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The solution structure of a DNA·RNA duplex containing 5-propynyl U and C; comparison with 5-Me modifications

The solution structure of a DNA·RNA duplex containing 5-propynyl U and C; comparison with 5-Me modifications
The solution structure of a DNA·RNA duplex containing 5-propynyl U and C; comparison with 5-Me modifications
The addition of the propynyl group at the 5 position of pyrimidine nucleotides is highly stabilising. We have determined the thermodynamic stability of the DNA·RNA hybrid r(GAAGAGAAGC)·d(GCpUpUpCpUp CpUpUpC) where p is the propynyl group at the 5 position and compared it with that of the unmodified duplex and the effects of methyl substitutions. The incorporation of the propyne group at the 5 position gives rise to a very large stabilisation of the hybrid duplex compared with the analogous 5-Me modification. The duplexes have been characterised by gel electrophoresis and NMR spectroscopy, which indicate that methyl substitutions have a smaller influence on local and global conformation than the propynyl groups. The increased NMR spectral dispersion of the propyne-modified duplex allowed a larger number of experimental restraints to be measured. Restrained molecular dynamics in a fully solvated system showed that the propyne modification leads to substantial conformational rearrangements stabilising a more A-like structure. The propynyl groups occupy a large part of the major groove and make favourable van der Waals interactions with their nearest neighbours and the atoms of the rings. This enhanced overlap may account at least in part for the increased thermodynamic stability. Furthermore, the simulations show a spine of hydration in the major groove as well as in the minor groove involving the RNA hydroxyl groups.
molecular-dynamics simulations, pyrimidine-rich strands, nucleic-acids, hydrodynamic properties, hybrid duplexes, solution conformation, gene-expression, triple-helix, purine-rich, nmr
0305-1048
2683-2693
Gyi, Jeffrey I.
34ff2471-5133-4b23-a361-ab6c1f100c99
Gao, Daquan
fab0f0ca-0cb5-4dd1-93b7-5728017566b4
Conn, Graeme L.
147603d7-8f0e-43fd-84da-eb8818788259
Trent, John O.
aabd4141-64bf-4107-9e61-e1407c09d430
Brown, Tom
a64aae36-bb30-42df-88a2-11be394e8c89
Lane, Andrew N.
45ad386f-2308-4610-998b-7913fa4d457c
Gyi, Jeffrey I.
34ff2471-5133-4b23-a361-ab6c1f100c99
Gao, Daquan
fab0f0ca-0cb5-4dd1-93b7-5728017566b4
Conn, Graeme L.
147603d7-8f0e-43fd-84da-eb8818788259
Trent, John O.
aabd4141-64bf-4107-9e61-e1407c09d430
Brown, Tom
a64aae36-bb30-42df-88a2-11be394e8c89
Lane, Andrew N.
45ad386f-2308-4610-998b-7913fa4d457c

Gyi, Jeffrey I., Gao, Daquan, Conn, Graeme L., Trent, John O., Brown, Tom and Lane, Andrew N. (2003) The solution structure of a DNA·RNA duplex containing 5-propynyl U and C; comparison with 5-Me modifications. Nucleic Acids Research, 31 (10), 2683-2693. (doi:10.1093/nar/gkg356).

Record type: Article

Abstract

The addition of the propynyl group at the 5 position of pyrimidine nucleotides is highly stabilising. We have determined the thermodynamic stability of the DNA·RNA hybrid r(GAAGAGAAGC)·d(GCpUpUpCpUp CpUpUpC) where p is the propynyl group at the 5 position and compared it with that of the unmodified duplex and the effects of methyl substitutions. The incorporation of the propyne group at the 5 position gives rise to a very large stabilisation of the hybrid duplex compared with the analogous 5-Me modification. The duplexes have been characterised by gel electrophoresis and NMR spectroscopy, which indicate that methyl substitutions have a smaller influence on local and global conformation than the propynyl groups. The increased NMR spectral dispersion of the propyne-modified duplex allowed a larger number of experimental restraints to be measured. Restrained molecular dynamics in a fully solvated system showed that the propyne modification leads to substantial conformational rearrangements stabilising a more A-like structure. The propynyl groups occupy a large part of the major groove and make favourable van der Waals interactions with their nearest neighbours and the atoms of the rings. This enhanced overlap may account at least in part for the increased thermodynamic stability. Furthermore, the simulations show a spine of hydration in the major groove as well as in the minor groove involving the RNA hydroxyl groups.

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Published date: 15 May 2003
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Keywords: molecular-dynamics simulations, pyrimidine-rich strands, nucleic-acids, hydrodynamic properties, hybrid duplexes, solution conformation, gene-expression, triple-helix, purine-rich, nmr
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Identifiers

Local EPrints ID: 19969
URI: http://eprints.soton.ac.uk/id/eprint/19969
DOI: doi:10.1093/nar/gkg356
ISSN: 0305-1048
PURE UUID: d8206a83-ed0f-47f5-addf-716d80a0236e

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Date deposited: 24 Feb 2006
Last modified: 15 Mar 2024 06:20

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Contributors

Author: Jeffrey I. Gyi
Author: Daquan Gao
Author: Graeme L. Conn
Author: John O. Trent
Author: Tom Brown
Author: Andrew N. Lane

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