0) or exchanged by repetitive concentration/dilution using 30 kDa Centricon or Microcon filters into 2-(N-morpholino)ethanesulfonic acid (MES) pH 6.5 or (2-[N-cyclohexylamino]ethane sulfonic acid (CHES) pH 9.5. Finally, the samples were concentrated to an OD802 of 80–130. CW X-band EPR measurements were performed with a Bruker ESP 300 spectrometer at room temperature using a rectangular cavity
with optical access (TE102, ER 4102ST, Bruker), using a capillary with 1 mm inner diameter. The radical cation P•+ was created via continuous illumination with white light in situ, using heat-absorbing glass and water filters. CW X-band Special TRIPLE measurements were done on the same spectrometer at 288 K. A home-built ENDOR cavity was used, similar to the one previously described (Zweygart et al. 1994),
but with a nitrogen gas cooling system. The cation radical P•+ was created in situ as described above. The data analysis was performed selleck compound using home-written routines in Matlab™, similar to the program used before (Tränkle and Lendzian 1989). In several cases, a baseline was recorded under identical conditions (with the magnetic field off-resonant and subtracted) under the assumption that possible drifts and artifacts would be the same in both cases. Q-band EPR and ENDOR measurements in frozen solution were done on a Bruker Elexsys E580 spectrometer at 80 K. For frozen solution experiments, sucrose (60%) was added to all samples. A home-built resonator was used (Silakov et al. 2007), similar to the one described previously SBI-0206965 order (Sienkiewicz et al. 1996). A Davies-type pulse ENDOR experiment (Davies 1974) was performed as described previously (Epel et al. 2006). Results X-band EPR measurements Measurements using the X-band EPR spectrometer were performed for both wild-type RCs and the four mutants, ND(L170), HE(L168), ND(M199), and HE(L168)/ND(L170), in liquid solution. In all cases, the spectrum was a single unresolved line centered at g
close to g e (see Fig. 2 for an example). Fig. 2 Comparison of CW X-band EPR spectra of light-induced P•+ in RCs from Rb. sphaeroides wild type with hepta-histidine tag (WT-H7) (red line) and from ND(L170) (blue line) at pH 8.0 For wild-type RCs at pH 8.0, the spectrum was simulated using a Gaussian before function with a linewidth ΔB pp (peak-to-peak) of 9.6 G (±0.2 G) at g = 2.0026 in agreement with published data of this radical in RCs from Rb. sphaeroides 2.4.1 (see for example Feher et al. 1975; Norris et al. 1971; Artz et al. 1997). The spectrum of the four mutant RCs at pH 8.0 were fitted yielding the same selleck chemicals llc g-value and different Gaussian linewidths. For all of the mutants, the EPR linewidth was increased relative to wild type. The linewidth is smallest for the ND(M199) mutant (10.1 G), followed by the HE(L168) mutant (10.2 G), with the ND(L170) mutant and the double mutant HE(L168)/ND(L170) having the most pronounced increase (11.0 G).