Mössbauer Quadrupole Splittings and Electronic Structure in Heme Proteins and Model Systems:  A Density Functional Theory Investigation

Mössbauer Quadrupole Splittings and Electronic Structure in Heme Proteins and Model Systems:  A Density Functional Theory Investigation

We report the results of a series of density functional theory (DFT) calculations aimed at predicting the 57Fe Mössbauer electric field gradient (EFG) tensors (quadrupole splittings and asymmetry parameters) and their orientations in S = 0, 1/2, 1, 3/2, 2, and 5/2 metalloproteins and/or model system...

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Bibliographic Details
Published in:Journal of the American Chemical Society Vol. 124; no. 46; pp. 13921 - 13930
Main Authors: Zhang, Yong, Mao, Junhong, Godbout, Nathalie, Oldfield, Eric
Format: Journal Article
Language:English
Published: Washington, DC American Chemical Society 20-11-2002
Subjects:
Analytical, structural and metabolic biochemistry
Biological and medical sciences
Fundamental and applied biological sciences. Psychology
General aspects, investigation methods
Hemeproteins - chemistry
Iron Isotopes - chemistry
Models, Chemical
Models, Molecular
Proteins
Spectroscopy, Mossbauer - methods
Chemistry
Electronic structure
Biochemical analysis
Chemical analysis
Density functional
Heme
Quadrupolar splitting
Method
Protein
Moessbauer parameter
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Summary:We report the results of a series of density functional theory (DFT) calculations aimed at predicting the 57Fe Mössbauer electric field gradient (EFG) tensors (quadrupole splittings and asymmetry parameters) and their orientations in S = 0, 1/2, 1, 3/2, 2, and 5/2 metalloproteins and/or model systems. Excellent results were found by using a Wachter's all electron basis set for iron, 6-311G* for other heavy atoms, and 6-31G* for hydrogen atoms, BPW91 and B3LYP exchange-correlation functionals, and spin-unrestricted methods for the paramagnetic systems. For the theory versus experiment correlation, we found R 2 = 0.975, slope = 0.99, intercept = −0.08 mm sec-1, rmsd = 0.30 mm sec-1 (N = 23 points) covering a ΔE Q range of 5.63 mm s-1 when using the BPW91 functional and R 2 = 0.978, slope = 1.12, intercept = −0.26 mm sec-1, rmsd = 0.31 mm sec-1 when using the B3LYP functional. ΔE Q values in the following systems were successfully predicted:  (1) ferric low-spin (S = 1/2) systems, including one iron porphyrin with the usual (d xy )2(d xz d yz )3 electronic configuration and two iron porphyrins with the more unusual (d xz d yz )4(d xy )1 electronic configuration; (2) ferrous NO-heme model compounds (S = 1/2); (3) ferrous intermediate spin (S = 1) tetraphenylporphinato iron(II); (4) a ferric intermediate spin (S = 3/2) iron porphyrin; (5) ferrous high-spin (S = 2) deoxymyoglobin and deoxyhemoglobin; and (6) ferric high spin (S = 5/2) metmyoglobin plus two five-coordinate and one six-coordinate iron porphyrins. In addition, seven diamagnetic (S = 0, d6 and d8) systems studied previously were reinvestigated using the same functionals and basis set scheme as used for the paramagnetic systems. All computed asymmetry parameters were found to be in good agreement with the available experimental data as were the electric field gradient tensor orientations. In addition, we investigated the electronic structures of several systems, including the (d xy )2(d xz ,d yz )3 and (d xz ,d yz )4(d xy )1 [Fe(III)/porphyrinate]+ cations as well as the NO adduct of Fe(II)(octaethylporphinate), where interesting information on the spin density distributions can be readily obtained from the computed wave functions.
Bibliography:ark:/67375/TPS-JVNZR86Z-L
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ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0002-7863
1520-5126
DOI:10.1021/ja020298o