An automated pipeline for the screening of diverse monoterpene synthase libraries

Neil Swainston,Katherine A Hollywood,Mark S Dunstan,Nigel S Scrutton,Eriko Takano,Adrian J Jervis,Nicole G H Leferink,Andrew Currin

doi:10.1038/s41598-019-48452-2

Neil Swainston, Katherine A Hollywood + Show 6 more

Open Access

https://doi.org/10.1038/s41598-019-48452-2

Copy DOI

Journal: Scientific Reports	Publication Date: Aug 15, 2019
Citations: 23	License type: open-access

Affiliation: University of Manchester

Abstract

Monoterpenoids are a structurally diverse group of natural products with applications as pharmaceuticals, flavourings, fragrances, pesticides, and biofuels. Recent advances in synthetic biology offer new routes to this chemical diversity through the introduction of heterologous isoprenoid production pathways into engineered microorganisms. Due to the nature of the branched reaction mechanism, monoterpene synthases often produce multiple products when expressed in monoterpenoid production platforms. Rational engineering of terpene synthases is challenging due to a lack of correlation between protein sequence and cyclisation reaction catalysed. Directed evolution offers an attractive alternative protein engineering strategy as limited prior sequence-function knowledge is required. However, directed evolution of terpene synthases is hampered by the lack of a convenient high-throughput screening assay for the detection of multiple volatile terpene products. Here we applied an automated pipeline for the screening of diverse monoterpene synthase libraries, employing robotic liquid handling platforms coupled to GC-MS, and automated data extraction. We used the pipeline to screen pinene synthase variant libraries, with mutations in three areas of plasticity, capable of producing multiple monoterpene products. We successfully identified variants with altered product profiles and demonstrated good agreement between the results of the automated screen and traditional shake-flask cultures. In addition, useful insights into the cyclisation reaction catalysed by pinene synthase were obtained, including the identification of positions with the highest level of plasticity, and the significance of region 2 in carbocation cyclisation. The results obtained will aid the prediction and design of novel terpene synthase activities towards clean monoterpenoid products.

Highlights

Terpenoids are a large class of natural products with more than 80,000 compounds identified up to now
To determine if the pipeline is suitable to screen monoterpene cyclases/synthases (mTC/S) product profiles in HTP, we compared the product profiles obtained using the pipeline to those previously obtained in conventional shake-flask cultures for native (-)-α-pinene synthase (PinS) and a PinS variant that produces a mixture of monoterpenoid products (VAR3-PinS, Fig. 2b)
Both enzymes were introduced into our dual-plasmid monoterpenoid production www.nature.com/scientificreports platform, which consists of a previously described isopropyl β-D-1-thiogalactopyranoside (IPTG)-inducible heterologous MVA pathway[6] encoded on the first plasmid, and a tetracycline inducible truncated GPP synthase followed by the native PinS or VAR3-PinS gene encoded on the second plasmid (See Fig. S1 in the Supplementary Information)

Summary

Introduction

Terpenoids are a large class of natural products with more than 80,000 compounds identified up to now (http:// dnp.chemnetbase.com). Prenyl transferases join the IPP and DMAPP molecules to form prenyl diphosphate substrates of different lengths (C10, C15, C20, etc.), which are used by terpene cyclases or synthases to produce structurally complex linear and cyclic mono-, sesqui-, di-, or larger terpene scaffolds Due to their structural diversity, terpenoids have a wide range of industrial applications as, for example, precursors for pharmaceuticals, flavourings, fragrances, antiseptics, pesticides, and other household products, as well as alternative fuels and bioplastics[2,3,4]. Other assays allow the detection of enhanced terpene production in vivo where terpene synthases compete for the available GPP pool with a heterologous carotenoid biosynthesis pathway[21,22], or include a fluorescent-based genetically-encoded biosensor for enhanced intracellular isoprene production[23] None of these examples allows the rapid detection of multiple volatile terpene compounds in a high-throughput fashion. The data obtained in this study provide a better understanding of the molecular determinants for product outcome in PinS, and the pipeline can be directly applied to other (mono) terpene synthase libraries

Methods

Results

Conclusion