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Squalene, cholesterol

Lipids, e.g. sitosterol, geraniol, dolichol, squalene, cholesterol 200 C, 15 min Induced fluorescence detection limits <1 pg cholesterol. [3]... [Pg.25]

Be familiar with geraniol, farnesol, isoprene unit, squalene, cholesterol. [Pg.125]

FIGURE 26 10 The biosyn thetic conversion of squa lene to cholesterol proceeds through lanosterol Lano sterol IS formed by enzyme catalyzed cyclization of the 2 3 epoxide of squalene... [Pg.1094]

Section 26 11 The triterpene squalene is the biosynthetic precursor to cholesterol by the pathway shown in Figure 26 10... [Pg.1103]

The path from squalene (114) to the corresponding oxide and thence to lanosterol [79-63-0] (126), C qH qO, cholesterol [57-88-5] (127), and cycloartenol [469-38-5] (128) (Fig. 6) has been demonstrated in nonphotosynthetic organisms. It has not yet been demonstrated that there is an obligatory path paralleling the one known for generation of plant sterols despite the obvious stmctural relationships of, for example, cycloartenol (128), C qH qO, to cyclobuxine-D (129), C25H42N2O. The latter, obtained from the leaves of Buxus sempervirens E., has apparentiy found use medicinally for many disorders, from skin and venereal diseases to treatment of malaria and tuberculosis. In addition to cyclobuxine-D [2241-90-9] (129) from the Buxaceae, steroidal alkaloids are also found in the Solanaceae, Apocynaceae, and LiUaceae. [Pg.554]

Mice fed a diet containing the hexaisoprenoid cholesterol precursor squalene [111-02-4]... [Pg.498]

Squalene is also an intermediate in the synthesis of cholesterol. StmcturaHy, chemically, and biogeneticaHy, many of the triterpenes have much in common with steroids (203). It has been verified experimentally that squalene is the precursor in the biosynthesis of all triterpenes through a series of cyclization and rearrangement reactions (203,204). Squalene is not used much in cosmetics and perfumery formulations because of its light, heat, and oxidative instabiUty however, its hydrogenated derivative, squalane, has a wide use as a fixative, a skin lubricant, and a carrier of Hpid-soluble dmgs. [Pg.431]

Like the a2ole derivatives, it inhibits the biosynthesis of ergosterol. However, naftifine [65472-88-0] does not inhibit the cytochrome P-450 dependent C-14-demethylase, but the epoxidation of squalene. Squalene epoxidase cataly2es the first step in the conversion of squalene via lanosterol to ergosterol in yeasts and fungi or to cholesterol in mammalian cells. The squalene epoxidase in C. albicans is 150 times more sensitive to naftifine, C2 H2 N, than the en2yme in rat fiver (15). Naftifine is available as a 1% cream. [Pg.254]

The most important oxirane, from an anthropocentric viewpoint, is probably squalene oxide (72), a precursor of lanosterol (73) and thus of the maligned but essential cholesterol (74 Scheme 87) 78MI50501). The cyclization of (72) to (73) represents nucleophilic tr-attack on oxirane carbon cf. Section 5.05.3.4.3(t)()), and the process has also been extensively investigated in vitro (68ACR1). Oxiranes are even more ubiquitous in steroid biosynthesis than had been thought, for a cholesterol epoxide has been shown to be a product of mammalian steroid biosynthesis <81JA6974). [Pg.119]

In 1952, Konrad Bloch and Robert Langdon showed conclusively that labeled squalene is synthesized rapidly from labeled acetate and also that cholesterol is derived from squalene. Langdon, a graduate student of Bloch s, performed the critical experiments in Bloch s laboratory at the University of Chicago, while Bloch spent the summer in Bermuda attempting to demonstrate that radioactively labeled squalene would be converted to cholesterol in shark livers. As Bloch himself admitted, All I was able to learn was that sharks of manageable length are very difficult to catch and their oily livers impossible to slice (Bloch, 1987). [Pg.838]

The biomimetic approach to total synthesis draws inspiration from the enzyme-catalyzed conversion of squalene oxide (2) to lanosterol (3) (through polyolefinic cyclization and subsequent rearrangement), a biosynthetic precursor of cholesterol, and the related conversion of squalene oxide (2) to the plant triterpenoid dammaradienol (4) (see Scheme la).3 The dramatic productivity of these enzyme-mediated transformations is obvious in one impressive step, squalene oxide (2), a molecule harboring only a single asymmetric carbon atom, is converted into a stereochemically complex polycyclic framework in a manner that is stereospecific. In both cases, four carbocyclic rings are created at the expense of a single oxirane ring. [Pg.83]

See other pages where Squalene, cholesterol is mentioned: [Pg.227]    [Pg.130]    [Pg.859]    [Pg.65]    [Pg.482]    [Pg.411]    [Pg.666]    [Pg.667]    [Pg.573]    [Pg.330]    [Pg.49]    [Pg.227]    [Pg.130]    [Pg.859]    [Pg.65]    [Pg.482]    [Pg.411]    [Pg.666]    [Pg.667]    [Pg.573]    [Pg.330]    [Pg.49]    [Pg.235]    [Pg.370]    [Pg.685]    [Pg.1094]    [Pg.1094]    [Pg.1095]    [Pg.1095]    [Pg.1095]    [Pg.1095]    [Pg.1252]    [Pg.1252]    [Pg.426]    [Pg.685]    [Pg.1094]    [Pg.1095]    [Pg.1095]    [Pg.1095]    [Pg.1095]    [Pg.1252]    [Pg.1252]    [Pg.251]    [Pg.838]    [Pg.838]    [Pg.641]   


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