Expanding the Terpene Biosynthetic Code with Non-canonical 16 Carbon Atom Building Blocks

Overview

Journal Nat Commun

Specialty Biology

Date 2022 Sep 3

PMID 36057727

Authors

Codruta Ignea

Morten H Raadam

Aikaterini Koutsaviti

Yong Zhao

Yao-Tao Duan

Maria Harizani

Karel Miettinen

Panagiota Georgantea

Mads Rosenfeldt

Sara E Viejo-Ledesma

Mikael A Petersen

Wender L P Bredie

Dan Staerk

Vassilios Roussis

Efstathia Ioannou

Sotirios C Kampranis

Affiliations

Soon will be listed here.

Abstract

Humankind relies on specialized metabolites for medicines, flavors, fragrances, and numerous other valuable biomaterials. However, the chemical space occupied by specialized metabolites, and, thus, their application potential, is limited because their biosynthesis is based on only a handful of building blocks. Engineering organisms to synthesize alternative building blocks will bypass this limitation and enable the sustainable production of molecules with non-canonical chemical structures, expanding the possible applications. Herein, we focus on isoprenoids and combine synthetic biology with protein engineering to construct yeast cells that synthesize 10 non-canonical isoprenoid building blocks with 16 carbon atoms. We identify suitable terpene synthases to convert these building blocks into C scaffolds and a cytochrome P450 to decorate the terpene scaffolds and produce different oxygenated compounds. Thus, we reconstruct the modular structure of terpene biosynthesis on 16-carbon backbones, synthesizing 28 different non-canonical terpenes, some of which have interesting odorant properties.

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