Secondary transport as an efficient membrane transport mechanism for plant secondary metabolites

Plants produce a large number of secondary metabolites, such as alkaloids, terpenoids, and phenolic compounds. Secondary metabolites have various functions including protection against pathogens and UV light in plants, and have been used as natural medicines for humans utilizing their diverse biological activities. Many of these natural compounds are accumulated in a particular compartment such as vacuoles, and some are even translocated from source cells to sink organs via long distance transport. Both primary and secondary transporters are involved in such compartmentation and translocation, and many transporter genes, especially genes belonging to the multidrug and toxin extrusion type transporter family, which consists of 56 members in Arabidopsis, have been identified as responsible for the membrane transport of secondary metabolites. Better understandings of these transporters as well as the biosynthetic genes of secondary metabolites will be important for metabolic engineering aiming to increase the production of commercially valuable secondary metabolites in plant cells.     

Catabolism of citronellol and related acyclic terpenoids in pseudomonads

Terpenes are a huge group of natural compounds characterised by their predominantly pleasant smell. They are built up by isoprene units in cyclic or acyclic form and can be functionalised by carbonyl, hydroxyl or carboxyl groups and by presence of additional carbon–carbon double bonds (terpenoids). Currently, much more than 10,000 terpenoid compounds are known, and many thereof are present in different iso- and stereoforms. Terpenoids are secondary metabolites and can have important biological functions in living organisms. In many cases, the biological functions of terpenoids are not known at all. Nevertheless, terpenoids are used in large quantities as perfumes and aroma compounds for food additives. Terpenoids can be also precursors and building blocks for synthesis of complex chiral compounds in chemical and pharmaceutical industry. Unfortunately, only few terpenoids are available in large quantities at reasonable costs. Therefore, characterisation of suited biocatalysts specific for terpenoid compounds and development of biotransformation processes of abundant terpenoids to commercially interesting derivates becomes more and more important. This minireview summarises knowledge on catabolic pathways and biotransformations of acyclic monoterpenes that have received only little attention. Terpenoids with 20 or more carbon atoms are not a subject of this study.     

The secondary metabolism of Arabidopsis thaliana: growing like a weed

Despite its small stature, short life-cycle and highly reduced genome, Arabidopsis thaliana has a complement of secondary metabolites that is every bit as numerous and diverse as those of other plant taxa. The list of secondary metabolites isolated from this model species has expanded more than five-fold in the past ten years, and many more substances are likely to be added in the near future. Among the classes of compounds recently discovered are coumarins, benzenoids and terpenoids. Many A. thaliana secondary metabolites appear to have internal roles within the plant instead of (or in addition to) mediating ecological interactions.     

Integrated view of plant metabolic defense with particular focus on chewing herbivores

Success of plants largely depends on their ability to defend against herbivores. Since emergence of the first voracious consumers, plants maintained adapting their structures and chemistry to escape from extinction. The constant pressure was further accelerated by adaptation of herbivores to plant defenses, which all together sparked the rise of a chemical empire comprised of thousands of specialized metabolites currently found in plants. Metabolic diversity in the plant kingdom is truly amazing, and although many plant metabolites have already been identified, a large number of potentially useful chemicals remain unexplored in plant bio-resources. Similarly, biosynthetic routes for plant metabolites involve many enzymes, some of which still wait for identification and biochemical characterization. Moreover, regulatory mechanisms that control gene expression and enzyme activities in specialized metabolism of plants are scarcely known. Finally, understanding of how plant defense chemicals exert their toxicity and/or repellency against herbivores remains limited to typical examples, such as proteinase inhibitors, cyanogenic compounds and nicotine. In this review, we attempt summarizing the current status quo in metabolic defense of plants that is predominantly based on the survey of ubiquitous examples of plant interactions with chewing herbivores.     

Metabolic diversity and bioactivity screening of mangrove plants: a review

Mangrove forests are salt tolerant plants confined to the coastal areas and occupy only 5% of the total forest areas of the world. These are the most hostile environment with fluctuating tidal and saline regime and a limited plant species can survive under such condition. Nevertheless, these plants are most valuable resources and provide economic and ecological benefits to the coastal people. Several mangrove species have been used in traditional medicine or have few applications as insecticide and pesticide. Mangroves are biochemically unique, producing wide array of natural products with unique bioactivity. They possess active metabolites with some novel chemical structures which belong to diverse chemical classes such as alkaloids, phenol, steroids, terpenoids, tannins, etc. The present review examines recent investigations on the biological activities of extracts and phytochemicals identified from mangroves and their associates as antimicrobial, antiviral, antioxidant, anticancer and many other properties like antiproliferative, insecticidal, antimalarial, antifeedant, central nervous system depressant and anti-plasmodial etc. The present article also emphasizes and creates an awareness of potential mangroves and their associates as a source of novel medicines, agrochemicals and source of many biologically active compounds.     

The use of Aspergillus niger cultures for biotransformation of terpenoids

Aspergillus niger is a well-known fungus that has been used for many different biotransformations of organic compounds. The terpenoids include a large variety of natural hydrocarbons and their derivatives, mostly obtained from plant essential oils, but some obtained from animals or fungi. They may be acyclic or have one or more rings of various sizes, and they show a variety of biological activities that include antibacterial, antifungal, antiparasitic, antiviral, and anticancer activities. Terpenoids are classified as monoterpenoids (C₁₀), sesquiterpenoids (C₁₅), diterpenoids (C₂₀), triterpenoids (C₃₀), and others. This review summarizes experimental processes that use cultures of various A. niger strains to carry out stereoselective biochemical reactions in terpenoids, including related epoxides, lactones, N-phenylcarbamates, and saponins, to produce metabolites that may be useful as flavors and fragrances or as new experimental drug candidates. Cultures of A. niger that add hydroxyl, carbonyl, and other groups at specific positions or reduce double bonds have resulted in the production of valuable new compounds.     

Metabolome‐genome‐wide association study dissects genetic architecture for generating natural variation in rice secondary metabolism

Plants produce structurally diverse secondary (specialized) metabolites to increase their fitness for survival under adverse environments. Several bioactive compounds for new drugs have been identified through screening of plant extracts. In this study, genome‐wide association studies (GWAS) were conducted to investigate the genetic architecture behind the natural variation of rice secondary metabolites. GWAS using the metabolome data of 175 rice accessions successfully identified 323 associations among 143 single nucleotide polymorphisms (SNPs) and 89 metabolites. The data analysis highlighted that levels of many metabolites are tightly associated with a small number of strong quantitative trait loci (QTLs). The tight association may be a mechanism generating strains with distinct metabolic composition through the crossing of two different strains. The results indicate that one plant species produces more diverse phytochemicals than previously expected, and plants still contain many useful compounds for human applications.     

萜类合成酶定向进化的新思路

萜类化合物是天然产物中种类最多且主要存在于植物和微生物体内的一类化合物。随着越来越多具有应用价值的萜类化合物被挖掘,其应用前景引起了人们的关注,但由于含量低、提取成本高等缺点,因此制约了萜类化合物的广泛应用。合成生物学的兴起,为异源合成具有应用价值的萜类化合物提供了新思路,使构建定向、高效的微生物细胞工厂成为现实。萜类合成酶常作为萜类化合物异源合成代谢调控的靶酶,但天然的萜类合成酶存在催化效率低、底物专一性差、立体/区域选择性差、稳定性差等问题,严重影响萜类化合物的产量。萜类合成酶的定向进化可以有效地解决上述问题,为实现微生物细胞工厂异源、高效合成萜类化合物奠定基础。本文综述了近年来酶的定向进化技术的最新进展及应用,并提出了萜类合成酶定向进化的策略。     

代谢改造酿酒酵母合成萜类化合物的研究进展

萜类化合物是一类种类繁多、功能多样的化合物,部分具有抗癌、增强免疫力等作用,具有良好的生物活性,在食品、保健品以及医疗等领域应用广泛.近年来,随着对萜类化合物生物合成途径研究的深入,研究人员采用代谢工程手段构建了多种萜类产物的高产酿酒酵母工程菌株,部分已经达到或者接近工业化生产水平.因此,采用合成生物学相关技术手段合成...     

植物萜类生物合成中的后修饰酶

萜类化合物由于其结构类型丰富多样而被称为"terpenome".除了参与植物生长发育、环境应答等生理过程,萜类化合物还应用于医药、有机化工等领域.萜类的生物合成大致可分为前体形成、骨架构建以及后修饰三部分,基本骨架通常由萜类合酶催化形成,进一步在后修饰酶的作用下产生数以万计的萜类化合物.结合我们对香茶菜二萜生物合成的初步研究结果,本文主要针对近年来植物萜类生物合成中的一些有代表性的后修饰酶包括P450单氧酶、双键还原酶、酰基转移酶和糖基转移酶,进行研究现状分析与展望.     

植物萜类次生代谢及其调控

植物次生代谢在植物生长发育、环境适应、抵御病虫害等方面发挥着重要作用,这些天然产物组成地球上最丰富的有机化合物的宝库．萜类是植物代谢产物中种类最多的一类,具有重要的生理和生态功能,一些成分还有应用价值．近十几年来,人们在萜类化合物的分离、鉴定、应用、生物合成、相关基因与基因族、酶蛋白结构和功能、代谢调控以及代谢工程等各方面取得了重大进展．本文概述了植物萜类化合物代谢及其调控领域的研究进展与发展趋势．     

Plant Terpenoids： Biosynthesis and Ecological Functions

Among plant secondary metabolites terpenolds are a structurally most diverse group; they function as phytoalexins In plant direct defense, or as signals In Indirect defense responses which involves herbivores and their natural enemies. In recent years, more and more attention has been paid to the Investigation of the ecological role of plant terpenolds. The biosynthesis pathways of monoterpenes, sesquiterpenes, and diterpenes Include the synthesis of C5 precursor isopentenyl diphosphate （IPP） and Its allylic isomer dlmethylallyl dlphosphate （DMAPP）, the synthesis of the immediate diphosphate precursors, and the formation of the diverse terpenoids. Terpene synthases （TPSs） play a key role In volatile terpene synthesis. By expression of the TPS genes, significant achievements have been made on metabolic engineering to Increase terpenoid production. This review mainly summarizes the recent research progress In elucidating the ecological role of terpenoids and characterization of the enzymes Involved in the terpenold biosynthesis. Spatial and temporal regulations of terpenoids metabolism are also discussed.     

Endophytic fungi from medicinal plants: a treasure hunt for bioactive metabolites

Endophytic fungi are ubiquitous organisms found in the plants, residing intercellular or intracellular, at least for a portion of their lives without causing apparent symptoms of infection. Almost all plants are known to harbor endophytes. The choice of the plant to be used for exploring endophytes for bioactives is important. Therefore, medicinal plants which are known to be used since centuries as an alternative source of medicine, are a valuable source for bioprospecting endophytes. Nevertheless, due to many reasons there is a dire need for novel resources for novel drugs which can be an answer to many deadly diseases. It is in this context that the present review was envisaged. The review reveals the importance of endophytic fungi from medicinal plants as a source of bioactive and chemically novel compounds. The bioactive metabolites produced by endophytic fungi originate from different biosynthetic pathways and belong to diverse structural groups such as terpenoids, steroids, quinones, phenols, coumarins etc. Endophytes therefore, represent a chemical reservoir for new compounds such as, anticancer, immunomodulatory, antioxidant, antiparasitic, antiviral, antitubercular, insecticidal etc. for use in the pharmaceutical and agrochemical industries. Although, efforts have been made to accommodate as many examples as possible but the depth of the subject is so vast that it cannot be covered in one single review. This in itself speaks of the fact that endophytic fungi from medicinal plants is indeed a treasure worth searching. In the present review only some selected examples have been covered.     

Biosynthesis of plant-specific stilbene polyketides in metabolically engineered Escherichia coli

Background  

Phenylpropanoids are the precursors to a range of important plant metabolites such as the cell wall constituent lignin and the secondary metabolites belonging to the flavonoid/stilbene class of compounds. The latter class of plant natural products has been shown to function in a wide range of biological activities. During the last few years an increasing number of health benefits have been associated with these compounds. In particular, they demonstrate potent antioxidant activity and the ability to selectively inhibit certain tyrosine kinases. Biosynthesis of many medicinally important plant secondary metabolites, including stilbenes, is frequently not very well understood and under tight spatial and temporal control, limiting their availability from plant sources. As an alternative, we sought to develop an approach for the biosynthesis of diverse stilbenes by engineered recombinant microbial cells.     

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。     

Secondary metabolites and plant/environment interactions: a view through Arabidopsis thaliana tinged glasses

Arabidopsis thaliana is a successful model plant for studying wide‐ranging topics including plant development, genetics and pathogen resistance. In addition, significant research has been conducted in the area of secondary metabolite biochemical genetics. The secondary metabolites in Arabidopsis include glucosinolates, terpenoids, phenylpropanoids, the alkaloid‐like camalexin, and other uncharacterized compounds. The genetic tools developed in studying secondary metabolite biochemistry are now being used to study how secondary metabolites control various biological processes. This includes compounds involved in plant/insect and plant/pathogen interactions, compounds preventing UV‐B damage, and compounds involved in hormone homeostasis. This review will describe what light Arabidopsis is shedding on the biological and ecological importance of specific secondary metabolites.     

Terpenoid bio-transformations and applications via cell/organ cultures: a systematic review

Abstract

Structurally diverse natural products are valued for their targeted biological activity. The challenge of working with such metabolites is their low natural abundance and complex structure, often with multiple stereocenters, precludes large-scale or unsophisticated chemical synthesis. Since select plants contain the enzymatic machinery necessary to produce specialized compounds, tissue cultures can be used to achieve key transformations for large-scale chemical and/or pharmaceutical applications. In this context, plant tissue-culture bio-transformations have demonstrated great promise in the preparation of pharmaceutical products. This review describes the capacity of cultured plant cells to transform terpenoid natural products and the specific application of such transformations over the past three decades (1988–2019).     

The biosynthetic potential of plant roots

The contribution of roots to the biology of the whole plant is being reevaluated in the light of classical and recent findings. In addition to their role in water and nutrient uptake and in symbiotic associations, plant roots also synthesize a remarkable variety of secondary metabolites. These chemicals, many of which are used as pharmaceuticals, agrichemicals, flavors, dyes, or fragrances, may help the plant cope with biotic and abiotic stress. Root cultures are being used as experimental systems to explore both root-specific secondary metabolites and their biological significance. They may also provide future systems for commercial production of plant specialty chemicals.     

Synthetic biosystems for the production of high-value plant metabolites

Plants display an immense diversity of specialized metabolites, many of which have been important to humanity as medicines, flavors, fragrances, pigments, insecticides and other fine chemicals. Apparently, much of the variation in plant specialized metabolism evolved through events of gene duplications followed by neo- or sub-functionalization. Most of the catalytic diversity of plant enzymes is unexplored since previous biochemical and genomics efforts have focused on a relatively small number of species. Interdisciplinary research in plant genomics, microbial engineering and synthetic biology provides an opportunity to accelerate the discovery of new enzymes. The massive identification, characterization and cataloguing of plant enzymes coupled with their deployment in metabolically optimized microbes provide a high-throughput functional genomics tool and a novel strain engineering pipeline.