Relationships between 31P Chemical Shift Tensors and Conformation of Nucleic Acid Backbobe: A DFT Study

PRECECHTELOVA, Jana, Markéta MUNZAROVÁ, Petr NOVÁK and Vladimír SKLENÁŘ. Relationships between 31P Chemical Shift Tensors and Conformation of Nucleic Acid Backbobe: A DFT Study. Journal of Physical Chemistry B. American Chemical Society, 2007, vol. 111, No 12, p. 2658-2667. ISSN 1520-6106.

Basic information

• Original name: Relationships between 31P Chemical Shift Tensors and Conformation of Nucleic Acid Backbobe: A DFT Study
• Name in Czech: Vztahy mezi tenzory 31P chemickeho posunu a konformaci patere nukleovych kyselin: DFT studie
• Authors: PRECECHTELOVA, Jana (203 Czech Republic), Markéta MUNZAROVÁ (203 Czech Republic), Petr NOVÁK (203 Czech Republic) and Vladimír SKLENÁŘ (203 Czech Republic, guarantor).
• Edition: Journal of Physical Chemistry B, American Chemical Society, 2007, 1520-6106.

Other information

• Original language: English
• Type of outcome: Article in a journal
• Field of Study: 10403 Physical chemistry
• Country of publisher: Czech Republic
• Confidentiality degree: is not subject to a state or trade secret
• Impact factor: Impact factor: 4.086
• RIV identification code: RIV/00216224:14310/07:00021992
• Organization unit: Faculty of Science
• UT WoS: 000244735300033
• Keywords in English: NMR chemical shift tensor 31P nucleic acids
• Tags: International impact, Reviewed

Abstract

Density functional theory (DFT) has been applied to study the conformational dependence of 31P chemical shift tensors in B-DNA. The gg and gt conformations of backbone phosphate groups representing BI- and BII-DNA have been examined. Calculations have been carried out on static models of dimethyl phosphate (dmp) and dinucleoside-3',5'-monophosphate with bases replaced by hydrogen atoms in vacuo as well as in an explicit solvent. Trends in 31P chemical shift anisotropy (CSA) tensors with respect to the backbone torsion angles alpha, zeta, beta, and epsilon are presented. Although these trends do not change qualitatively upon solvation, quantitative changes result in the reduction of the chemical shift anisotropy. For and in the range from 270 deg to 330 deg and from 240 deg to 300 deg, respectively, the delta22 and delta33 principal components vary within as much as 30 ppm, showing a marked dependence on backbone conformation. The calculated 31P chemical shift tensor principal axes deviate from the axes of O-P-O bond angles by at most 5 deg. For solvent models, our results are in a good agreement with experimental estimates of relative gg and gt isotropic chemical shifts. Solvation also brings the theoretical iso of the gg conformation closer to the experimental gg data of barium diethyl phosphate.

Abstract (in Czech)

Density functional theory (DFT) has been applied to study the conformational dependence of 31P chemical shift tensors in B-DNA. The gg and gt conformations of backbone phosphate groups representing BI- and BII-DNA have been examined. Calculations have been carried out on static models of dimethyl phosphate (dmp) and dinucleoside-3',5'-monophosphate with bases replaced by hydrogen atoms in vacuo as well as in an explicit solvent. Trends in 31P chemical shift anisotropy (CSA) tensors with respect to the backbone torsion angles alpha, zeta, beta, and epsilon are presented. Although these trends do not change qualitatively upon solvation, quantitative changes result in the reduction of the chemical shift anisotropy. For and in the range from 270 deg to 330 deg and from 240 deg to 300 deg, respectively, the delta22 and delta33 principal components vary within as much as 30 ppm, showing a marked dependence on backbone conformation. The calculated 31P chemical shift tensor principal axes deviate from the axes of O-P-O bond angles by at most 5 deg. For solvent models, our results are in a good agreement with experimental estimates of relative gg and gt isotropic chemical shifts. Solvation also brings the theoretical iso of the gg conformation closer to the experimental gg data of barium diethyl phosphate.

Links

• LC06030, research and development project: Name: Biomolekulární centrum

Investor: Ministry of Education, Youth and Sports of the CR, Biomolecular centre

• MSM0021622413, plan (intention): Name: Proteiny v metabolismu a při interakci organismů s prostředím

Investor: Ministry of Education, Youth and Sports of the CR, Proteins in metabolism and interaction of organisms with the environment