Chassis organism from Corynebacterium glutamicum--a top-down approach to identify and delete irrelevant gene clusters.

Simon Unthan,Kay Marin,Michael Bott,Julia Frunzke,Meike Baumgart,Reinhard Krämer,Anna Bartsch,Wolfgang Wiechert,Volker F Wendisch,Gerd Seibold,Natalie Brühl,Jörn Kalinowski,Marius Herbst,Stephan Noack,Christian Rückert,Stephan Hans,Andreas Radek,Daniel Siebert

doi:10.1002/biot.201400041

Simon Unthan, Kay Marin + Show 16 more

Open Access

https://doi.org/10.1002/biot.201400041

Copy DOI

Abstract

For synthetic biology applications, a robust structural basis is required, which can be constructed either from scratch or in a top-down approach starting from any existing organism. In this study, we initiated the top-down construction of a chassis organism from Corynebacterium glutamicum ATCC 13032, aiming for the relevant gene set to maintain its fast growth on defined medium. We evaluated each native gene for its essentiality considering expression levels, phylogenetic conservation, and knockout data. Based on this classification, we determined 41 gene clusters ranging from 3.7 to 49.7 kbp as target sites for deletion. 36 deletions were successful and 10 genome-reduced strains showed impaired growth rates, indicating that genes were hit, which are relevant to maintain biological fitness at wild-type level. In contrast, 26 deleted clusters were found to include exclusively irrelevant genes for growth on defined medium. A combinatory deletion of all irrelevant gene clusters would, in a prophage-free strain, decrease the size of the native genome by about 722 kbp (22%) to 2561 kbp. Finally, five combinatory deletions of irrelevant gene clusters were investigated. The study introduces the novel concept of relevant genes and demonstrates general strategies to construct a chassis suitable for biotechnological application.

Highlights

Synthetic biology aims to introduce engineering principles into the life sciences in order to allow the rational design of biological devices from scratch
We investigated the degree of conservation of each gene in the species and genus of C. glutamicum and determined three core genomes, which represent different degrees of phylogenetic proximity to ATCC 13032
In order to evaluate the conservation for each gene, the information as to whether a gene belongs to a certain core genome was converted into a three-bit conservation code, with each bit representing a core genome group of the following order: genus, subgroup, and species

Summary

Introduction

Synthetic biology aims to introduce engineering principles into the life sciences in order to allow the rational design of biological devices from scratch. Two main prerequisites are a library of well-characterized genetic entities and a robust structural basis [1]. The latter is regularly referred to as a minimal organism and described as a cell with the essential properties of any living organism, such as: (i) encapsulation, (ii) storage of information, (iii) gene expression, and (iv) cell replication. BioBtieocthencohlongoylogy JourJnoaul rnal www.biotechnology-journal.com www.biotecvisions.com thetic biology applications, such a minimal organism should not influence the function of any inserted genetic device (orthogonality principle) and should display a minimal biological complexity in order to ensure full predictability of the behavior of the constructed system [2]. The importance of formulating clear criteria, keeping applications in mind, and precisely defining the termini used for synthetic biology projects has been emphasized in a recent critical commentary [5]

Methods

Results

Conclusion