植物次生物的代谢途径

系统地介绍了关于植物次生物代谢途径方面的研究成果,归纳了植物次生物的3个主要代射途径:酚类代谢途径、萜类代谢途径、生物碱代谢途径,并对其代谢机理进行了探讨。     

植物生物碱代谢生物学研究进展

目前,植物生物碱作为植物的化学防御武器,在植物的生态适应过程中发挥积极作用的观点已得到了普遍的接受。生物碱代谢生物学的研究近年来取得了长足的进步,主要集中在生物碱合成和贮存部位、转运途径、代谢调控因子、生物合成途径和关键酶及其编码基因等方面,现就这方面的进展作一简要综述,并提出了该领域尚存在的问题和前景展望。     

植物生物碱代谢生物学研究进展

 目前,植物生物碱作为植物的化学防御武器,在植物的生态适应过程中发挥积极作用的观点已得到了普遍的接受。生物碱代谢生物学的研究近年来取得了长足的进步,主要集中在生物碱合成和贮存部位、转运途径、代谢调控因子、生物合成途径和关键酶及其编码基因等方面,现就这方面的进展作一简要综述,并提出了该领域尚存在的问题和前景展望。     

植物次生代谢物途径及其研究进展

植物次生代谢是植物在长期进化过程中与环境相互作用的结果,由初生代谢派生。萜类、生物碱类、苯丙烷类为植物次生代谢物的主要类型,其代谢途径多以代谢频道形式存在,具有种属、生长发育期等特异性。从植物次生代谢物的分类、代谢途径及代谢调控基因工程等方面展开论述,重点介绍了次生代谢物的生物合成途径,以及利用基因工程等技术对植物次生代谢途径进行遗传改良等方面的研究进展,为全面认识植物代谢网络、合理定位次生代谢及其关键酶、促进野生植物资源可持续利用等提供理论依据。     

bZIP转录因子调控植物次生代谢产物生物合成的研究进展

植物次生代谢产物是通过次生代谢产生的一类小分子有机化合物,是植物适应环境的表现,次生代谢产物也是重要药物和化工原料的来源。bZIP转录因子是普遍存在于真核生物中的一类多基因家族,可有效调控植物次生代谢产物的生物合成。本文概述了植物bZIP转录因子的结构和类型,重点阐述了bZIP转录因子调控萜类、黄酮类和生物碱等植物次生代谢产物生物合成的研究进展,并对研究前景进行了展望。深入探讨bZIP转录因子的调控机制,有助于利用基因工程技术优化植物次生代谢途径,提高次生代谢产物的含量,在新药创制、工农业生产等方面具有广泛的应用前景。     

茉莉素介导的长春花生物碱次生代谢转录调控机制

萜类吲哚生物碱（terpeniod indole alkaloids, TIAs）是植物中产生的一类具有药理活性的次生代谢产物.药用植物长春花（Catharanthus roseus）因含有长春碱和长春新碱等重要的抗肿瘤萜类吲哚生物碱而成为研究TIAs次生代谢的主要模式植物.应用正、反向遗传学和各种代谢组学技术对长春花TIAs次生代谢途径及其调控进行了较深入的研究,相继鉴定了参与TIAs代谢途径调控的CrORCAs、CrMYCs、CrZCTs和CrWRKYs等转录因子,特别是发现茉莉素（jasmonates, JAs）介导TIAs生物合成的转录调控网络. 本文以长春花TIAs生物合成途径为模式,重点论述其代谢途径中的关键酶、参与调节的转录因子,尤其是茉莉素介导的调控网络及机制,解析植物中这些天然抗癌生物碱合成积累水平低的制约因素和组织细胞特异性,讨论基于这些新知识的长春花抗肿瘤TIAs代谢工程策略和工厂化绿色生产前景.     

苄基异喹啉类生物碱生物合成与代谢工程研究进展

苄基异喹啉类生物碱(benzylisoquinoline alkaloids,BIAs)是一类具有重要研究及药用价值的次生代谢产物,目前该类生物碱主要来自于植物。但是BIAs在植物中的含量低、且大部分含有BIAs的植物具有生长周期长、受环境影响大、采集困难和难以大规模种植等问题。为解决这些问题,许多研究人员致力于解析BIAs生物合成途径并利用植物与微生物代谢工程技术提高BIAs的含量与开辟新药源。本研究将从BIAs类型与生物合成途径以及微生物与植物代谢工程几个方面对BIAs的生物合成与代谢工程研究进展进行综述,有利于BIAs的深入研究。     

植物次生代谢基因工程研究进展

随着对植物代谢网络日渐全面的认识,应用基因工程技术对植物次生代谢途径进行遗传改良已取得了可喜的进展.对次生代谢途径进行基因修饰的策略包括:导入单个、多个靶基因或一个完整的代谢途径,使宿主植物合成新的目标物质;通过反义RNA和RNA干涉等技术降低靶基因的表达水平,从而抑制竞争性代谢途径,改变代谢流和增加目标物质的含量;对控制多个生物合成基因的转录因子进行修饰,更有效地调控植物次生代谢以提高特定化合物的积累.作者结合对大豆种子异黄酮类代谢调控和基因工程改良的研究,着重介绍了花青素和黄酮类物质、生物碱、萜类化合物和安息香酸衍生物等次生代谢产物生物合成的基因工程研究进展.     

茄属生物碱的研究进展

甾体生物碱(SA)主要是茄属植物体内的一种次级代谢产物。它复杂的结构多样性决定了生物活性的多样性。它的合成途径也比较复杂,尚不十分清楚。以生物碱类化合物的化学结构为基础,对近几年来茄属生物碱的研究现状进行了简要综述。主要论述了茄属生物碱的化学结构、含量分布、生理活性以及与茄属生物碱合成途径相关的分子生物学研究。并分析了茄属生物碱今后的发展方向。以期为以后研究糖苷生物碱的生物合成途径、毒性机制、药理学作用等奠定一定的基础。     

石蒜属植物生物碱成分研究进展

石蒜属为东亚特有属。该属植物富含生物碱,且此类次生代谢产物具有细胞毒、抗疟疾、抗病毒以及对乙酰胆碱酯酶的抑制作用等活性。本文概述了该属中生物碱类成分的化学结构、药理活性及其生源途径。     

Polyamines and plant alkaloids

Naturally occurring alkaloids are nitrogenous compounds that constitute the pharmacogenically active basic principles of flowering plants. Alkaloids are classified into several biogenically related groups. Tobacco alkaloids are metabolised from polyamines and diamines putrescine and cadaverine. N-methyl transferase is the first enzyme in alkaloid biosynthetic pathway which drives the flow of nitrogen away from polyamine biosynthesis to alkaloid biosynthesis. Arginine decarboxylase has been suggested to be primarily responsible for providing putrescine for nicotine synthesis. Tryptophan is the precursor of indole alkaloids. However, the biosynthetic pathway of tropane and isoquinoline alkaloids are not clear. Genes for several key biosynthetic enzymes like arginine decarboxylase, ornithine decarboxylase, putrescine N-methyl transferase and spermidine synthase, hyoscyamine 6 beta hydroxylase,tryptophan decarboxylase etc have been cloned from different plant species. These genes are regulated by plant hormones, light, different kinds of stress and elicitors like jasmonates and their strong expression is primarily in the cultured roots. In view of this, the axenic hairy root cultures induced by Agrobacterium rhizogenes have been utilised to synthesise secondary metabolites. The current development in the knowledge of alkaloid biosynthesis, particularly molecular analysis, has been discussed in this review that may help to open up new avenues of investigation for the researchers.     

Quantification of metabolites in the indole alkaloid pathways of catharanthus roseus: implications for metabolic engineering

In this article, we present a review of the current state of metabolic engineering in Catharanthus roseus. A significant amount of research has contributed to characterization of several individual steps in the biosynthetic pathway of medicinally valuable alkaloids. However, knowledge of the regulation of these pathways is still sparse. Using hairy root cultures, we studied the responses of alkaloid metabolism to environmental stimulation such as light and elicitation. Through precursor feeding studies, the putative rate-limiting steps of the terpenoid pathway in hairy root cultures also have been examined. Relating this knowledge to specific events at the molecular level, and the cloning of corresponding genes are the next key steps in metabolic engineering of the C. roseus alkaloids. Copyright 1998 John Wiley & Sons, Inc.     

Alkaloid formation in cell suspension cultures of Tabernaemontana elegans after feeding of tryptamine and loganin or secologanin

A cell suspension culture of Tabernaemontana elegans lost its ability to produce alkaloids after a prolonged period of subculture. To determine whether it was still capable of performing the later steps of the alkaloid biosynthetic pathway, the culture was fed with tryptamine and loganin. The precursors and alkaloids were determined in the biomass and in the medium during a growth cycle. In this culture, an increase in the amount of serotonin was found in the biomass after feeding of tryptamine and loganin. Secologanin was detected in small amounts but strictosidine was not. Therefore, a limitation in alkaloid formation in this T. elegans cell line occured in the formation of secologanin from loganin. After feeding of secologanin alone, strictosidine, 10-hydroxy strictosidine, strictosidinic acid and two other indole alkaloids, as yet unidentified, were formed. However, the alkaloids originally produced by this cell line were not found. As the biosynthesis is impaired at several steps, it seems that the loss of productivity is more likely to be to a change on the level of the regulation of the pathway, than due to the loss of the capacity to express an individual biosynthetic gene of the pathway.     

药用植物甾体生物碱的药理作用及合成途径

甾体生物碱是药用植物中广泛存在的一类代谢产物,是一类具有降压、止咳、平喘、抗肿瘤等生物活性的天然产物。目前,甾体生物碱的合成代谢途径、分离纯化、鉴别及生物学功能研究已成为国内外天然产物研究的热点之一。对药用植物甾体生物碱的药理作用进行了综述,并根据萜类物质合成途径,推测总结了甾体生物碱的合成相关途径和参与该途径的关键酶及其基因克隆的研究进展,以期为药用植物甾体生物碱的代谢途径与基因表达调控及应用研究提供参考。     

Effects of Oxygen on Nicotine and Tropane Alkaloid Production in Cultured Roots Duboisia myoporoides

The effects of oxygen on nicotine and tropane alkaloid production in root cultures of Duboisia myoporoides were investigated. Duboisia roots cultured in air produced both nicotine and tropane alkaloids equally. However, when roots were cultured in pure oxygen, the metabolic flux to tropane alkaloids increased, and that to nicotine alkaloids decreased. Intermediate product analysis by GC-MS showed an increase in tropine, but decreases in acetyl derivatives of tropane alkaloids and tropine esters with low-class fatty acids. Furthermore, hyoscyamine 6β-hydroxylase (H6H, EC 1.14.11.11, the key enzyme in the pathway from hyosyamine to scopolamine) also increased. These results suggest that pure oxygen contributes to scopolamine production not only by activating the biosynthetic steps for scopolamine, but also by inactivating the biosynthetic steps for nicotine and other tropine derivatives.     

Molecular cloning and mRNA expression profiling of the first specific jasmonate biosynthetic pathway gene allene oxide synthase from <Emphasis Type="Italic">Hyoscyamus niger</Emphasis>

In the endeavor to enhance the production of pharmaceutically valuable tropane alkaloids including hyoscyamine and scopolamine in Hyoscyamus niger, methyl jasmonate (MeJA) showed significant stimulation both in tropane biosynthetic pathway enzymes activities and tropane alkaloids yields. Therefore it was speculated that genetic engineering of jasmonate biosynthetic pathway might enhance the endogenous jasmonates concentration, followed by stimulating the production of tropane alkaloids. Herein a full-length cDNA encoding allene oxide synthase (AOS, EC 4.2.1.92), the first committed step enzyme in jasmonate biosynthetic pathway was reported (named HnAOS, GenBank accession: EF532599). HnAOS was a novel member of the cytochrome P450 (CYP74A) subfamily. Real-time quantitative PCR analysis showed that HnAOS mRNA accumulated mainly in stems, and responded significantly to wounding or methyl jasmonate. The article is published in the original.     

Iridoid-specific glucosyltransferase from Gardenia jasminoides

Iridoids are one of the most widely distributed secondary metabolites in higher plants. They are pharmacologically active principles in various medicinal plants and key intermediates in the biosynthesis of monoterpenoid indole alkaloids as well as quinoline alkaloids. Although most iridoids are present as 1-O-glucosides, the glucosylation step in the biosynthetic pathway has remained obscure. We isolated a cDNA coding for UDP-glucose:iridoid glucosyltransferase (UGT85A24) from Gardenia jasminoides. UGT85A24 preferentially glucosylated the 1-O-hydroxyl group of 7-deoxyloganetin and genipin but exhibited only weak activity toward loganetin and no activity toward 7-deoxyloganetic acid. This suggests that, in the biosynthetic pathway of geniposide, a major iridoid compound in G. jasminoides, glucosylation occurs after methylation of 7-deoxyloganetic acid. UGT85A24 showed negligible activity toward any acceptor substrates other than iridoid aglycones. Thus, UGT85A24 has a remarkable specificity for iridoid aglycones. The mRNA level of UGT85A24 overlaps with the marked increase in genipin glucosylation activity in the methyl jasmonate-treated cell cultures of G. jasminoides and is related to iridoid accumulation in G. jasminoides fruits.     

Pyrrolizidine alkaloid biosynthesis,evolution of a pathway in plant secondary metabolism

The system of pyrrolizidine alkaloids has proven to be a powerful system for studying the evolution of a biosynthetic pathway in plant secondary metabolism. Pyrrolizidine alkaloids are typical plant secondary products produced by the plant as a defense against herbivores. The first specific enzyme, homospermidine synthase, has been shown to have evolved by duplication of the gene encoding deoxyhypusine synthase, which is involved in primary metabolism. Despite the identical function of homospermidine synthase for pyrrolizidine alkaloid biosynthesis in the various plant lineages, this gene duplication has occurred several times independently during angiosperm evolution. After duplication, these gene copies diverged with respect to gene function and regulation. In the diverse plant lineages producing pyrrolizidine alkaloids, homospermidine synthase has been shown to be expressed in a variety of tissues, suggesting that the regulatory elements were recruited individually after the duplication of the structural gene. The molecular, kinetic, and expression data of this system are discussed with respect to current models of gene and pathway evolution.