N-氨甲酰基-D-氨基酸酰胺水解酶的快速纯化及性质

通过硫酸铵分级沉淀、疏水层析及阴离子交换层析等三步 ,有效地从一菌株NO .2 2 6 2中纯化了N 氨甲酰基 D 氨基酸酰胺水解酶。结果表明 ,酶活性回收约 2 0 %,纯化了 8 4倍。天然PAGE与SDS PAGE分析表明 ,该酶分子为同源四聚体 ,单体分子量约为 3 5kD。酶催化反应的最适pH为 7 7～ 8 0 ,最适温度为 45℃。以N 氨甲酰 DL 丙氨酸为底物时 ,Km =1 3×1 0 - 3 mol L ,Vmax=0 .3 3mol min。二价金属离子Ni2 + 有激活作用 ,Zn2 + 有明显的抑制作用 ,而Co2 + 对酶活无影响。该酶N 末端 8个氨基酸残基依次为TRQKILAF。     

N-氨甲酰基-D-氨基酸酰胺水解酶的快速纯化及性质

通过硫酸铵分级沉淀、疏水层析及阴离子交换层析等三步 ,有效地从一菌株NO .2 2 6 2中纯化了N 氨甲酰基 D 氨基酸酰胺水解酶。结果表明 ,酶活性回收约 2 0 %,纯化了 8 4倍。天然PAGE与SDS PAGE分析表明 ,该酶分子为同源四聚体 ,单体分子量约为 3 5kD。酶催化反应的最适pH为 7 7～ 8 0 ,最适温度为 45℃。以N 氨甲酰 DL 丙氨酸为底物时 ,Km =1 3×1 0 - 3 mol L ,Vmax=0 .3 3mol min。二价金属离子Ni2 + 有激活作用 ,Zn2 + 有明显的抑制作用 ,而Co2 + 对酶活无影响。该酶N 末端 8个氨基酸残基依次为TRQKILAF。     

一步法发酵菊芋产乙醇菌种的筛选及产酶条件、酶学性质的研究

从腐烂的菊芋及实验室保存的菌种中,选育到一株发酵菊芋产乙醇的菌株克鲁维酵母Kluyveromyces marxianus Y1。利用正交实验法对克鲁维酵母产菊粉酶的培养基组成及培养条件进行优化,确定培养基组成（g/L）为：菊粉40,酵母粉4,蛋白胨4,尿素1;初始pH5．0,温度30℃,150r／min条件下培养达到最佳产酶效果（57U／mL）。该菌株所产菊粉酶的性质测定结果表明：以菊粉为底物,该菊粉酶最适反应温度为55℃,在60℃以下稳定性很好,高于60℃时酶迅速失活;最适pH为5．0,pH4．6—5．2范围内酶稳定性很好;该酶属于外切型菊粉酶,体积分数为8％的乙醇对酶活力基本没有影响。     

疏绵状嗜热丝孢菌热稳定几丁质酶的纯化及其性质研究

采用硫酸铵沉淀、DEAE SepharoseFastFlow阴离子层析、Phenyl Sepharose疏水层析等步骤获得了凝胶电泳均一的疏绵状嗜热丝孢菌 (Thermomyceslanuginosus)几丁质酶。经SDS PAGE和凝胶过滤层析测得纯酶蛋白的分子量在 4 8～ 4 9 .8kD之间。该酶反应的最适温度和最适pH分别为 5 5℃和 4 5 ,在pH4 5条件下 ,该酶在 5 0℃以下稳定 ;6 5℃的半衰期为 2 5min ;70℃保温 2 0min后 ,仍保留 2 4 %的酶活性。其N 端氨基酸序列为AQGYLSVQYFVNWAI。金属离子对几丁质酶的活性影响较大 ,Ca2 、Na 、K 、Ba2 对酶有激活作用 ;Ag 、Fe2 、Cu2 、Hg2 对酶有显著的抑制作用 ;以胶体几丁质为底物的Km 和Vmax值分别为 9 .5 6mg mL和 2 2 . 12 μmol min。抗菌活性显示 ,该酶对供试病原菌有不同程度的抑制作用。     

灰色链霉菌RX-17溶菌酶R2的纯化及其酶学鉴定

从灰色链霉菌 (Streptomycesgriseus)RX 1 7的发酵液中 ,通过硫酸铵分级沉淀 ,CM SephadexC 5 0和CM SepharoseFastFlow离子交换层析 ,纯化得到了溶菌酶R2 .该酶分子量约为 2 4 8kD ,等电点约为 9 7,N端 1 5个氨基酸的顺序为DTSGVQGIDVSHWQG .R2酶溶解变链球菌Ingbritt(StreptococcusmutansIngbritt)的最适作用温度为 5 5℃ ,最适pH为 7 0 .5 0℃处理 1h ,R2酶残存酶活74 % ,碱性条件 (pH >9)下该酶保持稳定 .Zn2 + 、Cu2 + 、Fe2 + 、Cd2 + 、Pb2 + 可使酶完全失活 ,螯合剂、盐酸羟胺、溴替丁二酰亚胺及离子型去垢剂SDS抑制R2酶的溶菌作用 ,而非离子型去垢剂TritonX 1 0 0等则能促进溶菌 .R2酶溶菌谱广泛 ,能够溶解多种鸡卵清溶菌酶不能作用的革兰氏阳性菌和革兰氏阴性菌 .从对金黄色葡萄球菌 (Staphylococcusaureus)的高活性来看 ,该酶应分类为 β 1 ,4 N ,6 O 二乙酰胞壁质酶 (β 1 ,4 N ,6 O diacetylmuramidase) .     

灵芝EIM-40漆酶的分离纯化及酶学性质

采用冻干浓缩、（NH4）2S04盐析、HiTrapphenyl（FF）疏水层析和QSepharose FastFlow离子交换层析对灵芝EIM-40发酵液进行分离纯化,获得纯化漆酶,纯化倍数为14．6,回收率为5．3％。SDS-PAGE银染的结果为单一条带,相对分子质量约为6．53×104。以愈创木酚和2,2-联氮-二（3-乙基-苯并噻唑-6-磺酸）二铵盐（ABTS）为催化底物进行酶学性质研究,最适pH分别为4．8和4．5,最适温度分别为55和50℃,2种底物在pH4．0。5．0范围内,温度低于50℃时,酶的稳定性都很好。以愈创木酚为底物,Km=645．0umol／L;以ABTS为底物,Km=22．2txmol／L。Cu2＋对该酶起激活作用,Fe2＋、Ca2＋、Ba2＋则完全抑制酶的活性。     

萌发绿豆种子中的一种大豆胰蛋白酶抑制剂钝化酶

通过 30 %～ 6 0 % (NH4 ) 2 SO4 分级沉淀、DEAE_SepharoseCL_6B离子交换层析、SephacrylS_2 0 0凝胶过滤层析和WatersAP_1离子交换层析 ,从萌发的绿豆 (Vignarabiata (L .)Wilczek)种子中分离纯化出一种可降解大豆胰蛋白酶抑制剂 (STI)的蛋白酶。SDS_PAGE测定该酶的分子量为 2 9.8kD。该酶催化降解STI的Km 值为 76 9.2BAEE/mL ,Vmax为 115 .3BAEE·mL-1·min-1。该酶在 5 0℃、pH 8.0、相对酶活力 5 0 0 0BAEE/mL和 4h的反应时间时可将脱脂大豆粉中的STI活性钝化 90 .91%。该酶在温度低于 5 0℃及pH 6 .5～ 8.5时能保持其活性。     

乳酸菌Enterococcuse faecalis TN-9低温蛋白酶的提纯及性质

对产自乳酸菌Enterococcuze fecalis TN-9的蛋白酶,进行了硫酸铵沉淀,DEAE—Sephadex A-25以及DEAE Cellulofine A-500离子交换层析的3步纯化和特性研究。纯化酶Native PAGE显示1条蛋白带。SDSPAGE和凝胶层析分子量分别为30ku及69ku。纯化酶最适作用温度为30℃,最适作用PH为7．5～8．0,在pH6．0～9．5和45℃以下条件下稳定,在0℃下显示了6．1％的相对活性,60℃以上热处理完全失去酶活。该酶被EDTA-2Na,Hg^2＋、Cu^2＋、Ni^2＋、Ag^2＋、Co^2＋及Pepstatin A不完全抑制。Zn^2＋对蛋白酶具有明显的激活作用。纯化酶作用于偶氮酪蛋白的Km和Vmax分别为0．098％和72mg／（h·mg）。该酶为N末端VGSEVTLKNS的明胶酶（Gelatinase）的一种,性质属于低温蛋白酶。     

极端嗜热古菌——芝田硫化叶菌DNA解旋酶的分离纯化和性质研究

采用Qsepharose离子交换层析、磷酸纤维素P1 1吸附层析、肝素琼脂糖吸附层析、Su perdex 2 0 0凝胶过滤和PhenylSuperose疏水层析等步骤 ,从嗜酸热芝田硫化叶菌细胞裂解液中分离纯化了一个DNA解旋酶。该解旋酶具有受DNA激活的ATP酶活性。根据SDS PAGE测定结果 ,该酶的分子质量约为 63kD。芝田硫化叶菌DNA解旋酶可以解开底物上 70bp的双链区 ,其解旋活性依赖于双链区旁的单链分叉。该解旋酶的活性依赖于Mg2 + 和ATP的水解 ,在NaCl浓度超过 2 0 0mmol L时受到抑制。该酶的最适pH为 6 7。该酶在 40℃～ 80℃之间均有活性 ,70℃时活性最高。芝田硫化叶菌DNA解旋酶是从古菌中分离得到的第一个天然DNA解旋酶。     

微生物酯酶拆分生物素手性中间体的初步研究

以镰刀霉菌 (Fusariumsp )ZG 2 3发酵的菌丝球做酶源 ,对生物素中间体内酯的溶解性做了研究 ,选取最适反应介质甲苯。酶水解反应条件研究表明 :该酶的最适反应温度为 45℃ ,最适反应pH为 7 0～ 7 5。在酶不对称水解生物素手性中间体内酯过程中 ,对甲苯溶液加酶量 5 0 0U ,底物浓度 2 %～ 5 %时 ,水解效果最好     

Purification and properties of a heat-stable exoinulinase isoform from Aspergillus fumigatus

An inducible extracellular exoinulinase (isoform II) was purified from the extracellular extract of Aspergillus fumigatus by ammonium sulphate precipitation, followed by successive chromatographies on DEAE-Sephacel, Octyl-Sepharose (HIC), Sephacryl S-200, affinity chromatography on ConA-CL Agarose and Sephacryl S-100 columns. The enzyme was purified 75-folds with 3.2% activity yield from the starting culture broth. The purified isoform II was a monomeric 62 kDa protein with a pI value of 4.5. The enzyme showed maximum activity at pH 6.0 and was stable over a pH range of 4.0-7.0, whereas the optimum temperature for enzyme activity was 60 degrees C. The inulinase isoform II showed exo-inulinolytic activity and retained 72% and 44% residual activity after 12 h at 60 degrees C and 70 degrees C, respectively. The inulin hydrolysis activity was completely abolished with 5 mM Hg2+ and Fe2+, whereas K+ and Cu2+ enhanced the inulinase activity. As compared to sucrose, stachyose and raffinose the purified enzyme had a lower Km (1.25 mM) and higher catalytic center activity (Kcat = 3.47 x 10(4) min(-1)) for inulin. As compared to exoinulinase isoform I of A. fumigatus, purified earlier, the isoform II is more thermostable and is a potential candidate for commercial production of fructose from inulin.     

Production of high-content inulo-oligosaccharides from inulin by a purified endoinulinase

Inulo-oligosaccharides were produced from inulin with high yield by using a purified endoinulinase from a commercial inulinase preparation. The maximum yield of oligosaccharide achieved was around 96% irrespective of substrate concentrations ranged from 50 to 150 g inulin/l. A wide range of degradation products from inulin, varying in their DP (degree of polymerization) 2 to 6, were obtained where the major oligosaccharides were DP3 and 4. The reaction pH gave rise to a significant difference in yield and sugar composition of inulo-oligosaccharides.     

Partial purification and characterization of exoinulinase from Kluyveromyces marxianus YS-1 for preparation of high-fructose syrup

An extracellular exoinulinase (2,1-beta-D fructan fructanohydrolase, EC 3.2.1.7), which catalyzes the hydrolysis of inulin into fructose and glucose, was purified 23.5-fold by ethanol precipitation, followed by Sephadex G-100 gel permeation from a cell-free extract of Kluyveromyces marxianus YS-1. The partially purified enzyme exhibited considerable activity between pH 5 to 6, with an optimum pH of 5.5, while it remained stable (100%) for 3 h at the optimum temperature of 50 degrees C. Mn2+ and Ca2+ produced a 2.4-fold and 1.2-fold enhancement in enzyme activity, whereas Hg2+ and Ag2+ completely inhibited the inulinase. A preparation of the partially purified enzyme effectively hydrolyzed inulin, sucrose, and raffinose, yet no activity was found with starch, lactose, and maltose. The enzyme preparation was then successfully used to hydrolyze pure inulin and raw inulin from Asparagus racemosus for the preparation of a high-fructose syrup. In a batch system, the exoinulinase hydrolyzed 84.8% of the pure inulin and 86.7% of the raw Asparagus racemosus inulin, where fructose represented 43.6 mg/ml and 41.3 mg/ml, respectively.     

黑曲霉菊糖酶的纯化及性质

黑曲霉(Aspergillus niger)319发酵液经硫酸铵分级沉淀、DEAE-纤维素52离子交换层析和Sephadex G-100分子筛层析,得到了电泳纯的菊糖酶组分。提纯倍数为67,收率为25.5％。菊糖酶的最适pH为5.0,最适温度为60℃。此酶为单亚基蛋白,凝胶过滤法测得分子量为28000,含糖13.9％,用等电聚焦法测得等电点为5.4,该酶对温度有较高的稳定性,对pH的稳定范围较窄。Hg²⁺、Pb²⁺和Cu²⁺对该酶有强烈的抑制作用。此酶对菊糖有较强的底物专一性,产物为果糖,但它也可作用于蔗糖,I/S值为0.348。当以菊糖为底物时,K_m为6.25mmol/L,V_m为67.11 μmol·mg~(-1)·min~(-1)。     

克鲁维酵母Y-85菊粉酶的纯化和性质

克鲁维酵母(Kluyveromyces sp.)Y-85产生的胞内菊粉酶(endocellular inulinase)和胞外菊粉酶(exocellular inulinase)粗酶液分别经PEG6000-磷酸盐缓冲液双水相抽提得部分纯化酶液。前者进一步用硫酸铵分级沉淀、Protein-PAK DEAE离子交换、Protein-PAK200SW凝胶过滤后得到两个菊粉酶组分EⅠ和EⅡ;后者采用DEAE-Sephacel离子交换、Sephadex G150凝胶过滤后得到菊粉酶Eexo。经Waters 650E蛋白纯化系统鉴定,三者均呈单一的对称峰;EⅠ和EⅡ达聚丙烯酰胺盘状凝胶电泳纯。EⅠ、EⅡ和Eexo的分子量分别为42kD、65kD和57kD;三者均为糖蛋白,多糖含量分别为30％、35％和25％;I/S(Inulinaseactivity/Sucrase activity)比值分别为0.086、0.078和0.072;三者均属外切菊粉酶。EⅠ、EⅡ和Eexo酶反应最适pH分别为4.6、4.5和4.6,最适温度分别为52℃、52℃和55℃;Ag^+、Hg^(2+)和PCMB对酶活性有强烈的抑制作用;三者水解菊芋粉糖液的产物均为果糖(86.5％)和葡萄糖(13.5％)。     

Purification and characterization of extracellular inulinase from a marine yeast <Emphasis Type="Italic">Pichia guilliermondii</Emphasis> and inulin hydrolysis by the purified inulinase

The extracellular inulinase of the marine yeast Pichia guilliermondii strain 1 was purified to homogeneity resulting in a 7.2-fold increase in specific inulinase activity. The molecular mass of the purified enzyme was estimated to be 50.0 kDa. The optimal pH and temperature for the purified enzyme were 6.0 and 60°C, respectively. The enzyme was activated by Mn²⁺, Ca²⁺, K⁺, Li⁺, Na⁺, Fe³⁺, Fe²⁺, Cu²⁺, and Co²⁺, but Mg²⁺, Hg²⁺, and Ag⁺ inhibited activity. The enzyme was strongly inhibited by phenylmethanesulphonyl fluoride (PMSF), iodoacetic acid, EDTA, and 1, 10-phenanthroline. The K _m and V _max values of the purified inulinase for inulin were 21.1 mg/mL and 0.08 mg/min, respectively. A large number of monosaccharides were detected after the hydrolysis of inulin. The deduced protein sequence from the cloned P. guilliermondii strain 1 inulinase gene contained the consensus motifs R-D-P-K-V-F-W-H and W-M-N-D-P-N-G, which are conserved among the inulinases from other microorganisms.     

Continuous production of fructose-syrups from inulin by immobilized inulinase from recombinantSaccharomyces cerevisiae

Recombinant exoinulinase was partially purified from the culture supernatant ofS. cerevisiae by (NH₄)₂SO₄ precipitation and PEG treatment. The purified inulinase was immobilized onto Amino-cellulofine with glutaraldehyde as a cross-linking agent. Immobilization yield based on the enzyme activity was about 15%. Optimal pH and temperature of immobilized enzyme were found to be 5.0 and 60°C, respectively. The enzyme activity was stably maintained in the pH ranges of 4.5 to 6.0 at 60°C. 100% of enzyme activity was observed even after incubation for 24 hr at 60°C. In the operation of a packed-bed reactor containing 412 U inulinase, dahalia inulin of 7.5%(w/v) concentration was completely hydrolyzed at flow rate of 2.0 mL/min at 60°C, resulting in a volumetric productivity of 693 g-reducing sugars/L/h. Under the reaction conditions of 1.0 mL/min flow rate with 2.5% inulin at 60°C, the reactor was successfully operated over 30 days without loss of inulinase activity.     

Purification and some important characters of extracellular inulinase of Alternaria alternata (Fr.) Keissler

Protein precipitate of cell-free dialysate of extracellular inulinase (2,1-beta-fructan fructanohydrolase, EC 3.2.1.7) of A. alternata was maximally obtained by methanol. Such protein was fractionated by using 2-step column chromatography on Sephadex G150 and DEAE-cellulose. The partially purified enzyme had activity of 81 x 10(3) U/mg protein, with a yield of 69% of the original activity and the fold of purification was 62. Optimum temperature and pH for the activity of the purified enzyme were found to be 55 degrees C and 4.5, respectively. The enzyme was found to be stable up to 55 degrees C and in pH range of 4 to 5. Ba2+ and Ca2+ were found to stimulate the enzyme activity while Cu2+, Fe3+, Hg2+, and iodoacetate were recorded as strong inhibitors. T(1/2) of the enzyme was estimated to be two weeks and its apparent Km was calculated to be 0.066 M. The enzyme recorded hydrolyzing activity against sucrose and raffinose recording I/S ratio of 0.50. Molecular mass of the enzyme preparation was estimated by gel filtration and found to be 115 +/- 5 kDa.     

Purification and characterisation of an extracellular fructan beta-fructosidase from a Lactobacillus pentosus strain isolated from fermented fish

Lactobacillus pentosus B235, which was isolated as part of the dominant microflora from a garlic containing fermented fish product, was grown in a chemically defined medium with inulin as the sole carbohydrate source. An extracellular fructan beta-fructosidase was purified to homogeneity from the bacterial supernatant by ultrafiltration, anion exchange chromatography and hydrophobic interaction chromatography. The molecular weight of the enzyme was estimated to be approximately 126 kDa by gel filtration and by SDS-PAGE. The purified enzyme had the highest activity for levan (a beta(2-->6)-linked fructan), but also hydrolysed garlic extract, (a beta(2-->1)-linked fructan with beta(2-->6)-linked fructosyl sidechains), 1,1,1-kestose, 1,1-kestose, 1-kestose, inulin (beta(2-->1)-linked fructans) and sucrose at 60, 45, 39, 12, 9 and 3%, respectively, of the activity observed for levan. Melezitose, raffinose and stachyose were not hydrolysed by the enzyme. The fructan beta-fructosidase was inhibited by p-chloromercuribenzoate, EDTA, Fe2+, Cu2+, Zn2+ and Co2+, whereas Mn2+ and Cu2+ had no effect. The sequence of the first 20 N-terminal amino acids was: Ala-Thr-Ser-Ala-Ser-Ser-Ser-Gln-Ile-Ser-Gln-Asn-Asn-Thr-Gln-Thr-Ser-Asp-Val-Val. The enzyme had temperature and pH optima at 25 degrees C and 5.5, respectively. At concentrations of up to 12% NaCl no adverse effect on the enzyme activity was observed.     

Purification and some properties of endoinulinase from Chrysosporium pannorum

One endoinulinase (2,1-β-d-fructan fructanohydrolase EC 3.2.1.7) was purified from Chrysosporium pannorum AHU 9700. The enzyme was a glycoprotein having an isoelectric point around pH 3.8. The molecular weight was 58,000 and 56,000 by SDS-polyacrylamide gel electrophoresis and gel filtration on Sephacryl S-200, respectively. The endoinulinase was most active between pH 6.0–7.0 at 50°C, and was stable at 45°C (10 min) and from pH 4.5 to 8.5 (24 h). This enzyme was active only on inulin, not on levan, sucrose, raffinose, or melezitose. The main products from inulin were inulotriose, inulotetraose, and inulopentaose.