1993) However, the mutations may also cause local

1993). However, the mutations may also cause local effects like spin redistributions within the BChl macrocycles or change the geometry of the BChl macrocycles. Since the hfcs

of the β-protons at positions 7, 8, 17, and 18 (Fig. 1c) are strongly dependent on learn more the geometry of the respective hydrated rings (Rautter et al. 1995), the EPR linewidth may be changed even without a spin redistribution between the two halves of the dimer. More definitive conclusions can, therefore, only be drawn if the resolution is increased significantly, e.g., by double and triple resonance experiments, yielding the individual nuclear hyperfine coupling constants. X-band CW 1H Special TRIPLE measurements P•+ in Wild-Type RCs Figure 3 compares the Special TRIPLE spectra Idasanutlin molecular weight of WT 2.4.1 (bacteria grown photosynthetically) and WT-H7 (hepta-histidine tag, grown non-photosynthetically) at pH 8.0. The WT 2.4.1 spectrum is identical to that observed before (Geßner et al. 1992; Artz et al. 1997; Müh et al. 2002). The assignment of lines and hfcs (Table 1) follows that of our earlier work (Geßner et al. 1992; Lendzian et al. 1993). Most pronounced are the resonances of the protons of the four (freely rotating) methyl groups (positive hfcs)1 and the two β-protons (L-side, positive hfcs). As an indicator for the spin density distribution in the BChl macrocycle, the hfcs of the β-protons at the positions 7, 8, 17, and 18 are less suited,

since they are sensitive to the dihedral angle of the respective rings that can easily change (Käss et al. 1994; Rautter et al. 1995). The two spectra show some very small but distinct differences of the proton

hfcs. Based upon previous studies, the shifts are unlikely to arise from a difference in the carotenoid composition, due to incorporation of spheroidene and spheroidenone in cultures grown under anaerobic and aerobic conditions, respectively, or differences in the preparations (Geßner et al. 1992; Rautter et al. 1994). The ENDOR/TRIPLE spectrum is sensitive to electrostatic interactions as indicated by the large changes observed upon introduction of hydrogen bonds or use of zwitterionic detergents (Rautter et al. 1995; Müh PRKACG et al. 1998; 2002). Thus, the most likely cause for the small spectral shift is addition of electrostatic interactions due to the presence of the hepta-histidine tag at the carboxyl terminus region of the M-subunit. For the discussion concerning the mutants, since the changes are very small, the two wild-type samples can be considered to be basically equivalent. Fig. 3 1H-Special TRIPLE spectra (X-band) of light-induced P•+ from RCs from Rb. sphaeroides wild type 2.4.1 (WT 2.4.1) (black line) and from wild type with hepta-histidine tag (WT-H7) (red line) at pH 8.0. The isotropic hyperfine Sapanisertib purchase couplings a iso are directly obtained from the Special TRIPLE frequency by ν ST = a iso/2 (for details see Lendzian et al. 1993).

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