Abstract
Chromosomal recombinant gene expression offers a number of advantages over plasmid-based synthetic biology. However, the methods applied for bacterial genome engineering are still challenging and far from being standardized. Here, in an attempt to realize the simplest recombinant genome technology imaginable and facilitate the transition from recombinant plasmids to genomes, we create a simplistic methodology and a comprehensive strain collection called the Standardized Genome Architecture (SEGA). In its simplest form, SEGA enables genome engineering by combining only two reagents: a DNA fragment that can be ordered from a commercial vendor and a stock solution of bacterial cells followed by incubation on agar plates. Recombinant genomes are identified by visual inspection using green-white colony screening akin to classical blue-white screening for recombinant plasmids. The modular nature of SEGA allows precise multi-level control of transcriptional, translational, and post-translational regulation. The SEGA architecture simultaneously supports increased standardization of genetic designs and a broad application range by utilizing well-characterized parts optimized for robust performance in the context of the bacterial genome. Ultimately, its adaption and expansion by the scientific community should improve predictability and comparability of experimental outcomes across different laboratories.
Highlights
Chromosomal recombinant gene expression offers a number of advantages over plasmidbased synthetic biology
Driven by the vision to optimize biological systems and to incorporate engineering principles in their design, the field of synthetic biology emerged. With these new principles being applied to molecular biology, including abstraction of a complex system into parts with defined functions, the need for standardization became more apparent and the synthetic biology community accepted the lack of standards as a problem and started to advocate for their implementation[17,18,19,20]
The Standardized Genome Architecture (SEGA) landing pads allow for reusable homology regions and time-efficient construction of parallel genetic designs with a minimal number of reagents and handling steps
Summary
Chromosomal recombinant gene expression offers a number of advantages over plasmidbased synthetic biology. By reducing the burden to the host cell, reproducibility of experiments will increase and thereby the fundamental understanding of biology itself Following this trend, numerous technologies for integrating DNA constructs into the genomes of bacteria have been developed[6,7,8,9,10,11,12,13]. Several standards have been described: BioBrick assembly marked the first approach of creating modular genetic parts for sharing between different laboratories[21] This was followed by optimized versions[22,23,24] and included a growing repository of biological parts driven by the international genetically engineered machine (iGEM) student competition (http:// parts.igem.org/). According to a recent study, most molecular biology standards are still in the innovator or early adopters’ phase—and the field requires new impulses and simpler technologies that will convince an increasing number of researchers to adopt them[18]
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