Commentary: Evolving a mitigation of the stress response pathway to change the basic chemistry of life

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Commentary: Evolving a mitigation of the stress response pathway to change the basic chemistry of life

In his 1859 work “On the Origin of Species,” Darwin acknowledged evolution as a slow process not readily observable (Darwin, 1859). However, in 1878, Reverend Dallinger conducted a groundbreaking experiment (Hass, 2000). Cultivating protozoa in a controlled environment with increasing temperatures, he observed them adapt to higher heat levels. Darwin, upon learning of this, remarked on the significance of the results (Lenski, 2011). Dallinger’s experiment, the first Adaptive Laboratory Evolution study, demonstrated the adaptability of even simple organisms and provided a tangible observation of evolution within a human lifetime.

In the 1960s, non-canonical amino acids (ncAAs) were viewed as growth inhibitors and antimetabolites (Richmond, 1962). However, the pioneering works of Wong (1983) and Bacher and Ellington (2001), in which tryptophan (Trp) was replaced by fluorinated analogs, showed that microbes can adapt adeptly in synthetic microenvironments and achieve substantial replacement levels. Trp, a rare amino acid encoded by a single TGG codon, is an ideal target due to its recent addition to the genetic code (Fournier and Alm, 2015), with diverse anthropogenically produced indole side chains like fluoroindole (or fluorotryptophan) (Budisa and Paramita Pal, 2004). Despite this, reassigning over 20,000 codons in Escherichia coli to chemically modified analogs remain a formidable task (Zhang and Ellington, 2020).

Notably, strict analytical evidence for the full replacement of Trp with analogs in the proteome was elusive until 2015 when Hoesl et al. (2015) reported on the evolution of the chemical composition of the Escherichia coli. Using adaptive laboratory evolution (ALE), they were able to prove analytically that all Trp residues were completely replaced by the non-canonical amino acid analog L-beta-(thieno[3,2-b]pyrrolyl)alanine ([3,2]Tpa). Subsequently, in 2019, Agostini et al. (2020) performed ALE experiments, successfully incorporating 4- and 5-fluorotryptophan into the entire E. coli proteome.

There are two reports in the current issue of Frontiers in Synthetic Biology that fundamentally address these questions. The first report by Tolle et al. (2023) provides a mechanistic understanding of the complete adaptation of E. coli to ([3,2]Tpa) as the sole replacement source for Trp. In the second report, Treiber-Kleinke et al. (2024) present a comprehensive study focusing on fermentation protocols that enable the strict, proteome-wide replacement of Trp with 6- and 7-fluorotryptophan.

Performing a “clean” proteome-wide exchange in microbial cells with a well-defined auxotrophic metabolic prototype and defined genomic background is challenging for several reasons, primarily rooted in empirical experimental design. The traditional approach involves serial dilution in minimal media with decreasing Trp concentrations over time, alongside a constant high level of analogs throughout ALE (Figure 1). However, difficulties arise due to the presence of traces of Trp in commercially available preparations, even those labeled as “ultrapure.” Cells tend to adhere to these residual traces under selection pressure for analog use.

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Figure 1. Escherichia coli is able to overcome the frozen state of the genetic code by mitigating its own stress response. In this context, the work of Tolle et al. (2023) is important evidence that the genetic code and the rigidity (conservation) of the protein translation machinery are also “guarded” by the regulatory network of metabolism, signal transduction and physiology in general.

In the works of Hoesl et al. (2015), Agostini et al. (2020), Tolle et al. (2023), and Treiber-Kleinke et al. (2024), overcoming challenges involved the utilization of chemically pure fluoroindole or analogous compounds like thienopyrrole. These were meticulously synthesized to exclude any presence of canonical (“natural”) Trp. In addition, state-of-the-art mass spectrometric analyses of proteomes and metabolomes were performed to ensure a thorough examination of the cellular composition and to detect any traces of Trp in the experimental setup.

Now, armed with well-established empirical protocols, we can advance to contemplate the chemical evolution of synthetic cells using various synthetic ncAAs. This involves a genomic-level approach, monitoring the emergence of key mutations in genes associated with various cellular processes, including the general stress response, amino acid metabolism, stringent response, and chemotaxis. Understanding these adaptation mechanisms to non-canonical biomass components is crucial for informing strategies in engineering synthetic metabolic pathways and cells (Lefèvre-Morand et al., 2024). With a substantial body of empirical data on ALE through ncAA proteome-wide insertions, the significance of the “oligogenic barrier” (Mat et al., 2010) becomes increasingly apparent. This barrier comprises a relatively small number of genes that must undergo mutation to facilitate the successful insertion of a new, non-canonical amino acid into the genetic code (Acevedo-Rocha and Schulze-Makuch, 2015).

The overcoming of these hurdles is illustrated by the discovery of Tolle et al. (2023): adapted bacterial strains successfully overcome the adverse effects associated with the incorporation of synthetic amino acids at Trp positions. This adaptation primarily involves the suppression of the growth-inhibitory stress response within the regulatory networks of the bacterial strains (Figure 1). Essentially, these strains have evolved to enforce a phenotype capable of utilizing [3,2] Tpa as a core building block by effectively modulating their regulatory networks, particularly by suppressing the stress response.

It is crucial to emphasize that substituting amino acids involves chemically diversifying their side chains. Efforts to modify the “alanine core” (Kubyshkin and Budisa, 2019a), as seen with proline analogs (Kubyshkin and Budisa, 2019b), are generally poorly tolerated and frequently rejected by the universally conserved protein translation machinery. Nevertheless, these experiments underscore the remarkable adaptability of the protein translation apparatus to chemical variations in amino acid side chains. The works of Hoesl, Agostini, Tolle, and Treiber-Kleinke clearly show that, among other factors, the stress response acts as both a physical and a biological constraint when attempting to alter the amino acid repertoire of the genetic code.

The findings emphasize that the universally conserved repertoire can be experimentally altered by addressing biological constraints, such as specific metabolic regulatory networks that have played a role in maintaining or “freezing” the code (Figure 1). Consequently, the laboratory-driven reassignment of codons becomes a feasible task when conservation mechanisms like the stress response or the quality of protein folding are effectively mitigated or bypassed. This illustrates the potential for further advances in our ability to “unfreeze” the genetic code through specific interventions in biological processes, using an efficient top-down approach to alter the chemical composition of living cells.

These experiments will provide a critical mass of empirical data that will enable us to use sophisticated genome-editing tools to configure chassis to adapt and thrive in man-made chemical processes. We are indeed at the very beginning of the long journey towards synthetic species away from the “old” living world (Marliere, 2009). With a built-in genetic firewall ensured by biological compounds of mostly anthropogenic origin, these chassis will allow us to create and explore strange new life forms and establish Xenobiology (Budisa et al., 2020) as the science of alien life forms.

Author contributions

NB: Conceptualization, Writing–original draft, Writing–review and editing.

Acknowledgments

Dedicated to Professor Luis Moroder on his 83rd birthday.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

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