Soluble variants of Rhodobacter capsulatus membrane-anchored cytochrome cy are efficient photosynthetic electron carriers

Photosynthetic (Ps) electron transport pathways often contain multiple electron carriers with overlapping functions. Here we focus on two c-type cytochromes (cyt) in facultative phototrophic bacteria of the Rhodobacter genus: the diffusible cyt c2 and the membrane-anchored cyt c(y). In species like R. capsulatus, cyt c(y) functions in both Ps and respiratory electron transport chains, whereas in other species like R. sphaeroides, it does so only in respiration. The molecular bases of this difference was investigated by producing a soluble variant of cyt c(y) (S-c(y)), by fusing genetically the cyt c2 signal sequence to the cyt c domain of cyt c(y). This novel electron carrier was unable to support the Ps growth of R. capsulatus. However, strains harboring cyt S-c(y) regained Ps growth ability by acquiring mutations in its cyt c domain. They produced cyt S-c(y) variants at amounts comparable with that of cyt c2, and conferred Ps growth. Chemical titration indicated that the redox midpoint potential of cyt S-c(y) was about 340 mV, similar to that of cyts c2 or c(y). Remarkably, electron transfer kinetics from the cyt bc1 complex to the photochemical reaction center (RC) mediated by cyt S-c(y) was distinct from those seen with the cyt c2 or cyt c(y). The kinetics exhibited a pronounced slow phase, suggesting that cyt S-c(y) interacted with the RC less tightly than cyt c2. Comparison of structural models of cyts c2 and S-c(y) revealed that several of the amino acid residues implicated in long-range electrostatic interactions promoting binding of cyt c2 to the RC are not conserved in cyt c(y), whereas those supporting short-range hydrophobic interactions are conserved. These findings indicated that attaching electron carrier cytochromes to the membrane allowed them to weaken their interactions with their partners so that they could accommodate more rapid multiple turnovers.     

The roles of Rhodobacter sphaeroides copper chaperones PCuAC and Sco (PrrC) in the assembly of the copper centers of the aa3-type and the cbb3-type cytochrome c oxidases

The α proteobacter Rhodobacter sphaeroides accumulates two cytochrome c oxidases (CcO) in its cytoplasmic membrane during aerobic growth: a mitochondrial-like aa₃-type CcO containing a di-copper Cu_A center and mono-copper Cu_B, plus a cbb₃-type CcO that contains Cu_B but lacks Cu_A. Three copper chaperones are located in the periplasm of R. sphaeroides, PCu_AC, PrrC (Sco) and Cox11. Cox11 is required to assemble Cu_B of the aa₃-type but not the cbb₃-type CcO. PrrC is homologous to mitochondrial Sco1; Sco proteins are implicated in Cu_A assembly in mitochondria and bacteria, and with Cu_B assembly of the cbb₃-type CcO. PCu_AC is present in many bacteria, but not mitochondria. PCu_AC of Thermus thermophilus metallates a Cu_A center in vitro, but its in vivo function has not been explored. Here, the extent of copper center assembly in the aa₃- and cbb₃-type CcOs of R. sphaeroides has been examined in strains lacking PCu_AC, PrrC, or both. The absence of either chaperone strongly lowers the accumulation of both CcOs in the cells grown in low concentrations of Cu^2 +. The absence of PrrC has a greater effect than the absence of PCu_AC and PCu_AC appears to function upstream of PrrC. Analysis of purified aa₃-type CcO shows that PrrC has a greater effect on the assembly of its Cu_A than does PCu_AC, and both chaperones have a lesser but significant effect on the assembly of its Cu_B even though Cox11 is present. Scenarios for the cellular roles of PCu_AC and PrrC are considered. The results are most consistent with a role for PrrC in the capture and delivery of copper to Cu_A of the aa₃-type CcO and to Cu_B of the cbb₃-type CcO, while the predominant role of PCu_AC may be to capture and deliver copper to PrrC and Cox11. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

The roles of Rhodobacter sphaeroides copper chaperones PCu(A)C and Sco (PrrC) in the assembly of the copper centers of the aa(3)-type and the cbb(3)-type cytochrome c oxidases

The α proteobacter Rhodobacter sphaeroides accumulates two cytochrome c oxidases (CcO) in its cytoplasmic membrane during aerobic growth: a mitochondrial-like aa(3)-type CcO containing a di-copper Cu(A) center and mono-copper Cu(B), plus a cbb(3)-type CcO that contains Cu(B) but lacks Cu(A). Three copper chaperones are located in the periplasm of R. sphaeroides, PCu(A)C, PrrC (Sco) and Cox11. Cox11 is required to assemble Cu(B) of the aa(3)-type but not the cbb(3)-type CcO. PrrC is homologous to mitochondrial Sco1; Sco proteins are implicated in Cu(A) assembly in mitochondria and bacteria, and with Cu(B) assembly of the cbb(3)-type CcO. PCu(A)C is present in many bacteria, but not mitochondria. PCu(A)C of Thermus thermophilus metallates a Cu(A) center in vitro, but its in vivo function has not been explored. Here, the extent of copper center assembly in the aa(3)- and cbb(3)-type CcOs of R. sphaeroides has been examined in strains lacking PCu(A)C, PrrC, or both. The absence of either chaperone strongly lowers the accumulation of both CcOs in the cells grown in low concentrations of Cu(2+). The absence of PrrC has a greater effect than the absence of PCu(A)C and PCu(A)C appears to function upstream of PrrC. Analysis of purified aa(3)-type CcO shows that PrrC has a greater effect on the assembly of its Cu(A) than does PCu(A)C, and both chaperones have a lesser but significant effect on the assembly of its Cu(B) even though Cox11 is present. Scenarios for the cellular roles of PCu(A)C and PrrC are considered. The results are most consistent with a role for PrrC in the capture and delivery of copper to Cu(A) of the aa(3)-type CcO and to Cu(B) of the cbb(3)-type CcO, while the predominant role of PCu(A)C may be to capture and deliver copper to PrrC and Cox11. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

G204D, a mutation that blocks the proton-conducting D-channel of the aa3-type cytochrome c oxidase from Rhodobacter sphaeroides

Cytochrome c oxidase uses the free energy of oxygen reduction to establish a transmembrane proton gradient. The proton-conducting D-channel in this enzyme is the major input pathway for protons which go to the binuclear center for water formation ("chemical protons") and likely the only input pathway for protons that get translocated across the lipid membrane ("pumped protons"). The D-channel starts at an acidic residue near the protein surface (D132, Rhodobacter sphaeroides numbering) and leads to another acidic residue near the binuclear center. Recent studies have shown that mutants that introduce an additional acidic residue in the channel (N139D) have the remarkable effect of accelerating steady-state oxidase activity but completely eliminating proton pumping. In this work, an aspartic acid was introduced at the position of glycine 204, G204D, which is also within the D-channel, and the effects were examined. In contrast to N139D, the G204D mutation results in a dramatic decrease of the steady-state oxygen reductase activity (<2% of wild type) [Aagaard, A., and Brzezinski, P. (2001) FEBS Lett. 494, 157-160]. The residual activity is not coupled to the proton pump, and furthermore, in reconstituted vesicles the mutant enzyme exhibits a reverse respiration control ratio; i.e., the mutant oxidase activity is stimulated rather than inhibited when working against a protonmotive force. Hence, the mutant behaves very much like the D132N, which blocks proton uptake through the D-channel. Single-turnover experiments show that the rate-limiting step in the reaction of O2 with the fully reduced G204D mutant is the F --> O transition, similar to the D132N mutant. The block of the D-channel in the D132N mutant can be partly bypassed by biochemically removing subunit III from the enzyme, indicating that removal of the subunit reveals an alternate entrance for protons to the channel. However, this is not observed with the G204D mutant. This suggests that the cryptic entrance to the D-channel that is revealed by the removal of subunit III is between the levels of G204 and D132.     

The binding domain on horse cytochrome c and Rhodobacter sphaeroides cytochrome c2 for the Rhodobacter sphaeroides cytochrome bc1 complex

The interaction of the Rhodobacter sphaeroides cytochrome bc1 complex with Rb. sphaeroides cytochrome c2 and horse cytochrome c was studied by using specific lysine modification and ionic strength dependence methods. The rate of the reactions with both cytochrome c and cytochrome c2 decreased rapidly with increasing ionic strength above 0.2 M NaCl. The ionic strength dependence suggested that electrostatic interactions were equally important to the reactions of the two cytochromes, even though they have opposite net charges at pH 7.0. In order to define the interaction domain on horse cytochrome c, the reaction rates of derivatives modified at single lysine amino groups with trifluoroacetyl or trifluoromethylphenylcarbamoyl were measured. Modification of lysine-8, -13, -27, -72, -79, and -87 surrounding the heme crevice was found to significantly lower the rate of the reaction, while modification of lysines in other regions had no effect. This result indicates that lysines surrounding the heme crevice of horse cytochrome c are involved in electrostatic interactions with carboxylate groups at the binding site on the cytochrome bc1 complex. In order to define the reaction domain on cytochrome c2, a fraction consisting of a mixture of singly labeled 4-carboxy-2,6-dinitrophenylcytochrome c2 derivatives modified at lysine-35, -88, -95, -97, and -105 and several unidentified lysines was prepared. Although it was not possible to resolve these derivatives, all of the identified lysines are located on the front surface of cytochrome c2 near the heme crevice. The rate of reaction of this fraction was significantly smaller than that of native cytochrome c2, suggesting that the binding domain on cytochrome c2 is also located at the heme crevice.(ABSTRACT TRUNCATED AT 250 WORDS)     

Blocking the K-pathway still allows rapid one-electron reduction of the binuclear center during the anaerobic reduction of the aa3-type cytochrome c oxidase from Rhodobacter sphaeroides

The K-pathway is one of the two proton-input channels required for function of cytochrome c oxidase. In the Rhodobacter sphaeroides cytochrome c oxidase, the K-channel starts at Glu101 in subunit II, which is at the surface of the protein exposed to the cytoplasm, and runs to Tyr288 at the heme a₃/Cu_B active site. Mutations of conserved, polar residues within the K-channel block or inhibit steady state oxidase activity. A large body of research has demonstrated that the K-channel is required to fully reduce the heme/Cu binuclear center, prior to the reaction with O₂, presumably by providing protons to stabilize the reduced metals (ferrous heme a₃ and cuprous Cu_B). However, there are conflicting reports which raise questions about whether blocking the K-channel blocks both electrons or only one electron from reaching the heme/Cu center. In the current work, the rate and extent of the anaerobic reduction of the heme/Cu center were monitored by optical and EPR spectroscopies, comparing the wild type and mutants that block the K-channel. The new data show that when the K-channel is blocked, one electron will still readily enter the binuclear center. The one-electron reduction of the resting oxidized (“O”) heme/Cu center of the K362M mutant, results in a partially reduced binuclear center in which the electron is distributed about evenly between heme a₃ and Cu_B in the R. sphaeroides oxidase. Complete reduction of the heme/Cu center requires the uptake of two protons which must be delivered through the K-channel.     

A functional hybrid between the cytochrome bc1 complex and its physiological membrane-anchored electron acceptor cytochrome cy in Rhodobacter capsulatus

The membrane integral ubihydroquinone (QH2): cytochrome (cyt) c oxidoreductase (or the cyt bc1 complex) and its physiological electron acceptor, the membrane-anchored cytochrome cy (cyt cy), are discrete components of photosynthetic and respiratory electron transport chains of purple non-sulfur, facultative phototrophic bacteria of Rhodobacter species. In Rhodobacter capsulatus, it has been observed previously that, depending on the growth condition, absence of the cyt bc1 complex is often correlated with a similar lack of cyt cy (Jenney, F. E., et al. (1994) Biochemistry 33, 2496-2502), as if these two membrane integral components form a non-transient larger structure. To probe whether such a structural super complex can exist in photosynthetic or respiratory membranes, we attempted to genetically fuse cyt cy to the cyt bc1 complex. Here, we report successful production, and initial characterization, of a functional cyt bc1-cy fusion complex that supports photosynthetic growth of an appropriate R. capsulatus mutant strain. The three-subunit cyt bc1-cy fusion complex has an unprecedented bis-heme cyt c1-cy subunit instead of the native mono-heme cyt c1, is efficiently matured and assembled, and can sustain cyclic electron transfer in situ. The remarkable ability of R. capsulatus cells to produce a cyt bc1-cy fusion complex supports the notion that structural super complexes between photosynthetic or respiratory components occur to ensure efficient cellular energy production.     

Sequence analysis of the cbb3 oxidases and an atomic model for the Rhodobacter sphaeroides enzyme

The cbb3-type oxidases are members of the heme-copper oxidase superfamily, distant by sequence comparisons, but sharing common functional characteristics. To understand the minimal common properties of the superfamily, and to learn about cbb3-type oxidases specifically, we have analyzed a wide set of heme-copper oxidase sequences and built a homology model of the catalytic subunit of the cbb3 oxidase from Rhodobacter sphaeroides. We conclude that with regard to the active site surroundings, the cbb3 oxidases greatly resemble the structurally known oxidases, while major differences are found in three segments: the additional N-terminal stretch of ca. 60 amino acids, the segment following helix 3 to the end of helix 5, and the C-terminus from helix 11 onward. The conserved core contains the active site tyrosine and also an analogue of the K-channel of proton transfer, but centered on a well-conserved histidine in the lower part of helix 7. Modeling the variant parts of the enzyme suggests that two periplasmic loops (between helices 3 and 4 and between helices 11 and 12) could interact with each other as a part of the active site structure and might have an important role in proton pumping. An analogue of the D-channel is not found, but an alternative channel might form around helix 9. A preliminary packing model of the trimeric enzyme is also presented.     

Membrane-associated cytochrome cy of Rhodobacter capsulatus is an electron carrier from the cytochrome bc1 complex to the cytochrome c oxidase during respiration.

We have recently established that the facultative phototrophic bacterium Rhodobacter capsulatus has two different pathways for reduction of the photooxidized reaction center during photosynthesis (F.E. Jenney and F. Daldal, EMBO J. 12:1283-1292, 1993; F.E. Jenney, R.C. Prince, and F. Daldal, Biochemistry 33:2496-2502, 1994). One pathway is via the well-characterized, water-soluble cytochrome c2 (cyt c2), and the other is via a novel membrane-associated c-type cytochrome named cyt cy. In this work, we probed the role of cyt cy in respiratory electron transport by isolating a set of R. capsulatus mutants lacking either cyt c2 or cyt cy, in the presence or in the absence of a functional quinol oxidase-dependent alternate respiratory pathway. The growth and inhibitor sensitivity patterns of these mutants, their respiratory rates in the presence of specific inhibitors, and the oxidation-reduction kinetics of c-type cytochromes monitored under appropriate conditions demonstrated that cyt cy, like cyt c2, connects the bc1 complex and the cyt c oxidase during respiratory electron transport. Whether cyt c2 and cyt cy are the only electron carriers between these two energy-transducing membrane complexes of R. capsulatus is unknown.     

Differential effects of glutamate-286 mutations in the aa(3)-type cytochrome c oxidase from Rhodobacter sphaeroides and the cytochrome bo(3) ubiquinol oxidase from Escherichia coli

Both the aa(3)-type cytochrome c oxidase from Rhodobacter sphaeroides (RsCcO(aa3)) and the closely related bo(3)-type ubiquinol oxidase from Escherichia coli (EcQO(bo3)) possess a proton-conducting D-channel that terminates at a glutamic acid, E286, which is critical for controlling proton transfer to the active site for oxygen chemistry and to a proton loading site for proton pumping. E286 mutations in each enzyme block proton flux and, therefore, inhibit oxidase function. In the current work, resonance Raman spectroscopy was used to show that the E286A and E286C mutations in RsCcO(aa3) result in long range conformational changes that influence the protein interactions with both heme a and heme a(3). Therefore, the severe reduction of the steady-state activity of the E286 mutants in RsCcO(aa3) to ~0.05% is not simply a result of the direct blockage of the D-channel, but it is also a consequence of the conformational changes induced by the mutations to heme a and to the heme a(3)-Cu(B) active site. In contrast, the E286C mutation of EcQO(bo3) exhibits no evidence of conformational changes at the two heme sites, indicating that its reduced activity (3%) is exclusively a result of the inhibition of proton transfer from the D-channel. We propose that in RsCcO(aa3), the E286 mutations severely perturb the active site through a close interaction with F282, which lies between E286 and the heme-copper active site. The local structure around E286 in EcQO(bo3) is different, providing a rationale for the very different effects of E286 mutations in the two enzymes. This article is part of a Special Issue entitled: Allosteric cooperativity in respiratory proteins.     

A novel membrane-associated c-type cytochrome, cyt cy, can mediate the photosynthetic growth of Rhodobacter capsulatus and Rhodobacter sphaeroides.

Mutants of Rhodobacter capsulatus lacking the soluble electron carrier cytochrome c2 are able to grow photosynthetically (Ps+), whereas Rhodobacter sphaeroides is unable to do so. To understand this unusual electron transfer pathway the gene required for cyt c2-independent growth of R.capsulatus was sought using chromosomal libraries derived from a cyt c2- mutant of this species to complement a Ps- cyt c2- mutant of R.sphaeroides to Ps+ growth. The complementing 1.2 kbp DNA fragment contained a gene, cycY, encoding a novel membrane-associated c-type cytochrome, cyt cy, based on predicted amino acid sequence, optical difference spectra and SDS-PAGE analysis of chromatophore membranes. The predicted primary sequence of cyt cy is unusual in having two distinct domains, a hydrophobic amino-terminal region and a carboxyl-terminus with strong homology to cytochromes c. A cyt cy- mutant of R.capsulatus remains Ps+ as does the cyt c2- mutant. However, a mutant lacking both cyt c2 and cy is Ps-, and can be complemented to Ps+ by either cyt c2 or cyt cy. These findings demonstrate that each of the cytochromes c2 and cy is essential for photosynthesis only in the absence of the other. Thus, two distinct electron transfer pathways, unrecognized until now, operate during photosynthesis in R.capsulatus under appropriate conditions, one via the soluble cyt c2 and the other via the membrane-associated cyt cy.     

Expression of a cytochrome c2 isozyme restores photosynthetic growth of Rhodobacter sphaeroides mutants lacking the wild-type cytochrome c2 gene

Deletion of the cytochrome c2 gene in the purple bacterium Rhodobacter sphaeroides renders it incapable of phototrophic growth (strain cycA65). However, suppressor mutants which restore the ability to grow phototrophically are obtained at relatively high frequency (1-10 in 10(7)). We examined two such suppressors (strains cycA65R5 and cycA65R7) and found the expected complement of electron transfer proteins minus cytochrome c2: SHP, c', c551.5, and c554. Instead of cytochrome c2 which elutes from DEAE-cellulose between SHP and cytochrome c', at about 50 mM ionic strength in wild-type extracts, we found a new high redox potential cytochrome c in the mutants which elutes with cytochrome c551.5 at about 150 mM ionic strength. The new cytochrome is more acidic than cytochrome c2, but is about the same size or slightly smaller (13,500 Da). The redox potential of the new cytochrome from strain cycA65R7 (294 mV) is about 70 mV lower than that of cytochrome c2. The 280 nm absorbance of the new cytochrome is smaller than that of cytochrome c2, which suggests that there is less tryptophan (the latter has two residues). In vitro kinetics of reduction by lumiflavin and FMN semiquinones show that the reactivity of the new cytochrome is similar to that of cytochrome c2, and that there is a relatively large positive charge (+2.6) at the site of reduction, despite the overall negative charge of the protein. This behavior is characteristic of cytochromes c2 and unlike the majority of bacterial cytochromes examined. Fourteen out of twenty-four of the N-terminal amino acids of the new cytochrome are identical to the sequence of cytochrome c2. The N-termini of the cycA65R5 and cycA65R7 cytochromes were the same. The kinetics and sequence data indicate that the new protein may be a cytochrome c2 isozyme, which is not detectable in wild-type cells under photosynthetic growth conditions. We propose the name iso-2 cytochrome c2 for the new cytochrome produced in the suppressor strains.     

Oxygen adaptation. The role of the CcoQ subunit of the cbb3 cytochrome c oxidase of Rhodobacter sphaeroides 2.4.1

The cbb(3) cytochrome c oxidase of Rhodobacter sphaeroides consists of four nonidentical subunits. Three subunits (CcoN, CcoO, and CcoP) comprise the catalytic "core" complex required for the reduction of O(2) and the oxidation of a c-type cytochrome. On the other hand, the functional role of subunit IV (CcoQ) of the cbb(3) oxidase was not obvious, although we previously suggested that it is involved in the signal transduction pathway controlling photosynthesis gene expression (Oh, J. I., and Kaplan, S. (1999) Biochemistry 38, 2688-2696). Here we go on to demonstrate that subunit IV protects the core complex, in the presence of O(2), from proteolytic degradation by a serine metalloprotease. In the absence of CcoQ, we suggest that the presence of O(2) leads to the loss of heme from the core complex, which destabilizes the cbb(3) oxidase into a "degradable" form, perhaps by altering its conformation. Under aerobic conditions the absence of CcoQ appears to affect the CcoP subunit most severely. It was further demonstrated, using a series of COOH-terminal deletion derivatives of CcoQ, that the minimum length of CcoQ required for stabilization of the core complex under aerobic conditions is the amino-terminal approximately 48-50 amino acids.     

Azorhizobium caulinodans uses both cytochrome bd (quinol) and cytochrome cbb3 (cytochrome c) terminal oxidases for symbiotic N2 fixation.

Azorhizobium caulinodans employs both cytochrome bd (cytbd; quinol oxidase) and cytcbb3 (cytc oxidase) as terminal oxidases in environments with very low O2 concentrations. To investigate physiological roles of these two terminal oxidases both in microaerobic culture and in symbiosis, knockout mutants were constructed. As evidenced by visible absorbance spectra taken from mutant bacteria carrying perfect gene replacements, both the cytbd- and cytcbb3- mutations were null alleles. In aerobic culture under 2% O2 atmosphere, Azorhizobium cytbd- and cytcbb3- single mutants both fixed N2 at 70 to 90% of wild-type rates; in root nodule symbiosis, both single mutants fixed N2 at 50% of wild-type rates. In contrast, Azorhizobium cytbd- cytcbb3-double mutants, which carry both null alleles, completely lacked symbiotic N2 fixation activity. Therefore, both Azorhizobium cytbd and cytcbb3 oxidases drive respiration in environments with nanomolar O2 concentrations during symbiotic N2 fixation. In culture under a 2% O2 atmosphere, Azorhizobium cytbd- cytcbb3- double mutants fixed N2 at 70% of wild-type rates, presumably reflecting cytaa3 and cytbo (and other) terminal oxidase activities. In microaerobic continuous cultures in rich medium, Azorhizobium cytbd- and cytcbb3- single mutants were compared for their ability to deplete a limiting-O2 sparge; cytbd oxidase activity maintained dissolved O2 at 3.6 microM steady state, whereas cytcbb3 oxidase activity depleted O2 to submicromolar levels. Growth rates reflected this difference; cytcbb3 oxidase activity disproportionately supported microaerobic growth. Paradoxically, in O2 limited continuous culture, Azorhizobium cytbd oxidase is inactive below 3.6 microM dissolved O2 whereas in Sesbania rostrata symbiotic nodules, in which physiological, dissolved O2 is maintained at 10 to 20 nM, both Azorhizobium cytbd and cytcbb3 seem to contribute equally as respiratory terminal oxidases.     

Product-controlled steady-state kinetics between cytochrome aa3 from Rhodobacter sphaeroides and equine ferrocytochrome c analyzed by a novel spectrophotometric approach

Cytochrome c oxidase (CcO) catalyzes the reduction of molecular oxygen to water using ferrocytochrome c (cyt c^2 +) as the electron donor. In this study, the oxidation of horse cyt c^2 + by CcO from Rhodobacter sphaeroides, was monitored using stopped-flow spectrophotometry. A novel analytic procedure was applied in which the spectra were deconvoluted into the reduced and oxidized forms of cyt c by a least-squares fitting method, yielding the reaction rates at various concentrations of cyt c^2 + and cyt c^3 +. This allowed an analysis of the effects of cyt c^3 + on the steady-state kinetics between CcO and cyt c^2 +. The results show that cyt c^3 + exhibits product inhibition by two mechanisms: competition with cyt c^2 + at the catalytic site and, in addition, an interaction at a second site which further modulates the reaction of cyt c^2 + at the catalytic site. These results are generally consistent with previous reports, indicating the reliability of the new procedure. We also find that a 6 × His-tag at the C-terminus of the subunit II of CcO affects the binding of cyt c at both sites. The approach presented here should be generally useful in spectrophotometric studies of complex enzyme kinetics. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).     

Replacing Asn207 by aspartate at the neck of the D channel in the aa3-type cytochrome c oxidase from Rhodobacter sphaeroides results in decoupling the proton pump

Cytochrome oxidase catalyzes the reduction of O2 to water and conserves the considerable free energy available from this reaction in the form of a proton motive force. For each electron, one proton is electrogenically pumped across the membrane. Of particular interest is the mechanism by which the proton pump operates. Previous studies of the oxidase from Rhodobacter sphaeroides have shown that all of the pumped protons enter the enzyme through the D channel and that a point mutant, N139D, in the D channel completely eliminates proton pumping without reducing oxidase activity. N139 is one of three asparagines near the entrance of the D channel, where there is a narrowing or neck, through which a single file of water molecules pass. In the current work, it is shown that replacement of a second asparagine in this region by an asparate, N207D, also decouples the proton pump without altering the oxidase activity of the enzyme. Previous studies demonstrated that the N139D mutant results in an increase in the apparent pKa of E286, a functionally critical residue that is located 20 A away from N139 at the opposite end of the D channel. In the current work, it is shown that the N207 mutation also increases the apparent pKa of E286. This finding reinforces the proposal that the elimination of proton pumping is the result of an increase of the apparent proton affinity of E286, which, in turn, prevents the timely proton transfer to a proton accepter group within the exit channel of the proton pump.     

X-ray structure determination of the cytochrome c2: reaction center electron transfer complex from Rhodobacter sphaeroides

In the photosynthetic bacterium Rhodobacter sphaeroides, a water soluble cytochrome c2 (cyt c2) is the electron donor to the reaction center (RC), the membrane-bound pigment-protein complex that is the site of the primary light-induced electron transfer. To determine the interactions important for docking and electron transfer within the transiently bound complex of the two proteins, RC and cyt c2 were co-crystallized in two monoclinic crystal forms. Cyt c2 reduces the photo-oxidized RC donor (D+), a bacteriochlorophyll dimer, in the co-crystals in approximately 0.9 micros, which is the same time as measured in solution. This provides strong evidence that the structure of the complex in the region of electron transfer is the same in the crystal and in solution. X-ray diffraction data were collected from co-crystals to a maximum resolution of 2.40 A and refined to an R-factor of 22% (R(free)=26%). The structure shows the cyt c2 to be positioned at the center of the periplasmic surface of the RC, with the heme edge located above the bacteriochlorophyll dimer. The distance between the closest atoms of the two cofactors is 8.4 A. The side-chain of Tyr L162 makes van der Waals contacts with both cofactors along the shortest intermolecular electron transfer pathway. The binding interface can be divided into two domains: (i) A short-range interaction domain that includes Tyr L162, and groups exhibiting non-polar interactions, hydrogen bonding, and a cation-pi interaction. This domain contributes to the strength and specificity of cyt c2 binding. (ii) A long-range, electrostatic interaction domain that contains solvated complementary charges on the RC and cyt c2. This domain, in addition to contributing to the binding, may help steer the unbound proteins toward the right conformation.     

Bioenergetics at extreme temperature: Thermus thermophilus ba3- and caa3-type cytochrome c oxidases

Seven years into the completion of the genome sequencing projects of the thermophilic bacterium Thermus thermophilus strains HB8 and HB27, many questions remain on its bioenergetic mechanisms. A key fact that is occasionally overlooked is that oxygen has a very limited solubility in water at high temperatures. The HB8 strain is a facultative anaerobe whereas its relative HB27 is strictly aerobic. This has been attributed to the absence of nitrate respiration genes from the HB27 genome that are carried on a mobilizable but highly-unstable plasmid. In T. thermophilus, the nitrate respiration complements the primary aerobic respiration. It is widely known that many organisms encode multiple biochemically-redundant components of the respiratory complexes. In this minireview, the presence of the two cytochrome c oxidases (CcO) in T. thermophilus, the ba₃- and caa₃-types, is outlined along with functional considerations. We argue for the distinct evolutionary histories of these two CcO including their respective genetic and molecular organizations, with the caa₃-oxidase subunits having been initially ‘fused’. Coupled with sequence analysis, the ba₃-oxidase crystal structure has provided evolutionary and functional information; for example, its subunit I is more closely related to archaeal sequences than bacterial and the substrate–enzyme interaction is hydrophobic as the elevated growth temperature weakens the electrostatic interactions common in mesophiles. Discussion on the role of cofactors in intra- and intermolecular electron transfer and proton pumping mechanism is also included. This article is part of a Special Issue entitled: Respiratory Oxidases.     

The cytochrome bc1 complex of Rhodobacter sphaeroides can restore cytochrome c2-independent photosynthetic growth to a Rhodobacter capsulatus mutant lacking cytochrome bc1.

Plasmids encoding the structural genes for the Rhodobacter capsulatus and Rhodobacter sphaeroides cytochrome (cyt) bc1 complexes were introduced into strains of R. capsulatus lacking the cyt bc1 complex, with and without cyt c2. The R. capsulatus merodiploids contained higher than wild-type levels of cyt bc1 complex, as evidenced by immunological and spectroscopic analyses. On the other hand, the R. sphaeroides-R. capsulatus hybrid merodiploids produced only barely detectable amounts of R. sphaeroides cyt bc1 complex in R. capsulatus. Nonetheless, when they contained cyt c2, they were capable of photosynthetic growth, as judged by the sensitivity of this growth to specific inhibitors of the photochemical reaction center and the cyt bc1 complex, such as atrazine, myxothiazol, and stigmatellin. Interestingly, in the absence of cyt c2, although the R. sphaeroides cyt bc1 complex was able to support the photosynthetic growth of a cyt bc1-less mutant of R. capsulatus in rich medium, it was unable to do so when C4 dicarboxylic acids, such as malate and succinate, were used as the sole carbon source. Even this conditional ability of R. sphaeroides cyt bc1 complex to replace that of R. capsulatus for photosynthetic growth suggests that in the latter species the cyt c2-independent rereduction of the reaction center is not due to a structural property unique to the R. capsulatus cyt bc1 complex. Similarly, the inability of R. sphaeroides to exhibit a similar pathway is not due to some inherent property of its cyt bc1 complex.