Identification of a stable ubisemiquinone and characterization of the effects of ubiquinone oxidation-reduction status on the Rieske iron-sulfur protein in the three-subunit ubiquinol-cytochrome c oxidoreductase complex of Paracoccus denitrificans

Fundamentals of the modern theory of the phenomenon of "pain" from the perspective of a systematic approach. Neurophysiological basis. Part 1: A brief presentation of key subcellular and cellular ctructural elements of the central nervous system

The phenomenon of “pain” is a psychophysiological phenomenon that is actualized in the mind of a person as a result of the systemic response of his body to certain external and internal stimuli. The heart of the corresponding mental processes is certain neurophysiological processes, which in turn are caused by a certain form of the systemic structural and functional organization of the central nervous system (CNS). Thus, the systemic structural and functional organization of the central nervous system of a person, determining the corresponding psychophysiological state in a specific time interval, determines its psycho-emotional states or reactions manifested by the pain phenomenon. The nervous system of the human body has a hierarchical structure and is a morphologically and functionally complete set of different, interconnected, nervous and structural formations. The basis of the structural formations of the nervous system is nervous tissue. It is a system of interconnected differentials of nerve cells, neuroglia and glial macrophages, providing specific functions of perception of stimulation, excitation, generation of nerve impulses and its transmission. The neuron and each of its compartments (spines, dendrites, catfish, axon) is an autonomous, plastic, active, structural formation with complex computational properties. One of them – dendrites – plays a key role in the integration and processing of information. Dendrites, due to their morphology, provide neurons with unique electrical and plastic properties and cause variations in their computational properties. The morphology of dendrites: 1) determines – a) the number and type of contacts that a particular neuron can form with other neurons; b) the complexity, diversity of its functions; c) its computational operations; 2) determines – a) variations in the computational properties of a neuron (variations of the discharges between bursts and regular forms of pulsation); b) back distribution of action potentials. Dendritic spines can form synaptic connection – one of the main factors for increasing the diversity of forms of synaptic connections of neurons. Their volume and shape can change over a short period of time, and they can rotate in space, appear and disappear by themselves. Spines play a key role in selectively changing the strength of synaptic connections during the memorization and learning process. Glial cells are active participants in diffuse transmission of nerve impulses in the brain. Astrocytes form a three-dimensional, functionally “syncytia-like” formation, inside of which there are neurons, thus causing their specific microenvironment. They and neurons are structurally and functionally interconnected, based on which their permanent interaction occurs. Oligodendrocytes provide conditions for the generation and transmission of nerve impulses along the processes of neurons and play a significant role in the processes of their excitation and inhibition. Microglial cells play an important role in the formation of the brain, especially in the formation and maintenance of synapses. Thus, the CNS should be considered as a single, functionally “syncytia-like”, structural entity. Because the three-dimensional distribution of dendritic branches in space is important for determining the type of information that goes to a neuron, it is necessary to consider the three-dimensionality of their structure when analyzing the implementation of their functions.

Semiquinone intermediates are involved in the energy coupling mechanism of E. coli complex I

Complex I (NADH:quinone oxidoreductase) is central to cellular aerobic energy metabolism, and its deficiency is involved in many human mitochondrial diseases. Complex I translocates protons across the membrane using electron transfer energy. Semiquinone (SQ) intermediates appearing during catalysis are suggested to be key for the coupling mechanism in complex I. However, the existence of SQ has remained controversial due to the extreme difficulty in detecting unstable and low intensity SQ signals. Here, for the first time with Escherichia coli complex I reconstituted in proteoliposomes, we successfully resolved and characterized three distinct SQ species by EPR. These species include: fast-relaxing SQ (SQNf) with P1/2 (half-saturation power level)>50mW and a wider linewidth (12.8 G); slow-relaxing SQ (SQNs) with P1/2=2-3mW and a 10G linewidth; and very slow-relaxing SQ (SQNvs) with P1/2= ~0.1mW and a 7.5G linewidth. The SQNf signals completely disappeared in the presence of the uncoupler gramicidin D or squamotacin, a potent E. coli complex I inhibitor. The pH dependency of the SQNf signals correlated with the proton-pumping activities of complex I. The SQNs signals were insensitive to gramicidin D, but sensitive to squamotacin. The SQNvs signals were insensitive to both gramicidin D and squamotacin. Our deuterium exchange experiments suggested that SQNf is neutral, while SQNs and SQNvs are anion radicals. The SQNs signals were lost in the ΔNuoL mutant missing transporter module subunits NuoL and NuoM. The roles and relationships of the SQ intermediates in the coupling mechanism are discussed.

Evolution of cytochrome bc complexes: from membrane-anchored dehydrogenases of ancient bacteria to triggers of apoptosis in vertebrates

This review traces the evolution of the cytochrome bc complexes from their early spread among prokaryotic lineages and up to the mitochondrial cytochrome bc1 complex (complex III) and its role in apoptosis. The results of phylogenomic analysis suggest that the bacterial cytochrome b6f-type complexes with short cytochromes b were the ancient form that preceded in evolution the cytochrome bc1-type complexes with long cytochromes b. The common ancestor of the b6f-type and the bc1-type complexes probably resembled the b6f-type complexes found in Heliobacteriaceae and in some Planctomycetes. Lateral transfers of cytochrome bc operons could account for the several instances of acquisition of different types of bacterial cytochrome bc complexes by archaea. The gradual oxygenation of the atmosphere could be the key evolutionary factor that has driven further divergence and spread of the cytochrome bc complexes. On the one hand, oxygen could be used as a very efficient terminal electron acceptor. On the other hand, auto-oxidation of the components of the bc complex results in the generation of reactive oxygen species (ROS), which necessitated diverse adaptations of the b6f-type and bc1-type complexes, as well as other, functionally coupled proteins. A detailed scenario of the gradual involvement of the cardiolipin-containing mitochondrial cytochrome bc1 complex into the intrinsic apoptotic pathway is proposed, where the functioning of the complex as an apoptotic trigger is viewed as a way to accelerate the elimination of the cells with irreparably damaged, ROS-producing mitochondria. This article is part of a Special Issue entitled: Respiratory complex III and related bc complexes.

Asymmetric Binding of Stigmatellin to the Dimeric Paracoccus denitrificans bc1 Complex

We have investigated the mechanism responsible for half-of-the-sites activity in the dimeric cytochrome bc(1) complex from Paracoccus denitrificans by characterizing the kinetics of inhibitor binding to the ubiquinol oxidation site at center P. Both myxothiazol and stigmatellin induced a 2-3 nm shift of the visible absorbance spectrum of the b(L) heme. The shift generated by myxothiazol was symmetric, with monophasic kinetics that indicate equal binding of this inhibitor to both center P sites. In contrast, stigmatellin generated an asymmetric shift in the b(L) spectrum, with biphasic kinetics in which each phase contributed approximately half of the total magnitude of the spectral change. The faster binding phase corresponded to a more symmetrical shift of the b(L) spectrum relative to the slower binding phase, indicating that approximately half of the center P sites bound stigmatellin more slowly and in a different position relative to the b(L) heme, generating a different effect on its electronic environment. Significantly, the slow stigmatellin binding phase was lost as the inhibitor concentration was increased. This implies that a conformational change is transmitted from one center P site in the dimer to the other upon stigmatellin binding to one monomer, rendering the second site less accessible to the inhibitor. Because the position that stigmatellin occupies at center P is considered to be analogous to that of the quinol substrate at the moment of electron transfer, these results indicate that the productive enzyme-substrate configuration is prevented from occurring in both monomers simultaneously.

Proton translocation by the cytochromebc1complexes 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.

Rapid Electron Transfer between Monomers when the Cytochrome bc1 Complex Dimer Is Reduced through Center N

We have obtained evidence for electron transfer between cytochrome b subunits of the yeast bc(1) complex dimer by analyzing pre-steady state reduction of cytochrome b in the presence of center P inhibitors. The kinetics and extent of cytochrome b reduced by quinol in the presence of variable concentrations of antimycin decreased non-linearly and could only be fitted to a model in which electrons entering through one center N can equilibrate between the two cytochrome b subunits of the bc(1) complex dimer. The b(H) heme absorbance in a bc(1) complex inhibited at center P and preincubated with substoichiometric concentrations of antimycin showed a red shift upon the addition of substrate, which indicates that electrons from the uninhibited center N in one monomer are able to reach the b(H) heme at the antimycin-blocked site in the other. The extent of cytochrome b reduction by variable concentrations of menaquinol could only be fitted to a kinetic model that assumes electron equilibration between center N sites in the dimer. Kinetic simulations showed that non-rate-limiting electron equilibration between the two b(H) hemes in the dimer through the two b(L) hemes is possible upon reduction through one center N despite the thermodynamically unfavorable b(H) to b(L) electron transfer step. We propose that electron transfer between cytochrome b subunits minimizes the formation of semiquinone-ferrocytochrome b(H) complexes at center N and favors ubiquinol oxidation at center P by increasing the amount of oxidized cytochrome b.

Thermodynamic and EPR studies of slowly relaxing ubisemiquinone species in the isolated bovine heart complex I

Previously, we investigated ubisemiquinone (SQ) EPR spectra associated with NADH-ubiquinone oxidoreductase (complex I) in the tightly coupled bovine heart submitochondrial particles (SMP). Based upon their widely differing spin relaxation rate, we distinguished SQ spectra arising from three distinct SQ species, namely SQ(Nf) (fast), SQ(Ns) (slow), and SQ(Nx) (very slow). The SQ(Nf) signal was observed only in the presence of the proton electrochemical gradient (deltamu(H)(+)), while SQ(Ns) and SQ(Nx) species did not require the presence of deltamu(H+). We have now succeeded in characterizing the redox and EPR properties of SQ species in the isolated bovine heart complex I. The potentiometric redox titration of the g(z,y,x)=2.00 semiquinone signal gave the redox midpoint potential (E(m)) at pH 7.8 for the first electron transfer step [E(m1)(Q/SQ)] of -45 mV and the second step [E(m2)(SQ/QH(2))] of -63 mV. It can also be expressed as [E(m)(Q/QH(2))] of -54 mV for the overall two electron transfer with a stability constant (K(stab)) of the SQ form as 2.0. These characteristics revealed the existence of a thermodynamically stable intermediate redox state, which allows this protein-associated quinone to function as a converter between n=1 and n=2 electron transfer steps. The EPR spectrum of the SQ species in complex I exhibits a Gaussian-type spectrum with the peak-to-peak line width of approximately 6.1 G at the sample temperature of 173 K. This indicates that the SQ species is in an anionic Q(-) state in the physiological pH range. The spin relaxation rate of the SQ species in isolated complex I is much slower than the SQ counterparts in the complex I in situ in SMP. We tentatively assigned slow relaxing anionic SQ species as SQ(Ns), based on the monophasic power saturation profile and several fold increase of its spin relaxation rate in the presence of reduced cluster N2. The current study also suggests that the very slowly relaxing SQ(Nx) species may not be an intrinsic complex I component. The functional role of SQ(Ns) is further discussed in connection with the SQ(Nf) species defined in SMP in situ.

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.

Ubiquinol:cytochrome c oxidoreductase (complex III). Effect of inhibitors on cytochrome b reduction in submitochondrial particles and the role of ubiquinone in complex III

Two sets of studies have been reported on the electron transfer pathway of complex III in bovine heart submitochondrial particles (SMP). 1) In the presence of myxothiazol, MOA-stilbene, stigmatellin, or of antimycin added to SMP pretreated with ascorbate and KCN to reduce the high potential components (iron-sulfur protein (ISP) and cytochrome c(1)) of complex III, addition of succinate reduced heme b(H) followed by a slow and partial reduction of heme b(L). Similar results were obtained when SMP were treated only with KCN or NaN(3), reagents that inhibit cytochrome oxidase, not complex III. The average initial rate of b(H) reduction under these conditions was about 25-30% of the rate of b reduction by succinate in antimycin-treated SMP, where both b(H) and b(L) were concomitantly reduced. These results have been discussed in relation to the Q-cycle hypothesis and the effect of the redox state of ISP/c(1) on cytochrome b reduction by succinate. 2) Reverse electron transfer from ISP reduced with ascorbate plus phenazine methosulfate to cytochrome b was studied in SMP, ubiquinone (Q)-depleted SMP containing </=0.06 mol of Q/mol of complex III, and Q-replenished SMP. The results showed that Q was not required for electron transfer from ISP to b, a reaction that was inhibited by antimycin (also by myxothiazol or MOA-stilbene as reported elsewhere). It was also shown that antimycin did not inhibit electron transfer from b (b(H)) to Q, in clear contrast to the assumption of the Q-cycle hypothesis regarding the site of antimycin inhibition.

Confirmation of the involvement of protein domain movement during the catalytic cycle of the cytochrome bc1 complex by the formation of an intersubunit disulfide bond between cytochrome b and the iron-sulfur protein

To study the essentiality of head domain movement of the Rieske iron-sulfur protein (ISP) during bc(1) catalysis, Rhodobacter sphaeroides mutants expressing His-tagged cytochrome bc(1) complexes with three pairs of cysteines engineered (one cysteine each) on the interface between cytochrome b and ISP, A185C(cytb)/K70C(ISP), I326C(cytb)/G165C(ISP), and T386C(cytb)/K164C(ISP), were generated and characterized. Formation of an intersubunit disulfide bond between cytochrome b and ISP is detected in membrane (intracytoplasmic membrane and air-aged chromatophore), and purified bc(1) complex was prepared from the A185C(cytb)/K70C(ISP) mutant cells. Formation of the intersubunit disulfide bond in this cysteine pair mutant complex is concurrent with the loss of its bc(1) activity. Reduction of this disulfide bond by beta-mercaptoethanol restores activity, indicating that mobility of the head domain of ISP is functionally important in the cytochrome bc(1) complex. The rate of intramolecular electron transfer, between 2Fe2S and heme c(1), in the A185C(cytb)/K70C(ISP) mutant complex is much lower than that in the wild type or in their respective single cysteine mutant complexes, indicating that formation of an intersubunit disulfide bond between cytochrome b and ISP arrests the head domain of ISP in the "fixed state" position, which is too far for electron transfer to heme c(1).

The involvement of serine 175 and alanine 185 of cytochrome b of Rhodobacter sphaeroides cytochrome bc1 complex in interaction with iron-sulfur protein

An approach involving cysteine replacement of potentially noncritical amino acid residues, followed by chemical modification studies, was used to investigate structure-function of the "cd helix" of cytochrome b from Rhodobacter sphaeroides. Three amino acid residues, Ser-155, Ser-175, and Ala-185, which span this region of cytochrome b, were selected for this study. The S155C substitution yields cells unable to support photosynthetic growth, indicating that Ser-155 is a critical amino acid residue. Further mutational studies of Ser-155 indicate that the size of the amino acid side chain at this position is critical for photosynthetic growth of R. sphaeroides. On the other hand, the S175C and A185C substitutions yield cells with photosynthetic growth rates and enzyme kinetics of the bc1 complexes very similar to those of the unmutated complex, indicating that Ser-175 and Ala-185 are noncritical residues. Thus, engineered cysteines at these two positions of cytochrome b are suitable for membrane topology and domain/subunit interaction studies. Cys-175 does not react with a sulfhydryl-modifying reagent, N-ethylmaleimide (NEM), either in sealed, inside-out chromatophores or in detergent-disrupted chromatophores, indicating that position 175 of cytochrome b is inaccessible from both sides of the membrane and is probably buried within the protein complex. Cys-185 reacts with NEM only after detergent disruption of the sealed, inside-out chromatophores, indicating that this position of cytochrome b is accessible on the outer (periplasmic) surface of the membrane. These results place the cd helix of cytochrome b on the periplasmic side of the chromatophore membrane. When purified A185C-substituted bc1 complex was treated with NEM, about 87% of the activity was abolished due to NEM modification of Cys-185. The signature of the Rieske iron-sulfur center is broadened upon NEM modification of A185C, with the gx signal shifting from g = 1.80 to g = 1.75, suggesting that Ala-185 of cytochrome b interacts with the iron-sulfur protein. When purified S175C-substituted bc1 complex is treated with NEM, no change in the activity is observed, since Cys-175 is inaccessible to NEM. However, when the iron-sulfur protein is removed from the S175C-substituted bc1 complex, Cys-175 becomes accessible to NEM, indicating that Ser-175 of cytochrome b is shielded by the iron-sulfur protein in the bc1 complex.

SOME NEW STRUCTURAL ASPECTS AND OLD CONTROVERSIES CONCERNING THE CYTOCHROME b6f COMPLEX OF OXYGENIC PHOTOSYNTHESIS

The cytochrome b6f complex functions in oxygenic photosynthetic membranes as the redox link between the photosynthetic reaction center complexes II and I and also functions in proton translocation. It is an ideal integral membrane protein complex in which to study structure and function because of the existence of a large amount of primary sequence data, purified complex, the emergence of structures, and the ability of flash kinetic spectroscopy to assay function in a readily accessible ms-100 mus time domain. The redox active polypeptides are cytochromes f and b6 (organelle encoded) and the Rieske iron-sulfur protein (nuclear encoded) in a mol wt = 210,000 dimeric complex that is believed to contain 22-24 transmembrane helices. The high resolution structure of the lumen-side domain of cytochrome f shows it to be an elongate (75 A long) mostly beta-strand, two-domain protein, with the N-terminal alpha-amino group as orthogonal heme ligand and an internal linear 11-A bound water chain. An unusual electron transfer event, the oxidant-induced reduction of a significant fraction of the p (lumen)-side cytochrome b heme by plastosemiquinone indicates that the electron transfer pathway in the b6f complex can be described by a version of the Q-cycle mechanism, originally proposed to describe similar processes in the mitochondrial and bacterial bc1 complexes.

Ubiquinol-cytochrome c oxidoreductase. The redox reactions of the bis-heme cytochrome b in ubiquinone-sufficient and ubiquinone-deficient systems

Antimycin and myxothiazol are stoichiometric inhibitors of complex III (ubiquinol-cytochrome c oxidoreductase), exerting their highest degree of inhibition at I mol each/mol of complex III monomer. Phenomenologically, however, they each inhibit three steps in the redox reaction of the bis-heme cytochrome b in submitochondrial particles (SMP), and all three inhibitions are incomplete to various extents. (i) In SMP, reduction of hemes bH and bL by NADH or succinate is inhibited when the particles are treated with both antimycin and myxothiazol. Each inhibitor alone allows reduced bH and bL to accumulate, indicating that each inhibits the reoxidation of these hemes. (E)-Methyl-3-methoxy-2-(4')-trans-stilbenyl)acrylatc in combination with antimycin or 2-n-heptyl-4-hydroxyquinoline-N-oxide in combination with myxothiazol causes less inhibition of b reduction than the combination of antimycin and myxothiazol. (ii) Reoxidation of reduced b, is inhibited by either antimycin or myxothiazol (or 2-n-heptyl-4-hydroxyquinoline-N-oxide, (E)-methyl-3-methoxy-2-(4'-trans-stilbenyl)acrylate, or stigmatellin). (iii) Reoxidation of reduced bH is also inhibited by any one of these reagents. These inhibitions are also incomplete, and reduced bL is oxidized through the leaks allowed by these inhibitors at least 10 times faster than reduced bH. Heme bH can be reduced in SMP via cytochrome c, and the Rieske iron-sulfur protein by ascorbate and faster by ascorbate + TMPD (N,N,N',N'-tetramethyl-p-phenylenediamine). Energization of SMP by the addition of ATP affords reduction of bL as well. Reverse electron transfer to bH and bL is inhibited partially by myxothiazol, much more by antimycin. Ascorbate + TMPD also reduce bH in ubiquinone-extracted SMP in which the molar ratio of ubiquinone to cytochrome b has been reduced 200-fold from 12.5 to aproximately 0.06. Reconstitution of the extracted particles with ubiquinone-10 restores substrate oxidation but does not improve the rate or the extent of b, reduction by ascorbate + TMPD. These reagents also partially reduce cytochrome b in SMP from a ubiquinone-deficient yeast mutant. The above results are discussed in relation to the Q-cycle hypothesis.

The involvement of threonine 160 of cytochrome b of Rhodobacter sphaeroides cytochrome bc1 complex in quinone binding and interaction with subunit IV

The cytochrome b subunit (subunit I) of the ubiquinolcytochrome c reductase (bc1 complex) is thought to participate in the formation of two quinone/quinol reaction centers, an oxidizing center (Qo) and a reducing center, in accordance with the quinone cycle mechanism. Threonine 160 is a highly conserved residue in a segment of subunit I that was shown to bind quinone and is placed near the putative Qo site in current models of the bc1 complex. Rhodobacter sphaeroides cells expressing bc1 complexes with Ser or Tyr substituted for Thr160 grow photosynthetically at a reduced rate, and cells expressing the mutated complexes produce an "elevated" level of the bc1 complex. The Ser substitution also affects the interaction of subunit IV with subunit I. Replacement of Thr160 by Ser results in about a 70% loss of the activity in the purified complex, whereas substitution by Tyr lowers the activity by more than 80%. Both replacements lower the apparent Km for ubiquinol. Electron paramagnetic resonance (EPR) spectroscopy shows that in the Ser substituted complex, the environments of the Rieske iron-sulfur cluster in subunit III and the high potential cytochrome b (b562) in subunit I have been modified. The spectra of the Ser160 and Tyr160 iron-sulfur clusters have become redox-insensitive, with a line shape resembling that of the native complex in the fully reduced state. The EPR signal of b562 in the Ser160 complex is shifted from g = 3.50 to g = 3.52, but otherwise the line shape is very similar to the spectrum of the native complex. Most of these results are consistent with current ideas regarding the structure and function of Qo in the bc1 complex, except for the alteration of the b562 EPR feature, because this heme is not thought to be located in proximity to Qo. Immunoblotting analysis showed that the Ser or Tyr substituted complex contained significantly less than a stoichiometric amount of subunit IV. The enzymatic activity of mutated bc1 complex was found to be activable by the addition of purified subunit IV. These results indicate that Thr160 plays an important role in the structure and/or function of the bc1 complex.

The protonmotive Q cycle in mitochondria and bacteria

The cytochrome bc1 complex is an oligomeric electron transfer enzyme located in the inner membrane of mitochondria and the plasma membrane of bacteria. The cytochrome bc1 complex participates in respiration in eukaryotic cells and also participates in respiration, cyclic photosynthetic electron transfer, denitrification, and nitrogen fixation in a phylogenetically diverse collection of bacteria. In all of these organisms, the cytochrome bc1 complex transfers electrons from ubiquinol to cytochrome c and links this electron transfer to translocation of protons across the membrane in which it resides, thus converting the available free energy of the oxidation-reduction reaction into an electrochemical proton gradient. The mechanism by which the cytochrome bc1 complex achieves this energy transduction is the protonmotive Q cycle. The Q cycle mechanism has been documented by extensive experimentation, and recent investigations have focused on structural features of the three redox subunits of the bc1 complex essential to the protonmotive and electrogenic activities of this membranous enzyme.

Characteristics of the energy-transducing NADH-quinone oxidoreductase of Paracoccus denitrificans as revealed by biochemical, biophysical, and molecular biological approaches

A comparison of the mitochondrial NADH-ubiquinone oxidoreductase and the energy-transducing NADH-quinone oxidoreductase (NDH-1) of Paracoccus denitrificans revealed that both systems have similar electron-transfer and energy-transduction pathways. In addition, both complexes are sensitive to the same inhibitors and contain similar electron carriers, suggesting that the Paracoccus NDH-1 may serve as a useful model system for the study of the human enzyme complex. The gene cluster encoding the Paracoccus NDH-1 has been cloned and sequenced. It is composed of 18,106 base pairs and contains 14 structural genes and six unidentified reading frames (URFs). The structural genes, URFs, and their polypeptides have been characterized. We also discuss nucleotide sequences which are believed to play a role in the regulation of the NDH-1 gene cluster and Paracoccus NDH-1 subunits which may contain the binding sites of substrates and/or electron carriers.

Assembly of the Rieske iron-sulfur subunit of the cytochrome bc1 complex in the Escherichia coli and Rhodobacter sphaeroides membranes independent of the cytochrome b and c1 subunits

The Rieske iron-sulfur subunit of the cytochrome bc1 complex from Rhodobacter sphaeroides has been expressed in Escherichia coli and also in a strain of Rb. sphaeroides lacking the other subunits of the bc1 complex. PCR products encoding the full-length subunit were introduced into expression vectors to produce the subunit alone or the subunit fused behind the mature portion of the E. coli maltose binding protein (MBP), but lacking the MBP signal sequence. These proteins are both located in the cytoplasmic membrane. The unfused Rieske subunit assembles a Rieske-like iron-sulfur cluster, but with EPR characteristics which differ from the normal rhombic signal observed in the cytochrome bc1 complex. The overproduced MBP fusion protein, on the other hand, does not contain an EPR-detectable iron-sulfur cluster. Subfragments of the Rieske subunit lacking the amino-terminal hydrophobic anchor also lack the iron-sulfur cluster were expressed in E. coli. When expressed in Rb. sphaeroides in the absence of the cytochrome b and c1 subunits, the fully metalated Rieske subunit with the diagnostic gy = 1.90 EPR signal is observed in the cytoplasmic membrane. The fact that the Rieske subunit has an assembled iron-sulfur cluster and is bound to either the E. coli or the Rb. sphaeroides membrane in the absence of the other subunits of the bc1 complex demonstrates a mode of membrane attachment independent of the other components of the complex. These data are consistent with models in which the Rieske subunit is bound to the membrane via a single membrane-spanning helix located near the amino terminus.(ABSTRACT TRUNCATED AT 250 WORDS)

Determination of the position of the Qi.- quinone binding site from the protein surface of the cytochrome bc1 complex in Rhodobacter capsulates chromatophores

The technique of distance measurement, utilizing spin relaxation enhancement by an external probe, has been extended to the study of intrinsic semiquinone radicals through the use of holmium-EDTA complexes and continuous wave electron paramagnetic resonance spectroscopy. This technique has been used to determine the distance of the semiquinone anion, Qi (also designated as Qn.- or Qc.-), from the surface of the ubiquinone cytochrome c oxidoreductase, consisting of only three subunits, in membrane particles from Rhodobacter capsulates. The location of the semiquinone anion is 6-10 A from the N side protein, establishing that there are two separate quinone reaction sites, i.e., 'Qi' and 'Qo', within this complex on opposite sides of the membrane. The results are discussed in relation to reported ENDOR, EPR, and optical studies of the mitochondrial counterpart.

The iron-sulfur clusters in the two related forms of mitochondrial NADH: ubiquinone oxidoreductase made by Neurospora crassa

Two related forms of the respiratory-chain complex, NADH: ubiquinone oxidoreductase (Complex I) are synthesized in the mitochondria of Neurospora crassa. Normally growing cells make a large, piericidin-A-sensitive form, which consists of some 23 different nuclear- and 6-7 mitochondrially encoded subunits. Cells grown in the presence of chloramphenicol make a small, piericidin-A-insensitive form which consists of only approximately 13 nuclear-encoded subunits. The subunits of the small form are either identical or similar to nuclear-encoded subunits of the large form. The iron-sulfur clusters in these two forms of Complex I are characterized by redox potentiometry and EPR spectroscopy. The large form of Complex I contains four EPR-detectable iron-sulfur clusters, N1, N2, N3 and N4, with the spin concentration of the individual clusters equivalent to the flavin concentration, similar to the mammalian counterparts. The small Complex I contains clusters N1, N3 and N4, but it is devoid of cluster N2. A model of the electron-transfer route through the large form of Complex I has been derived from these findings and an evolutionary pathway which leads to the emergence of large Complex I is discussed.

The three-subunit cytochrome bc1 complex of Paracoccus denitrificans. Its physiological function, structure, and mechanism of electron transfer and energy transduction

The cytochrome bc1 complex purified from P. denitrificans has the same electron-transfer and energy-transducing activities, is sensitive to the same electron-transfer inhibitors, and contains cytochromes b, c1, iron-sulfur protein, and thermodynamically stable ubisemiquinone identical to the counterpart complexes from mitochondria. However, the bacterial bc1 complex consists of only three proteins, the obligate electron-transfer proteins, while the mitochondrial complexes contain six or more supernumerary polypeptides, which have no obvious electron-transfer function. The P. denitrificans complex is a paradigm for the bc1 complexes of all gram-negative bacteria. In addition, because of its simple polypeptide composition and apparently minimal damage during isolation, the P. denitrificans bc1 complex is an ideal system in which to study structure-function relationships requisite to energy transduction linked to electron transfer.

EPR characterization of the cytochrome b-c1 complex from Rhodobacter sphaeroides

EPR characteristics of cytochrome c1, cytochromes b-565 and b-562, the iron-sulfur cluster, and an antimycin-sensitive ubisemiquinone radical of purified cytochrome b-c1 complex of Rhodobacter sphaeroides have been studied. The EPR specra of cytochrome c1 shows a signal at g = 3.36 flanked with shoulders. The oxidized form of cytochrome b-562 shows a broad EPR signal at g = 3.49, while oxidized cytochrome b-565 shows a signal at g = 3.76, similar to those of two b cytochromes in the mitochondrial complex. The distribution of cytochromes b-565 and b-562 in the isolated complex is 44 and 56%, respectively. Antimycin and 2,5-dibromo-3-methyl-6-isopropyl-1,4-benzoquinone (DBMIB) have little effect on the g = 3.76 signal, but they cause a slight downfield and upfield shifts of the g = 3.49 signal, respectively. 5-Undecyl-6-hydroxyl-4,7-dioxobenzothiazole (UHDBT) shifts the g = 3.49 signal downfield to g = 3.56 and sharpens the g = 3.76 signal slightly. Myxothiazol causes an upfield shift of both g = 3.49 and g = 3.76 signals. EPR characteristics of the reduced iron-sulfur cluster in bacterial cytochrome b-c1 complex are: gx = 1.8 with a small shoulder at g = 1.76, gy = 1.89 and gz = 2.02, similar to those observed with the mitochondrial enzyme. The gx = 1.8 signal decreased and the shoulder increased concurrently as the redox potential decreased, indicating that the environment of the iron-sulfur cluster is sensitive to the redox state of the complex. UHDBT sharpens the gz and and shifts it downfield from g = 2.02 to 2.03, and shifts gx upfield from g = 1.80 to 1.78. UHDBT also causes an upfield shift of gy but to a much lesser extent compared to the other two signals. Addition of DBMIB causes a downfield shift of the gy from 1.89 to 1.94 and broadens the gx signal with an upfield to g = 1.75. Myxothiazol and antimycin show little effect on the gy and gz signals, but they broaden and shift the gx signal upfield to g = 1.74. However, the myxothiazol effect is partially reversed by UHDBT. An antimycin-sensitive ubisemiquinone radical was detected in the cytochrome b-c1 complex. At pH 8.4, the antimycin-sensitive ubisemiquinone radical has a maximal concentration of 0.66 mol per mol complex at 100 mV.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Large-scale purification and characterization of a highly active four-subunit cytochrome bc1 complex from Rhodobacter sphaeroides

A highly active, large-scale preparation of ubiquinol:cytochrome c2 oxidoreductase (EC 1.10.2.2; cytochrome bc1 complex) has been obtained from Rhodobacter sphaeroides. The enzyme was solubilized from chromatophores by using dodecyl maltoside in the presence of glycerol and was purified by anion-exchange and gel filtration chromatography. The procedure yields 35 mg of pure bc1 complex from 4.5 g of membrane protein, and its consistently results in an enzyme preparation that catalyzes the reduction of horse heart cytochrome c with a turnover of 250-350 (mumol of cyt c reduced).(mumol of cyt c1)-1.s-1. The turnover number is at least double that of the best preparation reported in the literature [Ljungdahl, P. O., Pennoyer, J. D., Robertson, D. C., & Trumpower, B. L. (1987) Biochim. Biophys. Acta 891, 227-241]. The scale is increased 25-fold, and the yield is markedly improved by using this protocol. Four polypeptide subunits were observed by SDS-PAGE, with Mr values of 40K, 34K, 24K, and 14K. N-Terminal amino acid sequences were obtained for cytochrome c1, the iron-sulfur protein subunit, and for cytochrome b and were identical with the expected protein sequences deduced from the DNA sequence of the fbc operon, with the exceptions that a 22-residue fragment is processed off of the N-terminus of cytochrome c1 and the N-terminal methionine residue is cleaved off both the b cytochrome and iron-sulfur protein subunits. Western blotting experiments indicate that subunit IV is not a contaminating light-harvesting complex polypeptide.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure and function of the mitochondrial bc1 complex. A mutational analysis of the yeast Rieske iron-sulfur protein

Respiratory-defective mutants of Saccharomyces cerevisiae assigned to a single complementation group (G12) have been determined to have lesions in the iron-sulfur protein (Rieske protein) of ubiquinol: cytochrome c reductase. Mutants capable of expressing the protein were chosen for further studies. The genes from 13 independent isolates were cloned and their mutations sequenced. Twelve mutations were ascertained to cause single amino acid substitutions in the carboxyl-terminal regions of the protein between residues 127 and 173. This region is proposed to be part of the catalytic domain with the ligands responsible for co-ordinating the two irons of the 2Fe-2S cluster. Based on the catalytic properties of the ubiquinol: cytochrome c reductase complex and the electron paramagnetic resonance (e.p.r.) signals of the iron-sulfur protein, the mutants describe two different phenotypes. A subset of mutants have no detectable iron-sulfur cluster and are completely deficient in ubiquinol: cytochrome c reductase activity. These strains identify mutations in residues considered to be essential for binding of the iron or for maintaining a proper tertiary structure of the catalytic domain. A second group of mutants have reduced levels of enzymatic activity and exhibit e.p.r. spectra characteristic of the Rieske iron-sulfur cluster. The mutations in the latter strains have been ascribed to residues that influence the redox properties of the cluster by distorting the iron-binding pocket. A secondary and tertiary structure model is presented of the carboxyl-terminal 65 residues constituting the catalytic domain of the iron-sulfur protein. It is postulated that the two irons of the cluster are co-ordinated by three cysteine and a single histidine residue located in a loop structure. The catalytic domain also contains two short alpha-helices and three beta-strands that form a partial beta-barrel. Most of the hydrophilic amino acids are present in turns that map to one pole of the domain. When viewed in the context of the model, mutations that abolish the iron-sulfur cluster are mostly in residues defining the boundaries of the alpha-helices and beta-strands. The notable exception is a cysteine residue that has been assigned to the loop with the iron ligands. This cysteine residue is proposed to co-ordinate one iron of the cluster. Mutations that reduce ubiquinol: cytochrome c reductase activity and alter the redox potential of the cluster occur in residues located in the loop that contains the ligands of the cluster.