Recent Progress Toward the Templated Synthesis and Directed Evolution of Sequence-Defined Synthetic Polymers

Brudno, Yevgeny; Liu, David R.

doi:10.1016/j.chembiol.2009.02.004

Cited by 99 publications

(86 citation statements)

References 167 publications

(231 reference statements)

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“…However, the laboratory generation and amplification of such mosaic nucleic acid pools would require mutant DNA or RNA polymerase that could incorporate such nucleotides into polymers and transcribe them back into RNA or DNA. Some naturally occurring error-prone or bypass DNA polymerases as well as artificially evolved mutant polymerases show a remarkable ability to incorporate nucleotides with sugar modifications into polymers (46,47). Such polymerases may enable the identification of additional types of structural variation that are tolerable in the evolution of functional molecules.…”

Section: Discussionmentioning

confidence: 99%

Evolution of functional nucleic acids in the presence of nonheritable backbone heterogeneity

Trevino

Zhang

Elenko

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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Multiple lines of evidence support the hypothesis that the early evolution of life was dominated by RNA, which can both transfer information from generation to generation through replication directed by base-pairing, and carry out biochemical activities by folding into functional structures. To understand how life emerged from prebiotic chemistry we must therefore explain the steps that led to the emergence of the RNA world, and in particular, the synthesis of RNA. The generation of pools of highly pure ribonucleotides on the early Earth seems unlikely, but the presence of alternative nucleotides would support the assembly of nucleic acid polymers containing nonheritable backbone heterogeneity. We suggest that homogeneous monomers might not have been necessary if populations of heterogeneous nucleic acid molecules could evolve reproducible function. For such evolution to be possible, function would have to be maintained despite the repeated scrambling of backbone chemistry from generation to generation. We have tested this possibility in a simplified model system, by using a T7 RNA polymerase variant capable of transcribing nucleic acids that contain an approximately 1∶1 mixture of deoxy-and ribonucleotides. We readily isolated nucleotide-binding aptamers by utilizing an in vitro selection process that shuffles the order of deoxy-and ribonucleotides in each round. We describe two such RNA/DNA mosaic nucleic acid aptamers that specifically bind ATP and GTP, respectively. We conclude that nonheritable variations in nucleic acid backbone structure may not have posed an insurmountable barrier to the emergence of functionality in early nucleic acids.abiogenesis | genetic takeover | RNA progenitor | origin of life G iven that RNA is likely to have played a key role early in the evolution of life (1), understanding the origins of the RNAbased biosphere is a critical aspect of understanding the origin of life. The difficulties associated with the prebiotic synthesis of a macromolecule as complicated and fragile as RNA have stimulated interest in the hypothesis that RNA was preceded by simpler and/or more stable progenitor nucleic acids (2-4). The systematic exploration of nucleic acids that are structurally related to RNA has revealed that the formation of stable WatsonCrick base-paired, antiparallel duplex structures is compatible with a surprising degree of variation in the sugar-phosphate backbone (5). These studies imply that many distinct nucleic acids are in principle capable of mediating the inheritance of genetic information. On the other hand, recent advances in the prebiotic chemistry leading to the pyrimidine ribonucleotides (6) have revived the prospects of the RNA-first model, with the attendant advantage of avoiding a difficult genetic takeover. Both RNAfirst and RNA-late models assume that life began with a single, well-defined genetic polymer. Perhaps the greatest problem implicit in this assumption is the challenge of explaining the origin of pure nucleotide monomers on the early Earth. Indeed, the supp...

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Section: Discussionmentioning

confidence: 99%

Evolution of functional nucleic acids in the presence of nonheritable backbone heterogeneity

Trevino

Zhang

Elenko

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

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“…For this purpose, various synthetic approaches have been developed, such as Merrifi eld ' s solid-phase synthesis and enzymatic or non-enzymatic template polymerization, which are used for the synthesis of oligopeptides and oligonucleotides from natural or non-natural building blocks and for producing non-natural oligoamides, oligoesters, oligoureas, oligocarbamates and oligosaccharides 1 -10 . Th ese are all condensation polymers consisting of heteroatom-containing main-chain linkages, such as amide, ester, ether and so on, and prepared by successive stepwise condensation reactions, which can be automated sometimes 2,3 .…”

mentioning

confidence: 99%

Sequence-regulated vinyl copolymers by metal-catalysed step-growth radical polymerization

et al. 2010

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Proteins and nucleic acids are sequence-regulated macromolecules with various properties originating from their perfectly sequenced primary structures. However, the sequence regulation of synthetic polymers, particularly vinyl polymers, has not been achieved and is one of the ultimate goals in polymer chemistry. In this study, we report a strategy to obtain sequenceregulated vinyl copolymers consisting of styrene, acrylate and vinyl chloride units using metalcatalysed step-growth radical polyaddition of designed monomers prepared from common vinyl monomer building blocks. Unprecedented ABCC-sequence-regulated copolymers with perfect vinyl chloride -styrene -acrylate -acrylate sequences were obtained by copper-catalysed step-growth radical polymerization of designed monomers possessing unconjugated C = C and reactive C -Cl bonds. This strategy may open a new route in the study of sequence-regulated synthetic polymers.

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“…[75] These artificial biopolymers could overcome current limitations such as instability, limited functional groups, bioavailability and immunogenicity. [71] To conclude, engineered DNA polymerases already are and will be the workhorses in many biotechnological applications in the future, which is why this growing field of research is attractive to both industry and academia alike.…”

Section: Incorporation Of Modified Nucleotidesmentioning

confidence: 98%

“…[68] First examples show that DNA polymerases can indeed tolerate artificial amino acids without the significant loss of activity. [69] Future goals could be efficient enzymatic production and improved amplification of unnatural biopolymers [70,71] such as l-DNA, peptide nucleic acids (PNA), [72] locked nucleic acids (LNA), [73] glycol nucleic acids (GNA), [74] and threose nucleic acids (TNA). [75] These artificial biopolymers could overcome current limitations such as instability, limited functional groups, bioavailability and immunogenicity.…”

Section: Incorporation Of Modified Nucleotidesmentioning

confidence: 99%

Engineered DNA Polymerases in Biotechnology

Kranaster

Marx

2010

ChemBioChem

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Recent Progress Toward the Templated Synthesis and Directed Evolution of Sequence-Defined Synthetic Polymers

Cited by 99 publications

References 167 publications

Evolution of functional nucleic acids in the presence of nonheritable backbone heterogeneity

Evolution of functional nucleic acids in the presence of nonheritable backbone heterogeneity

Sequence-regulated vinyl copolymers by metal-catalysed step-growth radical polymerization

Engineered DNA Polymerases in Biotechnology

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