Insights from the structure of the yeast cytochrome bc1 complex: crystallization of membrane proteins with antibody fragments

The ubiquinol:cytochrome c oxidoreductase (EC 1.20.2.2, QCR or cytochrome bc1 complex) is a component of respiratory and photosynthetic electron transfer chains in mitochondria and bacteria. The complex transfers electrons from quinol to cytochrome c. Electron transfer is coupled to proton translocation across the lipid bilayer, thereby generating an electrochemical proton gradient, which conserves the free energy of the redox reaction. The yeast complex was crystallized with antibody Fv fragments, a promising technique to obtain well-ordered crystals from membrane proteins. The high-resolution structure of the yeast protein reveals details of the catalytic sites of the complex, which are important for electron and proton transfer.     

Regulation of ornithine decarboxylase by antizymes and antizyme inhibitor in zebrafish (Danio rerio)

The structure of the complex between cytochrome c (CYC) and the cytochrome bc(1) complex (QCR) from yeast crystallized with an antibody fragment has been recently determined at 2.97 A resolution [Proc. Natl. Acad. Sci. U. S. A. 99 (2002) 2800]. CYC binds to subunit cytochrome c(1) of the enzyme stabilized by hydrophobic interactions surrounding the heme crevices creating a small, compact contact site. A central cation-pi interaction is an important and conserved feature of CYC binding. Peripheral patches with highly conserved complementary charges further stabilize the enzyme-substrate complex by long-range electrostatic forces and may affect the orientation of the substrate. Size and characteristics of the contact site are optimal for a transient electron transfer complex. Kinetic data show a bell-shaped ionic strength dependence of the cytochrome c reduction with a maximum activity near physiological ionic strength. The dependence is less pronounced in yeast compared to horse heart CYC indicating less impact of electrostatic interactions in the yeast system. Interestingly, a local QCR activity minimum is found for both substrates at 120-140 mM ionic strength. The architecture of the complex results in close distance of both c-type heme groups allowing the rapid reduction of cytochrome c by QCR via direct heme-to-heme electron transfer. Remarkably, CYC binds only to one of the two possible binding sites of the homodimeric complex and binding appears to be coordinated with the presence of ubiquinone at the Q(i) site. Regulatory aspects of CYC reduction are discussed.     

Structural basis of multifunctional bovine mitochondrial cytochrome bc1 complex

The mitochondrial cytochrome bc1 complex is a multifunctional membrane protein complex. It catalyzes electron transfer, proton translocation, peptide processing, and superoxide generation. Crystal structure data at 2.9 A resolution not only establishes the location of the redox centers and inhibitor binding sites, but also suggests a movement of the head domain of the iron-sulfur protein (ISP) during bc1 catalysis and inhibition of peptide-processing activity during complex maturation. The functional importance of the movement of extramembrane (head) domain of ISP in the bc1 complex is confirmed by analysis of the Rhodobacter sphaeroides bc1 complex mutants with increased rigidity in the ISP neck and by the determination of rate constants for acid/base-induced intramolecular electron transfer between [2Fe-2S] and heme c1 in native and inhibitor-loaded beef complexes. The peptide-processing activity is activated in bovine heart mitochondrial bc1 complex by nonionic detergent at concentrations that inactivate electron transfer activity. This peptide-processing activity is shown to be associated with subunits I and II by cloning, overexpression and in vitro reconstitution. The superoxide-generation site of the cytochrome bc1 complex is located at reduced bL and Q*-. The reaction is membrane potential-, and cytochrome c-dependent.     

Cytochrome bc1 complexes of microorganisms.

The cytochrome bc1 complex is the most widely occurring electron transfer complex capable of energy transduction. Cytochrome bc1 complexes are found in the plasma membranes of phylogenetically diverse photosynthetic and respiring bacteria, and in the inner mitochondrial membrane of all eucaryotic cells. In all of these species the bc1 complex transfers electrons from a low-potential quinol to a higher-potential c-type cytochrome and links this electron transfer to proton translocation. Most bacteria also possess alternative pathways of quinol oxidation capable of circumventing the bc1 complex, but these pathways generally lack the energy-transducing, protontranslocating activity of the bc1 complex. All cytochrome bc1 complexes contain three electron transfer proteins which contain four redox prosthetic groups. These are cytochrome b, which contains two b heme groups that differ in their optical and thermodynamic properties; cytochrome c1, which contains a covalently bound c-type heme; and a 2Fe-2S iron-sulfur protein. The mechanism which links proton translocation to electron transfer through these proteins is the proton motive Q cycle, and this mechanism appears to be universal to all bc1 complexes. Experimentation is currently focused on understanding selected structure-function relationships prerequisite for these redox proteins to participate in the Q-cycle mechanism. The cytochrome bc1 complexes of mitochondria differ from those of bacteria, in that the former contain six to eight supernumerary polypeptides, in addition to the three redox proteins common to bacteria and mitochondria. These extra polypeptides are encoded in the nucleus and do not contain redox prosthetic groups. The functions of the supernumerary polypeptides of the mitochondrial bc1 complexes are generally not known and are being actively explored by genetically manipulating these proteins in Saccharomyces cerevisiae.     

Deletion of subunit 9 of the Saccharomyces cerevisiae cytochrome bc1 complex specifically impairs electron transfer at the ubiquinol oxidase site (center P) in the bc1 complex.

Deletion of QCR9, the nuclear gene encoding subunit 9 of the mitochondrial cytochrome bc1 complex in Saccharomyces cerevisiae, results in inactivation of the bc1 complex and inability of the yeast to grow on non-fermentable carbon sources. The loss of bc1 complex activity is due to loss of electron transfer activity at the ubiquinol oxidase site (center P) in the complex. Electron transfer at the ubiquinone reductase site (center N), is unaffected by the loss of subunit 9, but the extent of cytochrome b reduction is diminished. This is the first instance in which a supernumerary polypeptide, lacking a redox prosthetic group, has been shown to be required for an electron transfer reaction within the cytochrome bc1 complex.     

Design of a ruthenium-labeled cytochrome c derivative to study electron transfer with the cytochrome bc1 complex

A new ruthenium-cytochrome c derivative was designed to study electron transfer from cytochrome bc1 to cytochrome c (Cc). The single sulfhydryl on yeast H39C;C102T iso-1-Cc was labeled with Ru(2,2'-bipyrazine)2(4-bromomethyl-4'-methyl-2,2'-bipyridine) to form Ru(z)-39-Cc. The Ru(z)-39-Cc derivative has the same steady-state activity with yeast cytochrome bc1 as wild-type yeast iso-1-Cc, indicating that the ruthenium complex does not interfere in the binding interaction. Laser excitation of reduced Ru(z)-39-Cc results in electron transfer from heme c to the excited state of ruthenium with a rate constant of 1.5 x 10(6) x s(-1). The resulting Ru(I) is rapidly oxidized by atmospheric oxygen in the buffer. The yield of photooxidized heme c is 20% in a single flash. Flash photolysis of a 1:1 complex between reduced yeast cytochrome bc1 and Ru(z)-39-Cc at low ionic strength leads to rapid photooxidation of heme c, followed by intracomplex electron transfer from cytochrome c1 to heme c with a rate constant of 1.4 x 10(4) x s(-1). As the ionic strength is raised above 100 mM, the intracomplex phase disappears, and a new phase appears due to the bimolecular reaction between solution Ru-39-Cc and cytochrome bc1. The interaction of yeast Ru-39-Cc with yeast cytochrome bc1 is stronger than that of horse Ru-39-Cc with bovine cytochrome bc1, suggesting that nonpolar interactions are stronger in the yeast system.     

pH-induced intramolecular electron transfer between the iron-sulfur protein and cytochrome c(1) in bovine cytochrome bc(1) complex

Structural analysis of the bc(1) complex suggests that the extra membrane domain of iron-sulfur protein (ISP) undergoes substantial movement during the catalytic cycle. Binding of Qo site inhibitors to this complex affects the mobility of ISP. Taking advantage of the difference in the pH dependence of the redox midpoint potentials of cytochrome c(1) and ISP, we have measured electron transfer between the [2Fe-2S] cluster and heme c(1) in native and inhibitor-treated partially reduced cytochrome bc(1) complexes. The rate of the pH-induced cytochrome c(1) reduction can be estimated by conventional stopped-flow techniques (t1/2, 1-2 ms), whereas the rate of cytochrome c(1) oxidation is too high for stopped-flow measurement. These results suggest that oxidized ISP has a higher mobility than reduced ISP and that the movement of reduced ISP may require an energy input from another component. In the 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT)-inhibited complex, the rate of cytochrome c(1) reduction is greatly decreased to a t1/2 of approximately 2.8 s. An even lower rate is observed with the stigmatellin-treated complex. These results support the idea that UHDBT and stigmatellin arrest the [2Fe-2S] cluster at a fixed position, 31 A from heme c(1), making electron transfer very slow.     

Protonmotive pathways and mechanisms in the cytochrome bc1 complex

The cytochrome bc(1) complex catalyzes electron transfer from ubiquinol to cytochrome c by a protonmotive Q cycle mechanism in which electron transfer is linked to proton translocation across the inner mitochondrial membrane. In the Q cycle mechanism proton translocation is the net result of topographically segregated reduction of quinone and reoxidation of quinol on opposite sides of the membrane, with protons being carried across the membrane as hydrogens on the quinol. The linkage of proton chemistry to electron transfer during quinol oxidation and quinone reduction requires pathways for moving protons to and from the aqueous phase and the hydrophobic environment in which the quinol and quinone redox reactions occur. Crystal structures of the mitochondrial cytochrome bc(1) complexes in various conformations allow insight into possible proton conduction pathways. In this review we discuss pathways for proton conduction linked to ubiquinone redox reactions with particular reference to recently determined structures of the yeast bc(1) complex.     

The Q cycle of cytochrome bc complexes: a structure perspective

Aspects of the crystal structures of the hetero-oligomeric cytochrome bc(1) and b(6)f ("bc") complexes relevant to their electron/proton transfer function and the associated redox reactions of the lipophilic quinones are discussed. Differences between the b(6)f and bc(1) complexes are emphasized. The cytochrome bc(1) and b(6)f dimeric complexes diverge in structure from a core of subunits that coordinate redox groups consisting of two bis-histidine coordinated hemes, a heme b(n) and b(p) on the electrochemically negative (n) and positive (p) sides of the complex, the high potential [2Fe-2S] cluster and c-type heme at the p-side aqueous interface and aqueous phase, respectively, and quinone/quinol binding sites on the n- and p-sides of the complex. The bc(1) and b(6)f complexes diverge in subunit composition and structure away from this core. b(6)f Also contains additional prosthetic groups including a c-type heme c(n) on the n-side, and a chlorophyll a and β-carotene. Common structure aspects; functions of the symmetric dimer. (I) Quinone exchange with the bilayer. An inter-monomer protein-free cavity of approximately 30? along the membrane normal×25? (central inter-monomer distance)×15? (depth in the center), is common to both bc(1) and b(6)f complexes, providing a niche in which the lipophilic quinone/quinol (Q/QH(2)) can be exchanged with the membrane bilayer. (II) Electron transfer. The dimeric structure and the proximity of the two hemes b(p) on the electrochemically positive side of the complex in the two monomer units allow the possibility of two alternate routes of electron transfer across the complex from heme b(p) to b(n): intra-monomer and inter-monomer involving electron cross-over between the two hemes b(p). A structure-based summary of inter-heme distances in seven bc complexes, representing mitochondrial, chromatophore, cyanobacterial, and algal sources, indicates that, based on the distance parameter, the intra-monomer pathway would be favored kinetically. (III) Separation of quinone binding sites. A consequence of the dimer structure and the position of the Q/QH(2) binding sites is that the p-side QH(2) oxidation and n-side Q reduction sites are each well separated. Therefore, in the event of an overlap in residence time by QH(2) or Q molecules at the two oxidation or reduction sites, their spatial separation would result in minimal steric interference between extended Q or QH(2) isoprenoid chains. (IV) Trans-membrane QH(2)/Q transfer. (i) n/p-side QH(2)/Q transfer may be hindered by lipid acyl chains; (ii) the shorter less hindered inter-monomer pathway across the complex would not pass through the center of the cavity, as inferred from the n-side antimycin site on one monomer and the p-side stigmatellin site on the other residing on the same surface of the complex. (V) Narrow p-side portal for QH(2)/Q passage. The [2Fe-2S] cluster that serves as oxidant, and whose histidine ligand serves as a H(+) acceptor in the oxidation of QH(2), is connected to the inter-monomer cavity by a narrow extended portal, which is also occupied in the b(6)f complex by the 20 carbon phytyl chain of the bound chlorophyll.     

The role of extra fragment at the C-terminal of cytochrome b (Residues 421-445) in the cytochrome bc1 complex from Rhodobacter sphaeroides

Sequence alignment of cytochrome b of the cytochrome bc1 complex from various sources reveals that bacterial cytochrome b contain an extra fragment at the C terminus. To study the role of this fragment in bacterial cytochrome bc1 complex, Rhodobacter sphaeroides mutants expressing His-tagged cytochrome bc1 complexes with progressive deletion from this fragment (residues 421-445) were generated and characterized. The cytbDelta-(433-445) bc1 complex, in which 13 residues from the C-terminal end of this fragment are deleted, has electron transfer activity, subunit composition, and physical properties similar to those of the complement complex, indicating that this region of the extra fragment is not essential. In contrast, the electron transfer activity, binding of cytochrome b, ISP, and subunit IV to cytochrome c1, redox potentials of cytochromes b and c1 in the cytbDelta-(427-445), cytbDelta-(425-445), and cytbDelta-(421-445) mutant complexes, in which 19, 21, or all residues of this fragment are deleted, decrease progressively. EPR spectra of the [2Fe-2S] cluster and the cytochromes b in these three deletion mutant bc1 complexes are also altered; the extent of spectral alteration increases as this extra fragment is shortened. These results indicate that the first 12 residues (residues 421-432) from the N-terminal end of the C-terminal extra fragment of cytochrome b are essential for maintaining structural integrity of the bc1 complex.     

Analysis of suppressor mutation reveals long distance interactions in the bc(1) complex of Saccharomyces cerevisiae

Four totally conserved glycines are involved in the packing of the two cytochrome b hemes, b(L) and b(H), of the bc(1) complex. The conserved glycine 131 is involved in the packing of heme b(L) and is separated by only 3 A from this heme in the bc(1) complex structure. The cytochrome b respiratory deficient mutant G131S is affected in the assembly of the bc(1) complex. An intragenic suppressor mutation was obtained at position 260, in the ef loop, where a glycine was replaced by an alanine. This respiratory competent revertant exhibited a low bc(1) complex activity and was affected in the electron transfer at the Q(P) site. The k(min) for the substrate DBH(2) was diminished by an order of magnitude and EPR spectra showed a partially empty Q(P) site. However, the binding of the Q(P) site inhibitors stigmatellin and myxothiazol remained unchanged in the suppressor strain. Optical spectroscopy revealed that heme b(L) is red shifted by 0.8 nm and that the E(m) of heme b(L) was slightly increased (+20 mV) in the revertant strain as compared to wild type strain values. Addition of a methyl group at position 260 is thus sufficient to allow the assembly of the bc(1) complex and the insertion of heme b(L) despite the presence of the serine at position 131. Surprisingly, reversion at position 260 was located 13 A away from the original mutation and revealed a long distance interaction in the yeast bc(1) complex.     

The petite phenotype resulting from a truncated copy of subunit 6 results from loss of assembly of the cytochrome bc1 complex and can be suppressed by overexpression of subunit 9.

Disruption of the gene for subunit 6 of the yeast cytochrome bc1 complex (QCR6) causes a temperature-sensitive petite phenotype in contrast to deletion of the coding region of QCR6, which shows no growth defect. Mitochondria from the petite strain carrying the disruption allele were devoid of ubiquinol-cytochrome c oxidoreductase activity but retained cytochrome c oxidase and oligomycin-sensitive ATPase activities. Optical spectra of cytochromes in mitochondrial membranes from the petite strain lacked a cytochrome b absorption band and had a reduced amount of cytochrome c1. Analysis of mitochondrial translation products showed normal synthesis of cytochrome b. Western analysis of mitochondrial membranes from this disruption strain indicates core protein 1 of the cytochrome bc1 complex is present in normal amounts, while cytochrome c1, the Rieske iron-sulfur protein, subunit 6, and subunit 7 were absent or present in very low amounts. Taken together, these findings indicate a loss of assembly of the cytochrome bc1 complex. High copy suppressors of the disruption strain were selected. Two separate families of suppressors were found. The first contained QCR6. The second family consisted of overlapping clones of a second gene distinct from QCR6. These plasmids contained QCR9, the gene which codes for subunit 9 of the yeast cytochrome bc1 complex. Suppression of the QCR6 disruption strain by overexpression of QCR9 indicates a critical interaction between these two proteins in the assembly of the cytochrome bc1 complex.     

Flash-induced turnover of the cytochrome bc1 complex in chromatophores of Rhodobacter capsulatus: binding of Zn2+ decelerates likewise the oxidation of cytochrome b, the reduction of cytochrome c1 and the voltage generation

The effect of Zn2+ on the rates of electron transfer and of voltage generation in the cytochrome bc1 complex (bc1) was investigated under excitation of Rhodobacter capsulatus chromatophores with flashing light. When added, Zn2+ retarded the oxidation of cytochrome b and allowed to monitor (at 561-570 nm) the reduction of its high potential heme b(h) (in the absence of Zn2+ this reaction was masked by the fast re-oxidation of the heme). The effect was accompanied by the deceleration of both the cytochrome c(1) reduction (as monitored at 552-570 nm) and the generation of transmembrane voltage (monitored by electrochromism at 522 nm). At Zn2+ <100 microM the reduction of heme b(h) remained 10 times faster than other reactions. The kinetic discrepancy was observed even after an attenuated flash, when bc1 turned over only once. These observations (1) raise doubt on the notion that the transmembrane electron transfer towards heme b(h) is the main electrogenic reaction in the cytochrome bc1 complex, (2) imply an allosteric link between the site of heme b(h) oxidation and the site of cytochrome c1 reduction at the opposite side of the membrane, and (3) indicate that the internal redistribution of protons might account for the voltage generation by the cytochrome bc1 complex.     

Primary steps in the energy conversion reaction of the cytochrome bc1 complex Qo site

The primary energy conversion (Qo) site of the cytochrome bc1 complex is flanked by both high- and low-potential redox cofactors, the [2Fe-2S] cluster and cytochrome bL, respectively. From the sensitivity of the reduced [2Fe-2S] cluster electron paramagnetic resonance (EPR) spectral g(x)-band and line shape to the degree and type of Qo site occupants, we have proposed a double-occupancy model for the Qo site by ubiquinone in Rhodobacter capsulatus membrane vesicles containing the cytochrome bc1 complex. Biophysical and biochemical experiments have confirmed the double occupancy model and from a combination of these results and the available cytochrome bc1 crystal structures we suggest that the two ubiquinone molecules in the Qo site serve distinct catalytic roles. We propose that the strongly bound ubiquinone, termed Qos, is close to the [2Fe-2S] cluster, where it remains tightly associated with the Qo site during turnover, serving as a catalytic cofactor; and the weaker bound ubiquinone, Qow, is distal to the [2Fe-2S] cluster and can exchange with the membrane Qpool on a time scale much faster than the turnover, acting as the substrate. The crystallographic data demonstrates that the FeS subunit can adopt different positions. Our own observations show that the equilibrium position of the reduced FeS subunit is proximal to the Qo site. On the basis of this, we also report preliminary results modeling the electron transfer reactions that can occur in the cytochrome bc1 complex and show that because of the strong distance dependence of electron transfer, significant movement of the FeS subunit must occur in order for the complex to be able to turn over at the experimental observed rates.     

Effect of inhibitors on the ubiquinone binding capacity of the primary energy conversion site in the Rhodobacter capsulatus cytochrome bc(1) complex.

A key issue concerning the primary conversion (Q(O)) site function in the cytochrome bc(1) complex is the stoichiometry of ubiquinone/ubihydroquinone occupancy. Previous evidence suggests that the Q(O) site is able to accommodate two ubiquinone molecules, the double occupancy model [Ding, H., Robertson, D. E., Daldal, F., and Dutton, P. L. (1992) Biochemistry 31, 3144-3158]. In the recently reported crystal structures of the cytochrome bc(1) complex, no electron density was identified in the Q(O) site that could be ascribed to ubiquinone. To provide further insight into this issue, we have manipulated the cytochrome bc(1) complex Q(O) site occupancy in photosynthetic membranes from Rhodobacter capsulatus by using inhibitor titrations and ubiquinone extraction to modulate the amount of ubiquinone bound in the site. The nature of the Q(O) site occupants was probed via the sensitivity of the reduced [2Fe-2S] cluster electron paramagnetic resonance (EPR) spectra to modulation of Q(O) site occupancy. Diphenylamine (DPA) and methoxyacrylate (MOA)-stilbene are known Q(O) site inhibitors of the cytochrome bc(1) complex. Addition of stoichiometric concentrations of MOA-stilbene or excess DPA to cytochrome bc(1) complexes with natural levels of ubiquinone elicits the same change in the [2Fe-2S] cluster EPR spectra; the g(x)() resonance broadens and shifts from 1. 800 to 1.783. This is exactly the same signal as that obtained when there is only one ubiquinone present in the Q(O) site. Furthermore, addition of MOA-stilbene or DPA to the cytochrome bc(1) complex depleted of ubiquinone does not alter the [2Fe-2S] cluster EPR spectral line shapes, which remain indicative of one ubiquinone or zero ubiquinones in the Q(O) site, with broad g(x)() resonances at 1. 783 or 1.765, respectively. The results are quite consistent with the Q(O) site double occupancy model, in which MOA-stilbene and DPA inhibit by displacing one, but not both, of the Q(O) site ubiquinones.     

Conformational change of the Rieske [2Fe-2S] protein in cytochrome bc1 complex

Structures of mitochondrial bc1 complex have been reported based on four different crystal forms by three different groups. In these structures, the extrinsic domain of the Rieske [2Fe-2S] protein, surprisingly, appeared at three different positions: the "c1" position, where the [2Fe-2S] cluster exists in close proximity to the heme c1; the "b" position, where the [2Fe-2S] cluster exist in close proximity to the cytochrome b; and the "intermediate" position where the [2Fe-2S] cluster exists in-between "c1" and "b" positions. The conformational changes between these three positions can be explained by a combination of two rotations; (1) a rotation of the entire extrinsic domain and (2) a relative rotation between the cluster-binding fold and the base fold within the extrinsic domain. The hydroquinone oxidation and the electron bifurcation mechanism at the Q(P) binding pocket of the bc1 complex is well explained using these conformational changes of the Rieske [2Fe-2S] protein.     

Consequences of the structure of the cytochrome b6f complex for its charge transfer pathways

At least two features of the crystal structures of the cytochrome b6f complex from the thermophilic cyanobacterium, Mastigocladus laminosus and a green alga, Chlamydomonas reinhardtii, have implications for the pathways and mechanism of charge (electron/proton) transfer in the complex: (i) The narrow 11 x 12 A portal between the p-side of the quinone exchange cavity and p-side plastoquinone/quinol binding niche, through which all Q/QH2 must pass, is smaller in the b6f than in the bc1 complex because of its partial occlusion by the phytyl chain of the one bound chlorophyll a molecule in the b6f complex. Thus, the pathway for trans-membrane passage of the lipophilic quinone is even more labyrinthine in the b6f than in the bc1 complex. (ii) A unique covalently bound heme, heme cn, in close proximity to the n-side b heme, is present in the b6f complex. The b6f structure implies that a Q cycle mechanism must be modified to include heme cn as an intermediate between heme bn and plastoquinone bound at a different site than in the bc1 complex. In addition, it is likely that the heme bn-cn couple participates in photosytem I-linked cyclic electron transport that requires ferredoxin and the ferredoxin: NADP+ reductase. This pathway through the n-side of the b6f complex could overlap with the n-side of the Q cycle pathway. Thus, either regulation is required at the level of the redox state of the hemes that would allow them to be shared by the two pathways, and/or the two different pathways are segregated in the membrane.     

Proton translocation by the cytochrome bc1 complexes of phototrophic bacteria: introducing the activated Q-cycle.

The cytochrome bc1 complexes are proton-translocating, dimeric membrane ubiquinol:cytochrome c oxidoreductases that serve as "hubs" in the vast majority of electron transfer chains. After each ubiquinol molecule is oxidized in the catalytic center P at the positively charged membrane side, the two liberated electrons head out, according to the Mitchell's Q-cycle mechanism, to different acceptors. One is taken by the [2Fe-2S] iron-sulfur Rieske protein to be passed further to cytochrome c1. The other electron goes across the membrane, via the low- and high-potential hemes of cytochrome b, to another ubiquinone-binding site N at the opposite membrane side. It has been assumed that two ubiquinol molecules have to be oxidized by center P to yield first a semiquinone in center N and then to reduce this semiquinone to ubiquinol. This review is focused on the operation of cytochrome bc1 complexes in phototrophic purple bacteria. Their membranes provide a unique system where the generation of membrane voltage by light-driven, energy-converting enzymes can be traced via spectral shifts of native carotenoids and correlated with the electron and proton transfer reactions. An "activated Q-cycle" is proposed as a novel mechanism that is consistent with the available experimental data on the electron/proton coupling. Under physiological conditions, the dimeric cytochrome bc1 complex is suggested to be continually primed by prompt oxidation of membrane ubiquinol via center N yielding a bound semiquinone in this center and a reduced, high-potential heme b in the other monomer of the enzyme. Then the oxidation of each ubiquinol molecule in center P is followed by ubiquinol formation in center N, proton translocation and generation of membrane voltage.     

Isolation and characterization of QCR9, a nuclear gene encoding the 7.3-kDa subunit 9 of the Saccharomyces cerevisiae ubiquinol-cytochrome c oxidoreductase complex. An intron-containing gene with a conserved sequence occurring in the intron of COX4

A nuclear gene (QCR9) encoding the 7.3-kDa subunit 9 of the mitochondrial cytochrome bc1 complex from Saccharomyces cerevisiae has been isolated from a yeast genomic library by hybridization with a degenerate oligonucleotide corresponding to nine amino acids proximal to the N terminus of purified subunit 9. QCR9 includes a 195-base pair open reading frame capable of encoding a protein of 66 amino acids and having a predicted molecular weight of 7471. The N-terminal methionine of subunit 9 is removed posttranslationally because the N-terminal sequence of the purified protein begins with serine 2. The ATG triplet corresponding to the N-terminal methionine is separated from the open reading frame by an intron. The intron is 213 base pairs long and contains previously reported 5' donor, 3' acceptor, and TACTAAC sequences necessary for splicing. The splice junctions, as well as the 5' end of the message, were confirmed by isolation and sequencing of a cDNA copy of QCR9. In addition, the intron contains a nucleotide sequence in which 15 out of 18 nucleotides are identical with a sequence in the intron of COX4, the nuclear gene encoding cytochrome c oxidase subunit 4. The deduced amino acid sequence of the yeast subunit 9 is 39% identical with that of a protein of similar molecular weight from beef heart cytochrome bc1 complex. If conservative substitutions are allowed for, the two proteins are 56% similar. The predicted secondary structure of the 7.3-kDa protein revealed a single possible transmembrane helix, in which the amino acids conserved between beef heart and yeast are asymmetrically arranged along one face of the helix, implying that this domain of the protein is involved in a conserved interaction with another hydrophobic protein of the cytochrome bc1 complex. Two yeast strains, JDP1 and JDP2, were constructed in which QCR9 was deleted. Both strains grew very poorly, or not at all, on nonfermentable carbon sources and exhibited, at most, only 5% of wild-type ubiquinol-cytochrome c oxidoreductase activity. Optical spectra of mitochondrial membranes from the deletion strains revealed slightly reduced levels of cytochrome b. When JDP1 and JDP2 were complemented with a plasmid carrying QCR9, the resulting yeast grew normally on ethanol/glycerol and exhibited normal cytochrome c reductase activities and optical spectra. These results indicate that QCR9 encodes a 7.3-kDa subunit of the bc1 complex that is required for formation of a fully functional complex.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structure of complex III with bound cytochrome c in reduced state and definition of a minimal core interface for electron transfer

In cellular respiration, cytochrome c transfers electrons from cytochrome bc(1) complex (complex III) to cytochrome c oxidase by transiently binding to the membrane proteins. Here, we report the structure of isoform-1 cytochrome c bound to cytochrome bc(1) complex at 1.9 A resolution in reduced state. The dimer structure is asymmetric. Monovalent cytochrome c binding is correlated with conformational changes of the Rieske head domain and subunit QCR6p and with a higher number of interfacial water molecules bound to cytochrome c(1). Pronounced hydration and a "mobility mismatch" at the interface with disordered charged residues on the cytochrome c side are favorable for transient binding. Within the hydrophobic interface, a minimal core was identified by comparison with the novel structure of the complex with bound isoform-2 cytochrome c. Four core interactions encircle the heme cofactors surrounded by variable interactions. The core interface may be a feature to gain specificity for formation of the reactive complex.