Pulsed ENDOR at 95 GHz on the primary acceptor ubisemiquinone QA-• in photosynthetic bacterial reaction centers and related model systems

Davies-type pulsed H-1 electron nuclear double resonance (ENDOR) measurements were performed at a magnetic field of 3.4 T and a microwave (MW) frequency of 95 GHz (W-band). By taking advantage of the increased electron Zeeman interaction at high field, the small g-anisotropy of the semiquinone anion radicals could be resolved in frozen solutions. Hence, the W-band ENDOR spectra could be taken at the well-separated canonical peaks of the powder electron paramagnetic resonance (EPR) spectra, thereby becoming highly orientation-selective with respect to the relative orientation of the radicals to the external magnetic field. The measurements were performed on various randomly oriented semiquinone anion radicals in frozen alcoholic solution and on the primary ubiquinone anion radical, Q(A)(radical anion), in frozen photosynthetic bacterial reaction centers (RCs) of Rhodobacter sphaeroides in which the Fe was replaced by Zn (ZnRC). A simulation program was used to obtain magnitudes and orientations of the hyperfine tensors. The W-band ENDOR spectra of the immobilized radicals show not only hyperfine couplings (HFC) of local protons of the semiquinones, but also those of protons from the environment. These are, for example, involved in hydrogen bonds between the amino acid surrounding and the quinone carbonyl groups. For Q(A)(radical anion) in ZnRCs, a particularly large H-bond HFC was obtained from which direction and distance of the H-bond could be estimated. These data were compared with those measured for the respective ubisemiquinone radical, UQ-10(radical anion), in protonated and deuterated 2-propanol, where two H-bonds of comparable strength but different directions could be detected. Comparison of H-1 ENDOR spectra of the 2,3,5,6-tetra-methyl-1,4-benzoquinone anion radical in frozen solution, performed both at W-band and at X-band frequency, demonstrated the limitations of achieving orientation selected ENDOR spectra from X-band experiments on systems with small g-anisotropy.