Purification of two pressure-regulated c-type cytochromes from a deep-sea barophilic bacterium, Shewanella sp. strain DB-172F

From a deep-sea barophilic bacterium, Shewanella sp. strain DB-172F, a membrane-bound cytochrome c-551 and a cytoplasmic cytochrome c-552 were purified. The cytochrome c-551 contained 44.2 nmol of heme c mg protein⁻¹ and cytochrome c-552 contained 31.3 nmol of heme c mg protein⁻¹. The CO difference spectrum of cytochrome c-551 showed a peak at 413.7 nm and troughs at 423.2, 522 and 552 nm which indicated that this cytochrome combined with CO. Cytochrome c-551 was found to consist of two subunits with molecular masses of 29.1 kDa and 14.7 kDa, respectively, and each subunit contained one heme c molecule. Cytochrome c-552 also consisted of two subunits with molecular masses of 16.9 kDa and 14.7 kDa, respectively, and only one of these subunits contained heme c. Cytochrome c-551 was constitutively synthesized when the cells were grown at pressures of either 0.1 MPa or 60 MPa, whereas cytochrome c-552 was synthesized only at 0.1 MPa. These results together with the results of analysis of membrane-associated catalytic activities suggest that the respiratory system of DB-172F is regulated by pressure and may be intimately related to the baroadaptability mechanism of this deep-sea bacterium.     

The amino acid sequence of Nitrosomonas europaea cytochrome c-552

The complete amino acid sequence of cytochrome c-552 derived from the chemoautotrophic ammonia-oxidizing bacterium Nitrosomonas europaea was determined. The cytochrome consisted of 81 amino acid residues, and its molecular weight was calculated to be 9098 including heme c. Although the sequence of cytochrome c-552 was highly homologous to those of cytochromes c-551, which were known as the electron-donating components to dissimilatory nitrite reductase in pseudomonads, cytochrome c-552 differed from cytochrome c-551 in two points: (1) the sequence of cytochrome c-552 was shorter by two amino acid residues than that of cytochrome c-551 at the N-terminus and (2) one amino acid insertion was present in cytochrome c-552.     

Domain-Swapped Dimer of Pseudomonas aeruginosa Cytochrome c 551: Structural Insights into Domain Swapping of Cytochrome c Family Proteins

Cytochrome c (cyt c) family proteins, such as horse cyt c, Pseudomonas aeruginosa cytochrome c ₅₅₁ (PA cyt c ₅₅₁), and Hydrogenobacter thermophilus cytochrome c ₅₅₂ (HT cyt c ₅₅₂), have been used as model proteins to study the relationship between the protein structure and folding process. We have shown in the past that horse cyt c forms oligomers by domain swapping its C-terminal helix, perturbing the Met–heme coordination significantly compared to the monomer. HT cyt c ₅₅₂ forms dimers by domain swapping the region containing the N-terminal α-helix and heme, where the heme axial His and Met ligands belong to different protomers. Herein, we show that PA cyt c ₅₅₁ also forms domain-swapped dimers by swapping the region containing the N-terminal α-helix and heme. The secondary structures of the M61A mutant of PA cyt c ₅₅₁ were perturbed slightly and its oligomer formation ability decreased compared to that of the wild-type protein, showing that the stability of the protein secondary structures is important for domain swapping. The hinge loop of domain swapping for cyt c family proteins corresponded to the unstable region specified by hydrogen exchange NMR measurements for the monomer, although the swapping region differed among proteins. These results show that the unstable loop region has a tendency to become a hinge loop in domain-swapped proteins.     

Cytochrome c-556, a di-heme protein from Pseudomonas aeruginosa

A procedure is described for the purification of cytochrome c-556 from Pseudomonas aeruginosa. The isolated hemoprotein exists as a dimer with a molecular weight of approximately 77 200. The dimer can be dissociated into a monomeric species (or single polypeptide chain) of 40 500 molecular weight by means of sodium dodecyl sulfate or 4 M urea. The amino acid composition demonstrates the presence of four half-cystine residues per 43 000 molecular weight. Heme and iron analyses indicate that two c-type hemes are covalently linked to each polypeptide chain. The absorption spectrum of ferrocytochrome c-556 has a double α-band with a peak at 556 nm and a shoulder at 552 nm; the β-band appears at 521 nm and the Soret band at 420 nm.The electron paramagnetic resonance spectrum of ferricytochrome c-556 contains the elements of two ferric iron species, one a low spin and the other a high spin form.The function of cytochrome c-556 is obscure. The purified cytochrome does not react with Pseudomonas cytochrome oxidase nor with the Pseudomonas cytochrome c-551 or copper protein.The properties of cytochrome c-556 indicate that it is probably not the same species as the cytochrome c-554 previously isolated from the same organism.     

Structure of cytochrome c551 from Pseudomonas aeruginosa refined at 1.6 Å resolution and comparison of the two redox forms

The molecular structures of ferri- and ferrocytochrome c₅₅₁ from Pseudomonas aeruginosa have been refined at a resolution of 1.6 Å, to an R factor of 19.5% for the oxidized molecule and 18.7% for the reduced. Reduction of oxidized crystals with ascorbate produced little change in cell dimensions, a 10% mean change in F_obs, and no damage to the crystals. The heme iron is not significantly displaced from the porphyrin plane. Bond lengths from axial ligands to the heme iron are as expected in a low-spin iron compound. A total of 67 solvent molecules were incorporated in the oxidized structure, and 73 in the reduced, of which four are found inside the protein molecule. The oxidized and reduced forms have virtually identical tertiary structures with 2 ° root-mean-square differences in main-chain torsion angles φ and ψ, but with larger differences along the two edges of the heme crevice. The difference map and pyrrole ring tilt suggest that a partially buried water molecule (no. 23) in the heme crevice moves upon change of oxidation state.Pseudomonas cytochrome c₅₅₁ differs from tuna cytochrome c in having: (1) a water molecule (no. 23) at the upper left of the heme crevice; that is, between Pro62 and the heme pyrrol 3 ring on the sixth ligand Met61 side, where tuna cytochrome c has an evolutionary invariant Phe82 ring; (2) a string of hydrophobic side-chains along the left side of the heme crevice, and fewer positively charged lysines in the vicinity; and (3) a more exposed and presumably more easily ionizable heme propionate group at the bottom of the molecule. A network of hydrogen bonds in the heme crevice is reminiscent of that inside the heme crevice of tuna cytochrome c. As in tuna, a slight motion of the water molecule toward the heme is observed in the oxidized state, helping to give the heme a more polar microenvironment. The continuity of solvent environment between the heme crevice and the outer medium could explain the greater dependence of redox potential on pH in cytochrome c₅₅₁ than in cytochrome c.     

The role of soluble cytochrome c-551 in cyclic electron flow-driven active transport in Chromatium vinosum

Spheroplasts have been prepared from the photosynthetic purple sulfur bacterium Chromatium vinosum by lysozyme plus ethylenediaminetetraacetic acid treatment. These spheroplasts are able to take up alanine in the light, but light-dependent alanine uptake is lost upon subsequent washing of the spheroplasts. The observations that alanine uptake driven by a potassium plus valinomycin-induced membrane potential (outside positive) is not affected by washing and that light-dependent alanine uptake can be restored by addition of the supernatant from washing suggest that a soluble electron carrier is lost during washing. Light-dependent alanine uptake in washed spheroplasts could be restored by addition of C. vinosum cytochrome c-551. Other soluble electron carriers from C. vinosum (high-potential iron protein, cytochrome ‘f’, cytochrome c′ and the flavocytochrome c-552) did not restore alanine uptake nor did a variety of other soluble electron carrier proteins from other organisms. These results suggest that cytochrome c-551 functions as an electron carrier in the cyclic electron transfer chain of C. vinosum. Mitochondrial cytochrome c (equine heart) and cytochrome c-551 from Pseudomonas aeruginosa were highly effective in restoring light-dependent alanine uptake in washed spheroplasts, making it likely that C. vinosum cytochrome c-551 is related by evolution to the same cytochrome c family as these other two c cytochromes.     

The use of a water-soluble carbodiimide to study the interaction between Chromatium vinosum flavocytochrome c-552 and cytochrome c

The interaction between horse heart cytochrome c and Chromatium vinosum flavocytochrome c-552 was studied using the water-soluble reagent 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC). Treatment of flavocytochrome c-552 with EDC was found to inhibit the sulfide: cytochrome c reductase activity of the enzyme. SDS gel electrophoresis studies revealed that EDC treatment led to modification of carboxyl groups in both the M_r 21000 heme peptide and the M_r 46000 flavin peptide, and also to the formation of a cross-linked heme peptide dimer with an M_r value of 42000. Both the inhibition of sulfide: cytochrome c reductase activity and the formation of the heme peptide dimer were decreased when the EDC modification was carried out in the presence of cytochrome c. In addition, two new cross-linked species with M_r values of 34000 and 59000 were formed. These were identified as cross-linked cytochrome c-heme peptide and cytochrome c-flavin peptide species, respectively. Neither of these species were formed in the presence of a cytochrome c derivative in which all of the lysine amino groups had been dimethylated, demonstrating that EDC had cross-linked lysine amino groups on native cytochrome c to carboxyl groups on the heme and flavin peptides. A complex between cytochrome c and flavocytochrome c-552 was required for cross-linking to occur, since ionic strengths above 100 mM inhibited cross-linking.     

Function and properties of a soluble c-type cytochrome c-551 in secondary photosynthetic electron transport in whole cells of Chromatium vinosum as studied with flash spectroscopy

Changes in the absorption spectrum induced by 10-μs flashes and continuous light of various intensities were studied in whole cells of Chromatium vinosum.This paper describes the role and function of a soluble c-type cytochrome, c-551, which was surprisingly found to act in many ways similar to the cytochrome c-420 in Rhodospirillum rubrum, described in a previous paper [1].After the photooxidation of the membrane bound high potential cytochrome c-555 by a 10-μs flash, (the low potential cytochrome c-552 was kept permanently in the oxidized state) the oxidation of c-551 is observed ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 0.3}\text{ms}$). From a careful analysis of the absorbance difference spectrum and the kinetics it is concluded that there is approximately 0.6–0.7 c-551 per reaction center and that essentially all the c⁺-555 is reduced via the cytochrome c-551. The oxidized-reduced difference spectrum of c-551 shows peaks at 551 and 421.5 nm. The reduction of c⁺-551 following the flash-induced oxidation is strongly inhibited by HOQNO, but only slightly by antimycin A.Cytochrome c-551 reduces only the oxidized high potential cytochrome c-555, which is probably located on the outside of the membrane, on the opposite side of the primary acceptor. The low potential cytochrome c-552 does not show any detectable interaction with cytochrome c-551. After the cells have been sonicated, no c-551 is photooxidized and at least part of the cytochrome occurs in the solution.Analysis of the reduction kinetics of c⁺-551 in the absence and presence of external donors suggests that c⁺-551 is partly reduced via a cyclic pathway, which is blocked by addition of o-phenanthroline, and partly via a non-cyclic pathway. The non-cyclic reduction rate of c⁺-551 (k = 6 s^?1) is increased approximately 5–10 times upon thiosulphate addition, suggesting a role for c-551 between the final donor pool and the oxidized membrane bound c-type cytochromes.     

Structure and Sequence Conservation of hao Cluster Genes of Autotrophic Ammonia-Oxidizing Bacteria: Evidence for Their Evolutionary History

Comparison of the organization and sequence of the hao (hydroxylamine oxidoreductase) gene clusters from the gammaproteobacterial autotrophic ammonia-oxidizing bacterium (aAOB) Nitrosococcus oceani and the betaproteobacterial aAOB Nitrosospira multiformis and Nitrosomonas europaea revealed a highly conserved gene cluster encoding the following proteins: hao, hydroxylamine oxidoreductase; orf2, a putative protein; cycA, cytochrome c₅₅₄; and cycB, cytochrome c_m552. The deduced protein sequences of HAO, c₅₅₄, and c_m552 were highly similar in all aAOB despite their differences in species evolution and codon usage. Phylogenetic inference revealed a broad family of multi-c-heme proteins, including HAO, the pentaheme nitrite reductase, and tetrathionate reductase. The c-hemes of this group also have a nearly identical geometry of heme orientation, which has remained conserved during divergent evolution of function. High sequence similarity is also seen within a protein family, including cytochromes c_m552, NrfH/B, and NapC/NirT. It is proposed that the hydroxylamine oxidation pathway evolved from a nitrite reduction pathway involved in anaerobic respiration (denitrification) during the radiation of the Proteobacteria. Conservation of the hydroxylamine oxidation module was maintained by functional pressure, and the module expanded into two separate narrow taxa after a lateral gene transfer event between gamma- and betaproteobacterial ancestors of extant aAOB. HAO-encoding genes were also found in six non-aAOB, either singly or tandemly arranged with an orf2 gene, whereas a c₅₅₄ gene was lacking. The conservation of the hao gene cluster in general and the uniqueness of the c₅₅₄ gene in particular make it a suitable target for the design of primers and probes useful for molecular ecology approaches to detect aAOB.     

Protein surface charge effect on 3D domain swapping in cells for c-type cytochromes

Many c-type cytochromes (cyts) can form domain-swapped oligomers. The positively charged Hydrogenobacter thermophilus (HT) cytochrome (cyt) c₅₅₂ forms domain-swapped oligomers during expression in the Escherichia coli (E. coli) expression system, but the factors influencing the oligomerization remain unrevealed. Here, we found that the dimer of the negatively charged Shewanella violacea (SV) cyt c₅ exhibits a domain-swapped structure, in which the N-terminal helix is exchanged between protomers, similar to the structures of the HT cyt c₅₅₂ and Pseudomonas aeruginosa (PA) cyt c₅₅₁ domain-swapped dimers. Positively charged horse cyt c and HT cyt c₅₅₂ domain swapped during expression in E. coli, whereas negatively charged PA cyt c₅₅₁ and SV cyt c₅ did not. Oligomers were formed during expression in E. coli for HT cyt c₅₅₂ attached to either a co- or post-translational signal peptide for transportation through the cytoplasm membrane, but not for PA cyt c₅₅₁ attached to either signal peptide. HT cyt c₅₅₂ formed oligomers in E. coli in the presence and absence of rare codons. More oligomers were obtained from the in vitro folding of horse cyt c and HT cyt c₅₅₂ by the addition of negatively charged liposomes during folding, whereas the amount of oligomers for the in vitro folding of PA cyt c₅₅₁ and SV cyt c₅ did not change significantly by the addition. These results indicate that the protein surface charge affects the oligomerization of c-type cyts in cells; positively charged c-type cyts assemble on a negatively charged membrane, inducing formation of domain-swapped oligomers during folding.     

Structure analysis and characterization of the cytochrome c-554 from thermophilic green sulfur photosynthetic bacterium Chlorobaculum tepidum

The cytochrome (Cyt) c-554 in thermophilic green photosynthetic bacterium Chlorobaculum tepidum serves as an intermediate electron carrier, transferring electrons to the membrane-bound Cyt c _z from various enzymes involved in the oxidations of sulfide, thiosulfate, and sulfite compounds. Spectroscopically, this protein exhibits an asymmetric α-absorption band for the reduced form and particularly large paramagnetic ¹H NMR shifts for the heme methyl groups with an unusual shift pattern in the oxidized form. The crystal structure of the Cyt c-554 has been determined at high resolution. The overall fold consists of four α-helices and is characterized by a remarkably long and flexible loop between the α3 and α4 helices. The axial ligand methionine has S-chirality at the sulfur atom with its C^εH₃ group pointing toward the heme pyrrole ring I. This configuration corresponds to an orientation of the lone-pair orbital of the sulfur atom directed at the pyrrole ring II and explains the lowest-field ¹H NMR shift arising from the 18¹ heme methyl protons. Differing from most other class I Cyts c, no hydrogen bond was formed between the methionine sulfur atom and polypeptide chain. Lack of this hydrogen bond may account for the observed large paramagnetic ¹H NMR shifts of the heme methyl protons. The surface-exposed heme pyrrole ring II edge is in a relatively hydrophobic environment surrounded by several electronically neutral residues. This portion is considered as an electron transfer gateway. The structure of the Cyt c-554 is compared with those of other Cyts c, and possible interactions of this protein with its electron transport partners are discussed.     

Soluble cytochromes ofRhodopseudomonas marina

Three acidicc-type cytochromes (c-552,c-550 andc′) were purified from the soluble fraction ofRhodopseudomonas marina. Cytochromec′ is a high-spin cytochrome capable of binding carbon monoxide reversibly to its reduced form. It occurs as a dimer with anM_r of 36700 (estimated by gel filtration) while the monomer has anM_r of 17800 (determined by SDS-acrylamide gel electrophoresis). Cytochromec′ has a midpoint redox potential of +73 mV and an isoelectric point at pH 4.3. Cytochromesc-550 andc-552 are typical low-spin cytochromes. Cytochromec-550 has anM_r of 12500, an isoelectric point at pH 4.5 and a negative redox potential of −163 mV. The molecular properties of cytochromec-552 are as follows:M_r, 18000; isoelectric point, pH 5.4; redox potential, +283 mV.     

Effects of axial methionine coordination on the in-plane asymmetry of the heme electronic structure of cytochrome<Emphasis Type="Italic"> c</Emphasis>

The paramagnetic susceptibility () tensors of the oxidized forms of thermophile Hydrogenobacter thermophilus cytochrome c₅₅₂ (Ht cyt c₅₅₂) and a quintuple mutant (F7A/V13 M/F34Y/E43Y/V78I; qm) of mesophile Pseudomonas aeruginosa cytochrome c₅₅₁ (Pa cyt c₅₅₁) have been determined on the basis of the redox-dependent ¹H NMR shift changes of the main-chain NH and CH proton resonances of non-coordinated amino acid residues and the NMR structures of the reduced forms of the corresponding proteins (J. Hasegawa, T. Yoshida, T. Yamazaki, Y. Sambongi, Y. Yu, Y. Igarashi, T. Kodama, K. Yamazaki, Y. Kyogoku, Y. Kobayashi (1998) Biochemistry 37:9641–9649; J. Hasegawa, S. Uchiyama, Y. Tanimoto, M. Mizutani, Y. Kobayashi, Y. Sambongi,Y. Igarashi (2000) J Biol Chem 275:37824–37828). From the tensors determined, we obtained the contact shifts for heme methyl proton resonances, which provided the heme electronic structures of the oxidized forms of Ht cyt c₅₅₂ and qm. We also characterized the heme electronic structure of the cyanide adducts of the proteins, where the axial Met was replaced by an exogenous cyanide ion, through the analysis of ¹H NMR spectra. The results indicated that the heme electronic structures of both the proteins in their oxidized forms with axial His and Met coordination are largely different to each other, while those in their cyanide adducts are similar to each other. These results demonstrated that the orientation of the axial Met sulfur lone pair, with respect to heme, predominantly contributes to the spin delocalization into the porphyrin- system of heme in the oxidized proteins with axial His and Met coordination.Electronic Supplementary Material Supplementary material is available in the online version of this article at Abbreviations COSY correlation spectroscopy - DQF-COSY double quantum filtered COSY - TOCSY total correlation spectroscopy - NOE nuclear Overhauser effect - NOESY nuclear Overhauser effect correlated spectroscopy - Cyt c cytochrome c - Pa cyt c₅₅₁ Pseudomonas aeruginosa cytochrome c₅₅₁ - Ht cyt c₅₅₂ Hydrogenobacter thermophilus cytochrome c₅₅₂ - _obs observed shift - _para paramagnetic shift - _dia diamagnetic shift - _con contact shift - _pc pseudo-contact shift     

Complex formation between Chlorobium limicola f. thiosulfatophilumc-type cytochromes

It has been possible to demonstrate, using affinity chromatography, that Chlorobium flavocytochrome c-553 forms an electrostatically stabilized complex with Chlorobium cytochrome c-555. The binding site for cytochrome c-555 appears to be located on the heme-containing subunit of flavocytochrome c-553. This complex appears to be involved in the flavocytochrome c-553-catalyzed transfer of electrons from sulfide to cytochrome c-555. Complex formation has also been demonstrated between Chlorobium cytochromes c-555 and c-551, two components involved in the oxidation of thiosulfate by this green sulfur bacterium. Affinity chromatography data also suggest the possibility that the cytochrome binding sites on the Chlorobium flavocytochrome c-553 and on flavocytochrome c-552 from the purple sulfur bacterium Chromatium vinosum may be similar.     

Kinetics of electron transfer between soluble cytochrome c-554 and purified reaction center complex from the green sulfur bacterium Chlorobium tepidum

Soluble cytochrome c-554 (M _r 10 kDa) is purified from the green sulfur bacterium Chlorobium tepidum. Its midpoint redox potential is determined to be +148 mV from redox titration at pH 7.0. The kinetics of cytochrome c-554 oxidation by a purified reaction center complex from the same organism were studied by flash absorption spectroscopy at room temperature, and the results indicate that the reaction partner of cytochrome c-554 is cytochrome c-551 bound to the reaction center rather than the primary donor P840. The second-order rate constant for the electron donation from cytochrome c-554 to cytochrome c-551 was estimated to be 1.7×10⁷ M^–1 s^–1. The reaction rate was not significantly influenced by the ionic strength of the reaction medium.This revised version was published online in October 2005 with corrections to the Cover Date.     

The reaction of Euglena gracilis cytochrome c-552 with nonphysio-logical oxidants and reductants.

The reaction of Euglena gracilis cytochrome c-552 (cytochrome f) with the nonphysiological reactants potassium ferrocyanide, potassium ferricyanide, sodium ascorbate, sodium dithionite, and Chromatium vinosum high potential nonheme iron protein was studied by stopped-flow and temperature-jump kinetic methods. The reaction of the purified, water-soluble protein with the reactants was investigated as a function of ionic strength, pH, and temperature. The results demonstrated that reduction and oxidation takes place at a negatively charged site on the cytochrome c-552 surface. Participation of specific amino acid residues in electron transfer is implicated from the pH results. The results obtained for the nonphysiological reactions of cytochrome c-552 are compared with available data for horse heart cytochrome c and Rhodospirillum rubrum cytochrome c₂. The results strongly suggest that Euglena gracilis cytochrome c-552 undergoes nonphysiological oxidation and reduction by a mechanism different from that found for cytochrome c or cytochrome c₂.     

The NT-26 cytochrome c552 and its role in arsenite oxidation

Arsenite oxidation by the facultative chemolithoautotroph NT-26 involves a periplasmic arsenite oxidase. This enzyme is the first component of an electron transport chain which leads to reduction of oxygen to water and the generation of ATP. Involved in this pathway is a periplasmic c-type cytochrome that can act as an electron acceptor to the arsenite oxidase. We identified the gene that encodes this protein downstream of the arsenite oxidase genes (aroBA). This protein, a cytochrome c₅₅₂, is similar to a number of c-type cytochromes from the α-Proteobacteria and mitochondria. It was therefore not surprising that horse heart cytochrome c could also serve, in vitro, as an alternative electron acceptor for the arsenite oxidase. Purification and characterisation of the c₅₅₂ revealed the presence of a single heme per protein and that the heme redox potential is similar to that of mitochondrial c-type cytochromes. Expression studies revealed that synthesis of the cytochrome c gene was not dependent on arsenite as was found to be the case for expression of aroBA.     

Protein composition and architecture of the photosynthetic membranes from the cyanobacterium, Anacystis nidulans R2

The protein composition of the photosynthetic membrane from the cyanobacterium, Anacystis nidulans R2, was analyzed by acrylamide gel electrophoresis following solubilization with lithium dodecyl sulfate. Autoradiograms of ³⁵S-labelled membranes revealed over 90 bands by this procedure. The effect of solubilization conditions on protein resolution was analyzed by modifying temperature and sulfhydryl concentrations. Labelling cells with ⁵⁹Fe yielded nine iron-containing bands on these gels. Three of these bands, at 33, 19, and 14 kDa, were also heme proteins as determined by tetramethylbenzidine staining, and represent cytochromes f, b₆ and c-552, respectively. The remaining iron proteins are highly sensitive to solubilization conditions, especially the presence of 2-mercaptoethanol, and we suggest that these bands may be Fe-S proteins. Lactoperoxidase-catalyzed iodination of the membranes indicated that at least 41 proteins have surface-exposed domains. Some of the known proteins with external surfaces include cytochrome c-552 and the chlorophyll-binding proteins of Photosystems I and II. Neither cytochrome f nor b₆ appear to be accessible to external labelling. When this structural information was combined with the isolation of functional submembrane complexes, we constructed a topological model of the membrane. Using this model we have discussed the protein architecture of the cyanobacterial membrane.     

COMPONENTS OF THE ELECTRON-TRANSFERRING SYSTEM IN ACETOBACTER SUBOXYDANS AND RECONSTRUCTION OF THE LACTATE OXIDATION SYSTEM

1. Cytochromes a₁⁵⁹⁰, b⁵⁶⁰, c₁⁵⁵⁴ and c₁⁵⁵² were isolated andpurifiedfrom a strain of Acetobacter suboxydans. The proceduresusedwere described in detail.
2. The main cytochrome band at550-560 mµ in intact cellssplitted at liquid air temperatureinto two bands, 551 mµ(strong) and 559 mµ (weak).
3. Optical and physiological properties of the four cytochromeswere investigated. Lactic dehydrogenase activity was found tobe associated with cytochrome c₁⁵⁵⁴. The two c₁-type cytochromes,especially cytochrome c₁⁵⁵⁴, persisted in their reduced formafter the purification through many steps.
4. By some combinationsof isolated components reconstruction ofthe oxygen uptake systemcould be realized.
5. The oxygen-consuming activity of purifiedoxidase preparationswas accelerated by a-tocopherol but notby Emasoll 4130 andTween 80.
6. Some discussions were made onthe nature of terminal oxidase,the role of cytochrome c₁⁵⁵²in the electron-transport system,and persistence of reducedstate of c₁-type cytochromes.
7. A possible scheme of the electron-transferringsystem of Acetobactersuboxydans was presented.

(Received May 16, 1960; )     

Some properties and occurrence of cytochrome c-552 in the aerobic photosynthetic bacterium Roseobacter denitrificans

Characteristics and occurrence of cytochrome c-552 from an aerobic photosynthetic bacterium, Roseobacter denitrificans, were described.Relative molecular mass of the cytrochrome was 13.5 kDa on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and 15,000 by gel filtration. This cytochrome was a acidic protein having a pI of 5.6 and E_m was +215 mV at pH 7.0. Absorption peaks were at 278, 408 and 524 nm in the oxidized form and 416, 523 and 552 nm in the reduced form.Amino acid composition and N-terminal amino acid sequence of cytochrome c-552 determined for 24 residues had low similarities to those of cytochrome c-551 of this bacterium, which is homologous to cytochrome c ₂, although the physico-chemical properties of these two cytochromes were similar to each other.Cytochrome c-552 was maximally synthesized in the light under aerobic conditions but not in the dark. The synthesis also occurred in the presence of alternative acceptors such as trimethylamine N-oxide (TMAO) and nitrate under anaerobic conditions. Our results suggest that cytochrome c-552 is involved in TMAO respiration and denitrification in R. denitrificans, although the effect of light remains to be solved.Abbreviations E_m Midpoint redox potential - PAGE Polyacrylamide ge electrophoresis - SDS-PAGE Sodium dodecyl sulfate polyacrylamide gel electrophoresis - TMAO Trimethylamine N-oxide