Synthesis and catalytic kinetics of tellurium-modified hyaluronic acid with glutathione peroxidase activity

A novel mimic TeHA was synthesized by modifying hyaluronic acid (HA) with tellurium, whose function is similar to that of glutathione peroxidase (GPX). The structure of TeHA was characterized by means of infrared spectroscopy and nuclear magnetic resonance spectroscopy, showing that the target Te is located at -CH2OH of the N-acetyl-D-glucosamine of HA. The activity of TeHA is 163.6 U/mu mol according to Wilson's method. In contrast to other mimics, TeHA displays a high activity. Moreover, TeHA can use many hydroperoxides as substrates, such as H2O2, cumenyl hydroperoxide, and tert-butyl hydroperoxide, and cumenyl hydroperoxide is the optimal substrate. A ping-pong mechanism was deduced for the reduction reactions catalyzed by TeHA according to the steady-state kinetic studies.

Synthesis and kinetics of a novel mimic with glutathione peroxidase activity - Tellurium-containing hyaluronic acid (TeHA)

A novel mimic was synthesized by modifying hyaluronic acid (HA) with tellurium, whose function is similar to that of glutathione peroxidase (GPX). The structure of TeHA was characterized by means of IR and NMR, the target-Te was located at -CH2OH of the N-acetyl-D-glucosamine of HA. The H2O2 reducing activity of TeHA, by glutathione (GSH), was 163.6 U/mu mol according to Wilson's method. In contrast to other mimics, TeHA displayed the highest activity. Moreover, TeHA accepted many hydroperoxides as its substrates, such as H2O2, cumenyl hydroperoxide (CuOOH) and tert-butyl hydroperoxide (t-BuOOH), and CuOOH was the optimal substrate of TeHA. A ping-pong mechanism was observed in the steady-state kinetic studies of the reactions catalyzed by TeHA.

Effect of lanthanum ion on peroxidase in plant

The interaction of MP-11 as a model of antioxidatase enzymes with La3+ was investigated. It was found that La3+ can increase in the non-planarity of heme and the content of alpha helix and beta turn conformations of the MP11 molecule. The change in the secondary structure of the MP-11 molecule can increase in the exposure extent of heme to the solution. Therefore, the electrochemical reaction of MP-11 is promoted and the electrocatalytic activity to the reduction of H2O2 is increased. The results are consistent with that for the interaction of peroxidases(POD), one of the antioxidatase enzymes, obtained in the living plant experiments at low concentration of La3+.

Studies of soluble human catalytic antibody with glutathione peroxidase activity

By screening the phage-displayed human single chain antibody library, we have got the specific single chain antibody bound to GSH-S-DNP butyl ester as the hapten. The tertiary structure of the protein was analyzed with the aid of computer, and the results showed the CDR3 region located on the surface of the antibody. The soluble antibody was expressed in E. coli. and the active site serine was converted into selenocysteine with the chemical modifying method, which resulted in the catalytic antibody with GPx activity of 80 U/mu mol. Furthermore, the same Ping-Pong mechanism as the natural GPx was observed when the kinetic behavior of the antibody was studied.

Human catalytic antibodies with glutathione peroxidase activity

In order to generate catalytic antibodies with glutathione peroxidase (GPx) activity, we prepared GSH-S-DNP butyl ester and GSH-S-DNP benzyl ester as the haptens. Two ScFvs that bound specifically to the haptens were selected from the human phage-displayed antibody library. The two ScFv genes were highly homologous, consisting of 786 bps and belonging to the same VH family-DP25. In the premise of maintaining the amino acid sequence, mutated plasmids were constructed by use of the mutated primers in PCR, and they were over-expressed in E. coli. After the active site serine was converted into selenocysteine with the chemical modifying method, we obtained two human catalytic antibodies with GPx activity of 72.2U/mu mol and 28.8U/mu mol, respectively. With the aid of computer mimicking, it can be assumed that the antibodies can form dimers and the mutated selenocysteine residue is located in the binding site. Furthermore, the same Ping-Pong mechanism as the natural GPx was observed when the kinetic behavior of the antibody with the higher activity was studied. (C) 2001 Elsevier Science BY. All rights reserved.

A selenium-containing abzyme, the activity of which surpassed the level of native glutathione peroxidase

Using two different glutathione derivatives as hapten, we have prepared two abzymes, which display glutathione peroxidase (GPX) activity. Their GPX activities are 0.2 and 1.6 times that of natural GPX from rabbit liver, respectively. Selenium content analysis indicates that the activity difference between the two abzymes is possibly attributed to the conformation difference of the abzymes.

Hydrophobic pocket modification and humanized catalytic antibodies with glutathione peroxidase activity (I) - Preparation and characterization of haptenes and conjugates

The thiol group of glutathione (GSH) was protected by 2,4-dinitrochlorobenzene (DNCB), the product S-substituted dinitrophenyl GSH(GSH-S-DNP) was alcoholized to obtain haptenes 4 and 5 respectively. As haptenes, the two GSH derivatives were characterized by means of H-1 NMR, MALDI-TOF-MS and IR, followed by individually coupling with bovine serum albumin (BSA) via glutaraldehyde. BSB-Hp4 and BSA-Hp5 were purified by Sephadex G-25 gel filtration chromatography. For each conjugate, the average haptene-BSA ratio was 12 : 1. The electrophoresis analysis showed that the average molecular weight of each conjugate was 76 500. The CD spectrum indicated that the conjugates had more a-helix content than BSA did.

Biochemical characterization of selenium-containing catalytic antibody as a cytosolic glutathione peroxidase mimic

A selenium-containing catalytic antibody (Se-4A4), prepared by converting reactive serine residues of a monoclonal antibody (4A4) raised against a GSH derivative into selenocysteines, acts as a mimic of cytosolic glutathione peroxidase (cGPX). To clarify the mechanism of action of this catalytic antibody, detailed studies on kinetic behaviour and biological activity were carried out. A rate of acceleration (k(cat)/K-m/k(uncat)) 10(7)-fold that of the uncatalytic reaction is observed. Under similar conditions, the turnover number (k(cat)) of Se-4A4 is 42% of that of the natural rabbit liver cGPX. The Se-4A4 reaction involves a Ping Pong mechanism, which is the same as that of the natural cGPX. The selenocysteine residue is located in the binding site of the antibody and is shown to be crucial for this activity. Of the thiol compounds tested, only GSH is able to serve as substrate for Se-4A4. It was demonstrated, using the free-radical-damage system (hypoxanthine/xanthine oxidase) of cardiac mitochondria, that Se-4A4 can protect mitochondria from free-radical damage at least 10(4)-fold more effectively than the natural cGPX.

cDNA cloning and mRNA expression of a selenium-dependent glutathione peroxidase from Zhikong scallop Chlamys farreri

The glutathione peroxidases are essential enzymes of the cellular antioxidant defence system. In the present study, the full-length cDNA sequence encoding an extracellular glutathione peroxidase (designated CfGPx3) was isolated from Zhikong scallop Chlamys farreri. The complete cDNA was of 1194 bp, containing a 5' untranslated region (UTR) of 50 bp, a 3' UTR of 490 bp and an open reading frame (ORF) of 654 bp encoding a polypeptide of 217 amino acids. CfGPx3 possessed all the conserved features critical for the fundamental structure and function of glutathione peroxidase, such as the selenocysteine encoded by stop codon UGA, the GPx signature motif ((96)LGVPCNQFI(103)) and the active site motif ((WNFEKF184)-W-179). The high similarity of CfGPx3 with GPx from other organisms indicated that CfGPx3 should be a new member of the glutathione peroxidase family. By fluorescent quantitative real-time PCR, the CfGPx3 mRNA was universally detected in the tissues of haemocytes, gill, gonad, muscle and hepatopancreas with the highest expression in hepatopancreas. After scallops were challenged by Listonella anguillarum, the expression level of CfGPx3 transcript in haemocytes was significantly up-regulated (P<0.05) at 8 h post challenge. These results suggested that CfGPx3 was potentially involved in the immune response of scallops and perhaps contributed to the protective effects against oxidative stress. (C) 2010 Elsevier Inc. All rights reserved.

新疆紫草细胞悬浮培养生产紫草宁衍生物的动态测定机理化因子调控

本文在本实验室提供的新疆紫草愈伤组织高产系A1的基础上，采用二步培养法，进行摇瓶悬浮培养，分别在生长及生产培养基中测定了细胞生长，次生产物合成，培养基的C源（蔗糖）消耗，溶氧，电导率和pH值的动态变化曲线，确定了各动态曲线之间的关系，为进一步的放大培养提供了参考依据。同时，还测定了与细胞生长密切相关的过氧化物酶及与产物合成密切相关的苯丙氨酸解氨酶(PAL)的活性的动态变化曲线，进一步将宏观参数的动态变化与微观参数的动态变化联系起来。 本文还对不同理化因子对生产培养基中悬浮培养的细胞的生长及紫草宁衍生物合成的影响进行了研究。结果表明：过高或过低的供氧水平均不利于细胞的生长及产物的合成;C源及N源有较好的协同作用，适当地提高C源及N源的水平能明显提高紫草宁衍生物的产量：接种前往培养基里加入一定量的前体苯丙氨酸( Phe)，能明显提高紫草宁衍生物的产量，而在培养中期添加则有一定的负致应;一定量的拜土及琼脂(agar)的添加，对产物的合成均具有正效应，并且作用大小和细胞的生理状态有关。高密度培养的研究表明，在合适的接种量和培养基浓度下，适当提高溶氧，较大幅度地提高产量是有可能的，这还有待于进一步的研究验证。

毛竹茎木质化过程的组织细胞学研究

应用光学显微镜和透射电子显微镜，并结合组织化学和细胞化学方法，研究了毛竹（Phyllostachys pubescens Mazel）茎各组织中细胞壁的木质化过程、木质素异质性、酚酸类成分的分布、木质素在细胞壁中的沉积方式以及过氧化物酶的组织、细胞化学定位等。 研究结果表明：毛竹茎的原生木质部导管在维管束发育早期就已木质化;后生木质部导管和纤维细胞在维管束分化完成后，自胞间层和细胞角隅处开始木质化;基本薄壁组织细胞木质化的发生较晚，通常在茎的节间完成伸长生长后才开始，但也有少数薄壁组织细胞始终保持非木质化的薄壁状态。根据可见光显微分光光度的分析结果，纤维细胞壁在木质化的早期，主要形成愈创木基木质素（guaiacyl lignin）, 随着木质化过程的发展，紫丁得基木质素（syringyl lignin）含量不断增加，最后成为纤维细胞壁木质素的主要组成成分。导管分子的木质素主要成分为愈创木基木质素，基本薄壁组织细胞壁为愈创木基与紫丁香基两种。 毛竹茎各组织在紫外光激发下自发荧光的荧光显微分光光度分析表明，氨水处理可以有效地识别阿魏酸的分布，如在竹笋各种幼嫩组织中均分布有阿魏酸;而用过氧化氢／冰醋酸混合液处理，则可以区分木素与结合于半纤维素中的阿魏酸和对－香豆酸，随着毛竹茎的生长和细胞壁木质化的增加，阿魏酸的含量下降。 通过对毛竹茎纤维细胞壁木质化过程中超微结构的观察表明，高尔基体、高尔基小泡、内质网、壁旁体细胞器在木质素前体的形成和运输等方面均起着重要作用，而周质微管在细胞壁木质化过程中的具体作用方式尚不明确。木质素在细胞壁中的沉积方式分别为：胞间层的木质素呈分散的颗粒状沉积方式，导管次生壁的木质素为片层状沉积方式，而在纤维细胞次生壁Sl层中，木质素为团块状的沉积方式。木质素沉积方式与纤维素微纤丝的排列有密切关系。 在毛竹茎各组织的细胞壁尚未木质化之前，过氧化物酶仅分布于细胞角隅处，随着细胞次生壁的增厚和木质化的增强，过氧化物酶可大量出现在次生壁中;在纤维细胞次生壁中，木质素含量较高的St各层，过氧化物酶活性也较强，而木质素含量较低的Sl各层，过氧化物酶活性则较弱。由此表明，过氧化物酶直接参与了细胞壁木质素的合成。另外，在茎的部分基本薄壁组织细胞和韧皮部等未木质化的细胞壁中，过氧化物酶也同样表现出较强的活性，这说明在茎的不同组织中分布的这种酶，可能是几种不同功能的同工酶形式。

荔枝果实采后褐变及果皮过氧化物酶的提纯与性质研究

本文对荔枝果实采后贮藏中的关键问题果皮褐变的相关生理活动进行了研究。研究了采后荔枝果皮的总酚含量、花色素类物质含量、多酚氧化酶和过氧化物酶活性等在贮藏期间的变化，并就这些因素与荔枝果实采后贮藏和果皮褐变的关系进行了讨论。实验表明，在荔枝果实的采后贮藏过程中，果皮中的酚类物质、花色素苷类物质、多酚氧化酶和过氧化物酶等共同参与了导致荔枝果皮褐变的生理过程。 比较了荔枝果实在几种不同的气调环境中的贮藏效果和生理指标。结果表明高氧短时处理对于延长荔枝果实贮存时间，延缓果皮褐变有很好的效果。 过氧化物酶在以往的果实褐变过程的研究中一直没有得到足够的重视，对于荔枝果皮过氧化物酶的提纯和性质的研究也较少。为了研究过氧化物酶在褐变过程中的作用，进一步了解荔枝果皮褐变的机理，本文对荔枝果皮过氧化物酶进行了提纯。采用低浓度中性磷酸缓冲液抽提。纯化过程采用了硫酸铵分级沉淀、DEAE Sephadex A-50离子交换柱层析、Sephadex G-100凝胶过滤等技术，比较并摸索出提取和纯化的合适方法和条件，本文对该酶的热稳定性、pH 适应性、底物专一性、反应动力学参数和抑制剂等性质进行了研究，发现该酶热稳定很高，具有较广的pH适应范围，能催化双氧水氧化多种底物，对酚类物质的催化氧化能力很强。表明过氧化物酶在荔枝果皮的采后褐变过程中起重要作用，为荔枝果皮采后褐变的机理和荔枝果皮保色技术研究提出了新的探索方向。

果实对酵母拮抗菌和外源水杨酸诱导的抗病性应答机理

用生物和非生物因子来进行采后病害的防治，是一个非常有效的方法。诱导抗性作为控制果蔬采后病害的生物技术，已成为该领域的一个研究热点。然而诱导抗性的机制非常复杂，涉及到寄主、病原菌、激发子之间的相互作用关系。本研究主要利用酵母拮抗菌Pichia membranefaciens和SA处理果实，观察其抗性诱导表达和对采后青霉病菌（Penicillium expansum）的抑制作用，并从蛋白质组学水平上对诱导抗性的机理进行了分析。研究结果表明： 1、酵母拮抗菌P. membranefaciens (5 × 107 cells·ml-1)和SA(0.5 mM)处理采后甜樱桃果实，能够明显地降低病害的发病率和病斑直径。酵母菌和SA处理影响到了果实抗氧化酶的活性，同时还改变了POD同工酶谱和甜樱桃果实的总蛋白含量，并诱导了新的蛋白质条带产生。用光学显微镜和扫描电子显微镜技术观察发现，在in vitro条件下P. membranefaciens能够紧密地结合与病原菌的菌丝，而在in vivo条件下这种结合较为松散。 2、借鉴其它模式植物的方法，我们建立了一整套适用于多汁类植物材料的蛋白质组学研究方法。对于芒果，桃，甜樱桃、苹果以及冬枣等果实，都取得了重复性非常好的2-D图谱。我们应用该技术进一步研究了P. membranefaciens (1 × 108 cells·ml-1)以及SA (0.5 mM)处理对桃果实蛋白质组的诱导影响。结果显示，两种激发子处理都能够诱导桃果实产生抗性，从而减轻青霉病引起的腐烂。在诱导处理1 d以后，酵母拮抗菌和SA分别诱导22和16个蛋白的差异表达。质谱鉴定的蛋白属于6大类：代谢，防御反应，转录，能量途径以及细胞结构。有6个蛋白受到两种激发子的共同调控。其中，4种蛋白(包括glutathione peroxidase, polyphenol oxidase precursor, catalase和methionine sulfoxide reductase) 属于抗氧化蛋白，涉及到活性氧代谢。另2个蛋白（Major allergen Pru av 1和peroxidase）是病程相关蛋白，直接参与植物的防御反应。同时一些磷酸化酶和转录因子也受到两种激发子的调节从而参与果实的抗病反应。酶学测定和Northern杂交的结果表明，拮抗菌与SA处理均能影响过氧化氢酶活性及其基因的表达。 3、采前用较高浓度SA (2 mM) 短时间（10s）处理不同成熟期的甜樱桃果实，能够明显降低果实青霉病的病斑直径，并能减轻较低成熟度果实的发病率。在没有接菌的情况下，SA诱导了33个差异表达的蛋白，其中用质谱鉴定出了26个。而在接种病原菌的情况下，SA诱导了19个差异表达的蛋白，并鉴定出了其中的12个。这些蛋白分别涉及到代谢、防御反应、转录、能量途径、信号转导等过程。在没有接种病原菌的情况下，SA处理诱导了Putative DnaJ heat shock protein, PR1-like protein, Peroxidase, Major allergen Pru av 1 (Pru a 1)和Catalase等与抗病有关的蛋白。而在接种病原菌的情况下，诱导了PR1-like protein, Peroxidase和Catalase蛋白的差异表达。通过酶活性测定以及对细胞学定位的研究，我们发现在没有接种病原菌的情况下，POD的活性受到SA的诱导。但是在接种病原菌以后，诱导效果不明显。