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Redirection of cytosolic or plastidic isoprenoid precursors elevates terpene production in plants

Nature Biotechnology volume 24pages 1441–1447 (2006)Cite this article

Abstract

Terpenes constitute a distinct class of natural products1 that attract insects2, defend against phytopathogenic microbes3 and combat human diseases4. However, like most natural products, they are usually made by plants and microbes in small amounts and as complex mixtures. Chemical synthesis is often costly and inefficient, and may not yield enantiomerically pure terpenes, whereas large-scale microbial production requires expensive feedstocks. We engineered high-level terpene production in tobacco plants by diverting carbon flow from cytosolic or plastidic isopentenyl diphosphate through overexpression in either compartment of an avian farnesyl diphosphate synthase and an appropriate terpene synthase. Isotopic labeling studies suggest little, if any, metabolite exchange between these two subcellular compartments. The strategy increased synthesis of the sesquiterpenes patchoulol and amorpha-4,11-diene more than 1,000-fold, as well as the monoterpene limonene 10–30 fold, and seems equally suited to generating higher levels of other terpenes for research, industrial production or therapeutic applications.

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Figure 1: Strategies for diverting carbon flux from the mevalonate (MVA; cytosolic) and the methyl-erythritol phosphate (MEP; plastidic) pathways for biosynthesis of novel isoprenoids.
Figure 2: Differential labeling patterns can distinguish sesquiterpenes biosynthesized from the cytosolic (MVA) versus the plastidic (MEP) pathways.
Figure 3: Phenotypic traits of a plant line engineered for high-level patchoulol biosynthesis via the MEP (plastidic) pathway (2tpPTS+tpFPS).
Figure 4: Engineering production platforms for (a) amorpha-4,11-diene (sesquiterpene) and (b) limonene (monoterpene) by diverting carbon flux from the mevalonate (cytosolic) and the methyl-erythritol phosphate (plastidic) pathways.

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Acknowledgements

We thank Dale Poulter, University of Utah, for the avian farnesyl diphosphate synthase gene, Peter Brodelius, Kalmar University, for the amorpha-4,11-diene synthase gene and Randy Dinkins, University of Kentucky, for providing the Arabidopsis RUBISCO transit peptide sequence DNA. Special thanks to Nihar Nayak for his excellent advice concerning plant transformation, Scott Kinison for logistical and technical support, and Suphata Kaewpraparn for assistance with the insect bioassay experiment, all associated with the University of Kentucky. This work was supported by grants from Firmenich, Geneva (to J.C.) and from the US National Institutes of Health (GM 13956 to R.M.C).

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Authors and Affiliations

  1. Department of Plant & Soil Sciences, University of Kentucky, Lexington, 40546-0312, Kentucky, USA

    Shuiqin Wu & Joe Chappell

  2. Corporate R&D Division, Firmenich SA, Geneva, CH-1211, Switzerland

    Michel Schalk & Anthony Clark

  3. Department of Chemistry, University of Illinois, Urbana, 61801, Illinois, USA

    R Brandon Miles & Robert Coates

Authors
  1. Shuiqin Wu
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  6. Joe Chappell
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Contributions

Shuiqin Wu conceived and performed the experimental work; Michel Schalk and Anthony Clark made conceptual contributions to the work; Brandon Miles carried out the NMR experimental work; Robert Coates helped with interpretation of NMR spectra and data; and Joe Chappell conceived the work, helped to interpret the data and prepared the manuscript.

Corresponding author

Correspondence to Joe Chappell.

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Competing interests

M.S. and A.C. are current employees of Firmenich, which provided financial support for this work.

Supplementary information

Supplementary Fig. 1

Expression levels and processing of the patchoulol synthase (PTS) and farnesyl diphosphate synthase (FPS) proteins in transgenic plants were measured by immunodetection. (PDF 562 kb)

Supplementary Fig. 2

Head-space gas analysis of volatile emissions from control and PTS transgenic plants. (PDF 1281 kb)

Supplementary Fig. 3

A Ti vector system compatible for recombination cloning was developed to facilitate vector construction (pBDON). (PDF 80 kb)

Supplementary Table 1

Reports of genetic engineering terpene synthases in plants. (PDF 66 kb)

Supplementary Data

Supplementary Data for GC and NMR analyses performed at the University of Illinois. (PDF 69 kb)

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Wu, S., Schalk, M., Clark, A. et al. Redirection of cytosolic or plastidic isoprenoid precursors elevates terpene production in plants. Nat Biotechnol 24, 1441–1447 (2006). https://doi.org/10.1038/nbt1251

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