His92 and His110 selectively affect different heme centers of adrenal cytochrome b(561)

Adrenal cytochrome b(561) (cyt b(561)), a transmembrane protein that shuttles reducing equivalents derived from ascorbate, has two heme centers with distinct spectroscopic signals and reactivity towards ascorbate. The His54/His122 and His88/His161 pairs furnish axial ligands for the hemes, but additional amino acid residues contributing to the heme centers have not been identified. A computational model of human cyt b(561) (Bashtovyy, D., Berczi, A., Asard, H., and Pali, T. (2003) Protoplasma 221, 31-40) predicts that His92 is near the His88/His161 heme and that His110 abuts the His54/His122 heme. We tested these predictions by analyzing the effects of mutations at His92 or His110 on the spectroscopic and functional properties. Wild type cytochrome and mutants with substitutions in other histidine residues or in Asn78 were used for comparison. The largest lineshape changes in the optical absorbance spectrum of the high-potential (b(H)) peak were seen with mutation of His92; the largest changes in the low-potential (b(L)) peak lineshape were observed with mutation of His110. In the EPR spectra, mutation of His92 shifted the position of the g=3.1 signal (b(H)) but not the g=3.7 signal (b(L)). In reductive titrations with ascorbate, mutations in His92 produced the largest increase in the midpoint for the b(H) transition; mutations in His110 produced the largest decreases in DeltaA(561) for the b(L) transition. These results indicate that His92 can be considered part of the b(H) heme center, and His110 part of the b(L) heme center, in adrenal cyt b(561).     

Functional characterization of human duodenal cytochrome b (Cybrd1): Redox properties in relation to iron and ascorbate metabolism

Duodenal cytochrome b (Dcytb or Cybrd1) is an iron-regulated protein, highly expressed in the duodenal brush border membrane. It has ferric reductase activity and is believed to play a physiological role in dietary iron absorption. Its sequence identifies it as a member of the cytochrome b₅₆₁ family. A His-tagged construct of human Dcytb was expressed in insect Sf9 cells and purified. Yields of protein were increased by supplementation of the cells with 5-aminolevulinic acid to stimulate heme biosynthesis. Quantitative analysis of the recombinant Dcytb indicated two heme groups per monomer. Site-directed mutagenesis of any of the four conserved histidine residues (His 50, 86, 120 and 159) to alanine resulted in much diminished levels of heme in the purified Dcytb, while mutation of the non-conserved histidine 33 had no effect on the heme content. This indicates that those conserved histidines are heme ligands, and that the protein cannot stably bind heme if any of them is absent. Recombinant Dcytb was reduced by ascorbate under anaerobic conditions, the extent of reduction being 67% of that produced by dithionite. It was readily reoxidized by ferricyanide. EPR spectroscopy showed signals from low-spin ferriheme, consistent with bis-histidine coordination. These comprised a signal at g_max = 3.7 corresponding to a highly anisotropic species, and another at g_max = 3.18; these species are similar to those observed in other cytochromes of the b₅₆₁ family, and were reducible by ascorbate. In addition another signal was observed in some preparations at g_max = 2.95, but this was unreactive with ascorbate. Redox titrations indicated an average midpoint potential for the hemes in Dcytb of + 80 mV ± 30 mV; the data are consistent with either two hemes at the same potential, or differing in potential by up to 60 mV. These results indicate that Dcytb is similar to the ascorbate-reducible cytochrome b₅₆₁ of the adrenal chromaffin granule, though with some differences in midpoint potentials of the hemes.     

Mutations in cytochrome b that affect kinetics of the electron transfer reactions at center N in the yeast cytochrome bc1 complex

We have examined the pre-steady-state kinetics and thermodynamic properties of the b hemes in variants of the yeast cytochrome bc₁ complex that have mutations in the quinone reductase site (center N). Trp-30 is a highly conserved residue, forming a hydrogen bond with the propionate on the high potential b heme (b_H heme). The substitution by a cysteine (W30C) lowers the redox potential of the heme and an apparent consequence is a lower rate of electron transfer between quinol and heme at center N. Leu-198 is also in close proximity to the b_H heme and a L198F mutation alters the spectral properties of the heme but has only minor effects on its redox properties or the electron transfer kinetics at center N. Substitution of Met-221 by glutamine or glutamate results in the loss of a hydrophobic interaction that stabilizes the quinone ligands. Ser-20 and Gln-22 form a hydrogen-bonding network that includes His-202, one of the carbonyl groups of the ubiquinone ring, and an active-site water. A S20T mutation has long-range structural effects on center P and thermodynamic effects on both b hemes. The other mutations (M221E, M221Q, Q22E and Q22T) do not affect the ubiquinol oxidation kinetics at center P, but do modify the electron transfer reactions at center N to various extents. The pre-steady reduction kinetics suggest that these mutations alter the binding of quinone ligands at center N, possibly by widening the binding pocket and thus increasing the distance between the substrate and the b_H heme. These results show that one can distinguish between the contribution of structural and thermodynamic factors to center N function.     

Multiple step assembly of the transmembrane cytochrome b6

We have analyzed the role of individual heme-ligating histidine residues for assembly of holo-cytochrome b₆, and we show that the two hemes b_L and b_H bind in two subsequent steps to the apo-protein. Binding of the low-potential heme b_L is a prerequisite for binding the high-potential heme b_H. After substitution of His86, which serves as an axial ligand for heme b_L, the apo-protein did not bind heme, while substitution of the heme b_L-ligating residue His187 still allowed binding of both hemes. Similarly, after replacement of His202, one axial ligand to heme b_H, binding of only heme b_L was observed, whereas replacement of His100, the other heme b_H ligand, resulted in binding of both hemes. These data indicate sequential heme binding during formation of the holo-cytochrome, and the two histidine residues, which serve as axial ligands to the same heme molecule (heme b_L or heme b_H), have different importance during heme binding and cytochrome assembly. Furthermore, determination of the heme midpoint potentials of the various cytochrome b₆ variants indicates a cooperative adjustment of the heme midpoint potentials in cytochrome b₆.     

Spectral and kinetic resolution of the bc1 complex components in situ: A simple and robust alternative to the traditional difference wavelength approach

The kinetics of the cytochrome (cyt) components of the bc₁ complex (ubiquinol: cytochrome c oxidoreductase, Complex III) are traditionally followed by using the difference of absorbance changes at two or more different wavelengths. However, this difference-wavelength (DW) approach is of limited accuracy in the separation of absorbance changes of components with overlapping spectral bands. To resolve the kinetics of individual components in Rhodobacter sphaeroides chromatophores, we have tested a simplified version of a least squares (LS) analysis, based on measurement at a minimal number of different wavelengths. The success of the simplified LS analysis depended significantly on the wavelengths used in the set. The “traditional” set of 6 wavelengths (542, 551, 561, 566, 569 and 575 nm), normally used in the DW approach to characterize kinetics of cyt c_tot (cyt c₁ + cyt c₂), cyt b_L, cyt b_H, and P870 in chromatophores, could also be used to determine these components via the simplified LS analysis, with improved resolution of the individual components. However, this set is not sufficient when information about cyts c₁ and c₂ is needed. We identified multiple alternative sets of 5 and 6 wavelengths that could be used to determine the kinetics of all 5 components (P870 and cyts c₁, c₂, b_L, and b_H) simultaneously, with an accuracy comparable to that of the LS analysis based on a full set of wavelengths (1 nm intervals). We conclude that a simplified version of LS deconvolution based on a small number of carefully selected wavelengths provides a robust and significant improvement over the traditional DW approach, since it accounts for spectral interference of the different components, and uses fewer measurements when information about all five individual components is needed. Using the simplified and complete LS analyses, we measured the simultaneous kinetics of all cytochrome components of bc₁ complex in the absence and presence of specific inhibitors and found that they correspond well to those expected from the modified Q-cycle. This is the first study in which the kinetics of all cytochrome and reaction center components of the bc₁ complex functioning in situ have been measured simultaneously, with full deconvolution over an extended time range.     

Ascorbate-independent electron transfer between cytochromeb 561 and a 27 kDa ascorbate peroxidase of bean hypocotyls

Summary Cytochromeb ₅₆₁ (cytb ₅₆₁) is a trans-membrane cytochrome probably ubiquitous in plant cells. In vitro, it is readily reduced by ascorbate or by juglonol, which in plasma membrane (PM) preparations from plant tissues is efficiently produced by a PM-associated NAD(P)Hquinone reductase activity. In bean hypocotyl PM, juglonol-reduced cytb ₅₆₁ was not oxidized by hydrogen peroxide alone, but hydrogen peroxide led to complete oxidation of the cytochrome in the presence of a peroxidase found in apoplastic extracts of bean hypocotyls. This peroxidase active on cytb ₅₆₁ was purified from the apoplastic extract and identified as an ascorbate peroxidase of the cytosolic type. The identification was based on several grounds, including the ascorbate peroxidase activity (albeit labile), the apparent molecular mass of the subunit of 27 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the dimeric native structure, the typical spectral properties of a heme-containing peroxidase, and an N-terminal sequence strongly conserved with cytosolic ascorbate peroxidases of plants. Cytb ₅₆₁ used in the experiments was purified from bean hypocotyl PM and juglonol was enzymatically produced by recombinant NAD(P)H:quinone reductase. It is shown that NADPH, NAD(P)H:quinone reductase, juglone, cytb ₅₆₁, the peroxidase interacting with cytb ₅₆₁, and H₂O₂, in this order, constitute an artificial electron transfer chain in which cytb ₅₆₁ is indirectly reduced by NADPH and indirectly oxidized by H₂O₂.Abbreviations APX ascorbate peroxidase - b ₅₆₁PX cytochrome 6561 peroxidase - CPX coniferol peroxidase - cyt cytochrome - GPX guaia-col peroxidase - IWF intercellular washing fluid - MDHA monodehydroascorbate - PM plasma membrane     

Higher-plant plasma membrane cytochromeb 561: A protein in search of a function

Summary During the past twenty years evidence has accumulated on the presence of a specific high-potential, ascorbate-reducibleb-type cytochrome in the plasma membrane (PM) of higher plants. This cytochrome is named cytochromeb ₅₆₁ (cytb ₅₆₁) according to the wavelength maximum of its -band in the reduced form. More recent evidence suggests that this protein is homologous to ab-type cytochrome present in chromaffin granules of animal cells. The plant and animal cytochromes share a number of strikingly similar features, including the high redox potential, the ascorbate reducibility, and most importantly the capacity to transport electrons across the membrane they are located in. The PM cytb ₅₆₁ is found in all plant species and in a variety of tissues tested so far. It thus appears to be a ubiquitous electron transport component of the PM. The cytochromesb ₅₆₁ probably constitute a novel class of transmembrane electron transport proteins present in a large variety of eukaryotic cells. Of particular interest is the recent discovery of a number of plant genes that show striking homologies to the genes coding for the mammalian cytochromesb ₅₆₁. A number of highly relevant structural features, including hydrophobic domains, heme ligation sites, and possible ascorbate and monodehydroascorbate binding sites are almost perfectly conserved in all these proteins. At the same time the plant gene products show interesting differences related to their specific location at the PM, such as potentially N-linked glycosylation sites. It is also clear that at least in several plants cytb ₅₆₁ is represented by a multigene family. The current paper presents the first overview focusing exclusively on the plant PM cytb ₅₆₁, compares it to the animal cytb ₅₆₁, and discusses the possible physiological function of these proteins in plants.Abbreviations Asc ascorbate - cyt cytochrome - DHA dehydroascorbate - E₀ standard redox potential - EST expressed sequence tag - His histidine - MDA monodehydroascorbate - Met methionine - PM plasma membrane     

Heme-heme and heme-ligand interactions in the di-heme oxygen-reducing site of cytochrome bd from Escherichia coli revealed by nanosecond absorption spectroscopy

Cytochrome bd is a terminal quinol:O₂ oxidoreductase of respiratory chains of many bacteria. It contains three hemes, b₅₅₈, b₅₉₅, and d. The role of heme b₅₉₅ remains obscure. A CO photolysis/recombination study of the membranes of Escherichia coli containing either wild type cytochrome bd or inactive E445A mutant was performed using nanosecond absorption spectroscopy. We compared photoinduced changes of heme d-CO complex in one-electron-reduced, two-electron-reduced, and fully reduced states of cytochromes bd. The line shape of spectra of photodissociation of one-electron-reduced and two-electron-reduced enzymes is strikingly different from that of the fully reduced enzyme. The difference demonstrates that in the fully reduced enzyme photolysis of CO from heme d perturbs ferrous heme b₅₉₅ causing loss of an absorption band centered at 435 nm, thus supporting interactions between heme b₅₉₅ and heme d in the di-heme oxygen-reducing site, in agreement with previous works. Photolyzed CO recombines with the fully reduced enzyme monoexponentially with τ ∼ 12 μs, whereas recombination of CO with one-electron-reduced cytochrome bd shows three kinetic phases, with τ ∼ 14 ns, 14 μs, and 280 μs. The spectra of the absorption changes associated with these components are different in line shape. The 14 ns phase, absent in the fully reduced enzyme, reflects geminate recombination of CO with part of heme d. The 14-μs component reflects bimolecular recombination of CO with heme d and electron backflow from heme d to hemes b in ∼ 4% of the enzyme population. The final, 280-μs component, reflects return of the electron from hemes b to heme d and bimolecular recombination of CO in that population. The fact that even in the two-electron-reduced enzyme, a nanosecond geminate recombination is observed, suggests that namely the redox state of heme b₅₉₅, and not that of heme b₅₅₈, controls the pathway(s) by which CO migrates between heme d and the medium.     

Differential mechanism of light-induced and oxygen-dependent restoration of the high-potential form of cytochrome b559 in Tris-treated Photosystem II membranes

The effect of illumination and molecular oxygen on the redox and the redox potential changes of cytochrome b₅₅₉ (cyt b₅₅₉) has been studied in Tris-treated spinach photosystem II (PSII) membranes. It has been demonstrated that the illumination of Tris-treated PSII membranes induced the conversion of the intermediate-potential (IP) to the reduced high-potential (HP^Fe2+) form of cyt b₅₅₉, whereas the removal of molecular oxygen resulted in the conversion of the IP form to the oxidized high-potential (HP^Fe3+) form of cyt b₅₅₉. Light-induced conversion of cyt b₅₅₉ from the IP to the HP form was completely inhibited above pH 8 or by the modification of histidine ligand that prevents its protonation. Interestingly, no effect of high pH or histidine modification was observed during the conversion of the IP to the HP form of cyt b₅₅₉ after the removal of molecular oxygen. These results indicate that conversion from the IP to the HP form of cyt b₅₅₉ proceeds via different mechanisms. Under illumination, conversion of the IP to the HP form of cyt b₅₅₉ depends primarily on the protonation of the histidine residue, whereas under anaerobic conditions, the conversion of the IP to the HP form of cyt b₅₅₉ is driven by higher hydrophobicity of the environment around the heme iron resulting from the absence of molecular oxygen.     

Spectroscopic and Functional Characterizations of Cyanobacterium Synechocystis PCC 6803 Mutants on and near the Heme Axial Ligand of Cytochrome b559 in Photosystem II

The functional role of cytochrome (cyt) b₅₅₉ in photosystem II (PSII) was investigated in H22Kα and Y18Sα cyt b₅₅₉ mutants of the cyanobacterium Synechocystis sp. PCC6803. H22Kα and Y18Sα cyt b₅₅₉ mutant carries one amino acid substitution on and near one of heme axial ligands of cyt b₅₅₉ in PSII, respectively. Both mutants grew photoautotrophically, assembled stable PSII, and exhibited the normal period-four oscillation in oxygen yield. However, both mutants showed several distinct chlorophyll a fluorescence properties and were more susceptible to photoinhibition than wild type. EPR results indicated the displacement of one of the two axial ligands to the heme of cyt b₅₅₉ in H22Kα mutant reaction centers, at least in isolated reaction centers. The maximum absorption of cyt b₅₅₉ in Y18Sα mutant PSII core complexes was shifted to 561 nm. Y18Sα and H22Kα mutant PSII core complexes contained predominately the low potential form of cyt b₅₅₉. The findings lend support to the concept that the redox properties of cyt b₅₅₉ are strongly influenced by the hydrophobicity and ligation environment of the heme. When the cyt b₅₅₉ mutations placed in a D1-D170A genetic background that prevents assembly of the manganese cluster, accumulation of PSII is almost completely abolished. Overall, our data support a functional role of cyt b₅₅₉ in protection of PSII under photoinhibition conditions in vivo.     

Time-resolved OH → EH transition of the aberrant ba3 oxidase from Thermus thermophilus

The kinetics of single-electron injection into the oxidized nonrelaxed state (O_H → E_H transition) of the aberrant ba₃ cytochrome oxidase from Thermus thermophilus, noted for its lowered efficiency of proton pumping, was investigated by time-resolved optical spectroscopy. Two main phases of intraprotein electron transfer were resolved. The first component (τ ∼ 17 μs) reflects oxidation of Cu_A and reduction of the heme groups (low-spin heme b and high-spin heme a₃ in a ratio close to 50:50). The subsequent component (τ ∼ 420 μs) includes reoxidation of both hemes by Cu_B. This is in significant contrast to the O_H → E_H transition of the aa₃-type cytochrome oxidase from Paracoccus denitrificans, where the fastest phase is exclusively due to transient reduction of the low-spin heme a, without electron equilibration with the binuclear center. On the other hand, the one-electron reduction of the relaxed O state in ba₃ oxidase was similar to that in aa₃ oxidase and only included rapid electron transfer from Cu_A to the low-spin heme b. This indicates a functional difference between the relaxed O and the pulsed O_H forms also in the ba₃ oxidase from T. thermophilus.     

Superoxide oxidase and reductase activity of cytochrome b559 in photosystem II

This study provides evidence for the superoxide oxidase and the superoxide reductase activity of cytochrome b₅₅₉ (cyt b₅₅₉) in PSII. It is reported that in Tris-treated PSII membranes upon illumination, both the intermediate potential (IP) and the reduced high potential (HP^red) forms of cyt b₅₅₉ exhibit superoxide scavenging activity and interconversion between IP and HP^red form. When Tris-treated PSII membranes were illuminated in the presence of spin trap EMPO, the formation of superoxide anion radical (O₂⁻) was observed, as confirmed by EPR spin-trapping spectroscopy. The observations that the addition of enzymatic (superoxide dismutase) and non-enzymatic (cytochrome c, α-tocopherol and Trolox) O₂⁻ scavengers prevented the light-induced conversion of IP ↔ HP^red cyt b₅₅₉ confirmed that IP and HP^red cyt b₅₅₉ are reduced and oxidized by O₂⁻, respectively. Redox changes in cyt b₅₅₉ by an exogenous source of O₂⁻ reconfirmed the superoxide oxidase and reductase activity of cyt b₅₅₉. Furthermore, the light-induced conversion of IP to HP^red form of cyt b₅₅₉ was completely inhibited at pH > 8 and by chemical modification of the imidazole ring of histidine residues using diethyl pyrocarbonate. We proposed that a change in the environment around the heme iron, induced by the protonation and deprotonation of His²² residue generates a favorable condition for the oxidation and reduction of O₂⁻, respectively.     

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     

Molecular and biochemical comparison of two different apyrases from Arabidopsis thaliana

Recent advances in the Arabidopsis sequencing project has elucidated the presence of two genes Atb561-A and Atb561-B that show limited homology to the DNA sequence encoding for the mammalian chromaffin granule cytochrome b-561 (cyt b-561). Detailed analysis of the structural features and conserved residues reveals, however, that the structural homology between the presumptive Arabidopsis proteins and the animal proteins is very high. All proteins are hydrophobic and show highly conserved transmembrane helices. The presumably heme-binding histidine residues in the plant and animal sequences as well as the suggested binding site for the electron acceptor, monodehydroascorbate, are strictly conserved. In contrast, the suggested electron donor (ascorbate) binding site is not very well conserved between the plant and animal sequences questioning the function of this motif. Sequence analysis of the Atb561-B gene demonstrates a different splicing than that initially predicted in silico resulting in a protein with nine extra amino acids and a significantly higher homology to the other cyt b-561 sequences. The homology between the plant and animal sequences is further supported by the strong similarity between a number of biochemical properties of the chromaffin cyt b-561 and the cyt b-561 isolated from bean hook plasma membranes. Since the mammalian cyt b-561 is considered specific to neuroadrenergic tissues, the identification of a closely related homologue in an aneural organism demonstrates that these proteins constitute a new class of widely occurring membrane proteins. Both the plant and animal cyt b-561 are involved in transmembrane electron transport using ascorbate as an electron donor. The similarity between these proteins therefore suggests, for the first time, that this transport supports a number of different cell physiological processes. An evolutionary relationship between the plant and animal proteins is presented.     

Heme/heme redox interaction and resolution of individual optical absorption spectra of the hemes in cytochrome bd from Escherichia coli

Cytochrome bd is a terminal component of the respiratory chain of Escherichia coli catalyzing reduction of molecular oxygen to water. It contains three hemes, b₅₅₈, b₅₉₅, and d. The detailed spectroelectrochemical redox titration and numerical modeling of the data reveal significant redox interaction between the low-spin heme b₅₅₈ and high-spin heme b₅₉₅, whereas the interaction between heme d and either hemes b appears to be rather weak. However, the presence of heme d itself decreases much larger interaction between the two hemes b. Fitting the titration data with a model where redox interaction between the hemes is explicitly included makes it possible to extract individual absorption spectra of all hemes. The α- and β-band reduced-minus-oxidized difference spectra agree with the data published earlier ([22] J.G. Koland, M.J. Miller, R.B. Gennis, Potentiometric analysis of the purified cytochrome d terminal oxidase complex from Escherichia coli, Biochemistry 23 (1984) 1051-1056., and [23] R.M. Lorence, J.G. Koland, R.B. Gennis, Coulometric and spectroscopic analysis of the purified cytochrome d complex of Escherichia coli: evidence for the identification of “cytochrome a₁” as cytochrome b₅₉₅, Biochemistry 25 (1986) 2314-2321.). The Soret band spectra show λ_max = 429.5 nm, λ_min ≈ 413 nm (heme b₅₅₈), λ_max = 439 nm, λ_min ≈ 400 ± 1 nm (heme b₅₉₅), and λ_max = 430 nm, λ_min = 405 nm (heme d). The spectral contribution of heme d to the complex Soret band is much smaller than those of either hemes b; the Soret/α (ΔA₄₃₀:ΔA₆₂₉) ratio for heme d is 1.6.     

PCR-RFLP analysis of mitochondrial DNA cytochrome b gene among Haruan (Channa striatus) in Malaysia

Haruan (Channa striatus) is in great demand in the Malaysian domestic fish market. In the present study, mtDNA cyt b was used to investigate genetic variation of C. striatus among populations in Peninsular Malaysia. The overall population of C. striatus demonstrated a high level of haplotype diversity (h) and a low-to-moderate level of nucleotide diversity (π). Analysis of molecular variance (AMOVA) results showed a significantly different genetic differentiation among 6 populations (F_ST = 0.37566, P = 0.01). Gene flow (Nm) was high and ranged from 0.32469 to infinity (∞). No significant relationship between genetic distance and geographic distance was detected. A UPGMA tree based on the distance matrix of net interpopulation nucleotide divergence (d_A) and haplotype network of mtDNA cyt b revealed that C. striatus is divided into 2 major clades. The neutrality and mismatch distribution tests for all populations suggested that C. striatus in the study areas had undergone population expansion. The estimated time of population expansion in the mtDNA cyt b of C. striatus populations occurred 0.72-6.19 million years ago. Genetic diversity of mtDNA cyt b and population structure among Haruan populations in Peninsular Malaysia will be useful in fisheries management for standardization for Good Agriculture Practices (GAP) in fish-farming technology, as well as providing the basis for Good Manufacturing Practices (GMP).     

Spectral analysis of the bc1 complex components in situ: Beyond the traditional difference approach

The cytochrome (cyt) bc₁ complex (ubiquinol: cytochrome c oxidoreductase) is the central enzyme of mitochondrial and bacterial electron-transport chains. It is rich in prosthetic groups, many of which have significant but overlapping absorption bands in the visible spectrum. The kinetics of the cytochrome components of the bc₁ complex are traditionally followed by using the difference of absorbance changes at two or more different wavelengths. This difference-wavelength (DW) approach has been used extensively in the development and testing of the Q-cycle mechanism of the bc₁ complex in Rhodobacter sphaeroides chromatophores. However, the DW approach does not fully compensate for spectral interference from other components, which can significantly distort both amplitudes and kinetics. Mechanistic elaboration of cyt bc₁ turnover requires an approach that overcomes this limitation. Here, we compare the traditional DW approach to a least squares (LS) analysis of electron transport, based on newly determined difference spectra of all individual components of cyclic electron transport in chromatophores. Multiple sets of kinetic traces, measured at different wavelengths in the absence and presence of specific inhibitors, were analyzed by both LS and DW approaches. Comparison of the two methods showed that the DW approach did not adequately correct for the spectral overlap among the components, and was generally unreliable when amplitude changes for a component of interest were small. In particular, it was unable to correct for extraneous contributions to the amplitudes and kinetics of cyt b_L. From LS analysis of the chromophoric components (RC, c_tot, b_H and b_L), we show that while the Q-cycle model remains firmly grounded, quantitative reevaluation of rates, amplitudes, delays, etc., of individual components is necessary. We conclude that further exploration of mechanisms of the bc₁ complex, will require LS deconvolution for reliable measurement of the kinetics of individual components of the complex in situ.     

b-Type cytochromes in plasma membranes ofPhaseolus vulgaris hypocotyls,Arabidopsis thaliana leaves, andZea mays roots

Summary The plasma membrane of higher plants contains more than one kind ofb-type cytochromes. One of these has a high redox potential and can be fully reduced by ascorbate. This component, the cytochromeb ₅₆₁ (cytb ₅₆₁), has its characteristic -band absorbance close to 561 nm wavelength at room temperature. Cytb ₅₆₁ was first isolated from etiolated bean hook plasma membranes by two consecutive anion exchange chromatography steps. During the first step performed at pH 8, cytb ₅₆₁ did not bind to the anion exchange column, but otherb-type cytochromes did. In the second step performed at pH 9.9, cytb ₅₆₁ was bound to the column and was eluted from the column at an ionic strength of about 100 mM KCl. However, when the same protocol was applied to the solubilized plasma membrane proteins fromArabidopsis thaliana leaves and maize roots, the ascorbate-reducible cytb ₅₆₁ bound already to the first anion exchange column at pH 8 and was eluted also at an ionic strength of about 100 mM KCl. Otherb-type cytochromes than the ascorbate-reducible cytb ₅₆₁ from the plasma membranes of Arabidopsis leaves and maize roots showed similar Chromatographic characteristics to that of bean hypocotyls. These results demonstrate particular differences in the Chromatographic behavior of cytb ₅₆₁ from different sources.Abbreviations cyt b ₅₆₁ cytochromeb ₅₆₁ - PM plasma membrane - PAGE polyacrylamide gel electrophoresis     

Electron transfer patterns of the di-heme protein cytochrome c4 from Pseudomonas stutzeri

We report kinetic data for the two-step electron transfer (ET) oxidation and reduction of the two-domain di-heme redox protein Pseudomonas stutzeri cytochrome (cyt) c₄ by [Co(bipy)₃]^2+/3+ (bipy = 2,2′-bipyridine). Following earlier reports, the data accord with both bi- and tri-exponential kinetics. A complete kinetic scheme includes both “cooperative” intermolecular ET between each heme group and the external reaction partner, and intramolecular ET between the two heme groups. A new data analysis scheme shows unequivocally that two-ET oxidation and reduction of P. stutzeri cyt c₄ is entirely dominated by intermolecular ET between the heme groups and the external reaction partner in the ms time range, with virtually no contribution from intramolecular interheme ET in this time range. This is in striking contrast to two-ET electrochemical oxidation or reduction of P. stutzeri cyt c₄ for which fast, ms to sub-ms intramolecular interheme ET is a crucial step. The rate constant dependence on the solvent viscosity has disclosed strong coupling to both a (set of) frictionally damped solvent/protein nuclear modes and intramolecular friction-less “ballistic” modes, indicative of notable protein structural mobility in the overall two-ET process. We suggest that conformational protein mobility blocks intramolecular interheme ET in bulk homogeneous solution but triggers opening of this gated ET channel in the electrochemical environment or in the membrane environment of natural respiratory cyt c₄ function.     

The Rieske/cytochrome b complex of Heliobacteria

Heliobacteria have a Rieske/cytochrome b complex composed of a Rieske protein, a cytochrome b_6, a subunit IV and a di-heme cytochrome c. The overall structure of the complex seems close to the b₆f complex from cyanobacteria and chloroplasts to the exception of the di-heme cytochrome. We show here by biochemical and biophysical studies that a heme c_i is covalently attached to the Rieske/cytochrome b complex from Heliobacteria. We studied the EPR signature of this heme in two different species, Heliobacterium modesticaldum and Heliobacillus mobilis. In contrast to the case of b₆f complex, a strong axial ligand to the heme is present, most probably a protonatable amino acid residue.