Nonenzymatic assembly of active chimeric ribozymes from aminoacylated RNA oligonucleotides

Radakovic, Aleksandar; DasGupta, Saurja; Wright, Tom H.; Aitken, Harry R. M.; Szostak, Jack W.

doi:10.1073/pnas.2116840119

Cited by 15 publications

(16 citation statements)

References 52 publications

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“…A compatible in situ activation chemistry that could maintain sets of oligonucleotides in an activated state − might drive these ligation reactions closer to completion and thus favor ribozyme assembly by iterated loop-closing ligations. The efficiency of loop-closing ligation could also be increased by using 3′-amino terminated oligonucleotides, as suggested by our previous work with the splinted ligation of 3′-amino or 2′/3′-aminoacylated nucleotides. , …”

Section: Discussionmentioning

confidence: 97%

“…The efficiency of loop-closing ligation could also be increased by using 3′-amino terminated oligonucleotides, as suggested by our previous work with the splinted ligation of 3′-amino or 2′/ 3′-aminoacylated nucleotides. 10,17 The noncovalent assembly of fragments into partly functional ensembles can be seen as an evolutionary precursor to the assembly of full-length ribozymes by loop-closing ligation. [21][22][23][24]45 Notably, it has been demonstrated experimentally that compared to fully random pools of RNA, compact structured pools are superior sources of functional RNAs in in vitro selection experiments.…”

Section: ■ Discussionmentioning

confidence: 99%

“…However, ribozymes assembled in this manner are inevitably subject to inhibition by a full-length template or even by shorter splint templates. − , Either product purification to remove the template or the design of splints that bind strongly enough to allow for ligation but weakly enough to avoid inhibition are needed to enable RNA function. Previous efforts to assemble ribozymes by splinted ligation also made use of 3′-amino terminated or 2′,3′-aminoacylated oligonucleotides to increase the efficiency of ligation. A further problem with the generation of complex-structured RNAs is that the final structure is only realized during the folding stage (unfolded ligation product in Figure , top pathway).…”

Section: Introductionmentioning

confidence: 99%

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Template-Free Assembly of Functional RNAs by Loop-Closing Ligation

Liu

Roberts

et al. 2022

J. Am. Chem. Soc.

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The first ribozymes are thought to have emerged at a time when RNA replication proceeded via nonenzymatic template copying processes. However, functional RNAs have stable folded structures, and such structures are much more difficult to copy than short unstructured RNAs. How can these conflicting requirements be reconciled? Also, how can the inhibition of ribozyme function by complementary template strands be avoided or minimized? Here, we show that short RNA duplexes with single-stranded overhangs can be converted into RNA stem loops by nonenzymatic cross-strand ligation. We then show that loop-closing ligation reactions enable the assembly of full-length functional ribozymes without any external template. Thus, one can envisage a potential pathway whereby structurally complex functional RNAs could have formed at an early stage of evolution when protocell genomes might have consisted only of collections of short replicating oligonucleotides.

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Section: Discussionmentioning

confidence: 97%

Section: ■ Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Template-Free Assembly of Functional RNAs by Loop-Closing Ligation

Liu

Roberts

et al. 2022

J. Am. Chem. Soc.

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“…During these early “nonenzymatic” times, the chemical template‐directed RNA copying is thought to have played a key role in the origin of translation [80] where the aminoacylation of short RNA oligonucleotides helped in their assembly into functional ribozymes [81] . Prior to the evolution of ribosomal translation, such ribozymes, with their distinct sequences, would have been subject to the UV‐induced sequence selection as described in this review.…”

Section: Prebiotic Impactmentioning

confidence: 97%

The Photophysics of Nucleic Acids: Consequences for the Emergence of Life

2022

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Absorption of ultraviolet (UV) radiation can trigger a variety of photophysical and photochemical reactions in nucleic acids. In the prebiotic era, on the surface of the early Earth, UV light could have played a major role in the selection of the building blocks of life via a balance between synthetic and destructive pathways. As nucleic acid monomers assembled into polymers, their survival and facility for non‐enzymatic replication hinged on their photostability and the ability for self‐repair of lesions, e. g., by UV‐induced charge transfer. Such photoprocesses are known to be sequence‐dependent and could have led to an additional prebiotic selection of the genetic sequence pools available to the earliest life forms. This review summarizes the photophysical processes in nucleic acids upon the absorption of a UV photon and their implications for chemical and genetic selection at the emergence of life and the origin of translation.

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“…Specific interactions between nucleic acids (e.g., DNA and RNA) and peptides may have been essential at the origin of life. 17,18,[31][32][33][34][35]54,55 It is even possible that evidence for this primordial interaction is preserved today in the core of the ribosome, 56 making the interrogation of the available prebiotic composition of (cationic) peptides an especially important undertaking. By investigating the viability of Lys homologues in aqueous peptide nitrile ligations, we have observed a pronounced differentiation of Lys from both Orn and Dab.…”

Section: ■ Conclusionmentioning

confidence: 99%

Selective Synthesis of Lysine Peptides and the Prebiotically Plausible Synthesis of Catalytically Active Diaminopropionic Acid Peptide Nitriles in Water

Thoma

Powner

2023

J. Am. Chem. Soc.

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Why life encodes specific proteinogenic amino acids remains an unsolved problem, but a non-enzymatic synthesis that recapitulates biology’s universal strategy of stepwise N-to-C terminal peptide growth may hold the key to this selection. Lysine is an important proteinogenic amino acid that, despite its essential structural, catalytic, and functional roles in biochemistry, has widely been assumed to be a late addition to the genetic code. Here, we demonstrate that lysine thioacids undergo coupling with aminonitriles in neutral water to afford peptides in near-quantitative yield, whereas non-proteinogenic lysine homologues, ornithine, and diaminobutyric acid cannot form peptides due to rapid and quantitative cyclization that irreversibly blocks peptide synthesis. We demonstrate for the first time that ornithine lactamization provides an absolute differentiation of lysine and ornithine during (non-enzymatic) N-to-C-terminal peptide ligation. We additionally demonstrate that the shortest lysine homologue, diaminopropionic acid, undergoes effective peptide ligation. This prompted us to discover a high-yielding prebiotically plausible synthesis of the diaminopropionic acid residue, by peptide nitrile modification, through the addition of ammonia to a dehydroalanine nitrile. With this synthesis in hand, we then discovered that the low basicity of diaminopropionyl residues promotes effective, biomimetic, imine catalysis in neutral water. Our results suggest diaminopropionic acid, synthesized by peptide nitrile modification, can replace or augment lysine residues during early evolution but that lysine’s electronically isolated sidechain amine likely provides an evolutionary advantage for coupling and coding as a preformed monomer in monomer-by-monomer peptide translation.

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Nonenzymatic assembly of active chimeric ribozymes from aminoacylated RNA oligonucleotides

Cited by 15 publications

References 52 publications

Template-Free Assembly of Functional RNAs by Loop-Closing Ligation

Template-Free Assembly of Functional RNAs by Loop-Closing Ligation

The Photophysics of Nucleic Acids: Consequences for the Emergence of Life

Selective Synthesis of Lysine Peptides and the Prebiotically Plausible Synthesis of Catalytically Active Diaminopropionic Acid Peptide Nitriles in Water

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