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.     

我国资源植物化学与天然产物化学基础研究的现状与发展

本文从生物活性成分的筛选与分离、植物次生代谢产物生物合成及其分子调控、环境因子对植物次生代谢产物合成和积累的影响、植物体内生菌与植物次生代谢产物的关系等方面介绍了我国资源植物化学与天然产物化学领域基础研究的现状与发展。     

几种重要植物次生代谢防御反应物质的生物合成途径及分子调控机制研究进展

参与植物防御反应相关的次生代谢产物主要有酚类、萜类和生物碱类.近几年,随着转录组学、蛋白组学及新的分子生物学技术的广泛应用,极大地推进了植物次生代谢防御反应物质调控机制的研究进展.我们从这几类次生代谢物质的合成途径及其参与植物防御反应的分子调控机制两大方面进行概述,重点介绍这三类具有防御作用的次生代谢产物的生物合成途径、参与介导植物防御反应的相关信号分子及其转录调控机制,为正确认识植物次生代谢防御反应提供理论据.     

miRNA调控药用植物生长发育和次生代谢

microRNA(miRNA)作为一类内源性的短链非编码RNA,广泛存在于真核细胞中,主要通过对转录本剪切和抑制翻译等方式,参与转录后基因的表达调控。近年来研究表明,多种药用植物中鉴定出大量的miRNA。这些miRNA对药用植物的生长发育和次生代谢产物合成具有调控功能。次生代谢产物是药用植物的主要有效成分,研究miRNA对药用植物次生代谢过程的调控作用具有十分重要的意义。本文综述了miRNA在植物中的产生途径、作用方式和体内功能,在此基础上重点介绍了miRNA对药用植物生长发育和次生代谢产物生物合成的调控作用,并对药用植物miRNA的研究进行了展望,以期为提高药用植物产量,高效获得药用植物有效成分以及临床应用开拓新的思路。     

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.     

植物次生细胞壁生物合成的转录调控网络

植物次生细胞壁包含纤维素、半纤维素和木质素, 赋予细胞壁机械强度及疏水性, 这种特性对植物直立生长、水分和营养物质运输以及抵御生物和非生物胁迫十分重要。该文总结了调控次生细胞壁生物合成的转录因子及其调控机制, 包括NAC转录因子调控次生壁合成的一级开关作用, AtMYB46/AtMYB83及其下游调控因子的二级开关作用, 以及其它转录因子对次生壁生物合成的调控作用, 并对未来研究内容和方法进行了展望, 以期为深入系统理解次生细胞壁生物合成的转录调控网络提供参考。     

植物次生细胞壁生物合成的转录调控网络

植物次生细胞壁包含纤维素、半纤维素和木质素,赋予细胞壁机械强度及疏水性,这种特性对植物直立生长、水分和营养物质运输以及抵御生物和非生物胁迫十分重要。该文总结了调控次生细胞壁生物合成的转录因子及其调控机制,包括NAC转录因子调控次生壁合成的一级开关作用,AtMYB46/AtMYB83及其下游调控因子的二级开关作用,以及其它转录因子对次生壁生物合成的调控作用,并对未来研究内容和方法进行了展望,以期为深入系统理解次生细胞壁生物合成的转录调控网络提供参考。     

探讨组蛋白甲基化修饰在次生代谢产物调控中的作用

组蛋白甲基化是表观遗传调节模式中一种重要修饰方式,易受环境影响,对调控次生代谢产物生物合成具有一定作用。本文论述了组蛋白甲基化修饰的基本概念与转录调控机制,探讨了其通过不同方式调控次生代谢产物的生物合成,同时也阐明了组蛋白甲基化与其他组蛋白修饰协同调控次生代谢产物合成,旨在为构建以组蛋白甲基化为切入点,以转录调控为桥梁,以次生代谢产物为重点的药用植物次生代谢产物形成分子机制研究平台提供理论依据。     

链霉菌次生代谢中双因子调控系统的研究进展

链霉菌次生代谢产物的生物合成受到严格和复杂的调控,而双因子调控系统是其中重要的一类调控因子,在链霉菌中广泛存在,且存在作用方式的多样性和作用机制的复杂性。就近些年研究较多的参与链霉菌次生代谢的两类双因子调控系统(真核型和原核型)的研究状况做了综述,重点阐明其作用机制,并对其研究趋势以及在药物代谢工程中的应用前景进行了展望。     

花青素转录因子调控机制及代谢工程研究进展

花青素是广泛存在于植物中的一类重要的类黄酮化合物, 在植物生长发育和人类营养保健方面具有重要价值。花青素的生物合成途径已经解析得比较清楚, 但花青素的代谢调控网络还在不断完善。调控花青素生物合成的转录因子主要包括MYB、bHLH和WD40三大类, 这些转录因子通过激活或抑制CHS、ANS和DFR等花青素途径关键结构基因的表达水平, 进而决定花青素积累的部位与水平。该文结合国内外花青素生物合成与转录调控方面的研究进展, 简要介绍了花青素的生物合成途径, 归纳总结了模式植物中花青素代谢调控的分子机理, 尤其是MYB、bHLH和WD40三类主要转录因子的调控机理, 以及这些转录因子在观赏植物和水果等经济作物花青素代谢工程中的应用。该文将为系统阐明花青素的转录调控机制和利用代谢工程改良花青素的相关研究提供有益参考。     

Engineering biosynthesis of high-value compounds in photosynthetic organisms

The photosynthetic, autotrophic lifestyle of plants and algae position them as ideal platform organisms for sustainable production of biomolecules. However, their use in industrial biotechnology is limited in comparison to heterotrophic organisms, such as bacteria and yeast. This usage gap is in part due to the challenges in generating genetically modified plants and algae and in part due to the difficulty in the development of synthetic biology tools for manipulating gene expression in these systems. Plant and algal metabolism, pre-installed with multiple biosynthetic modules for precursor compounds, bypasses the requirement to install these pathways in conventional production organisms, and creates new opportunities for the industrial production of complex molecules. This review provides a broad overview of the successes, challenges and future prospects for genetic engineering in plants and algae for enhanced or de novo production of biomolecules. The toolbox of technologies and strategies that have been used to engineer metabolism are discussed, and the potential use of engineered plants for industrial manufacturing of large quantities of high-value compounds is explored. This review also discusses the routes that have been taken to modify the profiles of primary metabolites for increasing the nutritional quality of foods as well as the production of specialized metabolites, cosmetics, pharmaceuticals and industrial chemicals. As the universe of high-value biosynthetic pathways continues to expand, and the tools to engineer these pathways continue to develop, it is likely plants and algae will become increasingly valuable for the biomanufacturing of high-value compounds.     

Plant cell cultures: Chemical factories of secondary metabolites

This review deals with the production of high-value secondary metabolites including pharmaceuticals and food additives through plant cell cultures, shoot cultures, root cultures and transgenic roots obtained through biotechnological means. Plant cell and transgenic hairy root cultures are promising potential alternative sources for the production of high-value secondary metabolites of industrial importance. Recent developments in transgenic research have opened up the possibility of the metabolic engineering of biosynthetic pathways to produce high-value secondary metabolites. The production of the pungent food additive capsaicin, the natural colour anthocyanin and the natural flavour vanillin is described in detail.     

Natural products – modifying metabolite pathways in plants

The diversity of plant natural product (PNP) molecular structures is reflected in the variety of biochemical and genetic pathways that lead to their formation and accumulation. Plant secondary metabolites are important commodities, and include fragrances, colorants, and medicines. Increasing the extractable amount of PNP through plant breeding, or more recently by means of metabolic engineering, is a priority. The prerequisite for any attempt at metabolic engineering is a detailed knowledge of the underlying biosynthetic and regulatory pathways in plants. Over the past few decades, an enormous body of information about the biochemistry and genetics of biosynthetic pathways involved in PNPs production has been generated. In this review, we focus on the three large classes of plant secondary metabolites: terpenoids (or isoprenoids), phenylpropanoids, and alkaloids. All three provide excellent examples of the tremendous efforts undertaken to boost our understanding of biosynthetic pathways, resulting in the first successes in plant metabolic engineering. We further consider what essential information is still missing, and how future research directions could help achieve the rational design of plants as chemical factories for high-value products.     

Nitric oxide elicitation for secondary metabolite production in cultured plant cells

Nitric oxide (NO) is an important signal molecule in stress responses. Accumulation of secondary metabolites often occurs in plants subjected to stresses including various elicitors or signal molecules. NO has been reported to play important roles in elicitor-induced secondary metabolite production in tissue and cell cultures of medicinal plants. Better understanding of NO role in the biosynthesis of such metabolites is very important for optimizing the commercial production of those pharmaceutically significant secondary metabolites. This paper summarizes progress made on several aspects of NO signal leading to the production of plant secondary metabolites, including various abiotic and biotic elicitors that induce NO production, elicitor-triggered NO generation cascades, the impact of NO on growth development and programmed cell death in medicinal plants, and NO-mediated regulation of the biosynthetic pathways of such metabolites. Cross-talks among NO signaling and reactive oxygen species, salicylic acid, and jasmonic acid are discussed. Some perspectives on the application of NO donors for induction of the secondary metabolite accumulation in plant cultures are also presented.     

Improving production of bioactive secondary metabolites in actinomycetes by metabolic engineering

Production of secondary metabolites is a process influenced by several physico-chemical factors including nutrient supply, oxygenation, temperature and pH. These factors have been traditionally controlled and optimized in industrial fermentations in order to enhance metabolite production. In addition, traditional mutagenesis programs have been used by the pharmaceutical industry for strain and production yield improvement. In the last years, the development of recombinant DNA technology has provided new tools for approaching yields improvement by means of genetic manipulation of biosynthetic pathways. These efforts are usually focused in redirecting precursor metabolic fluxes, deregulation of biosynthetic pathways and overexpression of specific enzymes involved in metabolic bottlenecks. In addition, efforts have been made for the heterologous expression of biosynthetic gene clusters in other organisms, looking not only for an increase of production levels but also to speed the process by using rapidly growing and easy to manipulate organisms compared to the producing organism. In this review, we will focus on these genetic approaches as applied to bioactive secondary metabolites produced by actinomycetes.     

转录因子调控植物萜类化合物生物合成研究进展

萜类化合物是植物次生代谢物中结构和数量最多的一类化合物, 它们在植物体内以及植物与环境和其它生命体的相互作用中发挥重要作用。转录因子通过调控代谢通路中基因的转录起始来调节次生代谢物质的产量。目前, 研究发现参与萜类合成的转录因子家族主要有6个, 包括AP2/ERF、bHLH、MYB、NAC、WRKY和bZIP。该文主要对其家族的结构特点、调控模式以及研究进展进行综述, 以期进一步丰富萜烯合成的网络调控, 为植物萜类相关的分子育种、优质栽培和病虫害生物防治等提供新的思路与方法。     

The biosynthesis and genetic engineering of bioactive indole alkaloids in plants

Indole alkaloids are widely distributed secondary metabolites that exhibit a broad range of pharmacological activities. They are synthesized through plant biosynthetic pathways involving complex enzyme activities and regulatory strategies. Since many compounds of indole alkaloids are structurally too complex to be manufactured economically by chemical synthesis, they have to be isolated from naturally grown or cultivated plants. Therefore, the biotechnological production of high-value plant secondary metabolites in cultivated cells or transgenic plants is potentially an attractive alternative. The present review describes the regulation of indole alkaloids biosynthesis, as well as their pharmacological functions in plants such as anti-microbes, anti-inflammatory and anti-tumor. Furthermore, it discusses different strategies by which the genetic engineering of indole alkaloids biosynthesis through the reconstruction of the pathway achieves high production of specific compounds.