Glycosidic bond cleavage in deoxynucleotides — A density functional study

Density functional theory was used to study the glycosidic bond cleavage in deoxynucleotides with the main goal to determine the effects of the nucleobase, hydrogen bonding with the nucleobase, and the (bulk) environment on the reaction energetics. Since direct glycosidic bond cleavage is a high-ene...

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Veröffentlicht in:	Canadian journal of chemistry 2009-07, Vol.87 (7), p.850-863
Hauptverfasser:	Millen, Andrea L, Wetmore, Stacey D
Format:	Artikel
Sprache:	eng
Schlagworte:	Acidity Chemical properties Chemical reactions Density Density functionals Deoxyribonucleotides Hydrogen Hydrogen bonding Hydrogen bonds Molecular chemistry
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container_title	Canadian journal of chemistry
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creator	Millen, Andrea L Wetmore, Stacey D
description	Density functional theory was used to study the glycosidic bond cleavage in deoxynucleotides with the main goal to determine the effects of the nucleobase, hydrogen bonding with the nucleobase, and the (bulk) environment on the reaction energetics. Since direct glycosidic bond cleavage is a high-energy process, two nucleophile models were considered (HCO[O.sup.-] ... [H.sub.2]O and H[O.sup.-]), which represent different stages of activation of a water nucleophile. The glycosidic bond cleavage barriers were found to decrease, while the reaction exothermicity increases, with an increase in the nucleobase acidity. The gas-phase barriers and reaction energies for bond cleavage in all deoxynucleotides were found to be significantly affected by hydrogen-bonding interactions with the nucleobase (by up to 30 kJ [mol.sup.-1] depending on the nucleophile). Although the barriers increase and reaction energies become less exothermic in enzymatic and aqueous environments, the effects of the bulk environment are similar in the presence and absence of small molecules bound to the nucleobase. Therefore, the effects of hydrogen bonding with the bases are approximately the same in all environments. Our results suggest that hydrogen bonding with the nucleobase may play an important role in the glycosidic bond cleavage in both pyrimidine and purine nucleotides in a variety of environments.
doi_str_mv	10.1139/v09-024
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Since direct glycosidic bond cleavage is a high-energy process, two nucleophile models were considered (HCO[O.sup.-] ... [H.sub.2]O and H[O.sup.-]), which represent different stages of activation of a water nucleophile. The glycosidic bond cleavage barriers were found to decrease, while the reaction exothermicity increases, with an increase in the nucleobase acidity. The gas-phase barriers and reaction energies for bond cleavage in all deoxynucleotides were found to be significantly affected by hydrogen-bonding interactions with the nucleobase (by up to 30 kJ [mol.sup.-1] depending on the nucleophile). Although the barriers increase and reaction energies become less exothermic in enzymatic and aqueous environments, the effects of the bulk environment are similar in the presence and absence of small molecules bound to the nucleobase. Therefore, the effects of hydrogen bonding with the bases are approximately the same in all environments. 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subjects	Acidity Chemical properties Chemical reactions Density Density functionals Deoxyribonucleotides Hydrogen Hydrogen bonding Hydrogen bonds Molecular chemistry
title	Glycosidic bond cleavage in deoxynucleotides — A density functional study
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