K. Möbius

A novel high-field/high-frequency EPR and ENDOR spectrometer operating at 3 mm wavelength

A high-field/high-frequency EPR and ENDOR system operating at 3 mm wavelength is described. The probe-head designs of two different resonator types, i.e. an open Fabry-Perot resonator and a cylindrical TE011 cavity, are presented in detail. The advantages and limitations of high-field/high-frequency EPR and ENDOR spectroscopy are demonstrated for selected examples. The performance data of the spectrometer suggest that it will be very useful for broad applications in physics, chemistry and biology.

High-field EPR studies of the structure and conformational changes of site-directed spin labeled bacteriorhodopsin

Cw and pulsed high-field EPR (95 GHz, 3.4 T) are performed on site-directed spin labeled bacteriorhodopsin (BR) mutants. The enhanced Zeeman splitting leads to spectra with resolved g-tensor components of the nitroxide spin label. The g(xx) component shift determined for 10 spin labels located in the cytoplasmic loop region and in the protein interior along the BR proton channel reveals a maximum close to position 46 between the proton donor D96 and the retinal. A plot of g(xx) versus A(zz) of the nitrogen discloses grouping of 12 spin labeled sites in protic and aprotic sites. Spin labels at positions 46, 167 and 171 show the aprotic character of the cytoplasmic moiety of the proton channel whereas nitroxides at positions 53, 194 and 129 reveal the protic environment in the extracellular channel. The enhanced sensitivity of high-field EPR with respect to anisotropic reorientational motion of nitroxides allows the characterization of different motional modes for spin labels bound to positions 167 and 170. The motional restriction of the nitroxide at position 167 of the double mutant V167C/D96N is decreased in the M(N) photo-intermediate. An outward shift of the cytoplasmic moiety of helix F in the M(N) intermediate would account for the high-field EPR results and is in agreement with diffraction and recent X-band EPR data.

The electronic structure of the primary donor cation radical in Rhodobacter sphaeroides R-26: ENDOR and TRIPLE resonance studies in single crystals of reaction centers

Abstract The electron spin density distribution of the cation radical of the primary donor, D+, a bacteriochlorophyll a dimer was determined by ENDOR and TRIPLE resonance experiments performed on single crystals of reaction centers (RCs) of Rhodobacter sphaeroides R-26. Nine isotropic proton hyperfine coupling constants (hfcs) were obtained and from the angular dependence of the hfcs in three crystallographic planes, five complete hyperfine (hf) tensors were determined. Theoretical hf tensors were calculated by the all-valence-electron SCF molecular orbital method RHF-INDO/SP using the X-ray structure data of the dimer D and its amino acid environment. A comparison of the directions of the principal axes of the experimental and calculated hf tensors enabled us to identify the hfcs with specific protons on the two bacteriochlorophyll halves DL and DM of the dimer. The result shows that the unpaired valence electron is unequally distributed over the dimer halves, favoring DL by approx. 2:1. This ratio has been obtained from the proton hfcs of rotating methyl groups, which directly reflect the π-spin densities at the corresponding positions in the two macrocycles, DL and DM. It was further confirmed by recent 15N-ENDOR experiments on RC single crystals (Lendzian, F., Bonigk, B., Plato, M., Mobius, K. and Lubitz, W. (1992) in The Photosynthetic Bacterial Reaction Center II (Breton, J. and Vermeglio, A., eds.), pp. 89–97, Plenum Press, New York). The observed asymmetry of D+ is attributed to the difference in energies of the highest filled molecular π-orbitals of the monomeric halves, DL and DM, which is caused by differences in the structure of the two bacteriochlorophylls and/or their environment. Possible implications of this asymmetry for the electron transfer in the RC are discussed.

General TRIPLE resonance on free radicals in solution. Determination of relative signs of isotropic hyperfine coupling constants

For the first time a general type of electron–nuclear–nuclear TRIPLE resonance has been performed on radicals in liquid solution. In this method two inequivalent nuclei are irradiated simultaneously at their respective NMR frequencies, the resonance being detected by an enhancement of a saturated ESR line. This general TRIPLE experiment, the analog of which is known already in the solid state (DOUBLE ENDOR), gives direct information about relative signs of hyperfine coupling constants. Several important aspects of the experimental setup are described. The experimental results are discussed on the basis of a simple relaxation model.

Molecular orbital study of polarity and hydrogen bonding effects on the g and hyperfine tensors of site directed NO spin labelled bacteriorhodopsin

Semiempirical molecular orbital methods (PM3, INDO, ZINDO/S) have been used to calculate the effects of local electric fields and of hydrogen bonding on the g and hyperfine tensors of a nitroxide spin label model system. The results yield a linear correlation between the two principal tensor components g xx and A N zz at label sites of varying polarity. Hydrogen bonding with a single water molecule produces a constant shift of Δg xx ≅ −4 × 10−4. These theoretical results are used to interpret recent high field (3.4 T, 95 GHz) electron paramagnetic resonance investigations on site-directed spin labelled bacteriorhodopsin. This protein reveals a close correlation between proticity and polarity at the various label sites. The slope of the g xx versus A N zz dependence is affected strongly by polarity induced structural strains of the spin label.

Time-resolved W-band (95 GHz) EPR spectroscopy of Zn-substituted reaction centers of Rhodobacter sphaeroides R-26

Abstract Transient EPR spectra of protonated and deuterated Zn-substituted reaction centres of Rhodobacter sphaeroides R-26, measured at a microwave frequency of 95 GHz and an external magnetic field of 3.5 T, are presented. The high-field/high-frequency spin-polarized spectrum of the correlated coupled radical pair P 865 +. Q A −. after laser flash excitation is a very sensitive monitor of the relative orientation of the two g -matrices and the dipolar tensor with respect to each other. Therefore, detailed structural information of the RC concerning the relative orientation of the primary donor P 865 +. and the acceptor Q A −. with respect to the axis connecting the two molecules in the RC can be derived. Together with the information obtained by high-field cw-EPR on single crystals, the enhanced resolution of the polarized high-field spectra allows an unambiguous assignment of the g -matrix of the donor P 865 +. to the molecular axis system. The experimental results are compared with earlier X-band (9 GHz) and K-band (24 GHz) EPR experiments.

Pulsed 95 GHz high-field EPR heterodyne spectrometer with high spectral and time resolution

Various time resolved EPR methods are applied to different test samples to demonstrate the abilities of pulsed high-field EPR spectroscopy. Two-pulse-echo field swept EPR spectroscopy on a nitroxide radical shows the increased spectral resolution by separating different spin systems by their relaxation properties. Additionally N14 electron-spin-echo-envelope-modulation (ESEEM) is observed for these systems at fields as high as 3.5 T. Thus, the N14 hyperfine interaction couplings can be probed by ESEEM and pulsed ENDOR (electron-nuclear-double-resonance) experiments. The sensitivity of pulsed ENDOR experiments is compared with cw-ENDOR. The different linewidths and amplitudes of the two methods are discussed. Transient nutation experiments on light induced triplet states demonstrate the high sensitivity and time resolution of high-field pulsed EPR. The sensitivity and time resolution of our 95 GHz spectrometer are determined and compared with pulsed X-band EPR spectrometer performances.

Electron nuclear triple resonance of free radicals in solution

Electron nuclear triple resonance (TRIPLE) experiments on free radicals in solution not only give considerable signal‐to‐noise improvement as compared to ENDOR, but also decrease the observed linewidth and give additional information about the number of protons contributing to a particular hfs constant. The experimental setup is described and the results are discussed in terms of a phenomenological theory.

Molecular orbital investigation of dimer formations of bacteriochlorophyll a. Model configurations for the primary donor of photosynthesis

Abstract Three stable dimer configurations of bacteriochlorophyll a are predicted by a self-consistent-field molecular orbital calculation (all valence electrons, restricted Hartree-Fock, INDO-parametrization, perturbational treatment of spin polarization) including geometry optimization by energy minimization. Spin-density distributions of the cation radicals are also calculated and compared with results from magnetic resonance experiments. The largest binding energy is obtained from a strong overlap of the π-systems combined with the formation of two symmetrical MgO bonds between the monomeric components. This structure is compatible with the experimental spin density distribution and very similar to the recently determined X-ray structure of the bacteriochlorophyll b dimer in the photosynthetic reaction center of Rps. viridis. Some possible perturbations by the protein environment are discussed.

Photoactivation of the flavin cofactor in Xenopus laevis (6-4) photolyase: Observation of a transient tyrosyl radical by time-resolved electron paramagnetic resonance

The light-induced electron transfer reaction of flavin cofactor photoactivation in Xenopus laevis (6–4) photolyase has been studied by continuous-wave and time-resolved electron paramagnetic resonance spectroscopy. When the photoactivation is initiated from the fully oxidized form of the flavin, a neutral flavin radical is observed as a long-lived paramagnetic intermediate of two consecutive single-electron reductions under participation of redox-active amino acid residues. By time-resolved electron paramagnetic resonance, a spin-polarized transient radical-pair signal was detected that shows remarkable differences to the signals observed in the related cyclobutane pyrimidine dimer photolyase enzyme. In (6–4) photolyase, a neutral tyrosine radical has been identified as the final electron donor, on the basis of the characteristic line width, hyperfine splitting pattern, and resonance magnetic field position of the tyrosine resonances of the transient radical pair.