Squalene tetracyclic

Van Tamelen has examined extensively the cyclization of monoepoxide-polyolefins (94). For example, he found (95) that the treatment of racemic epoxide 247 with SnCl in nitromethane provided a major product (35% yield) which was identified as the racemic tetracycle 248. This represents an over all, close simulation of the squalene tetracyclic triterpene bioconversion (except for optical activity). 

The achiral triene chain of (a//-rrans-)-3-demethyl-famesic ester as well as its (6-cis-)-isoiner cyclize in the presence of acids to give the decalol derivative with four chirai centres whose relative configuration is well defined (P.A. Stadler, 1957 A. Escherunoser, 1959 W.S. Johnson, 1968, 1976). A monocyclic diene is formed as an intermediate (G. Stork, 1955). With more complicated 1,5-polyenes, such as squalene, oily mixtures of various cycliz-ation products are obtained. The 18,19-glycol of squalene 2,3-oxide, however, cyclized in modest yield with picric acid catalysis to give a complex tetracyclic natural product with nine chiral centres. Picric acid acts as a protic acid of medium strength whose conjugated base is non-nucleophilic. Such acids activate oxygen functions selectively (K.B. Sharpless, 1970). 

Recent syntheses of steroids apply efficient strategies in which open-chain or monocyclic educts with appropiate side-chains are stereoselectively cyclized in one step to a tri- or tetracyclic steroid precursor. These procedures mimic the biochemical synthesis scheme where acyclic, achiral squalene is first oxidized to a 2,3-epoxide containing one chiral carbon atom and then enzymatically cyclized to lanostetol with no less than seven asymmetric centres (W.S. Johnson, 1%8, 1976 E.E. van Tamden, 1968). 

Pentacyclosqualene, the symmetrical hydropicene corresponding to squalene, has not been made by acid-induced cation-olefin cyclization of squalene, despite considerable experimental study. A simple, convergent synthesis of pentacyclosqualene using cation-olefin cyclization to generate ring C was developed. The Cjo-framework was constructed by radical coupling to a tetracyclic intermediate that was also used for the synthesis of onoceradiene. 

Steroids are plant and animal lipids with a characteristic tetracyclic carbon skeleton. Like the eicosanoids, steroids occur widely in body tissues and have a large variety of physiological activities. Steroids are closely related to terpenoids and arise biosynthetically from the triterpene lanosterol. Lanosterol, in turn, arises from cationic cyclization of the acyclic hydrocarbon squalene. 

The tetracyclic alcohol 179 is produced by the action of boron trifluoride etherate or tin(IV) chloride on the oxirane 178 (equation 85)95. A similar cyclization of the oxirane 180 yields DL-<5-amyrin (181) (equation 86)96. In the SnCLt-catalysed ring-closure of the tetraene 182 to the all-fraws-tetracycle 183 (equation 87) seven asymmetric centres are created, yet only two of sixty-four possible racemates are formed97. It has been proposed that multiple ring-closures of this kind form the basis of the biosynthesis of steroids and tetra-and pentacyclic triterpenoids, the Stork-Eschenmoser hypothesis 98,99. Such biomimetic polyene cyclizations, e.g. the formation of lanosterol from squalene (equation 88), have been reviewed69,70. 

Steroids are important lipids whose structures are based on a tetracyclic system. Most steroids function as hormone chemical messengers, and thus these molecules have been discussed in detail in chapter 5. Structurally, steroids are heavily modified triterpenes that are biosynthesized starting from the acyclic hydrocarbon squalene and progressing through cholesterol to the final steroid product Bloch and Cornforth, who were awarded Nobel Prizes in medicine (1964), contributed greatly to the elucidation of this remarkable biosynthetic transformation. 

While squalene, the parent of all triterpenoids, is a linear acyclic compound, the majority of triterpeneoids exist in cyclic forms, penta- and tetracyclic triterpenes being the major types. Within these cyclic triterpenoids distinct structural variations lead to several structural classes of triterpenoids. Some of the major structures types of triterpenoids are shown helow. 

In the biogenesis of steroids, the enzyme-catalyzed polycyclization of squalene (225) produces the tetracyclic substance lanosterol (225) which is eventually converted into cholesterol (227) Eschenmoser, Stork, and their co-workers (80-82) have proposed that the squalene-1anosterol conversion can be rationalized on the basis of stereoelectronic effects. The stereochemical course of this biological cyclization (83, 84) can be illustrated by considering the transformation of squalene oxide (228) (an intermediate in the biosynthesis of cholesterol (83, 84)) into dammaradienol 229. This transfor-... 

The first enantioselective polyene tetracydization starting with a chiral epoxide was reported by Corey et al. in 1997 [8a]. The silylated enol ether 3 (Scheme 1) was converted into the tetracycle 4 by treatment with the Lewis acid MeAlCl2 at -90 °C. The synthetic route is modeled on the biosynthesis of lanosterol from (3S)-squalene 2,3-epoxide and has also been applied to the biomimetic synthesis of tetracyclic polyprenoids from sediment bacteria [8b]. 

Fig. 14.12. Enzymatic transformation of acyclic squalene oxide (A) into tetracyclic lano-sterol (G). The oxidosqualene-lanosterol cyclase controls the conformation of the substrate so effectively that only one out of 64 possible diastereomers is formed.

The Opening of Squalene-2,3-Epoxide Steroids are tetracyclic compounds that serve a wide variety of biological functions, including hormones (sex hormones), emulsifiers (bile acids), and membrane components (cholesterol). The biosynthesis of steroids is believed to involve an acid-catalyzed opening of squalene-2,3-epoxide (Figure 14-6). Squalene is a member of the class of natural products called terpenes (see Section 25-8). The enzyme squalene epoxidase oxidizes squalene to the epoxide,... 

Head-to-head condensation of two farnesylpyrophosphate (C]3—PP) molecules yields a G13-cyclopropane (C3)-CH intermediate which is then reduced to yield squalene H(CH2-C(CH3)=CH-CH2)3-(CH2-CH=C(CH3)CH2)3 (C30), that is, if one represents the isoprene polarities as IP and PI, one could represent squalene as (IP)3—(PI)3. Squalene is subsequently oxidized [via a squalene monooxygenase] to yield squalene 2,3-epoxide which is cyclized to the tetracyclic sterol terpene lanosterol (C30) [via squalene cyclase]. 

Squalene cyclises and the tetracyclic product is converted into cholesterol. 

Cyclization of squalene oxide yields a carbocation, called the protosterol cation. This reaction results in the formation of four new C—C bonds and the tetracyclic ring system. 

In stage three, squalene cyclizes in an astounding reaction and the tetracyclic product is subsequently converted into cholesterol. 

Figure 26.11. Squalene Cyclization. The formation of the steroid nucleus from squalene begins with the formation of squalene epoxide. This intermediate is protonated to form a carbocation that cyclizes to form a tetracyclic structure, which rearranges to form lanosterol.

Although cycloartenol (44) belongs to the tetracyclic triterpenoids as the parent compound, it is implicated as an important biosynthetic intermediate both in that class and in plant steroids and is thus a relevant introduction to the latter group which have been so significant in semi-synthetic applications. Following the enzyme-catalysed cyclisation of squalene epoxide, it is the first intermediary compound encountered and in the plant series it has a comparable position to lanosterol (45) in the animal... 

Steroids are formed from two sesquiterpene molecules—farnesyl pyrophosphate— which are attached to each other tail to tail to give the acyclic squalene (SOC-atoms) this undergoes complex reactions involving a cyclisation to tetracyclic or pentacychc ring systems, especially cholesterol. 

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