2002
DOI: 10.1021/ja020410i
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Recombinant Squalene Synthase. Synthesis of Non-Head-to-Tail Isoprenoids in the Absence of NADPH

Abstract: Squalene synthase (SQase) catalyzes two consecutive reactions in sterol biosynthesis. The first is the condensation of two molecules of farnesyl diphosphate (FPP) to form a cyclopropylcarbinyl intermediate, presqualene diphosphate (PSPP). The subsequent conversion of PSPP to squalene (SQ) involves an extensive rearrangement of the carbon skeleton and a NADPH-dependent reduction. Incubation of a truncated soluble form of recombinant yeast SQase with FPP in buffer lacking NADPH gave (1R,2R,3R)-PSPP. As the incub… Show more

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Cited by 52 publications
(73 citation statements)
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“…FPP is first converted to the intermediate PSPP, followed by its reductive rearrangement to squalene (24). However, PSPP is not evident in these reactions unless NADPH, the reducing reagent, is omitted from the incubations (19). Under conditions of adequate NADPH, it appears unlikely that PSPP is released from the squalene synthase enzyme, then rebound as a natural consequence of the catalytic cycle (34).…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…FPP is first converted to the intermediate PSPP, followed by its reductive rearrangement to squalene (24). However, PSPP is not evident in these reactions unless NADPH, the reducing reagent, is omitted from the incubations (19). Under conditions of adequate NADPH, it appears unlikely that PSPP is released from the squalene synthase enzyme, then rebound as a natural consequence of the catalytic cycle (34).…”
Section: Discussionmentioning
confidence: 99%
“…Our approach for identifying the triterpene biosynthetic genes in B. braunii has relied in large part on the putative similarities in the biosynthetic mechanisms for squalene and botryococcene (19)(20)(21). Squalene biosynthesis has been extensively investigated because it is positioned at a putative branch point in the isoprenoid biosynthetic pathway directing carbon flux to sterol metabolism, and thus represents a potential control point for cholesterol biosynthesis in man (22).…”
mentioning
confidence: 99%
“…Unable to convert into phytoene in wild-type CrtM, prephytoene diphosphate either remains stuck in the enzyme, departs, or undergoes other types of rearrangement to yield noncarotenoid products. (A similar phenomenon is well known for SqS; in the absence of NADPH, which is required to convert presqualene diphosphate to squalene, SqS produces a complex mixture of nonsqualene compounds including rillingol, 10-hydroxybotryococcene, and 12-hydroxysqualene [22,89].) However, in CrtM mutants where F26 or W38 is replaced with a smaller or more flexible amino acid, the prephytoene diphosphate formed from two molecules of C 20 PP is efficiently rearranged to form phytoene.…”
mentioning
confidence: 55%
“…The biosynthesis of carotenoid backbones (and squalene) has proven to be a complex process (22,88,89) (Fig. 5a).…”
Section: Directed Evolution Of Key Carotenoid Biosynthetic Enzymesmentioning
confidence: 99%
“…This mechanism is virtually identical to that of squalene synthase (SqS), the enzyme that catalyzes the first step in cholesterol biosynthesis. Indeed, when deprived of NADPH, SqS produces product 1 as the main product (3,11). Carotene synthases are similar to SqS in sequence and predicted secondary structure; they probably share a common ancestor and have virtually identical folds.…”
Section: And C 30 Carotenoid Synthase Activities Of Crtm Variantsmentioning
confidence: 99%