Application of methyl parathion hydrolase (MPH) as a labeling enzyme

Methyl parathion hydrolase (MPH) is an enzyme that catalyzes the degradation of methyl parathion, generating a yellow product with specific absorption at 405 nm. The application of MPH as a new labeling enzyme was illustrated in this study. The key advantages of using MPH as a labeling enzyme are as follows: (1) unlike alkaline phosphatase (AP), horseradish peroxidase (HRP), and glucose oxidase (GOD), MPH is rarely found in animal cells, and it therefore produces less background noise; (2) its active form in solution is the monomer, with a molecular weight of 37 kDa; (3) its turnover number is 114.70 +/- 13.19 s(-1), which is sufficiently high to yield a significant signal for sensitive detection; and (4) its 3D structure is known and its C-terminal that is exposed to the surface can be easily subjected to the construction of genetic engineering monocloning antibody-enzyme fusion for enzyme-linked immunosorbent assay (ELISA). To demonstrate its utility, MPH was ligated to an single-chain variable fragment (scFv), known as A1E, against a white spot syndrome virus (WSSV) with the insertion of a [-(Gly-Ser)(5)-] linker peptide. The resulting fusion protein MPH-A1E possessed both the binding specificity of the scFv segment and the catalytic activity of the MPH segment. When MPH-A1E was used as an ELISA reagent, 25 ng purified WSSV was detected; this was similar to the detection sensitivity obtained using A1E scFv and the HRP/Anti-E Tag Conjugate protocol. The fusion protein also recognized the WSSV in 1 mu L hemolymph from an infected shrimp and differentiated it from a healthy shrimp.

Structure identification of a prenylflavonol glycoside from Epimedium koreanum by electrospray ionization tandem mass spectrometry

A novel prenylflavonol glycoside, named acetylicariin, has been isolated from the aerial parts of Epimedium koreanum Nakai. The structure has been identified by electrospray ionization multi-stage tandem mass spectrometry (ESI-MSn) and other chemical evidence, which has been elucidated as 8-prenylkaempferol-4'-methoxyl-3-O-alpha-L-rhamnopyranosyl-7-O-beta-D-(2''-O-acetyl)glucopyranoside.

缺磷胁迫导致高等植物叶片中磷脂酰甘油（PG）含量降低的机理研究

磷脂酰甘油（PG）是植物类囊体膜中唯一的磷脂，在它的sn-2位上总是连着一个棕榈酸（16：0）或反式十六碳烯酸（16：1 trans）。由于PG的分子结构独特，对它的功能已有了很多研究，目前认为PG在维持类囊体膜的结构与功能方面具有非常重要的作用。缺磷胁迫下，蓝藻、衣藻及拟南芥、大麦等物种中均检测到了PG含量的下降。对这一现象的常见解释是缺磷导致了PG生物合成受阻，从而引起了其含量的降低。但迄今为止尚没有试验证据支持。本研究比较了缺磷对不同叶龄的小麦与烟草叶片中PG含量与PG水解酶的活性的影响，同时对缺磷叶片酶粗提液水解外源PG后的主要产物、几种磷脂酶抑制剂对上述酶反应的影响等进行了研究，以阐明缺磷条件下叶片中PG含量下降的主要原 因。 缺磷小麦第一叶完全展开时，PG含量与PG水解酶活性均与对照相似;而第三叶完全展开时，尽管缺磷第三叶中PG水解酶活性也与对照相似，但其PG含量低于对照。这一结果表明，在小麦叶片完全展开之前，缺磷条件未影响叶片中的PG水解酶活性，第三叶中较低的PG含量应由PG的生物合成受阻引起。并且，由于缺磷植株第一叶完全展开时PG含量未受影响而第三叶中却表现出了轻微降低，可以推测叶片萌发越晚，PG生物合成受到的抑制就会越严重。 为了研究叶片衰老过程中PG含量下降的原因，我们比较了6，10，14与18日龄时缺磷与对照小麦植株第一叶中PG的相对含量与PG水解酶活性。研究发现：6日龄时，刚刚完全展开的缺磷和对照小麦第一叶中无论是PG含量还是PG水解酶活性都较为相似;而随着叶片的逐渐衰老，缺磷植株第一叶中PG含量大幅度下降，同时伴随着PG水解酶活性的急剧上升。18日龄时，缺磷小麦第一叶中的PG含量较对照降低了69.1%，其PG水解酶活性也远高于对照，37ºC下温育30min后，缺磷叶片的酶粗提液使外源PG含量降低了74.16%，而对照中只降低了13.7%。上述结果表明，缺磷条件下，小麦叶片中PG含量降低的程度与PG水解酶活性的强弱密切相关，PG水解加剧是导致老叶中PG含量降低的一个重要原因。 磷脂酶是水解磷脂的主要酶类。目前在植物体中发现的磷脂酶种类主要有磷脂酶D（PLD）、磷脂酶C（PLC）与磷脂酶A（PLA）。通过薄层层析（TLC），我们发现缺磷小麦叶片的酶粗提液水解外源PG后的主要产物是磷脂酸（PA）、二脂酰甘油（DAG）与游离脂肪酸（FFA）。将n-丁醇加入到缺磷小麦叶片的体外酶反应体系中后，观察到PA、DAG与FFA的生成量均表现出一定程度的降低。由于n-丁醇是PA经PLD途径生成的抑制剂，因此，上述结果表明PLD参与了缺磷条件下小麦叶片中PG的水解。硫酸新霉素是PLC的非特异性抑制剂，低浓度的硫酸新霉素（100μM 和 200μM ）加入到缺磷小麦叶片的体外酶反应体系后，三种产物的生成受到了严重抑制，表明PLC也与缺磷叶片中PG的降解密切相关。 为了进一步分析缺磷导致PG含量降低的原因，我们以烟草为试验材料，检测了缺磷胁迫对烟草嫩叶和老叶中的PG含量、PG水解酶活性、与PG降解相关的酶的种类及PLC、PLDα、PLDβ与PAT-1基因在mRNA上表达水平的的影响。结果表明，缺磷烟草叶片中PG含量的降低由PG生物合成受阻与PG降解加剧共同导致，PLC和PLD活性与烟草叶片中PG的降解有关。缺磷植株老叶中PG水解酶活性及PLC、PLDα、PLDβ基因在mRNA水平上的表达量均高于对照，表明在磷胁迫条件下，老叶中PG水解酶活性可能受到转录水平上的调节， PLC、PLDα、PLDβ转录活性的增强导致了PLC、PLD活性加强，从而引起PG降解的加剧，最终导致了PG含量的降低。与PLC、PLDα和PLDβ不同，缺磷胁迫对patatin蛋白（表现PLA2活性）的编码基因PAT-1在转录水平上的表达无影响，TLC分析PG的水解产物也未检测到溶血磷脂酰甘油（LPG）的生成。由此可见，PLA活性可能与缺磷条件下PG的降解无关。

小麦杂交坏死蛋白质组学研究

小麦杂交坏死是某些小麦杂交种表现出的叶片提前逐渐死亡的现象。它是由两个坏死基因Ne1和Ne2在杂交种中相遇后发生显性互补引起的。坏死从叶片尖端逐渐过渡到叶片基部，从成熟叶片发展到幼嫩叶片。一些严重坏死的F1完成它的生活周期前就在不同的生长阶段死去，无法获得F1种子，这就限制了携带优良性状的亲本的选择和优良基因的交流。另外，小麦杂交坏死是一个独特的研究植物程序性死亡的遗传系统。虽然小麦杂交坏死这种现象已经发现很多年，但其详细的分子机理却仍然未知。对小麦杂交坏死的分子机理进行深入研究将有助于克服小麦杂交利用中杂交坏死的遗传障碍，此外，也为深入研究植物的PCD机理提供可操作靶分子。 本论文采用高通量蛋白质组研究技术对小麦杂交坏死进行了研究。携带坏死基因Ne2的小麦品种Pan555（P）和携带坏死基因Ne2的小麦品种Zheng891（Z）生长发育完全正常，将两个亲本杂交，所得杂交F1代PZF1表现杂交坏死。在小麦生长阶段8，旗叶（Flag leaf）刚刚出现，PZF1的旗叶下第一片叶子（FL-1）还是完全绿色，FL-2叶尖开始有坏死斑出现。在这个阶段，分别将PZF1，P，Z的FL-2叶剪成相等的尖，中，基三段。我们选择的PZF1的FL-2叶，其叶尖段已经有成片的坏死斑出现;中间段零星出现少量坏死斑点;基部段和亲本一样还是完全的绿色，代表坏死进程中的不同阶段。又选PZF1的FL-1和FL-2分别代表杂交坏死启动前和杂交坏死启动后。两个亲本P和Z的FL-2叶的三段及FL-1叶正常，都是完全绿色。 首先分别分析了PZF1，P和Z的FL-2叶的尖、中、基三段的蛋白表达情况。在PZF1的尖、中、基三段共检测到23个差异表达蛋白点。这23个点在两个亲本的尖、中、基三段中的表达丰度没有显著差异（p<0.05），说明这23个蛋白的差异表达不是由于叶段的不同引起，确与杂交坏死相关。对这23个蛋白进行了MALDI-TOF质谱鉴定，其中18个得到成功鉴定。然后对PZF1，P和Z的FL-1叶和FL-2叶的蛋白表达情况进行了分析。与PZF1的FL-1叶比较，在FL-2叶中检测到19个蛋白上调，20个蛋白下调。这39个蛋白的丰度在两个亲本的FL-1和FL-2叶之间没有显著差异，说明这39个蛋白的差异表达不是由于叶位的不同引起，确与杂交坏死相关。对这39个蛋白进行质谱鉴定其中26个得到成功鉴定。 根据被鉴定蛋白的功能及其表达丰度的变化，对这些蛋白在小麦杂交坏死中可能的作用进行了讨论。与PZF1的FL-2叶基部相比，S-腺苷同型半胱氨酸水解酶（S-adenosyl homocysteine hydrolase）在中部极显著（p<0.01）下调，而在中部和尖段之间没有显著差异，保持低丰度不变。腺苷甲硫氨酸3（AdoMet synthase 3）和甲硫氨酸合成酶1（Methionine synthase 1）都在PZF1的FL-2叶尖段上调。甲基化循环中的这3个酶比例的不协调可能会以不同的方式加速细胞老化。 与PZF1的FL-1叶比较，尿卟啉环脱羧酶（Uroporphyrinogen decarboxylase）在FL-2叶中下调，这将引起尿卟啉环III的积累。脂加氧酶（Lipoxygenases）在FL-2叶中上调。尿卟啉环III的积累和脂加氧酶的上调都会引起细胞内活性氧的增加。另外活性氧和脂加氧酶都会使脂发生过氧化作用，进而导致细胞膜完整性受到破坏，最终可能导致细胞死亡。 与基部段比较，在PZF1的FL-2叶的尖段和/或中间段;以及与PZF1的FL-1叶比较，在FL-2叶中，都有很多防御性蛋白的上调，这暗示应对活性氧、脂过氧化、甲基化循环中三个酶比例的不协调等引起的对细胞的破坏作用，细胞可能启动了抗细胞死亡系统来应对这种细胞内部的胁迫。 然而，与基部段比较，一些能量相关蛋白在PZF1的FL-2叶的尖段和/或中间段;以及与PZF1的FL-1叶比较，在FL-2叶中的异常表达可能会以干扰能量循环的方式加速细胞死亡。另外，与FL-2基部段比较，在尖段和/或中间段，以及与PZF1的FL-1比较，在FL-2中，都有一些防御性蛋白、蛋白合成相关的蛋白以及单链DNA结合蛋白下调，它们的变化可能会降低细胞的抵抗力，蛋白合成能力以及DNA修复能力。细胞正常代谢的很多方面都受到干扰从而使PZF1叶细胞最终走向死亡。 本研究中发现了三个甲基化循环中的酶变化，而且S-腺苷同型半胱氨酸水解酶是在坏死进程的较早阶段发生下调，它的变化可能是小麦杂交坏死的一个诱因，这暗示小麦杂交坏死可能是一个表观遗传学事件。另外本研究还发现一些和活性氧，脂氧化等相关的蛋白的变化，而活性氧增加和脂氧化都是细胞凋亡的典型特征。所以本研究为表观遗传细胞凋亡和氧化胁迫细胞凋亡的研究提供了很有价值的信息。

Relationship between COPD and polymorphisms of HOX-1 and mEPH in a Chinese population

Recent studies have proposed that susceptibility to chronic obstructive pulmonary disease (COPD) might be related with the polymorphisms of some genes encoding antioxidant enzymes, such as heme oxygenase-1 (HOX-1) and microsomal epoxide hydrolase (mEPH).

Chemical Constituents from the Leaves and Stems of Schisandra lancifolia

A new nortriterpenoid, 20-hydroxymicrandilactone D (1) and a novel lignan glycoside, lancilignanside A (2) were isolated from leaves and stems of Schisandra lancifolia, together with three known nortriterpenoids (3-5) and nine known phenolics (6-14). The structures of new compounds 1 and 2 were determined by detailed analysis of their 1D and 2D NMR spectra, and chemical evidences. In addition, compounds 1-2, 6-7, and 9-11 showed anti-human immunodeficiency virus (HIV)-1 activities with 50% effective concentration (EC50) in the range of 3.0-99.0 mu g/ml. Compound 12 was not bioactive in this assay with EC50 more than 200 mu g/ml.

In vitro anti-HIV and -HSV activity and safety of sodium rutin sulfate as a microbicide candidate

Sodium rutin sulfate (SRS) is a sulfated rutin modified from the natural flavonol glycoside rutin. Here, we investigated its in vitro anti-HIV and -HSV activities and its cytotoxic profile. Fifty percent inhibitory concentration (IC50) values of SRS against HIV-1 X4 virus IIIB, HIV-1 R5 isolates Ada-M and Ba-L were 2.3 +/- 0.2, 4.5 +/- 2.0 and 8.5 +/- 3.8 mu M with a selectivity index (SI) of 563, 575 and 329, respectively. Its IC50 against primary R5 HIV-1 isolate from Yunnan province in China was 13.1 +/- 5.5 mu M, with a Sl of 197. In contrast, unsulfated rutin had no activity against any of the HIV-1 isolates tested. Further study indicated that SRS blocked viral entry and virus-cell fusion likely through interacting with the HIV- I envelope glycoprotein. SRS also demonstrated some activity against human herpes simplex virus (HSV) with an IC50 of 88.3 +/- 0.1 mu M and a Sl of 30. The 50% cytotoxicity concentration (CC50) of SRS was >3.0 mM, as determined in human genital ME 180, HeLa and primary human foreskin fibroblast cells. Minimum inhibitory concentration of SRS for vaginal lactobacilli was >3.0 mM. These results collectively indicate that SRS represents a novel candidate for anti-HIV-1/HSV microbicide development. (C) 2007 Elsevier B.V. All rights reserved.

气体水合物生成特性实验研究

实验研究了添加剂对甲烷气体水合物形成过程的影响。发现微量的表面活性剂降低了甲烷气体水合物在静止反应器中形成的诱导时间，并使水合物快速形成和生长，提高了水合物形成过程中的填充密度。阴离子表面活性剂（十二烷基硫酸钠）对水合物生长的促进作用比非离子表面活性剂（烷基多糖苷）强。液态烃环戊烷降低了水合物形成的诱导时间，但环戊烷不能提高水合物的填充密度。

Chemical Constituents from the Leaves and Stems of Schisandra lancifolia

A new nortriterpenoid, 20-hydroxymicrandilactone D (1) and a novel lignan glycoside, lancilignanside A (2) were isolated from leaves and stems of Schisandra lancifolia, together with three known nortriterpenoids (3—5) and nine known phenolics (6—14). The structures of new compounds 1 and 2 were determined by detailed analysis of their 1D and 2D NMR spectra, and chemical evidences. In addition, compounds 1—2, 6—7, and 9—11 showed anti-human immunodeficiency virus (HIV)-1 activities with 50% effective concentration (EC50) in the range of 3.0—99.0m g/ml. Compound 12 was not bioactive in this assay with EC50 more than 200m g/ml.

水菖蒲的化学成分研究和忍冬属植物的色谱分析

本论文由三章组成。第一章阐述了藏药水菖蒲的化学成分研究，共分离鉴定了39个化学成分，其中6个为新化合物。第二章报道了几种忍冬属植物的HPLC、HPLC-MS、GC分析以及抑菌活性、重金属含量测定结果。第三章概述了菖蒲属植物的研究进展。 第一章报道了水菖蒲(Acorus calamus L.)化学成分的分离纯化与结构鉴定。采用正、反相硅胶柱层析等分离方法，从水菖蒲的根中共分离出41个化合物，通过红外、质谱、核磁共振及X-ray单晶衍射等波谱方法和模拟计算方法鉴定了其中39个化合物的结构，主要为倍半萜、苯丙素、甾体类化合物。其中含有5个新的倍半萜类化合物和1系列新的甾体皂苷衍生物。经波谱分析将它们的结构鉴定为 1b, 7a(H)-cadinane-4a, 6a, 10a-triol (1), (2R,6R,7S,9S)-1(10), 4-cadinadiene-2, 9-diol (2), 1a, 5b-guaiane-10a-O-ethyl-4b, 6b-diol (7), 6b, 7b(H)-cadinane-1a, 4a, 10a-triol (13)，(1R,4R,6S,10R)-1-hydroxy-7(11)-cadinen-5, 8-dione (14)， 4′-O-正n碳酰基-3-O- β-D-葡萄糖基谷甾醇(n=14, 16, 18, 22) (15)。 第二章包括四个部分。第一部分报道了忍冬属三种植物40个样品的HPLC测定和对主要活性成分绿原酸的定量分析结果，以及运用HPLC-MS技术对色谱图中8个峰进行指认。在此基础上，考察了种植和采收多个因素对绿原酸含量的影响。第二部分报道了忍冬属三种植物27个样品的GC分析，根据样品的挥发性成分的保留时间对不同样品进行了定性比较，并考察了花期及海拔高度对植物挥发性成分的影响。第三、四部分分别阐述了灰毡毛忍冬和红腺忍冬的体外抑菌活性研究和重金属含量测定结果。 第三章全面系统地概述了菖蒲属植物的化学成分和药理活性研究进展。 This dissertation is composed by three chapters. The first chapter elaborates the phytochemical investigation of Acorus calamus L. Thirty-nine compounds including six new compounds were isolated and identified. The second chapter reports the research on genus Lonicera by HPLC, HPLC-MS and GC. Antifungal activity and heavy metals measurement of genus Lonicera were reported. The third chapter is a review about the research progress on the plant family of Acorus. The first chapter focuses on the isolation and identification of chemical constituents from Acorus calamus L.. Forty-one compounds were isolated from the root of Acorus calamus L. by repeat column chromatography over normal and reversed phase silica gel, the structure of thirty-nine compounds was identified by spectroscopic methods and computational methods, including IR, MS, NMR and X-ray. Those compounds mainly belonged to sesquiterpene, phenylpropanoid and steroid. Among them, five are new sesquiterpenes and one series are new steroid glycoside derivatives. Their structure were suggested as 1b, 7a(H)-cadinane-4a, 6a, 10a-triol (1), (2R,6R,7S,9S)-1(10), 4-cadinadiene-2, 9-diol (2), 1a, 5b-guaiane-10a-O-ethyl-4b, 6b- diol (7), 6b, 7b(H)-cadinane-1a, 4a, 10a-triol (13), (1R,4R,6S,10R)-1-hydroxy-7(11)- cadinen-5, 8-dione (14), 4′-O-carbonyl-3-O-β-D-glucosyl-sitosterol (carbonyl = tetradecanoyl, hexadecanoyl, octadecyl, docosanoyl) (15). The second chapter consists of four parts. The first part reports the HPLC analysis of forty samples of the genus Lonicera, and the quantitative investigation of chlorogenic acid in these samples by HPLC analysis. Relationship between the content of chlorogenic acid in different samples and their planting conditions and harvesting time were discussed. Furthermore, eight compounds were identified or tentatively characterized based on their mass spectra and UV spectra profiles. The second part is about qualitative analysis of the volatile constituent in twenty-seven samples of genus Lonicera by GC. The effect of planting altitude and harvesting time on the volatile constituent was also investigated. The third and fourth parts describe the antifungal activity and content of some kinds of heavy metals of L. macranthoides Hand.-Mazz. and L. hypoglauca Miq.. The third chaspter is a review about the research progress of the plant family of Acorus.

野桂花的化学成分研究

首次从野桂花（Osmanthus yunnanensis Fr. P. S. Green）地上部分95%乙醇提取物中通过色谱分离得到20个化合物, 其中化合物20为新化合物。基于波谱数据它们被鉴定为(E)-阿魏酸二十烷基酯(1)、β-谷甾醇(2)、羽扇豆醇(3)、齐墩果酸(4)、7-oxo-β-sitosterol(5)、乙酰齐墩果酸(6)、(6′-O-palmitoyl)-sitosterol 3-O-β-D-glucoside(7)、rotundioic acid(8)、地榆糖甙Ⅱ(9)、27-O-(E)-对羟基肉桂酰-28-齐墩果酸(10)、27-O-(Z)-对羟基肉桂酰-28-齐墩果酸(11)、hycandinic acid ester(12)、绿原酸丁酯(13)、4,5-二咖啡酰奎尼酸丁酯(14)、4,5-dihydroxyprenyl caffeate(15)、28-O-β-D-glucopyranosyl rotundioic acid (16)、4-(6-O-caffeoyl-β-D-glucopyranosyloxy)-5-hydroxyprenyl caffeate (aohada-glycoside C, 17)、 4-β-D-glucopyranosyloxy-5-hydroxy-prenyl caffeate (aohada-glycoside A, 18)、β-胡萝卜甙(19)以及3-[O-β-D-(6-O-咖啡酰吡喃葡萄糖)]-甲基-2-烯-γ-内酯 (20)。化合物13、14、15和17有较强的α-葡萄糖甙酶抑制活性。当浓度为1 mg/ml时，它们对α-葡萄糖甙酶的抑制分别为61.5%、95.5%、72.1%、62.6%，活性高于阿卡波糖。 综述了木犀属植物化学成分及1993年以来苯丙素甙类化合物活性研究进展。 Twenty compounds were isolated from the 95% ethanol extract of the aerial parts of Osmanthus yunnanensis Fr. P. S. Green by chromatography for the first time. On the basis of spectral data, they were identified as (E)-ferulic acid eicosyl ester (1), β-sitosterol (2), lupenol (3), oleanolic acid (4), 7-oxo-β-sitosterol (5), acetyloleanolic acid (6), (6′-O-palmitoyl)-sitosterol 3-O-β-D-glucoside (7), rotundioic acid (8), ziyu glycosideⅡ (9), 3β-hydroxy-27-p-(E)-coumaroyloxy-olean-12-en-28-oic acid (10), 3β-hydroxy-27-p-(Z)-coumaroyloxyolean-12-en-28-oic acid (11), hycandinic acid ester (12), chlorogenic acid butyl ester (13), 4,5-di-O-caffeoylquinic acid butyl ester (14), 4,5-dihydroxyprenyl caffeate (15), 28-O-β-D-glucopyranosyl rotundioic acid (16), 4-(6-O-caffeoyl-β-D-glucopyranosyloxy)-5-hydroxyprenyl caffeate (aohada- glycoside C, 17), 4-β-D-glucopyranosyloxy-5-hydroxyprenyl caffeate (aohada- glycoside A, 18), β-daucosterol(19) and 3-[O-β-D-(6-O-caffeoylglucopyranosyl)]- methyl-2-en-γ-lactone (20). Compound 20 is a new one. Compounds 13, 14, 15 and 17 inhibit α-glucosidase with corresponding inhibitory rate of 61.5%, 95.5%, 72.1% and 62.6% at a concentration of 1 mg/ml, higher than acarbose. The chemical studies on Osmanthus genus and bioactivities of phenylpropanoid glycosides were summarized.