Sesquiterpenes metabolism

Takahashi S, Yeo Y, Greenhagen B, McMullin T, Song L, Maurina-Brunker J, Rosson R, Noel JP, Chappell J (2007) Metabolic engineering of sesquiterpene metabolism in yeast. Biotechnol... 

In plant plastids, GGPP is formed from products of glycolysis and is eight enzymatic steps away from central glucose metabolism. The MEP pathway (reviewed in recent literature - ) operates in plastids in plants and is a preferred source (non-mevalonate) of phosphate-activated prenyl units (IPPs) for plastid iso-prenoid accumulation, such as the phytol tail of chlorophyll, the backbones of carotenoids, and the cores of monoterpenes such as menthol, hnalool, and iridoids, diterpenes such as taxadiene, and the side chains of bioactive prenylated terpenophe-nolics such as humulone, lupulone, and xanthohumol. The mevalonic pathway to IPP that operates in the cytoplasm is the source of the carbon chains in isoprenes such as the polyisoprene, rubber, and the sesquiterpenes such as caryophyllene. 

Hampel, D., Mosandl, A., and Wust, M., Biosynthesis of mono- and sesquiterpenes in carrot roots and leaves (Daucus carota L.) metabolic cross talk of cytosolic mevalonate and plastidial methylerythritol phosphate pathways, Phytochemistry 66, 305, 2005. 

Isoprene metabolism in plants is very complex. Plants can synthesize many types of aromatic substances and volatile oils from isoprenoids. Examples include menthol (1= 2 ), camphor (1 = 2), and citronellal (1 = 2). These Cio compounds are also called monoterpenes. Similarly, compounds consisting of three isoprene units (1 = 3) are termed sesquiterpenes, and the steroids (1 = 6) are called triterpenes. 

Artemisinin is a natural endoperoxide-containing sesquiterpene, isolated from a plant used in traditional Chinese medicine. Acetalic artemisinin derivatives (arte-mether, artesunate) are very active against chemo-resistant forms of Plasmodium falciparum, and are clinically used for the treatment. However, they suffer from an unfavourable pharmacological profile. They are quickly metabolised by fast oxidative metabolism, hydrolytic cleavage and glucuronidation. 

Overall, however, the immensity of temperate land corresponds to a most various secondary metabolic production, different from that of tropical land. The most renowned alkaloids belong to the morphine class (Chart 6.2.A1), and, in combination with isoprenoids, to the ergot and triterpene classes (Chart 6.2. A2). Prominent in the peptides are the cyclosporins (the first of which was isolated from a fiingus collected in Norway), streptogramins, and P-lactams (Chart 6.2.P). The isoprenoids are represented by pyrethrin monoterpenes, cedrane sesquiterpenes, ginkgolide and taxane diterpenes, ophiobolane sesterterpenes, and arborane and amyrin-like triterpenes (Chart 6.2.1). In the polyketides, epothilones, recently discovered from Myxobacteria, and the long known rapamycin, are two prominent classes of macrolides (Chart 6.2.FA/PO/C). 

Essential oils consist of volatile, lipophilic substances that are mainly hydrocarbons or monofunctional compounds derived from the metabolism of mono- and sesquiterpenes, phenylpropanoids, amino acids (lower mass aliphatic compounds), and fatty acids (long-chain aliphatic compounds). Unlike fatty oils, essential oils do not leave a grease stain when dabbed on filter paper. 

Much attention has been paid to the last step of the formation of monoter-penes and sesquiterpenes, which is catalysed by terpenoid synthases. Over 30 complementary DNAs (cDNAs) encoding plant terpenoid synthases involved in the primary and secondary metabolism have been cloned, characterised, and the proteins heterologously expressed [6]. However, because geranyl diphosphate and farnesyl diphosphate are not readily available substrates, their biotransformation by terpenoid synthases is not economically viable. As a result, considerable effort has been put into engineering the total plant terpenoid biosynthetic pathway in recombinant microorganisms. 

Gershenzon, J. and Croteau, R. (1993). Terpenoid biosynthesis the basic pathway and formation of monoterpenes, sesquiterpenes and diterpenes. In Lipid Metabolism in Plants, ed. T. S. Moore Jr, pp. 339-388. Boca Raton, FL CRC Press. 

Sesquiterpenes containing either a methylene-y-lactone or a cyclopentenone moiety can react with thiol groups to form a covalent linkage. If the thiol group is on a key enzyme, interaction with artemisinin could inactivate the enzyme, disrupting metabolism. Cysteine is a good antidote for artemisinin as a phytotoxin, but there is no evidence that it is due to a direct interaction of the two molecules.15... 

Figure 10.5 Plant cell cultures have proven to be very useful for studying plant-pathogen interactions and isoprenoid metabolism. Tobacco cell cultures respond rapidly to the addition of fungal elicitors (0.5 pg cellulase/ml of culture) by browning (A) (analogous to a hypersensitive response) and the production of phytoalexins (B). Media was collected from elicited cell cultures at the indicated times, partitioned against an organic solvent, and concentrated aliquots run on a silica TLC plate. The plates were then sprayed with a suspension of Cladosporium cucumerinum spores and incubated in a humid environment for 5 days before viewing (B). The compound released from the elicitor-treated tobacco cells that inhibits spore germination is capsidiol, a sesquiterpene.

Another possibihty to gain the product encoded by a silent gene cluster can be achieved by a method called the in vitro reconstitution approach. A necessity is that the substrates of the pathway are predictable. The in vitro reconstitution of an entire biosynthetic pathway usually involves the separate overexpression of each gene, the purification of the resulting protein and the performance of enzymatic studies. Thus, the discovery of a fully elaborated metabolic product by this approach is likely to be very laborious. For example, after discovering a cryptic sesquiterpene synthase in the genome of S. coelicolor (64), the new epi-isozaene (8) could be produced successfully. This metabolite was shown to be an intermediate in the assembly line of the known Streptomyces sesquiterpene albaflavenone (9) (135). 

There are many examples in the literature for applications of LC-NMR in the pharmaceutical industry. In the area of natural products, LC-NMR has been applied to screen plant constituents from crude extracts [54,57,67,68] and to analyze plant and marine alkaloids [69-72], flavonoids [73], sesquiterpene lactones [74,75], saponins [58,76], vitamin E homologues [77], and antifungal and bacterial constituents [56,78,79] as examples. In the field of drug metabolism, LC-NMR has been extensively applied for the identihcation of metabolites [42, 80-88] and even polar [89] or unstable metabolites [43]. And hnally, LC-NMR has been used for areas such degradation products [90-93], drug impurities [94-102], drug discovery [103,104], and food analysis [105-107]. 

To date over 30 plant terpenoid synthases have been cloned as cDNAs, and many of these were found to encode enzymes of secondary metabolism (43). Isolation and analysis of six genomic clones encoding monoterpene ((—)-pinene and (—)-limonene), sesquiterpene ((E)-a-bisabolene and S-selinene) and diterpene (abietadiene) synthases from Abies grandis, and a diterpene (taxadiene) synthase from Taxus brevifolia have been reported (44). Overexpression of a cotton farnesyl diphosphate synthase (EPPS) in transgenic Artemesia annua has resulted in 3- to 4-fold increase in the yield of the sesquiterpenoid anti-malarial drug, artemisinin, in hairy roots (45). 

When guayule is in an active growth phase, it produces little or no rubber, but if the plants are stressed, such as in cool weather or because of reduced moisture supply, biomass growth slows and the photosynthetic products are diverted to rubber production. The rubbers are not metabolized by the plant, even when it is deprived of all carbohydrates and other energy sources, and continue to accumulate for at least 10 years. The resins, which include terpenes, sesquiterpenes, diterpenes, glycerides, and low-molecular-weight polyiso-prenes, are found in resin ducts throughout the plant they constitute 10-15 dry wt % of the plant. 

Sesquiterpenes, as already reported in the previous sections, are the most widespread Lactarius metabolites however, a few species possess a particular metabolism which leads to secondary metabolites of other classes. Moreover, interesting new compounds with a different biogenesis have been isolated also from species producing large quantities of sesquiterpenes. 

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