Pulsed cytochrome c oxidase from the thermophilic bacterium PS3

The aerobic respiratory chain of the acidophilic archaeon Ferroplasma acidiphilum: A membrane-bound complex oxidizing ferrous iron

The extremely acidophilic archaeon Ferroplasma acidiphilum is found in iron-rich biomining environments and is an important micro-organism in naturally occurring microbial communities in acid mine drainage. F. acidiphilum is an iron oxidizer that belongs to the order Thermoplasmatales (Euryarchaeota), which harbors the most extremely acidophilic micro-organisms known so far. At present, little is known about the nature or the structural and functional organization of the proteins in F. acidiphilum that impact the iron biogeochemical cycle. We combine here biochemical and biophysical techniques such as enzyme purification, activity measurements, proteomics and spectroscopy to characterize the iron oxidation pathway(s) in F. acidiphilum. We isolated two respiratory membrane protein complexes: a 850 kDa complex containing an aa3-type cytochrome oxidase and a blue copper protein, which directly oxidizes ferrous iron and reduces molecular oxygen, and a 150 kDa cytochrome ba complex likely composed of a di-heme cytochrome and a Rieske protein. We tentatively propose that both of these complexes are involved in iron oxidation respiratory chains, functioning in the so-called uphill and downhill electron flow pathways, consistent with autotrophic life. The cytochrome ba complex could possibly play a role in regenerating reducing equivalents by a reverse ('uphill') electron flow. This study constitutes the first detailed biochemical investigation of the metalloproteins that are potentially directly involved in iron-mediated energy conservation in a member of the acidophilic archaea of the genus Ferroplasma.

New functional sulfide oxidase-oxygen reductase supercomplex in the membrane of the hyperthermophilic bacterium Aquifex aeolicus

Aquifex aeolicus, a hyperthermophilic and microaerophilic bacterium, obtains energy for growth from inorganic compounds alone. It was previously proposed that one of the respiratory pathways in this organism consists of the electron transfer from hydrogen sulfide (H(2)S) to molecular oxygen. H(2)S is oxidized by the sulfide quinone reductase, a membrane-bound flavoenzyme, which reduces the quinone pool. We have purified and characterized a novel membrane-bound multienzyme supercomplex that brings together all the molecular components involved in this bioenergetic chain. Our results indicate that this purified structure consists of one dimeric bc(1) complex (complex III), one cytochrome c oxidase (complex IV), and one or two sulfide quinone reductases as well as traces of the monoheme cytochrome c(555) and quinone molecules. In addition, this work strongly suggests that the cytochrome c oxidase in the supercomplex is a ba(3)-type enzyme. The supercomplex has a molecular mass of about 350 kDa and is enzymatically functional, reducing O(2) in the presence of the electron donor, H(2)S. This is the first demonstration of the existence of such a respirasome carrying a sulfide oxidase-oxygen reductase activity. Moreover, the kinetic properties of the sulfide quinone reductase change slightly when integrated in the supercomplex, compared with the free enzyme. We previously purified a complete respirasome involved in hydrogen oxidation and sulfur reduction from Aquifex aeolicus. Thus, two different bioenergetic pathways (sulfur reduction and sulfur oxidation) are organized in this bacterium as supramolecular structures in the membrane. A model for the energetic sulfur metabolism of Aquifex aeolicus is proposed.

Electron transfer kinetics during the reduction and turnover of the cytochrome caa3 complex from Bacillus subtilis

The cytochrome caa3 complex from Bacillus subtilis is a member of the cytochrome oxidase superfamily of respiratory enzyme complexes. The key difference in the cytochrome caa3 complex lies in the addition of a domain, homologous with mitochondrial cytochrome c, that is fused to the C-terminal end of its subunit II. Measurements of steady-state and transient reduction kinetics have been carried out on the cytochrome caa3 complex. Reduction of the cyanide-bound enzyme with ascorbate and N,N,N',N'-tetramethyl-p-phenylenediamine (TMPD) supports a sequence of electron transfer in which cytochromec is reduced initially, and this is followed by rapid internal electron transfer from cytochrome c to CuA and from CuA to cytochrome a. Steady-state kinetics with exogenous cytochrome c as the substrate demonstrates the capability of the cytochrome caa3 complex to act as a cytochrome c oxidase. The cytochrome c from B. subtilis is the most efficient cytochrome c of those tested. Steady-state kinetics with ascorbate-TMPD as the reductant, in the absence of exogenous cytochrome c, reveals a biphasic pattern even though only a single, covalent cytochrome c interaction site is present. The two-phase kinetics are characterized by a low activity phase associated with a high apparent affinity for TMPD and a high activity phase with a low affinity for TMPD. This pattern is observed over a wide range of ionic strengths and enzyme concentrations, and with both purified and membrane extract forms of cytochrome caa3. It is proposed that the biphasic steady-state kinetics of this oxidase, and other members of the cytochrome oxidase superfamily, do not result directly from different interactions with cytochrome c but are due to a change in the redox kinetics within the centers of the conventional oxidase unit itself. Our results will be related to models that account for the biphasic steady-state kinetics exhibited by cytochrome oxidase.

Interconversion of fast and slow forms of cytochrome bo from Escherichia coli

The fully oxidized fast form of cytochrome bo from Escherichia coli is shown to convert spontaneously to a slow form when stored at -20 degrees C in 50 mM potassium borate, pH 8.5, containing 0.5 mM potassium EDTA. Evidence for the conversion, and that the form produced is analogous to the slow form of bovine heart cytochrome c oxidase, comes from (a) decreases in the extents of fast (k = 1-2 x 10(3) M-1 s-1) H2O2 binding and fast (k = 20-30 M-1 s-1) cyanide binding; (b) changes in the optical spectrum that are like those induced by formate, i.e., a blue shift in the Soret absorption band, loss of absorbance in the alpha and beta bands, and a red shift in the "630 nm" charge-transfer band; (c) changes in the EPR spectrum that are like those induced by formate, i.e., disappearance of signals at g = 8.6 and g = 3.71, and appearance of signals at g approximately 13, g = 3.14, and g = 2.58; and (d) appearance of a slow phase of reduction of heme o by dithionite. The mutant enzyme E286Q also converts to a slow form under the same conditions, as shown by (a) a decrease in the extent of fast H2O2 binding; (b) changes in the optical spectrum like those seen with wild-type enzyme; and (c) changes in the EPR spectrum that are like those induced by formate, i.e., disappearance of signals at g = 7.3 and g = 3.6 and appearance of signals at g approximately 13, g = 3.18, and g = 2.59.(ABSTRACT TRUNCATED AT 250 WORDS)

Physico-chemical characterisation of membrane-bound and water-soluble forms of Bacillus subtilis cytochrome c-550

Cytochrome c-550 of the Gram-positive bacterium, Bacillus subtilis, is a membrane-bound 13-kDa protein encoded by the cccA gene. The cytochrome has been proposed to be comprised of an N-terminal membrane anchor domain (about 30 residues) which spans the cytoplasmic membrane in an alpha-helical conformation and a C-terminal heme domain (about 70 residues) which is located on the outside of the cytoplasmic membrane. Cytochrome c-550 was purified in the presence of Triton X-100 and characterised. In the reduced state it shows absorption maxima at 415, 521, 550 nm and in the oxidised state a Soret band at 408 nm and a weak band at about 695 nm. The latter absorption band, together with data from amino acid sequence comparisons, strongly suggest His64 and Met99 as the fifth and sixth axial ligands to the heme iron in cytochrome c-550. The midpoint redox potential of the cytochrome, +178 mV, was pH-independent in the pH range 6.0-7.9. Oxidised cytochrome c-550 showed an EPR signal at gmax = 3.41, which is unusual for low-spin cytochromes c with His/Met axial ligation. The heme domain was isolated as a tryptic fragment of 74 residues and as a protein-A-cytochrome-c-550 hybrid protein. Both these forms were water-soluble and showed thermodynamic and spectroscopic properties indistinguishable from the membrane-bound form of cytochrome c-550 and are suitable for structural analysis of the heme domain by X-ray crystallography or NMR techniques. Polypeptide analysis of the membrane-bound and water-soluble tryptic fragment confirmed that B. subtilis cytochrome c-550 in the membrane consists of 120 amino acid residues and has a two-domain structure.

Bacillus subtilis expresses two kinds of haem-A-containing terminal oxidases

The expression of two different aa3-type cytochrome oxidases is demonstrated in Bacillus subtilis. One of them (denoted caa3-605), was predicted by DNA-sequencing of Bacillus cytochrome oxidase genes, but has not been found previously. It contains covalently bound haem C in subunit II and is very similar to the enzyme previously described in the thermophilic bacterium PS3. The other oxidase (denoted aa3-600) deviates from most known oxidases of aa3 type, and is probably identical with the oxidase described by de Vrij et al. [de Vrij, W., Azzi, A. & Konings, W. N. (1983) Eur. J. Biochem. 131, 97-103]. It shows no immunological cross-reactivity to the PS3 enzyme and differs from this spectroscopically; it contains no CuA and does not oxidise cytochrome c despite of its haem-A chromophores. It catalyses oxidation of quinols, which is proposed to be its physiological function.

Structure and function of cytochrome-c oxidase

Recent works on the structure and the function of cytochrome-c oxidase are reviewed. The subunit composition of the mitochondrial enzyme depends on the species and is comprised of between 5 and 13 subunits. It is reduced to 1 to 3 subunits in prokaryotes. The complete amino acid composition has been derived from protein sequencing. Gene sequences are partially known in several eukaryote species. Metal centers are only located in subunits I and II. The mitochondrial cytochrome-c oxidase is Y-shaped; the arms of the Y cross the inner membrane, the stalk protrudes into the intermembrane space. The bacterial enzyme has a simpler, elongated shape. A number of data have been accumulated on the subunit topology and on their location within the protein. All available spectrometric techniques have been used to investigate the environment of the metal centers as well as their interactions. From the literature, attention must be paid to what may be considered or not as an active form. The steady improvement of the instrumentation has yielded evidence for different kinds of heterogeneities which could reflect the in vivo situation. The 'pulsed' and 'resting' conformers have been well characterized. The 'oxygenated' form has been identified as a peroxide derivative of the fully oxidized cytochrome-c oxidase. The mammalian enzyme has been isolated in fully active monomeric form which does not preclude the initially suggested dimeric behavior in situ. The role of the lipids is still largely investigated, mainly through reconstitution experiments. Kinetic studies of electron transfer between cytochrome c and cytochrome-c oxidase lead to a single catalytic site model to account for the multiphasic kinetics. Results related to the low temperature investigation of the intermediate steps in the reaction between oxygen and cytochrome-c oxidase received a sound confirmation by the resolution of compound A at room temperature. It is also pointed out that the so-called mixed valence state might not be a transient state in the catalytic reduction of oxygen. The functioning of cytochrome-c oxidase as a proton pump has been supported by a number of experimental results. Subunit III would be involved in this process. The redox link to the proton pump has been suggested to be at the Fea-CuA site. The molecular mechanism responsible for the proton pumping is still unknown.