Chemistry and biological activity of azoprenylated secondary metabolites

N-Prenyl secondary metabolites (isopentenylazo-, geranylazo-, farnesylazo- and their biosynthetic derivatives) represent a family of extremely rare natural products. Only in recent years have these alkaloids been recognized as interesting and valuable biologically active secondary metabolites. To date about 35 alkaloids have been isolated from plants mainly belonging to the Rutaceae family, and from fungi, bacteria, and/or obtained by chemical synthesis. These metabolites comprise anthranilic acid derivatives, diazepinones, and indole, and xanthine alkaloids. Many of the isolated prenylazo secondary metabolites and their semisynthetic derivatives are shown to exert valuable in vitro and in vivo anti-cancer, anti-inflammatory, anti-bacterial, anti-viral, and anti-fungal effects. The aim of this comprehensive review is to examine the different types of prenylazo natural products from a chemical, phytochemical and biological perspective.     

Monascus secondary metabolites: production and biological activity

The genus Monascus, comprising nine species, can reproduce either vegetatively with filaments and conidia or sexually by the formation of ascospores. The most well-known species of genus Monascus, namely, M. purpureus, M. ruber and M. pilosus, are often used for rice fermentation to produce red yeast rice, a special product used either for food coloring or as a food supplement with positive effects on human health. The colored appearance (red, orange or yellow) of Monascus-fermented substrates is produced by a mixture of oligoketide pigments that are synthesized by a combination of polyketide and fatty acid synthases. The major pigments consist of pairs of yellow (ankaflavin and monascin), orange (rubropunctatin and monascorubrin) and red (rubropunctamine and monascorubramine) compounds; however, more than 20 other colored products have recently been isolated from fermented rice or culture media. In addition to pigments, a group of monacolin substances and the mycotoxin citrinin can be produced by Monascus. Various non-specific biological activities (antimicrobial, antitumor, immunomodulative and others) of these pigmented compounds are, at least partly, ascribed to their reaction with amino group-containing compounds, i.e. amino acids, proteins or nucleic acids. Monacolins, in the form of β-hydroxy acids, inhibit hydroxymethylglutaryl-coenzyme A reductase, a key enzyme in cholesterol biosynthesis in animals and humans.     

Identification and biological activity of secondary metabolites from Dryobalanops beccarii

A new trimeric oligostilbene, malaysianol D (1) and galloylglucoside, malaysin A (2), together with twelve known compounds (3–14) have been isolated from the methanol extract of the stem bark of Dryobalanops beccarii by combination of vacuum and radial chromatography techniques. Their structures were established on the basis of their spectroscopic evidence and comparison with the published data. The cytotoxic activity of isolated compounds was tested against A549 and MCF-7 cancer cell lines.     

The antiviral activity of cyclopentane β,β′-triketones related to secondary metabolites of higher plants

The effect of 20 cyclopentane β,β′-triketones and their sodium salts on the development of infections caused by tobacco mosaic virus (TMV) in leaves of tobacco (Nicotiana tabacum L. cv. Xanthi-nc) has been studied. It has been shown that the strongest antiviral effect is produced by sodium salts of 2-acetyl-4,7-dithio-2,3,4,5,6,7-hexahydro-1H-inden-1,3-dione, 2-acetyl-4-oxa-7-thio-2,3,4,5,6,7-hexahydro-1H-inden-1,3-dione, and 2-acetyl-4,5-didodecylthiocyclopent-4-en-1,3-dione. These compounds at a concentration of 2 mg/mL decrease the number of local TMV-induced necroses formed on inoculated tobacco leaves by 98% and have no toxic effect on leaf tissues.     

Secondary metabolites of plants from the genus cipadessa: chemistry and biological activity

The plants of genus Cipadessa, which are distributed across India and southwest of China, have been used as natural insecticides, as well as folk medicines for the treatment of a range of maladies such as diabetes, dysentery, malaria, piles, snake poison, rheumatism, etc. This article reviews the chemical constituents that have been isolated from Cipadessa species to date, including their biological activities. The compounds listed are tetranortriterpenoids (limonoids), diterpenoids, sesquiterpenoids, flavonoids, steroids, and some others.     

Secondary metabolites of plants from the genus Saussurea: chemistry and biological activity

The Asteraceae family comprises ca. 1000 genera, mainly distributed in Asia and Europe. Saussurea DC., as the largest subgenus of this family, comprises ca. 400 species worldwide, of which ca. 300 species occur in China. Most plants in China grow wild in the alpine zone of the Qingzang Plateau and adjacent regions at elevations of 4000 m. Plants of the genus Saussurea (Asteraceae) are used in both traditional Chinese folk medicine and Tibet folklore medicine, since they are efficacious in relieving internal heat or fever, harmonizing menstruation, invigorating blood circulation, stopping bleeding, alleviating pain, increasing energy, and curing rheumatic arthritis. A large number of biologically active compounds have been isolated from this genus. This review shows the chemotaxonomy of these compounds (215 compounds) such as sesquiterpenoids (101 compounds), flavonoids (19 compounds), phytosterols (15 compounds), triterpenoids (25 compounds), lignans (32 compounds), phenolics (23 compounds), and chlorophylls (11 compounds). Biological activities (anti‐inflammatory, anticancer, antitumor, hepatoprotective, anti‐ulcer, cholagogic, immunosuppressive, spasmolytic, antimicrobial, antiparasitic, antifeedant, CNS depressant, antioxidant, etc.) of these compounds, including structure–activity relationships, are also discussed.     

Proximate composition and biological activity of food plants gathered by chilean Amerindians

The proximate composition and biological activity of food plants and mushrooms gathered by Chilean Amerindians were assessed. The gathered plants served primarily as sources of carbohydrates with highest values for Dioscorea tubers, Prosopis alba pods meal and Bromus catharticus seeds. The mushrooms Clavaria coralloides and Boletus loyus proved to be the best protein sources in our survey, but deficient in the amino acids methionine and cysteine. Some extracts of the plants and mushrooms under study showed biological activity as free radical scavengers, enzyme inhibitors, hypotensive or DNA binding effect. Free radical scavenging activity was detected in Cryptocarya alba fruit extract, while Typha angustifolia showed a strong DNA binding effect at 0.50 mg/ml. Methanolic extracts of the Apiaceae species Sanicula graveolens and Apium australe were moderately active as β-glucuronidase inhibitors at 50 fig/ml.     

Influence of abiotic stress signals on secondary metabolites in plants

Plant secondary metabolites are unique sources for pharmaceuticals, food additives, flavors, and industrially important biochemicals. Accumulation of such metabolites often occurs in plants subjected to stresses including various elicitors or signal molecules. Secondary metabolites play a major role in the adaptation of plants to the environment and in overcoming stress conditions. Environmental factors viz. temperature, humidity, light intensity, the supply of water, minerals, and CO₂ influence the growth of a plant and secondary metabolite production. Drought, high salinity, and freezing temperatures are environmental conditions that cause adverse effects on the growth of plants and the productivity of crops. Plant cell culture technologies have been effective tools for both studying and producing plant secondary metabolites under in vitro conditions and for plant improvement. This brief review summarizes the influence of different abiotic factors include salt, drought, light, heavy metals, frost etc. on secondary metabolites in plants. The focus of the present review is the influence of abiotic factors on secondary metabolite production and some of important plant pharmaceuticals. Also, we describe the results of in vitro cultures and production of some important secondary metabolites obtained in our laboratory.     

Silica in plants: biological, biochemical and chemical studies

BACKGROUND: The incorporation of silica within the plant cell wall has been well documented by botanists and materials scientists; however, the means by which plants are able to transport silicon and control its polymerization, together with the roles of silica in situ, are not fully understood. RECENT PROGRESS: Recent studies into the mechanisms by which silicification proceeds have identified the following: an energy-dependent Si transporter; Si as a biologically active element triggering natural defence mechanisms; and the means by which abiotic toxicities are alleviated by silica. A full understanding of silica formation in vivo still requires an elucidation of the role played by the environment in which silica formation occurs. Results from in-vitro studies of the effects of cell-wall components associated with polymerized silica on mineral formation illustrate the interactions occurring between the biomolecules and silica, and the effects their presence has on the mineralized structures so formed. SCOPE: This Botanical Briefing describes the uptake, storage and function of Si, and discusses the role biomolecules play when incorporated into model systems of silica polymerization as well as future directions for research in this field.     

Molluscan biological and chemical diversity: secondary metabolites and medicinal resources produced by marine molluscs

The phylum Mollusca represents an enormous diversity of species with eight distinct classes. This review provides a taxonomic breakdown of the published research on marine molluscan natural products and the medicinal products currently derived from molluscs, in order to identify priority targets and strategies for future research. Some marine gastropods and bivalves have been of great interest to natural products chemists, yielding a diversity of chemical classes and several drug leads currently in clinical trials. Molluscs also feature prominently in a broad range of traditional natural medicines, although the active ingredients in the taxa involved are typically unknown. Overall secondary metabolites have only been investigated from a tiny proportion (<1%) of molluscan species. At the class level, the number of species subject to chemical studies mirrors species richness and our relative knowledge of the biology of different taxa. The majority of molluscan natural products research is focused within one of the major groups of gastropods, the opisthobranchs (a subgroup of Heterobranchia), which are primarily comprised of soft‐bodied marine molluscs. Conversely, most molluscan medicines are derived from shelled gastropods and bivalves. The complete disregard for several minor classes of molluscs is unjustified based on their evolutionary history and unique life styles, which may have led to novel pathways for secondary metabolism. The Polyplacophora, in particular, have been identified as worthy of future investigation given their use in traditional South African medicines and their abundance in littoral ecosystems. As bioactive compounds are not always constitutively expressed in molluscs, future research should be targeted towards biosynthetic organs and inducible defence reactions for specific medicinal applications. Given the lack of an acquired immune system, the use of bioactive secondary metabolites is likely to be ubiquitous throughout the Mollusca and broadening the search field may uncover interesting novel chemistry.     

Chemical and biological aspects of sponge secondary metabolites

Sponge secondary metabolites have been investigated to find potential lead compounds for the development of commercially interesting products. During the Camellia project entitled Environmentally compatible antifouling coatings for the protection of ships, water systems, fish cages and other immersed structures against aquatic growth, several analogues of terpenes containing isocyano, thioisocyano, thiocyano and formamide functionalities were synthesized and evaluated for their antifouling activity against the settlement of the barnacle Balanus amphitrite. The best activities were obtained with N-formylated alkylamines the length of the carbon chain of which is comprised between C-11 and C-14. In the aromatic series, the isocyano derivatives showed high antifouling activities. But they were too toxic against many microorganisms to be incorporated in paint formulations. During the Symbiosponge project entitled Biology of sponge natural products the methanolic extract of about 230 sponges were submitted to bioassays guided fractionation to isolate bioactive compounds. Several cytostatic sesquiterpene quinones and tryptamine-derived alkaloids were isolated from 4 sponges of the genus Hyrtios. A new 4-sphingenine analogue and a novel polyacetylenic derivative were found to be responsible for the bioactivities of the methanolic extracts of Haliclona vansoesti and Callyspongia pseudoreticulata, respectively.     

Effect of soil salinity and soil water availability on growth and chemical composition ofSorghum halepense L.

Summary Effects of soil salinity and soil water regime on growth and chemical composition ofSorghum halepense L. was studied with a view to evaluating its potential as a forage crop in saline soils. The experiment was conducted under controlled conditions using pot-culture with three levels of soil salinity (EC_e 0.5, 5.0, 10.0 ds/m) and three soil water regimes (60%, 40% and 20% of water holding capacity of the soil). High soil salinity and low soil water combiningly had an adverse effect on plant growth but the biomass production was appreciably high (57 to 75% of control) even under high soil salinity (EC_e 10 ds/m) when sufficient water was available. Belowground plant parts were relatively more salt-tolerant than shoots. There occurred an increase in the concentration of certain nutrients (N, Ca, Mg, TNC) in the plants in response to salinity, which along with increased root: shoot ratios was inferred as an adaptive feature of the plant for persistence under saline conditions.     

The characteristics of the chemical composition and biological activity of Proteus antigens isolated using hydroxylamine

The comparative study of the chemical composition and biological properties of antigens isolated from Proteus vulgaris with the use of hydroxylamine and by two classical methods (Boivin's and Westphal's methods) has been made. As shown in this study, the treatment of bacteria with hydroxylamine makes it possible to obtain antigenic complexes with lower toxicity. At the same time hydroxylamine produces no denaturing effect on lipopolysaccharides and protein fractions of bacterial cells.     

Variation of antioxidants and secondary metabolites in nitrogen-deficient barley plants

Barley (Hordeum vulgare cv. Bojos) plants cultured in low nitrogen (N) containing Hoagland solution (20 mg/l) were exposed to N deficiency (−N) over 15 days. Plants revealed relatively high tolerance to total N deficit because shoot length was not altered and dry biomass was depleted by ca. 30% while root length increased by ca. 50% and dry biomass remained unaffected. Soluble proteins and free amino acids decreased more pronouncedly in the roots. Antioxidants (glutathione and ascorbic acid) decreased in the shoots but increased or were not affected in the roots. Ascorbate peroxidase and glutathione reductase activities were depleted in shoots and/or roots while guaiacol peroxidase activity was stimulated in the shoots. In accordance, fluorescence signal of reactive oxygen species (ROS) and nitric oxide was elevated in shoots but no extensive changes were observed in roots if +N and −N treatments are compared. At the level of phenolic metabolites, slight increase in soluble phenols and some phenolic acids and strong elevation of flavonoid homoorientin was found in the shoots but not in the roots. Fluorescence microscopy in terms of detection of phenols is also discussed. We also briefly discussed accuracy of quantification of some parameters owing to discrepancies in the literature. It is concluded that N deficiency induces increase in shoot phenolics but also elevates symptoms of oxidative stress while increase in root antioxidants probably contributes to ROS homeostasis aimed to maintain root development.     

草原与荒漠植物内生真菌次生代谢产物研究进展

草原与荒漠植物内生真菌是一类特殊生境真菌类群,由于其独特的生存与生态环境,该类真菌在进化的过程中产生出具有不同生态与生物功能的次生代谢产物。相对于其他植物内生真菌而言,该类真菌化学研究相对薄弱与零散,但是目前仍然从这类特殊生境真菌类群中发现了大量结构新颖、活性独特并具有不同化学生态与生物功能的次生代谢产物。本文主要从化学结构角度综述近年来从草原与荒漠植物内生真菌中分离的次生代谢产物(生物碱、聚酮、酚酸、萜类、环肽等5类结构)、药理活性(抗病毒,免疫调节,促进骨髓增殖,细胞毒及Hsp90抑制剂活性等)与化学生态功能活性(杀虫、拒食与动物神经毒活性等),拟为该类特殊生境真菌类群次生代谢产物进一步开发提供研究基础与理论依据,同时对该领域研究存在的问题进行分析与探讨并提出展望。     

The effects of thyrotropin-releasing hormone, metabolites and analogues on locomotor activity in rats

Thyrotropin-releasing hormone (TRH) has generally been reported to increase locomotor activity in rats; however there are also some negative reports. In order to identify the possible causes for this discrepancy, the effects of intra-cerebroventricular injection of TRH, its metabolites 'acid TRH' (TRH-OH) and His-Pro-diketopiperazine (DKP), and two analogues 3-methyl-His-TRH and RX 77368 (3,3-dimethyl-Pro-TRH), were assessed using photocell activity cages. All compounds were tested in groups of eight rats in the afternoon (1300-1700 h), but in addition TRH and DKP were tested in two further groups of rats during the morning (0900-1230 h). TRH and DKP failed to induce a significant rise in activity during the morning test period, but TRH did have a significant effect when tested in the afternoon. Both TRH and TRH-OH caused dose dependent increases in locomotor activity, whereas DKP and the two analogues had no effect. This stimulation of activity was shown to be at least partly mediated by dopamine since locomotor enhancement was blocked in a second experiment using the dopamine antagonist alpha-Flupenthixol. The results are discussed in terms of actions on the mesolimbic dopamine system, and the importance of circadian variations within this system to the expression of peptide effects in general.     

The effects of substrate composition, quantity, and diversity on microbial activity

Variation in organic matter inputs caused by differences in plant community composition has been shown to affect microbial activity, although the mechanisms controlling these effects are not entirely understood. In this study we determine the effects of variation in substrate composition, quantity, and diversity on soil extracellular enzyme activity and respiration in laboratory microcosms. Microbial respiration responded predictably to substrate composition and quantity and was maximized by the addition of labile substrates and greater substrate quantity. However, there was no effect of substrate diversity on respiration. Substrate composition significantly affected enzyme activity. Phosphatase activity was maximized with addition of C and N together, supporting the common notion that addition of limiting resources increases investment in enzymes to acquire other limiting nutrients. Chitinase activity was maximized with the addition of chitin, suggesting that some enzymes may be stimulated by the addition of the substrate they degrade. In contrast, activities of glucosidase and peptidase were maximized by the addition of the products of these enzymes, glucose and alanine, respectively, for reasons that are unclear. Substrate diversity and quantity also stimulated enzyme activity for three and four of the six enzymes assayed, respectively. We found evidence of complementary (i.e., non-additive) effects of additions of different substrates on activity for three of the six enzymes assayed; for the remaining enzymes, effects of adding a greater diversity of substrates appeared to arise from the substrate-specific effects of those substrates included in the high-diversity treatment. Finally, in a comparison of measures of microbial respiration and enzyme activity, we found that labile C and nutrient-acquiring enzymes, not those involved in the degradation of recalcitrant compounds, were the best predictors of respiration rates. These results suggest that while composition, quantity, and diversity of inputs to microbial communities all affect microbial enzyme activity, the mechanisms controlling these relationships are unique for each particular enzyme.     

Trypanocidal activity of a new pterocarpan and other secondary metabolites of plants from Northeastern Brazil flora

Two hundred fifteen compounds isolated from plants of Northeastern Brazil flora have been assayed against epimastigote forms of Trypanosoma cruzi, using the tetrazolium salt MTT as an alternative method. Eight compounds belonging to four different species: Harpalyce brasiliana (Fabaceae), Acnistus arborescens and Physalis angulata (Solanaceae), and Cordia globosa (Boraginaceae) showed significant activity. Among them, a novel and a known pterocarpan, a chalcone, four withasteroids, and a meroterpene benzoquinone were the represented chemical classes.