环酰亚胺水解酶C末端区为该酶活性所必需

 为了研究一个新环酰亚胺水解酶（CIH）C端区残基对酶分子构象及酶活性的影响,设计了C末端缺失1～4个氨基酸残基以及C 末端2个Lys替代为2个Glu或2个Leu的突变酶,以野生型酶基因重组质粒pE-cih₂₉₃为模板,在相应引物存在下,通过PCR扩增获得突变的CIH基因片段.经克隆、表达与纯化,得到不同的突变酶蛋白.酶活性测定、荧光光谱与CD谱分析表明,随着C 末端缺失残基的增多,酶活性丧失也越来越多,但酶分子的聚合状态未发生变化;当CIH的C末端2个Lys替代为2个Glu时,酶活性及分子结构变化均不明显,但当替代为2个Leu时,酶活性丧失殆尽,分子结构变得松散而不再保持寡聚态.pH及热稳定性实验也表明,酶的稳定性与其分子的完整性密切相关.结果证实,CIH的C末端电荷残基对该酶活性与分子状态具有重要作用.     

假单胞菌YZ-26来源环酰亚胺水解酶中半胱氨酸残基的反应性能

【目的】研究环酰亚胺水解酶(Imidase,CIH)中的两个半胱氨酸残基的反应性及功能。【方法】设计了3个半胱氨酸突变酶:CIH7,108、CIH7、CIH108。将天然酶以及突变酶基因分别与麦芽糖结合蛋白(MBP)基因在大肠杆菌(Escherichia coli)中进行融合表达,融合蛋白经纯化后得到了电泳纯的样品。使用5,5’-二硫代双(2-硝基苯甲酸)(DTNB)对天然酶CIH的巯基基团进行修饰,并分析了DTT对分子状态的影响。进一步研究了经H2O2处理后CIH及其突变酶的锌离子结合能力及分子状态。【结果】酶活测定表明CIH7,108和CIH7的活力基本丧失,而CIH108仍保持了72%的酶活性。CIH中的两个半胱氨酸残基以游离形式存在,不形成链内或链间二硫键。CIH与CIH108为四聚体结构且具有一定的锌离子结合能力,CIH7,108为多聚体,CIH7为单体及多体的混合物且都不具备锌离子结合能力,随着H2O2浓度的增加,CIH中的链内二硫键及CIH108中的链间二硫键逐渐增加。【结论】说明Cys7是结合锌离子和稳定CIH分子结构的必要残基。     

C-末端残基Arg缺失的D-海因酶的分子形式与稳定性

报道D-海因酶分子C-末端Arg残基的缺失,导致酶的解聚与稳定性的显著改变。用基因克隆、表达与纯化的方法,制备了重组D-海因酶(P479)及其C-末端残基Arg缺失的D-海因酶(P478)。SDS-PAGE和Native-PAGE分析表明,在完全相同的条件下,两者单体的分子量相同;但天然P479为二聚体,而P478为单体并保持约40%催化底物海因的活性。突变酶P478的pH值稳定性显著增加,抗SDS能力亦有所提高,但热稳定性明显降低。结果预示:D-海因酶的C-末端残基Arg显著影响酶的分子形式及热稳定性,虽也影响酶活性,但非酶活性所必需。     

Arthrobacter K1108乙内酰脲酶反应条件和立体选择性研究

研究了Arthrobacter K1108乙内酰脲酶的反应条件,结果表明,K1108乙内酰脲酶的最适反应温度为55℃,最适pH为7.0,Co^2 和Fe^2 对该酶有激活作用,而Ca^2 有严重抑制作用。K1108乙内酰脲酶的底物专一性较强,其最适底物为5－苄基乙内酰脲,5－苯基乙内酰脲和5－吲哚甲基乙内酰脲均不能作为其有效底物。对K1108乙内酰脲酶立体反应机制研究结果表明,其乙内酰脲水解酶不具立体选择性,决定产物立体构型的酶是N－氨甲酰氨基酸水解酶。     

纤维素酶的底物专一性

天然纤维素的有效酶解取决于外切葡聚糖纤维二糖水解酶（ＣＢＨ）和内切葡聚糖水解酶（ＥＧ）的协同作用。ＥＧ随机水解纤维素无定形区分子链内的β－１,４－糖苷键;ＣＢＨ则由分子链的还原性末端水解出纤维二糖。这种底物专一性差别的原因在于ＣＢＨ呈“桶状”的活性部痊表面存在２个“ｌｏｏｐ”结构,只能容许纤维素分子链的末端伸入到活性裂隙中。ＥＧ无“ｌｏｏｐ”结构在存在,对底物是充分可及的。ＥＧ催化结构域中底物结合     

Arthrobacter K1108乙内酰脲酶反应条件和立体选择性研究

研究了ArthrobacterK110 8乙内酰脲酶的反应条件 ,结果表明 ,K1108乙内酰脲酶的最适反应温度为 55℃ ,最适pH为 70 ,Co²⁺ 和Fe²⁺ 对该酶有激活作用 ,而Ca²⁺ 有严重抑制作用。K1108乙内酰脲酶的底物专一性较强 ,其最适底物为 5 苄基乙内酰脲 ,5 苯基乙内酰脲和 5 吲哚甲基乙内酰脲均不能作为其有效底物。对K1108乙内酰脲酶立体反应机制研究结果表明 ,其乙内酰脲水解酶不具立体选择性 ,决定产物立体构型的酶是N 氨甲酰氨基酸水解酶。     

大肠杆菌CMP-唾液酸合成酶最小活性域的研究

比较大肠杆菌与脑膜炎奈瑟氏球菌的CMP-唾液酸合成酶的氨基酸序列,发现大肠杆菌CMP-唾液酸合成酶的保守区域主要位于N-端,其C-末端似乎对其催化活性没有作用。通过PCR方法,对大肠杆菌CMP唾液酸合成酶的C-末端进行了一系列截短,将得到的产物连接至表达载体pET-15b中,在大肠杆菌BL21(DE3)pLysS中表达。经IPTG诱导,发现从C-末端截去189个氨基酸酶仍有催化活性,说明大肠杆菌CMP唾液酸合成酶的最小活性域主要集中在N-末端的229个氨基酸。有催化活性的C-端缺失突变合成酶的比活、最适pH及热稳定性发生变化,提示被截去的C-端氨基酸残基虽不直接参与构成酶的催化活性中心,但可影响催化活性域的构象,从而对酶的催化活性与稳定性产生影响。      

黑曲霉硫氧还蛋白的克隆表达纯化及其酶活位点特征分析

首次从黑曲霉Aspergillus niger全基因组中克隆出黑曲霉硫氧还原蛋白基因AnTrx,并对其编码蛋白的第33-37位保守区的活性位点实施定点突变C34S、C37S及C34S-C37S,获得相应的3个定点突变基因。将野生型AnTrx及其突变子分别在大肠杆菌Escherichia coli中诱导表达,比浊法测定纯化的各表达产物还原牛胰岛素α与β链之间二硫键的活性。结果表明,AnTrx的3个突变体都不表现明显催化活性。当突变型与野生型AnTrx等量混合后,发现突变型AnTrx-C34S可显著提高野生型AnTrx的催化效率,而突变型AnTrx-C37S却无此功能。由此证明,AnTrx活性结构域的第37位Cys残基上的巯基能参与攻击硫氧还蛋白和底物蛋白所形成的二硫键而释放被还原的底物蛋白,而第34位Cys残基同其他微生物的同一活性域一样参与硫氧化还蛋白与底物的结合。这一结果有助于认识真菌硫氧还蛋白第37位活性位点的作用。     

亚位点+1处突变提高软化类芽胞杆菌环糊精糖基转移酶底物麦芽糊精特异性

通过改造来源于软化类芽胞杆菌Paenibacillus macerans的环糊精糖基转移酶(Cyclodextrin glycosyltransferase,CGT酶)的+1亚位点提高其对麦芽糊精的底物特异性,并进一步提高以麦芽糊精为糖基供体催化合成2-O-D-吡喃葡糖基-L-抗坏血酸(AA-2G)的效率。首先对+1亚位点附近的3个氨基酸残基Leu194、Ala230和His233分别进行定点饱和突变,得到3个优势突变体L194N(亮氨酸→天冬酰胺),A230D(丙氨酸→天冬氨酸),H233E(组氨酸→谷氨酸),然后以这3个优势突变体为模板进一步进行两点和三点复合突变,获得7个复合突变体。研究结果表明,突变体L194N/A230D/H233E以麦芽糊精为底物合成AA-2G的产量最高,达到1.95 g/L,比野生型CGT酶提高了62.5%。对获得的突变体进行动力学分析,发现高浓度的底物L-AA对突变型CGT酶催化的酶促反应具有抑制作用。确定了突变体酶促反应的最适温度、pH和反应时间。模拟突变体的三维结构并进行分析,突变体底物特异性的改善可能与CGT酶第194位、230位和233位的氨基酸残基的亲水性及与底物分子间的作用力的改变有关。     

定点突变对酰胺水解酶DamH可溶性表达和酶活的影响

摘要:【目的】DamH是一种具有酯酶活性的酰胺水解酶,其非活性中心氨基酸残基的突变对重组酶可溶性表达和比酶活产生一定的影响。拟探索DamH的活性中心氨基酸残基构成,并对其非活性中心氨基酸残基突变对可溶性表达和比酶活的影响进行研究。【方法】通过重叠延伸的方法对DamH可能的活性中心氨基酸S149、E244和H274以及非活性中心氨基酸D165及N192进行定点突变,通过静息细胞测活验证了S149、E244和H274 在催化2-氯-N-(2’-甲基-6’-乙基苯基)乙酰胺(CMEPA)水解反应中的作用,通过Ni2+- NTA亲和层析对D165及N192突变子进行纯化,对突变株和野生型比酶活进行比较。【结果】研究表明S149A使DamH的CMEPA 水解酶活性下降为野生型的5%,E244A和H274A突变导致其失去活性;D165P和N192P突变影响到DamH的可溶性表达,表达量分别为野生型的28.2%和20.8%,突变子N192P、D165P比酶活分别为野生型比酶活的55.5%和49.7%。【结论】DamH催化酯类底物和芳基酰胺类底物可能共用同一活性中心S149、E244和H274,其两个α螺旋的转角处氨基酸侧链极性和刚性结构的改变对可溶性表达以及活性有很大的影响。     

唾液乳杆菌BSH1及其突变体的底物特异性

为了解析胆盐水解酶催化中心中关键氨基酸位点与其底物特异性的关系,以大肠杆菌pET-20b(+)表达系统为分子改造平台,采用理性设计,结合氨基酸定点突变的方法,成功构建了唾液乳杆菌Lactobacillus salivarius胆盐水解酶BSH1的7种突变体。通过对比L.salivarius BSH1及其突变体对6种结合胆盐的底物特异性表明,7种突变体对不同的结合胆盐的水解活性有所改变。结果说明,Cys2和Thr264分别是BSH1催化TCA和GCA的关键残基,且对酶的催化活性的保持具有关键作用。其中,高保守性的氨基酸位点Cys2不是BSH1唯一的活性位点,而其他突变的氨基酸位点可能作为BSH1的结合位点参与了底物的结合,也可能影响了底物进入BSH1活性中心的通道或底物结合口袋的体积与形状,进而影响了BSH1对不同结合胆盐的水解活性。     

Comparative structural analysis and substrate specificity engineering of the hyperthermostable beta-glucosidase CelB from Pyrococcus furiosus

The substrate specificity of the beta-glucosidase (CelB) from the hyperthermophilic archaeon Pyrococcus furiosus, a family 1 glycosyl hydrolase, has been studied at a molecular level. Following crystallization and X-ray diffraction of this enzyme, a 3.3 A resolution structural model has been obtained by molecular replacement. CelB shows a homo-tetramer configuration, with subunits having a typical (betaalpha)(8)-barrel fold. Its active site has been compared to the one of the previously determined 6-phospho-beta-glycosidase (LacG) from the mesophilic bacterium Lactococcus lactis. The overall design of the substrate binding pocket is very well conserved, with the exception of three residues that have been identified as a phosphate binding site in LacG. To verify the structural model and alter its substrate specificity, these three residues have been introduced at the corresponding positions in CelB (E417S, M424K, F426Y) in different combinations: single, double, and triple mutants. Characterization of the purified mutant CelB enzyme revealed that F426Y resulted in an increased affinity for galactosides, whereas M424K gave rise to a shifted pH optimum (from 5.0 to 6.0). Analysis of E417S revealed a 5-fold and a 3-fold increase of the efficiency of hydrolyzing o-nitrophenol-beta-D-galactopyranoside-6-phosphate, in the single and triple mutants, respectively. In contrast, their activity on nonphosphorylated sugars was largely reduced (30-300-fold). The residue at position E417 in CelB seems to be the determining factor for the difference in substrate specificity between the two types of family 1 glycosidases.     

Identification of the substrate specificity-conferring amino acid residues of 4-coumarate:coenzyme A ligase allows the rational design of mutant enzymes with new catalytic properties

4-Coumarate:coenzyme A ligases (4CLs) generally use, in addition to coumarate, caffeate and ferulate as their main substrates. However, the recently cloned Arabidopsis thaliana isoform At4CL2 is exceptional because it has no appreciable activity with ferulate. On the basis of information obtained from the crystal structure of the phenylalanine-activating domain of gramicidin S-synthetase, 10 amino acid residues were identified that may form the substrate binding pocket of 4CL. Among these amino acids, representing the putative "substrate specificity motif," only one residue, Met(293), was not conserved in At4CL2, compared with At4CL1 and At4CL3, two isoforms using ferulate. Substitution of Met(293) or Lys(320), another residue of the putative substrate specificity motif, which in the predicted three-dimensional structure is located in close proximity to Met(293), by smaller amino acids converted At4CL2 to an enzyme capable of using ferulate. The activity with caffeate was not or only moderately affected. Conversely, substitution of Met(293) by bulky aromatic amino acids increased the apparent affinity (K(m)) for caffeate up to 10-fold, whereas single substitutions of Val(294) did not affect substrate use. The results support our structural assumptions and suggest that the amino acid residues 293 and 320 of At4CL2 directly interact with the 3-methoxy group of the phenolic substrate and therefore allow a first insight into the structural principles determining substrate specificity of 4CL.     

His-404 and His-405 are essential for enzyme catalytic activities of a bacterial indole-3-acetyl-L-aspartic acid hydrolase

Bacterial indole-3-acetyl-l-aspartic acid (IAA-Asp) hydrolase has shown very high substrate specificity compared with similar IAA-amino acid hydrolase enzymes found in Arabidopsis thaliana. The IAA-Asp hydrolase also exhibits, relative to the Arabidopsis thaliana-derived enzymes, a very high Vmax (fast reaction rate) and a higher Km (lower substrate affinity). These two characteristics indicate that there are fundamental differences in the catalytic activity between this bacterial enzyme and the Arabidopsis enzymes. By employing a computer simulation approach, a catalytic residue, His-385, from a non-sequence-related zinc-dependent exopeptidase of Pseudomonas was found to structurally match His-405 of IAA-Asp hydrolase. The His-405 residue is conserved in all related sequences of bacteria and Arabidopsis. Point mutation experiments of this His-405 to seven different amino acids resulted in complete elimination of enzyme activity. However, point mutation on the neighboring His-404 to eight other residues resulted in reduction, to various degrees, of enzyme activity. Amino acid substitutions for His-404 also showed that this residue influenced the minor activity of the IAA-Asp hydrolase for the substrates IAA-Gly, IAA-Ala, IAA-Ser, IAA-Glu and IAA-Asn. These results show the value and potential of structural modeling for predicting target residues for further study and for directing bioengineering of enzyme structure and function.     

Mutations in the substrate binding site of thrombin-activatable fibrinolysis inhibitor (TAFI) alter its substrate specificity

Thrombin-activable fibrinolysis inhibitor (TAFI) is a zymogen that inhibits the amplification of plasmin production when converted to its active form (TAFIa). TAFI is structurally very similar to pancreatic procarboxypeptidase B. TAFI also shares high homology in zinc binding and catalytic sites with the second basic carboxypeptidase present in plasma, carboxypeptidase N. We investigated the effects of altering residues involved in substrate specificity to understand how they contribute to the enzymatic differences between TAFI and carboxypeptidase N. We expressed wild type TAFI and binding site mutants in 293 cells. Recombinant proteins were purified and characterized for their activation and enzymatic activity as well as functional activity. Although the thrombin/thrombomodulin complex activated all the mutants, carboxypeptidase B activity of the activated mutants against hippuryl-arginine was reduced. Potato carboxypeptidase inhibitor inhibited the residual activity of the mutants. The functional activity of the mutants in a plasma clot lysis assay correlated with their chromogenic activity. The effect of the mutations on other substrates depended on the particular mutation, with some of the mutants possessing more activity against hippuryl-His-leucine than wild type TAFIa. Thus mutations in residues around the substrate binding site of TAFI resulted in altered C-terminal substrate specificity.     

The presence of acyl-CoA hydrolase in rat brown-adipose-tissue peroxisomes.

The subcellular distribution of acyl-CoA hydrolase was studied in rat brown adipose tissue, with special emphasis on possible peroxisomal localization. Subcellular fractionation by sucrose-density-gradient centrifugation, followed by measurement of short-chain (propionyl-CoA) acyl-CoA hydrolase in the presence of NADH, resulted in two peaks of activity in the gradient: one peak corresponded to the distribution of cytochrome oxidase (mitochondrial marker enzyme), and another peak of activity coincided with the peroxisomal marker enzyme catalase. The distribution of the NADH-inhibited short-chain hydrolase activity fully resembled that of cytochrome oxidase. The substrate-specificity curve of the peroxisomal acyl-CoA hydrolase activity indicated the presence of a single enzyme exhibiting a broad substrate specificity, with maximal activity towards fatty acids with chain lengths of 3-12 carbon atoms. The mitochondrial acyl-CoA hydrolase substrate specificity, in contrast, indicated the presence of at least two acyl-CoA hydrolases (of short- and medium-chain-length specificity). The peroxisomal acyl-CoA hydrolase activity was inhibited by CoA at low (microM) concentrations and by ATP at high concentrations (greater than 0.8 mM). In contrast with the mitochondrial short-chain hydrolase, the peroxisomal acyl-CoA hydrolase activity was not inhibited by NADH.     

S1 site residues of Lactococcus lactis prolidase affect substrate specificity and allosteric behaviour

Lactococcus lactis prolidase preferably hydrolyzes Xaa-Pro dipeptides where Xaa is a hydrophobic amino acid. Anionic Glu-Pro and Asp-Pro dipeptides cannot be hydrolyzed at any observable rates and the hydrolysis of cationic Arg-Pro and Lys-Pro dipeptides is at about one tenth of the rate of Leu-Pro. It was hypothesized that the hydrophobic residues in the S₁ site were responsible for this substrate specificity, thus the residues in the S₁ site were substituted with hydrophilic residues. The substitution of Leu193 and Val302 revealed that these residues influenced the substrate specificity. The introduction of a cationic residue, L193R, allowed Asp-Pro to be utilized as a substrate at 37.0% of the rate of Leu-Pro, and the anionic mutation, V302D, yielded mutants that could hydrolyze Asp-Pro, Arg-Pro and Lys-Pro at 25.9 to 57.4% rates. Interestingly, these mutants of S₁ site residues eliminated the allosteric behaviour of L. lactis prolidase that makes this enzyme unique among known prolidases. Results of pH dependency, thermal dependency, and molecular modelling suggested that these observed changes were due to the alteration of the interactions among catalytic zinc cations, Arg293, His296, and the mutated residues.     

The structural basis of substrate recognition in an exo-beta-D-glucosaminidase involved in chitosan hydrolysis

Family 2 of the glycoside hydrolase classification is one of the largest families. Structurally characterized members of this family include enzymes with β-galactosidase activity (Escherichia coli LacZ), β-glucuronidase activity (Homo sapiens GusB), and β-mannosidase activity (Bacteroides thetaiotaomicron BtMan2A). Here, we describe the structure of a family 2 glycoside hydrolase, CsxA, from Amycolatopsis orientalis that has exo-β-d-glucosaminidase (exo-chitosanase) activity. Analysis of a product complex (1.85 Å resolution) reveals a unique negatively charged pocket that specifically accommodates the nitrogen of nonreducing end glucosamine residues, allowing this enzyme to discriminate between glucose and glucosamine. This also provides structural evidence for the role of E541 as the catalytic nucleophile and D469 as the catalytic acid/base. The structures of an E541A mutant in complex with a natural β-1,4-d-glucosamine tetrasaccharide substrate and both E541A and D469A mutants in complex with a pNP-β-d-glucosaminide synthetic substrate provide insight into interactions in the + 1 subsite of this enzyme. Overall, a comparison with the active sites of other GH2 enzymes highlights the unique architecture of the CsxA active site, which imparts specificity for its cationic substrate.     

Identification of the enzymatic active site of CD38 by site-directed mutagenesis

CD38 is a ubiquitous protein originally identified as a lymphocyte antigen and recently also found to be a multifunctional enzyme participating in the synthesis and metabolism of two Ca(2+) messengers, cyclic ADP-ribose (cADPR) and nicotinic acid adenine dinucleotide phosphate. It is homologous to Aplysia ADP-ribosyl cyclase, where the crystal structure has been determined. Residues of CD38 corresponding to those at the active site of the Aplysia cyclase were mutagenized. Changing Glu-226, which corresponded to the catalytic residue of the cyclase, to Asp, Asn, Gln, Leu, or Gly eliminated essentially all enzymatic activities of CD38, indicating it is most likely the catalytic residue. Photoaffinity labeling showed that E226G, nevertheless, retained substantial NAD binding activity. The secondary structures of these inactive mutants as measured by circular dichroism were essentially unperturbed as compared with the wild type. Other nearby residues were also investigated. The mutants D147V and E146L showed 7- and 19-fold reduction in NADase activity, respectively. The cADPR hydrolase activity of the two mutants was similarly reduced. Asp-155, on the other hand, was crucial for the GDP-ribosyl cyclase activity since its substitution with either Glu, Asn, or Gln stimulated the activity 3-15-fold, whereas other activities remained essentially unchanged. In addition to these acidic residues, two tryptophans were also important, since all enzyme activities of W125F, W125Y, W189G and W189Y were substantially reduced. This is consistent with the two tryptophans serving a substrate positioning function. A good correlation was observed when the NADase activity of all the mutants was plotted against the cADPR hydrolase activity. Homology modeling revealed all these critical residues are clustered in a pocket near the center of the CD38 molecule. The results indicate a strong structural homology between the active sites of CD38 and the Aplysia cyclase.