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

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

Mechanistic and phenomenological features of proton pumps in the respiratory chain of mitochondria

Various direct, indirect (kinetic and thermodynamic), and combined mechanisms have been proposed to explain the conversion of redox energy into a transmembrane protonmotive force (p) by enzymatic complexes of respiratory chains. The conceptual evolution of these models is examined. The characteristics of thermodynamic coupling between redox transitions of electron carriers and scalar proton transfer in cytochromec oxidase and its possible involvement in proton pumping is discussed. Other aspects dealt with in this paper are: (i) variability of H⁺/e ^– stoichiometries, in cytochromec oxidase and cytochromec reductase and its mechanistic implications; (ii) possible models by which the reduction of dioxygen to water at the binuclear heme-copper center of protonmotive oxidases can be directly involved in proton pumping. Finally a unifying concept for proton pumping by the redox complexes of respiratory chain is presented.     

Differential exposure of components of cytochromeb−c 1 region in beef heart mitochondria and electron transport particles

The reduction of cyctochromesc +c ₁ by durohydroquinone and ferrocyanide in electron transport particles (ETP) and intact cytochromec-depleted beef heart mitochondria has been studied. At least 94% of the ETP are in an inverted orientation. Durohydroquinone reduces 80% ofc +c ₁ in ETP but less than 20% in mitochondria; sonication of mitochondria allows reduction of cytochromesc +c ₁ (80%). Addition of ferrocyanide (effective redox potential +245 mV) to electron transport particles results in 30% reduction of cytochromesc +c ₁. Addition of ferrocyanide to intact cytochromec-depleted mitochondria does not reduce cytochromec ₁; treatment withN,N,N,N-tetramethylphenylenediamine, Triton X-100, or sonic oscillation results in 30% reduction of cytochromesc +c ₁. TheK _m value of ferrocyanide oxidase for K-ferrocyanide is pH-dependent in ETP only, increasing with increasing pH. The extent of reduction of cytochromec ₁ is also pH-dependent in ETP only, the extent of reduction increasing with decreasing pH. On the basis of these data cytochromec ₁ is exposed to the matrix face and cytochromec is exposed to the cytoplasmic face. No redox center other than cytochromec in the segment between the antimycin site and cytochromec is exposed on the C-side.Abbreviations Used: MES, 2(N-morpholino)-ethanesulfonic acid; EDTA, ethylenediaminetetraacetic acid; TMPD,N,N,N,N-tetramethylphenylenediamine; ETP, electron transport particles; NAD-NADH, nicotinamide adenine dinucleotide; PMS, phenazine methosulfate.     

Biogenesis of mitochondrialc-type cytochromes

Cytochromesc andc ₁ are essential components of the mitochondrial respiratory chain. In both cytochromes the heme group is covalently linked to the polypeptide chain via thioether bridges. The location of the two cytochromes is in the intermembrane space; cytochromec is loosely attached to the surface of the inner mitochondrial membrane, whereas cytochromec ₁ is firmly anchored to the inner membrane. Both cytochromec andc ₁ are encoded by nuclear genes, translated on cytoplasmic ribosomes, and are transported into the mitochondria where they become covalently modified and assembled. Despite the many similarities, the import pathways of cytochromec andc ₁ are drastically different. Cytochromec ₁ is made as a precursor with a complex bipartite presequence. In a first step the precursor is directed across outer and inner membranes to the matrix compartment of the mitochondria where cleavage of the first part of the presequence takes place. In a following step the intermediate-size form is redirected across the inner membrane; heme addition then occurs on the surface of the inner membrane followed by the second processing reaction. The import pathway of cytochromec is exceptional in practically all aspects, in comparison with the general import pathway into mitochondria. Cytochromec is synthesized as apocytochromec without any additional sequence. It is translocated selectively across the outer membrane. Addition of the heme group, catalyzed by cytochromec heme lyase, is a requirement for transport. In summary, cytochromec ₁ import appears to follow a conservative pathway reflecting features of cytochromec ₁ sorting in prokaryotic cells. In contrast, cytochromec has invented a rather unique pathway which is essentially non-conservative.     

Isolation,sequencing and mutational analysis of a gene cluster involved in nitrite reduction inParacoccus denitrificans

By using the gene encoding the C-terminal part of thecd ₁-type nitrite reductase ofPseudomonas stutzeri JM300 as a heterologous probe, the corresponding gene fromParacoccus denitrificans was isolated. This gene,nirS, codes for a mature protein of 63144 Da having high homology withcd ₁-type nitrite reductases from other bacteria. Directly downstream fromnirS, three othernir genes were found in the ordernirECF. The organization of thenir gene cluster inPa. denitrificans is different from the organization ofnir clusters in some Pseudomonads.nirE has high homology with a S-adenosyl-L-methionine:uroporphyrinogen III methyltransferase (uro'gen III methylase). This methylase is most likely involved in the hemed ₁ biosynthesis inPa. denitrificans. The third gene,nirC, codes for a small cytochromec of 9.3 kDa having high homology with cytochromec _55X ofPs. stutzeri ZoBell. The 4th gene,nirF, has no homology with other genes in the sequence databases and has no relevant motifs. Inactivation of either of these 4 genes resulted in the loss of nitrite and nitric oxide reductase activities but not of nitrous oxide reductase activity.nirS mutants lack thecd ₁-type nitrite reductase whilenirE, nirC andnirF mutants produce a small amount ofcd ₁-type nitrite reductase, inactive due to the absence of hemed ₁. Upstream from thenirS gene the start of a gene was identified which has limited homology withnosR, a putative regulatory gene involved in nitrous oxide reduction. A potential FNR box was identified between this gene andnirS.Abbreviations SDS sodium dodecyl sulfate - NBT nitroblue tetrazolium - PAGE polyacrylamide gel electrophoresis     

Genes coding for cytochromec oxidase inParacoccus denitrificans

Several loci on theParacoccus denitrificans chromosome are involved in the synthesis of cytochromec oxidase. So far three genetic loci have been isolated. One of them contains the structural genes of subunits II and III, as well as two regulatory genes which probably code for oxidase-specific assembly factors. In addition, two distinct genes for subunit I have been cloned, one of which is located adjacent to the cytochromec ₅₅₀ gene. An alignment of six promoter regions reveals only short common sequences.     

C1 metabolism inParacoccus denitrificans: Genetics ofParacoccus denitrificans

Paracoccus denitrificans is able to grow on the C₁ compounds methanol and methylamine. These compounds are oxidized to formaldehyde which is subsequently oxidized via formate to carbon dioxide. Biomass is produced by carbon dioxide fixation via the ribulose biphosphate pathway. The first oxidation reaction is catalyzed by the enzymes methanol dehydrogenase and methylamine dehydrogenase, respectively. Both enzymes contain two different subunits in an ₂₂ configuration. The genes encoding the subunits of methanol dehydrogenase (moxF andmoxI) have been isolated and sequenced. They are located in one operon together with two other genes (moxJ andmoxG) in the gene ordermoxFJGI. The function of themoxJ gene product is not yet known.MoxG codes for a cytochromec _551i , which functions as the electron acceptor of methanol dehydrogenase. Both methanol dehydrogenase and methylamine dehydrogenase contain PQQ as a cofactor. These so-called quinoproteins are able to catalyze redox reactions by one-electron steps. The reaction mechanism of this oxidation will be described. Electrons from the oxidation reaction are donated to the electron transport chain at the level of cytochromec. P. denitrificans is able to synthesize at least 10 differentc-type cytochromes. Five could be detected in the periplasm and five have been found in the cytoplasmic membrane. The membrane-bound cytochromec ₁ and cytochromec ₅₅₂ and the periplasmic-located cytochromec ₅₅₀ are present under all tested growth conditions. The cytochromesc _551i andc _553i , present in the periplasm, are only induced in cells grown on methanol, methylamine, or choline. The otherc-type cytochromes are mainly detected either under oxygen limited conditions or under anaerobic conditions with nitrate as electron acceptor or under both conditions. An overview including the induction pattern of allP. denitrificans c-type cytochromes will be given. The genes encoding cytochromec ₁, cytochromec ₅₅₀, cytochromec _551i , and cytochromec _553i have been isolated and sequenced. By using site-directed mutagenesis these genes were mutated in the genome. The mutants thus obtained were used to study electron transport during growth on C₁ compounds. This electron transport has also been studied by determining electron transfer rates inin vitro experiments. The exact pathways, however, are not yet fully understood. Electrons from methanol dehydrogenase are donated to cytochromec _551i . Further electron transport is either via cytochromec ₅₅₀ or cytochromec _553i to cytochromeaa ₃. However, direct electron transport from cytochromec _551i to the terminal oxidase might be possible as well. Electrons from methylamine dehydrogenase are donated to amicyanin and then via cytochromec ₅₅₀ to cytochromeaa ₃, but other routes are used also.P. denitrificans is studied by several groups by using a genetic approach. Several genes have already been cloned and sequenced and a lot of mutants have been isolated. The development of a host/vector system and several techniques for mutation induction that are used inP. denitrificans genetics will be described.     

Activation studies by phospholipids on the purified cytochromec 4:o oxidase ofAzotobacter vinelandii

A modified procedure is described that was used to solubilize and purify the TMPD-dependent cytochromec ₄:o oxidase fromAzotobacter vinelandii. Two functional components (Fractions I and V) were obtained after DEAE-cellulose chromatography. Fraction V contained both cytochromec ₄ (3.6 nmol/mg protein) and cytochromeo (1.6 nmol/mg protein). This cytochrome oxidase complex oxidized TMPD at moderate rates. Fraction I, a clear greenish-yellow fraction, contained primarily phosphatidylethanolamine with some phosphatidylglycerol. Fraction I itself could not oxidize TMPD, but when it was preincubated with Fraction V, a 2–4-fold stimulation in TMPD oxidase activity occurred. Other authentic micellar phospholipids also readily activited TMPD oxidase activity in Fraction V. Themaximum activation effect obtained with Fraction I was in essence duplicated with purified phosphatidylethanolamine.Dedicated to the memory of David E. Green, a fine gentleman, an excellent scientist, and a true scholar. He will be missed by many of his former colleagues.     

Interaction of horse cytochromec with the photosynthetic reaction center ofRhodospirillum rubrum

Mitochondrial cytochromec (horse), which is a very efficient electron donor to bacterial photosynthetic reaction centersin vitro, binds to the reaction center ofRhodospirillum rubrum with an approximate dissociation constant of 0.3–0.5 µM at pH 8.2 and low ionic strength. The binding site for the reaction center is on the frontside of cytochromec which is the side with the exposed heme edge, as revealed by differential chemical acetylation of lysines of free and reaction-center-bound cytochromec. In contrast, bacterial cytochromec ₂ was found previously to bind to the detergent-solubilized reaction center through its backside, i.e., the side opposite to the heme cleft [Rieder, R., Wiemken, V., Bachofen, R., and Bosshard, H. R. (1985).Biochem. Biophys. Res. Commun. 128, 120–126]. Binding of mitochondrial cytochromec but not of mitochondrial cytochromec ₂ is strongly inhibited by low concentrations of poly-l-lysine. The results are difficult to reconcile with the existence of an electron transfer site on the backside of cytochromec ₂.     

Formation of active nitrite reductase (cytochromecd 1) in the strainParacoccus denitrificans HUUG25

Strain HUUG25 ofParacoccus denitrificans has been frequently thought to be devoid of allc-type cytochromes. We show here by means of enzymological and immunological techniques that the mutant synthesizes active nitrite reductase (cytochromecd ₁) upon prolonged exposure to microoxic conditions. The synthesis occurred faster in the presence of exogenous hemin. The time pattern of 5-aminolevulinate synthase activity was also altered by the mutation. These findings suggest a defective regulation of heme supply to the site of nitrite reductase assembly in the periplasm.     

Cytochromec oxidase inParacoccus denitrificans. Protein,chemical, structural,and evolutionary aspects

Preparations and protein chemical characterizations performed with cytochromec oxidase (E.C. 1.9.3.1) from the purple bacteriumParacoccus denitrificans are reviewed. The simplest catalytically competent complex of the enzyme consists of two subunits of 62012 and 27999 Da. The theoretical hemea/protein ratio of the purified enzyme is 22.0 nmol/mg. The amino acid sequences of both proteins are compared with examples of subunits I and II of mitochondrial terminal oxidases from the main kingdoms of eukaryotes. The significance of the emerging conserved features such as membrane penetration patterns, invariant residues, stoichiometry, and sites of prosthetic groups are discussed. TheParacoccus enzyme represents the only prokaryotic oxidase detailed so far, which is directly related to the mitochondrial oxidases by common ancestry in the growing O₂ atmosphere.     

Cytochromec oxidase fromParacoccus denitrificans in Triton X-100: Aggregation state and kinetics

Cytochromec oxidase fromParacoccus denitrificans was homogenously dispersed in Triton X-100. Using gel exclusion chromatography and sucrose gradient centrifugation analysis a molecular weight of the detergent-protein complex of 155,000 was determined. After subtraction of the bound detergent (111 mol/mol hemeaa ₃) a molecular weight of 85,000 resulted, which agreed well with the model of a monomer containing two subunits. This monomer showed high cytochromec oxidase activity when measured spectrophotometrically in the presence of Triton X-100 (V _max=85 s^–1). The molecular activity, plotted according to Eadie-Hofstee, was monophasic as a function of the cytochromec concentration. AK _m of 3.6×10^–6 M was evaluated, similar to theK _m observed in the presence of dodecyl maltoside [Naeczet al. (1985).Biochim. Biophys. Acta 808, 259–272].     

Metabolic pathways inParacoccus denitrificans and closely related bacteria in relation to the phylogeny of prokaryotes

Denitrification and methylotrophy inParacoccus denitrificans are discussed. The properties of the enzymes of denitrification: the nitrate-nitrite antiporter, nitrate reductase, nitrite reductase, nitric oxide reductase and nitrous oxide reductase are described. The genes for none of these proteins have yet been cloned and sequenced fromP. denitrificans. A number of sequences are available for enzymes fromEscherichia coli, Pseudomonas stutzeri andPseudomonas aeruginosa. It is concluded that pathway specificc-type cytochromes are involved in denitrification. At least 40 genes are involved in denitrification.In methanol oxidation at least 20 genes are involved. In this case too pathway specificc-type cytochromes are involved. The sequence homology between the quinoproteins methanol dehydrogenase, alcoholdehydrogenase and glucose dehydrogenase is discussed. This superfamily of proteins is believed to be derived from a common ancestor. ThemoxFJGI operon determines the structural components of methanol dehydrogenase and the associatedc-type cytochrome. Upstream of this operon 3 regulatory proteins were found. The mox Y protein shows the general features of a sensor protein and the moxX protein those of a regulatory protein. Thus a two component regulatory system is involved in both denitrification and methylotrophy.The phylogeny of prokaryotes based on 16S rRNA sequence is discussed. It is remarkable that the 16S rRNA ofThiosphaera pantotropha is identical to that ofP. denitrificans. Still these bacteria show a number of differences.T. pantotropha is able to denitrify under aerobic circumstances and it shows heterotrophic nitrification. Nitrification and heterotrophic nitrification are found in species belonging to the -and -subdivisions of purple non-sulfur bacteria. Thus the occurrence of heterotrophic nitrification inT. pantotropha which belongs to the -subdivision of purple non-sulfur bacteria is a remarkable property. FurthermoreT. pantotropha contains two nitrate reductases of which the periplasmic one is supposed to be involved in aerobic denitrification. The nitrite reductase is of the Cu-type and not of the cytochromecd ₁ type as inP. denitrificans. Also the cytochromeb of theQbc complex ofT. pantotropha is highly similar to its counterpart inP. denitrificans. It is hypothesized that the differences between these two organisms which both contain large megaplasmids is due to a combination of loss of genetic information and plasmid-coded properties. The distribution of a number of complex metabolic systems in eubacteria and in a number of species belonging to the -group of purple non sulphur bacteria is reviewed. Two possibilities to explain this haphazard distribution are considered: 1. Lateral gene transfer between distantly related micro organisms occurs frequently. 2. The eubacterial ancestors must have possessed already these properties. The distribution of these properties is due to sporadic loss during evolutionary divergence.With respect to the occurrence and frequency of lateral gene transfer two opposing views exist. According to molecular biologists lateral gene transfer occurs frequently and is very easy. Bacteria are supposed to form one large gene pool. On the other hand population geneticists have provided evidence that strong systems operate that establish reproductive isolation between diverged species and even between closely related cell lines.Data on amino acid sequences of nitrogenase proteins, cytochromesc, cytochrome oxidases, -subunits of ATP synthase and tryptophan biosynthetic enzymes of various micro organisms were reviewed. In all these cases phylogenetic trees could be constructed based on the amino acid sequence data. In all cases this phylogenetic tree was similar to the one based on 16S rRNA homology. Only in one case evidence for the occurrence of lateral gene transfer was obtained. Therefore it is concluded that lateral gene transfer played a minor role in the distribution of complex metabolic systems among prokaryotes. It must be stressed that this does not exclude the possibility that lateral gene transfer occurred frequently in the initial stage of bacterial evolution. It is hypothesized that the appearance of nitrogen fixation, denitrification and cytochrome oxidase formation were early events in the evolution of micro organisms. Both systems are supposed to have evolved only once. Subsequently the capacity to fix nitrogen or to denitrifymust have been lost many times, just as photosynthetic capacity is supposed to have been lost many times. During evolution many systems have been lost leading to a haphazard distribution of metabolic characters among bacteria. As an example it is suggested that organisms with a respiratory chain similar to that ofEscherichia coli arose by loss of the capacity to form the Qbc complex andc-type cytochromes. The remaining systems could be controlled much better however than in the ancestral organisms.     

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

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

Cytochromec oxidase ofEuglena gracilis: Purification,characterization, and identification of mitochondrially synthesized subunits

Cytochromec oxidase was purified from mitochondria ofEuglena gracilis and separated into 15 different polypeptide subunits by polyacrylamide gel electrophoresis. All 15 subunits copurify through various purification procedures, and the subunit composition of the isolated enzyme is identical to that of the immunoprecipitated one. Therefore, the 15 protein subunits represent integral components of theEuglena oxidase. In anin vitro protein-synthesizing system using isolated mitochondria, polypeptides 1–3 were radioactive labeled in the presence of [³⁵S]methionine. This further identifies these polypeptides with the three largest subunits of cytochromec oxidse encoded by mitochondrial DNA in other eukaryotic organisms. By subtraction, the other 12 subunits can be assigned to nuclear genes. The isolatedEuglena oxidase was highly active withEuglena cytochromec ₅₅₈ and has monophasic kinetics. Using horse cytochromec ₅₅₀ as a substrate, activity of the isolated oxidase was rather low. These findings correlate with the oxidase activity of mitochondrial membranes. Again, reactivity was low with cytochromec ₅₅₀ and 35-fold higher with theEuglena cytochromec ₅₅₈. The data show that the cytochromec oxidase of the protistEuglena is different from other eukaryotic cytochromec oxidases in number and size of subunits, and also with regard to kinetic properties and substrate specificity.Abbreviations kDa kilodalton - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate - TN turnover number     

Photo-oxidation of membrane-bound and soluble cytochromec in the green sulfur bacteriumChlorobium tepidum

We studied the photosynthetic electron transfer system of membrane-bound and soluble cytochromec inChlorobium tepidum, a thermophilic green sulfur bacterium, using whole cells and membrane preparations. Sulfide and thiosulfate, physiological electron donors, enhanced flash-induced photo-oxidation ofc-type cytochromes in whole cells. In membranes,c-553 cytochromes with two (or three) heme groups served as immediate electron donors for photo-oxidized bacteriochlorophyll (P840) in the reaction center, and appeared to be closely associated with the reaction center complex. The membrane-bound cytochromec-553 had anE _m-value of 180 mV. When isolated soluble cytochromec-553, which has an apparent molecular weight of 10 kDa and seems to correspond to the cytochromec-555 inChlorobium limicola andChlorobium vibrioforme, was added to a membrane suspension, rapid photo-oxidation of both soluble and membrane-bound cytochromesc-553 was observed. The oxidation of soluble cytochromec-553 was inhibited by high salt concentrations. In whole cells, photo-oxidation was observed in the absence of exogenous electron donors and re-reduction was inhibited by stigmatellin, an inhibitor of the cytochromebc complex. These results suggest that the role of membrane-bound and soluble cytochromec inC. tepidum is similar to the role of cytochromec in the photosynthetic electron transfer system of purple bacteria.     

Initial purification study of the cytochromeb 561 of bean hypocotyl plasma membrane

Summary The plasma membrane (PM) of higher plants contains a major ascorbate-reducible, high-potentialb-type cytochrome, named cytochromeb ₅₆₁ (cytb ₅₆₁). In this paper a rapid purification protocol for the cytb ₅₆₁ of bean hypocotyls PM is described. An almost 200-fold increase of cytb ₅₆₁ specific concentration was achieved with respect to the PM fraction, which contained about 0.2 nmol of ascorbate-reducible heme per mg protein. The procedure can be performed in one day starting from purified PMs obtained by the phase-partitioning procedure. However, cytb ₅₆₁ proved to be unstable during chromatographic purification and the amount of protein finally recovered was low. Purified cytb ₅₆₁ eluted as a 130,000 Da protein-detergent complex from gel-filtration columns. It was completely reduced by ascorbate and reduced-minus-oxidized spectra showed -, - and -bands at 561, 530, and 429 nm respectively, not unlike the spectra of whole PMs. This work represents an initial approach to the biochemical characterization of the cytb ₅₆₁ of higher plants, formerly suggested to be related to cytb ₅₆₁ of animal chromaffin granules.Abbreviations cytb ₅₆₁ cytochromeb ₅₆₁ - PM plasma membrane - UPV upper-phase vesicles - GSII glucan synthase II - CCR NADH-dependent cytochromec reductase - CCO cytochromec oxidase - TX-100R reduced Triton X-100     

Metabolic regulation including anaerobic metabolism inParacoccus denitrificans

Under anaerobic circumstances in the presence of nitrateParacoccus denitrificans is able to denitrify. The properties of the reductases involved in nitrate reductase, nitrite reductase, nitric oxide reductase, and nitrous oxide reductase are described. For that purpose not only the properties of the enzymes ofP. denitrificans are considered but also those fromEscherichia coli, Pseudomonas aeruginosa, andPseudomonas stutzeri. Nitrate reductase consists of three subunits: the subunit contains the molybdenum cofactor, the subunit contains the iron sulfur clusters, and the subunit is a special cytochromeb. Nitrate is reduced at the cytoplasmic side of the membrane and evidence for the presence of a nitrate-nitrite antiporter is presented. Electron flow is from ubiquinol via the specific cytochromeb to the nitrate reductase. Nitrite reductase (which is identical to cytochromecd ₁) and nitrous oxide reductase are periplasmic proteins. Nitric oxide reductase is a membrane-bound enzyme. Thebc ₁ complex is involved in electron flow to these reductases and the whole reaction takes place at the periplasmic side of the membrane. It is now firmly established that NO is an obligatory intermediate between nitrite and nitrous oxide. Nitrous oxide reductase is a multi-copper protein. A large number of genes is involved in the acquisition of molybdenum and copper, the formation of the molybdenum cofactor, and the insertion of the metals. It is estimated that at least 40 genes are involved in the process of denitrification. The control of the expression of these genes inP. denitrificans is totally unknown. As an example of such complex regulatory systems the function of thefnr, narX, andnarL gene products in the expression of nitrate reductase inE. coli is described. The control of the effects of oxygen on the reduction of nitrate, nitrite, and nitrous oxide are discussed. Oxygen inhibits reduction of nitrate by prevention of nitrate uptake in the cell. In the case of nitrite and nitrous oxide a competition between reductases and oxidases for a limited supply of electrons from primary dehydrogenases seems to play an important role. Under some circumstances NO formed from nitrite may inhibit oxidases, resulting in a redistribution of electron flow from oxygen to nitrite.P. denitrificans contains three main oxidases: cytochromeaa ₃, cytochromeo, and cytochromeco. Cytochromeo is proton translocating and receives its electrons from ubiquinol. Some properties of cytochromeco, which receives its electrons from cytochromec, are reported. The control of the formation of these various oxidases is unknown, as well as the control of electron flow in the branched respiratory chain. Schemes for aerobic and anaerobic electron transport are given. Proton translocation and charge separation during electron transport from various electron donors and by various electron transfer pathways to oxygen and nitrogenous oxide are given. The extent of energy conservation during denitrification is about 70% of that during aerobic respiration. In sulfate-limited cultures (in which proton translocation in the NADH-ubiquinone segment of the respiratory chain is lost) the extent of energy conservation is about 60% of that under substrate-limited conditions. These conclusions are in accordance with measurements of molar growth yields.     

Cloning and sequencing of a cDNA encoding ascorbate peroxidase fromArabidopsis thaliana

A cDNA clone encoding ascorbate peroxidase (AP, EC 1.11.1.11) was isolated from a phage gt11 library of cDNA fromArabidopsis thaliana by immunoscreening with monoclonal antibodies against the enzyme, and then sequenced. The cDNA insert hybridized to a 1.1 kb poly(A)⁺ RNA from leaves ofA thaliana. Genomic hybridization suggests that the cDNA obtained here corresponds to a single-copy gene. The N-terminal amino acid sequence ofArabidopsis AP was determined by protein sequencing of the immunochemically purified enzyme, and proved to be homologous to the N-terminal amino acid sequence of the chloroplastic AP of spinach. The predicted amino acid sequence of the mature AP ofA. thaliana, deduced from the nucleotide sequence, consists of 249 amino acid residues, which is 34% homologous with cytochromec peroxidase of yeast, but less homologous with other plant peroxidases. Amino acid residues at the active site of yeast cytochromec peroxidase are conserved in the amino acid sequence ofArabidopsis AP. The poly(dG-dT) sequence, which is a potential Z-DNA-forming sequence, was found in the 3 untranslated region of the cDNA.     

Interactions involving the cyanine dye,diS-C3-(5), cytochromec and liposomes and their implications for estimations of Δψ in cytochromec oxidase-reconstituted proteoliposomes

Summary The interference of cytochromec with absorption and fluorescence changes of the cyanine dye, diS-C₃-(5), was investigated in the presence of liposomes and cytochromec-oxidase reconstituted proteoliposomes. The apparent cytochromec-dependent quenching of diS-C₃-(5) fluorescence, and the associated absorbance losses in the presence of liposomes and proteoliposomes in low ionic strength media, are due to destruction of the dye caused by cytochromec-mediated lipid peroxidation. The rate of this reaction was further enhanced in the presence of hydrogen peroxide. Even in the absence of liposomes or proteoliposomes, a cytochromec-induced breakdown of dye was observed in the presence of hydrogen peroxide.The cytochromec mediated absorbance and fluorescence losses of diS-C₃-(5) in liposomal or proteoliposomal systems are prevented by Ca²⁺ and La³⁺ ions, by ascorbate, by high ionic strength and by the antioxidant BHT. Under these conditions, the process of lipid peroxidation mediated by cytochromec is inhibited either directly (e. g. by BHT) or indirectly, by preventing the binding of cytochromec to lipid vesicles. The impact of these findings upon the experimental estimation of membrane potential inaa ₃-reconstituted proteoliposomes is discussed.