Probing the role of the Fe-S subunit hinge region during Q(o) site catalysis in Rhodobacter capsulatus bc(1) complex.

The ubihydroquinone:cytochrome c oxidoreductase, or bc(1) complex, functions according to a mechanism known as the modified Q cycle. Recent crystallographic data have revealed that the extrinsic domain containing the [2Fe2S] cluster of the Fe-S subunit of this enzyme occupies different positions in various crystal forms, suggesting that this subunit may move during ubihydroquinone oxidation. As in these structures the hydrophobic membrane anchor of the Fe-S subunit remains at the same position, the movement of the [2Fe2S] cluster domain would require conformational changes of the hinge region linking its membrane anchor to its extrinsic domain. To probe the role of the hinge region, Rhodobacter capsulatus bc(1) complex was used as a model, and various mutations altering the hinge region amino acid sequence, length, and flexibility were obtained. The effects of these modifications on the bc(1) complex function and assembly were investigated in detail. These studies demonstrated that the nature of the amino acid residues located in the hinge region (positions 43-49) of R. capsulatus Fe-S subunit was not essential per se for the function of the bc(1) complex. Mutants with a shorter hinge (up to five amino acid residues deletion) yielded functional bc(1) complexes, but contained substoichiometric amounts of the Fe-S subunit. Moreover, mutants with increased rigidity or flexibility of the hinge region altered both the function and the assembly or the steady-state stability of the bc(1) complex. In particular, the extrinsic domain of the Fe-S subunit of a mutant containing six proline residues in the hinge region was shown to be locked in a position similar to that seen in the presence of stigmatellin. Interestingly, the latter mutant readily overcomes this functional defect by accumulating an additional mutation which shortens the length of the hinge. These findings indicate that the hinge region of the Fe-S subunit of bacterial bc(1) complexes has a remarkable structural plasticity.

Proteolytic cleavage of the Fe-S subunit hinge region of Rhodobacter capsulatus bc(1) complex: effects of inhibitors and mutations.

The three-dimensional structure of the mitochondrial bc(1) complex reveals that the extrinsic domain of the Fe-S subunit, which carries the redox-active [2Fe2S] cluster, is attached to its transmembrane anchor domain by a short flexible hinge sequence (amino acids D43 to S49 in Rhodobacter capsulatus). In various structures, this extrinsic domain is located in different positions, and the conformation of the hinge region is different. In addition, proteolysis of this region has been observed previously in a bc(1) complex mutant of R. capsulatus [Saribas, A. S., Valkova-Valchanova, M. B., Tokito, M., Zhang, Z., Berry E. A., and Daldal, F. (1998) Biochemistry 37, 8105-8114]. Thus, possible correlations between proteolysis, conformation of the hinge region, and position of the extrinsic domain of the Fe-S subunit within the bc(1) complex were sought. In this work, we show that thermolysin, or an endogenous activity present in R. capsulatus, cleaves the hinge region of the Fe-S subunit between its amino acid residues A46-M47 or D43-V44, respectively, to yield a protease resistant fragment with a M(r) of approximately 18 kDa. The cleavage was affected significantly by ubihydroquinone oxidation (Q(o)) and ubiquinone reduction (Q(i)) site inhibitors and by specific mutations located in the bc(1) complex. In particular, using either purified or detergent dispersed chromatophore-embedded R. capsulatus bc(1) complex, we demonstrated that while stigmatellin blocked the cleavage, myxothiazol hardly affected it, and antimycin A greatly enhanced it. Moreover, mutations in various regions of the Fe-S subunit and cyt b subunit changed drastically proteolysis patterns, indicating that the structure of the hinge region of the Fe-S subunit was modified in these mutants. The overall findings establish that protease accessibility of the Fe-S subunit of the bc(1) complex is a useful biochemical assay for probing the conformation of its hinge region and for monitoring indirectly the position of its extrinsic [2Fe2S] cluster domain within the Q(o) pocket.

Uncovering the [2Fe2S] domain movement in cytochrome bc1 and its implications for energy conversion.

In crystals of the key respiratory and photosynthetic electron transfer protein called ubihydroquinone:cytochrome (cyt) c oxidoreductase or cyt bc(1), the extrinsic [2Fe2S] cluster domain of its Fe-S subunit assumes several conformations, suggesting that it may move during catalysis. Herein, using Rhodobacter capsulatus mutants that have modifications in the hinge region of this subunit, we were able to reveal this motion kinetically. Thus, the bc(1) complex (and possibly the homologous b(6)f complex in chloroplasts) employs the [2Fe2S] cluster domain as a device to shuttle electrons from ubihydroquinone to cyt c(1) (or cyt f). We demonstrate that this domain movement is essential for cyt bc(1) function, because a mutant enzyme with a nonmoving Fe-S subunit has no catalytic activity, and one with a slower movement has lower activity. This motion is apparently designed with a natural frequency slow enough to assure productive Q(o) site charge separation but fast enough not to be rate limiting. These findings add the unprecedented function of intracomplex electron shuttling to large-scale domain motions in proteins and may well provide a target for cyt bc(1) antibiotics.

Structure and function of the bacterial bc1 complex: domain movement, subunit interactions, and emerging rationale engineering attempts.

The ubiquinol: cytochrome c oxidoreductase, or the bc1 complex, is a key component of both respiratory and photosynthetic electron transfer and contributes to the formation of an electrochemical gradient necessary for ATP synthesis. Numerous bacteria harbor a bc1 complex comprised of three redox-active subunits, which bear two b-type hemes, one c-type heme, and one [2Fe-2S] cluster as prosthetic groups. Photosynthetic bacteria like Rhodobacter species provide powerful models for studying the function and structure of this enzyme and are being widely used. In recent years, extensive use of spontaneous and site-directed mutants and their revertants, new inhibitors, discovery of natural variants of this enzyme in various species, and engineering of novel bc1 complexes in species amenable to genetic manipulations have provided us with a wealth of information on the mechanism of function, nature of subunit interactions, and assembly of this important enzyme. The recent resolution of the structure of various mitochondrial bc1 complexes in different crystallographic forms has consolidated previous findings, added atomic-scale precision to our knowledge, and raised new issues, such as the possible movement of the Rieske Fe-S protein subunit during Qo site catalysis. Here, studies performed during the last few years using bacterial bc1 complexes are reviewed briefly and ongoing investigations and future challenges of this exciting field are mentioned.

Isolation and characterization of a two-subunit cytochrome b-c1 subcomplex from Rhodobacter capsulatus and reconstitution of its ubihydroquinone oxidation (Qo) site with purified Fe-S protein subunit.

The presence of a two-subunit cytochrome (cyt) b-c1 subcomplex in chromatophore membranes of Rhodobacter capsulatus mutants lacking the Rieske iron-sulfur (Fe-S) protein has been described previously [Davidson, E., Ohnishi, T., Tokito, M., and Daldal, F. (1992) Biochemistry 31, 3351-3358]. Here, this subcomplex was purified to homogeneity in large quantities, and its properties were characterized. As expected, it contained stoichiometric amounts of cyt b and cyt c1 subunits forming a stable entity devoid of the Fe-S protein subunit. The spectral and thermodynamic properties of its heme groups were largely similar to those of a wild-type bc1 complex, except that those of its cyt bL heme were modified as revealed by EPR spectroscopy. Dark potentiometric titrations indicated that the redox midpoint potential (Em7) values of cytochromes bH, bL, and c1 were very similar to those of a wild-type bc1 complex. The purified b-c1 subcomplex had a nonfunctional ubihydroquinone (UQH2) oxidation (Qo) site, but it contained an intact ubiquinone (UQ) reductase (Qi) site as judged by its ability to bind the Qi inhibitor antimycin A, and by the presence of antimycin A sensitive Qi semiquinone. Interestingly, its Qo site could be readily reconstituted by addition of purified Fe-S protein subunit. Reactivated complex exhibited myxothiazol, stigmatellin, and antimycin A sensitive cyt c reductase activity and an EPR gx signal comparable to that observed with a bc1 complex when the Qo site is partially occupied with UQ/UQH2. However, a mutant derivative of the Fe-S protein subunit lacking its first 43 amino acid residues was unable to reactivate the purified b-c1 subcomplex although it could bind to its Qo site in the presence of stigmatellin. These findings demonstrated for the first time that the amino-terminal membrane-anchoring domain of the Fe-S protein subunit is necessary for UQH2 oxidation even though its carboxyl-terminal domain is sufficient to provide wild-type-like interactions with stigmatellin at the Qo site of the bc1 complex.

Interactions between the cytochrome b, cytochrome c1, and Fe-S protein subunits at the ubihydroquinone oxidation site of the bc1 complex of Rhodobacter capsulatus.

Ubihydroquinone:cytochrome (cyt) c oxidoreductase (bc1 complex and its plant counterpart b6f complex) is a vital component of energy-transducing systems in most organisms from bacteria to eukaryotes. In the facultative phototrophic (Ps) bacterium Rhodobacter capsulatus, it is constituted by the cyt b, cyt c1, and Rieske Fe-S protein subunits and is essential for Ps growth. Of these subunits, cyt b has two nontransmembrane helices, cd1 and cd2, which are critical for its structure and function. In particular, substitution of threonine (T) at position 163 on cd1 with phenylalanine (F) or proline (P) leads to the absence of the bc1 complex. Here, Ps+ revertants of B:T163F were obtained, and their detailed characterizations indicated that position 163 is important for the assembly of the bc1 complex by mediating subunit interactions at the Qo site. The loss of the hydroxyl group at position 163 of cyt b was compensated for by the gain of either a hydroxyl group at position 182 of cyt b or 46 of the Fe-S protein or a sulfhydryl group at position 46 of cyt c1. Examination of the mitochondrial bc1 complex crystal structure [Zhang, Z., Huang, L., Shulmeister, V. M., Chi, Y.-I., Kim, K. K., Hung, L.-W., Crofts, A. R., Berry, E. A., and Kim, S.-H. (1998) Nature 392, 677-684] revealed that the counterparts of B:G182 (i.e., G167) and F:A46 (i.e. , A70) are located close to B:T163 (i.e., T148), whereas the C:R46 (i.e., R28) is remarkably far from it. The revertants contained substoichiometric amounts of the Fe-S protein subunit and exhibited steady-state and single-turnover, electron transfer activities lower than that of a wild-type bc1 complex. Interestingly, their membrane supernatants contained a smaller form of this subunit with physicochemical properties identical to those of its membrane-bound form. Determination of the amino-terminal amino acid sequence of this soluble Fe-S protein revealed that it was derived from the wild-type protein by proteolytic cleavage at V44. This work revealed for the first time that position 163 of cyt b is important both for proper subunit interactions at the Qo site and for inactivation of the bc1 complex by proteolytic cleavage of its Fe-S protein subunit at a region apparently responsible for its mobility during Qo site catalysis.

Purification and characterization of two new c-type cytochromes involved in Fe2+ oxidation from Thiobacillus ferrooxidans.

Two new c-type cytochromes have been purified from cell membranes of the acidophilic Thiobacillus ferrooxidans. In contrast to a soluble cytochrome c with molecular mass of 14 kDa reported earlier, a membrane-bound cytochrome c with a mass of 21 kDa was solubilized with octylthioglucoside and purified to homogeneity. In addition, a high molecular mass c-type cytochrome (68 kDa) was also solubilized and purified using Triton X-100 as a detergent. Both acid-stable species are partially released during osmotic shock and chloroform treatment of the bacteria; they are integral components in the respiratory chain donating electrons to the terminal cytochrome oxidase.