The cytochromec reductase/oxidase respiratory pathway ofParacoccus denitrificans: Genetic and functional studies

Data are presented on three components of the quinol oxidation branch of theParacoccus respiratory chain: cytochromec reductase, cytochromec ₅₅₂, and thea-type terminal oxidase. Deletion mutants in thebc ₁ and theaa ₃ complex give insight into electron pathways, assembly processes, and stability of both redox complexes, and, moreover, are an important prerequisite for future site-directed mutagenesis experiments. In addition, evidence for a role of cytochromec ₅₅₂ in electron transport between complex III and IV is presented.     

Characterization of the bifunctional mitochondrial processing peptidase (MPP)/bc 1 complex inSpinacia oleracea

The mitochondrial general processing peptidase (MPP) in plant mitochondria constitutes an integral part of the cytochromebc ₁ complex of the respiratory chain. Here we present a characterization of this bifunctional complex from spinach leaf mitochondria. The purified MPP/bc ₁ complex has a molecular mass of 550 kDa, which corresponds to a dimer. Increased ionic strength results in partial dissociation of the dimer as well as loss of the processing activity. Micellar concentrations of nonionic and zwitterionic detergents stimulate the activity by decreasing the temperature optimum of the processing reaction, whereas anionic detergents totally suppress the activity. MPP is a metalloendopeptidase. Interestingly, hemin, a potent regulator of mitochondrial and cytosolic biogenesis and inhibitor of proteosomal degradation, inhibits the processing activity. Measurements of the processing activity at different redox states of thebc ₁ complex show that despite bifunctionality of the MPP/bc ₁ complex, there is no correlation between electron transfer and protein processing.     

A clarification of the effects of DCCD on the electron transfer and antimycin binding of the mitochondrialbc 1 complex

We have studied in detail the effects of dicyclohexylcarbodiimide (DCCD) on the redox activity of the mitochondrialbc ₁ complex, and on the binding of its most specific inhibitor antimycin. An inhibitory action of the reagent has been found only at high concentration of the diimide and/or at prolonged times of incubation. Under these conditions, DCCD also displaced antimycin from its specific binding site in thebc ₁ complex, but did not apparently change the antimycin sensitivity of the ubiquinol-cytochromec reductase activity. On the other hand, using lower DCCD concentrations and/or short times of incubation, i.e., conditions which usually lead to the specific inhibition of the proton-translocating activity of thebc ₁ complex, no inhibitory effect of DCCD could be detected in the ubiquinol-cytochromec reductase activity. However, a clear stimulation of the rate of cytochromeb reduction in parallel to an inhibition of cytochromeb oxidation has been found under these conditions. On the basis of the present work and of previous reports in the literature about the effects of DCCD on thebc ₁ complex, we propose a clarification of the various effects of the reagent depending on the experimental conditions employed.     

Thebc 1 complexes ofRhodobacter sphaeroides andRhodobacter capsulatus

Photosynthetic bacteria offer excellent experimental opportunities to explore both the structure and function of the ubiquinol-cytochromec oxidoreductase (bc ₁ complex). In bothRhodobacter sphaeroides andRhodobacter capsulatus, thebc ₁ complex functions in both the aerobic respiratory chain and as an essential component of the photosynthetic electron transport chain. Because thebc ₁ complex in these organisms can be functionally coupled to the photosynthetic reaction center, flash photolysis can be used to study electron flow through the enzyme and to examine the effects of various amino acid substitutions. During the past several years, numerous mutations have been generated in the cytochromeb subunit, in the Rieske iron-sulfur subunit, and in the cytochromec ₁ subunit. Both site-directed and random mutagenesis procedures have been utilized. Studies of these mutations have identified amino acid residues that are metal ligands, as well as those residues that are at or near either the quinol oxidase (Q_o) site or the quinol reductase (Q_i) site. The postulate that these two Q-sites are located on opposite sides of the membrane is supported by these studies. Current research is directed at exploring the details of the catalytic mechanism, the nature of the subunit interactions, and the assembly of this enzyme.     

All-atom molecular dynamics simulations reveal significant differences in interaction between antimycin and conserved amino acid residues in bovine and bacterial bc1 complexes

Antimycin A is the most frequently used specific and powerful inhibitor of the mitochondrial respiratory chain. We used all-atom molecular dynamics (MD) simulations to study the dynamic aspects of the interaction of antimycin A with the Q_i site of the bacterial and bovine bc₁ complexes embedded in a membrane. The MD simulations revealed considerable conformational flexibility of antimycin and significant mobility of antimycin, as a whole, inside the Q_i pocket. We conclude that many of the differences in antimycin binding observed in high-resolution x-ray structures may have a dynamic origin and result from fluctuations of protein and antimycin between multiple conformational states of similar energy separated by low activation barriers, as well as from the mobility of antimycin within the Q_i pocket. The MD simulations also revealed a significant difference in interaction between antimycin and conserved amino acid residues in bovine and bacterial bc₁ complexes. The strong hydrogen bond between antimycin and conserved Asp-228 (bovine numeration) was observed to be frequently broken in the bacterial bc₁ complex and only rarely in the bovine bc₁ complex. In addition, the distances between antimycin and conserved His-201 and Lys-227 were consistently larger in the bacterial bc₁ complex. The observed differences could be responsible for a weaker interaction of antimycin with the bacterial bc₁ complex.     

Cloning by functional complementation, and inactivation, of theSchizosaccharomyces pombe homologue of theSaccharomyces cerevisiae geneABC1

TheSaccharomyces cerevisiae geneABC1 is required for the correct functioning of thebc ₁ complex of the mitochondrial respiratory chain. By functional complementation of aS. cerevisiae abc1 ^– mutant, we have cloned aSchizosaccharomyces pombe cDNA, whose predicted product is 50% identical to the Abc1 protein. Significant homology is also observed with bacterial, nematode, and even human amino acid sequences of unknown function, suggesting that the Abc1 protein is conserved through evolution. The cloned cDNA corresponds to a singleS. pombe geneabc1Sp, located on chromosome II, expression of which is not regulated by the carbon source. Inactivation of theabc1Sp gene by homologous gene replacement causes a respiratory deficiency which is efficiently rescued by the expression of theS. cerevisiae ABC1 gene. The inactivated strain shows a drastic decrease in thebc ₁ complex activity, a decrease in cytochromeaa3 and a slow growth phenotype. To our knowledge, this is the first example of the inactivation of a respiratory gene inS. pombe. Our results highlight the fact thatS. pombe growth is highly dependent upon respiration, and thatS. pombe could represent a valuable model for studying nucleo-mitochondrial interactions in higher eukaryotes.     

The three-subunit cytochromebc 1 complex ofParacoccus denitrificans. Its physiological function,structure, and mechanism of electron transfer and energy transduction

The cytochromebc ₁ complex purified fromP. denitrificans has the same electron-transfer and energy-transducing activities, is sensitive to the same electron-transfer inhibitors, and contains cytochromesb, c ₁, iron-sulfur protein, and thermodynamically stable ubisemiquinone identical to the counterpart complexes from mitochondria. However, the bacterialbc ₁ complex consists of only three proteins, the obligate electron-transfer proteins, while the mitochondrial complexes contain six or more supernumerary poly-peptides, which have no obvious electron-transfer function. TheP. denitrificans complex is a paradigm for thebc ₁ complexes of all gram-negative bacteria. In addition, because of its simple polypeptide composition and apparently minimal damage during isolation, theP. denitrificans bc ₁ complex is an ideal system in which to study structure-function relationships requisite to energy transduction linked to electron transfer.     

Organization and function of cytochromeb and ubiquinone in the cristae membrane of beef heart mitochondria

The arrangement and function of the redox centers of the mammalianbc ₁ complex is described on the basis of structural data derived from amino acid sequence studies and secondary structure predictions and on the basis of functional studies (i.e., EPR data, inhibitor studies, and kinetic experiments). Two ubiquinone reaction centers do exist—a QH₂ oxidation center situated at the outer, cytosolic surface of the cristae membrane (Q₀ center), and a Q reduction center (Q _i center) situated more to the inner surface of the cristae membrane. The Q₀ center is formed by theb-566 domain of cytochromeb, the FeS protein, and maybe an additional small subunit, whereas the Q _i center is formed by theb-562 domain of cytochromeb and presumably the 13.4kDa protein (QP-C). The Q binding proteins are proposed to be protein subunits of the Q reaction centers of various multiprotein complexes. The path of electron flow branches at the Q₀ center, half of the electrons flowing via the high-potential cytochrome chain to oxygen and half of the electrons cycling back into the Q pool via the cytochromeb path connecting the two Q reaction centers. During oxidation of QH₂, 2H⁺ are released to the cytosolic space and during reduction of Q, 2H⁺ are taken up from the matrix side, resulting in a net transport across the membrane of 2H⁺ per e^– flown from QH₂ to cytochromec, the H⁺ being transported across the membrane as H (H⁺ + e^–) by the mobile carrier Q. The authors correct their earlier view of cytochromeb functioning as a H⁺ pump, proposing that the redox-linkedpK changes of the acidic groups of cytochromeb are involved in the protonation/deprotonation processes taking place during the reduction and oxidation of Q. The reviewers stress that cytochromeb is in equilibrium with the Q pool via the Q _i center, but not via the Q₀ center. Their view of the mechanisms taking place at the reductase is a Q cycle linked to a Q-pool where cytochromeb is acting as an electron pump.     

Exogenous Ubiquinol Analogues Affect the Fluorescence of NCD-4 Bound to Aspartate-160 of Yeast Cytochrome b

Previously, we reported that the carboxyl-reacting reagent DCCD, and its fluorescent derivative NCD-4 binds covalently to aspartate-160 localized in amphipathic helix cd of the CD loop connecting membrane-spanning helices C and D of cytochrome b (Wang et al., 1995). We have investigated the fluorescent properties of NCD-4 to probe possible changes in the cd helix resulting from the binding of exogenous ubiquinol analogues to the bc ₁ complex. Preincubation of the bc ₁ complex with the reduced substrate analogues, DQH₂, DBH₂, and Q₆H₂ resulted in 20–40% increase in the fluorescence emission intensity of NCD-4 and a 10–20% increase in the binding of [¹⁴C]DCCD to the bc ₁ complex. By contrast, preincubation with the oxidized analogues DQ, DB, and Q₆ resulted in a 20–40% decrease in the fluorescence emission intensity of NCD-4 and a 20–40% decrease in the binding of [¹⁴C]DCCD to the bc ₁ complex. Moreover, addition of the reduced ubiquinols to the bc ₁ complex preincubated with NCD-4 resulted in a blue shift in the fluorescence emission spectrum. In addition, incubation of the cytochrome bc ₁ complex reconstituted into proteoliposomes with both reduced and oxidized ubiquinol analogues resulted in changes in the quenching of NCD-4 fluorescence by CAT-16, the spin-label probe that intercalates at the membrane surface. These results indicate that the addition of exogenous ubiquinol to the bc ₁ complex may result in changes in the cd helix leading to a more hydrophobic environment surrounding the NCD-4 binding site. By contrast, preincubation with the inhibitors of electron transfer through the bc ₁ complex had no effect on the binding of NCD-4 to the bc ₁ complex or on the fluorescent emission spectra, which suggests that the binding of the inhibitors does not result in changes in the environment of the NCD-4 binding site.     

What information do inhibitors provide about the structure of the hydroquinone oxidation site of ubihydroquinone: Cytochromec oxidoreductase?

The Q cycle mechanism of thebc ₁ complex requires two quinone reaction centers, the hydroquinone oxidation (Q_P) and the quinone reduction (Q_N) center. These sites can be distinguished by the specific binding of inhibitors to either of them. A substantial body of information about the hydroquinone oxidation site has been provided by the analysis of the binding of Q_P site inhibitors to thebc ₁ complex in different redox states and to preparations depleted of lipid or protein components as well as by functional studies with mutantbc ₁ complexes selected for resistance toward the inhibitors. The reaction site is formed by at least five protein segments of cytochromeb and parts of the iron-sulfur protein. At least two different binding sites for Q_P site inhibitors could be detected, one for the methoxyacrylate-type inhibitors binding predominantly to cytochromeb, the other for the chromone-type inhibitors and hydroxyquinones binding predominantly to the iron-sulfur protein. The interactions with the protein segments, between different protein segments, and between protein and ligands (substrate, inhibitors) are discussed in detail and a working model of the Q_P pocket is proposed.     

Decoupling of thebc1 complex inS. cerevisiae; point mutations affecting the cytochromeb gene bring new information about the structural aspect of the proton translocation

Four mutations in the mitochondrial cytochromeb ofS. cerevisiae have been characterized with respect to growth capacities, catalytic properties, ATP/2e ^– ratio, and transmembrane potential. The respiratory-deficient mutant G137E and the three pseudo-wild type revertants E137 + I147F, E137 + C133S, and E137 + N256K were described previously (Tron and Lemesle-Meunier, 1990; Di Ragoet al., 1990a). The mutant G137E is unable to grow on respiratory substrates but its electron transfer activity is partly conserved and totally inhibited by antimycin A. The secondary mutations restore the respiratory growth at variable degree, with a phosphorylation efficiency of 12–42% as regards the parental wild type strain, and result in a slight increase in the various electron transfer activities at the level of the whole respiratory chain. The catalytic efficiency for ubiquinol was slightly (G137E) or not affected (E137 + I147F, E137 + C133S, and E137 + N256K) in these mutants. Mutation G137E induces a decrease in the ATP/2e ^– ratio (50% of the W.T. value) and transmembrane potential (60% of the W.T. value) at thebc1 level, whereas the energetic capacity of the cytochrome oxidase is conserved. Secondary mutations I147F, C133S, and N256K partly restore the ATP/ 2e ^– ratio and the transmembrane potential at thebc1 complex level. The results suggest that a partial decoupling of thebc1 complex is induced by the cytochromeb point mutation G137E. In the framework of the protonmotive Q cycle, this decoupling can be explained by the existence of a proton wire connecting centers P and N in the wild typebc1 complex which may be amplified or uncovered by the G137E mutation when the bc1 complex is functioning.     

Proton/electron stoichiometry of mitochondrialbc 1 complex. Influence of pH and transmembrane δpH

The effect of pH and transmembrane pH on the efficiency of the proton pump of the mitochondrialbc ₁ complex bothin situ and in the reconstituted state was studied. In both cases the H⁺/e ^– ratio for vectorial proton translocation by thebc ₁ complex respiring at the steady state, under conditions in which the transmembrane pH difference (pH) represents the only component of the proton motive force (p), was significantly lower than that measured under level flow conditions. The latter amounts, at neutral pH, to 1 (2 including the scalar H⁺ release). In the reconstituted system steady-state pH was modulated by changing the intravesicular buffer as well as the intra/extra-liposomal pH. Under these conditions the H⁺/e^– ratio varied inversely with the pH. The data presented show that pH exerts a critical control on the proton pump of thebc ₁ complex. Increasing the external pH above neutrality caused a decrease of the level flowH ⁺/e ^– ratio. This effect is explained in terms of proton/electron linkage inb cytochromes.     

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     

Is there sufficient experimental evidence to consider the mitochondrial cytochromebc 1 complex a proton pump? Probably no.

The electron flow through the cytochromebc ₁ complex of the mitochondrial respiratory chain is accompanied by vectorial proton translocation, though the mechanism of the latter phenomenon has not yet been clarified. Several proposed hypotheses are briefly presented and discussed here. Recently, a number of papers have appeared claiming the existence of a proton pump in the enzyme mainly on the basis of the interaction of the complex with N,N-dicyclohexylcarbodiimide. These data are reviewed here with the aim of showing their ability to fit multiple interpretations. This together with some other arguments leads to the conclusion that a proton pump in the mitochondrialbc ₁ complex has not yet been demonstrated.This article is dedicated to the memory of my friend and long-time close collaborator Dr. Robert P. Casey who has passed away after a short, tragic illness at the age of 34.     

The reactions of the oxidase and reductases ofParacoccus denitrificans with cytochromesc

Electron transport in theParacoccus denitrificans respiratory chain system is considerably more rapid when it includes the membrane-bound cytochromec ₅₅₂ than with either solubleParacoccus c ₅₅₀ or bovine cytochromec; a pool function for cytochromec is not necessary. Low concentrations ofParacoccus or bovine cytochromec stimulate the oxidase activity. This observation could explain the multiphasic Scatchard plots which are obtained. A negatively charged area on the back side ofParacoccus c which is not present in mitochondrialc could be a control mechanism forParacoccus reactions.Paracoccus oxidase and reductase reactions with bovinec show the same properties as mammalian systems; and this is true ofParacoccus oxidase reactions with its own soluble cytochromec if added polycation masks the negatively charged area. Evidence for different oxidase and reductase reaction sites on cytochromec include: (1) stimulation of the oxidase but not reductase by a polycation; (2) differences in the inhibition of the oxidase and reductases by monoclonal antibodies toParacoccus cytochromec; and (3) reaction of another bacterial cytochromec withParacoccus reductases but not oxidase. Rapid electron transport occurs in cytochromec-less mutants ofParacoccus, suggesting that the reactions result from collision of diffusing complexes.     

Steady-State Proton Translocation in Bovine Heart Mitochondrial bc 1 Complex Reconstituted into Liposomes

The effect of different anions on the steady-state proton translocation in bovine bc ₁ complex reconstituted in liposomes was studied. The H⁺/e ^– ratio for vectorial proton translocation is at the steady state definitely lower than that measured at level flow, (0.3 vs. 1.0). The presence of azide or arachidonate at micro- and submicromolar concentrations, respectively, gave a substantial reactivation of the proton pumping activity at the steady state, without any appreciable effect on respiration-dependent transmembrane pH difference. Addition of azide to turning-over bc ₁ vesicles also caused a transition of b cytochromes toward oxidation. The results are discussed in terms of possible involvement of an acidic residue in the protonation of the semiquinone/quinol couple at the N side of the membrane.     

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.     

Integration of the Mitochondrial-Processing Peptidase into the Cytochrome bc 1 Complex in Plants

The plant mitochondrial cytochrome bc ₁ complex, like nonplant mitochondrial complexes,consists of cytochromes b and c ₁, the Rieske iron–sulfur protein, two Core proteins, and fivelow-molecular mass subunits. However, in contrast to nonplant sources, the two Core proteinsare identical to subunits of the general mitochondrial processing peptidase (MPP). The MPPis a fascinating enzyme that catalyzes the specific cleavage of the diverse presequence peptidesfrom hundreds of the nuclear-encoded mitochondrial precursor proteins that are synthesizedin the cytosol and imported into the mitochondrion. Integration of the MPP into the bc ₁complex renders the bc ₁ complex in plants bifunctional, being involved both in electrontransport and in protein processing. Despite the integration of MPP into the bc ₁ complex,electron transfer as well as translocation of the precursor through the import channel areindependent of the protein-processing activity. Recognition of the processing site by MPPoccurs via the recognition of higher-order structural elements in combination with charge andcleavage-site properties. Elucidation of the three-dimensional (3-D) structure of the mammaliancytochrome bc ₁ complex is highly useful for understanding of the mechanism of action of MPP.In memory of my teacher—an insightful, devoted, and enthusiastic scientist and an amiable and kind-hearted human being—Lars Ernster     

Assembly of Deletion Mutants of the Rieske Iron–Sulfur Protein into the Cytochrome bc 1 Complex of Yeast Mitochondria

The assembly of two deletion mutants of the Rieske iron-sulfur protein into the cytochrome bc ₁ complex was investigated after import in vitro into mitochondria isolated from a strain of yeast, JPJ1, from which the iron-sulfur protein gene (RIP) had been deleted. The assembly process was investigated by immunoprecipitation of the labeled iron-sulfur protein or the two deletion mutants from detergent-solubilized mitochondria with specific antisera against either the iron-sulfur protein or the bc ₁ complex (complex III) [Fu and Beattie (1991). J. Biol. Chem. 266, 16212–16218]. The deletion mutants lacking amino acid residues 55–66 or residues 161–180 were imported into mitochondria in vitro and processed to the mature form via an intermediate form. After import in vitro, the protein lacking residues 161–180 was not assembled into the complex, suggesting that the region of the iron-sulfur protein containing these residues may be involved in the assembly of the protein into the bc ₁ complex; however, the protein lacking residues 55–66 was assembled in vitro into the bc ₁ complex as effectively as the wild type iron-sulfur protein. Moreover, this mutant protein was present in the mitochondrial membrane fraction obtained from JPJ1 cells transformed with a single-copy plasmid containing the gene for this protein lacking residues 55–66. This deletion mutant protein was also assembled into the bc ₁ complex in vivo, suggesting that the hydrophobic stretch of amino acids, residues 55–66, is not required for assembly of the iron-sulfur protein into the bc ₁ complex; however, this association did not lead to enzymatic activity of the bc ₁ complex, as the Rieske FeS cluster was not epr detectable in these mitochondria.     

Reaction center and UQH2:cytc 2 oxidoreductase act as independent enzymes inRps. sphaeroides

Turnover of the ubiquinol oxidizing site of the UQH₂:cyt c₂ oxidoreductase (b/c ₁ complex) ofRps. sphaeroides can be assayed by measuring the rate of reduction of cytb ₅₆₁ in the presence of antimycin (AA). Oxidation of ubiquinol is a second-order process, with a value ofk ₂ of about 3 × 10⁵ M^–1. The reaction shows saturation at high quinol concentrations, with an apparentK _m of about 6–8 mM (with respect to the concentration of quinol in the membrane). When the quinone pool is oxidized before illumination, reduction of the complex shows a substantial lag (about 1 ms) after a flash, indicating that the quinol produced as a result of the photochemical reactions is not immediately available to the complex. We have suggested that the lag may be due to several factors, including the leaving time of the quinol from the reaction center, the diffusion time to the complex, and the time for the head group to cross the membrane. We have suggested aminimal value for the diffusion coefficient of ubiquinone in the membrane (assuming that the lag is due entirely to diffusion) of about 10^–9 cm^–2 sec^–1. The lag is reduced to about 100 µsec when the pool is significantly reduced, showing that quinol from the pool is more rapidly available to the complex than that from the reaction center. With the pool oxidized, similar kinetics are seen when the reduction of cytb ₅₆₁ occurs through the AA-sensitive site (with reactions at the quinol oxidizing site blocked by myxothiazol). These results show that there is no preferential reaction pathway for transfer of reducing equivalents from reaction center tob/c ₁ complex. Oxidation of cytb ₅₆₁ through the AA-sensitive site can be assayed from the slow phase of the carotenoid electrochromic change, and by comparison with the kinetics of cytb ₅₆₁. As long as the quinone pool is significantly oxidized, the reaction is not rate-determining for the electrogenic process. On reduction of the pool below 1 quinone per complex, a slowing of the electrogenic process occurs, which could reflect a dependence on the concentration of quinone. If the process is second-order, the rate constant must be about 2–5 times greater than that for quinol oxidation, since the effect on rate is relatively small compared with the effect seen at the quinol oxidizing site when the quinol concentration is changed over theE _h range where the first few quinols are produced on reductive titration. When the quinone pool is extracted (experiments in collaboration with G. Venturoli and B. A. Melandri), the slowing of the electrochromic change on reduction of the pool is not enhanced; we assume that this is due to the fact that a minimum of one quinone per active complex is produced by turnover of the quinol oxidizing site. Two lines of research lead us to revise our previous estimate for the minimal value of the quinone diffusion coefficient. These relate to the relation between the diffusion coefficient and the rate constants for processes involving the quinones: (a) The estimated rate constant for reaction of quinone at the AA-site approaches the calculated diffusion limited rate constant, implying an improbably efficient reaction. (b) From a preliminary set of experiments, the activation energy determined by measuring the variation of the rate constant for quinol oxidation with temperature, is about 8 kcal mol^–1. Although we do not know the contribution of entropic terms to the pre-exponential factor, the result is consistent with a considerably larger value for the diffusion coefficient than that previously suggested.