Redox potentials of the photosynthetic bacterial cytochromes c2 and the structural bases for variability

Martin David Kamen (1913-2002): discoverer of carbon 14, and of new cytochromes in photosynthetic bacteria

Martin Kamen was a giant of twentieth century science. Trained as a physical chemist, he was the co-discoverer of radioactive Carbon 14, which has transformed many areas of science as a tracer and as a way to date artifacts. He later switched to the study of metabolism and biochemistry and made important contributions to the understanding of nitrogen fixation and photosynthesis. Finally, he studied cytochromes, primarily from anoxygenic photosynthetic bacteria.

Genomics of a phototrophic nitrite oxidizer: insights into the evolution of photosynthesis and nitrification

Oxygenic photosynthesis evolved from anoxygenic ancestors before the rise of oxygen ~2.32 billion years ago; however, little is known about this transition. A high redox potential reaction center is a prerequisite for the evolution of the water-oxidizing complex of photosystem II. Therefore, it is likely that high-potential phototrophy originally evolved to oxidize alternative electron donors that utilized simpler redox chemistry, such as nitrite or Mn. To determine whether nitrite could have had a role in the transition to high-potential phototrophy, we sequenced and analyzed the genome of Thiocapsa KS1, a Gammaproteobacteria capable of anoxygenic phototrophic nitrite oxidation. The genome revealed a high metabolic flexibility, which likely allows Thiocapsa KS1 to colonize a great variety of habitats and to persist under fluctuating environmental conditions. We demonstrate that Thiocapsa KS1 does not utilize a high-potential reaction center for phototrophic nitrite oxidation, which suggests that this type of phototrophic nitrite oxidation did not drive the evolution of high-potential phototrophy. In addition, phylogenetic and biochemical analyses of the nitrite oxidoreductase (NXR) from Thiocapsa KS1 illuminate a complex evolutionary history of nitrite oxidation. Our results indicate that the NXR in Thiocapsa originates from a different nitrate reductase clade than the NXRs in chemolithotrophic nitrite oxidizers, suggesting that multiple evolutionary trajectories led to modern nitrite-oxidizing bacteria.

Crystallization of proteins from crude bovine rod outer segments

Obtaining protein crystals suitable for X-ray diffraction studies comprises the greatest challenge in the determination of protein crystal structures, especially for membrane proteins and protein complexes. Although high purity has been broadly accepted as one of the most significant requirements for protein crystallization, a recent study of the Escherichia coli proteome showed that many proteins have an inherent propensity to crystallize and do not require a highly homogeneous sample (Totir et al., 2012). As exemplified by RPE65 (Kiser, Golczak, Lodowski, Chance, & Palczewski, 2009), there also are cases of mammalian proteins crystallized from less purified samples. To test whether this phenomenon can be applied more broadly to the study of proteins from higher organisms, we investigated the protein crystallization profile of bovine rod outer segment (ROS) crude extracts. Interestingly, multiple protein crystals readily formed from such extracts, some of them diffracting to high resolution that allowed structural determination. A total of seven proteins were crystallized, one of which was a membrane protein. Successful crystallization of proteins from heterogeneous ROS extracts demonstrates that many mammalian proteins also have an intrinsic propensity to crystallize from complex biological mixtures. By providing an alternative approach to heterologous expression to achieve crystallization, this strategy could be useful for proteins and complexes that are difficult to purify or obtain by recombinant techniques.

Analysis of the electrochemistry of hemes with E(m)s spanning 800 mV

The free energy of heme reduction in different proteins is found to vary over more than 18 kcal/mol. It is a challenge to determine how proteins manage to achieve this enormous range of E(m)s with a single type of redox cofactor. Proteins containing 141 unique hemes of a-, b-, and c-type, with bis-His, His-Met, and aquo-His ligation were calculated using Multi-Conformation Continuum Electrostatics (MCCE). The experimental E(m)s range over 800 mV from -350 mV in cytochrome c(3) to 450 mV in cytochrome c peroxidase (vs. SHE). The quantitative analysis of the factors that modulate heme electrochemistry includes the interactions of the heme with its ligands, the solvent, the protein backbone, and sidechains. MCCE calculated E(m)s are in good agreement with measured values. Using no free parameters the slope of the line comparing calculated and experimental E(m)s is 0.73 (R(2) = 0.90), showing the method accounts for 73% of the observed E(m) range. Adding a +160 mV correction to the His-Met c-type hemes yields a slope of 0.97 (R(2) = 0.93). With the correction 65% of the hemes have an absolute error smaller than 60 mV and 92% are within 120 mV. The overview of heme proteins with known structures and E(m)s shows both the lowest and highest potential hemes are c-type, whereas the b-type hemes are found in the middle E(m) range. In solution, bis-His ligation lowers the E(m) by approximately 205 mV relative to hemes with His-Met ligands. The bis-His, aquo-His, and His-Met ligated b-type hemes all cluster about E(m)s which are approximately 200 mV more positive in protein than in water. In contrast, the low potential bis-His c-type hemes are shifted little from in solution, whereas the high potential His-Met c-type hemes are raised by approximately 300 mV from solution. The analysis shows that no single type of interaction can be identified as the most important in setting heme electrochemistry in proteins. For example, the loss of solvation (reaction field) energy, which raises the E(m), has been suggested to be a major factor in tuning in situ E(m)s. However, the calculated solvation energy vs. experimental E(m) shows a slope of 0.2 and R(2) of 0.5 thus correlates weakly with E(m)s. All other individual interactions show even less correlation with E(m). However the sum of these terms does reproduce the range of observed E(m)s. Therefore, different proteins use different aspects of their structures to modulate the in situ heme electrochemistry. This study also shows that the calculated E(m)s are relatively insensitive to different heme partial charges and to the protein dielectric constant used in the simulation.

Cloning, expression and physicochemical characterization of a di-heme cytochrome c (4) from the psychrophilic bacterium Pseudoalteromonas haloplanktis TAC 125

The 20-kDa di-heme cytochrome c (4) from the psycrophilic bacterium Pseudoalteromonas haloplanktis TAC 125 was cloned and expressed in Escherichia coli and investigated through UV-vis and (1)H NMR spectroscopies and protein voltammetry. The model structure was computed using the X-ray structure of Pseudomonas stutzeri cytochrome c (4) as a template. The protein shows unprecedented properties within the cytochrome c (4) family, including (1) an almost nonpolar surface charge distribution, (2) the absence of high-spin heme Fe(III) states, indicative of a thermodynamically stable and kinetically inert axial heme His,Met coordination, and (3) identical E degrees ' values for the two heme centers (+0.322 V vs the standard hydrogen elecrode). At pH extremes, both heme groups undergo the "acid" and "alkaline" conformational transitions typical of class I cytochromes c, involving ligand-exchange equilibria, whereas at intermediate pH values their electronic properties are sensitive to several residue ionizations.

Conservation of the free energy change of the alkaline isomerization in mitochondrial and bacterial cytochromes c

The thermodynamic parameters of the alkaline transition for oxidized native yeast iso-1 cytochrome c and Rhodopseudomonas palustris cytochrome c(2) (cytc(2)) have been determined through direct electrochemistry experiments carried out at variable pH and temperature and compared to those for horse and beef heart cytochromes c. We have found that both transition enthalpy and entropy are remarkably species dependent, following the order R. palustris cytc(2) >> beef (horse) heart cytc>yeast iso-1 cytc. Considering the high homology at the heme-protein interface in the native species, this variability is likely to be mainly determined by differences in the structural and solvation properties and the relative abundance of the various alkaline conformers. Notably, changes in transition enthalpy and entropy among these cytochromes c are compensative and result in small variations in the free energy change of the process (which amounts approximately to +50 kJ mol(-1)) and consequently in the apparent pK(a) value. This compensation indicates that solvent reorganization effects play an important role in the thermodynamics of the transition. This mechanism is functional to ensure a relatively high pK(a) value for the alkaline transition, which is needed to preserve His,Met ligation to the heme iron in cytochrome c at physiological pH and temperature, hence the E(o) value required for the biological function.

Cleavage of the iron-methionine bond in c-type cytochromes: crystal structure of oxidized and reduced cytochrome c(2) from Rhodopseudomonas palustris and its ammonia complex

The three-dimensional structures of the native cytochrome c(2) from Rhodopseudomonas palustris and of its ammonia complex have been obtained at pH 4.4 and pH 8.5, respectively. The structure of the native form has been refined in the oxidized state at 1.70 A and in the reduced state at 1.95 A resolution. These are the first high-resolution crystal structures in both oxidation states of a cytochrome c(2) with relatively high redox potential (+350 mV). The differences between the two oxidation states of the native form, including the position of internal water molecules, are small. The unusual six-residue insertion Gly82-Ala87, which precedes the heme binding Met93, forms an isolated 3(10)-helix secondary structural element not previously observed in other c-type cytochromes. Furthermore, this cytochrome shows an external methionine residue involved in a strained folding near the exposed edge of the heme. The structural comparison of the present cytochrome c(2) with other c-type cytochromes has revealed that the presence of such a residue, with torsion angles phi and psi of approximately -140 and -130 degrees, respectively, is a typical feature of this family of proteins. The refined crystal structure of the ammonia complex, obtained at 1.15 A resolution, shows that the sulphur atom of the Met93 axial ligand does not coordinate the heme iron atom, but is replaced by an exogenous ammonia molecule. This is the only example so far reported of an X-ray structure with the heme iron coordinated by an ammonia molecule. The detachment of Met93 is accompanied by a very localized change in backbone conformation, involving mainly the residues Lys92, Met93, and Thr94. Previous studies under typical denaturing conditions, including high-pH values and the presence of exogenous ligands, have shown that the detachment of the Met axial ligand is a basic step in the folding/unfolding process of c-type cytochromes. The ammonia adduct represents a structural model for this important step of the unfolding pathway. Factors proposed to be important for the methionine dissociation are the strength of the H-bond between the Met93 and Tyr66 residues that stabilizes the native form, and the presence in this bacterial cytochrome c(2) of the rare six-residue insertion in the helix 3(10) conformation that increases Met loop flexibility.

Protein dynamics: imidazole binding to class I C-type cytochromes

The oxidized cytochrome c(2) from the purple phototrophic bacteria, Rhodobacter sphaeroides and Rhodobacter capsulatus, bind the neutral species of imidazole (K(a) = 1440 +/- 40 M(-1)) 50 times more strongly than does horse mitochondrial cytochrome c (K(a) = 30 +/- 1 M(-1)). The kinetics of imidazole binding are consistent with a change in rate-limiting step at high ligand concentrations for all three proteins. This is attributed to a conformational change leading to breakage of the iron-methionine bond which precedes imidazole binding. The three-dimensional structure of the Rb. sphaeroides cytochrome c(2) imidazole complex (Axelrod et al., Acta Crystalogr. D50, 596-602) supports the view that the conformational changes are essentially localized to approximately seven residues on either side of the ligated methionine and there is a hydrogen bond between the Phe 102 carbonyl, an internal water, and the bound imidazole. Insertions and deletions in this region of cytochrome c(2), the presence of a proline near the methionine, and the smaller size of the dynamic region of horse cytochrome c suggest that the stabilizing hydrogen bond is not present in horse cytochrome c, hence, the dramatic difference in affinity for imidazole. The kinetics of ligand binding do not correlate with either the strength of the iron-methionine bond as measured by the pK of the 695-nm absorption band or the overall stability of the cytochromes studied. However, the very similar imidazole binding properties of the two cytochromes c(2) indicate that the Rb. sphaeroides cytochrome c(2)-imidazole complex structure is an excellent model for the corresponding Rb. capsulatus cytochrome c(2) complex. It is notable that the movement of the peptide chain in the vicinity of the ligated methionine has been preserved throughout evolution and suggests a role in the function of c-type cytochromes.

Replacement of lysine 45 by uncharged residues modulates the redox-Bohr effect in tetraheme cytochrome c3 of Desulfovibrio vulgaris (Hildenborough)

The structural basis for the pH dependence of the redox potential in the tetrahemic Desulfovibrio vulgaris (Hildenborough) cytochrome c3 was investigated by site-directed mutagenesis of charged residues in the vicinity of heme I. Mutation of lysine 45, located in the neighborhood of the propionates of heme I, by uncharged residues, namely threonine, glutamine and leucine, was performed. The replacement of a conserved charged residue, aspartate 7, present in the N-terminal region and near heme I was also attempted. The analysis of the redox interactions as well as the redox-Bohr behavior of the mutated cytochromes c3 allowed the conclusion that residue 45 has a functional role in the control of the pKa of the propionate groups of heme I and confirms the involvement of this residue in the redox-Bohr effect.

Purification and primary structure analysis of two cytochrome c2 isozymes from the purple phototrophic bacterium Rhodospirillum centenum

The isolation and amino acid sequences of two cytochromes c-552 from the thermotolerant bacterium Rhodospirillum (R.) centenum have been determined. They are very similar to one another with 85% identity. They are homologous to the cytochromes c2 from purple bacteria with approximately 67% identity to that from Rhodopseudomonas (Rps.) palustris compared to only 42% identity with others of the c2 subclass. In addition, they share an unusual six-residue insertion with Rps. palustris cytochrome c2 not found in any other cytochrome. The relationship with Rps. palustris is thus highly significant. The redox potentials of the R. centenum isozymes are 293 and 316 mV. Although the proteins have strongly different iso-electric points, both have three conserved lysine residues at the proposed site of electron transfer. These results suggest that they may be functionally interchangeable.

Cyclic voltammetry and 1H-NMR of Rhodopseudomonas palustris cytochrome c2 pH-dependent conformational states

The pH-induced protein conformational transitions and changes in the ligation state of the heme iron in cytochrome c2 from Rhodopseudomonas palustris were monitored by electrochemical and spectroscopic measurements. In the pH range 1.5-11, the E degree values (and/or the peak potentials) determined by cyclic voltammetry, the electronic spectra and the hyperfine-shifted 1H-NMR resonances of the protein are sensitive to a number of acid/base equilibria. In particular, four equilibria have been determined for the oxidized protein with pKa values of 2.5, 5.5, 6.6 and 9.0. The lowest pKa most probably involves disruption of both axial heme iron bonds and protein unfolding. The subsequent pKa is associated with a low-pH oxidation of the protein by dioxygen, which is accompanied by a conformational change. The equilibrium with an apparent pKa of 6.6 modulates the E degree values without determining any detectable spectral change and most likely involves the acid/base equilibrium of an histidine residue in close vicinity of the heme (possibly His53). Finally, the alkaline ionization is due to the replacement of the methionine axially bound to the heme iron with a stronger (most probably N-donor) ligand. The reduced alkaline form is unstable and spontaneously converts to the neutral reduced form with a kinetic constant of 0.98 s-1 at pH 9.2.

Structural similarity of cytochrome c2 from Rhodopseudomonas viridis to mitochondrial cytochromes c revealed by its crystal structure at 2.7 A resolution

The crystal structure of cytochrome c2 from Rhodopseudomonas viridis has been refined using molecular dynamics and restrained least-squares methods to a crystallographic R-factor of 0.216 at 2.7 A resolution. A structural comparison between Rps. viridis cytochrome c2 and the other bacterial cytochromes c2 or mitochondrial cytochromes c indicates that the overall protein foldings are very similar to each other with the exception of the surface loop and terminal region of the polypeptide chain. However, the position and hydrogen-bond pattern of the evolutionarily conserved water molecule buried within the heme binding pocket in Rps. viridis cytochrome c2 are common to those in the mitochondrial cytochromes c. This fact indicates that Rps. viridis cytochrome c2 is structurally more similar to mitochondrial cytochromes c than to the other bacterial cytochromes c2.

Overexpression of Desulfovibrio vulgaris Hildenborough cytochrome c553 in Desulfovibrio desulfuricans G200. Evidence of conformational heterogeneity in the oxidized protein by NMR

Plasmid pRC41, containing the cyf gene encoding cytochrome c533 from Desulfovibrio vulgaris Hildenborough, was transferred by conjugation from Escherichia coli to Desulfovibrio desulfuricans G200. The structural properties of the purified protein were studied by one-dimensional and two-dimensional NMR. A heterogeneity in the folding of the cytochrome isolated from D. vulgaris Hildenborough and from D. desulfuricans G200 was observed for the oxidized from. Temperature, pH and salt-dependence studies indicated that the heterogeneity does not result from an intermediate in the protein unfolding process, but derives from two conformations which are not in dynamic equilibrium.

Cytochrome c6 from Monoraphidium braunii. A cytochrome with an unusual heme axial coordination

A soluble monoheme c-type cytochrome (cytochrome c6) has been isolated from the green alga Monoraphidium braunii. It has a molecular mass of 9.3 kDa, an isoelectric point of 3.6 and a reduction potential of 358 mV at pH 7. The determined amino acid sequence allows its classification as a class-I c-type cytochrome. The ferric and ferrous cytochrome forms and their pH equilibria have been studied using 1H-NMR, ultraviolet/visible, EPR and Mössbauer spectroscopies. The pH equilibria are complex, several pKa values and pH-dependent forms being observed. The amino acid sequence, the reduction-potential value and the visible and NMR spectroscopies data in the pH range 4-9 indicate that the heme iron has a methionine-histidine axial coordination. However, the EPR and Mössbauer data obtained for the ferricytochrome show that in this pH range two distinct forms are present: form I, gz = 3.27, gy = 2.05 and gx = 1.05; form II, gz = 2.95, gy = 2.29 and gx = 1.43. While form I has crystal-field parameters typical of a methionine-histidine coordination, those associated with form II would suggest a histidine-histidine axial ligation. This possibility was extensively analyzed by spectroscopic methods and by chemical modification of a histidine residue. It was concluded that form II actually corresponds to an unusual type of methionine-histidine axial coordination. Straightforward examples of this type of coordination have recently been found in other c-type hemeproteins [Teixeira, M., Campos, A. P., Aguiar, A. P., Costa, H. S., Santos, H., Turner, D. L. & Xavier, A. V. (1993) FEBS Lett. 317, 233-236], corroborating our proposal. Since both forms, with very distinct crystal-field parameters, are shown to have the same reduction potential, it may be concluded that the axial and rhombic distortions of the heme-iron ligand field cannot be directly correlated with the heme-reduction potential. The pH-dependence studies have also shown that the form I and form II are interconvertible, with pKa approximately 5. To establish a possible physiological significance for this process, in particular for the interaction of the cytochrome with the membrane-bound electron-transfer complexes b6f and photosystem I, the effect of surfactants on the spectroscopic characteristics of cytochrome c6 has been studied.

Hydrogen bonding of iron-coordinated histidine in heme proteins

The hydrogen-bonding motifs of the proton on the N delta atom of iron-coordinated histidine residues in heme proteins have been classified into three categories: (1) Those in which the hydrogen-bond acceptor is either an amino acid residue (serine) directly adjacent to the histidine or a carbonyl group of the polypeptide chain less than five residues away from the histidine; (2) those in which the hydrogen-bonding acceptor is a carbonyl group of the polypeptide backbone associated with an amino acid residue 8 to 17 residues away from the histidine; and (3) those in which the hydrogen-bonding acceptor is an exogenous water molecule or an amino acid residue located far from the histidine in the amino acid sequence. Some biological functions are defined by this classification, whereas others span all classes.

Regulation of a cytochrome c2 isoform in wild-type and cytochrome c2 mutant strains of Rhodobacter sphaeroides

In Rhodobacter sphaeroides, mutations that suppress the photosynthetic deficiency (spd mutations) of strains lacking cytochrome c2 (cyt c2) cause accumulation of a periplasmic cyt c2 isoform that has been designated isocytochrome c2 (isocyt c2). In this study, a new method for purification of both cyt c2 and isocyt c2 is described that uses periplasmic fluid as a starting material. In addition, antiserum to isocyt c2 has been used to demonstrate that all suppressor mutants contain an isocyt c2 of approximately 15 kDa. Western blot analysis indicates that isocyt c2 was present at lower levels in both wild-type and cyt c2 mutants than in spd-containing mutants. Although isocyt c2 is detectable under all growth conditions in wild-type cells, the highest level of isocyt c2 is present under aerobic conditions. Our results demonstrate that spd mutations increase the steady state level of isocyt c2 under photosynthetic conditions. Although the physiological function of isocyt c2 in wild-type cells is not known, we show that a nitrate-regulated protein in Rhodobacter sphaeroides f. sp. denitrificans also reacts with the isocyt c2 antiserum.

NMR study of the structural characteristics of variants of yeast iso-1-cytochrome c in which unvaried aromatic residues have been substituted

The structures of variants of yeast iso-1-cytochrome c, in which the previously unchanged Tyr48 and Tyr48 + Trp59 have been replaced by Phe, have been characterised by NMR. The NMR data indicated that the structures of the variant cytochromes c are very similar to the wild-type protein. In particular, the heme environment and interactions of the heme macrocycle were shown to be preserved. The observation of chemical shift differences have allowed for the assessment of conformational changes. The substitution of Trp59 by Phe may have caused a small conformational change, a manifestation of which is the observed chemical shift differences at His39, Val57 and Tyr74. The structural basis for the reduction in redox potential accompanying the amino acid substitutions is discussed and the proposal made that the changes in potential are a direct consequence of the side chain properties and do not result primarily from conformational changes.

Bacterial 4-alpha-helical bundle cytochromes

The biological functions of cytochrome c' and bacterioferritin, both haemoproteins with a common 4-alpha-helical bundle structure, are discussed and an example given of one of Kamen's laws, namely: comparative studies of prokaryotic cytochromes and their eukaryotic counterparts are useful. In the present case, the comparison is between bacterioferritin and its animal counterpart, haemoferritin.

Redox potentials of flavocytochromes c from the phototrophic bacteria, Chromatium vinosum and Chlorobium thiosulfatophilum

The redox potentials of flavocytochromes c (FC) from Chromatium vinosum and Chlorobium thiosulfatophilum have been studied as a function of pH. Chlorobium FC has a single heme which has a redox potential of +98 mV at pH 7 (N = 1) that is independent of pH between 6 and 8. The average two-electron redox potential of the flavin extrapolated to pH 7 is +28 mV and decreases 35 mV/pH between pH 6 and 7. The anionic form of the flavin semiquinone is stabilized above pH 6. The redox potential of Chromatium FC is markedly lower than for Chlorobium. The two hemes in Chromatium FC appear to have a redox potential of 15 mV at pH 7 (N = 1), although they reside in very different structural environments. The hemes of Chromatium FC have a pH-dependent redox potential, which can be fit in the simplest case by a single ionization with pK = 7.05. The flavin in Chromatium FC has an average two-electron redox potential of -26 mV at pH 7 and decreases 30 mV/pH between pH 6 and 8. As with Chlorobium, the anionic form of the flavin semiquinone of Chromatium FC is stabilized above pH 6. The unusually high redox potential of the flavin, a stabilized anion radical, and sulfite binding to the flavin in both Chlorobium and Chromatium FCs are characteristics shared by the flavoprotein oxidases. By analogy with glycolate oxidase and lactate dehydrogenase for which there are three-dimensional structures, the properties of the FCs are likely to be due to a positively charged amino acid side chain in the vicinity of the N1 nitrogen of the flavin.

A spectroscopic analysis of the Pro35----Ala mutant of Rhodobacter capsulatus cytochrome c2. The strictly conserved Pro35 is not structurally essential

Visible, near-ultraviolet circular dichroic, near-infrared and nuclear magnetic resonance spectroscopies show that the secondary and tertiary structures of the mutant Pro35----Ala Rhodobacter capsulatus ferrocytochrome c2 are similar to the wild-type protein. The near-infrared spectrum shows that the methionine-S--Fe-heme bond is intact; however, a small red shift in the heme M transition of the near-ultraviolet circular dichroic spectrum of the mutant indicates that the heme environment may differ slightly between the two proteins. This difference may be a consequence of changes in the ligand and hydrogen bonds of His17 [Gooley, P. R. & MacKenzie, N. E. (1990) FEBS Lett. 260, 225-228]. 1H and 15N chemical shift differences suggest that the microenvironment of pyrrole rings III and IV of the heme prosthetic group differs between the two proteins. As the rings of the Phe51 and Tyr53 flip faster in the mutant protein than the wild type, these chemical shift differences may reflect changes in the time-average ring-current effects and not structural alterations.

Reaction of cytochrome c2 with photosynthetic reaction centers from Rhodopseudomonas viridis

The reactions of Rhodopseudomonas viridis cytochrome c2 and horse cytochrome c with Rps. viridis photosynthetic reaction centers were studied by using both single- and double-flash excitation. Single-flash excitation of the reaction centers resulted in rapid photooxidation of cytochrome c-556 in the cytochrome subunit of the reaction center. The photooxidized cytochrome c-556 was subsequently reduced by electron transfer from ferrocytochrome c2 present in the solution. The rate constant for this reaction had a hyperbolic dependence on the concentration of cytochrome c2, consistent with the formation of a complex between cytochrome c2 and the reaction center. The dissociation constant of the complex was estimated to be 30 microM, and the rate of electron transfer within the 1:1 complex was 270 s-1. Double-flash experiments revealed that ferricytochrome c2 dissociated from the reaction center with a rate constant of greater than 100 s-1 and allowed another molecule of ferrocytochrome c2 to react. When both cytochrome c-556 and cytochrome c-559 were photooxidized with a double flash, the rate constant for reduction of both components was the same as that observed for cytochrome c-556 alone. The observed rate constant decreased by a factor of 14 as the ionic strength was increased from 5 mM to 1 M, indicating that electrostatic interactions contributed to binding. Molecular modeling studies revealed a possible cytochrome c2 binding site on the cytochrome subunit of the reaction center involving the negatively charged residues Glu-93, Glu-85, Glu-79, and Glu-67 which surround the heme crevice of cytochrome c-554.(ABSTRACT TRUNCATED AT 250 WORDS)

Changing the invariant proline-30 of rat and Drosophila melanogaster cytochromes c to alanine or valine destabilizes the heme crevice more than the overall conformation

Drosophila melanogaster and rat cytochromes c in which proline-30 was converted to alanine or valine were expressed in a strain of baker's yeast, Saccharomyces cerevisiae, where they sustained aerobic growth. The mutations had no significant effect on the spectra or redox potentials but altered drastically the stability of the bond between the methionine-80 sulfur and the heme iron, as judged by four criteria: (i) the alkaline pKa values of the 695-nm band of the ferric form of the mutant proteins decreased by almost 1 pH unit as compared to the wild types; (ii) the acid pKa values increased by 0.5 to 1.2 pH units; (iii) the 695-nm band half-disappeared at temperatures 10-20 degrees C lower in the mutant proteins than in the wild types; and (iv) the 695-nm band of the mutant proteins was susceptible to concentrations of urea that had little influence on their overall structure. The valine-substituted rat cytochrome c had properties intermediate between those of the wild type and the alanine mutant. The destabilized coordinative bond is located in space a long distance from the mutation site. It is suggested that the mutations weaken the hydrogen bond between the carbonyl of residue 30 and the imino group of the imidazole of histidine-18, modifying the bonding of the heme iron by that imidazole, which, in turn, through a trans effect, weakens the bond between the heme iron and the other axial ligand, the sulfur of methionine-80. Alternatively, the effect of the mutations may be propagated allosterically along the peptide chain.

Assignments of 15N and 1H NMR resonances and a neutral pH ionization in Rhodospirillum rubrum cytochrome c2

The phi NH proton and 15N resonances of the ligand histidine of Rhodospirillum rubrum fericytochrome c2 are found at 14.7 and 184 ppm, respectively, contradicting the proposal that this proton is absent in the R. rubrum ferricytochrome. Substitution of the deuterium atom for this proton causes small upfield shifts of the phi nitrogen in both oxidation states, indicating that the phi NH-peptide carboxyl hydrogen bond is not substantially weakened by the substitution. The proton and 15N resonances of the indolic NH group of the invariant tryptophan-62 and numerous proton resonances of the heme and extraheme ligands in the spectrum of the ferricytochrome are also assigned. An ionization in the ferrocytochrome occurring at neutral pH is assigned to the single nonligand histidine. This attribution is supported by the direct measurement of the ionization by NOE difference spectroscopy and by comparative structural arguments involving closely related cytochromes and chemically modified cytochromes.

Characterization of pH-dependent conformational heterogeneity in Rhodospirillum rubrum cytochrome c2 using 15N and 1H NMR

The 15N-enriched ferricytochrome c2 from Rhodospirillum rubrum has been studied by 15N and 1H NMR spectroscopy as a function of pH. The 15N resonances of the heme and ligand tau nitrogen are broadened beyond detection because of paramagnetic relaxation. The 15N resonance of the ligand histidine phi nitrogen was unambiguously identified at 184 ppm (pH 5.6). The 15N resonances of the single nonligand histidine are observed only at low pH, as in the ferrocytochrome because of the severe broadening caused by tautomerization. The dependence of the 15N and 1H spectra of the ferricytochrome on pH indicated that the ligand histidine tau NH does not dissociate in the neutral pH range and is involved in a hydrogen bond, similar to that in the reduced state. Because neither deprotonated nor non-hydrogen-bonded forms of the ligand histidine are observed in the spectra of either oxidation state, the participation of such forms in producing heterogeneous populations having different electronic g tensors is ruled out. Transitions having pKa's of 6.2, 8.6, and 9.2 are observed in the ferricytochrome. The localized conformational change around the omega loops is observed in the neutral pH range, as in the ferrocytochrome. Structural heterogeneity leads to multiple resonances of the heme ring methyl at position 8. The exchange rate between the conformations is temperature dependent. The transition with a pKa of 6.2 is assigned to the His-42 imidazole group. The displacement of the ligand methionine, which occurs with a pKa of 9.2, causes gross conformational change near the heme center.(ABSTRACT TRUNCATED AT 250 WORDS)

1H, 13C, and 15N resonance assignments for a ferrocytochrome c553 heme by multinuclear NMR spectroscopy

A novel strategy has been used to assign the 1H, 13C, and 15N resonances of the heme in Anabaena 7120 ferrocytochrome c553. 13C[13C] double-quantum coherence spectroscopy was used to delineate the heme carbons, 1H[13C] single-bond correlation spectroscopy was used to define the attached protons, and 1H[15N] multiple-bond correlation spectroscopy was used to assign the nitrogens. 1H[13C] multiple-bond correlation spectroscopy confirmed many of the assignments. Proteins were labeled uniformly with 13C or 15N to obtain the required spectral sensitivity.

Expression of a cytochrome c2 isozyme restores photosynthetic growth of Rhodobacter sphaeroides mutants lacking the wild-type cytochrome c2 gene

Deletion of the cytochrome c2 gene in the purple bacterium Rhodobacter sphaeroides renders it incapable of phototrophic growth (strain cycA65). However, suppressor mutants which restore the ability to grow phototrophically are obtained at relatively high frequency (1-10 in 10(7)). We examined two such suppressors (strains cycA65R5 and cycA65R7) and found the expected complement of electron transfer proteins minus cytochrome c2: SHP, c', c551.5, and c554. Instead of cytochrome c2 which elutes from DEAE-cellulose between SHP and cytochrome c', at about 50 mM ionic strength in wild-type extracts, we found a new high redox potential cytochrome c in the mutants which elutes with cytochrome c551.5 at about 150 mM ionic strength. The new cytochrome is more acidic than cytochrome c2, but is about the same size or slightly smaller (13,500 Da). The redox potential of the new cytochrome from strain cycA65R7 (294 mV) is about 70 mV lower than that of cytochrome c2. The 280 nm absorbance of the new cytochrome is smaller than that of cytochrome c2, which suggests that there is less tryptophan (the latter has two residues). In vitro kinetics of reduction by lumiflavin and FMN semiquinones show that the reactivity of the new cytochrome is similar to that of cytochrome c2, and that there is a relatively large positive charge (+2.6) at the site of reduction, despite the overall negative charge of the protein. This behavior is characteristic of cytochromes c2 and unlike the majority of bacterial cytochromes examined. Fourteen out of twenty-four of the N-terminal amino acids of the new cytochrome are identical to the sequence of cytochrome c2. The N-termini of the cycA65R5 and cycA65R7 cytochromes were the same. The kinetics and sequence data indicate that the new protein may be a cytochrome c2 isozyme, which is not detectable in wild-type cells under photosynthetic growth conditions. We propose the name iso-2 cytochrome c2 for the new cytochrome produced in the suppressor strains.

Fourier-transform infra-red studies of the alkaline isomerization of mitochondrial cytochrome c and the ionization of carboxylic acids

The alkaline transitions of tuna and horse ferricytochromes c and the trifluoroacetyl-lysine derivative of horse ferricytochrome c have been studied by Fourier-transform (FT) i.r. spectroscopy. The spectral perturbations resulting from the transition have been interpreted by reference to FT i.r. data on simple carboxylic-acid-containing compounds and a bacterial cytochrome c551 in which a haem propionate ionizes without causing a significant conformational change. The analysis strongly suggests that ionization of a haem propionate of mitochondrial cytochrome c triggers the alkaline conformation change.

Effects of buried ionizable amino acids on the reduction potential of recombinant myoglobin

The temperature dependences of the reduction potentials (E degrees') of wild-type human myoglobin (Mb) and three site-directed mutants have been measured by the use of thin-layer spectroelectrochemistry. Residue Val68, which is in van der Waals contact with the heme in Mb, has been replaced by Glu, Asp, and Asn. The changes in E degrees' and the standard entropy (delta S degrees') and enthalpy (delta H degrees') of reduction in the mutant proteins were determined relative to values for wild type; the change in E degrees' at 25 degrees C was about -200 millivolts for the Glu and Asp mutants, and about -80 millivolts for the Asn mutant. At pH 7.0, reduction of Fe(III) to Fe(II) in the Glu and Asp mutants is accompanied by uptake of a proton by the protein. These studies demonstrate that Mb can tolerate substitution of a buried hydrophobic group by potentially charged and polar residues and that such amino acid replacements can lead to substantial changes in the redox thermodynamics of the protein.

pH-induced changes in Rhodospirillum rubrum cytochrome c2 and subsequent renaturation: an 15N NMR study

The 15N-enriched ferrocytochrome c2 from Rhodospirillum rubrum was studied by 15N NMR at different solvent pH values. The mobility and chemical shift of the N-terminal glutamic acid (335.4 ppm at pH 5.1) were found to depend on pH. It was least mobile between pH 8 and 9.0, which is explained in terms of pH-dependent conformational changes and formation of salt linkages and/or hydrogen bonds. The resonances of the lysine side chains are centered around 341.7 ppm at low pH and move upfield with pH by about 8.4 ppm with pKa values of 10.8. The exchange rates of the epsilon NH protons are lowest near their pKa values. The protein is very stable in the pH range between 4.9 and 10.0 but unfolds abruptly at pH 10.5-11. Denaturation was verified by the measurement of several parameters by NMR. The renaturation of the protein demonstrates that the folding begins with reformation of heme coordination and establishment of a hydrophobic core, followed by positioning of side chains and peptide backbones linking the nucleation centers. The repositioning processes had time scales of minutes to hours in contrast to the reported values of seconds in some studies.

15N and 1H NMR studies of Rhodospirillum rubrum cytochrome c2

15N-Enriched cytochrome c2 was purified from Rhodospirillum rubrum that had been grown on 15NH4Cl, and the diamagnetic iron(II) form of the cytochrome was studied by 15N and 1H NMR spectroscopy. 15N resonances of the four pyrrole nitrogens, the ligand histidine nitrogens, the highly conserved tryptophan indole nitrogen, and some proline nitrogens are assigned. The resonances of the single nonligand histidine are observed only at low pH because of severe broadening produced by proton tautomerization. The resonances of exchangeable protons bonded to the nitrogens of the ligand histidine, the tryptophan, and some amide groups are also assigned. The exchange rates of the nitrogen-bound protons vary greatly: most have half-lives of less than minutes, the indolic NH of Trp-62 exchanges with a half-time of weeks, and the ligand histidine NH proton exchanges with a half-time of months. The latter observation is indicative of extreme exclusion of solvent from the area surrounding the ligand histidine and lends credence to theories implicating the degree of hydrophobicity in this region as an important factor in adjusting the midpoint potential. The dependence of the 15N and 1H NMR spectra of ferrocytochrome c2 on pH indicates neither the Trp-62 nor the ligand His side chains become deprotonated to any appreciable extent below pH 9.5. The His-18 NH remains hydrogen bonded, presumably to the Pro-19 carboxyl group, throughout the pH titrations. Because neither deprotonated nor non-hydrogen-bonded forms of His-18 are observed in spectra of the ferrocytochrome, the participation of such forms in producing a heterogeneous population having different g tensor values seems unlikely.(ABSTRACT TRUNCATED AT 250 WORDS)

Alkylamine derivatives of cytochrome c. Comparison with other lysine-modified analogues illuminates structure/function relations in the protein

For investigations of the functional roles of the lysine residues of cytochrome c, analogues in which these residues are modified without charge loss are highly desirable. The 19 lysine residues of the horse heart protein have been modified by reductive alkylation. Two analogues were prepared, using formaldehyde and acetone as the dialkylating and monoalkylating reagent respectively. Modification was shown to be clean and quantitative. Characterisation of the alkylamine derivatives by physicochemical measurements and biological activity determinations was carried out. The potential of these analogues in structure/function studies of cytochrome c is discussed. It is illustrated by their use, in conjunction with other lysine-modified derivatives, to investigate the extent to which surface charge determines redox potential, and to study the physicochemical changes that accompany rising pH. In the latter case the observed phenomena are not as closely correlated as previously thought, suggesting that there is a complex set of rearrangements of structure underlying the functional changes. The data confirm that modification of the lysine residues influences these changes. These residues participate in numerous surface intramolecular links, so the lack of correlation may be explained if each of the changing parameters were under the influence of a different set of residues. However, neither a lysine residue, nor a histidine residue directly displaces methionine from the sixth coordination position of the haem iron at alkaline pH.

Factors influencing redox potentials of electron transfer proteins

The redox potentials of electron transfer proteins vary over a wide range, even when the type of redox center is the same. Rees [Proc. Natl. Acad. Sci. USA (1985) 82, 3082-3085] proposed that this variation of redox potential partly reflects the different net charges of the proteins, and he presented a linear correlation between these two properties for 36 proteins. A review of the factors that influence protein redox potentials makes it clear that this linear correlation is fortuitous. The key factors influencing redox potentials are the contributions to the Gibbs energy difference between the two redox states, resulting from bonding interactions at the redox center, electrostatic interactions between the redox-center charge and polar groups within the protein and solvent, and redox-state conformational changes. The relative importance of these terms is likely to vary from protein to protein.

Soluble cytochrome composition of the purple phototrophic bacterium, Rhodopseudomonas sphaeroides ATCC 17023

A detailed study of the soluble cytochrome composition of Rhodopseudomonas sphaeroides (ATCC 17023) indicates that there are five c-type cytochromes and one b-type cytochrome present. The molecular weights, heme contents, amino acid compositions, isoelectric points, and oxidation-reduction potentials were determined and the proteins were compared with those from other bacterial sources. Cytochromes c2 and c' have previously been well characterized. Cytochrome c-551.5 is a diheme protein which has a very low redox potential, similar to certain purple bacterial and algal cytochromes. Cytochrome c-554 is an oligomer, which is spectrally similar to the low-spin isozyme of cytochrome c' found in other purple bacteria (e.g., Rhodopseudomonas palustris cytochrome c-556). An unusual high-spin c-type heme protein has also been isolated. It is spectrally distinguishable from cytochrome c' and binds a variety of heme ligands including oxygen. A large molecular-weight cytochrome b-558 is also present which appears related to a similar protein from Rhodospirillum rubrum, and the bacterioferritin from Escherichia coli. None of the soluble proteins appear to be related to the abundant membrane-bound c-type cytochrome in Rps. sphaeroides which has a larger subunit molecular weight similar to mitochondrial cytochrome c1 and chloroplast cytochrome f.

A spectroscopic investigation of the structure and redox properties of Escherichia coli cytochrome b-562

The six-coordinate monohaem ferricytochrome b-562 from Escherichia coli exhibits two haem-linked pH-dependent transitions detected by NMR and optical spectroscopy. Only one of these transitions, that of the Fe(III)-coordinated His-102, is detected by EPR and MCD; the ionisation of a haem propionate is not. Both ionisations are redox-state-dependent and the midpoint redox potential of the protein is markedly pH-dependent. Over the pH range 5.0 to 8.5 the potential drops from 260 mV to 110 mV and at least five single proton ionisations are responsible for this. In addition to the two spectroscopically identified ferricytochrome ionisations, there are at least three unidentified ionisations, two of which occur in the ferrous protein. From a consideration of the X-ray structure, together with NMR data, it seems probable that at least one of these ionisations involves an amino acid carboxylate. The X-ray structure also suggests that the relatively low pKa of His-102 is a result of its proximity to Arg-98. However, an appreciable interaction between these groups requires that the solution conformation differs slightly from the X-ray structure. The fast rate of electron self-exchange, over 4 X 10(6) M-1 X s-1 at 315 K and pH* 7, may be a reflection of the fact that, as shown by the X-ray structure, a large amount of the haem and axial histidine ligand are exposed at the molecular surface with an asymmetric distribution of charged groups surrounding them.

Amino acid sequence, haem-iron co-ordination geometry and functional properties of mitochondrial and bacterial c-type cytochromes

Cytochromes are found in all biological oxidation Systems which involve transport of reducing equivalents through organized chains of membrane bound intermediates, regardless of the ultimate oxidant (Keilin, 1966; Bartsch, 1978; Meyer & Kamen, 1982). Thus, cytochromes are present not only in the aerobic mitochondrial and bac-terial respiratory chain, but are also found in much more diversified procariotic Systems, including all varieties of facultative anaerobes (nitrate and nitrite reducers), obligate anaerobes (sulphate reducers and phototrophic sulphur bacteria), facultative photoheterotrophes (phototrophic non-sulphur purple bacteria), and the photoautotrophic cyanobacteria (blue-green algae). Among the different types of cytochromes occurring in the cell, the soluble c-type cytochromes (‘class I’, Meyer & Kamen, 1982) are the most abundant and best characterized group of proteins (Bartsch, 1978; Meyer & Kamen, 1982; Dickerson & Timkovitch, 1975; Lemberg & Barrett, 1973; Salemme, 1977; Ferguson-Miller, Brautigan & Margoliash, 1979). The amino acid sequences of more than 80 mitochrondrial and close to 40 bacterial cytochromes c are known (Meyer & Kamen, 1982; Dickerson & Timkovitch, 1975; Schwartz & Dayhoff, 1976; Dayhoff & Barker, 1978).

The influence of electrostatic interactions between buried charges on the properties of membrane proteins

The importance of electrostatic interactions between buried charges in determining the properties of membrane proteins is considered. It is demonstrated that in some cases altered properties may result from the extraction of a membrane protein into an aqueous medium even when the protein conformation is unperturbed.

Isolation and characterization of soluble cytochromes, ferredoxins and other chromophoric proteins from the halophilic phototrophic bacterium Ectothiorhodospira halophila

A cytochrome c-551 and a pair of 'high redox-potential' ferredoxins (iso-high-potential iron-sulfur proteins) were found to be the major soluble electron-transport proteins in Ectothiorhodospira halophila. Smaller amounts of 'bacterial' ferredoxin and cytochrome c' were also observed. With the exception of cytochrome c-551, these proteins are commonly encountered in the purple sulfur bacteria, family Chromatiaceae and less frequently in the purple bacteria, family Rhodospirillaceae. In addition to the cytochromes and ferredoxins, E. halophila synthesizes substantial amounts of a small yellow-colored protein, which has a chromophore spectrally similar to flavins having oxygen, nitrogen or sulfur substituents in place of the 8-methyl group such as roseoflavin and the methanogen cofactor F-420. A purple-colored protein was only partially purified, but it is spectrally similar to iron proteins having a tyrosine ligand, such as transferrin, catechuate dioxygenase, and especially the purple acid phosphatases. Neither the yellow protein nor the purple one has previously been observed in phototrophic bacteria, but may in some way be required for survival in extremely halophilic habitats. The only feature common to halophiles including E. halophila is the very acidic nature of their proteins.

The effect of iron-hexacyanide binding on the determination of redox potentials of cytochromes and copper proteins

The midpoint redox potentials of Pseudomonas aeruginosa cytochrome c-551 and Rhodopseudomonas viridis cytochrome c2 were measured as a function of pH in the presence of Euglena cytochrome c-558 and the results compared with those obtained in the presence of ferro-ferricyanide. The pattern of pH dependence observed for the two bacterial cytochromes was the same whether it was measured by equilibrium with another redox protein or with the inorganic redox couple. Thus, the pH dependence of redox potential is not a consequence of pH-dependent ligand binding. The midpoint potential of Ps. aeruginosa azurin was measured as a function of pH using both ferro-ferricyanide mixtures and redox equilibrium with horse cytochrome c or Rhodopseudomonas capsulata cytochrome c2. In this case also the pattern of pH dependence obtained did not vary with the redox system used and it closely resembled that of Ps. aeruginosa cytochrome c-551. This is consistent with the observation that the equilibrium between cytochrome c-551 and azurin is relatively independent of pH. An equation was derived which described ph-dependent ligand binding and which can produce theoretical curves to fit the experimental pH dependence of redox potential for both cytochrome and azurin. However, the pronounced effect on such curves produced by varying the ligand association constants, and the insensitivity of the experimental data to changes in ionic strength, suggest that ligand binding effects do not account for the pH dependence of redox potential.

Three c-type cytochromes from the red alga Porphyridium cruentum

Three c-type cytochromes were isolated from the red alga, Porphyridium cruentum, and partially characterized. The cytochrome c553 was an extrinsic membrane protein which was easily released to the aqueous phase with a yield of 10 to 15 mg pure protein/100 g cells. The properties of this cytochrome were similar to other algal and cyanobacterial cytochromes which function as Photosystem I electron donors. Absorption maxima in reduced cytochrome c553 were at 552.8, 521.8, and 415.6 nm. The molecular mass was 10 kDa, the redox potential was +340m V, and the pI was 4.3. The near-infrared absorption band of ferricytochrome was found to titrate with a single pK of 9.5. In addition to the loss of the near-infrared band at alkaline pH, other spectral changes were noted in the ferrocytochrome. The most obvious change was that of the alpha-band shifting to 550 nm in the dithionite-reduced cytochrome at alkaline pH. Small quantities of a cytochrome c550 were detected in some preparations of P. cruentum. This cytochrome had absorption maxima in the reduced form at 550, 522, and 416 nm. The pI was 4.1. This cytochrome was isolated in the oxidized form and was not ascorbate-reducible. The third c-type cytochrome isolated from P. cruentum was an intrinsic membrane protein analogous to higher plant cytochrome f. The absorption maxima in the reduced cytochrome were at 553.8, 522.5, and 421.0 nm. Cytochrome f was always isolated in the reduced form with a yield of 1 to 1.5 mg/100 g of algal membranes. The cytochrome f was unstable at 4 or -20 degrees C. The molecular mass was 26 kDa, and the pI was 6.5. Photosynthetically active vesicles from P. cruentum were prepared and exogenous cytochrome c553 stimulated Photosystem I-dependent activity but not reactions dependent on both photosystems. Antibody to cytochrome c553 had no effect on photochemical activity.