Enzyme-free translation of DNA into sequence-defined synthetic polymers structurally unrelated to nucleic acids.
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Abstract | The translation of DNA sequences into corresponding biopolymers enables the production, function and evolution of the macromolecules of life. In contrast, methods to generate sequence-defined synthetic polymers with similar levels of control have remained elusive. Here, we report the development of a DNA-templated translation system that enables the enzyme-free translation of DNA templates into sequence-defined synthetic polymers that have no necessary structural relationship with nucleic acids. We demonstrate the efficiency, sequence-specificity and generality of this translation system by oligomerizing building blocks including polyethylene glycol, α-(D)-peptides, and β-peptides in a DNA-programmed manner. Sequence-defined synthetic polymers with molecular weights of 26 kDa containing 16 consecutively coupled building blocks and 90 densely functionalized β-amino acid residues were translated from DNA templates using this strategy. We integrated the DNA-templated translation system developed here into a complete cycle of translation, coding sequence replication, template regeneration and re-translation suitable for the iterated in vitro selection of functional sequence-defined synthetic polymers unrelated in structure to nucleic acids. |
Year of Publication | 2013
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Journal | Nat Chem
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Volume | 5
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Issue | 4
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Pages | 282-92
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Date Published | 2013 Apr
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ISSN | 1755-4349
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DOI | 10.1038/nchem.1577
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PubMed ID | 23511416
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PubMed Central ID | PMC4277153
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Grant list | Howard Hughes Medical Institute / United States
R01 GM065865 / GM / NIGMS NIH HHS / United States
R01GM065865 / GM / NIGMS NIH HHS / United States
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