Genetic code engineering that enables reassignment of genetic codons to non-canonical
amino acids (ncAAs) is a powerful strategy for enhancing ribosomally synthesized
peptides and proteins with functions not commonly found in Nature. Here we report
the expression of a ribosomally synthesized and post-translationally modified
peptide (RiPP), the 32-mer lantibiotic lichenicidin with a canonical tryptophan
(Trp) residue replaced by the ncAA
L-β-(thieno[3,2-b]pyrrolyl)alanine ([3,2]Tpa) which does
not sustain cell growth in the culture. We have demonstrated that cellular toxicity
of [3,2]Tpa for the production of the new-to-nature bioactive congener of
lichenicidin in the host Escherichia coli can be alleviated by using an
evolutionarily adapted host strain MT21 which not only tolerates [3,2]Tpa but also
uses it as a proteome-wide synthetic building block. This work underscores the
feasibility of the biocontainment concept and establishes a general framework for
design and large scale production of RiPPs with evolutionarily adapted host
strains.
Billions of years of evolution have produced only slight variations in the standard genetic code, and the number and identity of proteinogenic amino acids have remained mostly consistent throughout all three domains of life. These observations suggest a certain rigidity of the genetic code and prompt musings as to the origin and evolution of the code. Here we conducted an adaptive laboratory evolution (ALE) to push the limits of the code restriction, by evolving Escherichia coli to fully replace tryptophan, thought to be the latest addition to the genetic code, with the analog L-β-(thieno[3,2-b]pyrrolyl)alanine ([3,2]Tpa). We identified an overshooting of the stress response system to be the main inhibiting factor for limiting ancestral growth upon exposure to β-(thieno[3,2-b]pyrrole ([3,2]Tp), a metabolic precursor of [3,2]Tpa, and Trp limitation. During the ALE, E. coli was able to "calm down" its stress response machinery, thereby restoring growth. In particular, the inactivation of RpoS itself, the master regulon of the general stress response, was a key event during the adaptation. Knocking out the rpoS gene in the ancestral background independent of other changes conferred growth on [3,2]Tp. Our results add additional evidence that frozen regulatory constraints rather than a rigid protein translation apparatus are Life's gatekeepers of the canonical amino acid repertoire. This information will not only enable us to design enhanced synthetic amino acid incorporation systems but may also shed light on a general biological mechanism trapping organismal configurations in a status quo.
A first step towards the creation of synthetic cells is described by N. Budisa et al. in their Communication on The chemical composition and the genetic code of an auxotrophic E. coli were changed in the frame of a long‐term evolution experiment. During the experiment the cells were gradually forced to replace the natural building block tryptophan with thienopyrrolylalanine in their proteomes. This is the first step in the creation of synthetic life, which should be genetically and metabolically so far away from that found in nature that it cannot survive outside of the laboratory.
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