Structural and Energetic Impact of Non-Natural 7-Deaza-8-Azaadenine and Its 7-Substituted Derivatives on H-Bonding Potential with Uracil in RNA Molecules

Chawla, Mohit; Credendino, Raffaele; Oliva, Romina; Cavallo, Luigi

doi:10.1021/acs.jpcb.5b06861

Cited by 18 publications

(24 citation statements)

References 55 publications

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“…35,39,41,44,48−50 In the present study, we also derived the interaction energies in water, which were calculated using the same recipe as suggested by Sponer and co-workers. 48,74 To have an immediate and intuitive understanding of the impact of a specific modification, we introduced the modification energy, E mod , 36,38 defined as the energy difference between the interaction energy of the modified and that of the corresponding unmodified base pair (in this specific case, the Z:P base pair) Table 1. Geometry and Interaction Energy a of cWW Z:P and tWW Z:iP/iZ:P Base Pairs with 5-Substituted Z. Geometry and interaction energy of cWW G:C and tWW iG:C/G:iC are also reported for comparison.…”

Section: ■ Models and Computational Detailsmentioning

confidence: 99%

Theoretical Characterization of the H-Bonding and Stacking Potential of Two Nonstandard Nucleobases Expanding the Genetic Alphabet

et al. 2016

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We report a quantum chemical characterization of the non-natural (synthetic) H-bonded base pair formed by 6-amino-5-nitro-2(1H)-pyridone (Z) and 2-aminoimidazo[1,2-a]-1,3,5-triazin-4(8H)-one (P). The Z:P base pair, orthogonal to the classical G:C base pair, has been introduced into DNA molecules to expand the genetic code. Our results indicate that the Z:P base pair closely mimics the G:C base pair in terms of both structure and stability. To clarify the role of the NO2 group on the C5 position of the Z base, we compared the stability of the Z:P base pair with that of base pairs having different functional groups at the C5 position of Z. Our results indicate that the electron-donating/-withdrawing properties of the group on C5 have a clear impact on the stability of the Z:P base pair, with the strong electron-withdrawing nitro group achieving the largest stabilizing effect on the H-bonding interaction and the strong electron-donating NH2 group destabilizing the Z:P pair by almost 4 kcal/mol. Finally, our gas-phase and in-water calculations confirm that the Z-nitro group reinforces the stacking interaction with its adjacent purine or pyrimidine ring.

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Section: ■ Models and Computational Detailsmentioning

confidence: 99%

Theoretical Characterization of the H-Bonding and Stacking Potential of Two Nonstandard Nucleobases Expanding the Genetic Alphabet

et al. 2016

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“…We notice that both DAA and DAiG feature a N6 amino group, which can directly interact with the C7-substituents, as indicated by the modification in the electron density around it (Figure 6). [14]…”

Section: Chembiochemmentioning

confidence: 99%

“…[12] Our subsequent quantum mechanics analysis confirmed that the modified 7-deaza-8-azaadenine (DAA) and its 7-substituted derivatives have a negligible impact on the geometry and interaction energy of the base pairs they make with uracil, both in antiparallel and parallel doublehelix strands, and provided a theoretical explanation for that. [14] Similarly, several 7-deaza-8-aza analogues of guanine have also been synthesized and used in different applications in the last couple of decades, especially in the context of DNA. [15] A variety of 7-substituted 7-deaza-8-azaguanine (abbreviated here as DAG) residues, including 7-halogen derivatives, have been shown to stabilize the classical antiparallel DNA duplex, [16] while 7-deaza-8azaisoguanine (abbreviated here as DAiG) and its 7-halogen derivatives have been shown to stabilize the parallel DNA duplex when paired to self-complementary strands.…”

Section: Introductionmentioning

confidence: 99%

“…This is an approach we and others have been applying previously to evaluate the impact of natural and non-natural modifications on various H-bonded base pair systems. [14,21] First, we analyzed the impact of the N7 and C8 atoms translocation in the G skeleton, leading to the DAG modification. Next, we analyzed the impact of the ethynyl and triazole substituents on the C7 atom of DAG, as they are widely used for the chemical labeling of nucleic acids (especially using click chemistry reactivity), allowing to image and retrieve them even in whole organisms, thus monitoring their dynamics in living systems.…”

Section: Introductionmentioning

confidence: 99%

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Structural and Energetic Impact of Non‐natural 7‐Deaza‐8‐azaguanine, 7‐Deaza‐8‐azaisoguanine, and Their 7‐Substituted Derivatives on Hydrogen‐Bond Pairing with Cytosine and Isocytosine

Chawla

Minenkov

et al. 2019

ChemBioChem

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We theoretically characterized the impact that the 7-deaza-8-azaguanine (DAG) and 7-deaza-8azaisoguanine (DAiG) modifications have on the geometry and stability of the G:C Watson-Crick (cWW) base pair and of the G:iC and iG:C reverse Watson-Crick (tWW) base pairs. In addition, we investigated the effect on the same base pairs of seven C7-substituted DAG and DAiG, some of which have been previously experimentally characterized. Our calculations indicate that all these modifications have a negligible impact on the geometry of the above base pairs, and that the modification of the heterocycle skeleton has small impact on the base pair interaction energies. Instead, base pair interaction energies are dependent on the nature of the C7 substituent. For the 7substituted DAG-C cWW systems we found a linear correlation between the base pair interaction energy and the Hammett constant of the 7-substituent, with higher interaction energies corresponding to more electron-withdrawing substituents. Therefore, the explored modifications are expected to be accommodated in both parallel and antiparallel nucleic acid duplexes without perturbing their

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“…This is a rather standard approach used in this kind of calculations. [69][70][71][72][73][74] download file view on ChemRxiv Manuscript.docx (2.22 MiB)…”

Section: Computational Detailsmentioning

confidence: 99%

Enzymatic Formation of an Artificial Base Pair Using a Modified Adenine Nucleoside Triphosphate

Flamme¹,

Röthlisberger²,

Levi‐Acobas³

et al. 2019

Preprint

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The expansion of the genetic alphabet with additional, unnatural base pairs (UBPs) is an important and long standing goal in synthetic biology. Nucleotides acting as ligands for the coordination of metal cations have advanced as promising candidates for such an expansion of the genetic alphabet. However,the inclusion of artificial metal base pairs in nucleic acids mainly relies on solid-phase synthesis approaches and very little is known on polymerase-mediated synthesis. Herein, we report on the selective and high yielding enzymatic construction of a silver-mediated base pair as well as a two-step protocol for the synthesis of DNA duplexes containing a metal UBP. Guided by DFT calculations, we also shed light into the mechanism of formation of this UBP as well as into the structural and energetic preferences. Even though this silver UBP is not directly amenable to in vitro selection experiments, the enzymatic synthesis of this UBP provides valuable insights for the design of future, more potent systems aiming at expanding the genetic alphabet. <br>

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Structural and Energetic Impact of Non-Natural 7-Deaza-8-Azaadenine and Its 7-Substituted Derivatives on H-Bonding Potential with Uracil in RNA Molecules

Cited by 18 publications

References 55 publications

Theoretical Characterization of the H-Bonding and Stacking Potential of Two Nonstandard Nucleobases Expanding the Genetic Alphabet

Theoretical Characterization of the H-Bonding and Stacking Potential of Two Nonstandard Nucleobases Expanding the Genetic Alphabet

Structural and Energetic Impact of Non‐natural 7‐Deaza‐8‐azaguanine, 7‐Deaza‐8‐azaisoguanine, and Their 7‐Substituted Derivatives on Hydrogen‐Bond Pairing with Cytosine and Isocytosine

Enzymatic Formation of an Artificial Base Pair Using a Modified Adenine Nucleoside Triphosphate

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