Jaime N. Coronado scite author profile

The site-specific incorporation of noncanonical monomers into polypeptides through genetic code reprogramming permits synthesis of bio-based products that extend beyond natural limits. To better enable such efforts, flexizymes (transfer RNA (tRNA) synthetase-like ribozymes that recognize synthetic leaving groups) have been used to expand the scope of chemical substrates for ribosome-directed polymerization. The development of design rules for flexizyme-catalyzed acylation should allow scalable and rational expansion of genetic code reprogramming. Here we report the systematic synthesis of 37 substrates based on 4 chemically diverse scaffolds (phenylalanine, benzoic acid, heteroaromatic, and aliphatic monomers) with different electronic and steric factors. Of these substrates, 32 were acylated onto tRNA and incorporated into peptides by in vitro translation. Based on the design rules derived from this expanded alphabet, we successfully predicted the acylation of 6 additional monomers that could uniquely be incorporated into peptides and direct N-terminal incorporation of an aldehyde group for orthogonal bioconjugation reactions.

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Sequencing of Sequence-Defined Oligourethanes via Controlled Self-Immolation

Dahlhauser

Escamilla

VandeWalle

et al. 2020

J. Am. Chem. Soc.

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Sequence-defined polymers show promise for biomimetics, self-assembly, catalysis, and information storage, wherein the primary structure begets complex chemical processes. Here we report the solution-phase and the high-yielding solid-phase syntheses of discrete oligourethanes and methods for their self-immolative sequencing, resulting in rapid and robust characterization of this class of oligomers and polymers, without the use of MS/MS. Crucial to the sequencing is the inherent reactivity of the terminal alcohol to "unzip" the oligomers, in a controlled and iterative fashion, releasing each monomer as a 2-oxazolidinone. By monitoring the self-immolation reaction via LC/MS, an applied algorithm rapidly produces the sequence of the oligourethane. Not only does this process provide characterization of structurally complex molecules, it works as a reader of molecular information.Sequence-defined polymers, e.g., β-peptides, γ-peptides, peptoids, polyureas, and polycarbamates, 1 have garnered significant interest over recent decades, to the point that their size and structural complexity are nearing those of biopolymers. 2 This complexity renders sequence elucidation difficult, at times -impossible. When successful, analysis has relied upon an assortment of 1 and 2D NMR spectroscopy together with sophisticated mass spectrometry techniques. 3 Molecular sequencing techniques such as Edman degradation for peptides and Sanger sequencing for DNA are among the most significant chemical achievements of the 20th century. Modern proteomic studies rely on comparisons to databases for protein identification, 4 wherein many of the protein sequences were elucidated via Edman degradations. Notably, very few techniques analogous to Edman or Sanger sequencing exist for synthetic macromolecules, likely due to the fact that only recently has synthetic methodology been capable of creating monodisperse macromolecules as structurally complex as biopolymers. 1 Peptoids are one exception, with Zuckerman realizing their stepwise chemical degradation on resin. 5 As more examples of sequence-defined

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Efficient molecular encoding in multifunctional self-immolative urethanes

Dahlhauser

Moor

Vera

et al. 2021

Cell Reports Physical Science

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SUMMARY Molecular encoding in sequence-defined polymers shows promise as a new paradigm for data storage. Here, we report what is, to our knowledge, the first use of self-immolative oligourethanes for storing and reading encoded information. As a proof of principle, we describe how a text passage from Jane Austen’s Mansfield Park was encoded in sequence-defined oligourethanes and reconstructed via self-immolative sequencing. We develop Mol.E-coder, a software tool that uses a Huffman encoding scheme to convert the character table to hexadecimal. The oligourethanes are then generated by a high-throughput parallel synthesis. Sequencing of the oligourethanes by self-immolation is done concurrently in a parallel fashion, and the liquid chromatography-mass spectrometry (LC-MS) information decoded by our Mol.E-decoder software. The passage is capable of being reproduced wholly intact by a third-party, without any purifications or the use of tandem MS (MS/MS), despite multiple rounds of compression, encoding, and synthesis.

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Chemical insights into flexizyme-mediated tRNA acylation

Coronado

Ngo

Anslyn

et al. 2022

Cell Chemical Biology

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Ribosome-mediated biosynthesis of pyridazinone oligomers in vitro

et al. 2022

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The ribosome is a macromolecular machine that catalyzes the sequence-defined polymerization of L-α-amino acids into polypeptides. The catalysis of peptide bond formation between amino acid substrates is based on entropy trapping, wherein the adjacency of transfer RNA (tRNA)-coupled acyl bonds in the P-site and the α-amino groups in the A-site aligns the substrates for coupling. The plasticity of this catalytic mechanism has been observed in both remnants of the evolution of the genetic code and modern efforts to reprogram the genetic code (e.g., ribosomal incorporation of non-canonical amino acids, ribosomal ester formation). However, the limits of ribosome-mediated polymerization are underexplored. Here, rather than peptide bonds, we demonstrate ribosome-mediated polymerization of pyridazinone bonds via a cyclocondensation reaction between activated γ-keto and α-hydrazino ester monomers. In addition, we demonstrate the ribosome-catalyzed synthesis of peptide-hybrid oligomers composed of multiple sequence-defined alternating pyridazinone linkages. Our results highlight the plasticity of the ribosome’s ancient bond-formation mechanism, expand the range of non-canonical polymeric backbones that can be synthesized by the ribosome, and open the door to new applications in synthetic biology.

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Jaime N. Coronado

Expanding the limits of the second genetic code with ribozymes

Sequencing of Sequence-Defined Oligourethanes via Controlled Self-Immolation

Efficient molecular encoding in multifunctional self-immolative urethanes

Chemical insights into flexizyme-mediated tRNA acylation

Ribosome-mediated biosynthesis of pyridazinone oligomers in vitro

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