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Stability and structural evolution of double-stranded DNA molecules under high pressures : A molecular dynamics study

Herrera-Velarde, Salvador ; Villanueva-Valencia, José Ramón LU ; Mendoza-Espinosa, Paola and Castañeda-Priego, Ramón (2023) In Frontiers in Physics 11.
Abstract

Conformational changes and stability of interacting double-stranded DNA chains under high hydrostatic pressure in biological systems are striking topics of importance to study several biomolecular phenomena. For example, to unravel the physiological conditions at which life might occur and to ensure the right functionality of the biochemical processes into the cell under extreme thermodynamic conditions. Furthermore, such processes could shed light on the physicochemical properties of the DNA under high confinement and how, through different mechanisms, a virus releases its genome in order to infect a cell and, therefore, to promote the process of viral replication. To achieve a few steps toward this direction, we propose an... (More)

Conformational changes and stability of interacting double-stranded DNA chains under high hydrostatic pressure in biological systems are striking topics of importance to study several biomolecular phenomena. For example, to unravel the physiological conditions at which life might occur and to ensure the right functionality of the biochemical processes into the cell under extreme thermodynamic conditions. Furthermore, such processes could shed light on the physicochemical properties of the DNA under high confinement and how, through different mechanisms, a virus releases its genome in order to infect a cell and, therefore, to promote the process of viral replication. To achieve a few steps toward this direction, we propose an all-atomistic molecular dynamics approach in the NPT isothermal-isobaric ensemble to account for how the interplay of DNA—DNA interaction, hydrogen bonding, and the hydrostatic pressure modifies both the DNA conformational degrees of freedom and the spatial organization of the DNA chains in the available volume. We consider two interacting double-stranded DNA chains immersed in an explicit aqueous solution, i.e., water and ions. Our preliminary results highlight the role of hydrogen bonding and electrostatic interactions between DNA strands to avoid denaturation and, therefore, to provide mechanical stability for the DNA molecules. However, the structural evolution, whose kinetics depends on the relaxation of the stresses induced by the pressure, indicates that almost in all pressure conditions, the equilibrium configuration corresponds to an alignment of the two double-stranded DNA molecules along their main axis of symmetry; the rearrangement between the two approaching DNA dodecamers does not always correspond to complementary base pairs and becomes a function of the thermodynamic conditions.

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author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
denaturation, DNA, molecular dynamics, pressure-driven processes, stability
in
Frontiers in Physics
volume
11
article number
1076787
publisher
Frontiers Media S. A.
external identifiers
  • scopus:85148525414
ISSN
2296-424X
DOI
10.3389/fphy.2023.1076787
language
English
LU publication?
yes
id
f6399d6e-2c71-45dd-96c9-5f1d5c45ef77
date added to LUP
2023-03-06 10:07:33
date last changed
2023-11-18 17:24:17
@article{f6399d6e-2c71-45dd-96c9-5f1d5c45ef77,
  abstract     = {{<p>Conformational changes and stability of interacting double-stranded DNA chains under high hydrostatic pressure in biological systems are striking topics of importance to study several biomolecular phenomena. For example, to unravel the physiological conditions at which life might occur and to ensure the right functionality of the biochemical processes into the cell under extreme thermodynamic conditions. Furthermore, such processes could shed light on the physicochemical properties of the DNA under high confinement and how, through different mechanisms, a virus releases its genome in order to infect a cell and, therefore, to promote the process of viral replication. To achieve a few steps toward this direction, we propose an all-atomistic molecular dynamics approach in the NPT isothermal-isobaric ensemble to account for how the interplay of DNA—DNA interaction, hydrogen bonding, and the hydrostatic pressure modifies both the DNA conformational degrees of freedom and the spatial organization of the DNA chains in the available volume. We consider two interacting double-stranded DNA chains immersed in an explicit aqueous solution, i.e., water and ions. Our preliminary results highlight the role of hydrogen bonding and electrostatic interactions between DNA strands to avoid denaturation and, therefore, to provide mechanical stability for the DNA molecules. However, the structural evolution, whose kinetics depends on the relaxation of the stresses induced by the pressure, indicates that almost in all pressure conditions, the equilibrium configuration corresponds to an alignment of the two double-stranded DNA molecules along their main axis of symmetry; the rearrangement between the two approaching DNA dodecamers does not always correspond to complementary base pairs and becomes a function of the thermodynamic conditions.</p>}},
  author       = {{Herrera-Velarde, Salvador and Villanueva-Valencia, José Ramón and Mendoza-Espinosa, Paola and Castañeda-Priego, Ramón}},
  issn         = {{2296-424X}},
  keywords     = {{denaturation; DNA; molecular dynamics; pressure-driven processes; stability}},
  language     = {{eng}},
  publisher    = {{Frontiers Media S. A.}},
  series       = {{Frontiers in Physics}},
  title        = {{Stability and structural evolution of double-stranded DNA molecules under high pressures : A molecular dynamics study}},
  url          = {{http://dx.doi.org/10.3389/fphy.2023.1076787}},
  doi          = {{10.3389/fphy.2023.1076787}},
  volume       = {{11}},
  year         = {{2023}},
}