The role of the membrane bound cytochromes of b- and c-type in the electron transport chain of Rhodobacter capsulatus

(1) The electron transport system of heterotrophically dark-grown Rhodobacter capsulatus was investigated using the wild-type strain MT1131 and the phototrophic non-competent (Ps^-) mutant MT-GS18 carrying deletions of the genes for cytochrome c ₁ and b of the bc ₁ complex and for cytochrome c ₂. (2) Spectroscopic and thermodynamic data demonstrate that deletion of both bc ₁ complex and cyt. c ₂ still leaves several haems of c- and b-type with Em_7.0 of +265 mV and +354 mV at 551–542 nm, and +415 mV and +275 mV at 561–575 nm, respectively. (3) Analysis of the oxidoreduction kinetic patterns of cytochromes indicated that cyt. b ₄₁₅ and cyt. b ₂₇₅ are reduced by either ascorbate-diaminodurene or NADH, respectively. (4) Growth on different carbon and nitrogen sources revealed that the membrane-bound electron transport chain of both MT1131 and MT-GS18 strains undergoes functional modifications in response to the composition of the growth medium used. (5) Excitation of membrane fragments from cells grown in malate minimal medium by a train of single turnover flashes of light led to a rapid oxidation of 32% of the membrane-bound c-type haem complement. Conversely, membranes prepared from peptone/yeast extract grown cells did not show cyt. c photooxidation. These results are discussed within the framework of an electron transport chain in which alternative pathways bypassing both the cyt. c ₂ and bc ₁ complex might involve high-potential membrane bound haems of b- and c-type.Abbreviations AA antimycin A - CCCP carbonylcyanide m-chlorophenyl hydrazone - CN^- cyanide - DAD diaminodurene - Q₂H₂ ubiquinol-2 - Q-pool ubiquinone-10 pool - RC photochemical reaction center     

Structural Basis of Multifunctional Bovine Mitochondrial Cytochrome bc 1 Complex

The mitochondrial cytochrome bc ₁ complex is a multifunctional membrane protein complex. Itcatalyzes electron transfer, proton translocation, peptide processing, and superoxide generation.Crystal structure data at 2.9 Å resolution not only establishes the location of the redox centersand inhibitor binding sites, but also suggests a movement of the head domain of the iron–sulfurprotein (ISP) during bc ₁ catalysis and inhibition of peptide-processing activity during complexmaturation. The functional importance of the movement of extramembrane (head) domain ofISP in the bc ₁ complex is confirmed by analysis of the Rhodobacter sphaeroides bc ₁ complexmutants with increased rigidity in the ISP neck and by the determination of rate constants foracid/base-induced intramolecular electron transfer between [2Fe–2S] and heme c ₁ in nativeand inhibitor-loaded beef complexes. The peptide-processing activity is activated in bovineheart mitochondrial bc ₁ complex by nonionic detergent at concentrations that inactivate electrontransfer activity. This peptide-processing activity is shown to be associated with subunits Iand II by cloning, overexpression and in vitro reconstitution. The superoxide-generation siteof the cytochrome bc ₁ complex is located at reduced b _L and Q^–. The reaction is membranepotential-, and cytochrome c-dependent.     

Electron donation from membrane-bound cytochrome c to the photosynthetic reaction center in whole cells and isolated membranes of Heliobacterium gestii

The reaction between membrane-bound cytochrome c and the reaction center bacteriochlorophyll g dimer P798 was studied in the whole cells and isolated membranes of Heliobacterium gestii. In the whole cells, the flash-oxidized P798⁺ was rereduced in multiple exponential phases with half times (t _1/2s) of 10 s, 300 s and 4 ms in relative amplitudes of 40, 35 and 25%, respectively. The faster two phases were in parallel with the oxidation of cytochrome c. In isolated membranes, a significantly slow oxidation of the membrane-bound cytochrome c was detected with t _1/2 = 3 ms. This slow rate, however, again became faster with the addition of Mg²⁺. The rate showed a high temperature dependency giving apparent activation energies of 88.2 and 58.9 kJ/mol in the whole cells and isolated membranes, respectively. Therefore, membrane-bound cytochrome c donates electrons to the P798⁺ in a collisional reaction mode like the reaction of water-soluble proteins. The rereduction of the oxidized cytochrome c was suppressed by the addition of stigmatellin both in the whole cells and isolated membranes. This indicates that the electron transfer from the cytochrome bc complex to the photooxidized P798⁺ is mediated by the membrane-bound cytochrome c. The multiple flash excitation study showed that 2–3 hemes c were connected to the P798. By the heme staining after the SDS-PAGE analysis of the membraneous proteins, two cytochromes c were detected on the gel indicating apparent molecular masses of 17 and 30 kDa, respectively. The situation resembles the case in green sulfur bacteria, that is, the membrane-bound cyotochrome c _z couples electron transfer between the cytochrome bc complex and the P840 reaction center complex.This revised version was published online in October 2005 with corrections to the Cover Date.     

Role of phospholipids in respiratory cytochrome bc1 complex catalysis and supercomplex formation

Specific protein-lipid interactions have been identified in X-ray structures of membrane proteins. The role of specifically bound lipid molecules in protein function remains elusive. In the current study, we investigated how phospholipids influence catalytic, spectral and electrochemical properties of the yeast respiratory cytochrome bc₁ complex and how disruption of a specific cardiolipin binding site in cytochrome c₁ alters respiratory supercomplex formation in mitochondrial membranes. Purified yeast cytochrome bc₁ complex was treated with phospholipase A₂. The lipid-depleted enzyme was stable but nearly catalytically inactive. The absorption maxima of the reduced b-hemes were blue-shifted. The midpoint potentials of the b-hemes of the delipidated complex were shifted from − 52 to − 82 mV (heme b_L) and from + 113 to − 2 mV (heme b_H). These alterations could be reversed by reconstitution of the delipidated enzyme with a mixture of asolectin and cardiolipin, whereas addition of the single components could not reverse the alterations. We further analyzed the role of a specific cardiolipin binding site (CL_i) in supercomplex formation by site-directed mutagenesis and BN-PAGE. The results suggested that cardiolipin stabilizes respiratory supercomplex formation by neutralizing the charges of lysine residues in the vicinity of the presumed interaction domain between cytochrome bc₁ complex and cytochrome c oxidase. Overall, the study supports the idea, that enzyme-bound phospholipids can play an important role in the regulation of protein function and protein-protein interaction.     

Isolation of cytochrome bc 1 complexes from the photosynthetic bacteria Rhodopseudomonas viridis and Rhodospirillum rubrum

Cytochrome bc ₁ complexes have been isolated from wild type Rhodopseudomonas viridis and Rhodospirillum rubrum and purified by affinity chromatography on cytochrome c-Sepharose 4B. Both complexes are largely free of bacteriochlorophyll and carotenoids and contain cytochromes b and c ₁ in a 2:1 molar ratio. For the Rps. viridis complex, evidence has been obtained for two spectrally distinct b-cytochromes. The R. rubrum complex contains a Rieske iron-sulfur protein (present in approximately 1:1 molar ratio to cytochrome c ₁) and catalyzes an antimycin A- and myxothiazol-sensitive electron transfer from duroquinol to equine cytochrome c or R. rubrum cytochrome c ₂. Although an attempt to prepare a cytochrome bc ₁ complex from the gliding green bacterium Chloroflexus aurantiacus was not successful, membranes isolated from phototrophically grown Cfl. aurantiacus were shown to contain a Rieske iron-sulfur protein and protoheme (the prosthetic group of b-type cytochromes).Dedicated to Prof. L.N.M. Duysens on the occasion of his retirement.     

Formation of engineered intersubunit disulfide bond in cytochrome bc1 complex disrupts electron transfer activity in the complex

Protein domain movement of the Rieske iron-sulfur protein has been speculated to play an essential role in the bifurcated oxidation of ubiquinol catalyzed by the cytochrome bc₁ complex. To better understand the electron transfer mechanism of the bifurcated ubiquinol oxidation at Qp site, we fixed the head domain of ISP at the cyt c₁ position by creating an intersubunit disulfide bond between two genetically engineered cysteine residues: one at position 141 of ISP and the other at position 180 of the cyt c₁ [S141C(ISP)/G180C(cyt c₁)]. The formation of a disulfide bond between ISP and cyt c₁ in this mutant complex is confirmed by SDS-PAGE and Western blot. In this mutant complex, the disulfide bond formation is concurrent with the loss of the electron transfer activity of the complex. When the disulfide bond is released by treatment with β-mercaptoethanol, the activity is restored. These results further support the hypothesis that the mobility of the head domain of ISP is functionally important in the cytochrome bc₁ complex. Formation of the disulfide bond between ISP and cyt c₁ shortens the distance between the [2Fe-2S] cluster and heme c₁, hence the rate of intersubunit electron transfer between these two redox prosthetic groups induced by pH change is increased. The intersubunit disulfide bond formation also decreases the rate of stigmatellin induced reduction of ISP in the fully oxidized complex, suggesting that an endogenous electron donor comes from the vicinity of the b position in the cytochrome b.     

Evidence that energy conserving electron transport pathways to nitrate and cytochrome o branch at ubiquinone in Paracoccus denitrificans

The organisation and function of electron transport pathways in Paracoccus denitrificans has been studied with both inhibitors and electrode probes for O₂ or N₂O respiration and membrane potential. Myxothiazol completely inhibits electron flow through the cytochrome bc₁ region of the electron transport chain, as judged by its effect on nitrous oxide respiration. Electron flow to oxygen via the cytochrome o oxidase was shown to be insensitive to myxothiazol in a mutant, HUUG 25, that lacks cytochrome c and in which the aa₃ oxidase is therefore inactive. Myxothiazol did not inhibit nitrate reduction. It is concluded that myxothiazol is a specific inhibitor of electron flow through the cytochrome bc₁ region and more potent than antimycin which does not give complete inhibition.As neither antimycin nor myxothiazol, nor a combination of the two, inhibits electron transport to either nitrate reductase or cytochrome o it is concluded that electron transport pathways to these enzymes do not involve the cytochrome bc₁ region but rather branch at the level of ubiquinone. Although the cytochrome o pathway branches at ubiquinone, it is associated with the generation of a protonmotive force; this is shown by measurements of membrane potential in vesicle preparations from the mutant HUUG 25.In contrast to antimycin and myxothiazol, the ubiquinone analogues 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT) and 2-n-undecyl-3-hydroxy-1,4-naphthoquinone (UHNQ) inhibit electron flow through both the cytochrome bc₁ complex and the cytochrome o pathway, although a higher titre is required in the latter case. These two inhibitors were without effect on the nitrate reductase pathway. Thus myxothiazol is the inhibitor of choice for selective and complete inhibition of cytochrome bc₁.Recently published schemes for electron transport in P. denitrificans are analysed.Non standard abbreviations S-13 2,5-dichloro-3-t-butyl-4-nitrososalicylanilide - UHNQ 2-n-undecyl-3-hydroxy-1,4-naphthoquinone - UHDBT 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole     

Identification of a cytochrome bc1-aa3 supercomplex in Rhodobacter sphaeroides

Respiration is carried out by a series of membrane-bound complexes in the inner mitochondrial membrane or in the cytoplasmic membrane of bacteria. Increasing evidence shows that these complexes organize into larger supercomplexes. In this work, we identified a supercomplex composed of cytochrome (cyt.) bc₁ and aa₃-type cyt. c oxidase in Rhodobacter sphaeroides. We purified the supercomplex using a His-tag on either of these complexes. The results from activity assays, native and denaturing PAGE, size exclusion chromatography, electron microscopy, optical absorption spectroscopy and kinetic studies on the purified samples support the formation and coupled quinol oxidation:O₂ reduction activity of the cyt. bc₁-aa₃ supercomplex. The potential role of the membrane-anchored cyt. c_y as a component in supercomplexes was also investigated.     

The role of c-type cytochromes in the photosynthetic electron transport pathway of Rhodobacter capsulatus

(1) Short flash excitation of membrane vesicles of a cytochrome-c2-deficient mutant of Rhodobacter capsulatus (strain MT-G4/S4) led to rapid oxidation of a c-type cytochrome. In redox titrations, the photooxidation of c-type cytochrome was attenuated with a midpoint of approx. +360 mV. Vesicles from a control strain, MT1131, gave similar results. These findings are consistent with those of Prince et al. (Prince, R.C., Davidson, E., Haith, L.E. and Daldal, F. (1986) Biochemistry 25, 5208-5214). (2) In anaerobic intact cells the extent of rapid re-reduction of c-type cytochrome oxidised after a flash was less in MT-G/S4 than in MT1131. Cytochrome c reduction in both strains was inhibited by myxothiazol. The myxothiazol-sensitive component of the electrochromic absorbance change in cells indicated that rapid charge separation through the cytochrome bc1 complex was less extensive after a flash in MT-G4/S4 than in MT 1131. (3) In anaerobic intact cells and in chromatophores of Rb. capsulatus strain MT-GS18, a mutant deficient in both cytochrome c1 and cytochrome c2, flash excitation led to the oxidation of c-type cytochrome. Redox titrations and spectra of chromatophores suggested that this is the same cytochrome as was photooxidized in vesicles of MT-G4/S4 and MT1131. This result is in contrast with earlier findings (Prince, R.C. and Daldal, F. (1987) Biochim. Biophys, Acta 894, 370-378) in which it was reported that no photooxidation of c-type cytochrome occurred in the absence of c1 and c2, and argues against the possibility that cytochrome c1 can rapidly and directly donate electrons to the reaction centre. (4) It is proposed that a previously uncharacterized, membrane-bound c-type cytochrome (Em7 approximately +360 mV) is present in Rb-capsulatus MT1131, in the c2-deficient mutant MT-G4/34 and in the c1/c2-deficient mutant MTGS18. This cytochrome and cytochrome c2 are alternative electron donors to the reaction centre in strain MT1131.     

Generation,characterization and crystallization of a cytochrome c1-subunit IV fused cytochrome bc1 complex from Rhodobacter sphaeroides

Cytochrome bc₁ complex catalyzes the reaction of electron transfer from ubiquinol to cytochrome c (or cytochrome c₂) and couples this reaction to proton translocation across the membrane. Crystallization of the Rhodobacter sphaeroides bc₁ complex resulted in crystals containing only three core subunits. To mitigate the problem of subunit IV being dissociated from the three-subunit core complex during crystallization, we recently engineered an R. sphaeroides mutant in which the N-terminus of subunit IV was fused to the C-terminus of cytochrome c₁ with a 14-glycine linker between the two fusing subunits, and a 6-histidine tag at the C-terminus of subunit IV (c₁-14Gly-IV-6His). The purified fusion mutant complex shows higher electron transfer activity, more structural stability, and less superoxide generation as compared to the wild-type enzyme. Preliminary crystallization attempts with this mutant complex yielded crystals containing four subunits and diffracting X-rays to 5.5 Å resolution.     

Conformational Change of the Rieske [2Fe–2S] Protein inCytochrome bc 1 Complex

Structures of mitochondrial bc ₁ complex have been reported based on four different crystalforms by three different groups. In these structures, the extrinsic domain of the Rieske [2Fe–2S]protein, surprisingly, appeared at three different positions: the c ₁ position, where the [2Fe–2S]cluster exists in close proximity to the heme c ₁; the b position, where the [2Fe–2S] clusterexist in close proximity to the cytochrome b; and the intermediate position where the[2Fe–2S] cluster exists in between c ₁ and b positions. The conformational changes betweenthese three positions can be explained by a combination of two rotations; (1) a rotation of theentire extrinsic domain and (2) a relative rotation between the cluster-binding fold and thebase fold within the extrinsic domain. The hydroquinone oxidation and the electron bifurcationmechanism at the Q_P binding pocket of the bc ₁ complex is well explained using theseconformational changes of the Rieske [2Fe–2S] protein.     

Molecular modeling studies of the DCCD-treated cytochrome bc1 complex: predicted conformational changes and inhibition of proton translocation

Dicyclohexylcarbodiimide (DCCD) binds covalently to an acidic amino acid located in the cd loop connecting membrane-spanning helices C and D of cytochrome b resulting in an inhibition of proton translocation in the cytochrome bc ₁ complex with minimal effects on the steady state rate of electron transfer. Single turnover studies performed with the yeast cytochrome bc ₁ complex indicated that the initial phase of cytochrome b reduction was inhibited 25–45% in the DCCD-treated cytochrome bc ₁ complex, while the rate of cytochrome c ₁ reduction was unaffected. Simulations by molecular modeling predict that binding of DCCD to glutamate 163 located in the cd2 loop of cytochrome b of chicken liver mitochondria results in major conformational changes in the protein. The conformation of the cd loop and the end of helix C appeared twisted with a concomitant rearrangement of the amino acid residues of both cd1 and cd2 loops. The predicted rearrangement of the amino acid residues of the cd loop results in disruptions of the hydrogen bonds predicted to form between amino acid residues of the cd and ef loops. Simultaneously, two new hydrogen bonds are predicted to form between glutamate 272 and two residues, aspartate 253 and tyrosine 272. Formation of these new hydrogen bonds would restrict the rotation and protonation of glutamate 272, which may be necessary for the release of the second electrogenic proton obtained during ubiquinol oxidation in the bc₁ complex.     

Discovery and characterization of electron transfer proteins in the photosynthetic bacteria

Research on photosynthetic electron transfer closely parallels that of other electron transfer pathways and in many cases they overlap. Thus, the first bacterial cytochrome to be characterized, called cytochrome c ₂, is commonly found in non-sulfur purple photosynthetic bacteria and is a close homolog of mitochondrial cytochrome c. The cytochrome bc ₁ complex is an integral part of photosynthetic electron transfer yet, like cytochrome c ₂, was first recognized as a respiratory component. Cytochromes c ₂ mediate electron transfer between the cytochrome bc ₁ complex and photosynthetic reaction centers and cytochrome a-type oxidases. Not all photosynthetic bacteria contain cytochrome c ₂; instead it is thought that HiPIP, auracyanin, Halorhodospira cytochrome c551, Chlorobium cytochrome c555, and cytochrome c ₈ may function in a similar manner as photosynthetic electron carriers between the cytochrome bc ₁ complex and reaction centers. More often than not, the soluble or periplasmic mediators do not interact directly with the reaction center bacteriochlorophyll, but require the presence of membrane-bound intermediates: a tetraheme cytochrome c in purple bacteria and a monoheme cytochrome c in green bacteria. Cyclic electron transfer in photosynthesis requires that the redox potential of the system be delicately poised for optimum efficiency. In fact, lack of redox poise may be one of the defects in the aerobic phototrophic bacteria. Thus, large concentrations of cytochromes c ₂ and c′ may additionally poise the redox potential of the cyclic photosystem of purple bacteria. Other cytochromes, such as flavocytochrome c (FCSD or SoxEF) and cytochrome c551 (SoxA), may feed electrons from sulfide, sulfur, and thiosulfate into the photosynthetic pathways via the same soluble carriers as are part of the cyclic system. This revised version was published online in August 2006 with corrections to the Cover Date.     

Role of the Rieske Iron–Sulfur Protein Midpoint Potential in the Protonmotive Q-Cycle Mechanism of the Cytochrome bc 1 Complex

The midpoint potential of the [2Fe–2S] cluster of the Rieske iron–sulfurprotein (E _{m 7} = +280mV) is the primary determinant of the rate of electron transfer from ubiquinol to cytochromec catalyzed by the cytochrome bc ₁ complex. As the midpoint potential of the Rieske clusteris lowered by altering the electronic environment surrounding the cluster, theubiquinol-cytochrome c reductase activity of the bc ₁ complex decreases; between 220 and 280 mV therate changes 2.5-fold. The midpoint potential of the Rieske cluster also affects thepresteady-state kinetics of cytochrome b and c ₁ reduction. When the midpoint potential of the Rieskecluster is more positive than that of the heme of cytochrome c ₁, reduction of cytochrome bis biphasic. The fast phase of b reduction is linked to the optically invisible reduction of theRieske center, while the rate of the second, slow phase matches that of c ₁ reduction. The ratesof b and c ₁ reduction become slower as the potential of the Rieske cluster decreases andchange from biphasic to monophasic as the Rieske potential approaches that of theubiquinone/ubiquinol couple. Reduction of b and c ₁ remain kinetically linked as the midpoint potentialof the Rieske cluster is varied by 180 mV and under conditions where the presteady statereduction is biphasic or monophasic. The persistent linkage of the rates of b and c ₁ reduction isaccounted for by the bifurcated oxidation of ubiquinol that is unique to the Q-cycle mechanism.     

Comparison of the Cytochrome bc 1 Complex with theAnticipated Structure of the Cytochrome b 6 f Complex:De Plus Ça Change de Plus C'est la Même Chose

Structural alignment of the integral cytochrome b ₆-SU IV subunits with the solved structure of themitochondrial bc ₁ complex shows a pronounced asymmetry. There is a much higher homology onthe p-side of the membrane, suggesting a similarity in the mechanisms of intramembrane andinterfacial electron and proton transfer on the p-side, but not necessarily on the n-side. Structuraldifferences between the bc ₁ and b ₆ f complexes appear to be larger the farther the domain or subunitis removed from the membrane core, with extreme differences between cytochromes c ₁ and f. Aspecial role for the dimer may involve electron sharing between the two hemes b _p, which is indicatedas a probable event by calculations of relative rate constants for intramonomer heme b _p hemeb _n, or intermonomer heme b _p heme b _p electron transfer. The long-standing observation offlash-induced oxidation of only 0.5 of the chemical content of cyt f may be partly a consequence ofthe statistical population of ISP bound to cyt f on the dimer. It is proposed that the p-side domainof cyt f is positioned with its long axis parallel to the membrane surface in order to: (i) allow itslarge and small domains to carry out the functions of cyt c ₁ and suVIII, respectively, of the bc ₁complex, and (ii) provide maximum dielectric continuity with the membrane. (iii) This positionwould also allow the internal water chain (proton wire) of cyt f to serve as the p-side exit portfor an intramembrane H⁺ transfer chain that would deprotonate the semiquinol located in themyxothiazol/MOA-stilbene pocket near heme b _p. A hypothesis is presented for the identity of theamino acid residues in this chain.     

Kinetics of electron transfer between soluble cytochrome c-554 and purified reaction center complex from the green sulfur bacterium Chlorobium tepidum

Soluble cytochrome c-554 (M _r 10 kDa) is purified from the green sulfur bacterium Chlorobium tepidum. Its midpoint redox potential is determined to be +148 mV from redox titration at pH 7.0. The kinetics of cytochrome c-554 oxidation by a purified reaction center complex from the same organism were studied by flash absorption spectroscopy at room temperature, and the results indicate that the reaction partner of cytochrome c-554 is cytochrome c-551 bound to the reaction center rather than the primary donor P840. The second-order rate constant for the electron donation from cytochrome c-554 to cytochrome c-551 was estimated to be 1.7×10⁷ M^–1 s^–1. The reaction rate was not significantly influenced by the ionic strength of the reaction medium.This revised version was published online in October 2005 with corrections to the Cover Date.     

The pet operon,encoding the prosthetic group-containing subunits of the cytochrome bc1 complex,of the purple sulfur bacterium Chromatium vinosum

The pet operon, encoding the prosthetic group-containing subunits of the cytochrome bc ₁ complex of the purple sulfur bacterium Chromatium vinosum, has been cloned and sequenced. The 5 to 3 order of the C. vinosum genes is: petA, encoding the Rieske iron-sulfur protein; petB, encoding cytochrome b; and petC, encoding cytochrome c₁. Cytochrome b is the best conserved subunit of the C. vinosum complex, when compared to the corresponding proteins from four photosynthetic purple non-sulfur bacteria (70 to 74% identity). Identities for the C. vinosum Rieske protein and those from purple non-sulfur bacteria range from 60 to 64%. The C-terminal region of the C. vinosum Rieske protein is quite similar to those of purple non-sulfur bacteria, while the N-terminal region is more closely related to mitochondrial Rieske proteins of organisms such as Neurospora crassa. Cytochrome c₁ is the least well-conserved protein of the C. vinosum cytochrome bc₁ complex, with identities ranging from 49 to 51% when compared to the corresponding proteins from purple non-sulfur bacteria. A well-conserved negatively-charged region of the cytochromes c₁ of the purple non-sulfur bacteria, thought to be involved in binding the electron acceptor for the complex, cytochrome c₂, is absent in C. vinosum cytochrome c₁. A positive Southern hybridization using a probe constructed from the Rhodobacter sphaeroides fbcQ gene, which codes for a fourth subunit of the cytochrome bc₁ complex in that bacterium, suggests the presence of a homologous gene in C. vinosum.     

Cytochrome c1 exhibits two binding sites for cytochrome c in plants

In plants, channeling of cytochrome c molecules between complexes III and IV has been purported to shuttle electrons within the supercomplexes instead of carrying electrons by random diffusion across the intermembrane bulk phase. However, the mode plant cytochrome c behaves inside a supercomplex such as the respirasome, formed by complexes I, III and IV, remains obscure from a structural point of view. Here, we report ab-initio Brownian dynamics calculations and nuclear magnetic resonance-driven docking computations showing two binding sites for plant cytochrome c at the head soluble domain of plant cytochrome c₁, namely a non-productive (or distal) site with a long heme-to-heme distance and a functional (or proximal) site with the two heme groups close enough as to allow electron transfer. As inferred from isothermal titration calorimetry experiments, the two binding sites exhibit different equilibrium dissociation constants, for both reduced and oxidized species, that are all within the micromolar range, thus revealing the transient nature of such a respiratory complex. Although the docking of cytochrome c at the distal site occurs at the interface between cytochrome c₁ and the Rieske subunit, it is fully compatible with the complex III structure. In our model, the extra distal site in complex III could indeed facilitate the functional cytochrome c channeling towards complex IV by building a “floating boat bridge” of cytochrome c molecules (between complexes III and IV) in plant respirasome.     

Spectral analysis of the bc1 complex components in situ: Beyond the traditional difference approach

The cytochrome (cyt) bc₁ complex (ubiquinol: cytochrome c oxidoreductase) is the central enzyme of mitochondrial and bacterial electron-transport chains. It is rich in prosthetic groups, many of which have significant but overlapping absorption bands in the visible spectrum. The kinetics of the cytochrome components of the bc₁ complex are traditionally followed by using the difference of absorbance changes at two or more different wavelengths. This difference-wavelength (DW) approach has been used extensively in the development and testing of the Q-cycle mechanism of the bc₁ complex in Rhodobacter sphaeroides chromatophores. However, the DW approach does not fully compensate for spectral interference from other components, which can significantly distort both amplitudes and kinetics. Mechanistic elaboration of cyt bc₁ turnover requires an approach that overcomes this limitation. Here, we compare the traditional DW approach to a least squares (LS) analysis of electron transport, based on newly determined difference spectra of all individual components of cyclic electron transport in chromatophores. Multiple sets of kinetic traces, measured at different wavelengths in the absence and presence of specific inhibitors, were analyzed by both LS and DW approaches. Comparison of the two methods showed that the DW approach did not adequately correct for the spectral overlap among the components, and was generally unreliable when amplitude changes for a component of interest were small. In particular, it was unable to correct for extraneous contributions to the amplitudes and kinetics of cyt b_L. From LS analysis of the chromophoric components (RC, c_tot, b_H and b_L), we show that while the Q-cycle model remains firmly grounded, quantitative reevaluation of rates, amplitudes, delays, etc., of individual components is necessary. We conclude that further exploration of mechanisms of the bc₁ complex, will require LS deconvolution for reliable measurement of the kinetics of individual components of the complex in situ.