Isoprenoid compounds synthesis

The isoprenoid compound shown is a scent marker present in the urine of the red fox Sug gest a reasonable synthesis for this substance from 3 methyl 3 buten 1 ol and any necessary organic or inorganic reagents... 

Bark beetles primarily utilize isoprenoid derived pheromones [100,101] and have been the most studied regarding their biosynthesis [8,98]. Earlier work indicated that the isoprenoid pheromones could be produced by the beetle altering host derived isoprenoids however more recent work indicates that for the most part bark beetles are producing pheromones de novo. The production of isoprenoids follows a pathway outlined in Fig. 4 which is similar to the isoprenoid pathway as it occurs in cholesterol synthesis in mammals. Insects cannot synthesize cholesterol but can synthesize farnesyl pyrophosphate. Insects apparently do not have the ability to cyclize the longer chain isoprenoid compounds into steroids. The key enzymes in the early steps of the isoprenoid... 

It is also a precursor for synthesis of polyprenyl (isoprenoid) compounds, and it can give rise to free acetoacetate, an important constituent of blood. Acetoacetate is a (3-oxoacid that can undergo decarboxylation to acetone or can be reduced by an NADH-dependent dehydrogenase to D-3-hydroxybutyrate. Notice that the configuration of this compound is opposite to that of L-3-hydroxybutyryl-CoA which is... 

In animals all isoprenoid compounds are apparently synthesized from mevalonate, which is converted by the consecutive action of two kinases21 23 into mevalonate 5-diphosphate (Fig. 22-1, step b). Mevalonate kinase is found predominantly in peroxisomes, which are also active in other aspects of steroid synthesis in humans.2124 A deficiency of this enzyme is associated with mevalonic aciduria, a serious hereditary disease in which both blood and urine contain very high concentrations of mevalonate.23 Mevalonate diphosphate kinase, which is also a decarboxylase, catalyzes phosphorylation of the 3-OH group of mevalonate (step c, Fig. 22-1) and decarboxylative elimination of phosphate (step d)25 to form isopentenyl diphosphate. 

The syntheses described above and the individual reaction steps, respectively, are the historical basis for the development of the synthesis of isoprenoid juvenile hormones. In addition to the latter, a great number of naturally occurring or synthetic analogous substances as well as non-isoprenoid compounds with juvenile hormone activity can also be obtained via Wittig reaction. However, since these syntheses do not offer basically new aspects with respect to the olefination step, they are not further discussed here. 

Statins. Statins, such as atorvastatin (Lipotor), simvastatin (Zocor) and lovastatin (Mevacor), are fungal-derived HMG-CoA reductase inhibitors. Treatment results in an increased cellular uptake of LDLs, since the intracellular synthesis of cholesterol is inhibited and cells are therefore dependent on extracellular sources of cholesterol. However, since mevalonate (the product of the HMG-CoA reductase reaction) is also required for the synthesis of other important isoprenoid compounds besides cholesterol, long-term treatments carry some risk of toxicity. 

Jegou, A, Pacheco, C, Veyrieres, A, Stereoselective synthesis of a-C-glycopyranosyl isoprenoid compounds, Synlett, 81-83, 1998. 

The pathways of formation of ketone bodies are shown in Figure 18-9. The major pathway of production of acetoacetate is from j6-hydroxy-j8-methylglutaryl-CoA (HMG-CoA). Hydrolysis of acetoacetyl-CoA to acetoacetate by acetoacetyl-CoA hydrolase is of minor importance because the enzyme has a high for acetoacetyl-CoA. HMG-CoA is also produced in the cytosol, where it is essential for the synthesis of several isoprenoid compounds and cholesterol (Chapter 19). The reduction of acetoacetyl-CoA to /8-hydroxybutyrate depends on the mitochondrial [NAD+]/[NADH] ratio. 

Dolichol phosphate is an isoprenoid compound (90-100 carbons total) made from dolichol (see here for synthesis of dolichol via the cholesterol biosynthetic route) by phosphorylation catalyzed by a kinase that uses CTP as the energy and phosphate source. Dolichol phosphate performs two important functions in synthesis of N-linked glycoproteins. 

Plant secondary metabolites are biosynthesized from rather simple building blocks supplied by primary metabolism. Two important metabolic routes in this are the shikimate pathway and the isoprenoid biosynthesis. The shikimate pathway leads to the synthesis of phenolic compounds and the aromatic amino acids phenylalanine, tyrosine and tryptophan. The isoprenoid biosjmthesis is a heavily branched pathway leading to a broad spectrum of compounds (fig. 1). From plants and microorganisms more than 37,000 isoprenoid compounds have been isolated so far [1]. 

The organization of Part Two is according to structural type. The first section, Chapter Seven, is concerned with the synthesis of macrocyclic compounds. Syntheses of a number of heterocyclic target structures appear in Chapter Eight. Sesquiterpenoids and polycyclic higher isoprenoids are dealt with in Chapters Nine and Ten, respectively. The remainder of Part Two describes syntheses of prostanoids (Chapter Eleven) and biologically active acyclic polyenes including leukotrienes and other eicosanoids (Chapter Twelve). 

Cholesterol is one of the isoprenoids, synthesis of which starts from acetyl CoA (see p. 52). In a long and complex reaction chain, the C27 sterol is built up from C2 components. The biosynthesis of cholesterol can be divided into four sections. In the first (1), mevalonate, a Ce compound, arises from three molecules of acetyl CoA. In the second part (2), mevalonate is converted into isopen-tenyl diphosphate, the active isoprene. In the third part (3), six of these C5 molecules are linked to produce squalene, a C30 compound. Finally, squalene undergoes cycliza-tion, with three C atoms being removed, to yield cholesterol (4). The illustration only shows the most important intermediates in biosynthesis. 

We begin with an account of the main steps in the biosynthesis of cholesterol from acetate, then discuss the transport of cholesterol in the blood, its uptake by cells, the normal regulation of cholesterol synthesis, and its regulation in those with defects in cholesterol uptake or transport. We next consider other cellular components derived from cholesterol, such as bile acids and steroid hormones. Finally, an outline of the biosynthetic pathways to some of the many compounds derived from isoprene units, which share early steps with the pathway to cholesterol, illustrates the extraordinary versatility of isoprenoid condensations in biosynthesis. 

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