Pulmonary reduction of an intravascular redox polymer

Pulmonary endothelial cells in culture reduce external electron acceptors via transplasma membrane electron transport (TPMET). In studying endothelial TPMET in intact lungs, it is difficult to exclude intracellular reduction and reducing agents released by the lung. Therefore, we evaluated the role of endothelial TPMET in the reduction of a cell-impermeant redox polymer, toluidine blue O polyacrylamide (TBOP(+)), in intact rat lungs. When added to the perfusate recirculating through the lungs, the venous effluent TBOP(+) concentration decreased to an equilibrium level reflecting TBOP(+) reduction and autooxidation of its reduced (TBOPH) form. Adding superoxide dismutase (SOD) to the perfusate increased the equilibrium TBOP(+) concentration. Kinetic analysis indicated that the SOD effect could be attributed to elimination of the superoxide product of TBOPH autooxidation rather than of superoxide released by the lungs, and experiments with lung-conditioned perfusate excluded release of other TBOP(+) reductants in sufficient quantities to cause significant TBOP(+) reduction. Thus the results indicate that TBOP(+) reduction is via TPMET and support the utility of TBOP(+) and the kinetic model for investigating TPMET mechanisms and their adaptations to physiological and pathophysiological stresses in the intact lung.     

N-oxidation of imipramine by isolated perfused rat and rabbit lung

Pulmonary uptake and metabolism of imipramine (IMP) was investigated in isolated perfused rat (IPrL) and rabbit (IPRL) lung preparations. Perfusate containing ¹⁴C-IMP (1.2 μmole/g lung) was recirculated through the pulmonary artery in artificially ventilated lungs. The radioactivity in the perfusate declined rapidly and about 80% of the dose was taken up by the lungs within 10 minutes in both IPrL and IPRL preparations. A steady-state was apparently reached thereafter in the IPRL, while a portion of the radiolabel effluxed into the perfusate of the IPrLs, thus reducing the net lung content to 54% of added IMP by 60 minutes. After 60 minutes perfusion, metabolites of IMP accounted for the major radioactivity (80%) in the perfusate, while the lung contained mainly (83%) the unchanged parent compound. The principal metabolite was identified as IMP-N-oxide (IMP-NO) which was found in the perfusate after 5 minutes of perfusion. Only 3% of the added IMP was metabolized by IPRL in 60 minutes. SKF-525A, an inhibitor of cytochrome P-450-mediated monooxygenase system, did not inhibit but enhanced the metabolism of IMP by IPrL to IMP-NO. IMP was principally metabolized to IMP-NO by incubations of 9,000 g supernatant fractions of rat lungs to a significantly higher extent than similar rabbit lung preparations. Including SKF-525A significantly accelerated the metabolism of IMP to IMP-NO in accordance with the perfusion experiments. These results suggest that in contradiction to publishedd reports, IMP is appreciably metabolized by the rat lung $\text{via}$ N-oxidation by non-cytochrome P-450 pathway and the metabolite formed in the lung is released into the circulation indicating its low affinity for the lung tissue.     

Reduction of cytochrome C by ascorbic free radical.

The rate of "in vivo" reduction of cytochrome c by ascorbic acid (AA) increases from 69 nmoles of cytochrome c for minute, to 202 nanomoles when ascorbate oxidase is added. Since the AA oxidation by AA oxidase is a system to generate ascorbic free radical (AFR), data suggest that AFR is a better reducing compound than ascorbate in cytochrome c reduction. Since the addition of oxidized glutathione and human immunoglobulins (-S-S- bridge containing compounds) in the medium produces a remarkable decrease in cytochrome c reduction, it is suggested that AFR could also reduce -S-S- groups.     

The metabolism of 3-H-cortisone and 3-H-cortisol by the isolated perfused rat and guinea pig lungs.

Isolated perfused rat lungs removed more than 35% of 3-H-cortisone (1 times 10-9M) from the perfusate during one passage through the pulmonary circulation. The cortisone in the lungs was then rapidly converted to cortisol, which was returned to the perfusate. The tritiated steroid taken up was so rapidly washed from the lung, that only 10% remained after a 12 minute perfusion with steroid-free medium. In recirculating experiments, nearly 60% conversion to cortisol occurred over 32 cycles; in addition, there was a slow increase in the percentage of polar compounds in the medium. Similarly, the perfused hindlimbs preparation from the rat converted cortisone to cortisol and returned the cortisol to the perfusate. In contrast, guinea pig isolated perfused lungs had neglible effect on cortisone. Rat lungs demonstrated only a limited ability to convert 3-H-cortisol to cortisone. The results suggest that the lungs may play an important role in maintaining cortisone/cortisol levels in the plasma.     

Relation of the structure and function of ferricytochrome c bound to the phosphoprotein phosvitin

The relationship between the structure and function of ferricytochrome c bound to the phosphoprotein phosvitin was investigated. The rates of reduction of phosvitin-bound ferricytochrome c by cytochrome b2, ascorbate and the superoxide radical generated by xanthine oxidase wer repressed where the binding ratio was less than half the maximum, but at higher ratios they were restored gradually with increase in the ratio. The affinity of cytochrome b2 for cytochrome c was not affected by binding of cytochrome c to phosvitin. The redox potential of the bond form was lower than that of the free form and only decreased with decrease in the ratio. The conformatin around the heme moiety and the electronic structure of the heme group of bound ferricytochrome c were similar to those of free ferricytochrome c, but the conformational stability in the vicinity of the prosthetic group was related to the binding ratio as ratios above half the maximum and was well correlated with the reduction rate. Since the binding of cytochrome c to phosvitin is much stronger at binding ratios below half the maximum, these results suggest that this binding strength exclusively affects the conformational flexibility of the heme crevice in the cytochrome molecule, thus altering the reduction rate.     

The effect of complex formation upon the reduction rates of cytochrome c and cytochrome c peroxidase compound II

The effect of complex formation between ferricytochrome c and cytochrome c peroxidase (Ferrocytochrome-c:hydrogen peroxide oxidoreductase, EC 1.11.1.5) on the reduction of cytochrome c by N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD), reduced N-methylphenazonium methosulfate (PMSH), and ascorbate has been determined at low ionic strength (pH 7) and 25 degrees C. Complex formation with the peroxidase enhances the rate of ferricytochrome c reduction by the neutral reductants TMPD and PMSH. Under all experimental conditions investigated, complex formation with cytochrome c peroxidase inhibits the ascorbate reduction of ferricytochrome c. This inhibition is due to the unfavorable electrostatic interactions between the ascorbate dianion and the negatively charged cytochrome c-cytochrome c peroxidase complex. Corrections for the electrostatic term by extrapolating the data to infinite ionic strength suggest that ascorbate can reduce cytochrome c peroxidase-bound cytochrome c faster than free cytochrome c. Reduction of cytochrome c peroxidase Compound II by dicyanobis(1,10-phenanthroline)iron(II) (Fe(phen)2(CN)2) is essentially unaffected by complex formation between the enzyme and ferricytochrome c at low ionic strength (pH 6) and 25 degrees C. However, reduction of Compound II by the negatively changed tetracyano-(1,10-phenanthroline)iron(II) (Fe(phen)(CN)4) is enhanced in the presence of ferricytochrome c. This enhancement is due to the more favorable electrostatic interactions between the reductant and cytochrome c-cytochrome c peroxidase Compound II complex then for Compound II itself. These studies indicate that complex formation between cytochrome c and cytochrome c peroxidase does not sterically block the electron-transfer pathways from these small nonphysiological reductants to the hemes in these two proteins.     

The mechanism of reduction of single-site redox proteins by ascorbic acid.

The reduction of single-site haem and copper redox proteins by ascorbic acid was studied as a function of pH. Evidence is presented that indicates that the double-deprotonated ascorbate anion, ascorbate2-, is the reducing agent, and the pH-independent second-order rate constants for reduction by this species are given. Investigation of the temperature dependences of these rate constants have yielded the values of the activation parameters (delta H++ and delta S++) for reduction. These values, together with ligand-replacement studies, suggest that ascorbate2- acts as an outer-sphere reductant for these proteins. Reasons to account for the apparent inability of ascorbic acid to reduce the alkaline conformer of mammalian ferricytochrome c are suggested.     

Removal of type 2 Cu from ascorbate oxidase and laccase by reaction with n,n-diethyldithiocarbamate

The type 2 Cu of ascorbate oxidase from zucchini peelings can be rapidly removed by reaction with a tenfold excess N,N-diethyldithiocarbamate (DDC) in air, while other chelating agents, such as EDTA, require anaerobic reducing conditions. The type 2 Cu of laccase from Rhus vernicifera is never removed under aerobic conditions. In anaerobiosis and in the presence of a reducing agent, EDTA is also unable to remove the copper unless a smaller lipophilic molecule (DDC or dimethylglyoxime) is present, acting as a mediator. Type 1 Cu is not involved in the reaction of ascorbate oxidase with DDC, but reduction of type 3 Cu is probably required for type 2 Cu depletion, suggesting interdependence of type 2 and type 3 copper. Type 2 Cu is less exposed in laccase, possibly because of the large carbohydrate content of this protein.     

A quantitative test for superoxide radicals produced in biological systems.

The preparation and properties of a partially succinoylated cytochrome c, suited for the detection of superoxide anion radicals in liver microsomes, is reported. By succinoylation of 45% of the primary amino groups of horse heart cytochrome c the activity towards solubilized NADPH--cytochrome P-450 reductase was diminished by 99% compared with native cytochrome c. The capacities of cytochrome b5 and cytochrome c oxidase to reduce the succinoylated ferricytochrome c and oxidize succinoylated ferrocytochrome c respectively were decreased to a similar extent. However, the bimolecular rate constant for the reduction of the partially succinoylated ferricytochrome c by O2-. was estimated to be one-tenth of the value for the reaction of O2-. with native ferricytochrome c a pH 7.7. On this basis the quantification of O2-. generated by NADPH-supplemented liver microsomes became possible. The initial rates of succinoylated ferricytochrome c reduction determined at various finite concentrations of the cytochrome c derivative can be extrapolated to obtain true rates of O2-. generation in a homogeneous system. The problems encountered in the quantitative determination of O2-. produced in biological membranes, e.g. microsomes, are discussed.     

Pulse-radiolysis studies on the interaction of one-electron reduced species with blue oxidases. Reduction of type-2-copper-depleted ascorbate oxidase.

The interaction of one-electron reduced metronidazole (ArNO2.-) with native and Type-2-copper-depleted ascorbate oxidase were studied in buffered aqueous solution at pH 6.0 and 7.4 by using the technique of pulse radiolysis. With ArNO2.-, reduction of Type 1 copper of the native enzyme and of the Type-2-copper-depleted ascorbate oxidase occurs via a bimolecular step and at the same rate. Whereas the native protein accepts, in the absence of O2, 6-7 reducing equivalents, Type-2-copper-depleted ascorbate oxidase accepts only 3 reducing equivalents with stoichiometric reduction of Type 1 copper. On reaction of O2.- with ascorbate oxidase under conditions of [O2.-] much greater than [ascorbate oxidase], removal of Type 2 copper results in reduction of all the Type 1 copper atoms, in contrast with reduction of the equivalent of only one Type 1 copper atom in the holoprotein. From observations at 610 nm, the rate of reduction of ascorbate oxidase by O2.- is not dependent on the presence of Type 2 copper. For the holoprotein, no significant optical-absorption changes were observed at 330 nm. It is proposed that electrons enter the protein via Type 1 copper in a rate-determining step followed by a fast intramolecular transfer of electrons within the protein. For the Type-2-copper-depleted protein, intramolecular transfer within the protein, however, is slow or does not occur. In the presence of O2, it is also suggested that re-oxidation of the partially reduced holoprotein occurs at steady state, as inferred from the observations at 330 nm and 610 nm. The role of Type 2 copper in ascorbate oxidase is discussed in terms of its involvement in redistribution of electrons within the protein or structural considerations.     

Effects of electron donors on Ca2+-dependent K+ transport in one-step inside-out vesicles from the human erythrocyte membrane

The interactions between reducing agents and Ca2+ in the activation of Ca2+-dependent K+ transport have been studied in one-step inside-out vesicles. The artificial electron donor system ascorbate + phenazine methosulphate increases the apparent sensitivity to Ca2+ by about 5-times over control values (half activation constant, about 5 X 10(-8) M) while oxidized cytochrome c decreases the sensitivity to about 1/3 of the controls. Using redox buffers at a fixed pCa it is shown that the shift from the low to the high-affinity state can be accounted by the reduction of a membrane component accepting two electrons and with an apparent standard redox potential (pH 7.5) of 47 mV. The electrons can be transferred directly from reduced PMS or to oxidized cytochrome c, but not from ascorbate, NADH or reduced glutathione.     

Heparin is not metabolized by the perfused rat liver

The role of the liver in metabolism of heparin was studied using the isolated rat liver perfused in vitro for 10 hr. Porcine intestinal heparin (1000 u) was added to the recirculating liver perfusate, and serial heparin measurements were performed on the liver perfusate every 2 hr, as well as on bile samples secreted by the perfused liver. Heparin concentration remained at a constant level throughout the 10 hr of perfusion, and there was no detectable heparin secreted into bile samples. The findings suggest that hepatic metabolism/clearance plays a minimal role in heparin kinetics in plasma.     

The catalytic effect of the carcinogen "4-nitroquinoline-N-oxide" on the oxidation of vitamin C.

The carcinogen 4-nitroquinoline-N-oxide was found to mediate the reaction between ascorbate and oxygen. The oxidation of ascorbate was initiated by the production of the nitro radical anion which reacted with oxygen to produce the oxygen superoxide radical anion, peroxide and hydroxyl radical. The production of partially reduced oxygen intermediates resulted in additional reactions with ascorbate. The consumption of oxygen could be either completely blocked by reacting the nitro radical with ferricytochrome c or partially blocked by the combined effects of superoxide dismutase and catalase. The consumption of oxygen could be enhanced by reducing the hydroxyl radicals with dimethylsulfoxide.     

Ascorbate- and dehydroascorbic acid-mediated reduction of free radicals in the human erythrocyte

Nitroxides were used as models of persistent free radicals to study the antioxidant function of ascorbic acid in the human erythrocyte. It was concluded that: 1) ascorbate and other reductant(s) derived from dehydroascorbic acid (DHA) in the presence of thiols are the only significant reducing agents for nitroxides, 2) glutathione and DHA reduce nitroxides by a process that cannot be inhibited by ascorbic acid oxidase, 3) erythrocytes can be depleted of ascorbic acid by exhaustive washing in the presence of membrane-permeable cationic nitroxides such as N,N-dimethylamino-Tempo, 4) ascorbate-depleted cells do not reduce nitroxides; however, nitroxide reduction is restored when the cells are incubated with DHA, 5) reduction of nitroxides in ascorbate-depleted, DHA-treated cells is significantly faster than in buffered solutions of DHA and glutathione, 6) several equivalents of nitroxide are reduced relative to the intracellular ascorbate pool, 7) sustained nitroxide reduction is observed even when most of the intracellular ascorbate is oxidized, 8) spin trapping of oxyradicals in tert-butyl hydroperoxide-treated cells is accelerated with ascorbate depletion and inhibited with ascorbate loading, 9) ascorbate can be quantified within intact cells by analyzing the initial reduction rates of membrane-permeable cationic nitroxides, and 10) DHA-stimulated reduction of cationic nitroxides is slower and less extensive in erythrocytes deficient in glucose-6-phosphate dehydrogenase than in normal erythrocytes.     

一种猪模型的体外肺灌注系统的建立

目的:体外肺灌注技术(Ex vivo lung perfusion, EVLP)对于肺移植的实施意义重大,但成本昂贵。本文采用国产经济材料建立猪模型的EVLP系统,以探索保证系统性能的同时降低移植费用。方法:我们首先依据国产材料配置肺灌注液,并组装管道、连接仪器以建立EVLP系统;之后通过外科手段获得3头家猪的肺脏,并灌注肺灌注液,低温保存6小时;最后我们将肺脏连接到EVLP系统,通过血气分析和肺功能检查来评估肺脏随时间变化的状况。结果:离体并在低温保存6小时的猪肺脏,通过我们建立的相对经济的EVLP系统,可以在2小时内维持良好的氧合功能和肺生理指标:肺动脉压、气道峰压、平台压力、肺动脉氧气分压和二氧化碳分压和左心房的氧气分压和二氧化碳分压都保持稳定,同时肺脏具有正常的颜色和弹性,没有明显水肿和功能损害。结论:我们建立的EVLP系统可以有效地维护离体猪肺的生理功能,且降低了成本,从而为肺移植体外肺灌注技术的优化应用提供了研究基础。     

Cytochrome c reduction by cysteine plus copper: a pseudosubstrate system for cytochrome c oxidase

Cysteine alone reduces horse heart cytochrome c very slowly (k approximately or equal too 1.0 M-1s-1) with a rate constant virtually identical in high and low ionic strength buffers. Copper catalyzes this reaction increasing the rate by a factor of 10(5) in 50 mM phosphate and by a factor of 10(6) in 10mM Tris buffers. When ferricytochrome c and cysteine are mixed in an oxygen electrode a "burst" of oxygen uptake is seen, the decline in which parallels the reduction of cytochrome c. When cytochrome oxidase is added to such a mixture two routes of electron transfer to oxygen exist: enzymatic and ferricytochrome c dependent nonenzymatic. Both processes are sensitive to cyanide, but azide inhibits only the authentic cytochrome c oxidase catalyzed process and BCS the ferricytochrome c stimulated reaction.     

The H+/e? stoicheiometry of respiration-linked proton translocation in the cytochrome system of mitochondria

1. The -->H(+)/e(-) quotients for proton release from mitochondria associated with electron flow from succinate and duroquinol to O(2), ferricyanide or ferricytochrome c, and from NNN'N'-tetramethyl-p-phenylenediamine+ascorbate to O(2), were determined from rate measurements of electron flow and proton translocation. 2. Care was taken to avoid, or to take into account, unrelated electron flow and proton translocation, which might take place in addition to the oxido-reductions that were the subject of our analysis. Spectrophotometric techniques were chosen to provide accurate measurement of the rate of consumption of oxidants and reductants. The rate of proton translocation was measured with fast pH meters with a precision of 10(-3) pH unit. 3. The -->H(+)/O quotient for succinate or duroquinol oxidation was, at neutral pH, 4, when computed on the basis of spectrophotometric determinations of the rate of O(2) consumption or duroquinol oxidation. Higher -->H(+)/O quotients for succinate oxidation, obtained from polarographic measurements of O(2) consumption, resulted from underestimation of the respiratory rate. 4. The -->H(+)/2e(-) quotient for electron flow from succinate and duroquinol to ferricyanide or ferricytochrome c ranged from 3.9 to 3.6. 5. Respiration elicited by NNN'N'-tetramethyl-p-phenylenediamine+ascorbate by antimycin-inhibited mitochondria resulted in extra proton release in addition to that produced for oxidation of ascorbate to dehydroascorbate. Accurate spectrophotometric measurement of respiration showed that the -->H(+)/e(-) ratio was only 0.25 and not 0.7-1.0 as obtained with the inadequate polarographic assay of respiration. Proton release was practically suppressed when mitochondria were preincubated aerobically in the absence of antimycin. Furthermore, the rate of scalar proton consumption for water production was lower than that expected from the stoicheiometry. Thus the extra proton release observed during respiration elicited by NNN'N'-tetramethyl-p-phenylenediamine+ascorbate is caused by oxidation of endogenous hydrogenated reductants. 6. It is concluded that (i) the -->H(+)/O quotient for the cytochrome system is, at neutral pH, 4 and not 6 or 8 as reported by others; (ii) all the four protons are released during electron flow from quinol to cytochrome c; (iii) the oxidase transfers electrons from cytochrome c to protons from the matrix aqueous phase and does not pump protons from the matrix to the outer aqueous phase.     

Mixed-valence cytochrome oxidase-formate complex. A steady-state intermediate.

At neutral pH, formate binds to the haem a3 component of cytochrome c oxidase to give a complex that reacts differently from the non-liganded enzyme with reducing agents. Addition of sodium dithionite to the formate complex leads directly to the formation of the fully reduced species, whereas reduction with ascorbate/tetramethylenephenylene-diamine can lead to the production of a mixed-valence species. The stability of this mixed-valence form was studied, and the species appears to represent a 'steady-state' situation that is stable only in the presence of an excess of O2 and reducing equivalents. Characterization of the mixed-valence complex by electron paramagnetic resonance and magnetic circular dichroism reveals the presence of reduced low-spin haem a together with reduced detectable copper and high-spin ferric haem a3.     

Effect of chelating agents and metal ions on the degradation of DNA by bleomycin.

The degradation of DNA by bleomycin was studied in the absence and in the presence of added reducing agents, including 2-mercaptoethanol, dithiothreitol, reduced nicotinamide adenine dinucleotide phosphate, H2O2, and ascorbate, and in the presence of a superoxide anion generating system consisting of xanthine oxidase and hypoxanthine. In all cases, breakage of DNA was inhibited by low concentrations of chelators; where examined in detail, deferoxamine mesylate was considerably more potent than (ethylenedinitrilo)tetraacetic acid. Iron was found to be present in significant quantities in all reaction mixtures. Thus, the pattern of inhibition observed is attributed to the involvement of contaminating iron in the degradation of DNA by bleomycin. Cu(II), Zn(II), and Co(II) inhibit degradation of DNA by bleomycin and Fe(II) in the absence of added reducing agents. A model is proposed in which the degradation of DNA in these systems is dependent on the oxidation of an Fe(II)-bleomycin-DNA complex.     

Metabolism of high density lipoproteins by the perfused rabbit liver

The role of the liver in the catabolism of high density lipoproteins (HDL) was examined in isolated perfused rabbit livers. Using 125I-labeled rabbit HDL the disappearance of labeled apolipoproteins from the perfusate was biphasic with 7% of the label removed after 20 min and a further 6% between 20 and 90 min. In contrast, with HDL labeled with [3H]cholesteryl esters 35% of label had been removed after 90 min. The effect of liver perfusion on HDL size and composition was further studied by recirculating rabbit HDL for 120 min. In control experiments HDL was incubated at 37 degrees C for 120 min with nonperfused media and with media that had been liver perfused. The added HDL was predominantly particles of 4.8-4.9-mm radius, and incubation with nonperfused and preperfused media produced no significant change in size. However, liver perfusion resulted in particles predominantly 4.2-4.3-mm radius. Hepatic perfusion also significantly reduced HDL cholesteryl ester composition as a percentage of lipoproteins mass from 13.3 +/- 2.2% in control incubations to 10.7 +/- 3.1% (p less than 0.001), and cholesteryl ester:protein mass ratio was reduced from 0.31 +/- 0.06 in control to 0.24 +/- 0.10 (p less than 0.001) after 120 min of liver perfusion. Thus interaction of rabbit HDL with rabbit liver results in smaller HDL particles significantly depleted of core cholesteryl esters.