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URL: https://pubmed.ncbi.nlm.nih.gov/21746901/

⇱ Identification of unique mechanisms for triterpene biosynthesis in Botryococcus braunii - PubMed

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Abstract

Botryococcene biosynthesis is thought to resemble that of squalene, a metabolite essential for sterol metabolism in all eukaryotes. Squalene arises from an initial condensation of two molecules of farnesyl diphosphate (FPP) to form presqualene diphosphate (PSPP), which then undergoes a reductive rearrangement to form squalene. In principle, botryococcene could arise from an alternative rearrangement of the presqualene intermediate. Because of these proposed similarities, we predicted that a botryococcene synthase would resemble squalene synthase and hence isolated squalene synthase-like genes from Botryococcus braunii race B. While B. braunii does harbor at least one typical squalene synthase, none of the other three squalene synthase-like (SSL) genes encodes for botryococcene biosynthesis directly. SSL-1 catalyzes the biosynthesis of PSPP and SSL-2 the biosynthesis of bisfarnesyl ether, while SSL-3 does not appear able to directly utilize FPP as a substrate. However, when combinations of the synthase-like enzymes were mixed together, in vivo and in vitro, robust botryococcene (SSL-1+SSL-3) or squalene biosynthesis (SSL1+SSL-2) was observed. These findings were unexpected because squalene synthase, an ancient and likely progenitor to the other Botryococcus triterpene synthases, catalyzes a two-step reaction within a single enzyme unit without intermediate release, yet in B. braunii, these activities appear to have separated and evolved interdependently for specialized triterpene oil production greater than 500 MYA. Coexpression of the SSL-1 and SSL-3 genes in different configurations, as independent genes, as gene fusions, or targeted to intracellular membranes, also demonstrate the potential for engineering even greater efficiencies of botryococcene biosynthesis.

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Conflict of interest statement

The authors declare no conflict of interest.

Figures

👁 Fig. 1.
Fig. 1.
The triterpene oils of B. braunii race B (illustrated as tetramethyl-botryococcene) have been recognized as likely progenitors to existing coal and oil shale deposits for over a century because of geochemical and fossil records (49) and have drawn considerable interest because these oils are readily converted under standard hydrocracking processes to molecular species of direct utility in industrial chemical manufacturing or can be distilled in high yields to all classes of combustible fuels, including gasoline (67%), aviation fuels (15%) and diesel (15%) (carbon chain length, distillation temperature, % volume conversion) (17) (A). The biosynthetic origin of the B. braunii triterpene oils has remained enigmatic. Poulter (23) suggested that the biosynthesis of the botryococcene scaffold could arise from a mechanism similar to that for squalene, a key intermediate in sterol and cyclized triterpene metabolism (B). Squalene biosynthesis occurs from an initial head-to-head condensation of two farnesyl diphosphate molecules (FPP) into the stable intermediate presqualene diphosphate (PSPP), followed by a reductive rearrangement to form squalene catalyzed by a single enzyme without release of the PSPP intermediate (34). Botryococcene biosynthesis is suggested to parallel that of squalene in the first half reaction, differing only in the reductive rearrangement of PSPP to yield the methyl/ethyl branched, 1′-3 linked botryococcene product.
👁 Fig. 2.
Fig. 2.
Functional characterization of the squalene synthase-like genes of Botryococcus braunii race B. The squalene synthase-like genes, SSL-1, SSL-2 and SSL-3, were expressed in yeast separately [SSL-1 (B), SSL-2 (C), or SSL-3 (D)] or in combinations [SSL-1 + SSL-2 (E), SSL-1 + SSL-3 (F)] and the hexane extractable metabolites profiled by GC-MS. The chemical profile of yeast not engineered with any gene constructs serves as the background control (A). The SSL genes were also expressed in bacteria, the affinity-tagged proteins purified and assayed separately [SSL-2 (G)] or in combinations [SSL-1 + SSL-2 (H); SSL-1 + SSL-3 (I)] for the reaction products generated upon incubation with FPP and profiled by GC-MS (GI), or for quantitative determination of radiolabeled FPP incorporated into specific reaction products separated by TLC (J). Data (J) represents mean ± S.E.M. obtained from three independent experiments (n = 3). The chromatograms (AI) are also annotated for the elution behavior of botryococcene (1), squalene (2), presqualene alcohol (3), and bisfarnesyl ether (4).
👁 Fig. 3.
Fig. 3.
Proposed mechanism for bisfarnesyl ether biosynthesis by SSL-2. When two molecules of FPP are bound by the SSL-2 enzyme, ionization of the diphosphate substituent from one creates a carbocation, which can react with a water molecule in close proximity to generate farnesol, FOH. If the FOH becomes appropriately positioned relative to the second FPP molecule, then a Williamson ether synthesis (32) reaction could occur to yield bisfarnesyl ether.
👁 Fig. 4.
Fig. 4.
Comparison of botryococcene production in yeast engineered with different configurations of SSL-1 and SSL-3. Yeast line TN7 was engineered with the SSL-1 and SSL-3 genes on separate plasmids (squares), with gene fusions [SSL-1 fused to SSL-3 via a triplet repeat of GGSG (triangles), or vice versa (diamonds)], or with 63 or 71 amino acids of the carboxy terminus of the Botryococcus squalene synthase, sequences containing a membrane spanning domain, appended to the carboxy termini of the SSL-1 and SSL-3 enzymes, respectively (circles). The data represents mean ± S.E.M.
👁 Fig. 5.
Fig. 5.
A cartoon depiction of the catalytic roles of the squalene synthase-like enzymes in Botryococcus braunii race B and their putative contributions to the triterpene constituents that accumulate. The previously identified squalene synthase gene (BSS) (31) is thought to provide squalene essential for sterol metabolism, whereas the squalene synthase-like genes SSL-1, SSL-2, and SSL-3 provide for the triterpene oils serving specialized functions for the algae. In combination with SSL-1, SSL-2 could provide squalene for extracellular matrix and methylated squalene derivatives, while SSL-1 plus SSL-3 generates botryococcene, which along with its methyl derivatives, accounts for the majority of the triterpene oil.

References

    1. Brown AC, Knights BA, Conway E. Hydrocarbon content and its relationship to physiological state in green alga botryococcus braunii. Phytochemistry. 1969;8:543–547.
    1. Metzger P, Largeau C. Botryococcus braunii: A rich source for hydrocarbons and related ether lipids. Appl Microbiol Biotechnol. 2005;66:486–496. - PubMed
    1. Gelpi E, Oro J, Schneide HJ, Bennett EO. Olefins of high molecular weight in 2 microscopic algae. Science. 1968;161:700–701. - PubMed
    1. Metzger P, Allard B, Casadevall E, Berkaloff C, Coute A. Structure and chemistry of a new chemical race of Botryococcus braunii (Chlorophyceae) that produces lycopadiene, a tetraterpenoid hydrocarbon. J Phycol. 1990;26:258–266.
    1. Okada S, Murakami M, Yamaguchi K. Hydrocarbon composition of newly isolated strains of the green microalga Botryococcus braunii. J Appl Phycol. 1995;7:555–559.

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