B-DNA model systems in non-terran bio-solvents: Implications for structure, stability and replication

Trevor A. Hamlin; Jordi Poater; Célia Fonseca Guerra; F. Matthias Bickelhaupt

doi:10.1039/c7cp01908d

B-DNA model systems in non-terran bio-solvents: Implications for structure, stability and replication

Trevor A. Hamlin, Jordi Poater, Célia Fonseca Guerra, F. Matthias Bickelhaupt

Research output: Contribution to journal › Article › peer-review

25 Citations (Scopus)

Abstract

We have computationally analyzed a comprehensive series of Watson-Crick and mismatched B-DNA base pairs, in the gas phase and in several solvents, including toluene, chloroform, ammonia, methanol and water, using dispersion-corrected density functional theory and implicit solvation. Our analyses shed light on how the molecular-recognition machinery behind life's genetic code depends on the medium, in order to contribute to our understanding of the possibility or impossibility for life to exist on exoplanetary bodies. Calculations show how a common non-terran environment like ammonia, less polar than water, exhibits stronger hydrogen-bonding affinities, although showing reduced selectivities towards the correct incorporation of Watson-Crick base pairs into the backbone. Thus, we prove the viability of DNA replication in a non-terran environment.

Original language	English
Pages (from-to)	16969-16978
Number of pages	10
Journal	Physical Chemistry Chemical Physics
Volume	19
Issue number	26
DOIs	https://doi.org/10.1039/c7cp01908d
Publication status	Published - 2017
Externally published	Yes

ASJC Scopus subject areas

General Physics and Astronomy
Physical and Theoretical Chemistry

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title = "B-DNA model systems in non-terran bio-solvents: Implications for structure, stability and replication",

abstract = "We have computationally analyzed a comprehensive series of Watson-Crick and mismatched B-DNA base pairs, in the gas phase and in several solvents, including toluene, chloroform, ammonia, methanol and water, using dispersion-corrected density functional theory and implicit solvation. Our analyses shed light on how the molecular-recognition machinery behind life's genetic code depends on the medium, in order to contribute to our understanding of the possibility or impossibility for life to exist on exoplanetary bodies. Calculations show how a common non-terran environment like ammonia, less polar than water, exhibits stronger hydrogen-bonding affinities, although showing reduced selectivities towards the correct incorporation of Watson-Crick base pairs into the backbone. Thus, we prove the viability of DNA replication in a non-terran environment.",

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T2 - Implications for structure, stability and replication

AU - Hamlin, Trevor A.

AU - Poater, Jordi

AU - Fonseca Guerra, Célia

AU - Bickelhaupt, F. Matthias

PY - 2017

Y1 - 2017

N2 - We have computationally analyzed a comprehensive series of Watson-Crick and mismatched B-DNA base pairs, in the gas phase and in several solvents, including toluene, chloroform, ammonia, methanol and water, using dispersion-corrected density functional theory and implicit solvation. Our analyses shed light on how the molecular-recognition machinery behind life's genetic code depends on the medium, in order to contribute to our understanding of the possibility or impossibility for life to exist on exoplanetary bodies. Calculations show how a common non-terran environment like ammonia, less polar than water, exhibits stronger hydrogen-bonding affinities, although showing reduced selectivities towards the correct incorporation of Watson-Crick base pairs into the backbone. Thus, we prove the viability of DNA replication in a non-terran environment.

AB - We have computationally analyzed a comprehensive series of Watson-Crick and mismatched B-DNA base pairs, in the gas phase and in several solvents, including toluene, chloroform, ammonia, methanol and water, using dispersion-corrected density functional theory and implicit solvation. Our analyses shed light on how the molecular-recognition machinery behind life's genetic code depends on the medium, in order to contribute to our understanding of the possibility or impossibility for life to exist on exoplanetary bodies. Calculations show how a common non-terran environment like ammonia, less polar than water, exhibits stronger hydrogen-bonding affinities, although showing reduced selectivities towards the correct incorporation of Watson-Crick base pairs into the backbone. Thus, we prove the viability of DNA replication in a non-terran environment.

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B-DNA model systems in non-terran bio-solvents: Implications for structure, stability and replication

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