The Cu chaperone CopZ is required for Cu homeostasis in Rhodobacter capsulatus and influences cytochrome cbb3 oxidase assembly

Cu homeostasis depends on a tightly regulated network of proteins that transport or sequester Cu, preventing the accumulation of this toxic metal while sustaining Cu supply for cuproproteins. In Rhodobacter capsulatus, Cu‐detoxification and Cu delivery for cytochrome c oxidase (cbb₃‐Cox) assembly depend on two distinct Cu‐exporting P_1B‐type ATPases. The low‐affinity CopA is suggested to export excess Cu and the high‐affinity CcoI feeds Cu into a periplasmic Cu relay system required for cbb₃‐Cox biogenesis. In most organisms, CopA‐like ATPases receive Cu for export from small Cu chaperones like CopZ. However, whether these chaperones are also involved in Cu export via CcoI‐like ATPases is unknown. Here we identified a CopZ‐like chaperone in R. capsulatus, determined its cellular concentration and its Cu binding activity. Our data demonstrate that CopZ has a strong propensity to form redox‐sensitive dimers via two conserved cysteine residues. A ΔcopZ strain, like a ΔcopA strain, is Cu‐sensitive and accumulates intracellular Cu. In the absence of CopZ, cbb₃‐Cox activity is reduced, suggesting that CopZ not only supplies Cu to P_1B‐type ATPases for detoxification but also for cuproprotein assembly via CcoI. This finding was further supported by the identification of a ~150 kDa CcoI‐CopZ protein complex in native R. capsulatus membranes.     

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.     

Two conserved non-canonical histidines are essential for activity of the cbb 3-type oxidase in Rhodobacter capsulatus

Cytochrome cbb ₃ oxidase, a member of the heme–copper oxidase superfamily, catalyses the reduction of oxygen to water and generates a proton gradient. Cytochrome c oxidases are characterized by a catalytic subunit (subunit I) containing two hemes and one copper ion ligated by six invariant histidine residues, which are diagnostic of heme–copper oxidases in all type of the heme–copper oxidase superfamily. Alignments of the amino acid sequences of subunit I (FixN or CcoN) of the cbb ₃-type oxidases show that catalytic subunit also contains six non-canonical histidine residues that are conserved in all CcoN subunits of the cbb ₃ oxidase, but not the catalytic subunits of other members of heme–copper oxidases superfamily. The function of these six CcoN-specific conserved histidines of cbb ₃-type oxidase in R. capsulatus is unknown. To analyze the contribution of the two invariant histidines of CcoN, H300 and H394, in activity and assembly of the Rhodobacter capsulatus cbb ₃-type oxidase, they were substituted for valine and alanine, respectively by site-directed mutagenesis. H300V and H394A mutations were analyzed with respect to their activity and assembly. It was found that H394A mutation led to a defect in the assembly of both CcoP and CcoO in the membrane, which results in almost complete loss of activity and that although the H300V mutant is normally assembled in the membrane and retain their stability, its catalytic activity is significantly reduced when compared with wild-type oxidase.     

Mutagenesis of tyrosine residues within helix VII in subunit I of the cytochrome <Emphasis Type="Italic">cbb</Emphasis><Subscript>3</Subscript> oxidase from <Emphasis Type="Italic">Rhodobacter capsulatus</Emphasis>

The cbb ₃-type oxidases are members of the heme-copper oxidase superfamily, distant by sequence comparisons, but sharing common functional characteristics. The cbb ₃ oxidases are missing an active-site tyrosine residue that is absolutely conserved in all A and B-type heme-copper oxidases. This tyrosine is known to play a critical role in the catalytic mechanisms of A and B-type oxidases. The absence of this tyrosine in the cbb ₃ oxidases raises the possibility that the cbb ₃ oxidases utilize a different catalytic mechanism from that of the other members of the superfamily, or have this conserved residue in different helices. Recently sequence comparisons indicate that, a tyrosine residues that might be analogous to the active-site tyrosine in other oxidases are present in the cbb ₃ oxidases but these tyrosines originates from a different transmembrane helix within the protein. In this research, three conserved tyrosine residues, Y294, Y308 and Y318, in helix VII were substituted for phenylalanine. Y318F mutant in the Rhodobacter capsulatus oxidase resulted in a fully assembled enzyme with nativelike structure and activity, but Y294F mutant is not assembled and have a catalytic activity. On the other hand, Y308F mutant is fully assembled enzyme with nativelike structure, but lacking catalytic activity. This result indicates that Y308 should be crucial in catalytic activity of the cbb ₃ oxidase of R. capsulatus. These findings support the assumption that all of the heme-copper oxidases utilize the same catalytic mechanism and provide a residue originates from different places within the primary sequence for different members of the same superfamily.     

Biogenesis of cbb3-type cytochrome c oxidase in Rhodobacter capsulatus

The cbb₃-type cytochrome c oxidases (cbb₃-Cox) constitute the second most abundant cytochrome c oxidase (Cox) group after the mitochondrial-like aa₃-type Cox. They are present in bacteria only, and are considered to represent a primordial innovation in the domain of Eubacteria due to their phylogenetic distribution and their similarity to nitric oxide (NO) reductases. They are crucial for the onset of many anaerobic biological processes, such as anoxygenic photosynthesis or nitrogen fixation. In addition, they are prevalent in many pathogenic bacteria, and important for colonizing low oxygen tissues. Studies related to cbb₃-Cox provide a fascinating paradigm for the biogenesis of sophisticated oligomeric membrane proteins. Complex subunit maturation and assembly machineries, producing the c-type cytochromes and the binuclear heme b₃-Cu_B center, have to be coordinated precisely both temporally and spatially to yield a functional cbb₃-Cox enzyme. In this review we summarize our current knowledge on the structure, regulation and assembly of cbb₃-Cox, and provide a highly tentative model for cbb₃-Cox assembly and formation of its heme b₃-Cu_B binuclear center. This article is part of a Special Issue entitled: Biogenesis/Assembly of Respiratory Enzyme Complexes.     

Stability of the cbb3-type cytochrome oxidase requires specific CcoQ-CcoP interactions

Cytochrome cbb₃-type oxidases are members of the heme copper oxidase superfamily and are composed of four subunits. CcoN contains the heme b-Cu_B binuclear center where oxygen is reduced, while CcoP and CcoO are membrane-bound c-type cytochromes thought to channel electrons from the donor cytochrome into the binuclear center. Like many other bacterial members of this superfamily, the cytochrome cbb₃-type oxidase contains a fourth, non-cofactor-containing subunit, which is termed CcoQ. In the present study, we analyzed the role of CcoQ on the stability and activity of Rhodobacter capsulatus cbb₃-type oxidase. Our data showed that CcoQ is a single-spanning membrane protein with a N_out-C_in topology. In the absence of CcoQ, cbb₃-type oxidase activity is significantly reduced, irrespective of the growth conditions. Blue native polyacrylamide gel electrophoresis analyses revealed that the lack of CcoQ specifically impaired the stable recruitment of CcoP into the cbb₃-type oxidase complex. This suggested a specific CcoQ-CcoP interaction, which was confirmed by chemical cross-linking. Collectively, our data demonstrated that in R. capsulatus CcoQ was required for optimal cbb₃-type oxidase activity because it stabilized the interaction of CcoP with the CcoNO core complex, leading subsequently to the formation of the active 230-kDa cbb₃-type oxidase complex.     

CtpA,a Copper-translocating P-type ATPase Involved in the Biogenesis of Multiple Copper-requiring Enzymes

The ctpA (ccoI) gene product, a putative inner membrane copper-translocating P1B-type ATPase present in many bacteria, has been shown to be involved only in the cbb₃ assembly in Rhodobacter capsulatus and Bradyrhizobium japonicum. ctpA was disrupted in Rubrivivax gelatinosus, and the mutants showed a drastic decrease in both cbb₃ and caa₃ oxidase activities. Inactivation of ctpA results also in a decrease in the amount of the nitrous oxide reductase, NosZ. This pleiotropic phenotype could be partially rescued by excess copper in the medium, indicating that CtpA is likely a copper transporter that supplies copper-requiring proteins in the membrane with this metal. Although CtpA shares significant sequence homologies with the homeostasis copper efflux P1B-type ATPases including the bacterial CopA and the human ATP7A and ATP7B, disruption of ctpA did not result in any sensitivity to excess copper. This indicates that the CtpA is not crucial for copper tolerance but is involved in the assembly of membrane and periplasmic copper enzymes in this bacterium. The potential roles of CtpA in bacteria in comparison with CopA are discussed.     

cbb3-Type Cytochrome c Oxidases,Aerobic Respiratory Enzymes,Impact the Anaerobic Life of Pseudomonas aeruginosa PAO1

For bacteria, many studies have focused on the role of respiratory enzymes in energy conservation; however, their effect on cell behavior is poorly understood. Pseudomonas aeruginosa can perform both aerobic respiration and denitrification. Previous studies demonstrated that cbb₃-type cytochrome c oxidases that support aerobic respiration are more highly expressed in P. aeruginosa under anoxic conditions than are other aerobic respiratory enzymes. However, little is known about their role under such conditions. In this study, it was shown that cbb₃ oxidases of P. aeruginosa PAO1 alter anaerobic growth, the denitrification process, and cell morphology under anoxic conditions. Furthermore, biofilm formation was promoted by the cbb₃ oxidases under anoxic conditions. cbb₃ oxidases led to the accumulation of nitric oxide (NO), which is produced during denitrification. Cell elongation induced by NO accumulation was reported to be required for robust biofilm formation of P. aeruginosa PAO1 under anoxic conditions. Our data show that cbb₃ oxidases promote cell elongation by inducing NO accumulation during the denitrification process, which further leads to robust biofilms. Our findings show that cbb₃ oxidases, which have been well studied as aerobic respiratory enzymes, are also involved in denitrification and influence the lifestyle of P. aeruginosa PAO1 under anoxic conditions.     

A fresh view of the cell biology of copper in enterobacteria

Copper ions are essential but also very toxic. Copper resistance in bacteria is based on export of the toxic ion, oxidation from Cu(I) to Cu(II), and sequestration by copper‐binding metal chaperones, which deliver copper ions to efflux systems or metal‐binding sites of copper‐requiring proteins. In their publication in this issue, Osman et al. ( 2013 ) demonstrate how tightly copper resistance, homeostasis and delivery pathways are interwoven in Salmonella enterica sv. Typhimurium. Copper is transported from the cytoplasm by the two P‐type ATPases CopA and GolT to the periplasm and transferred to SodCII by CueP, a periplasmic copper chaperone. When copper levels are higher, SodCII is also able to bind copper without the help of CueP. This scheme raises the question as to why copper ions present in the growth medium have to make the detour through the cytoplasm. The data presented in the publication by Osman et al. ( 2013 ) change our view of the cell biology of copper in enterobacteria.     

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.     

Pleiotropic role of the Sco1/SenC family copper chaperone in the physiology of Streptomyces

Antibiotic production and cell differentiation in Streptomyces is stimulated by micromolar levels of Cu²⁺. Here, we knocked out the Sco1/SenC family copper chaperone (ScoC) encoded in the conserved gene cluster ‘sco’ (the S treptomycesco pper utilization) in Streptomyces coelicolor A3(2) and S. griseus. It is known that the Sco1/SenC family incorporates Cu²⁺ into the active centre of cytochrome oxidase (cox). The knockout caused a marked delay in antibiotic production and aerial mycelium formation on solid medium, temporal pH decline in glucose‐containing liquid medium, and significant reduction of cox activity in S. coelicolor. The scoC mutant produced two‐ to threefold higher cellular mass of the wild type exhibiting a marked cox activity in liquid medium supplied with 10 µM CuSO₄, suggesting that ScoC is involved in not only the construction but also the deactivation of cox. The scoC mutant was defective in the monoamine oxidase activity responsible for cell aggregation and sedimentation. These features were similarly observed with regard to the scoC mutant of S. griseus. The scoC mutant of S. griseus was also defective in the extracellular activity oxidizing N,N′‐dimethyl‐p‐phenylenediamine sulfate. Addition of 10 µM CuSO₄ repressed the activity of the conserved promoter preceding scoA and caused phenylalanine auxotrophy in some Streptomyces spp. probably because of the repression of pheA; pheA encodes prephenate dehydratase, which is located at the 3′ terminus of the putative operon structure. Overall, the evidence indicates that Sco is crucial for the utilization of copper under a low‐copper condition and for the activation of the multiple Cu²⁺‐containing oxidases that play divergent roles in the complex physiology of Streptomyces.     

Structural and functional analysis of aa3-type and cbb3-type cytochrome c oxidases of Paracoccus denitrificans reveals significant differences in proton-pump design

In Paracoccusdenitrificans the aa₃-type cytochrome c oxidase and the bb₃-type quinol oxidase have previously been characterized in detail, both biochemically and genetically. Here we report on the isolation of a genomic locus that harbours the gene cluster ccoNOQP, and demonstrate that it encodes an alternative cbb₃-type cytochrome c oxidase. This oxidase has previously been shown to be specifically induced at low oxygen tensions, suggesting that its expression is controlled by an oxygen-sensing mechanism. This view is corroborated by the observation that the ccoNOQP gene cluster is preceded by a gene that encodes an FNR homologue and that its promoter region contains an FNR-binding motif. Biochemical and physiological analyses of a set of oxidase mutants revealed that, at least under the conditions tested, cytochromes aa₃, bb₃. and cbb₃ make up the complete set of terminal oxidases in P. denitrificans. Proton-translocation measurements of these oxidase mutants indicate that all three oxidase types have the capacity to pump protons. Previously, however, we have reported decreased H⁺/e coupling efficiencies of the cbb₃-type     

Functional analysis of the copy 1 of the fixNOQP operon of Ensifer meliloti under free‐living micro‐oxic and symbiotic conditions

Aim

In this work, phenotypic analyses of a Ensifer meliloti fixN1 mutant under free‐living and symbiotic conditions have been carried out.

Methods and Results

Ensifer meliloti fixN1 mutant showed a defect in growth as well as in TMPD‐dependent oxidase activity when cells were incubated under micro‐oxic conditions. Furthermore, haem c staining analyses of a fixN1 and a fixP1 mutant identified two membrane‐bound c‐type cytochromes of 27 and 32 kDa, present in microaerobically grown cells and in bacteroids, as the FixO and FixP components of the E. meliloti cbb₃ oxidase. Under symbiotic conditions, fixN1 mutant showed a clear nitrogen fixation defect in alfalfa plants that were grown in an N‐free nutrient solution during 3 weeks. However, in plants grown for a longer period, fixNOQP1 copy was not indispensable for symbiotic nitrogen fixation.

Conclusions

The copy 1 of the fixNOQP operon is involved in E. meliloti respiration and growth under micro‐oxic conditions as well as in the expression of the FixO and FixP components of the cbb₃ oxidase present in free‐living microaerobic cultures and in bacteroids. This copy is important for nitrogen fixation during the early steps of the symbiosis.

Significance and Impact of the Study

It is the first time that a functional analysis of the E. meliloti copy 1 of the fixNOQP operon is performed. In this work, the cytochromes c that constitute the cbb₃ oxidase operating in free‐living micro‐oxic cultures and in bacteroids of E. meliloti have been identified.     

Isolation and Characterization of Rhodobacter capsulatus Mutants Affected in Cytochrome cbb3 Oxidase Activity

The facultative phototrophic bacterium Rhodobacter capsulatus contains only one form of cytochrome (cyt) c oxidase, which has recently been identified as a cbb₃-type cyt c oxidase. This is unlike other related species, such as Rhodobacter sphaeroides and Paracoccus denitrificans, which contain an additional mitochondrial-like aa₃-type cyt c oxidase. An extensive search for mutants affected in cyt c oxidase activity in R. capsulatus led to the isolation of at least five classes of mutants. Plasmids complementing them to a wild-type phenotype were obtained for all but one of these classes from a chromosomal DNA library. The first class of mutants contained mutations within the structural genes (ccoNOQP) of the cyt cbb₃ oxidase. Sequence analysis of these mutants and of the plasmids complementing them revealed that ccoNOQP in R. capsulatus is not flanked by the oxygen response regulator fnr, which is located upstream of these genes in other species. Genetic and biochemical characterizations of mutants belonging to this group indicated that the subunits CcoN, CcoO, and CcoP are required for the presence of an active cyt cbb₃ oxidase, and unlike in Bradyrhizobium japonicum, no active CcoN-CcoO subcomplex was found in R. capsulatus. In addition, mutagenesis experiments indicated that the highly conserved open reading frame 277 located adjacent to ccoNOQP is required neither for cyt cbb₃ oxidase activity or assembly nor for respiratory or photosynthetic energy transduction in R. capsulatus. The remaining cyt c oxidase-minus mutants mapped outside of ccoNOQP and formed four additional groups. In one of these groups, a fully assembled but inactive cyt cbb₃ oxidase was found, while another group had only extremely small amounts of it. The next group was characterized by a pleiotropic effect on all membrane-bound c-type cytochromes, and the remaining mutants not complemented by the plasmids complementing the first four groups formed at least one additional group affecting the biogenesis of the cyt cbb₃ oxidase of R. capsulatus.The gram-negative facultative photosynthetic bacterium Rhodobacter capsulatus has a highly branched electron transport chain, resulting in its ability to grow under a wide variety of conditions (52). Its light-driven photosynthetic electron transfer pathway is a cyclic process between the photochemical reaction center and the ubihydroquinone cytochrome (cyt) c oxidoreductase (cyt bc₁ complex) (30). On the other hand, the respiratory electron transfer pathways of R. capsulatus are branched after the quinone pool and contain two different terminal oxidases, previously called cyt b₄₁₀ (cyt c oxidase) and cyt b₂₆₀ (quinol oxidase) (3, 27, 29, 53). The branch involving cyt c oxidase is similar to the mitochondrial electron transfer chain in that it depends on the cyt bc₁ complex and a c-type cyt acting as an electron carrier. The quinol oxidase branch circumvents the cyt bc₁ complex and the cyt c oxidase by taking electrons directly from the quinone pool to reduce O₂ to H₂O. The pronounced metabolic versatility, including the ability to grow under dark, anaerobic conditions (50, 52), makes these purple non-sulfur bacteria excellent model organisms for studying microbial energy transduction.Marrs and Gest (29) have reported the first R. capsulatus mutants which were defective in the respiratory electron transport chain. Of these mutants, M5 was incapable of catalyzing the α-naphthol plus N′,N′-dimethyl-p-phenylenediamine (DMPD) plus O₂→indophenol blue plus H₂O reaction (NADI reaction) and unable to grow by respiration (Res⁻), and hence was deficient in both terminal oxidases. Another mutant, M4, was also NADI⁻ but Res⁺ due to the presence of an active quinol oxidase. Marrs and Gest have also described two different spontaneous revertants of M5, called M6 and M7, which regained the ability to grow by respiration (29). M6 regained cyt c oxidase activity and became concurrently NADI⁺ and sensitive to low concentrations of cyanide and the cyt bc₁ inhibitor myxothiazol, but remained quinol oxidase⁻. On the other hand, M7 regained the quinol oxidase activity but remained cyt c oxidase⁻ (thus, NADI⁻ and resistant to myxothiazol, a phenotype identical to that of M4). All of these mutants remained proficient for phototrophic (Ps) growth.The cyt c oxidase of R. capsulatus has been purified previously and characterized as being a novel cbb₃-type cyt c oxidase without a Cu_A center (15). It is composed of at least a membrane-integral b-type cyt (subunit I [CcoN]) with a low-spin heme b and a high-spin heme b₃-Cu_B binuclear center, and two membrane-anchored c-type cyts (CcoO and CcoP). It has a unique active site that possibly confers a very high affinity for its substrate oxygen (49). The structural genes of this enzyme (ccoNOQP) have been sequenced recently from R. capsulatus 37b4 (45) and aligned to the partial amino acid sequence of the purified enzyme from R. capsulatus MT1131 (15). Although a ccoN mutant of strain 37b4 was reported to lack cyt c oxidase activity (45), the observed discrepancies between the amino acid sequence and the nucleotide sequence do not entirely exclude the possible presence of two similar cb-type cyt c oxidases in this species. The presence of a similar cyt c oxidase has also been demonstrated in several other bacteria, including P. denitrificans (9), R. sphaeroides (13), and Rhizobium spp. In the latter species, the homologs of ccoNOQP have been named fixNOQP (23, 34) and are required to support respiration under oxygen-limited growth during symbiotic nitrogen fixation (36).The biogenesis of a multisubunit protein complex containing several prosthetic groups, such as cyt cbb₃ oxidase, is likely to require many accessory proteins involved in various posttranslational events, including protein translocation, assembly, cofactor insertion, and maturation (46). Thus, insights into this important biological process, about which currently little is known, may be gained by searching for mutants defective in cyt c oxidase activity. In this work, we describe the isolation of such mutants and their molecular genetic characterization, including those already available, such as M4, M5, and M7G. These studies indicate that in R. capsulatus, gene products of at least five different loci are involved in the formation of an active cyt cbb₃ oxidase.     

A decade of crystallization drops: Crystallization of the cbb3 cytochrome c oxidase from Pseudomonas stutzeri

The cbb₃ cytochrome c oxidases are distant members of the superfamily of heme copper oxidases. These terminal oxidases couple O₂ reduction with proton transport across the plasma membrane and, as a part of the respiratory chain, contribute to the generation of an electrochemical proton gradient. Compared with other structurally characterized members of the heme copper oxidases, the recently determined cbb₃ oxidase structure at 3.2 Å resolution revealed significant differences in the electron supply system, the proton conducting pathways and the coupling of O₂ reduction to proton translocation. In this paper, we present a detailed report on the key steps for structure determination. Improvement of the protein quality was achieved by optimization of the number of lipids attached to the protein as well as the separation of two cbb₃ oxidase isoenzymes. The exchange of n‐dodecyl‐β‐d ‐maltoside for a precisely defined mixture of two α‐maltosides and decanoylsucrose as well as the choice of the crystallization method had a most profound impact on crystal quality. This report highlights problems frequently encountered in membrane protein crystallization and offers meaningful approaches to improve crystal quality.     

Adaptation to Oxygen: ROLE OF TERMINAL OXIDASES IN PHOTOSYNTHESIS INITIATION IN THE PURPLE PHOTOSYNTHETIC BACTERIUM,RUBRIVIVAX GELATINOSUS*

The appearance of oxygen in the Earth''s atmosphere via oxygenic photosynthesis required strict anaerobes and obligate phototrophs to cope with the presence of this toxic molecule. Here we show that in the anoxygenic phototroph Rubrivivax gelatinosus, the terminal oxidases (cbb₃, bd, and caa₃) expand the range of ambient oxygen tensions under which the organism can initiate photosynthesis. Unlike the wild type, the cbb₃⁻/bd⁻ double mutant can start photosynthesis only in deoxygenated medium or when oxygen is removed, either by sparging cultures with nitrogen or by co-inoculation with strict aerobes bacteria. In oxygenated environments, this mutant survives nonphotosynthetically until the O₂ tension is reduced. The cbb₃ and bd oxidases are therefore required not only for respiration but also for reduction of the environmental O₂ pressure prior to anaerobic photosynthesis. Suppressor mutations that restore respiration simultaneously restore photosynthesis in nondeoxygenated medium. Furthermore, induction of photosystem in the cbb₃⁻ mutant led to a highly unstable strain. These results demonstrate that photosynthetic metabolism in environments exposed to oxygen is critically dependent on the O₂-detoxifying action of terminal oxidases.     

The ccoNOQP gene cluster codes for a cb-type cytochrome oxidase that functions in aerobic respiration of Rhodobacter capsulatus

The genes for a new type of a haem-copper cytochrome oxidase were cloned from Rhodobacter capsulatus strain 37b4, using the Bradyrhizobium japonicum fixNOQP gene region as a hybridizing probe. Four genes, probably organized in an operon (ccoNOQP), were identified; their products share extensive amino acid sequence similarity with the FixN, O, Q and P proteins that have recently been shown to be the subunits of a cb-type oxidase. CcoN is a c-type cytochrome, CcoO and CcoP are membrane-bound mono- and dihaem c-type cytochromes and CcoQ is a small membrane protein of unknown function. Genes for a similar oxidase are also present in other non-rhizobial bacterial species such as Azoto-bacter vinelandii, Agrobacterium tumefaciens and Pseudomonas aeruginosa, as revealed by polymerase chain reaction analysis. A ccoN mutant was constructed whose phenotype, in combination with the structural information on the gene products, provides evidence that the CcoNOQP oxidase is a cytochrome c oxidase of the cb type, which supports aerobic respiration in R. capsulatus and which is probably identical to the cbb₃-type oxidase that was recently purified from a different strain of the same species. Mutant analysis also showed that this oxidase has no influence on photosynthetic growth and nitrogen-fixation activity.