锰超氧化物歧化酶对神经系统作用的研究综述

锰超氧化物歧化酶（SOD2）是线粒体基质酶,作为细胞内氧自由基的清除剂,SOD2与氧化应激相关的神经系统疾病密切相关。本文从SOD2的一般生物学特性、在神经系统中的作用以及在临床上的应用等方面对其近期的研究成果和未来发展趋势进行了综述。     

植物超氧化物歧化酶（SOD）的研究进展

超氧化物歧化酶(superoxide dismutase,SOD)在需氧原核生物和真核生物中广泛存在,是活性氧清除系统中第一个发挥作用的抗氧化酶。植物正常代谢过程和在各种环境胁迫下均能产生活性氧和自由基,活性氧和自由基的积累引起细胞结构和功能的破坏。SOD岐化超氧物阴离子自由基生成过氧化氢和分子氧,在保护细胞免受氧化损伤过程中具有十分重要的作用。本文综述了SOD的功能、在细胞中的分布、表达调控和与植物抗逆性的关系。 Abstract:Superoxide Dismutases (SODs) are ubiquitously expressed antioxidant enzyme in aerobic organisms and catalyze dismutation of superoxide anion to hydrogen and molecular oxygen,the first step in active oxygen-scavenging systems.SODs play a central role in protecting cells against the toxic effects of reactive oxygen species generated during normal cellular metabolic activity or as a result of various environmental stresses.This paper reviews the expression and regulation of Sod genes and their functional role(s) during development and in response to stresses.     

鸭血超氧化物歧化酶(SOD)的纯化及性质研究

超氧化物歧化酶(E、C、1.15.1.1)是催化超氧阴离子起歧化反应的金属酶类,血红细胞中的SOD属Cu Zn—SOD。本文详细报道了从鸭血分离纯化SOD的改进方法(同时用猪血作对比研究)。设计了热变性、(NH_4)_2SO_4分级监析、低浓乙醇—氯仿短时去除残留血红蛋白、凝胶层析四步纯化方案,获得高产率电泳纯SOD。用紫外扫描,PAGE电泳后考马斯亮蓝和SOD活性杂色,SDS—电泳,HPLC分离和各电泳带组分的N—端测定等技术检测纯度,并进行性质研究。证明所得SOD是均一的;N—端为Ala;分子量和亚分子量各为32,359和16,500dt;并与猪血SOD对比研究其某些性质;对HPLC出现的多个活力峰及PAGE电泳显现的多条活性带进行了讨论。     

Characterization of an Atypical Superoxide Dismutase from Sinorhizobium meliloti

Sinorhizobium meliloti Rm5000 is an aerobic bacterium that can live free in the soil or in symbiosis with the roots of leguminous plants. A single detectable superoxide dismutase (SOD) was found in free-living growth conditions. The corresponding gene was isolated from a genomic library by using a sod fragment amplified by PCR from degenerate primers as a probe. The sodA gene was located in the chromosome. It is transcribed monocistronically and encodes a 200-amino-acid protein with a theoretical M(r) of 22,430 and pI of 5. 8. S. meliloti SOD complemented a deficient E. coli mutant, restoring aerobic growth of a sodA sodB recA strain, when the gene was expressed from the synthetic tac promoter but not from its own promoter. Amino acid sequence alignment showed great similarity with Fe-containing SODs (FeSODs), but the enzyme was not inactivated by H(2)O(2). The native enzyme was purified and found to be a dimeric protein, with a specific activity of 4,000 U/mg. Despite its Fe-type sequence, atomic absorption spectroscopy showed manganese to be the cofactor (0.75 mol of manganese and 0.24 mol of iron per mol of monomer). The apoenzyme was prepared from crude extracts of S. meliloti. Activity was restored by dialysis against either MnCl(2) or Fe(NH(4))(2)(SO(4))(2), demonstrating the cambialistic nature of the S. meliloti SOD. The recovered activity with manganese was sevenfold higher than with iron. Both reconstituted enzymes were resistant to H(2)O(2). Sequence comparison with 70 FeSODs and MnSODs indicates that S. meliloti SOD contains several atypical residues at specific sites that might account for the activation by manganese and resistance to H(2)O(2) of this unusual Fe-type SOD.     

The Interaction of Mitochondrial Iron with Manganese Superoxide Dismutase

Superoxide dismutase 2 (SOD2) is one of the rare mitochondrial enzymes evolved to use manganese as a cofactor over the more abundant element iron. Although mitochondrial iron does not normally bind SOD2, iron will misincorporate into Saccharomyces cerevisiae Sod2p when cells are starved for manganese or when mitochondrial iron homeostasis is disrupted by mutations in yeast grx5, ssq1, and mtm1. We report here that such changes in mitochondrial manganese and iron similarly affect cofactor selection in a heterologously expressed Escherichia coli Mn-SOD, but not a highly homologous Fe-SOD. By x-ray absorption near edge structure and extended x-ray absorption fine structure analyses of isolated mitochondria, we find that misincorporation of iron into yeast Sod2p does not correlate with significant changes in the average oxidation state or coordination chemistry of bulk mitochondrial iron. Instead, small changes in mitochondrial iron are likely to promote iron-SOD2 interactions. Iron binds Sod2p in yeast mutants blocking late stages of iron-sulfur cluster biogenesis (grx5, ssq1, and atm1), but not in mutants defective in the upstream Isu proteins that serve as scaffolds for iron-sulfur biosynthesis. In fact, we observed a requirement for the Isu proteins in iron inactivation of yeast Sod2p. Sod2p activity was restored in mtm1 and grx5 mutants by depleting cells of Isu proteins or using a dominant negative Isu1p predicted to stabilize iron binding to Isu1p. In all cases where disruptions in iron homeostasis inactivated Sod2p, we observed an increase in mitochondrial Isu proteins. These studies indicate that the Isu proteins and the iron-sulfur pathway can donate iron to Sod2p.Metal-containing enzymes are generally quite specific for their cognate cofactor. Misincorporation of the wrong metal ion can be deleterious and tends to be a rare occurrence in biology. A prime example of metal ion selectivity is illustrated by the family of manganese- and iron-containing superoxide dismutases (SODs)³. This large family of enzymes utilizes either manganese or iron as cofactors to scavenge superoxide anion. The iron- and manganese-containing forms are highly homologous to one another at primary, secondary, and tertiary levels and have virtually identical metal binding and catalytic sites (1–3). Despite this extensive homology, Mn- and Fe-SODs are only active with their cognate metal. Misincorporation of iron into Mn-SOD or vice versa alters the redox potential of the enzyme''s active site and prohibits superoxide disproportionation (4, 5). Nevertheless, misincorporation of iron into Mn-SOD does occur in vivo (6, 7). The isolated Mn-SOD from Escherichia coli is found as a mixture of manganese- and iron-bound forms (7); binding of manganese is favored under oxidative stress, whereas iron binding is increased under anaerobic conditions (3, 8). It has been proposed that changes in bioavailability of manganese versus iron determine the metal selectivity of Mn-SOD in bacterial cells (3, 8). But is this also true for Fe-SOD? Currently, there is no documentation of manganese misincorporation into Fe-SOD in vivo.Unlike bacteria that co-express Mn- and Fe-SOD molecules in the same cell, eukaryotic mitochondria generally harbor only one member of the Fe/Mn-SOD family, a tetrameric Mn-SOD typically known as SOD2 (9). In some organisms, SOD2 is essential for survival (10–12), and mitochondria have therefore evolved to prevent iron-SOD2 interactions despite high levels of mitochondrial iron relative to manganese. Using a yeast model system, we have shown previously that metal ion mis-incorporation can occur with Saccharomyces cerevisiae Sod2p (7). Specifically, iron binds and inactivates yeast Sod2p when cells are either starved for manganese or have certain disruptions in mitochondrial iron homeostasis. These disruptions include mutations in MTM1, a mitochondrial carrier protein that functions in iron metabolism (7, 13), and mutations in GRX5 or SSQ1, involved in iron-sulfur biogenesis (14). We proposed that these disruptions lead to expansion of a mitochondrial pool of so-called SOD2-reactive iron (7). Currently, it is unknown whether SOD2-reactive iron represents a major shift in the chemistry of bulk mitochondrial iron or whether it is just a small pool of the metal emerging from one or more specific sites.The grx5 and ssq1 mutants that promote iron-SOD2 interactions encode just two of many components of a complex pathway for iron-sulfur biogenesis (15, 16). One of the key components is a well conserved iron-sulfur scaffold protein originally described for bacteria as IscU, also known as mammalian ISCU and S. cerevisiae Isu1p and Isu2p, referred collectively herein as “Isu proteins” (17–22). The iron-sulfur clusters on Isu proteins are labile and can be transferred to target iron-sulfur proteins through the aid of mitochondrial factors including Grx5p and Ssq1p (15, 16). It is not clear whether disruption of the iron-sulfur pathway per se is sufficient to promote iron interactions with yeast Sod2p or whether this effect is specific to grx5, ssq1, and mtm1 mutants.In the current study, we explore the nature of mitochondrial iron that can interact with Sod2p. We find that the changes in mitochondrial metal homeostasis that shift metal binding in yeast Sod2p likewise alter metal cofactor selection in a heterologously expressed Mn-SOD, but not in a Fe-SOD molecule. Through x-ray absorption near edge structure (XANES) and extended x-ray absorption fine structure (EXAFS) analyses of mitochondrial iron, we detected no major change in bulk mitochondrial iron under conditions that promote iron-SOD2 interactions. SOD2-reactive iron appears to represent a small pool of the metal, and we provide evidence that the iron-sulfur scaffold Isu1p can act as an important source of this reactive iron.     

Determination of Manganese Superoxide Dismutase Activity By Direct Spectrophotometry

A method to determine Mn-superoxide dismutase activity by measuring directly the rate of decay of O₂^- in a spectrophotometer, is described. Decay of O₂^- generated by KO₂ at pH 9.5, was monitored as the fall in absorbance (A_250nm-A_360nm). Mn-superoxide dismutase was determined as the activity of cyanide-resistant superoxide dismutase, calculated from the rate of O₂^- dismutation. Mn-superoxide dismutase could be determined in the presence of a 700 times higher Cu, Zn-superoxide dismutase activity. The alkaline pH did not cause analytical problems. The assay was used to measure both Mn- and Cu, Zn-superoxide dismutase activity in mitochondrial preparations. The assay had a detection limit of 2.8 ng/ml when Mn-superoxide dismutase from E. coli was used, and the between-day CV was 5.8%. The assay is an alternative to indirect methods for detecting superoxide dismutase activity.     

Characterization of a lectin-binding storage protein from pea (Pisum sativum)

From the storage proteins of the pea (Pisum sativum), the fraction which interacts with the pea lectin by the sugar-binding site was studied. By electrophoretical subunit patterns and other criteria, this fraction resembles the group of the 7S storage proteins (vicilins). The fraction was resolved into subunits by micropreparative SDS PAGE. The N-terminal sequences of the individual subunits were determined. Most of these are identical with published vivilin subunit sequences; therefore this lectin-binding fraction belongs to the vicilins. Selected subunits and tryptic fragments were analysed for amino-acid compositions. Though unequivocal assignments to vicilin segments were possible, significant differences could be recognized, in particular in the tryptic fragments.     

Isolation and Characterization of Manganese-containing Superoxide Dismutase from Gluconobacter cerinus

Among 21 strains of Gluconobacter, Gluconobacter cerinus (IFO 3268) had a thermostable super oxide dismutase activity. The enzyme was purified about 110-fold to homogeneity from a cell- free extract by ammonium sulfate fractionation and DEAE-Toyopearl and Sephadex G-100 chromatography. The enzyme has a molecular weight of 47,000 and consists of two identical subunits, and contains 1.22 g atoms of Mn per mole of enzyme as the catalytically active metal. The enzyme disappeared from circulation in the guinea pig with a half-life of 45min, but enzyme modified with polyethylene glycol 5,000 had a half-life of 330 min.     

蛹虫草超氧化物歧化酶分离纯化及稳定性的研究

以蛹虫草为材料,经过硫酸铵盐析、Sephedex G-75柱层析和DEAE-52柱层析,得到纯化的超氧化物歧化酶（SOD）,经聚丙烯酰胺凝胶电泳显示单一区带,此酶比活力为17855．73u／mg,纯化倍数为53．7,回收率为21．8％。同时鉴于SOD在溶液中容易失活,无法长期保存,该文研究了不同浓度的糖类及不同浓度的有机酸类对SOD活力的影响,发现糖类对SOD活力影响不明显,有机酸均使SOD活力下降,但随着酸浓度的增加,SOD活力下降的程度也减轻。     

Plant Lectins Induce the Production of a Phytoalexin in Pisum sativum

The effects of several plant lectins on the production of apea phytoalexin, pisatin, were examined. Con A, PHA, PNA andPSA each induced the production of pisatin in pea epicotyl tissues,demonstrating that plant lectins can act as elicitors. The productionof pisatin in response to PHA, PNA or PSA was not affected bythe simultaneous presence of the respective hapten sugars, whereashaptens specific for Con A, such as -D-mannose and methyl--D-mannoside,abolished the induction of pisatin by Con A. These results indicatethat the elicitor effect of Con A is attributable to its abilityto bind to specific carbohydrates in pea cells. Induction ofthe production of pisatin by Con A was markedly inhibited bythe suppressor derived from a pea pathogen, Mycosphaerella pinodes,and by several inhibitors related to signal-transduction pathways.It is suggested, therefore, that the Con A-induced productionof pisatin in pea tissues might be associated with activationof a signal-transduction pathway. An additive effect on theaccumulation of pisatin was observed when Con A was presentwith a polysaccharide elicitor from M. pinodes, suggesting thatexogenous Con A does not compete with the recognition site(s)for the fungal elicitor in pea cells. The present data alsoindicate that Con A may be useful for characterization of thesignal-transduction system that leads to the synthesis of phytoalexinin pea epicotyl tissues. (Received November 16, 1994; Accepted April 20, 1995)     

扬子鳄红细胞超氧物歧化酶的纯化及其性质研究

扬子鳄红细胞超氧物歧化酶的纯化及其性质研究周衍茂（安徽教育学院生物系,合肥２３００６１）尹路明（中国科学技术大学生物系,合肥２３００２６）关键词超氧物歧化酶;纯化;扬子鳄;红细胞超氧物歧化酶（的田广泛存在于各类生物组织中,是生物体内超氧自由基有效的清...     

锰超氧化物歧化酶的催化原理与酶活性调节机制

锰超氧化物歧化酶(MnSOD)催化两分子超氧自由基歧化为分子氧和过氧化氢。超氧自由基被Mn³⁺SOD氧化成分子氧的反应以扩散的方式进行。超氧自由基被Mn²⁺SOD还原为过氧化氢的反应以快循环和慢循环两条途径平行进行。在慢循环途径中,Mn²⁺SOD与超氧自由基形成产物抑制复合物,然后该复合物被质子化而缓慢释放出过氧化氢。在快循环途径中,超氧自由基直接被Mn²⁺SOD转化为产物过氧化氢,快速循环有利于酶的复活与周转。本文提出温度是调节锰超氧化物歧化酶进入慢速或者快速循环催化途径的关键因素。随着在生理温度范围内的温度升高,慢速循环成为整个催化反应的主流,因而生理范围内的温度升高反而抑制该酶的活性。锰超氧化物歧化酶的双相酶促动力学特性可以用该酶保守活性中心的温度依赖性配位模型进行合理化解释。当温度降低时,1个水分子(或者OH^-)接近Mn、甚至与Mn形成配位键,从而干扰超氧自由基与Mn形成配位键而避免形成产物抑制。因此在低温下该酶促反应主要在快循环通路中进行。最后阐述了几种化学修饰模式对...     

Isoenzymes of Superoxide Dismutase in Nodules of Phaseolus vulgaris L., Pisum sativum L., and Vigna unguiculata (L.) Walp

The activity and isozymic composition of superoxide dismutase (SOD; EC 1.15.1.1) were determined in nodules of Phaseolus vulgaris L., Pisum sativum L., and Vigna unguiculata (L.) Walp. formed by Rhizobium phaseoll 3622, R. Ieguminosarum 3855, and Bradyrhizobium sp. BR7301, respectively. A Mn-SOD was present in Rhizobium and two in Bradyrhizobium and bacteroids. Nodule mitochondria from all three legume species had a single Mn-SOD with similar relative mobility, whereas the cytosol contained several CuZn-SODs: two in Phaseolus and Pisum, and four in Vigna. In the cytoplasm of V. unguiculata nodules, a Fe-containing SOD was also present, with an electrophoretic mobility between those of CuZn- and Mn-SODs, and an estimated molecular weight of 57,000. Total SOD activity of the soluble fraction of host cells, expressed on a nodule fresh weight basis, exceeded markedly that of bacteroids. Likewise, specific SOD activities of free-living bacteria were superior or equal to those of their symbiotic forms. Soluble extracts of bacteria and bacteroids did not show peroxidase activity (EC 1.11.1.7), but the nodule cell cytoplasm contained diverse peroxidase isozymes which were readily distinguishable from leghemoglobin components by electrophoresis. Data indicated that peroxidases and leghemoglobins did not significantly interfere with SOD localization on gels. Treatment with chloroform-ethanol scarcely affected the isozymic pattern of SODs and peroxidases, and had limited success in the removal of leghemoglobin.     

苦荞叶片超氧化物歧化酶的纯化及性质研究

从荞麦生化遗传以及器官衰老机理的研究目的出发,以苦荞叶片为材料,制备出活力较高的铜锌趋氧化物歧化酶。对其理化性质分析表明：该酶在２５９ｎｍ处有一特征吸收峰,分子量约为３１ｋＤ,含有３０８个氨基酸残基,同工酶电泳结果显示三条活性带。     

Changes in Expression of Manganese Superoxide Dismutase,Copper and Zinc Superoxide Dismutase and Catalase in Brachionus calyciflorus during the Aging Process

Rotifers are useful model organisms for aging research, owing to their small body size (0.1–1 mm), short lifespan (6–14 days) and the relative easy in which aging and senescence phenotypes can be measured. Recent studies have shown that antioxidants can extend the lifespan of rotifers. In this paper, we analyzed changes in the mRNA expression level of genes encoding the antioxidants manganese superoxide dismutase (MnSOD), copper and zinc SOD (CuZnSOD) and catalase (CAT) during rotifer aging to clarify the function of these enzymes in this process. We also investigated the effects of common life-prolonging methods [dietary restriction (DR) and resveratrol] on the mRNA expression level of these genes. The results showed that the mRNA expression level of MnSOD decreased with aging, whereas that of CuZnSOD increased. The mRNA expression of CAT did not change significantly. This suggests that the ability to eliminate reactive oxygen species (ROS) in the mitochondria reduces with aging, thus aggravating the damaging effect of ROS on the mitochondria. DR significantly increased the mRNA expression level of MnSOD, CuZnSOD and CAT, which might explain why DR is able to extend rotifer lifespan. Although resveratrol also increased the mRNA expression level of MnSOD, it had significant inhibitory effects on the mRNA expression of CuZnSOD and CAT. In short, mRNA expression levels of CAT, MnSOD and CuZnSOD are likely to reflect the ability of mitochondria to eliminate ROS and delay the aging process.     

人锰超氧化物歧化酶基因剪接异构体的表达分析

对人锰超氧化物歧化酶(human manganese superoxide dismutase,hMn-SOD)基因剪接异构体进行分析,并检测异构体的表达情况。在GenBank库中检索人锰超氧化物歧化酶基因异构体及编码基因组序列,利用Vector NTI9生物软件进行核酸及蛋白序列比对;利用RT-PCR方法分析锰超氧化物歧化酶基因异构体的表达。结果显示,在GenBank库检索发现有3种人锰超氧化物歧化酶基因异构体,剪接异构的类型为可变的5′剪接位点和外显子盒,各异构体基因内含子均符合"GT-AG"规则。3种基因异构体编码两种异构体蛋白,即222个氨基酸的人锰超氧化物歧化酶蛋白以及中部缺少39个氨基酸的截短型异构蛋白。RT-PCR检测结果表明,剪接异构体hMn-SODb在HEK293T和HSC细胞中的表达比在HepG2细胞中高,未见异构体hMn-SODc的表达。     

近江牡蛎铜锌超氧化物歧化酶的纯化及部分性质研究

经６５℃加热,硫酸铵分级沉淀,ＳｅｐｈａｄｅｘＧ－１００凝胶过滤和ＤＥ－５２柱层析,从近江牡蛎（ＯｓｔｒｅａｒｉｖｕｌａｒｉｓＧｏｕｌｄ）软体部分提纯了铜锌超氧化物歧化酶（Ｃｕ,Ｚｎ－ＳＯＤ）．对其理化性质鉴定表明,用此法纯化的酶纯度均一．该酶系由两个相同亚基组成的二聚体,分子量２７．９ｋＤ．该酶的紫外吸收峰在２７２．５ｎｍ,红外光谱表现出其氨基酸组成特征,与猪血ＳＯＤ存在差异．该酶在不同的升温速率下及经不同浓度的Ｈ２Ｏ２处理后的稳定性与猪血ＳＯＤ不同．其氨基酸组成与不同来源的同类酶存在差异．