超氧化物歧化酶的功能,性质及临床意义

自从1969年（MeCord）和（Fridovich）发现了超氧化物歧化酶（EC．1．15．1．1,superoxidedismutase,以下简称SOD）以来,国内外学者对SOD的研究日益广泛而深人。现已证明SOD存在于所有需氧生物的细胞中。SOD是一类金属酶,根据其所含金属辅基的不同,可将其分为3类：即Cu．Zn－SOD,Mn－SOD,和Fe－SOD。Cu、Zn－SOD主要存在于真核细胞的胞浆和线粒体,Mn－SOD主要存在于真核细胞的线粒体和原核细胞中,也存在于灵长类的胞浆。Fe－S（）D只存在于原核细胞。研究表明SOD与机体的衰老、炎症、肿瘤、抗细胞毒性等方面关系…     

细菌AcrAB-TolC型外排泵中AcrA蛋白的进化分析

研究不同耐药细菌AcrAB-Tolc型外排泵中关键蛋白AcrA的序列,针对其保守及非保守氨基酸残基进行该类蛋白的进化分析,构建蛋白进化树。收集来源于不同细菌的已知序列的AcrA蛋白,去除冗余并进行序列比对之后,根据其序列比对结果的相似性、氨基酸残基的保守性研究其进化特征。结果表明,不同细菌的AcrA蛋白部分氨基酸残基具有高度的保守性,这与其实现生物学功能有关,非保守区域是主要的进化区域。可为不同菌株的进化提供参考,同时为以AcrAB-Tolc型外排泵为靶标的新药研究提供相关数据。     

原核生物的碳酸酐酶

碳酸酐酶（CA）催化CO2和HCO3^-之间的相互转化反应,其显著特征是存在α,β,γ三种分子结构不同且独立进化的分子类别,最近的研究表明CA不仅广泛存在于真核界所有高度进化的生物体中,而且还广泛存在于古细菌界和细菌界代谢多样化的原核生物种类中,这表明该酶在原核生物中的作用比先前所认识的更广泛和更基本,鉴于CA在原核生物生理学上的重要性,有必要对近年来原核生物CA的进化分类,分子结构特性,酶学特性及其在原核生物中的分布以及可能的生理功能等方面的研究进展作一介绍。     

大肠杆菌与酵母菌基因特定序列信息参量的研究

提出核酸序列的矩阵表示形式,按位点定义了有生物学意义的信息参数M1（1）、M2（l）和M3(l）。着重研究了不同表达水平的大肠杆菌（Escherichia coli,E.coli）的SD序列（Shine-Dalgrno region,SD）以及大肠杆菌（E.coli）和酵母菌（Yeast）基因起始、终止密码子邻近区域核酸序列的碱基关联性与保守性。并求出相应矩阵的本征值,给出了信息参量与基因表达水平的关系。发现信息参量体现了原核生物和真核生物释放起始区域的显著差异,而且真核生物碱基起始区域的单碱基保守性程度及碱基关联性程度要比原核生物强。     

PAGE活性染色法分析D.radiodurans过氧化氢酶和超氧化物歧化酶

用PAGE活性染色法分析了D．rndiodurans过氧化氢酶（Cat）和超氧化物歧化酶(SOD)._2种同种异型D．radiodurans（RI和Sark）的Cat在电泳带型上存在差异,两者Kat均可分为A、B和C3条带,但各带所占比例明显不同。SOD的分析结果表明,D.radioduransSOD以Fe2 和Mn2 离子的嵌合体形式存在,其中Fe－SOD成分占90％以上。PAGE活性染色法可检出Cat和SOD的最低菌体总蛋白量分别为1.2和2.0μg。     

外源SOD和APX基因在转基因烟草中的表达与遗传

分析转超氧化物歧化酶基因（SOD）或抗坏血酸过氧化物酶基因（APX）烟草及其自交和杂交后代的叶片中超氧化物歧化酶（SOD）和过氧化物酶（POD）活性的结果表明：转基因烟草的SOD和POD活性在终花期最强,不同叶位叶中SOD活性差异不明显,POD活性以下部叶为最高;转基因烟草的SOD或POD活性显著高于近等基因的非转基因品系。杂交后代（F1、F2）的SOD活性能保持稳定,略高于亲本;自交后代（S1～S3）与自交亲本的SOD和POD活性相当。     

3种进化类型大豆叶片的某些生理特性比较

半野生、半栽培和栽培大豆叶片可溶性糖和可溶性蛋白含量以及过氧化物酶（POD）和超氧化物歧化酶（SOD）活性均表现为随品种的进化而增加的变化趋势。POD活性在生育期中呈上升变化,SOD活性则随着生育进程逐渐下降。栽培大豆的可溶性糖含量和POD活性以上部叶片最高,半栽培大豆与栽培大豆类似,半野生大豆的变化则不明显。     

草鱼线粒体型超氧化物歧化酶的生化遗传特性

超氧化物歧化酶 (SOD)是一种对生物细胞保护至关重要、在进化上比较保守的酶。因此 ,超氧化物歧化酶作为分子钟或分子标记已被广泛应用于生物进化研究、群体遗传结构分析以及品系鉴定。但鱼类SOD的生物化学和遗传学特性都尚未进行过系统和深入的研究。为使这一重要的分子标记能更好地应用于鱼类遗传育种、种质资源保护以及进化研究 ,本实验采用聚丙烯酰胺梯度凝胶垂直电泳法 ,研究了草鱼线粒体型超氧化物歧化酶 (fm SOD)的同功酶形式 ,生化遗传表型、亚基组成以及金属类型。实验结果表明 ,草鱼fm SOD有三种不同的同功酶形式 ;按从正极到负极的排列分别命名为fm SOD 1 ,fm SOD 2 ,fm SOD 3。这三种不同的fm SOD在草鱼群体中可构成 3种不同的生化遗传学表型 :表型 1个体只含有迁移率最快的fm SOD 1同功酶 ;表型3个体只含有迁移率最慢的fm SOD 3同功酶 ;而表型 2个体中含有所有三种不同形式的同功酶。在野生草鱼群体中 ,存在所有三种表现型 ;而在基因纯合型的雌核发育草鱼群体中只检测到表型 1和表型 3。野生草鱼群体中三种表现型的个体数之比符合一对等位基因分离的 1∶2∶1孟德尔遗传分离比例。由这些实验结果得出以下结论 :(1 )草鱼fm SOD是由细胞核DNA上的基因所编码而不是由线粒体DNA上的基因所编码的     

贝类毒素大田软海绵酸OA对小鼠肝脏还原型谷胱甘肽GSH、过氧化氢酶CAT、超氧化物岐化酶SOD的影响

为了探究腹腔注射贝类毒素OA对小鼠肝脏还原性谷胱甘肽（GSH）、过氧化氢酶（CAT）、超氧化物歧化酶（SOD）的影响,采用对一月龄的小鼠腹腔注射不同浓度的OA,24h后取其小鼠肝脏测定还原性谷胱甘肽（GSH）、过氧化氢酶（CAT）、超氧化物歧化酶（SOD）各项指标。结果表明,测定注射OA毒素各剂量组的超氧化物歧化酶（GSH）、过氧化氢酶（CAT）、超氧化物歧化酶（SOD）3项指标均显著低于对照组。其中,GSH高剂量组和中剂量组差异性不显著。CAT高剂量组（96μg/h）、中剂量组（48μg／kg）、低剂量组（24μg/kg）各组变化显著,呈现一定的剂量-效应关系,SOD高中低各组差异性不显著。因此,在小鼠染毒OA24h后,还原性谷胱甘肽（GSH）,超氧化物歧化酶（SOD）,过氧化氢酶（CAT）这3项指标均受到了显著性抑制作用,说明这3项指标对毒素OA较为敏感,其中CAT呈现了显著的剂量一效应关系。     

原核生物信号识别颗粒（SRP）介导蛋白识别转运途径的研究进展

SRP介导的蛋白识别转运过程首先在真核细胞中发现,作用机制已经研究清楚;而SRP在原核细胞中的发现较晚,虽然该途径主要功能蛋白的序列同真核细胞相似,进化上比较保守,但作用机制还未完全揭示,而且SRP体系在原核生物物种间有一定差别,预示着其机制既有统一性,又具有物种特异性。目前原核生物SRP途径的研究主要集中在Ffh、FtsY和4.5SRNA结构与功能,以及这一过程中能量物质GTP的代谢和作用;文章以此为着眼点,概括总结了原核生物中SRP介导蛋白识别转运的研究进展,同时简单介绍了链霉菌中SRP介导蛋白识别转运的研究近况。希望通过链霉菌的相关研究,从进化角度完善和统一原核生物SRP途径的作用机制。     

Characterization of a superoxide dismutase gene from the archaebacterium Methanobacterium thermoautotrophicum

A gene encoding superoxide dismutase (SOD) was cloned from the archaebacterium Methanobacterium thermoautotrophicum, the first example from an anaerobic bacterium. The deduced amino acid sequence showed overall similarity to sequences of known Mn- and Fe-SODs from aerobic organisms. Judging from a detailed sequence comparison, the cloned SOD gene is classified as Mn-SOD. By comparison of Mn-SOD sequences among various species it was suggested that archaebacterial superoxide dismutase is a direct descendant of a primordial enzyme. Between a putative promoter and the start codon there is an inverted repeat sequence which is also found in the counterpart of Halobacterium halobium.     

Role of the tertiary and quaternary structures in the stability of dimeric copper, zinc superoxide dismutases

The equilibrium unfolding process of human Cu,Zn superoxide dismutase has been quantitatively monitored through circular dichroism and fluorescence spectroscopy as a function of increasing guanidinium hydrochloride concentration. The process occurs through the formation of a monomeric intermediate species following a three-state transition equilibrium. Comparison with the stability of the prokaryotic Cu,Zn SOD from P. leiognathi shows that the eukaryotic enzyme is more stable than the prokaryotic enzyme by approximately 3 kcal/mol. This difference is due to the monomer-to-unfolded equilibrium, while the dimer-to-monomer equilibrium is comparable for the two enzymes despite their different intersubunit interactions. These results are confirmed by the unfolding of the copper-depleted derivatives. The Cu,Zn superoxide dismutase represents a good example of how evolution has found two independent quaternary assemblies maintaining the same dimer stability.     

The iron-containing superoxide dismutase of Ralstonia metallidurans CH34

The iron-containing superoxide dismutase (Fe-SOD) of Ralstonia metallidurans CH34 was purified and characterised as a homodimer of 2 x 21500 Da containing one iron atom per monomer and exhibiting all the characteristics of the prokaryotic Fe-SODs except for a higher isoelectric point. The protein was 2-fold overexpressed in the presence of selenite, zinc or paraquat. R. metallidurans CH34 was suggested to contain a gene encoding for a manganese-containing SOD located in the inducible chromate resistance operon. Whatever the culture conditions used in this study, including the presence of chromate, only a Fe-SOD, genetically distinct from the putative Mn-SOD, was detected. This Fe-SOD seems to be the only active superoxide dismutase expressed in R. metallidurans CH34.     

Biosynthesis and regulation of superoxide dismutases

The past two decades have witnessed an explosion in our understanding of oxygen toxicity. The discovery of superoxide dismutases (SODs) (EC.1.15.1.1), which specifically catalyze the dismutation of superoxide radicals (O₂⁻) to hydrogen peroxide (H₂O₂) and oxygen, has indicated that O₂⁻ is a normal and common byproduct of oxygen metabolism. There is an increasing evidence to support the conclusion that superoxide radicals play a major role in cellular injury, mutagenesis, and many diseases. In all cases SODs have been shown to protect the cells against these deleterious effects. Recent advances in molecular biology and the isolation of different SOD genes and SOD c-DNAs have been useful in proving beyond doubt the physiological function of the enzyme. The biosynthesis of SODs, in most biological systems, is under rigorous controls. In general, exposure to increased pO₂, increased intracellular fluxes of O₂⁻, metal ions perturbation, and exposures to several environmental oxidants have been shown to influence the rate of SOD synthesis in both prokaryotic and eukaryotic organisms. Recent developments in the mechanism of regulation of the manganese-containing superoxide dismutase of Escherichia coli will certainly open new research avenues to better understand the regulation of SODs in other organisms.     

Phylogenetic distribution of superoxide dismutase supports an endosymbiotic origin for chloroplasts and mitochondria

Three isozymes of superoxide dismutase (SOD) have been identified and characterized. The iron and manganese isozymes (Fe-SOD and Mn-SOD, respectively) show extensive primary sequence and structural homology, suggesting a common evolutionary ancestor. In contrast, the copper/zinc isozyme (CuZn-SOD) shows no homology with Fe-SOD or Mn-SOD, suggesting an independent origin for this enzyme. The three isozymes are unequally distributed throughout the biological kingdoms and are located in different subcellular compartments. Obligate anaerobes and aerobic diazotrophs contain Fe-SOD exclusively. Facultative aerobes contain either Fe-SOD or Mn-SOD or both. Fe-SOD is found in the cytosol of cyanobacteria while the thylakoid membranes of these organisms contain a tightly bound Mn-SOD. Similarly, most eukaryotic algae contain Fe-SOD in the chloroplast stroma and Mn-SOD bound to the thylakoids. Most higher plants contain a cytosol-specific and a chloroplast-specific CuZn-SOD, and possibly a thylakoid-bound Mn-SOD as well. Plants also contain Mn-SOD in their mitochondria. Likewise, animals and fungi contain a cytosolic CuZn-SOD and a mitochondrial Mn-SOD. The Mn-SOD found in the mitochondria of eukaryotes shows strong homology to the prokaryotic form of the enzyme. Taken together, the phylogenetic distribution and subcellular localization of the SOD isozymes provide strong support for the hypothesis that the chloroplasts and mitochondria of eukaryotic cells arose from prokaryotic endosymbionts.     

Periplasmic superoxide dismutase from Desulfovibrio desulfuricans 1388 is an iron protein

It is shown that the genome of the sulfate-reducing bacterium Desulfovibrio desulfuricans 1388 contains a superoxide dismutase (SOD) gene (sod). The gene encodes an export signal peptide characteristic for periplasmic redox proteins. The amino acid sequence showed high homology with iron-containing SODs from other bacteria. Electrophoretically pure SOD was isolated from the periplasmic fraction of bacterial cells by FPLC chromatography. Like other Fe-SODs, D. desulfuricans 1388 superoxide dismutase is inhibited by H2O2 and azide, but not by cyanide.     

Molecular characterization and quantitative analysis of superoxide dismutases in virulent and avirulent strains of Aeromonas salmonicida subsp. salmonicida

Aeromonas salmonicida subsp. salmonicida is a facultatively intracellular gram-negative bacterium that is the etiological agent of furunculosis, a bacterial septicemia of salmonids that causes significant economic loss to the salmon farming industry. The mechanisms by which A. salmonicida evades intracellular killing may be relevant in understanding virulence and the eventual design of appropriate treatment strategies for furunculosis. We have identified two open reading frames (ORFs) and related upstream sequences that code for two putative superoxide dismutases (SODs), sodA and sodB. The sodA gene encoded a protein of 204 amino acids with a molecular mass of approximately 23.0 kDa (SodA) that had high similarity to other prokaryotic Mn-SODs. The sodB gene encoded a protein of 194 amino acids with a molecular mass of approximately 22.3 kDa that had high similarity to other prokaryotic Fe-SODs. Two enzymes with activities consistent with both these ORFs were identified by inhibition of O(2)(-)-catalyzed tetrazolium salt reduction in both gels and microtiter plate assays. The two enzymes differed in their expression patterns in in vivo- and in vitro-cultured bacteria. The regulatory sequences upstream of putative sodA were consistent with these differences. We could not identify other SOD isozymes such as sodC either functionally or through data mining. Levels of SOD were significantly higher in virulent than in avirulent strains of A. salmonicida subsp. salmonicida strain A449 when cultured in vitro and in vivo.     

A protein isolated from Brucella abortus is a Cu-Zn superoxide dismutase

Brucella abortus contains a protein that elicits an antigenic response in cattle previously exposed to the organism. The amino acid sequence of the recombinant form of this antigenic protein was determined by gas-phase sequencing of the pyridylethylated protein and its peptides obtained by digestion with cyanogen bromide (CNBr), clostripain, and Staphylococcus aureus V8 protease. The Brucella protein demonstrated 53.6% identity with the Cu-Zn superoxide dismutase (SOD) from Photobacterium leiognathi. Residues essential for metal coordination and enzymatic activity and cysteines required for the formation of the intrasubunit disulfide bridge of Cu-Zn SOD were conserved in the Brucella protein. also exhibited SOD activity that was inhibited by cyanide, which is characteristic of a Cu-Zn SOD. Brucella abortus Cu-Zn SOD is the second prokaryotic Cu-Zn SOD to be sequenced, and the fifth found in prokaryotes. The high degree of conservation between Photobacterium and Brucella Cu-Zn SOD supports the hypothesis of a separately evolved prokaryotic and eukaryotic Cu-Zn SOD gene.     

A cambialistic SOD in a strictly aerobic hyperthermophilic archaeon, Aeropyrum pernix.

The superoxide dismutase (SOD) gene of Aeropyrum pernix, a strictly aerobic hyperthermophilic archaeon, was cloned and expressed in Escherichia coli, and its gene product was characterized. The molecular mass of the protein, based on the deduced amino acid sequence, was 24.6 kDa. The sequence showed overall similarity to the sequences of known Mn- and Fe-SODs. The metal binding residues conserved in Mn- and Fe-SODs were also found in A. pernix SOD. When the SOD gene was expressed in E. coli cells, the product formed a homodimer, and contained both Mn and Fe. Metal reconstitution experiments showed that A. pernix SOD is cambialistic, i.e. active with either Fe or Mn. The specific activities were 906 U/mg with Mn and 175 U/mg with Fe. No loss of activity of Mn-reconstituted SOD was observed at 105 degrees C even after 5 h incubation. Sodium azide, an inhibitor of SODs, did not inhibit the Mn-reconstituted SOD from A. pernix even at concentrations up to 400 mM. This SOD from an aerobic hyperthermophilic archaeon, Aeropyrum pernix, was extremely thermostable and active with either Mn or Fe. With Mn as a metal cofactor, it was more thermostable, and less sensitive to sodium azide and sodium fluoride than with Fe.