On the spatial organization of hemes and chlorophyll in cytochrome b(6)f. A linear and circular dichroism study.

The organization of chromophores in the cytochrome b(6) f from Chlamydomonas reinhardtii has been studied spectroscopically. Linear dichroism (LD) measurements, performed on the complex co-reconstituted into vesicles with photosynthetic reaction centers as an internal standard, allow the determination of the orientations of the chromophore with respect to the membrane plane. The orientations of the b(H)- and b(L)-hemes are comparable to those determined crystallographically on the cytochrome bc(1). The excitonic CD signal, resulting from the interaction between b-hemes, is similar to that reported for the cytochrome bc(1). LD and CD data are consistent with the differences between the b(6) f and bc(1) leaving the orientation of the b-hemes unaffected. By contrast, the LD data yield a different orientation for the heme f as compared either to the heme c(1) in the crystallographic structures or to the heme f as studied by electron paramagnetic resonance. This difference could either result from incorrect assumptions regarding the orientations of the electronic transitions of the f-heme or may point to the possibility of a redox-dependent movement of cytochrome f. The chlorophyll a was observed in a well defined orientation, further corroborating a specific binding site for it in the b(6) f complex.

Relative orientation of the hemes of the cytochrome bc(1) complexes from Rhodobacter sphaeroides, Rhodospirillum rubrum, and beef heart mitochondria. A linear dichroism study.

The orientation of the chromophores in the cytochrome bc(1) of Rhodospirillum rubrum, Rhodobacter sphaeroides, and beef heart mitochondria is reported. The combination of redox-resolved absorption spectrophotometry and linear dichroism experiments at low temperature allows the determination of the orientation of the three hemes with respect to the membrane plane. The orientations of the b(H)-and b(L)-hemes of the R. sphaeroides and beef heart mitochondrial complexes are similar to those determined by crystallographic studies of the mitochondrial cytochrome bc(1). On the other hand the orientations of the b-hemes of the R. rubrum complex lead to the conclusion that the b(H)-heme is more perpendicular to the membrane plane than the b(L)-heme. This could be explained by a specific organization of the b-hemes due to subunit composition of the complex or, alternatively, to a different spatial position of the heme transitions with respect to the porphyrin macrocycle compared with the other complexes. Moreover, our results demonstrate a different orientation of the heme c(1) of the three studied complexes in comparison to crystallographic studies. This difference may arise from the above hypothesis on the transitions of the heme or from flexibility of this subunit in function of its redox state.

The Qo-site inhibitor DBMIB favours the proximal position of the chloroplast Rieske protein and induces a pK-shift of the redox-linked proton.

The interaction of the inhibitor 2,5-dibromo-3-methyl-6-isopropylbenzoquinone (DBMIB) with the Rieske protein of the chloroplast b6f complex has been studied by EPR. All three redox states of DBMIB were found to interact with the iron-sulphur cluster. The presence of the oxidised form of DBMIB altered the equilibrium distribution of the Rieske protein's conformational substates, strongly favouring the proximal position close to heme bL. In addition to this conformational effect, DBMIB shifted the pK-value of the redox-linked proton involved in the iron-sulphur cluster's redox transition by about 1.5 pH units towards more acidic values. The implications of these results with respect to the interaction of the native quinone substrate and the Rieske cluster in cytochrome bc complexes are discussed.

Distinct structures and environments for the three hemes of the cytochrome bc1 complex from Rhodospirillum rubrum. A resonance Raman study using B-band excitations.

The B-band excited resonance Raman (RR) spectra (100-1700 cm-1) of the bacterial cytochrome bc1 complex purified from Rhodospirillum rubrum are reported. Four redox states, i.e., the persulfate-oxidized, "as prepared", and ascorbate- and dithionite-reduced states of the complex, were investigated with the laser excitations at 406.7, 413.1, and 441.6 nm. Following the different absorption properties of the b- and c-type hemes and the different resonance enhancements of the vibrational modes of oxidized and reduced hemes, RR contributions from the b- and c-type hemes were characterized. For the nu2, nu10, and nu8 porphyrin vibrational modes, individual contributions of hemes c1, bH, and bL were determined. The data show that the macrocycle conformation of the three hemes of the cytochrome bc1 complex is different. In particular, the frequencies assigned to ferrous heme bL (1580, 1610, and 352 cm-1, respectively) reveal that its porphyrin is more strongly distorted than that of ferrous heme bH (1584, 1614, and 344 cm-1, respectively). The frequencies of the nu11 modes (1543, 1536, and 1526 cm-1 for ferrous heme c1, heme bH, and heme bL, respectively) confirm that the axial histidylimidazole ligands of heme bL have a marked anionic character. Strong differences in the peripheral interactions of the three hemes with the proteins were also detected through the frequency differences of the nu5, nu13, nu14, and nu42 modes. Considering that hemes bH and bL are inserted into a four-helice bundle, the RR data are interpreted in the frame of a strong protein constraint on heme bL.

Characterization of the reaction center bound tetraheme cytochrome of Rhodocyclus tenuis.

Properties of the tetrahemic reaction center bound cytochrome have been investigated by different techniques. The mid-point potentials of the four hemes were determined by redox titration. The best fit of the data was obtained with a (n = 1) Nernst curve by using the following values of the redox parameters: Em = +420 mV for the two high-potential hemes and Em = +110 and +60 mV for the two low-potential hemes. The mid-point potentials of the two high-potential hemes are the highest reported so far. The spectral properties of the four hemes in the alpha-band have been determined by absorption spectroscopy and measurements of light-induced difference spectra in membranes of Rhodocyclus tenuis. The two high potential hemes present very similar spectra centered at 557 nm. The absorption spectra of the two low-potential hemes are very similar, and their alpha-band centered around 551 nm. Spectral properties at 100 K and the linear dichroism of optical transitions allow the determination of the relative orientations of the hemes with respect to the membrane plane. The orientation patterns thus obtained corresponds to none of the arrangements described so far for reaction center bound cytochromes.

Photoinduced cyclic electron transfer in Rhodocyclus tenuis cells: participation of HiPIP or cyt c8 depending on the ambient redox potential.

We demonstrate the participation of a cytochrome c8 and a high-potential iron-sulfur protein (HiPIP) in the photoinduced electron transfer in whole cells of Rhodocyclus tenuis depending on the redox state or background continuous illumination. At high redox potentials (above 350 mV) or under a strong background illumination (5 W m-2), the cytochrome c8 acts as the physiological electron donor to the photo-oxidized high-potential hemes of the tetraheme cytochrome bound to the reaction center. For redox potentials ranging from 200 to 310 mV or under weak background illumination (1. 25 W m-2), the electron carrier is the HiPIP. The electron transfer between cyt c8 and HiPIP and the tetraheme cytochrome has half-times of 300 and 480 micros, respectively. A slow electrogenic phase of the membrane potential is linked to their rereduction. This phase is sensitive to a specific inhibitor of the cyt bc1 complex, indicating involvement of cyt c8 and HiPIP in the photoinduced cyclic electron transfer at these two redox conditions.

Cyclic electron transfer in Heliobacillus mobilis involving a menaquinol-oxidizing cytochrome bc complex and an RCI-type reaction center.

Flash-induced absorption changes arising from b-type hemes were studied on whole cells of Heliobacillus mobilis under physiological and redox-controlled conditions. The sensitivity of the monitored redox changes to inhibitors of cytochrome bc complexes and the redox potential dependence of reduction and oxidation reactions of cytochrome b-hemes demonstrate that the respective b-hemes are part of a cytochrome bc complex. Both the half-time and the extent of flash-induced reduction of cytochrome b titrated with apparent potentials of about -60 and -50 mV (both n = 2), respectively, i.e., close to the Em,7 value of the menaquinone (MK) pool, indicating a collisional interaction between menaquinol and the Qo site of the cytochrome bc complex. At strongly reducing ambient potentials (< -150 mV), a net flash-induced oxidation of b-hemes was observed in agreement with the Em,7 values of the individual hemes of -90 mV (b(h)) and -190 mV (b(l)) determined in equilibrium redox titrations on membrane fragments. From the extent of photooxidized b- and c-type hemes as well as P798+, a stoichiometry of 0.6-0.75 cytochrome bc complexes per photosynthetic reaction center was estimated. The kinetic behavior and also the energy profiles for Q-cycle turnover of the heliobacterial complex are compared to those of cytochrome bc1 complexes from purple bacteria and of cytochrome b6f complexes from chloroplasts.

Membrane-bound c-type cytochromes in Heliobacillus mobilis. Characterisation by EPR and optical spectroscopy in membranes and detergent-solubilised material.

The spectral and electrochemical parameters, as well as the orientations of the heme plane with respect to the membrane plane, of the c-type hemes present in membrane fragments from Heliobacillus mobilis were characterised by optical and EPR spectroscopy. Cytochrome C53, was thereby shown to represent at least four and possibly five heme species with the following characteristics: Em = -60 mV +/- 10 mV, g, = 2.92, 60 degrees; Em = +90 mV +/- 10 mV, g, = 2.92, 90 degrees; Em = +120 mV +/- 20 mV, g, = 3.03; and Em = +170 mV +/- 20 mV, g, = 3.03. The latter component may correspond to two hemes with redox midpoint potentials of Em = +160 mV +/- 20 mV and Em = +180 mV +/- 20 mV (all Em values at pH 7.0). For the heme species having g, peaks at g approximately 3.03, determination of individual orientations was precluded due to the superposition of several differently oriented hemes. About one copy of each heme was found to be present per photosynthetic reaction centre, with the exception of the +120 mV component for which a stoichiometry of 2 hemes/reaction centre was obtained. The heme proteins were detergent-solubilised and partially purified. Three c-type cytochromes that migrated with apparent molecular masses of 18, 29 and 50 kDa were detected on SDS/PAGE. Optical redox titrations at pH 7.0 showed redox midpoint potentials of +160 mV +/- 10 mV for the 18-kDa cytochrome, and -60 mV +/- 10 mV, with possible contributions around +160 mV, for the 50-kDa cytochrome. A tentative attribution of heme species observed in membranes to the isolated heme proteins is presented. The results obtained on H. mobilis are compared with those reported for green sulphur bacteria.

In vivo participation of a high potential iron-sulfur protein as electron donor to the photochemical reaction center of Rubrivivax gelatinosus.

We have found that the only high redox potential electron transfer component in the soluble fraction of Rubrivivax gelatinosus TG-9 is a high-potential iron-sulfur protein (HiPIP). We demonstrated the participation of this HiPIP in the photoinduced electron transfer both in vivo and in vitro. First, the addition of HiPIP to purified membranes enhanced the rate of re-reduction of the photooxidized reaction center. Second, the photooxidation of HiPIP was observed in intact cells of Ru. gelatinosus TG-9 under anaerobic conditions by EPR and absorption spectroscopies. Analysis of flash-induced absorption changes showed that the equilibration of positive equivalents between the reaction center and HiPIP occurs in less than 1 ms after flash excitation. The complete re-reduction of the photooxidized reaction center is achieved in tens of milliseconds. The turnover of a cyt bc1 is also involved in this reaction, as shown by a slow electrogenic phase of the membrane potential linked to this process.