin. However, the sodium nitrite reaction proceeds in a sigmoidal fashion which makes a strict comparison between these compounds relative toxicities less clear cut.     

Proteolysis in human erythrocytes is triggered only by selected oxidative stressing agents

Human erythrocytes have been treated with different agents producing oxidative stress. Diamide, tetrathionate, chromate, cystamine and iodate preferentially influenced the cellular redox state by oxidation of free and protein thiol groups leaving the redox state of hemoglobin virtually unaffected. None of these compounds was able to stimulate the proteolysis. By contrast, phenylhydrazine, nitrite, hydrogen peroxide, ter-butylhydroperoxide, cumene hydroperoxide and copper-ascorbate caused a noticeable oxidation of hemoglobin to methemoglobin. These latter agents, except nitrite and copper-ascorbate, triggered proteolysis. Identical results have been obtained in a ghost-free hemolysate. The fraction containing the proteolytic activity was isolated from hemolysate and tested on native or oxidant-treated hemoglobin. The proteolysis was stimulated by all agents able to produce methemoglobin. It is concluded that proteolysis correlated to an unbalance of cellular redox state. The results obtained with isolated and recombined fractions suggests that increased proteolysis does not depend on the removal of the effect of protease(s) inhibitor(s). Since all agents stimulating proteolysis are able to generate free radicals, it seems that protein breakdown is triggered by the direct effect of these intermediates on proteins (mostly hemoglobin) without the involvement of radical species produced in the membranes by action of organic hydroperoxides. In addition, since nitrite and copper-ascorbate, which also oxidize hemoglobin by radical generation, are unable to stimulate proteolysis, it should be concluded that protein degradation induced by oxidative stress is a complex event induced only by specific agents.     

Nitrite-induced methemoglobinemia in Nile tilapia, Oreochromis niloticus

Exposure of Nile tilapia, Oreochromis niloticus (mean weight, 55.72 ± 4.30 g), to two sublethal NO₂–N concentrations was studied for 24 and 48 h in a static test. In nitrite exposure tests, the percentages of methemoglobin, external nitrite, plasma nitrite, hemoglobin and hematocrit were assessed. Nitrite exposure in the range of 0.50 and 1.38 mg l⁻¹ NO₂–N caused an increase in methemoglobin levels; however, methemoglobin percentages ranging from 16% to 42% represented a mild methemoglobinemia. Levels of methemoglobin were unrelated to environmental and plasmatic nitrite concentrations. The nitrite concentration in the blood did not seem to be linked to time of exposure. Nitrite exposure in Nile tilapia was associated with a marked reduction in hemoglobin and hematocrit.     

Adaptation of rats following sodium-nitrite-induced methemoglobinemia]

Adaptation of rats following sodium nitrite induced methemoglobinemia. The effect of repeated intraperitoneal injections of sodium nitrite on methemoglobin, hemoglobin and blood sugar level, on leucine aminopeptidase activity in plasma and methemoglobin reductase activity in red blood cells was investigated in rats. Repeated methemoglobinemia produced gradual disappearance of hyperglycemia, changes of hemoglobin content in blood and increase of methemoglobin reductase activity in red blood cells.     

Nitrite uptake and metabolism and oxidant stress in human erythrocytes

Nitric oxide, when released into the bloodstream, is quicklyscavenged by Hb in erythrocytes or oxidized to nitrite. Nitrite canalso enter erythrocytes and oxidize Hb. The goals of this work were todetermine the mechanism of erythrocyte nitrite uptake and whether thisuptake causes oxidant stress in these cells. Erythrocytes took up 0.8 mM nitrite with a half-time of 11 min. Nitrite uptake was sensitive totemperature and to the pH and ionic composition of the medium but wasnot inhibited by the specific anion-exchange inhibitor DIDS. About 25%of nitrite uptake occurred on the sodium-dependent phosphatetransporter and the rest as diffusion of nitrous acid or other speciesacross the plasma membrane. Methemoglobin formation increased inproportion to the intracellular nitrite concentration. Nitritereacted with erythrocyte ascorbate, but ascorbate loading of cellsdecreased nitrite-induced methemoglobin formation only at high nitriteconcentrations. In conclusion, nitrite rapidly enters erythrocytes andreacts with oxyhemoglobin but does not exert a strong oxidant stress onthese cells.

     

Studies on the influence of nitrite on methemoglobin formation in Amazonian fishes

Twenty one species of fishes, collected from the Rio Solim?es and a tributary lake in the Amazon Basin near Manaus, showed a wide range of methemoglobin formation 1 hr after a dose of 30 mg/kg of sodium nitrite i.p. Methemoglobin formation in two experimental fishes, Brycon cf. melanopterum and Semaprochilodus insignis, maintained in tanks in our INPA laboratory, was studied in detail. Both fishes survived a dose of 10 mg/kg of nitrite i.p. but usually died within 3 hr of a dose of 30 mg/kg with levels of blood methemoglobin in excess of 80%. Methemoglobin produced in vitro by addition of nitrite to fresh blood was slowly reduced back to hemoglobin over a period of several hours at room temperature. Hemoglobin in hemolysates was auto-oxidized to methemoglobin at pH 6.1 and below but not at 6.9 and above.     

Low NO concentration dependence of reductive nitrosylation reaction of hemoglobin

The reductive nitrosylation of ferric (met)hemoglobin is of considerable interest and remains incompletely explained. We have previously observed that at low NO concentrations the reaction with tetrameric hemoglobin occurs with an observed rate constant that is at least 5 times faster than that observed at higher concentrations. This was ascribed to a faster reaction of NO with a methemoglobin-nitrite complex. We now report detailed studies of this reaction of low NO with methemoglobin. Nitric oxide paradoxically reacts with ferric hemoglobin with faster observed rate constants at the lower NO concentration in a manner that is not affected by changes in nitrite concentration, suggesting that it is not a competition between NO and nitrite, as we previously hypothesized. By evaluation of the fast reaction in the presence of allosteric effectors and isolated β- and α-chains of hemoglobin, it appears that NO reacts with a subpopulation of β-subunit ferric hemes whose population is influenced by quaternary state, redox potential, and hemoglobin dimerization. To further characterize the role of nitrite, we developed a system that oxidizes nitrite to nitrate to eliminate nitrite contamination. Removal of nitrite does not alter reaction kinetics, but modulates reaction products, with a decrease in the formation of S-nitrosothiols. These results are consistent with the formation of NO(2)/N(2)O(3) in the presence of nitrite. The observed fast reductive nitrosylation observed at low NO concentrations may function to preserve NO bioactivity via primary oxidation of NO to form nitrite or in the presence of nitrite to form N(2)O(3) and S-nitrosothiols.     

Hemoglobin conversion to hemichrome under the influence of fatty acids

The effect of free fatty acids on the process of hemoglobin conversion and lipid peroxidation has been studied in model systems and erythrocytes. It has been found that methemoglobin and oxyhemoglobin are converted to the low spin oxidized form, namely, reversible hemichrome under the action of fatty acids. In the case of oxyhemoglobin, an increase in the level of active oxygen forms is observed in the system which initiates the formation of primary and secondary lipid peroxidation products. Incubation of erythrocytes with free fatty acids causes the formation of Heinz bodies and is accompanied by an increase of the lipid peroxidation level.     

Prooxidative effects of TEMPO on human erythrocytes

The prooxidative effects of 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO) were observed in human erythrocytes. Incubation of red blood cells with the membrane-permeable TEMPO leads to a decrease in the concentration of intracellular reduced glutathione, accompanied by the reduction of TEMPO. Extracellular ferricyanide inhibited the loss of glutathione and reduction of TEMPO. TEMPO induced glutathione release from the cells and oxidation of hemoglobin to methemoglobin; ferricyanide prevented these effects. These results indicate that TEMPO may act as an oxidant to erythrocytes, whilst extracellular ferricyanide protects against its effects.     

The basis for EDTA-stimulation of methemoglobin reduction in hemolysates of human erythrocytes.

We have studied the stimulation by EDTA of methemoglobin reduction in hemolysates of human erythrocytes. The EDTA effect has been shown not to be the result of an allosteric interaction of EDTA with hemoglobin or the result of a photochemical reduction. The effect does not appear to be due to a direct interaction of free EDTA with either of the catalytic components of the erythrocyte methemoglobin reduction system. The EDTA stimulation seen in hemolysates is due to the formation of an iron-EDTA complex, which transfers electrons from the reductase to methemoglobin.     

Methemoglobin reductase activity and in vitro sensitivity towards oxidant induced methemoglobinemia in Swiss mice and Beagle dogs erythrocytes

The NADH methemoglobin-reductase (EC 1.6.2.2) is mainly responsible for the maintenance of hemoglobin in its reduced and active state. The present study reveals the comparative status of this enzyme in normal Beagle dogs, rats, mice, mastomys and hamsters erythrocytes. The spectrophotometric and electrophoretic determinations showed that the above mentioned enzyme was deficient in the Beagle dog's erythrocytes. Furthermore, in vitro studies on the sensitivity of these rodents and Beagle dogs hemolysate towards oxidants, like primaquine and sodium nitrate, depicted a higher level of methemoglobin formation in the Beagle dogs hemolysate as compared to that of the rodent species. The deficiency of methemoglobin reductase in Beagle dogs erythrocytes could be responsible for their increased sensitivity towards oxidant induced methemoglobinemia.     

Copper-specific damage in human erythrocytes exposed to oxidative stress

Ascorbate and complexes of Cu(II) and Fe(III) are capable of generating significant levels of oxygen free radicals. Exposure of erythrocytes to such oxidative stress leads to increased levels of methemoglobin and extensive changes in cell morphology. Cu(II) per mole is much more effective than Fe(III). However, isolated hemoglobin is oxidized more rapidly and completely by Fe(III)- than by Cu(II)-complexes. Both Fe(III) and Cu(II) are capable of inhibiting a number of the key enzymes of erythrocyte metabolism. The mechanism for the enhanced activity of Cu(II) has not been previously established. Using intact erythrocytes and hemolysates we demonstrate that Cu(II)-, but not Fe(III)-complexes in the presence of ascorbate block NADH-methemoglobin reductase. Complexes of Cu(II) alone are not inhibitory. The relative inability of Fe(III)-complexes and ascorbate to cause methemoglobin accumulation is not owing to Fe(III) association with the membrane, or its failure to enter the erythrocytes. The toxicity of Cu(II) and ascorbate appears to be a result of site-specific oxidative damage of erythrocyte NADH-methemoglobin reductase and the enzyme's subsequent inability to reduce the oxidized hemoglobin.