邻苯二酚2,3-双加氧酶的结构和功能研究进展

邻苯二酚是所有芳香族化合物降解过程中的重要的中间产物,其降解有邻位和间位裂解两条裂解途径,分别由邻苯二酚1,2-双加氧酶(C12O)和邻苯二酚2,3-双加氧酶(C23O)催化裂解。本综述简要介绍了邻苯二酚2,3-双加氧酶的结构和功能的研究进展。     

恶臭假单胞菌ND6菌株catA基因的克隆和表达及其儿茶酚裂解途径探讨

恶臭假单胞菌ND6菌株的萘降解质粒pND6-1中编码儿茶酚1,2-双加氧酶的catA基因在大肠杆菌中进行了克隆和表达,并研究表达产物的酶学性质。结果表明:酶的Km为0.019μmol/L,Vmax为1.434μmol/(min.mg);具有很好的耐热性,在50℃保温45min后仍能够保留酶活力的93.7%;Fe2 对酶活性有显著的促进作用,其比活力是对照反应的292%;酶对4-氯儿茶酚的催化活性非常低,属于Ⅰ型儿茶酚1,2-双加氧酶。以萘为底物生长时,ND6菌株的细胞提取液中既存在催化邻位裂解途径的儿茶酚1,2-双加氧酶活性,也存在催化间位裂解途径的儿茶酚2,3-双加氧酶活性。以苯甲酸、对羟基苯甲酸和苯乙酸为唯一碳源生长时,ND6菌株细胞提取液的儿茶酚1,2-双加氧酶活性远远大于儿茶酚2,3-双加氧酶活性。表明ND6菌株既能通过儿茶酚间位裂解途径降解萘,也能通过儿茶酚邻位裂解途径降解萘,而以苯甲酸、对羟基苯甲酸和苯乙酸为诱导物时只利用儿茶酚邻位裂解途径。     

恶臭假单胞菌ND6菌株catA基因的克隆和表达及其儿茶酚裂解途径探讨

恶臭假单胞菌ND6菌株的萘降解质粒pND6-1中编码儿茶酚1,2-双加氧酶的catA基因在大肠杆菌中进行了克隆和表达,并研究表达产物的酶学性质。结果表明:酶的K_m为0.019μmol/L,V_max为1.434μmol/(min.mg);具有很好的耐热性,在50℃保温45min后仍能够保留酶活力的93.7%;Fe²⁺对酶活性有显著的促进作用,其比活力是对照反应的292%;酶对4-氯儿茶酚的催化活性非常低,属于Ⅰ型儿茶酚1,2-双加氧酶。以萘为底物生长时,ND6菌株的细胞提取液中既存在催化邻位裂解途径的儿茶酚1,2-双加氧酶活性,也存在催化间位裂解途径的儿茶酚2,3-双加氧酶活性。以苯甲酸、对羟基苯甲酸和苯乙酸为唯一碳源生长时,ND6菌株细胞提取液的儿茶酚1,2-双加氧酶活性远远大于儿茶酚2,3-双加氧酶活性。表明ND6菌株既能通过儿茶酚间位裂解途径降解萘,也能通过儿茶酚邻位裂解途径降解萘,而以苯甲酸、对羟基苯甲酸和苯乙酸为诱导物时只利用儿茶酚邻位裂解途径。     

苯甲酸-1,2-双加氧酶高产菌株的筛选和发酵条件的研究

苯甲酸-1,2-双加氧酶(ECl.13.99.2)催化苯甲酸转化成邻苯二酚。该酶是微生物降解芳香烃的一个关键酶,它催化氧化开环的第一步反应,在研究微生物的芳香烃代谢中占有重要位置。近年来,发现该酶可以用来在工业上合成邻苯二酚以及消除芳环化合物的污     

好氧氯苯降解菌的分离鉴定

【目的】分离好氧氯苯降解菌,并通过研究降解特性为应用提供理论依据。【方法】利用富集培养技术分离菌株,通过形态、生理生化反应特征及16S rRNA基因序列分析鉴定菌株,测定培养液中氯苯、其它氯苯类化合物和氯离子的浓度以及菌体细胞的密度和菌体细胞粗提液中邻苯二酚双加氧酶的活性,研究菌株的降解特性。【结果】16S rRNA基因序列相似性比较表明,分离出的菌株与乙酸钙不动杆菌(Acinetobacter calcoaceticus)的相似性高达98.5%。以初始浓度为50mg/L的氯苯为唯一碳源和能源时,120h内菌株对氯苯的降解率高达98.2%,氯离子净释放量和氯苯降解量的摩尔比范围为1:1.85-1:1.39,菌体细胞粗提液中邻苯二酚1,2-双加氧酶的平均活性为0.538U/mg蛋白质。加入葡萄糖后,菌体细胞数量和氯离子浓度明显增加,但单位细胞的氯苯降解能力明显下降。在二氯苯和三氯苯共存时,菌株对氯苯的降解能力受到明显的抑制作用,但对二氯苯有一定的降解作用,降解能力大小顺序为:1,3-二氯苯1,2-二氯苯1,4-二氯苯。【结论】分离出的好氧氯苯降解菌属于Acinetobacter属菌株,该菌株对氯苯和二氯苯均具有降解作用,可能通过邻位裂环途径降解氯苯,氯苯对菌株的降解能力和邻苯二酚1,2-双加氧酶的活性具有明显的增强作用。     

石油污染土壤中苯酚降解菌ad049的鉴定及降解特性

以苯酚为唯一碳源,采用富集培养方法,从陕北靖边油田污染土壤中分离获得1株苯酚高效降解菌(ad049),对菌株进行形态观察、生理生化检验及16S rDNA序列分析,确定该菌株为红球菌(Rhodococcus)。采用摇瓶振荡培养方法,研究了接种量、pH值、温度和底物浓度对ad049生长量和苯酚降解率的影响,同时对该菌株脱氢酶和邻苯二酚双加氧酶活性进行了测定。结果表明,ad049具有较强的苯酚降解能力;在苯酚浓度1000 mg/L,温度35℃,pH值8,接种量5%的培养条件下,反应24 h后,苯酚降解率达99%以上,且整个降解过程符合零级动力学方程,速率常数k_0=41.51,相关系数R~2=0.96。通过邻苯二酚双加氧酶活性的测定,推测出该菌株降解苯酚的途径可能是以邻苯二酚1,2双加氧酶为主要途径进行邻位开环,辅以邻苯二酚2,3双加氧酶进行间位开环。     

三氯卡班降解菌株Sphingomonas sp. YL-JM2C中多个邻苯二酚双加氧酶的功能

【目的】研究Sphingomonas sp.YL-JM2C菌株的生长特性,确定以三氯卡班作为碳源的生长情况。挖掘菌株YL-JM2C潜在的邻苯二酚1,2-双加氧酶及邻苯二酚2,3-双加氧酶基因,在大肠杆菌(Escherichia coli)中异源表达邻苯二酚双加氧酶基因并研究其酶学性质。【方法】优化S.sp.YL-JM2C菌株以三氯卡班作为碳源时的培养条件,并利用全自动生长曲线测定仪测定菌株生长情况,绘制生长曲线。通过生物信息学方法挖掘潜在的邻苯二酚双加氧酶基因,并分别在Escherichia coli BL21(DE3)中进行异源表达,通过AKTA快速纯化系统纯化蛋白,分别以邻苯二酚、3-和4-氯邻苯二酚为底物检测重组蛋白的酶学特性。【结果】菌株在pH为7.0-7.5时生长最优。在以浓度为4-8 mg/L的三氯卡班做为底物时,菌株适宜生长。当R2A培养基仅含有0.01%酵母提取物和无机盐时,加入终浓度为4 mg/L的三氯卡班可促进菌株生长。挖掘到6个潜在的邻苯二酚双加氧酶基因stcA1、stcA2、stcA3、stcE1、stcE2和stcE3,表达并通过粗酶液分析证明其中5个基因stcA1、stcA2、stcA3、stcE1和stcE2编码的酶均具有邻苯二酚双加氧酶和氯邻苯二酚双加氧酶的活性;纯化酶的底物范围研究揭示了StcA1、StcA2和StcA3均属于Ⅱ型邻苯二酚1,2-双加氧酶,StcE1和StcE2为两个新型邻苯二酚2,3-双加氧酶;它们酶动力学分析研究证明了5个酶对邻苯二酚的亲和力和催化效率最高,4-氯邻苯二酚次之。【结论】在同一菌株中发现了5个具有功能的邻苯二酚双加氧酶基因,stcA1、stcA2和stcA3编码的酶均属于Ⅱ型邻苯二酚1,2-双加氧酶,stcE1和stcE2为两个新型邻苯二酚2,3-双加氧酶编码基因。5个酶均具有催化邻苯二酚和氯邻苯二酚开环反应的功能,这为更好地理解微生物基因组内代谢邻苯二酚及其衍生物氯代邻苯二酚基因的多样性奠定了基础。     

邻苯二酚-1,2-双加氧酶的催化性质

邻苯二酚-1,2-双加氧酶能催化邻苯二酚的两个羟基之间裂解,生成顺,顺-己二烯二酸,加水很容易转化为尼龙-6,6的原料己二酸。此外,它有极易起化学反应的共轭双键和羧基,可成为新功能树脂的原料。1955年发现邻苯二酚-1,2-双加氧酶,此后进行了大量研究工作,但是直到近几年由于合成顺,顺-己二烯二酸的需要,才引起人们的高度重视。我们对胞外酶产生菌的发酵条件及其所产的邻苯二酚-1,2-双加氧酶性质进行了研究,为工业规模的生产应用作了准备。     

丛毛睾丸酮单胞菌ZD4-1和铜绿假单胞菌ZD4-3降解芳香烃化合物的机理

从某农药厂二沉池污泥中筛选分离得到两株革兰氏阴性的芳香烃降解菌ZD41和ZD43。经鉴定,它们分别属于Comamonas testosteroni和Pseudomonas aeruginosa。基于16S rDNA 序列的系统分类分析,结果表明,在分类地位上菌株ZD41和ZD43 分别属于两个不同的分类亚组。苯酚降解产物紫外光谱扫描和双加氧酶检测证明,菌株ZD41利用邻裂途径降解苯酚,而ZD43则通过间裂途径降解苯酚,邻裂途径的1,2双加氧酶和间裂途径的2,3双加氧酶都是可诱导的双加氧酶,其活性强烈的依赖于降解底物的出现。芳香烃降解试验结果表明,邻裂和间裂两种途径的降解性能不一样,虽然ZD43降解苯酚的效率要高于菌株ZD41,但是ZD41降解苯酚的pH值范围以及芳烃利用基质谱宽于后者。     

陶厄氏菌Thauera sp.K11对酚类化合物降解作用及途径研究

旨在分析陶厄氏菌属(Genus Thuaera)中的一株菌株Thauera sp.K11对含酚废水中酚类化合物的降解作用和途径。以石化污水厂分离菌株K11为研究对象,克隆其16S r RNA基因和关键酶基因,并进行系统发育分析,在基因水平探究苯酚降解机理;利用气相色谱技术检测酚类化合物降解效果和苯酚降解机理。结果显示,利用16S r RNA系统学分析发现K11是陶厄氏菌属的一株细菌。该菌对11种酚类化合物具有降解作用,其中5种酚类化合物72 h的降解率90%。克隆并获得了K11的苯酚羟化酶和邻苯二酚双加氧酶基因。酶活性测定表明,K11通过苯酚羟化酶催化苯酚转化为邻苯二酚,然后利用邻苯二酚-2,3-双加氧酶催化产生2-HMSA。陶厄氏菌Thauera sp.K11是一株能够降解多种酚类化合物的菌株,具有较强的酚类污染物降解能力,其通过苯酚→邻苯二酚→2-HMSA途径进行苯酚降解。     

Properties of cyanogen bromide-activated, Agarose-immobilized catechol 1,2-dioxygenase from freeze-dried extracts of Nocardia sp. NCIB 10503

Catechol 1,2-dioxygenase [catechol: oxygen 1,2-oxidoreductase (decyclizing); EC 1.13.11.1], the aromatic intradiol ring-cleaving enzyme of Nocardia sp. NCIB 10503 prepared by freeze-drying cell-free extracts, was covalently attached to cyanogen bromide-activated Agarose. The properties of the immobilized enzyme were compared to those of the free enzyme preparation. Immobilization was shown to increase the thermal stability of the enzyme. The pH-activity profile was altered by immobilization. Various explanations for this phenomenon are discussed. The V_max and K_m of the enzyme were not significantly affected on immobilization. The enzyme had a broader substrate specificity than any previously reported catechol 1,2-dioxygenase, and this was largely unaltered by immobilization. The properties of the preparations are compared to those of other (free) catechol 1,2-dioxygenases. The results presented show that the immobilization of catechol 1,2-dioxygenase offers an attractive means for the production of cis,cis-muconate and novel substituted analogues.     

DNA sequence of the Acinetobacter calcoaceticus catechol 1,2-dioxygenase I structural gene catA: evidence for evolutionary divergence of intradiol dioxygenases by acquisition of DNA sequence repetitions.

The DNA sequence of a 1.6-kilobase-pair SalI-KpnI Acinetobacter calcoaceticus restriction fragment carrying catA, the structural gene for catechol 1,2-dioxygenase I, was determined. The 933-nucleotide gene encodes a protein product with a deduced molecular weight of 34,351. The similarly sized Pseudomonas clcA gene encodes catechol 1,2-dioxygenase II, an enzyme with relatively broad substrate specificity and relatively low catalytic efficiency. Comparison of the catA and clcA sequences demonstrated their common ancestry and suggested that acquisitions of direct and inverted sequence repetitions of 6 to 10 base pairs were frequent events in their evolutionary divergence. The catechol 1,2-dioxygenases proved to be evolutionarily homologous with the alpha and beta subunits of Pseudomonas protocatechuate 3,4-dioxygenase, and analysis of conserved residues in the intradiol dioxygenases revealed conserved histidyl and tyrosyl residues that are probably involved in the ligation of ferric ion in their active sites.     

Cloning of a gene encoding hydroxyquinol 1,2-dioxygenase that catalyzes both intradiol and extradiol ring cleavage of catechol.

Two Escherichia coli transformants with catechol 1,2-dioxygenase activity were selected from a gene library of the benzamide-assimilating bacterium Arthrobacter species strain BA-5-17, which produces four catechol 1,2-dioxygenase isozymes. A DNA fragment isolated from one transformant contained a complete open reading frame (ORF). The deduced amino acid sequence of the ORF shared high identity with hydroxyquinol 1,2-dioxygenase. An enzyme expressed by the ORF was purified to homogeneity and characterized. When hydroxyquinol was used as a substrate, the purified enzyme showed 6.8-fold activity of that for catechol. On the basis of the sequence identity and substrate specificity of the enzyme, we concluded that the ORF encoded hydroxyquinol 1,2-dioxygenase. When catechol was used as a substrate, cis,cis-muconic acid and 2-hydroxymuconic 6-semialdehyde, which were products by the intradiol and extradiol ring cleavage activities, respectively, were produced. These results showed that the hydroxyquinol 1,2-dioxygenase reported here was a novel dioxygenase that catalyzed both the intradiol and extradiol cleavage of catechol.     

Chemical structure and biodegradability of halogenated aromatic compounds. Two catechol 1,2-dioxygenases from a 3-chlorobenzoate-grown pseudomonad.

1. Two catechol 1,2-dioxygenases, pyrocatechase I and pyrocatechase II, were found in 3-chlorobenzoate-grown cells of Pseudomonas sp. B 13. The latter enzyme showed high relative activities with 3- and 4-chlorocatechol compared with catechol. 2. In benzoate-grown cells, only pyrocatechase I was induced. It was purified 29-fold with a final specific activity of 20 mumol of catechol oxygenated/min per mg of protein and an overall yield of 22%. Because of the instability of pyrocatechase II on chromatography and dialysis, no increase of specific activity was obtained during the purification experiments. 3. Molecular weights of pyrocatechase I and pyrocatechase II were 82000 and 67000 respectively. 4. For both pyrocatechases the pH optimum was found to be at 8.0.5. Inhibitions of the two pyrocatechases by Cu2+ and Hg2+ ions and p-chloromercuribenzoate were different. The effect on pyrocatechase I after incubation for 20 h with the heavy metals was decreased by addition of 1 mM-2-mercaptoethanol to the reaction mixture. The inhibition of pyrocatechase II was even enhanced under these conditions. 6. Extradiol cleavage of 3-methylcatechol in addition to intradiol fission at a ratio of 1:14 was observed only with pyrocatechase I.     

An archetypical extradiol-cleaving catecholic dioxygenase: the crystal structure of catechol 2,3-dioxygenase (metapyrocatechase) from Ppseudomonas putida mt-2.

BACKGROUND: Catechol dioxygenases catalyze the ring cleavage of catechol and its derivatives in either an intradiol or extradiol manner. These enzymes have a key role in the degradation of aromatic molecules in the environment by soil bacteria. Catechol 2, 3-dioxygenase catalyzes the incorporation of dioxygen into catechol and the extradiol ring cleavage to form 2-hydroxymuconate semialdehyde. Catechol 2,3-dioxygenase (metapyrocatechase, MPC) from Pseudomonas putida mt-2 was the first extradiol dioxygenase to be obtained in a pure form and has been studied extensively. The lack of an MPC structure has hampered the understanding of the general mechanism of extradiol dioxygenases. RESULTS: The three-dimensional structure of MPC has been determined at 2.8 A resolution by the multiple isomorphous replacement method. The enzyme is a homotetramer with each subunit folded into two similar domains. The structure of the MPC subunit resembles that of 2,3-dihydroxybiphenyl 1,2-dioxygenase, although there is low amino acid sequence identity between these enzymes. The active-site structure reveals a distorted tetrahedral Fe(II) site with three endogenous ligands (His153, His214 and Glu265), and an additional molecule that is most probably acetone. CONCLUSIONS: The present structure of MPC, combined with those of two 2,3-dihydroxybiphenyl 1,2-dioxygenases, reveals a conserved core region of the active site comprising three Fe(II) ligands (His153, His214 and Glu265), one tyrosine (Tyr255) and two histidine (His199 and His246) residues. The results suggest that extradiol dioxygenases employ a common mechanism to recognize the catechol ring moiety of various substrates and to activate dioxygen. One of the conserved histidine residues (His199) seems to have important roles in the catalytic cycle.     

Cloning and characterization of two catA genes in Acinetobacter lwoffii K24.

Two novel type I catechol 1,2-dioxygenases inducible on aniline media were isolated from Acinetobacter lwoffii K24. Although the two purified enzymes, CD I1 and CD I2, had similar intradiol cleavage activities, they showed different substrate specificities for catechol analogs, physicochemical properties, and amino acid sequences. Two catA genes, catA1 and catA2, encoding by CD I1 and CD I2, respectively, were isolated from the A. lwoffii K24 genomic library by using colony hybridization and PCR. Two DNA fragments containing the catA1 and catA2 genes were located on separate regions of the chromosome. They contained open reading frames encoding 33.4- and 30.4-kDa proteins. The amino acid sequences of the two proteins matched well with previously determined sequences. Interestingly, further analysis of the two DNA fragments revealed the locations of the catB and catC genes as well. Moreover, the DNA fragment containing catA1 had a cluster of genes in the order catB1-catC1-catA1 while the catB2-catA2-catC2 arrangement was found in the catA2 DNA fragment. These results may provide an explanation of the different substrate specificities and physicochemical properties of CD I1 and CD I2.     

Specificity of catechol ortho-cleavage during para-toluate degradation by Rhodococcus opacus 1cp

Degradation of para-toluate by Rhodococcus opacus 1cp was investigated. Activities of the key enzymes of this process, catechol 1,2-dioxygenase and muconate cycloisomerase, are detected in this microorganism. Growth on p-toluate was accompanied by induction of two catechol 1,2-dioxygenases. The substrate specificity and physicochemical properties of one enzyme are identical to those of chlorocatechol 1,2-dioxygenase; induction of the latter enzyme was observed during R. opacus 1cp growth on 4-chlorophenol. The other enzyme isolated from the biomass grown on p-toluate exhibited lower rate of chlorinated substrate cleavage compared to the catechol substrate. However, this enzyme is not identical to the catechol 1,2-dioxygenase cloned in this strain within the benzoate catabolism operon. This supports the hypothesis on the existence of multiple forms of dioxygenases as adaptive reactions of microorganisms in response to environmental stress.     

The 1.8 A crystal structure of catechol 1,2-dioxygenase reveals a novel hydrophobic helical zipper as a subunit linker

BACKGROUND: Intradiol dioxygenases catalyze the critical ring-cleavage step in the conversion of catecholate derivatives to citric acid cycle intermediates. Catechol 1,2-dioxygenases (1, 2-CTDs) have a rudimentary design structure - a homodimer with one catalytic non-heme ferric ion per monomer, that is (alphaFe(3+))(2). This is in contrast to the archetypical intradiol dioxygenase protocatechuate 3,4-dioxygenase (3,4-PCD), which forms more diverse oligomers, such as (alphabetaFe(3+))(2-12). RESULTS: The crystal structure of 1,2-CTD from Acinetobacter sp. ADP1 (Ac 1,2-CTD) was solved by single isomorphous replacement and refined to 2.0 A resolution. The structures of the enzyme complexed with catechol and 4-methylcatechol were also determined at resolutions of 1.9 A and 1.8 A, respectively. While the characteristics of the iron ligands are similar, Ac 1,2-CTD differs from 3,4-PCDs in that only one subunit is used to fashion each active-site cavity. In addition, a novel 'helical zipper', consisting of five N-terminal helices from each subunit, forms the molecular dimer axis. Two phospholipids were unexpectedly found to bind within an 8 x 35 A hydrophobic tunnel along this axis. CONCLUSIONS: The helical zipper domain of Ac 1, 2-CTD has no equivalent in other proteins of known structure. Sequence analysis suggests the domain is a common motif in all members of the 1,2-CTD family. Complexes with catechol and 4-methylcatechol are the highest resolution complex structures to date of an intradiol dioxygenase. Furthermore, they confirm several observations seen in 3,4-PCDs, including ligand displacement upon binding exogenous ligands. The structures presented here are the first of a new family of intradiol dioxygenases.     

Extradiol Cleavage of 3-Methylcatechol by Catechol 1,2-Dioxygenase from Various Microorganisms

The isofunctional enzymes of catechol 1,2-dioxygenase from species of Acinetobacter, Pseudomonas, Nocardia, Alcaligenes, and Corynebacterium oxidize 3-methylcatechol according to both the intradiol and extradiol cleavage patterns. However, the enzyme preparations from Brevibacterium and Arthrobacter have only the intradiol cleavage activity. Comparison of substrate specificity among these isofunctional dioxygenases shows striking differences in the oxidation of 3-methylcatechol, 4-methylcatechol and pyrogallol.