Sesquiterpene synthetase

There is an expanding body of evidence to suggest that sesquiterpene lactones inhibit the synthesis NO synthetase. One such compound is an ambrosanolides-type sesquiterpene known as cumanin characterized from Ambrosia psilostachya. This sesquiterpene inhibit the enzymatic activity of NO synthetase with an IC50 value of 9.38 xM (49). Another example is the well-known artemisinin, a sesquiterpene used as an alternative drug in the treatment of severe and multidrug-resistant malaria, which inhibits NO synthesis in cytokine-stimulated human astrocytoma T67 cells (50). 

Feverfew is widely consumed in England as a remedy for arthritis and migraine. Feverfew contains parthenolide, which is a member of sesquiterpene. Parthenolide inhibits the activity of prostaglandin synthetase. It also inhibits platelet aggregation and alter serotonin release (Figure 25.2). 

VOGELI, U., CHAPPELL, J., Induction of sesquiterpene cyclase and suppression of squalene synthetase activities in plant cell cultures treated with fungal elicitor, Plant Physiol., 1988, 88, 1291-1296. 

There are a number of allelochemicals among the mono-, sesqui-, and diterpenoids. In particular, plants in arid and semiarid regions produce diverse volatile terpenoids with allelopathic activity.5 Among the volatile monoterpenes, 1,8-cineole (4) and camphor (5) exhibit strong growth inhibitory effects on plants and are considered to be involved in plant competition. 1,4-Cineole (6), a minor isomer of 1,8-cineole, is a potent inhibitor of asparagine synthetase.6 -Menthane-3,8-diols (fir 7 and frw .r8), -menth-2-en-l-ols (cis 9 and trans 10), thymol (11), carvacrol (12), 1,8-cineole, cr-pinene (13), and /3-pinene (14) were isolated as allelopathic monoterpenes from Eucalyptus species.7 Eucalyptus trees also produce allelopathic sesquiterpenes including spathulenol (15), and a-, (3-, and 7-eudesmols (16-18).7... 

The mevalonate pathway in the cytosol is responsible for biosynthesis of sterols, sesquiterpenes, and triterpenoids. After conversion of mevalonic acid to isopentenyl pyrophosphate, three C5 units can be joined head to tail to produce a C15 compound, famesyl pyrophosphate. Two famesyl pyrophosphates are then united head to head to form squalene, the progenitor of the C30 isoprenoids from which sterols are derived. The plant squalene synthetase, like its mammalian homologue, is found in the ER and the reaction proceeds via a presqualene pyrophosphate intermediate (Chapter 14). In the last step prior to cyclization, squalene is converted to squalene 2,3-epoxide. 

Parthenolide, isolated from Tanacetum parthenium and other species, is a sesquiterpene lactone widely investigated for its anti-inflammatory activity [168,169,170]. Recent in vitro studies have shown that this compound inhibits the NF-kB pathway. A study on the effect of parthenolide in endotoxic shock in rodents showed that treatment with this compound stopped nitrotyrosine formation, PARP synthetase expression, and apoptosis. It also reduced iNOS mRNA content in the tissues studied. All these effects are brought about by the compound s inhibition of NF-kB [171]. In addition, parthenolide mimicked the effects of IkBoc in that it inhibited both NF-kB DNA binding activity as well as Mn-SOD expression, while simultaneously increasing paclitaxel-induced apoptosis of breast cancer cells [90]. 

Steroids are members of a large class of lipid compounds called terpenes. Using acetate as a starting material, a variety of organisms produce terpenes by essentially the same biosynthetic scheme (Fig. 8). The self-condensation of two molecules of acetyl coenzyme A (CoA) forms acetoacetyl CoA. Condensation of acetoacetyl CoA with a third molecule of acetyl CoA, then followed by an NADPH-mediated reduction of the thioester moiety produces mevalonic acid [150-97-0] (72). Phosphorylation of (72) followed by concomitant decarboxylation and dehydration processes produce isopentenyl pyrophosphate. Isopentenyl pyrophosphate isomerase establishes an equilibrium between isopentenyl pyrophosphate and 3,3-dimethylallyl pyrophosphate (73). The head-to-tail addition of these isoprene units forms geranyl pyrophosphate. The addition of another isopentenyl pyrophosphate unit results in the sesquiterpene (C15) famesyl pyrophosphate (74). Both of these head-to-tail additions are catalyzed by prenyl transferase. Squalene synthetase catalyzes the head-to-head addition of two achiral molecules of famesyl pyrophosphate, through a chiral cyclopropane intermediate, to form the achiral triterpene, squalene (75). 

The biosynthesis of sesquiterpenes in plants appears to be isolated from that of either monoterpenes or diterpenes. A prenyl transferase isolated from pumpkin Cucurbita pepo, Cucurbitaceae) converts C5 units into FPP, but not into gera-nylgeranyl pyrophosphate (the precursor to diterpenes). Another enzyme from the same source forms C20 terpenoids from C5 units, but does not accumulate lower homologs (also see Chapters 19 and 22). However, because famesyl pyrophosphate synthetase is a branch-point metabolite for the synthesis of sesquiterpenes, triterpenes, and sterols, this enzyme is ubiquitous in plants (Croteau and Johnson, 1985). 

The enzyme, farnesyl pyrophosphate synthetase (prenyl transferase), is responsible for the condensation of (4.14) with (4.15) to give geranyl pyrophosphate (4.41). The same enzyme mediates addition of a further molecule of (4.14) to (4.41) yielding 2- ran5-farnesyl pyrophosphate (4.19). This is the basic unit for the elaboration of the structurally diverse sesquiterpenes. The results obtained on biosynthesis are as interesting as the sesquiterpene structures. The 2 cis... 

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