Boris Kushkuley scite author profile

The vibronic theory of activation and quantum chemical intermediate neglect of differential overlap (INDO) calculations are used to study the activation of carbon monoxide (change of the C-O bond index and force field constant) by the imidazole complex with heme in dependence on the distortion of the porphyrin ring, geometry of the CO coordination, iron-carbon and iron-imidazole distances, iron displacement out of the porphyrin plane, and presence of the charged groups in the heme environment. It is shown that the main contribution to the CO activation stems from the change in the sigma donation from the 5 sigma CO orbital to iron, and back-bonding from the iron to the 2 pi orbital of CO. It follows from the results that none of the studied distortions can explain, by itself, the wide variation of the C-O vibrational frequency in the experimentally studied model compounds and heme proteins. To study the dependence of the properties of the FeCO unit on the presence of charged groups in the heme environment, the latter are simulated by the homogeneous electric field and point charges of different magnitude and location. The results show that charged groups can strongly affect the strength of the C-O bond and its vibrational frequency. It is found that the charges located on the distal side of the heme plane can affect the Fe-C and C-O bond indexes (and, consequently, the Fe-C and C-O vibrational frequencies), both in the same and in opposite directions, depending on their position. The theoretical results allow us to understand the peculiarities of the effect of charged groups on the properties of the FeCO unit both in heme proteins and in their model compounds.

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Theoretical Study of the Electrostatic and Steric Effects on the Spectroscopic Characteristics of the Metal-Ligand Unit of Heme Proteins. 2. C-O Vibrational Frequencies, 17O Isotropic Chemical Shifts, and Nuclear Quadrupole Coupling Constants

Kushkuley

Stavrov

1997

Biophysical Journal

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The quantum chemical calculations, vibronic theory of activation, and London-Pople approach are used to study the dependence of the C-O vibrational frequency, 17O isotropic chemical shift, and nuclear quadrupole coupling constant on the distortion of the porphyrin ring and geometry of the CO coordination, changes in the iron-carbon and iron-imidazole distances, magnitude of the iron displacement out of the porphyrin plane, and presence of the charged groups in the heme environment. It is shown that only the electrostatic interactions can cause the variation of all these parameters experimentally observed in different heme proteins, and the heme distortions could modulate this variation. The correlations between the theoretically calculated parameters are shown to be close to the experimentally observed ones. The study of the effect of the electric field of the distal histidine shows that the presence of the four C-O vibrational bands in the infrared absorption spectra of the carbon monoxide complexes of different myoglobins and hemoglobins can be caused by the different orientations of the different tautomeric forms of the distal histidine. The dependence of the 17O isotropic chemical shift and nuclear quadrupole coupling constant on pH and the distal histidine substitution can be also explained from the same point of view.

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Infrared Spectroscopy of the Cyanide Complex of Iron(II) Myoglobin and Comparison with Complexes of Microperoxidase and Hemoglobin

Yonetani

Tsuneshige

et al. 1996

Biochemistry

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The cyanide complex of FeIIMb prepared and maintained at temperatures below 0 degrees C is sufficiently stable to permit spectroscopic characterization and allow comparison with free HCN and other ferric and ferrous CN complexes. The visible absorption spectrum of FeIIMb-CN has a split alpha band maxima at 571 and 563 nm, suggesting distortion in the x-y plane of the porphyrin. FeIIMb-CN, like the CO complex, was found to be optically active by circular dichroism. The C-N stretching frequencies for the CN-ferrous complexes are very sensitive to parameters within the heme pocket. The values are as follows: FEIIMb at pH 8, 2057 cm-1 with a shoulder appearing at 2078 cm-1 at pH 5.6; FeIIMp, 2034 cm-1. In contrast, the frequencies for C-N stretch differ little among ferric heme complexes, ranging from 2123 to 2125 cm-1 for myoglobin, hemoglobin, and microperoxidase. These values compare with free HCN (2094 cm-1) or CN- (2080 cm-1). Quantum chemical modeling of the neutral iron-porphyrin complex with imidazole and cyanide and of its anion was used to explain the effects of the cyanide coordination and of iron reduction on the C-N stretching frequencies. The lower nu C-N for FeIIMb-CN relative to the ferric complex is attributed to the appearance of additional electron density on all the anti-bonding CN orbitals. The extra electron density was also used to explain that the band width of C-N stretching mode was greater in the ferrous complexes than in the ferric complex. Finally, the calculation shows that sigma donation weakens the Fe-C bond, in qualitative agreement with the spontaneous dissociation of CN- from FeIIMb at -5 degrees C. The sensitivity of CN complexes of ferrous heme proteins to the heme pocket environment and the ability to correlate spectroscopic parameters with calculated electron density suggest that infrared spectroscopy of the CN ligand is an appropriate tool to study ferrous heme proteins.

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Theoretical study of the electrostatic and steric effects on the spectroscopic characteristics of the metal-ligand unit of heme proteins. 3. Vibrational properties of Fe(III)CN−

Kushkuley

Stavrov

1997

Biochimica et Biophysica Acta (BBA) - Protein Structure and Mol

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Boris Kushkuley

Theoretical study of the distal-side steric and electrostatic effects on the vibrational characteristics of the FeCO unit of the carbonylheme proteins and their models

Theoretical Study of the Electrostatic and Steric Effects on the Spectroscopic Characteristics of the Metal-Ligand Unit of Heme Proteins. 2. C-O Vibrational Frequencies, 17O Isotropic Chemical Shifts, and Nuclear Quadrupole Coupling Constants

Infrared Spectroscopy of the Cyanide Complex of Iron(II) Myoglobin and Comparison with Complexes of Microperoxidase and Hemoglobin

Theoretical study of the electrostatic and steric effects on the spectroscopic characteristics of the metal-ligand unit of heme proteins. 3. Vibrational properties of Fe(III)CN−

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