New insight into the biosynthesis and regulation of indole compounds in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

In spite of their silent and sessile life, plants are dynamic organisms that have developed advanced defence strategies in their adaptation to the pressure of herbivores and pathogens. Natural plant products play an important role as chemical weapons in this warfare. Characteristic of cruciferous plants is the synthesis of nitrogen- and sulphur-rich compounds, such as glucosinolates (Mikkelsen et al. 2002) and indole alkaloids (Pedras et al. 2000). Glucosinolates are believed to be largely non-toxic, but upon tissue disruption, they are hydrolyzed by endogenous -thioglucosidases (myrosinases) (Rask et al. 2000) to primarily isothiocyanates and nitriles, which have many biological activities. These include not only important roles as repellents against herbivorous insects and microorganisms, but also as volatile attraction of specialized insects (Wittstock and Halkier 2002). For humans, these compounds serve as cancer-preventive agents, biopesticides, and flavor compounds (Talalay and Fahey 2001). Indole alkaloids are phytoalexins and production of specific alkaloids is usually limited to only a few species. Cruciferous plants include the model plant Arabidopsis, which produces the indole alkaloid camalexin. This review will focus on the central role of indole-3-acetaldoxime (IAOx) in the biosynthesis of indole glucosinolates, camalexin, and the phytohormone IAA.     

Oxidative stress and production of bioactive monoterpene indole alkaloids: biotechnological implications

Monoterpene indole alkaloids (MIAs) encompass plant natural products with important pharmacological relevance. They include the anti-tumoral MIAs found in Catharanthus roseus and Camptotheca acuminata. The often low yields of bioactive alkaloids in plants has prompted research to identify the factors regulating MIA production. Oxidative stress is a general response associated with biotic and abiotic stresses leading to several secondary responses, including elicitation of MIA production. These changes in secondary metabolism may take place directly or via second messengers, such as Ca²⁺ and reactive oxygen species (ROS). H₂O₂ is the main ROS that participates in MIA biosynthesis. This review analyzes the links between oxidative stress, elicitation of bioactive MIA production and their potential roles in antioxidant defense, as well as exploring the implications to developing biotechnological strategies relevant for alkaloid supply.     

Cytochromes P450 in the biosynthesis of glucosinolates and indole alkaloids

Characteristic of cruciferous plants is the synthesis of nitrogen- and sulfur-rich compounds, such as glucosinolates and indole alkaloids. The intact glucosinolates have limited biological activity, but give rise to an array of bio-active breakdown products when hydrolysed by endogenous β-thioglucosidases (myrosinases) upon tissue disruption. Both glucosinolates and indole alkaloids constitute an important part of the defence of plants against herbivores and pathogens, with the difference that a basal level of glucosinolates is ever-present in the plant whereas indole alkaloids are true phytoalexins that are de novo synthesised upon pathogen attack. With the completion of the genome sequence of the model plant, Arabidopsis thaliana, which is a crucifer, many genes involved in the biosynthesis of glucosinolates and indole alkaloids have been identified and cytochromes P450 are key players in these pathways. In the present review, we will focus on the cytochromes P450 in the biosynthesis of both groups of compounds. Their functional roles and regulation will be discussed.     

环境因子对植物萜类化合物生物合成的影响研究进展

植物在应对不同环境胁迫时会做出不同的应对措施,其中一种常见的方式是产生次生代谢产物。萜类化合物为植物次生代谢产物中种类最多、结构最复杂的一类化合物,几乎存在于所有植物中,发挥着重要的生物功能,很多具有显著的药理活性,如免疫调节、抗肿瘤、降血脂、保肝等。该文对近年来国内外有关环境温度、紫外线辐射、光照、干旱、臭氧及植物生长发育阶段等环境因素对植物萜类化合物合成影响的研究进展进行综述,探究植物萜类化合物受环境因子影响产生应激反应的一般性规律。     

Metabolic Engineering of Tropane Alkaloid Biosynthesis in Plants

Over the past decade, the evolving commercial importance of so-called plant secondary metabolites has resulted in a great interest in secondary metabolism and, particularly, in the possibilities to enhance the yield of fine metabolites by means of genetic engineering. Plant alkaloids, which constitute one of the largest groups of natural products, provide many pharmacologically active compounds. Several genes in the tropane alkaloids biosynthesis pathways have been cloned, making the metabolic engineering of these alkaloids possible. The content of the target chemical scopolamine could be significantly increased by various approaches, such as introducing genes encoding the key biosynthetic enzymes or genes encoding regulatory proteins to overcome the specific rate-limiting steps. In addition, antisense genes have been used to block competitive pathways. These investigations have opened up new, promising perspectives for increased production in plants or plant cell culture. Recent achievements have been made in the metabolic engineering of plant tropane alkaloids and some new powerful strategies are reviewed in the present paper.     

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.     

Metabolic Engineering of Tropane Alkaloid Biosynthesis in Plants

Over the past decade, the evolving commercial importance of so-called plant secondary metabolites has resulted in a great interest in secondary metabolism and, particularly, in the possibilities to enhance the yield of fine metabolites by means of genetic engineering. Plant alkaloids, which constitute one of the largest groups of natural products, provide many pharmacologically active compounds. Several genes in the tropane alkaloids biosynthesis pathways have been cloned, making the metabolic engineering of these alkaloids possible. The content of the target chemical scopolamine could be significantly increased by various approaches, such as introducing genes encoding the key biosynthetic enzymes or genes encoding regulatory proteins to overcome the specific rate-limiting steps. In addition, antisense genes have been used to block competitive pathways. These investigations have opened up new, promising perspectives for increased production in plants or plant cell culture. Recent achievements have been made in the metabolic engineering of plant tropane alkaloids and some new powerful strategies are reviewed in the present paper.     

Effect of plant growth regulators on the biosynthesis of vinblastine,vindoline and catharanthine in <Emphasis Type="Italic">Catharanthus roseus</Emphasis>

Catharanthuse roseus is a well-known medicinal plant for its two valuable anticancer compounds: vinblastine and vincristine, which belongs to terpenoid indole alkaloids. Great efforts have been made to study the principles of its secondary metabolic pathways to regulate the alkaloids biosynthesis. In this article, different plant growth regulators were shortly applied to Catharanthus roseus plants during the blooming period to study their effects on the biosynthesis of vinblastine, vindoline and catharanthine. Salicylic acid and ethylene (ethephon) treatments resulted in a significant increase of vinblastine, vindoline and catharanthine while abscisic acid and gibberellic acid had a strongly negative influence on the accumulation of the three important alkaloids. Methyl jasmonate showed no great effect on the production of these valuable alkaloids. Chlormequat chloride highly enhanced the accumulation of vinblastine but greatly decreased the contents of vindoline and catharanthine.     

Opium poppy and Madagascar periwinkle: model non-model systems to investigate alkaloid biosynthesis in plants

Alkaloids represent a large and diverse group of compounds that are related by the occurrence of a nitrogen atom within a heterocyclic backbone. Unlike other types of secondary metabolites, the various structural categories of alkaloids are unrelated in terms of biosynthesis and evolution. Although the biology of each group is unique, common patterns have become apparent. Opium poppy ( Papaver somniferum ), which produces several benzylisoquinoline alkaloids, and Madagascar periwinkle ( Catharanthus roseus ), which accumulates an array of monoterpenoid indole alkaloids, have emerged as the premier organisms used to study plant alkaloid metabolism. The status of these species as model systems results from decades of research on the chemistry, enzymology and molecular biology responsible for the biosynthesis of valuable pharmaceutical alkaloids. Opium poppy remains the only commercial source for morphine, codeine and semi-synthetic analgesics, such as oxycodone, derived from thebaine. Catharanthus roseus is the only source for the anti-cancer drugs vinblastine and vincristine. Impressive collections of cDNAs encoding biosynthetic enzymes and regulatory proteins involved in the formation of benzylisoquinoline and monoterpenoid indole alkaloids are now available, and the rate of gene discovery has accelerated with the application of genomics. Such tools have allowed the establishment of models that describe the complex cell biology of alkaloid metabolism in these important medicinal plants. A suite of biotechnological resources, including genetic transformation protocols, has allowed the application of metabolic engineering to modify the alkaloid content of these and related species. An overview of recent progress on benzylisoquinoline and monoterpenoid indole alkaloid biosynthesis in opium poppy and C. roseus is presented.     

珙桐科植物化学成分研究进展(综述)

本文概述从珙桐科植物中得到的数十种化合物的结构和波谱数据及药理活性,这些化合物大多结构新颖、具有较强生理活性,主要为喹啉类生物碱、吲哚类生物碱、鞣花酸类化合物、黄酮类化合物以及其它化合物。     

Plant cytochromes P450: tools for pharmacology,plant protection and phytoremediation

Cytochromes P450 catalyse extremely diverse and often complex regiospecific and/or stereospecific reactions in the biosynthesis or catabolism of plant bioactive molecules. Engineered P450 expression is needed for low-cost production of antineoplastic drugs such as taxol or indole alkaloids and offers the possibility to increase the content of nutraceuticals such as phytoestrogens and antioxidants in plants. Natural products may serve important functions in plant defence and metabolic engineering of P450s is a prime target to improve plant defence against insects and pathogens. Herbicides, pollutants and other xenobiotics are metabolised by some plant P450 enzymes. These P450s are tools to modify herbicide tolerance, as selectable markers and for bioremediation.     

Catharanthus biosynthetic enzymes: the road ahead

Alkaloids are one of the most diverse groups of secondary metabolites found in living organisms. The most economically important alkaloids are the bisindole vinblastine, and vincristine. Unraveling the complexity of the genetic, catalytic and transport processes of monoterpene indole alkaloids biosynthesis is one of the most stimulating intellectual challenges in the plant secondary metabolism field. More than 50 metabolic steps are required to synthesize the most important alkaloids in Catharanthus roseus. Until now about only 20 of the 50 enzymes required for their biosynthesis have been determined and characterized. Hence, there are still a number of important enzymes that need to be characterized, beginning with the isolation and cloning of genes. It is also of fundamental importance to elucidate the regulatory aspects of their biosynthesis, both at the cellular and the molecular level, in order to address the question of their function in the plants that are producing them. In this review, we present an analysis of the state of the art related to the biosynthesis of the monoterpene indole alkaloids.     

Effects of light and plant growth regulators on the biosynthesis of vindoline and other indole alkaloids in Catharanthus roseus callus cultures

A callus strain with stable ability for vindoline synthesis was selected from many prepared Catharanthus roseus leaf calli to study the regulation of vindoline biosynthesis as well as other indole alkaloids. It was shown that light and plant growth regulators significantly influenced the biosynthesis of vindoline and other alkaloids as well as acidic and basic peroxidase activities. Light promoted vindoline and serpentine biosynthesis, and stimulated plastid development and peroxidase activity. However, 2,4-D suppressed the biosynthesis of all indole alkaloids and peroxidase activity. Our results suggest that light or plant hormones regulate vindoline, serpentine and other alkaloid biosynthesis and accumulation by influencing peroxidase activity and the differentiation status of callus cultures, especially chloroplast development. Some possible relationships between serpentine or vindoline biosynthesis and peroxidase activity are proposed.     

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.     

Catharanthus roseus: micropropagation and in vitro techniques

Different methods of in vitro culture of Catharanthus roseus provide new sources of plant material for the production of secondary metabolites such as indole alkaloids. Callus, cell suspension, plantlets, and transgenic roots cultured in the bioreactor are used in those experiments. The most promising outcomes include the production of the following indole alkaloids: ajmalicine in unorganised tissue, catharanthine in the leaf and cell culture in the shake flask and airlift bioreactor, and vinblastine in shoots and transformed roots. What is very important, enzymatic coupling of monomeric indole alkaloids, vindoline and catharanthine, is possible to form vinblastine in cell cultures. The method of catharanthine and ajmalicine production in the suspension culture in bioreactors has been successful. In this method, elicitation may be used acting on different metabolic pathways. Also of interest is the method of obtaining arbutin from the callus culture of C. roseus conducted with hydroquinone. The transformed root culture seems to be the most promising for alkaloid production. The genetically transformed roots, obtained by the infection with Agrobacterium rhizogenes, produce higher levels of secondary metabolites than intact plants. Also, whole plants can be regenerated from hairy roots. The content of indole alkaloids in the transformed roots was similar or even higher when compared to the amounts measured in studies of natural roots. The predominant alkaloids in transformed roots are ajmalicine, serpentine, vindoline and catharanthine, found in higher amounts than in untransformed roots. Transformed hairy roots have been also used for encapsulation in calcium alginate to form artificial seeds.     

Evolutionary and cellular webs in benzylisoquinoline alkaloid biosynthesis

Alkaloids are a group of approximately 12,000 low molecular weight and nitrogenous secondary metabolites found in 20% of plant species. Their potent biological activity suggests that alkaloids function as defense compounds. Benzylisoquinoline alkaloids (BIAs) are derived from tyrosine and are diversified by an intricate biochemical network of intramolecular coupling, reduction, methylation, hydroxylation, and other reactions to generate the estimated 2500 known structures. Several BIAs are used directly as pharmaceuticals or serve as precursors for the synthesis of semi-synthetic drugs. Plants remain the only economical source for the production of compounds such as morphine and codeine owing to their chemical complexity, which makes de novo synthesis challenging and costly. Much research has been directed toward understanding the biosynthesis of the BIAs and manipulating source plants to increase production of key products and pathway intermediates. However, metabolic engineering experiments often yield unexpected results demonstrating the need for an improved perspective on the biochemistry, regulation, and cell biology of BIA pathways. This review summarizes recent advances in the establishment of predictive metabolic engineering within the context of plant alkaloid biosynthesis.     

Alkaloid Uptake Increases Fitness in a Hemiparasitic Plant via Reduced Herbivory and Increased Pollination

It has been historically difficult to manipulate secondary compounds in living plants to assess how these compounds influence plant-herbivore and plant-pollinator interactions. Using a hemiparasitic plant that takes up secondary compounds from host plants, I experimentally manipulated secondary compounds in planta and assessed their effects on herbivores and pollinators in the field. Here, I show that the uptake of alkaloids in the annual hemiparasite Castilleja indivisa resulted in decreased herbivory, increased visitation by pollinators, and increased lifetime seed production. These results indicate that resistance traits such as alkaloids can increase plant fitness directly by reducing herbivore attack and indirectly by increasing pollinator visitation to defended plants. Thus, selection for production of secondary compounds may be underestimated by considering only the direct effect of herbivores on plant fitness.     

Enzymatic oxidations in the biosynthesis of complex alkaloids

The biosynthesis of complex alkaloids in plants involves enzymes that, due to high substrate specificity, appear to have evolved solely for a role in secondary metabolism. At least one class of these enzymes, the oxidoreductases, catalyze transformations that are in some cases difficult to chemically mimick with an equivalent stereo- or regiospecificity and yield. Oxidoreductases are frequently catalyzing reactions that result in the formation of parent ring systems, thereby determining the class of alkaloid that a plant will produce. The oxidoreductases of alkaloid formation are a potential target for the biotechnological exploitation of medicinal plants in that they could be used for biomimetic syntheses of alkaloids. Analyzing the molecular genetics of alkaloid biosynthetic oxidations is requisite to eventual commercial application of these enzymes. To this end, a wealth of knowledge has been gained on the biochemistry of select monoterpenoid indole and isoquinoline biosynthetic pathways, and in recent years this has been complemented by molecular genetic analyses. As the nucleotide sequences of the oxidases of alkaloid synthesis become known, consensus sequences specific to select classes of enzymes can be identified. These consensus sequences will potentially facilitate the direct cloning of alkaloid biosynthetic genes without the need to purify the native enzyme for partial amino acid sequence determination or for antibody production prior to cDNA isolation. The current state of our knowledge of the biochemistry and molecular genetics of oxidases involved in alkaloid biosynthesis is reviewed herein.     

A review of the ethnomedicinal uses,phytochemistry and pharmacology of the <Emphasis Type="Italic">Pleiocarpa</Emphasis> genus

Pleiocarpa genus is a flowering plant from the Apocynaceae family which are rich sources of phytochemicals and have been reported to be useful in the treatment of gastrointestinal ailments, fever, malaria, pain, diabetes and cancer. The aim of this review is to present the past and current ethnomedicinal uses, phytochemistry and the pharmacology of Pleiocarpa genus which are underexploited as revealed through this review in order to enhance its potential source of phytochemical leads in medicine. Some pharmacological activities of these plants based on their acclaimed ethnomedicinal uses have been investigated by various researchers. The chemical profile of the genus is limited to alkaloids and triterpenoids, where indole alkaloids may be considered as important taxonomical markers.     

Molecular cloning and functional bacterial expression of a plant glucosidase specifically involved in alkaloid biosynthesis

Monoterpenoid indole alkaloids are a vast and structurally complex group of plant secondary compounds. In contrast to other groups of plant products which produce many glycosides, indole alkaloids rarely occur as glucosides. Plants of Rauvolfia serpentina accumulate ajmaline as a major alkaloid, whereas cell suspension cultures of Rauvolfia mainly accumulate the glucoalkaloid raucaffricine at levels of 1.6 g/l. Cell cultures do contain a specific glucosidase. known as raucaffricine-O-beta-D-glucosidase (RG), which catalyzes the in vitro formation of vomilenine, a direct intermediate in ajmaline biosynthesis. Here, we describe the molecular cloning and functional expression of this enzyme in Escherichia coli. RG shows up to 60% amino acid identity with other glucosidases of plant origin and it shares several sequence motifs with family 1 glucosidases which have been characterized. The best substrate specificity for recombinant RG was raucaffricine (KM 1.3 mM, Vmax 0.5 nkat/microg protein) and only a few closely related structural derivatives were also hydrolyzed. Moreover, an early intermediate of ajmaline biosynthesis, strictosidine, is a substrate for recombinant RG (KM 1.8 mM, Vmax 2.6 pkat/microg protein) which was not observed for the low amounts of enzyme isolated from Rauvolfia cells.