纤维二糖脱氢酶抑制酚型化合物聚合及促进木素降解的研究

裂褶菌纤维二糖脱氢酶（ＣＤＨ）可以氧化纤维二糖并还原多种物质,催化的是一双底物双产物反应,符合乒乓反应机制,在电子供体纤维二糖存在下,ＣＤＨ可以还原由豆壳过氧化物酶（ＳＨＰ）氧化多种芳香化合物所生成的产物,ＳＨＰ氧化１－羟基苯丙三唑（１－ｈｙｄｒｏｘｙｂｅｚｏｔｒｉａｚｏｌｅ,ＨＢＴ）生成的产物对ＳＨＰ有失活作用,而在纤维二糖存在下,ＣＤＨ可以还原该氧化产物从而阻止其对酶的失活作用,ＣＤＨ可以抑制     

铜锌超氧物歧化酶对几种羟自由基产生系统的影响

应用脱氧核糖降解法研究了ＣｕＺｎ－ＳＯＤ对几种·ＯＨ产生系统的作用机理．结果证明：ＳＯＤ对Ｆｅ（３＋）·Ｏ·Ｈ２Ｏ２系统中·ＯＨ的产生有明显的抑制作用,而失活ＳＯＤ或ＢＳＡ对它的抑制作用不大;在Ｆｅ（２＋）·Ｈ２Ｏ２和ＣＵ（２＋）·Ｈ２Ｏ２系统中,ＳＯＤ、失活ＳＯＤ和ＢＡＳ均能抑制·ＯＨ的产生;在Ｆｅ（２＋）·Ｏ系统中,ＳＯＤ对·ＯＨ产生作用不大,而失活ＳＯＤ或ＢＳＡ对它有明显的抑制作用．由此推测ＳＯＤ对·ＯＨ形成可能有三方面的影响：１．对Ｏ的清除作用,阻断Ｈａｂｅｒ－Ｗｅｉｓｓ反应;２．对金属离子的络合作用,降低·ＯＨ的产额;３．促进Ｈ２Ｏ２的积累,加快Ｆｅｎｔｏｎ反应．     

金属硫蛋白清除自由基及其对自由基引起的核酸损伤保护作用的研究

通过化学反应体系产生ＯＨ－和Ｏ自由基,采用荧光和化学发光检测体系,比较研究了不同亚型及不同结合金属的金属硫蛋白（ＭＴ）清除自由基能力的大小。结果表明,对于同一亚型,Ｚｎ结合ＭＴ清除自由基的能力大于Ｃｄ结合ＭＴ同一结合金属的ＭＴ,ＭＴ１清除自由基的能力大于ＭＴ２。通过比较ＺｎＭＴ１与谷胱甘肽（ＧＳＨ）及超氧化物歧化酶（ＳＯＤ）清除自由基的能力大小发现,ＺｎＭＴ１清除ＯＨ的能力是ＧＳＨ的１００倍,清除Ｏ自由基的能力分别是ＧＳＨ和ＳＯＤ的２５和０．０１倍。即ＭＴ是一种很好的ＯＨ自由基清除剂。以ＯＨ对核酸（ＤＮＡ）的损伤为例,研究了ＭＴ对核酸损伤的保护作用,其变化规律与上述结果相一致。     

纤维二糖脱氢酶在纤维素降解中的作用研究*

裂褶菌纤维二糖脱氢酶（ｃｅｌｌｏｂｉｏｓｅ ｄｅｈｙｄｒｏｇｅｎａｓｅ, ＣＤＨ）可以提高纤维素酶对纤维素的降解。以纤维二糖为电子供体, ＣＤＨ作用于羧甲基纤维素可降低其溶液的粘度,作用于纤维素 ＣＦ１１和磷酸膨胀纤维素,分别使其悬浊液的浊度提高７％和１４．４％。ＣＤＨ与纤维二糖水解酶或内切纤维素酶在降解棉花纤维素时没有表现出协同作用。但若棉花事先在纤维二糖存在下用ＣＤＨ预处理,则变得易于被水解。     

纤维二糖脱氢酶的纤维素降解中的作用研究

裂褶菌纤维二糖脱氢酶（ｃｅｌｌｏｂｉｏｓｅ ｄｅｈｙｄｒｏｇｅｎａｓｅ,ＣＤＨ）可以提高纤维素酶对纤维素的降解。以纤维二糖为电子供体,ＣＤＨ作用于羧甲基纤维可降低其溶液的粘度,作用纤维素ＣＦ１１和磷酸膨胀纤维素,分别使其悬浊液的浊度提高７％和１４．４％。ＣＤＨ与纤维二糖水解酶或切纤维素酶在降解棉花纤维素时没有表现出协同作用。但若棉花事先在纤维二糖存在下用ＣＤＨ预处理,则变得易于被水解。     

黑曲霉纤维素酶的化学组成

本文测定的黑曲霉纤维素酶各组分均为糖蛋白,但含糖量和组成各不相同,含糖量分别为：β－葡萄糖苷酶１１．３％,内切β－葡聚糖酶１１．８％,β－葡聚糖纤维二糖水解酶ＣＢＨ—１７．２％、ＣＢＨ－Ⅱ５．８％。各酶组分的氨基酸组成有一定的差异,但也有一些共同之处,即都含有较多的酸性氨基酸（Ａｓｐ、Ｇｌｕ）,碱性氨基酸（Ｈｉｓ、Ａｒｇ）含量较低。分析酶组分间的相似性时发现,β－葡聚精纤维二糖水解酶的ＣＢＨ－Ⅰ组分与内切β－葡聚糖酶在各种氨基酸的含量上较为相似,而同属于β－葡聚糖纤维二糖水解酶的两个组分ＣＢＨⅠ和ＣＢＨ—Ⅱ在氨基酸的含量上有一定的差异。     

植物中的多酚物质对超氧物自由基的清除作用

芒果、番石榴、松、龙眼等叶片和绿茶中含有Ｏ２（超氧物自由基）的非酶促清除剂,仅０．５—１ｍｇ鲜重或０．２９ｍｇ茶叶就相当一个ＳＯＤ酶单位作用,热处理不能降低清除Ｏ２的能力．用显示酚类物质的喷洒剂（ＡｇＮＯ３－ＮＨ４ＯＨ）和显示ＳＯＤ同工酶带的ＮＢＴ法对电泳后的凝胶分别染色处理,对比显示结果,表明酚类物质与ＳＯＤ活性物质有相似的电泳行为,叶片中的酚类物质可能为非酶促清除Ｏ２的组份．人工合成的酚类化合物（对硝基酚、间苯二酚、愈创木酚）和从植物中分离的鞣酸等,在体外均能有效地清除Ｏ２．     

金属硫蛋白清除自由基及其对自由基引起的核酸损伤保护作用的研究

通过化学反应体系产生ＯＨ＾－和Ｏ＾－２自由基,采用荧光和化学发光检测体系,比较研究了不同亚型及不同结合金属的金属硫蛋白（ＭＴ）清除自由基能力的大小。结果表明,对于同一亚型,Ｚｎ结合ＭＴ清除自由基的能力大于Ｃｄ结合ＭＴ;同一结合金属的ＭＴ,ＭＴ１清除自由基的能力大于ＭＴ２。通过比较ＺｎＭＴ１与谷胱甘肽（ＧＳＨ）及超氧化物歧化酶（ＳＯＤ）清除自由基的能力大小发现,ＺｎＭＴ１清除ＯＨ的能力是ＧＳＨ的１０     

羟自由基对心肌线粒体膜的影响及硒的效应

由Ｈ２Ｏ２和ＦｅＳＯ４体系产生的羟自由基（ＯＨ·）作用于大鼠心肌线粒体后,其膜脂双层内产生了脂类自由基。在观测时间内,其脂类自由基与自旋捕捉剂形成的自旋加合物的电子自旋共振（ＥＳＲ）信号强度随着孵育时间的延长而加强。一定浓度的硒代蛋氨酸（Ｓｅ—Ｍｅｔ）或Ｎａ２ＳｅＯ３可明显清除ＯＨ·并抑制脂类自由基的产生。在ＯＨ·的影响下,荧光探针ＤＰＨ在心肌线体膜脂中的荧光寿命和膜脂流动性的测试结果发生了明显变化。与此同时,心肌线粒体膜的能量转换过程（氧化磷酸化效率和呼吸控制率）也发生了显著的改变。１．０μｍｏｌ／Ｌ的Ｓｅ—Ｍｅｔ或２．３μｍｏｌ／Ｌ的Ｎａ２ＳｅＯ３可明显拮抗ＯＨ·的上述影响。前者的作用更为显著。     

细胞质雄性不育水稻的呼吸作用和自由基代谢的关系初探

用呼吸电子传递细胞色素途径的抑制剂氰化钾（ＫＣＮ）与抗氰呼吸途径的抑制剂水杨基氧肟酸（ＳＨＡＭ）处理水稻细胞质雄性不育系（ＣＭＳ）珍汕９７Ａ及其保持系珍汕９７Ｂ的幼穗和花药后,ＫＣＮ使不育系与保持系的超氧阴离子自由基（Ｏ２■）产生受到抑制,不育系的Ｏ２■的形成受抑制较多。ＳＨＡＭ处理则增高Ｏ２■形成,以不育系的增加较多．ＫＣＮ与ＳＨＡＭ处理后都使不育系与保持系的丙二醛（ＭＤＡ）含量升高,ＫＣＮ使保持系的ＭＤＡ含量升高较多,ＳＨＡＭ则使不育系的ＭＤＡ含量升高较多．ＫＣＮ处理后,不育系与保持系的超氧物歧化酶（ＳＯＤ）活性下降,ＳＨＡＭ处理后不育系与保持系的ＳＯＤ活性变化不明显。Ｈ２Ｏ２处理对不育系与保持系幼穗的呼吸速率影响不大．Ｈ２Ｏ２＋ＦｅＳＯ４处理后,使呼吸速率大幅度下降,表明Ｈ２Ｏ２＋ＦｅＳＯ４所形成的羟自由基（ＯＨ）比Ｈ２Ｏ２对呼吸代谢的破坏作用更大。     

Purification and Characterization of Cellobiose Dehydrogenases from the White Rot Fungus Trametes versicolor

The white rot fungus Trametes versicolor degrades lignocellulosic material at least in part by oxidizing the lignin via a number of secreted oxidative and peroxidative enzymes. An extracellular reductive enzyme, cellobiose dehydrogenase (CDH), oxidizes cellobiose and reduces insoluble Mn(IV)O(inf2), commonly found as dark deposits in decaying wood, to form Mn(III), a powerful lignin-oxidizing agent. CDH also reduces ortho-quinones and produces sugar acids which can promote manganese peroxidase and therefore ligninolytic activity. To better understand the role of CDH in lignin degradation, proteins exhibiting cellobiose-dependent quinone-reducing activity were isolated and purified from cultures of T. versicolor. Two distinct proteins were isolated; the proteins had apparent molecular weights of 97,000 and 81,000 and isoelectric points of 4.2 and 6.4, respectively. The larger CDH (CDH 4.2) contained both flavin and heme cofactors, whereas the smaller contained only a flavin (CDH 6.4). These CDH enzymes were rapidly reduced by cellobiose and lactose and somewhat more slowly by cellulose and certain cello-oligosaccharides. Both glycoproteins were able to reduce a very wide range of quinones and organic radical species but differed in their ability to reduce metal ion complexes. Temperature and pH optima for CDH 4.2 were affected by the reduced substrate. Although CDH 4.2 showed rather high substrate specificity among the ortho-quinones, it could also rapidly reduce a structurally very diverse collection of other species, from negatively charged triiodide ions to positively charged hexaquo ferric ions. CDH 6.4 showed a higher K(infm) and a lower V(infmax) and turnover number than did CDH 4.2 for all substrates tested. Furthermore, CDH 6.4 did not reduce the transition metals Fe(III), Cu(II), and Mn(III) at concentrations likely to be physiologically relevant, while CDH 4.2 was able to rapidly reduce even very low concentrations of these ions. The reduction of Fe(III) and Cu(II) by CDH 4.2 may be important in sustaining a Fenton's-type reaction, which produces hydroxyl radicals that can cleave both lignin and cellulose. Unlike the CDH proteins from Phanerochaete chrysosporium, CDH 4.2 and CDH 6.4 are unable to produce hydrogen peroxide.     

Is cellobiose dehydrogenase from Phanerochaete chrysosporium a lignin degrading enzyme?

Cellobiose dehydrogenase (CDH) is an extracellular redox enzyme of ping-pong type, i.e. it has separate oxidative and reductive half reactions. Several wood degrading fungi produce CDH, but the biological function of the enzyme is not known with certainty. It can, however, indirectly generate hydroxyl radicals by reducing Fe(3+) to Fe(2+) and O2 to H2O2. Hydroxyl radicals are then generated by a Fenton type reaction and they can react with various wood compounds, including lignin. In this work we study the effect of CDH on a non-phenolic lignin model compound (3,4-dimethoxyphenyl glycol). The results indicate that CDH can affect lignins in three important ways. (1) It breaks beta-ethers; (2) it demethoxylates aromatic structures in lignins; (3) it introduces hydroxyl groups in non-phenolic lignins. The gamma-irradiated model compound gave a similar pattern of products as the CDH treated model compound, when the samples were analyzed by HPLC, suggesting that hydroxyl radicals are the active component of the CDH system.     

Production of Fenton's reagent by cellobiose oxidase from cellulolytic cultures of Phanerochaete chrysosporium.

The reduction of dioxygen by cellobiose oxidase leads to accumulation of H2O2, with either cellobiose or microcrystalline cellulose as electron donor. Cellobiose oxidase will also reduce many Fe(III) complexes, including Fe(III) acetate. Many Fe(II) complexes react with H2O2 to produce hydroxyl radicals or a similarly reactive species in the Fenton reaction as shown: H2O2 + Fe2+----HO. + HO- + Fe3+. The hydroxylation of salicylic acid to 2,3-dihydroxybenzoic acid and 2,5-dihydroxybenzoic acid is a standard test for hydroxyl radicals. Hydroxylation was observed in acetate buffer (pH 4.0), both with Fe(II) plus H2O2 and with cellobiose oxidase plus cellobiose, O2 and Fe(III). The hydroxylation was suppressed by addition of catalase or the absence of iron [Fe(II) or Fe(III) as appropriate]. Another test for hydroxyl radicals is the conversion of deoxyribose to malondialdehyde; this gave positive results under similar conditions. Further experiments used an O2 electrode. Addition of H2O2 to Fe(II) acetate (pH 4.0) or Fe(II) phosphate (pH 2.8) in the absence of enzyme led to a pulse of O2 uptake, as expected from production of hydroxyl radicals as shown: RH+HO.----R. + H2O; R. + O2----RO2.----products. With phosphate (pH 2.8) or 10 mM acetate (pH 4.0), the O2 uptake pulse was increased by Avicel, suggesting that the Avicel was being damaged. Oxygen uptake was monitored for mixtures of Avicel (5 g.1-1), cellobiose oxidase, O2 and Fe(III) (30 microM). An addition of catalase after 20-30 min indicated very little accumulation of H2O2, but caused a 70% inhibition of the O2 uptake rate. This was observed with either phosphate (pH 2.8) or 10 mM acetate (pH 4.0) as buffer, and is further evidence that oxidative damage had been taking place, until the Fenton reaction was suppressed by catalase. A separate binding study established that with 10 mM acetate as buffer, almost all (98%) of the Fe(III) would have been bound to the Avicel. In the presence of Fe(III), cellobiose oxidase could provide a biological method for disrupting the crystalline structure of cellulose.     

The cellobiose-oxidizing enzymes CBQ and CbO as related to lignin and cellulose degradation — a review

Abstract: In this review properties of cellobiose:quinone oxidoreductase (CBQ) and cellobiose oxidase (CbO) are presented and their possible involvement in lignin and cellulose degradation is discussed. Although these enzymes are produced by many different fungi, their importance for wood-degrading fungi is the topic here. CBQ is a FAD enzyme, while CbO also contains a heine group of the cytochrome b type. Protease activity is reported to convert CbO to CBQ. During oxidation of cellobiose (emanating from cellulose) to cellobiono-l,5-lactone, both enzymes reduce quinones produced by laccase and peroxidase during lignin degradation to the corresponding phenols. Many phenoxy and cation radicals are also reduced. Quinone reduction is more rapid than oxygen reduction, although oxygen is slowly reduced to superoxide and/or hydrogen peroxide. Thus, a more appropriate name for CbO is cellobiose dehydrogenase. CbO also reduces Fe(III) and together with hydrogen peroxide produced by the enzyme Fenton's reagent may be formed, resulting in hydroxyl radical production. This radical can degrade both lignin and cellulose, possibly indicating that cellobiose oxidase has a central role in degradation of wood by wood-degrading fungi.     

ESR spin-trapping studies on the reaction of Fe2+ ions with H2O2-reactive species in oxygen toxicity in biology

Using ESR spin-trapping techniques with 5,5-dimethyl-1-pyrroline-N-oxide (DMPO), we confirmed the 1:1 stoichiometry for the formation of hydroxyl radicals with Fe2+ in the Fenton reaction under experimental conditions wherein [H2O2] is 90 microM and [Fe2+] is very low, 1 microM or less. The stoichiometry decreased markedly as the Fe2+ concentration was increased. The efficiency of hydroxyl radical generation varied with the nature of the iron chelators used and increased in the order of phosphate alone approximately ADP less than EDTA less than diethylenetriaminepentaacetic acid (DETAPAC). The second order rate constant for the Fenton reaction was measured to be 2.0 x 10(4) M-1 s-1 for phosphate alone, 8.2 x 10(3) M-1 s-1 for ADP, 1.4 x 10(4) M-1 s-1 for EDTA, and 4.1 x 10(2) M-1 s-1 for DETAPAC. Measuring the radicals formed as spins trapped in the presence of ethanol, we estimated the amount of total oxidizing intermediates formed in the Fenton reaction, which we concluded consists of hydroxyl radicals and an iron species. The oxidizing species of iron which might be assigned as ferryl, FeO2+, or Fe(IV) = O was generated effectively in the presence of ADP even at low Fe2+ concentrations. In general, as the Fe2+ concentration was increased, the ferryl species predominated over the hydroxyl radical except for the case of Fe(II)-DETAPAC, which generated only hydroxyl radicals as the oxidizing species. Three possible pathways are proposed for the Fenton reaction, the dominant ones depending very much on the nature of the iron chelator being used.     

Protective effect of metallothionein to ras DNA damage induced by hydrogen peroxide and ferric ion-nitrilotriacetic acid

Metallothionein (MT) is a strong antioxidant, due to a large number of thiol groups in the MT molecule and MT has been found in the nucleus. To investigate whether MT can directly protect DNA from damage induced by hydroxyl radical, the effects of MTs on DNA strand scission due to incubation with ferric ion-nitrilotriacetic acid and H2O2 (Fe3+ -NTA/H2O2) were studied. The Fe3+-NTA/H2O2 resulted in a higher rate of deoxyribose degradation, compared to incubation of Fe3+/H2O2, presumably mediated by the formation of hydroxyl radicals (*OH). This degradation was inhibited by either Zn-MT or Cd-MT, but not by Zn2+ or Cd2+ at similar concentrations. The Fe3+ -NTA/H2O2 resulted in a concentration dependent of increase in DNA strand scission. Damage to the sugar-phosphodiester chain was predominant over chemical modifications of the base moieties. Incubation with either Zn-MT or Cd-MT inhibited DNA damage by approximately 50%. Preincubation of MT with EDTA and N-ethylmaleimide, to alkylate sulfhydryl groups of MT, resulted in MT that was no longer able to inhibit DNA damage. These results indicates that MT can protect DNA from hydroxyl radical attack and that the cysteine thiol groups of MT may be involved in its nuclear antioxidant properties.     

Homogentisic acid autoxidation and oxygen radical generation: implications for the etiology of alkaptonuric arthritis

The metabolic disorder, alkaptonuria, is distinguished by elevated serum levels of 2,5-dihydroxyphenylacetic acid (homogentisic acid), pigmentation of cartilage and connective tissue and, ultimately, the development of inflammatory arthritis. Oxygen radical generation during homogentisic acid autoxidation was characterized in vitro to assess the likelihood that oxygen radicals act as molecular agents of alkaptonuric arthritis in vivo. For homogentisic acid autoxidized at physiological pH and above, yielding superoxide (O2-)2 and hydrogen peroxide (H2O2), the homogentisic acid autoxidation rate was oxygen dependent, proportional to homogentisic acid concentration, temperature dependent and pH dependent. Formation of the oxidized product, benzoquinoneacetic acid was inhibited by the reducing agents, NADH, reduced glutathione, and ascorbic acid and accelerated by SOD and manganese-pyrophosphate. Manganese stimulated autoxidation was suppressed by diethylenetriaminepentaacetic acid (DTPA). Homogentisic acid autoxidation stimulated a rapid cooxidation of ascorbic acid at pH 7.45. Hydrogen peroxide was among the products of cooxidation. The combination of homogentisic acid and Fe3+-EDTA stimulated hydroxyl radical (OH.) formation estimated by salicylate hydroxylation. Ferric iron was required for the reaction and Fe3+-EDTA was a better catalyst than either free Fe3+ or Fe3+-DTPA. SOD accelerated OH. production by homogentisic acid as did H2O2, and catalase reversed much of the stimulation by SOD. Catalase alone, and the hydroxyl radical scavengers, thiourea and sodium formate, suppressed salicylate hydroxylation. Homogentisic acid and Fe3+-EDTA also stimulated the degradation of hyaluronic acid, the chief viscous element of synovial fluid. Hyaluronic acid depolymerization was time dependent and proportional to the homogentisic acid concentration up to 100 microM. The level of degradation observed was comparable to that obtained with ascorbic acid at equivalent concentrations. The hydroxyl radical was an active intermediate in depolymerization. Thus, catalase and the hydroxyl radical scavengers, thiourea and dimethyl sulfoxide, almost completely suppressed the depolymerization reaction. The ability of homogentisic acid to generate O2-, H2O2 and OH. through autoxidation and the degradation of hyaluronic acid by homogentisic acid-mediated by OH. production suggests that oxygen radicals play a significant role in the etiology of alkaptonuric arthritis.     

Irreversible inactivation of purple acid phosphatase by hydrogen peroxide and ascorbate.

Treatment of the Cu(II)-Fe(III) derivative of pig allantoic fluid acid phosphatase with hydrogen peroxide caused irreversible inactivation of the enzyme and loss of half of the intensity of the visible absorption spectrum. Phosphate, a competitive inhibitor, protected against this inactivation, suggesting that it occurred as a result of a reaction at the active site. The native Fe(II)-Fe(III) enzyme was irreversibly inactivated by H2O2 to a much smaller extent than the Cu(II)-Fe(III) derivative, whereas the Zn(II)-Fe(III) derivative was stable to H2O2 treatment. The rates of inactivation of the Cu(II)-Fe(III) and Fe(II)-Fe(III) enzymes in the presence of H2O2 were increased by addition of ascorbate. These results suggest involvement of a Fenton-type reaction, generating hydroxyl radicals which react with essential active site groups. Experiments carried out on the Fe(II)-Fe(III) enzyme showed that irreversible inactivation by H2O2 in the presence of ascorbate obeyed pseudo first-order kinetics. A plot of kobs for this reaction against H2O2 concentration (at saturating ascorbate) was hyperbolic, giving kobs(max) = 0.41 +/- 0.025 min-1 and S0.5(H2O2) = 1.16 +/- 0.18 mM. A kinetic scheme is presented to describe the irreversible inactivation, involving hydroxyl radical generation by reaction of H2O2 with Fe(II)-Fe(III) enzyme, reduction of the product Fe(III)-Fe(III) enzyme by ascorbate and reaction of hydroxyl radical with an essential group in the enzyme.     

Cellobiose dehydrogenase (cellobiose oxidase) from Phanerochaete chrysosporium as a wood-degrading enzyme. Studies on cellulose,xylan and synthetic lignin

Degradation of carboxymethylcellulose (CMC), xylan and synthetic lignin was studied in a cellobiose dehydrogenase system, that reduced Fe(III) to Fe(II) with cellobiose as electron donor, which in the presence of hydrogen peroxide degraded all the above representatives of the main wood components, probably by forming Fenton's reagent. The production of hydroxyl radicals was shown by benzoate decarboxylation. For the CMC and xylan studies viscometry was used, while lignin degradation was studied by measuring the passage of ¹⁴C-labelled synthetic lignin (DHP) through membranes of different molecular-mass cut-off. The possible participation of cellobiose dehydrogenase, Fe(III) and hydrogen peroxide in wood degradation by white-rot and brown-rot fungi is discussed.     

Leukotriene B4, C4, D4 and E4 inactivation by hydroxyl radicals

Leukotriene B4 chemotactic activity and leukotriene C4, D4 and E4 slow reacting substance activity were rapidly decreased by hydroxyl radicals generated by two different iron-supplemented acetaldehyde-xanthine oxidase systems. At low Fe2+, leukotriene inactivation was inhibited by catalase, superoxide dismutase, mannitol and ethanol, suggesting involvement of hydroxyl radicals generated by the iron-catalyzed interaction of superoxide and H2O2 (Haber-Weiss reaction). Leukotriene inactivation increased at high Fe2+ concentrations, but was no longer inhibitable by superoxide dismutase, suggesting that inactivation resulted from a direct interaction between H2O2 and Fe2+ to form hydroxyl radicals (Fenton reaction). The inactivation of leukotrienes by hydroxyl radicals suggests that oxygen metabolites generated by phagocytes may play a role in modulating leukotriene activity.