Your search keyword '"O'Flaherty DK"' showing total 10 results

1. Unusual Base Pair between Two 2-Thiouridines and Its Implication for Nonenzymatic RNA Copying.

Author

Ding D, Fang Z, Kim SC, O'Flaherty DK, Jia X, Stone TB, Zhou L, and Szostak JW

Subjects

Base Pairing, Thiouridine chemistry, Nucleic Acid Conformation, RNA chemistry, Thiouridine analogs & derivatives, RNA, Catalytic chemistry

Abstract

2-Thiouridine (s 2 U) is a nucleobase modification that confers enhanced efficiency and fidelity both on modern tRNA codon translation and on nonenzymatic and ribozyme-catalyzed RNA copying. We have discovered an unusual base pair between two 2-thiouridines that stabilizes an RNA duplex to a degree that is comparable to that of a native A:U base pair. High-resolution crystal structures indicate similar base-pairing geometry and stacking interactions in duplexes containing s 2 U:s 2 U compared to those with U:U pairs. Notably, the C═O···H-N hydrogen bond in the U:U pair is replaced with a C═S···H-N hydrogen bond in the s 2 U:s 2 U base pair. The thermodynamic stability of the s 2 U:s 2 U base pair suggested that this self-pairing might lead to an increased error frequency during nonenzymatic RNA copying. However, competition experiments show that s 2 U:s 2 U base-pairing induces only a low level of misincorporation during nonenzymatic RNA template copying because the correct A:s 2 U base pair outcompetes the slightly weaker s 2 U:s 2 U base pair. In addition, even if an s 2 U is incorrectly incorporated, the addition of the next base is greatly hindered. This strong stalling effect would further increase the effective fidelity of nonenzymatic RNA copying with s 2 U. Our findings suggest that s 2 U may enhance the rate and extent of nonenzymatic copying with only a minimal cost in fidelity.

Published

2024

2. Thermally Driven Membrane Phase Transitions Enable Content Reshuffling in Primitive Cells.

Author

Rubio-Sánchez R, O'Flaherty DK, Wang A, Coscia F, Petris G, Di Michele L, Cicuta P, and Bonfio C

Subjects

Cell Membrane chemistry, Cell Membrane metabolism, Temperature, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Phase Transition, Fatty Acids chemistry, Artificial Cells chemistry, Artificial Cells metabolism

Abstract

Self-assembling single-chain amphiphiles available in the prebiotic environment likely played a fundamental role in the advent of primitive cell cycles. However, the instability of prebiotic fatty acid-based membranes to temperature and pH seems to suggest that primitive cells could only host prebiotically relevant processes in a narrow range of nonfluctuating environmental conditions. Here we propose that membrane phase transitions, driven by environmental fluctuations, enabled the generation of daughter protocells with reshuffled content. A reversible membrane-to-oil phase transition accounts for the dissolution of fatty acid-based vesicles at high temperatures and the concomitant release of protocellular content. At low temperatures, fatty acid bilayers reassemble and encapsulate reshuffled material in a new cohort of protocells. Notably, we find that our disassembly/reassembly cycle drives the emergence of functional RNA-containing primitive cells from parent nonfunctional compartments. Thus, by exploiting the intrinsic instability of prebiotic fatty acid vesicles, our results point at an environmentally driven tunable prebiotic process, which supports the release and reshuffling of oligonucleotides and membrane components, potentially leading to a new generation of protocells with superior traits. In the absence of protocellular transport machinery, the environmentally driven disassembly/assembly cycle proposed herein would have plausibly supported protocellular content reshuffling transmitted to primitive cell progeny, hinting at a potential mechanism important to initiate Darwinian evolution of early life forms.

Published

2021

3. The Emergence of RNA from the Heterogeneous Products of Prebiotic Nucleotide Synthesis.

Author

Kim SC, O'Flaherty DK, Giurgiu C, Zhou L, and Szostak JW

Subjects

Nucleotides chemistry, RNA genetics, Templates, Genetic, Evolution, Molecular, RNA chemistry

Abstract

Recent advances in prebiotic chemistry are beginning to outline plausible pathways for the synthesis of the canonical ribonucleotides and their assembly into oligoribonucleotides. However, these reaction pathways suggest that many noncanonical nucleotides are likely to have been generated alongside the standard ribonucleotides. Thus, the oligomerization of prebiotically synthesized nucleotides is likely to have led to a highly heterogeneous collection of oligonucleotides comprised of a wide range of types of nucleotides connected by a variety of backbone linkages. How then did relatively homogeneous RNA emerge from this primordial heterogeneity? Here we focus on nonenzymatic template-directed primer extension as a process that would have strongly enriched for homogeneous RNA over the course of multiple cycles of replication. We review the effects on copying the kinetics of nucleotides with altered nucleobase and sugar moieties, when they are present as activated monomers and when they are incorporated into primer and template oligonucleotides. We also discuss three variations in backbone connectivity, all of which are nonheritable and regenerate native RNA upon being copied. The kinetic superiority of RNA synthesis suggests that nonenzymatic copying served as a chemical selection mechanism that allowed relatively homogeneous RNA to emerge from a complex mixture of prebiotically synthesized nucleotides and oligonucleotides.

Published

2021

4. Assembly of a Ribozyme Ligase from Short Oligomers by Nonenzymatic Ligation.

Author

Zhou L, O'Flaherty DK, and Szostak JW

Subjects

Ligases chemistry, Oligonucleotides chemistry, RNA, Catalytic chemistry, Ligases metabolism, Oligonucleotides metabolism, RNA, Catalytic metabolism

Abstract

Our current understanding of the chemistry of the primordial genetic material is fragmentary at best. The chemical replication of oligonucleotides long enough to perform catalytic functions is particularly problematic because of the low efficiency of nonenzymatic template copying. Here we show that this problem can be circumvented by assembling a functional ribozyme by the templated ligation of short oligonucleotides. However, this approach creates a new problem because the splint oligonucleotides used to drive ribozyme assembly strongly inhibit the resulting ribozyme. We explored three approaches to the design of splint oligonucleotides that enable efficient ligation but which allow the assembled ribozyme to remain active. DNA splints, splints with G:U wobble pairs, and splints with G to I (Inosine) substitutions all allowed for the efficient assembly of an active ribozyme ligase. Our work demonstrates the possibility of a transition from nonenzymatic ligation to enzymatic ligation and reveals the importance of avoiding ribozyme inhibition by complementary oligonucleotides.

Published

2020

5. A Model for the Emergence of RNA from a Prebiotically Plausible Mixture of Ribonucleotides, Arabinonucleotides, and 2'-Deoxynucleotides.

Author

Kim SC, Zhou L, Zhang W, O'Flaherty DK, Rondo-Brovetto V, and Szostak JW

Subjects

Polymerization, Arabinonucleotides chemistry, Deoxyribonucleotides chemistry, Models, Chemical, RNA chemistry, Ribonucleotides chemistry

Abstract

The abiotic synthesis of ribonucleotides is thought to have been an essential step toward the emergence of the RNA world. However, it is likely that the prebiotic synthesis of ribonucleotides was accompanied by the simultaneous synthesis of arabinonucleotides, 2'-deoxyribonucleotides, and other variations on the canonical nucleotides. In order to understand how relatively homogeneous RNA could have emerged from such complex mixtures, we have examined the properties of arabinonucleotides and 2'-deoxyribonucleotides in nonenzymatic template-directed primer extension reactions. We show that nonenzymatic primer extension with activated arabinonucleotides is much less efficient than with activated ribonucleotides, and furthermore that once an arabinonucleotide is incorporated, continued primer extension is strongly inhibited. As previously shown, 2'-deoxyribonucleotides are also less efficiently incorporated in primer extension reactions, but the difference is more modest. Experiments with mixtures of nucleotides suggest that the coexistence of ribo- and arabinonucleotides does not impede the copying of RNA templates. Moreover, chimeric oligoribonucleotides containing 2'-deoxy- or arabinonucleotides are effective templates for RNA synthesis. We propose that the initial genetic polymers were random sequence chimeric oligonucleotides formed by untemplated polymerization, but that template copying chemistry favored RNA synthesis; multiple rounds of replication may have led to pools of oligomers composed mainly of RNA.

Published

2020

6. Prebiotically Plausible "Patching" of RNA Backbone Cleavage through a 3'-5' Pyrophosphate Linkage.

Author

Wright TH, Giurgiu C, Zhang W, Radakovic A, O'Flaherty DK, Zhou L, and Szostak JW

Subjects

Half-Life, Hydrolysis, Kinetics, RNA Cleavage, Diphosphates chemistry, RNA chemistry

Abstract

Achieving multiple cycles of RNA replication within a model protocell would be a critical step toward demonstrating a path from prebiotic chemistry to cellular biology. Any model for early life based on an "RNA world" must account for RNA strand cleavage and hydrolysis, which would degrade primitive genetic information and lead to an accumulation of truncated, phosphate-terminated strands. We show here that cleavage of the phosphodiester backbone is not an end point for RNA replication. Instead, 3'-phosphate-terminated RNA strands can participate in template-directed copying reactions with activated ribonucleotide monomers. These reactions form a pyrophosphate linkage, the stability of which we have characterized in the context of RNA copying chemistry. The presence of free magnesium cations results in cleavage of the pyrophosphate bond within minutes. However, we found that the pyrophosphate bond is relatively stable within an RNA duplex and in the presence of chelated magnesium. We show that, under these conditions, pyrophosphate-linked RNA can act as a template for the polymerization of ribonucleotides into canonical 3'-5' phosphodiester-linked RNA. We suggest that primer extension of 3'-phosphate-terminated RNA followed by template-directed copying represents a plausible nonenzymatic pathway for the salvage and recovery of genetic information following strand cleavage.

Published

2019

7. Nonenzymatic Template-Directed Synthesis of Mixed-Sequence 3'-NP-DNA up to 25 Nucleotides Long Inside Model Protocells.

Author

O'Flaherty DK, Zhou L, and Szostak JW

Subjects

DNA chemistry, Models, Molecular, Artificial Cells chemistry, DNA chemical synthesis

Abstract

Efficiently copying mixed-sequence oligonucleotide templates nonenzymatically is a long-standing problem both with respect to the origin of life, and with regard to bottom up efforts to synthesize artificial living systems. Here we report an efficient and sequence-general nonenzymatic process in which RNA templates direct the synthesis of a complementary strand composed of N3'→P5' phosphoramidate DNA (3'-NP-DNA) using 3'-amino-2',3'-dideoxyribonucleotides activated with 2-aminoimidazole. Using only the four canonical nucleobases (A, G, C, and T) of modern DNA, we demonstrate the chemical copying of a variety of mixed-sequence RNA templates, both in solution and within model protocells, into complementary 3'-NP-DNA strands. Templates up to 25 nucleotides long were chemically transcribed with an average stepwise yield of 96-97%. The nonenzymatic template-directed generation of primer extension products long enough to encode active ribozymes and/or aptamers inside model protocells suggests possible routes to the synthesis of evolving cellular systems.

Published

2019

8. Copying of Mixed-Sequence RNA Templates inside Model Protocells.

Author

O'Flaherty DK, Kamat NP, Mirza FN, Li L, Prywes N, and Szostak JW

Subjects

Base Sequence, Temperature, Citric Acid chemistry, Fatty Acids chemistry, Magnesium chemistry, RNA chemistry

Abstract

The chemical replication of RNA inside fatty acid vesicles is a plausible step in the emergence of cellular life. On the primitive Earth, simple protocells with the ability to import nucleotides and short oligomers from their environment could potentially have replicated and retained larger genomic RNA oligonucleotides within a spatially defined compartment. We have previously shown that short 5'-phosphoroimidazolide-activated "helper" RNA oligomers enable the nonenzymatic copying of mixed-sequence templates in solution, using 5'-phosphoroimidazolide-activated mononucleotides. Here, we report that citrate-chelated Mg 2+ , a catalyst of nonenzymatic primer extension, enhances fatty acid membrane permeability to such short RNA oligomers up to the size of tetramers, without disrupting vesicle membranes. In addition, selective permeability of short, but not long, oligomers can be further enhanced by elevating the temperature. The ability to increase the permeability of fatty acid membranes to short oligonucleotides allows for the nonenzymatic copying of RNA templates containing all four nucleotides inside vesicles, bringing us one step closer to the goal of building a protocell capable of Darwinian evolution.

Published

2018

9. A Mechanistic Explanation for the Regioselectivity of Nonenzymatic RNA Primer Extension.

Author

Giurgiu C, Li L, O'Flaherty DK, Tam CP, and Szostak JW

Subjects

Nucleic Acid Conformation, Stereoisomerism, RNA chemistry

Abstract

A working model of nonenzymatic RNA primer extension could illuminate how prebiotic chemistry transitioned to biology. All currently known experimental reconstructions of nonenzymatic RNA primer extension yield a mixture of 2'-5' and 3'-5' internucleotide linkages. Although long seen as a major problem, the causes of the poor regioselectivity of the reaction are unknown. We used a combination of different leaving groups, nucleobases, and templating sequences to uncover the factors that yield selective formation of 3'-5' internucleotide linkages. We found that fast and high yielding reactions selectively form 3'-5' linkages. Additionally, in all cases with high 3'-5' regioselectivity, Watson-Crick base pairing between the RNA monomers and the template is observed at the extension site and at the adjacent downstream position. Mismatched base-pairs and other factors that would perturb the geometry of the imidazolium bridged intermediate lower both the rate and regioselectivity of the reaction.

Published

2017

10. Enhanced Nonenzymatic RNA Copying with 2-Aminoimidazole Activated Nucleotides.

Author

Li L, Prywes N, Tam CP, O'Flaherty DK, Lelyveld VS, Izgu EC, Pal A, and Szostak JW

Subjects

RNA chemistry, Imidazoles chemistry, Nucleotides chemistry, RNA chemical synthesis

Abstract

Achieving efficient nonenzymatic replication of RNA is an important step toward the synthesis of self-replicating protocells that may mimic early forms of life. Despite recent progress, the nonenzymatic copying of templates containing mixed sequences remains slow and inefficient. Here we demonstrate that activating nucleotides with 2-aminoimidazole results in superior reaction kinetics and improved yields of primer extension reaction products. This new leaving group significantly accelerates monomer addition as well as trimer-assisted RNA primer extension, allowing efficient copying of a variety of short RNA templates with mixed sequences.

Published

2017