A Shared Prebiotic Formation of Neopterins and Guanine Nucleosides from Pyrimidine Bases

Menor-Salván, C. A.; Burcar, Bradley T.; Bouza, Marcos; Fialho, David M.; Fernández, Facundo M.; Hud, Nicholas V.

doi:10.1002/chem.202200714

Cited by 9 publications

(7 citation statements)

References 51 publications

(96 reference statements)

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“…Then, we found P22 as another important precursor as it can lead to tetraminopyrimidine 68 upon reaction with HCN trimer, aminomalononitrile. Subsequently, tetraminopyrimidine reacts with formamide for the formation of guanine.…”

Section: ■ Results and Discussionmentioning

confidence: 96%

Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH₃ Reactions

Panda,

Anoop

2024

ACS Earth Space Chem.

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In this study, we explore the potential for prebiotic chemistry in an extraterrestrial atmosphere through computational modeling of reactions involving hydrogen cyanide (HCN), hydrogen isocyanide (HNC), and ammonia (NH 3 ). Based on our automated reaction search, we identified several key intermediates, including formamidine (A), formaldehyde hydrazone (B), and methanediimine (C) which serve as precursors for a variety of complex organic compounds. Among the products, methanimine (P5) and guanidine (P22) have been proposed for their relevance to early biological activity. The calculated low activation barriers and exothermic nature of several reactions suggest the viability of these pathways in a cold extraterrestrial environment. Notably, the formation of molecules such as a triazole derivative (P18) and N-cyanoimidoformamide (P20), linked to biomarker cyanamide, underscores the potential for synthesizing biologically significant molecules. We provide theoretical roto-vibrational spectral parameters to assist in the experimental detection of these species, offering insights into the molecular complexity achievable in extraterrestrial atmosphere and contributing to our understanding of prebiotic chemistry in extraterrestrial environments.

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Section: ■ Results and Discussionmentioning

confidence: 96%

Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH₃ Reactions

Panda,

Anoop

2024

ACS Earth Space Chem.

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“…“Ancient” coenzymes comprise those that could be prebiotically synthesized, according to available studies (Miller and Schlesinger, 1993; Keefe et al, 1995; Holliday et al, 2007; Kirschning, 2021; Menor-Salván et al, 2022; Pinna et al, 2022); while the subcategory “Nucleotide derived” includes cofactors chemically derived from nucleotides (White, 1975; (White, 1975; Monteverde et al, 2017). “LUCA” coenzymes were presumably present in the last universal common ancestor (LUCA) and exhibit a universal distribution among Bacteria, Archaea, and Eukarya, although their prebiotically feasible synthesis was not established.…”

Section: Resultsmentioning

confidence: 99%

“…Those are found at the very heart of cellular metabolism and some of them quite possibly branch deep to life’s early start (White, 1976). The core chemistries of the most abundant and ancient coenzymes have been repeatedly detected in material and experiments mimicking prebiotic environments (Miller and Schlesinger, 1993; Keefe et al, 1995; Holliday et al, 2007; Kirschning, 2021; Menor-Salván et al, 2022; Pinna et al, 2022). Along with metal ions and minerals, some of the extant coenzymes could probably catalyze metabolic reactions in the absence of enzymes, before their emergence (Muchowska et al 2020; Henriques Pereira et al 2022; Cvjetan et al, 2023; Dherbassy et al 2023).…”

Section: Discussionmentioning

confidence: 99%

Coenzyme-Protein Interactions since Early Life

Sanchez-Rocha,

Makarov,

Pravda

et al. 2023

Preprint

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Recent findings in protein evolution and peptide prebiotic plausibility have been setting the stage for reconsidering the role of peptides in the early stages of life’s origin. Ancient protein families have been found to share common themes and proteins reduced in composition to prebiotically plausible amino acids have been reported capable of structure formation and key functions, such as binding to RNA. While this may suggest peptide relevance in early life, their functional repertoire when composed of a limited number of early residues (missing some of the most sophisticated functional groups of today’s alphabet) has been debated.Cofactors enrich the functional scope of about half of extant enzymes but whether they could also bind to peptides lacking the evolutionary late amino acids remains speculative. The aim of this study was to resolve the early peptide propensity to bind organic cofactors by analysis of protein-coenzyme interactions across the Protein Data Bank (PDB). We find that the prebiotically plausible amino acids are more abundant in the binding sites of the most ancient coenzymes and that such interactions rely more frequently on the involvement of the protein backbone atoms and metal ion cofactors. Moreover, we have identified a few select examples in today’s enzymes where coenzyme binding is supported solely by prebiotically available amino acids. These results imply the plausibility of a coenzyme-peptide functional collaboration preceding the establishment of the Central Dogma and full protein alphabet evolution.

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“…Secondly, for similar reasons, the class of "nucleic acid bases" should be expanded to include chemicals with similar composition, structure, function and biosynthesis to the canonical adenine, guanine, thymine, cytosine and uracil. Therefore, we should also include, for example, nicotinamide and pterins [80]. We note that this class, therefore, includes the majority of the enzyme cofactors, further strengthening the case that the reason for their existence was catalysis.…”

Section: The Autocatalytic Origins Of Nucleic Acidsmentioning

confidence: 89%

Autocatalytic Selection as a Driver for the Origin of Life

Williamson

2024

Life

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Darwin’s theory of evolution by natural selection was revolutionary because it provided a mechanism by which variation could be selected. This mechanism can only operate on living systems and thus cannot be applied to the origin of life. Here, we propose a viable alternative mechanism for prebiotic systems: autocatalytic selection, in which molecules catalyze reactions and processes that lead to increases in their concentration. Crucially, this provides a driver for increases in concentrations of molecules to a level that permits prebiotic metabolism. We show how this can produce high levels of amino acids, sugar phosphates, nucleotides and lipids and then lead on to polymers. Our outline is supported by a set of guidelines to support the identification of the most likely prebiotic routes. Most of the steps in this pathway are already supported by experimental results. These proposals generate a coherent and viable set of pathways that run from established Hadean geochemistry to the beginning of life.

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A Shared Prebiotic Formation of Neopterins and Guanine Nucleosides from Pyrimidine Bases

Cited by 9 publications

References 51 publications

Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH₃ Reactions

Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH₃ Reactions

Coenzyme-Protein Interactions since Early Life

Autocatalytic Selection as a Driver for the Origin of Life

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A Shared Prebiotic Formation of Neopterins and Guanine Nucleosides from Pyrimidine Bases

Cited by 9 publications

References 51 publications

Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH3 Reactions

Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH3 Reactions

Coenzyme-Protein Interactions since Early Life

Autocatalytic Selection as a Driver for the Origin of Life

Contact Info

Product

Resources

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Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH₃ Reactions

Potential Prebiotic Pathways in Extraterrestrial Atmosphere: A Computational Exploration of HCN and NH₃ Reactions