Glucose–Nucleobase Pseudo Base Pairs: Biomolecular Interactions within DNA

E. Vengut-Climent; I. Goméz-Pinto; R. Lucas; P. Peñalver; A. Avino; C. Fonseca Guerra; F.M. Bickelhaupt; R. Eritja; C. Gonzalez; J.C. Morales

doi:10.1002/anie.201603510

Glucose–Nucleobase Pseudo Base Pairs: Biomolecular Interactions within DNA

E. Vengut-Climent, I. Goméz-Pinto, R. Lucas, P. Peñalver, A. Avino, C. Fonseca Guerra, F.M. Bickelhaupt, R. Eritja, C. Gonzalez, J.C. Morales

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Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Noncovalent forces rule the interactions between biomolecules. Inspired by a biomolecular interaction found in aminoglycoside–RNA recognition, glucose-nucleobase pairs have been examined. Deoxyoligonucleotides with a 6-deoxyglucose insertion are able to hybridize with their complementary strand, thus exhibiting a preference for purine nucleobases. Although the resulting double helices are less stable than natural ones, they present only minor local distortions. 6-Deoxyglucose stays fully integrated in the double helix and its OH groups form two hydrogen bonds with the opposing guanine. This 6-deoxyglucose-guanine pair closely resembles a purine-pyrimidine geometry. Quantum chemical calculations indicate that glucose-purine pairs are as stable as a natural T-A pair.

Original language	English
Pages (from-to)	8643-8647
Number of pages	5
Journal	Angewandte Chemie International Edition in English
Volume	55
Issue number	30
DOIs	https://doi.org/10.1002/anie.201603510
Publication status	Published - 22 Jun 2016

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title = "Glucose–Nucleobase Pseudo Base Pairs: Biomolecular Interactions within DNA",

abstract = "Noncovalent forces rule the interactions between biomolecules. Inspired by a biomolecular interaction found in aminoglycoside–RNA recognition, glucose-nucleobase pairs have been examined. Deoxyoligonucleotides with a 6-deoxyglucose insertion are able to hybridize with their complementary strand, thus exhibiting a preference for purine nucleobases. Although the resulting double helices are less stable than natural ones, they present only minor local distortions. 6-Deoxyglucose stays fully integrated in the double helix and its OH groups form two hydrogen bonds with the opposing guanine. This 6-deoxyglucose-guanine pair closely resembles a purine-pyrimidine geometry. Quantum chemical calculations indicate that glucose-purine pairs are as stable as a natural T-A pair.",

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T1 - Glucose–Nucleobase Pseudo Base Pairs: Biomolecular Interactions within DNA

AU - Vengut-Climent, E.

AU - Goméz-Pinto, I.

AU - Lucas, R.

AU - Peñalver, P.

AU - Avino, A.

AU - Fonseca Guerra, C.

AU - Bickelhaupt, F.M.

AU - Eritja, R.

AU - Gonzalez, C.

AU - Morales, J.C.

PY - 2016/6/22

Y1 - 2016/6/22

N2 - Noncovalent forces rule the interactions between biomolecules. Inspired by a biomolecular interaction found in aminoglycoside–RNA recognition, glucose-nucleobase pairs have been examined. Deoxyoligonucleotides with a 6-deoxyglucose insertion are able to hybridize with their complementary strand, thus exhibiting a preference for purine nucleobases. Although the resulting double helices are less stable than natural ones, they present only minor local distortions. 6-Deoxyglucose stays fully integrated in the double helix and its OH groups form two hydrogen bonds with the opposing guanine. This 6-deoxyglucose-guanine pair closely resembles a purine-pyrimidine geometry. Quantum chemical calculations indicate that glucose-purine pairs are as stable as a natural T-A pair.

AB - Noncovalent forces rule the interactions between biomolecules. Inspired by a biomolecular interaction found in aminoglycoside–RNA recognition, glucose-nucleobase pairs have been examined. Deoxyoligonucleotides with a 6-deoxyglucose insertion are able to hybridize with their complementary strand, thus exhibiting a preference for purine nucleobases. Although the resulting double helices are less stable than natural ones, they present only minor local distortions. 6-Deoxyglucose stays fully integrated in the double helix and its OH groups form two hydrogen bonds with the opposing guanine. This 6-deoxyglucose-guanine pair closely resembles a purine-pyrimidine geometry. Quantum chemical calculations indicate that glucose-purine pairs are as stable as a natural T-A pair.

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ER -

Glucose–Nucleobase Pseudo Base Pairs: Biomolecular Interactions within DNA

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