Analyzing and Engineering the Product Selectivity of a 2-Methylenebornane Synthase.

Terpenes constitute the largest class of natural products with more than 70 000 compounds. Many different terpenes find applications in the flavor and fragrance industry or can be used as fine chemicals or drugs. In some bacteria, noncanonical terpenes with 11 carbon atoms are synthesized via a GPP-C2-methyltransferase and the subsequent conversion of 2-methyl-GPP by certain terpene synthases into mainly 2-methylisoborneol and 2-methylenebornane. Many other C11-terpenes were reported as side products, but they are synthesized only in minor amounts by the bacterial C11-terpene biosynthesis pathway. To enable biotechnological synthesis of these largely unexplored natural products, we changed the product selectivity of the 2-methylenebornane synthase from Pseudomonas fluorescens by a semirational protein engineering approach. Active site amino acids with impact on the product selectivity were identified and variants with completely altered product spectra could be identified and characterized. The gathered data provide new insights into the structure-function relationship for C11-terpene synthases and demonstrate the production of formerly inaccessible noncanonical terpenes.

Expanding the Isoprenoid Building Block Repertoire with an IPP Methyltransferase from Streptomyces monomycini.

Many synthetic biology approaches aim at expanding the product diversity of enzymes or whole biosynthetic pathways. However, the chemical structure space of natural product forming routes is often restricted by the limited cellular availability of different starting intermediates. Although the terpene biosynthesis pathways are highly modular, their starting intermediates are almost exclusively the C5 units IPP and DMAPP. To amplify the possibilities of terpene biosynthesis through the modification of its building blocks, we identified and characterized a SAM-dependent methyltransferase converting IPP into a variety of C6 and C7 prenyl pyrophosphates. Heterologous expression in Escherichia coli not only extended the intracellular prenyl pyrophosphate spectrum with mono- or dimethylated IPP and DMAPP, but also enabled the biosynthesis of C11, C12, C16, and C17 prenyl pyrophosphates. We furthermore demonstrated the general high promiscuity of terpenoid biosynthesis pathways toward uncommon building blocks by the E. coli-based production of polymethylated C41, C42, and C43 carotenoids. Integration of the IPP methyltransferase in terpene synthesis pathways enables an expansion of the terpenoid structure space beyond the borders predetermined by the isoprene rule which indicates a restricted synthesis by condensation of C5 units.

Heterologous expression of 2-methylisoborneol / 2 methylenebornane biosynthesis genes in Escherichia coli yields novel C11-terpenes.

The structural diversity of terpenoids is limited by the isoprene rule which states that all primary terpene synthase products derive from methyl-branched building blocks with five carbon atoms. With this study we discover a broad spectrum of novel terpenoids with eleven carbon atoms as byproducts of bacterial 2-methylisoborneol or 2-methylenebornane synthases. Both enzymes use 2-methyl-GPP as substrate, which is synthesized from GPP by the action of a methyltransferase. We used E. coli strains that heterologously produce different C11-terpene synthases together with the GPP methyltransferase and the mevalonate pathway enzymes. With this de novo approach, 35 different C11-terpenes could be produced. In addition to eleven known compounds, it was possible to detect 24 novel C11-terpenes which have not yet been described as terpene synthase products. Four of them, 3,4-dimethylcumene, 2-methylborneol and the two diastereomers of 2-methylcitronellol could be identified. Furthermore, we showed that an E. coli strain expressing the GPP-methyltransferase can produce the C16-terpene 6-methylfarnesol which indicates the condensation of 2-methyl-GPP and IPP to 6-methyl-FPP by the E. coli FPP-synthase. Our study demonstrates the broad range of unusual terpenes accessible by expression of GPP-methyltransferases and C11-terpene synthases in E. coli and provides an extended mechanism for C11-terpene synthases.