Adaptive evolution of genomically recoded Escherichia coli

Efforts are underway to construct several recoded genomes anticipated to exhibit multivirus resistance, enhanced nonstandard amino acid (nsAA) incorporation, and capability for synthetic biocontainment. Although our laboratory pioneered the first genomically recoded organism (Escherichia coli strain...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2018-03, Vol.115 (12), p.3090-3095
Main Authors: Wannier, Timothy M., Kunjapur, Aditya M., Rice, Daniel P., McDonald, Michael J., Desai, Michael M., Church, George M.
Format: Article
Language:English
Subjects:
Acid resistance
adaptive evolution
Amino acids
Bacteria
BASIC BIOLOGICAL SCIENCES
Biological Sciences
Cell growth
E coli
Escherichia coli
Evolution
Evolution & development
Fitness
Gene expression
Gene sequencing
genetic code expansion
Genomes
Genomics
Growth rate
Metabolic engineering
Mutation
nonstandard amino acids
Population genetics
Populations
Protein engineering
Proteins
recoded genome
Reproductive fitness
Strains (organisms)
synthetic biology
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Summary:Efforts are underway to construct several recoded genomes anticipated to exhibit multivirus resistance, enhanced nonstandard amino acid (nsAA) incorporation, and capability for synthetic biocontainment. Although our laboratory pioneered the first genomically recoded organism (Escherichia coli strain C321.ΔA), its fitness is far lower than that of its nonrecoded ancestor, particularly in defined media. This fitness deficit severely limits its utility for nsAA-linked applications requiring defined media, such as live cell imaging, metabolic engineering, and industrial-scale protein production. Here, we report adaptive evolution of C321.ΔA for more than 1,000 generations in independent replicate populations grown in glucose minimal media. Evolved recoded populations significantly exceeded the growth rates of both the ancestral C321.ΔA and nonrecoded strains. We used next-generation sequencing to identify genes mutated in multiple independent populations, and we reconstructed individual alleles in ancestral strains via multiplex automatable genome engineering (MAGE) to quantify their effects on fitness. Several selective mutations occurred only in recoded evolved populations, some of which are associated with altering the translation apparatus in response to recoding, whereas others are not apparently associated with recoding, but instead correct for off-target mutations that occurred during initial genome engineering. This report demonstrates that laboratory evolution can be applied after engineering of recoded genomes to streamline fitness recovery compared with application of additional targeted engineering strategies that may introduce further unintended mutations. In doing so, we provide the most comprehensive insight to date into the physiology of the commonly used C321.ΔA strain.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1715530115