Your search keyword '"SYNCHROTRON-RADIATION"' showing total 4 results

1. Fe vibrational Spectroscopy of myoglobin and cytochrome f

Author

Adams, K. L., Tsoi, S., Yan, J. S., Durbin, S. M., Ramdas, A. K., Cramer, W. A., Sturhahn, W., Alp, E. E., and Schulz, C.

Subjects

nuclear resonant scattering, density-of-states, iron normal-modes, oxygenic photosynthesis, b(6)f complex, structural fluctuations, synchrotron-radiation, raman-spectroscopy, heme-proteins, complete set

Abstract

The Fe vibrational density of states (VDOS) has been determined for the heme proteins deoxymyoglobin, metmyoglobin, and cytochrome f in the oxidized and reduced states, using nuclear resonance vibrational spectroscopy (NRVS). For cytochrome f in particular, the NRVS spectrum is compared with multiwavelength resonance Raman spectra to identify those Raman modes with significant Fe displacement. Modes not seen by Raman due to optical selection rules appear in the NRVS spectrum. The mean Fe force constant extracted from the VDOS illustrates how Fe dynamics varies among these four monoheme proteins, and is correlated with oxidation and spin state trends seen in model heme compounds. The protein's contribution to Fe motion is dominant at low frequencies, where coupling to the backbone tightly constrains Fe displacements in cytochrome f, in contrast to enhanced heme flexibility in myoglobin.

Published

2006

2. Vibrational spectroscopy and normal-mode analysis of Fe(II) octaethylporphyrin

Author

Starovoitova, V., Budarz, T. E., Wyllie, G. R. A., Scheidt, W. R., Sturhahn, W., Alp, E. E., Prohofsky, E. W., and Durbin, S. M.

Subjects

nuclear resonant scattering, porphyrin force-field, lying spin states, iron normal-modes, x-ray-scattering, raman-spectra, structural fluctuations, synchrotron-radiation, infrared-spectra, nickel porphine

Abstract

The normal-mode spectrum for the four-coordinated heme compound Fe(II) octaethylporphyrin, Fe(OEP), has been determined by refining force constants to the experimental Fe vibrational density of states measured with nuclear resonance vibrational spectroscopy (NRVS). Convergence of the calculated spectrum to the data was achieved by first imposing D-4 symmetry on the model structure as well as the force constants, progressively including different internal coordinates of motion, then allowing the true C-i (or S-2) point group symmetry of the C-i(1) Fe(OEP) crystal structure. The NRVS-refined normal modes are in good agreement with Raman and IR spectra at high frequencies. Prior density functional theory predictions for a model porphyrin are similar to the core modes computed with the best-fit force field, but significant differences between D-4 and C-i modes underline the sensitivity of porphyrin Fe normal modes to structural details. Some differences between the C-i best fit and the NRVS data can be attributed to intermolecular contacts not included in the normal-mode analysis.

Published

2006

3. Determination of the complete set of iron normal modes in the heme model compound Fe-III(OEP)C1 from nuclear resonance vibrational spectroscopic data

Author

Budarz, T. E., Prohofsky, E. W., Durbin, S. M., Sjodin, T., Sage, J. T., Sturhahn, W., and Alp, E. E.

Subjects

porphyrin force-field, lying spin states, nickel octaethylporphyrin, synchrotron-radiation, infrared-spectra, isotope shifts, raman-spectra, scattering, myoglobin, dynamics

Abstract

The vibrational spectrum of Fe-57 in chloro iron octaethylporphyrin, Fe(OEP)Cl, has been calculated by normal-mode analysis refined to absorption data from nuclear resonance vibrational spectroscopy. This technique directly measures the amplitudes and frequencies for all modes that have significant iron participation, providing rigorous constraints to the best-fit values for the force constants. The calculated normal modes reveal the importance of Fe displacements perpendicular to the heme plane for both the lowest frequency modes and the ligand modes. The actual normal modes of Fe(OEP)Cl are not well described by single modes of the core porphyrin; instead they are hybrids of multiple core modes and ethyl and chlorine displacements.

Published

2003

4. Direct determination of the complete set of iron normal modes in a porphyrin-imidazole model for carbonmonoxy-heme proteins: [Fe(TPP)(CO)(1-Melm)]

Author

Rai, B. K., Durbin, S. M., Prohofsky, E. W., Sage, J. T., Ellison, M. K., Roth, A., Scheidt, W. R., Sturhahn, W., and Alp, E. E.

Subjects

nuclear resonant scattering, density-functional theory, spin cobalt porphyrins, force-field, molecular stereochemistry, synchrotron-radiation, vibrational-spectra, raman intensities, infrared-spectra, nickel porphine

Abstract

Detailed Fe vibrational spectra have been obtained for the heme model complex [Fe(TPP)(CO)-(1-Melm)] using a new, highly selective and quantitative technique, Nuclear Resonance Vibrational Spectroscopy (NRVS). This spectroscopy measures the complete vibrational density of states for iron atoms, from which normal modes can be calculated via refinement of the force constants. These data and mode assignments can reveal previously undetected vibrations and are useful for validating predictions based on optical spectroscopies and density functional theory, for example. Vibrational modes of the iron porphyrin-imidazole compound [Fe(TPP)(CO)(1-Melm)] have been determined by refining normal mode calculations to NRVS data obtained at an X-ray synchrotron source. Iron dynamics of this compound, which serves as a useful model for the active site in the six-coordinate heme protein, carbonmonoxy-myoglobin, are discussed in relation to recently determined dynamics of a five-coordinate deoxy-myoglobin model, [Fe(TPP)(2-MeHIm)]. For the first time in a six-coordinate heme system, the iron-imidazole stretch mode has been observed, at 226 cm(-1). The heme in-plane modes with large contributions from the nu(42), nu(49), nu(50), and nu(53) modes of the core porphyrin are identified. In general, the iron modes can be attributed to coupling with the porphyrin core, the CO ligand, the imidazole ring, and/or the phenyl rings. Other significant findings are the observation that the porphyrin ring peripheral substituents are strongly coupled to the iron doming mode and that the Fe-C-O tilting and bending modes are related by a negative interaction force constant.

Published

2003