Mutagenesis of methionine-183 drastically affects the physicochemical properties of cytochrome c1 of the bc1 complex of Rhodobacter capsulatus.

Site-directed mutagenesis was used to investigate which of the highly conserved methionine residues (M183 and M205) provides the sixth axial ligand to the heme Fe in the cyt c1 subunit of the bc1 complex from the bacterium Rhodobacter capsulatus. These residues were changed to leucine (cM183L) and valine (cM205V). Two additional mutants were constructed, 1 in which a stop codon was inserted at M205 (cM205*) and the second in which 127 amino acids were deleted between the signal sequence and the putative C-terminal transmembrane alpha-helix (c delta SfuI). Only cM205V grew photosynthetically, and membranes isolated from this strain catalyzed quinol-dependent reduction of cyt c in amounts similar to that in a wild-type strain. Even though cM183L could not grow photosynthetically, it contained all the appropriate polypeptides and cofactors of the bc1 complex, as shown by SDS-PAGE and optical difference spectroscopy of intact membrane particles. Neither of the two deletion mutants contained a stable complex. Flash absorption spectroscopy using chromatophores showed no cytochrome c rereduction after oxidation by the reaction center in cM183L. The bc1 complex from each strain was isolated and characterized. Oxidation reduction midpoint potential titrations revealed that cyt c1 from cM183L had a dramatically shifted Em value (delta Em = -390 mV) compared with wild type and cM205V. While the optical absorption spectrum of cyt c1 from cM183L suggested that the c-type heme was low-spin, nonetheless it was able to react with the exogenous ligand carbon monoxide. The overall data support that M183, and not M205, is the sixth ligand to the heme Fe of cyt c1 of the bc1 complex.     

Spectroscopic and oxidation-reduction properties of Rhodobacter capsulatus cytochrome c1 and its M183K and M183H variants

Two variants of the cytochrome c1 component of the Rhodobacter capsulatus cytochrome bc1 complex, in which Met183 (an axial heme ligand) was replaced by lysine (M183K) or histidine (M183H), have been analyzed. Electron paramagnetic resonance (EPR) and magnetic circular dichroism (MCD) spectra of the intact complex indicate that the histidine/methionine heme ligation of the wild-type cytochrome is replaced by histidine/lysine ligation in M183K and histidine/histidine ligation in M183H. Variable amounts of histidine/histidine axial heme ligation were also detected in purified wild-type cytochrome c1 and its M183K variant, suggesting that a histidine outside the CSACH heme-binding domain can be recruited as an alternative ligand. Oxidation-reduction titrations of the heme in purified cytochrome c1 revealed multiple redox forms. Titrations of the purified cytochrome carried out in the oxidative or reductive direction differ. In contrast, titrations of cytochrome c1 in the intact bc1 complex and in a subcomplex missing the Rieske iron-sulfur protein were fully reversible. An Em7 value of -330 mV was measured for the single disulfide bond in cytochrome c1. The origins of heme redox heterogeneity, and of the differences between reductive and oxidative heme titrations, are discussed in terms of conformational changes and the role of the disulfide in maintaining the native structure of cytochrome c1.     

Resilience of Rhodobacter sphaeroides cytochrome bc1 to heme c1 ligation changes

Typically, c hemes are bound to the protein through two thioether bonds to cysteines and two axial ligands to the heme iron. In high-potential class I c-type cytochromes, these axial ligands are commonly His-Met. A change in this methionine axial ligand is often correlated with a dramatic drop in the heme redox potential and loss of function. Here we describe a bacterial cytochrome c with an unusual tolerance to the alternations in the heme ligation pattern. Substitution of the heme ligating methionine (M185) in cytochrome c1 of the Rhodobacter sphaeroides cytochrome bc1 complex with Lys and Leu lowers the redox midpoint potential but not enough to prevent physiologically competent electron transfer in these fully functional variants. Only when Met-185 is replaced with His is the drop in the redox potential sufficiently large to cause cytochrome bc1 electron transfer chain failure. Functional mutants preserve the structural integrity of the heme crevice: only the nonfunctional His variant allows carbon monoxide to bind to reduced heme, indicating a significant opening of the heme environment. This range of cytochrome c1 ligand mutants exposes both the relative resilience to sixth axial ligand change and the ultimate thermodynamic limits of operation of the cofactor chains in cytochrome bc1.     

Strategic roles of axial histidines in structure formation and redox regulation of tetraheme cytochrome c3

Tetraheme cytochrome c 3 (cyt c 3) exhibits extremely low reduction potentials and unique properties. Since axial ligands should be the most important factors for this protein, every axial histidine of Desulfovibrio vulgaris Miyazaki F cyt c 3 was replaced with methionine, one by one. On mutation at the fifth ligand, the relevant heme could not be linked to the polypeptide, revealing the essential role of the fifth histidine in heme linking. The fifth histidine is the key residue in the structure formation and redox regulation of a c-type cytochrome. A crystal structure has been obtained for only H25M cyt c 3. The overall structure was not affected by the mutation except for the sixth methionine coordination at heme 3. NMR spectra revealed that each mutated methionine is coordinated to the sixth site of the relevant heme in the reduced state, while ligand conversion takes place at hemes 1 and 4 during oxidation at pH 7. The replacement of the sixth ligand with methionine caused an increase in the reduction potential of the mutated heme of 222-244 mV. The midpoint potential of a triheme H52M cyt c 3 is higher than that of the wild type by approximately 50 mV, suggesting a contribution of the tetraheme architecture to the lowering of the reduction potentials. The hydrogen bonding of Thr24 with an axial ligand induces a decrease in reduction potential of approximately 50 mV. In conclusion, the bis-histidine coordination is strategically essential for the structure formation and the extremely low reduction potential of cyt c 3.     

Cytochromes c555 from the hyperthermophilic bacterium Aquifex aeolicus. 2. Heterologous production of soluble cytochrome c555s and investigation of the role of methionine residues.

The cycB2 gene encoding the soluble cytochrome c555s from Aquifex aeolicus, an hyperthermophilic organism, has been cloned and expressed using Escherichia coli as the host organism. The cytochrome was successfully produced in the periplasm of an E. coli strain coexpressing the ccmABCDEFGH genes involved in the cytochrome c maturation process. Comparison of native and recombinant cytochrome c555s shows that both proteins are indistinguishable in terms of spectroscopic and physicochemical properties. Since two different methionine residues are present in the sequence stretch usually providing the sixth ligand to the heme iron, site-directed mutagenesis has been performed in order to identify the methionine serving as the axial ligand. Two single mutations were introduced, leading to the replacement of each methionine by a histidine residue. Characterization of both mutants, M78H and M84H cytochromes c555s, using biochemical and biophysical techniques has been carried out. The M84H mutant exhibits spectral features identical to those of native cytochrome. Its redox midpoint potential is decreased by 40 mV. By contrast, substitution of methionine 78 by a histidine residue strongly alters the structural and physicochemical properties of the molecule which exhibits characteristics of His/His iron coordination type rather than His/Met. These results allow us to identify methionine 78 as the sixth ligand of cytochrome c555s heme iron. Preliminary results on the thermostability of the native and mutant cytochromes c555 are also reported.     

ATR-FTIR spectroscopy studies of iron-sulfur protein and cytochrome c1 in the Rhodobacter capsulatus cytochrome bc1 complex

Redox transitions in the Rhodobacter capsulatus cytochrome bc(1) complex were investigated by perfusion-induced attenuated total reflection-Fourier transform infrared (ATR-FTIR) spectroscopy combined with synchronous visible spectroscopy, in both the wild type and a cytochrome c(1) point mutant, M183K, in which the midpoint potential of heme was lowered from the wild-type value of 320 mV to 60 mV. Overall redox difference spectra of the wild type and M183K mutant were essentially identical, indicating that the mutation did not cause any major structural perturbation. Spectra were compared with data on the bovine bc(1) complex, and tentative assignments of several bands could be made by comparison with available data on model compounds and crystallographic structures. The bacterial spectra showed contributions from ubiquinone that were much larger than in the bovine enzyme, arising from additional bound and adventitious ubiquinone. The M183K mutant enabled selective reduction of the iron-sulfur protein which in turn allowed the IR redox difference spectra of ISP and cytochrome c(1) to be deconvoluted at high signal/noise ratios, and features of these spectra are interpreted in light of structural and mechanistic information.     

Q-Band resonance Raman investigation of turnip cytochrome f and Rhodobacter capsulatus cytochrome c1

The results of a comprehensive Q-band resonance Raman investigation of cytochrome c1 and cytochrome f subunits of bc1 and b6f complexes are presented. Q-band excitation provides a particularly effective probe of the local heme environments of these species. The effects of protein conformation (particularly axial ligation) on heme structure and function were further investigated by comparison of spectra obtained from native subunits to those of a site directed c1 mutant (M183L) and various pH-dependent species of horse heart cytochrome c. In general, all species examined displayed variability in their axial amino acid ligation that suggests a good deal of flexibility in their hemepocket conformations. Surprisingly, the large scale protein rearrangements that accompany axial ligand replacement have little or no effect on macrocycle geometry in these species. This indicates the identity and/or conformation of the peptide linkage between the two cysteines that are covalently linked to the heme periphery may determine heme geometry.     

Role of acidic and aromatic amino acids in Rhodobacter capsulatus cytochrome c1. A site-directed mutagenesis study

The roles of two evolutionarily conserved aromatic residues in the cytochrome c(1) component of the Rhodobacter capsulatus cytochrome bc(1) complex, phenylalanine 138 and tyrosine 194, were analyzed by site-directed mutagenesis, in combination with biophysical and biochemical measurements. Changing Phe138 to either alanine or valine, but not to tyrosine, results in redox heterogeneity of cytochrome c(1). Replacement of Phe138 by an aliphatic amino acid also caused changes in the EPR spectrum of the cytochrome and resulted in decreases in the steady-state V(max) for the hydroquinone/cytochrome c oxidoreductase activity of cytochrome bc(1) complexes containing the mutated cytochrome c(1). These findings indicate that the presence of an aromatic residue at position 138 is essential for maintaining the native environment of the cytochrome c(1) heme. In contrast, replacement of Tyr194 by aliphatic amino acids had no significant effect on either the E(m) of cytochrome c(1) or the steady-state activity parameters. Site-directed mutagenesis of glutamate and aspartate residues in a conserved acidic patch (region 2) on Rb. capsulatus cytochrome c(1) suggests that these negatively charged residues do not play a role in the docking of cytochrome c(2) with the cytochrome bc(1) complex.     

The cytochrome bc1 complex of Rhodobacter sphaeroides can restore cytochrome c2-independent photosynthetic growth to a Rhodobacter capsulatus mutant lacking cytochrome bc1.

Plasmids encoding the structural genes for the Rhodobacter capsulatus and Rhodobacter sphaeroides cytochrome (cyt) bc1 complexes were introduced into strains of R. capsulatus lacking the cyt bc1 complex, with and without cyt c2. The R. capsulatus merodiploids contained higher than wild-type levels of cyt bc1 complex, as evidenced by immunological and spectroscopic analyses. On the other hand, the R. sphaeroides-R. capsulatus hybrid merodiploids produced only barely detectable amounts of R. sphaeroides cyt bc1 complex in R. capsulatus. Nonetheless, when they contained cyt c2, they were capable of photosynthetic growth, as judged by the sensitivity of this growth to specific inhibitors of the photochemical reaction center and the cyt bc1 complex, such as atrazine, myxothiazol, and stigmatellin. Interestingly, in the absence of cyt c2, although the R. sphaeroides cyt bc1 complex was able to support the photosynthetic growth of a cyt bc1-less mutant of R. capsulatus in rich medium, it was unable to do so when C4 dicarboxylic acids, such as malate and succinate, were used as the sole carbon source. Even this conditional ability of R. sphaeroides cyt bc1 complex to replace that of R. capsulatus for photosynthetic growth suggests that in the latter species the cyt c2-independent rereduction of the reaction center is not due to a structural property unique to the R. capsulatus cyt bc1 complex. Similarly, the inability of R. sphaeroides to exhibit a similar pathway is not due to some inherent property of its cyt bc1 complex.     

Replacement of putative axial ligands of heme iron in yeast cytochrome c1 by site-directed mutagenesis

The His-44 and Met-164 residues of yeast cytochrome c1 are evolutionally conserved and regarded as heme axial ligands bonding to the fifth and sixth coordination sites of the heme iron, which is directly involved in the electron transfer mechanism. Oligonucleotide-directed mutagenesis was used to generate mutant forms of cytochrome c1 of yeast having amino acid replacements of the putative axial ligands of the heme iron. When a cytochrome c1-deficiency yeast strain was transformed with a gene encoding the Phe-44, Tyr-44, Leu-164, or Lys-164 protein, none of these transformants could grow on the non-fermentable carbon source. These results suggest that the His-44 and Met-164 residues have a critical role in the function of cytochrome c1 in vivo, most probably as axial ligands of the heme iron. Further analysis revealed that the mutant yeast cells with the Phe-44, Tyr-44, or Leu-164 protein lacked the characteristic difference spectroscopic signal of cytochrome c1. However, in the Lys-164 mutant cells, partial recovery of the cytochrome c1 signal was observed. Moreover, the Lys-164 protein retained a low but significant level of succinate-cytochrome c reductase activity in vitro. The possibility that the nitrogen of Lys-164 served as the sixth heme ligand is discussed in comparison with cytochrome f of a photosynthetic electron-transfer complex, in which lysine has been proposed to be the sixth ligand.     

Mobile cytochrome c2 and membrane-anchored cytochrome cy are both efficient electron donors to the cbb3- and aa3-type cytochrome c oxidases during respiratory growth of Rhodobacter sphaeroides

We have recently established that the facultative phototrophic bacterium Rhodobacter sphaeroides, like the closely related Rhodobacter capsulatus species, contains both the previously characterized mobile electron carrier cytochrome c2 (cyt c2) and the more recently discovered membrane-anchored cyt cy. However, R. sphaeroides cyt cy, unlike that of R. capsulatus, is unable to function as an efficient electron carrier between the photochemical reaction center and the cyt bc1 complex during photosynthetic growth. Nonetheless, R. sphaeroides cyt cy can act at least in R. capsulatus as an electron carrier between the cyt bc1 complex and the cbb3-type cyt c oxidase (cbb3-Cox) to support respiratory growth. Since R. sphaeroides harbors both a cbb3-Cox and an aa3-type cyt c oxidase (aa3-Cox), we examined whether R. sphaeroides cyt cy can act as an electron carrier to either or both of these respiratory terminal oxidases. R. sphaeroides mutants which lacked either cyt c2 or cyt cy and either the aa3-Cox or the cbb3-Cox were obtained. These double mutants contained linear respiratory electron transport pathways between the cyt bc1 complex and the cyt c oxidases. They were characterized with respect to growth phenotypes, contents of a-, b-, and c-type cytochromes, cyt c oxidase activities, and kinetics of electron transfer mediated by cyt c2 or cyt cy. The findings demonstrated that both cyt c2 and cyt cy are able to carry electrons efficiently from the cyt bc1 complex to either the cbb3-Cox or the aa3-Cox. Thus, no dedicated electron carrier for either of the cyt c oxidases is present in R. sphaeroides. However, under semiaerobic growth conditions, a larger portion of the electron flow out of the cyt bc1 complex appears to be mediated via the cyt c2-to-cbb3-Cox and cyt cy-to-cbb3-Cox subbranches. The presence of multiple electron carriers and cyt c oxidases with different properties that can operate concurrently reveals that the respiratory electron transport pathways of R. sphaeroides are more complex than those of R. capsulatus.     

Membrane-associated cytochrome cy of Rhodobacter capsulatus is an electron carrier from the cytochrome bc1 complex to the cytochrome c oxidase during respiration.

We have recently established that the facultative phototrophic bacterium Rhodobacter capsulatus has two different pathways for reduction of the photooxidized reaction center during photosynthesis (F.E. Jenney and F. Daldal, EMBO J. 12:1283-1292, 1993; F.E. Jenney, R.C. Prince, and F. Daldal, Biochemistry 33:2496-2502, 1994). One pathway is via the well-characterized, water-soluble cytochrome c2 (cyt c2), and the other is via a novel membrane-associated c-type cytochrome named cyt cy. In this work, we probed the role of cyt cy in respiratory electron transport by isolating a set of R. capsulatus mutants lacking either cyt c2 or cyt cy, in the presence or in the absence of a functional quinol oxidase-dependent alternate respiratory pathway. The growth and inhibitor sensitivity patterns of these mutants, their respiratory rates in the presence of specific inhibitors, and the oxidation-reduction kinetics of c-type cytochromes monitored under appropriate conditions demonstrated that cyt cy, like cyt c2, connects the bc1 complex and the cyt c oxidase during respiratory electron transport. Whether cyt c2 and cyt cy are the only electron carriers between these two energy-transducing membrane complexes of R. capsulatus is unknown.     

Heme attachment motif mobility tunes cytochrome c redox potential

Hydrogen exchange (HX) rates and midpoint potentials (Em) of variants of cytochrome c from Pseudomonas aeruginosa (Pa cyt c551) and Hydrogenobacter thermophilus (Ht cyt c552) have been characterized in an effort to develop an understanding of the impact of properties of the Cys-X-X-Cys-His pentapeptide c-heme attachment (CXXCH) motif on heme redox potential. Despite structural conservation of the CXXCH motif, Ht cyt c552 exhibits a low level of protection from HX for amide protons within this motif relative to Pa cyt c551. Site-directed mutants have been prepared to determine the structural basis for and functional implications of these variations on HX behavior. The double mutant Ht-M13V/K22M displays suppressed HX within the CXXCH motif as well as a decreased Em (by 81 mV), whereas the corresponding double mutant of Pa cyt c551 (V13M/M22K) exhibits enhanced HX within the CXXCH pentapeptide and a modest increase in Em (by 30 mV). The changes in Em correlate with changes in axial His chemical shifts in the ferric proteins reflecting the extent of histidinate character. Thus, the mobility of the CXXCH pentapeptide is found to impact the His-Fe(III) interaction and therefore the heme redox potential.     

Site-directed mutagenesis of tetraheme cytochrome c3. Modification of oxidoreduction potentials after heme axial ligand replacement.

The nature of the axial ligands of a heme group is an important factor in maintaining the oxidation-reduction potential of a c-type cytochrome. Cytochrome c3 from Desulfovibrio vulgaris Hildenborough contains four bis-histidinyl coordinated hemes with low oxidation-reduction potentials. Site-directed mutagenesis was used to generate a mutant in which histidine 70, the sixth axial ligand of heme 4, has been replaced by a methionine. The mutant protein was expressed in Desulfovibrio desulfuricans G200 at a level similar to the wild type cytochrome. A model for the three-dimensional structure of D. vulgaris Hildenborough cytochrome c3 was generated on the basis of the crystal structure of D. vulgaris Miyazaki cytochrome c3 in order to investigate the effects of the H70M mutation. The model, together with NMR data, suggested that methionine 70 has effectively replaced histidine 70 as the sixth axial ligand of heme 4 without significant alteration of the structure. A large increase of at least 200 mV of one of the four oxidation-reduction potentials was observed by electrochemistry and is interpreted in terms of structure/potential relationships.     

The disulfide bridge in the head domain of rhodobacter sphaeroides cytochrome c1 is needed to maintain its structural integrity

Cytochrome c(1) of Rhodobacter sphaeroides ubiquinol-cytochrome c oxidoreductase contains several insertions and deletions that distinguish it from the complex of other higher organisms. Additionally, this bacterial cytochrome c(1) contains two nonconserved cysteines, C145 and C169, with the latter included in the second long insertion located upstream of the sixth heme ligand, M185. The orientation of the insertions and the state of these non-heme binding cysteines remain unknown. Mutating one or both cysteines is found to have comparable effects on the functionality of the cytochrome bc(1) complex. Mutants show an electron transfer activity decreased to a rate that is still high enough to support delayed photosynthetic growth. The mutated cytochrome c(1) has a decreased E(m) without any alteration in the heme ligation environment since none of the mutants binds carbon monoxide. The low E(m) is believed to be caused by a structural modification in the head domain of cytochrome c(1). Analysis of the mutants reveals that the two cysteines form a disulfide bridge. Cleavage of cytochrome c(1) between the two cysteines followed by gel electrophoresis shows two fragments only under reducing conditions, confirming the existence of a disulfide bridge. The disulfide bridge is essential in maintaining the structural integrity of cytochrome c(1) and thus the functionality of the cytochrome bc(1) complex.     

Tyrosine triad at the interface between the Rieske iron-sulfur protein, cytochrome c(1) and cytochrome c(2) in the bc(1) complex of Rhodobacter capsulatus

A triad of tyrosine residues (Y152-154) in the cytochrome c(1) subunit (C1) of the Rhodobacter capsulatus cytochrome bc(1) complex (BC1) is ideally positioned to interact with cytochrome c(2) (C2). Mutational analysis of these three tyrosines showed that, of the three, Y154 is the most important, since its mutation to alanine resulted in significantly reduced levels, destabilization, and inactivation of BC1. A second-site revertant of this mutant that regained photosynthetic capacity was found to have acquired two further mutations-A181T and A200V. The Y152Q mutation did not change the spectral or electrochemical properties of C1, and showed wild-type enzymatic C2 reduction rates, indicating that this mutation did not introduce major structural changes in C1 nor affect overall activity. Mutations Y153Q and Y153A, on the other hand, clearly affect the redox properties of C1 (e.g. by lowering the midpoint potential as much as 117mV in Y153Q) and the activity by 90% and 50%, respectively. A more conservative Y153F mutant on the other hand, behaves similarly to wild-type. This underscores the importance of an aromatic residue at position Y153, presumably to maintain close packing with P184, which modeling indicates is likely to stabilize the sixth heme ligand conformation.     

Increasing the conformational stability by replacement of heme axial ligand in c-type cytochrome

To investigate the role of the heme axial ligand in the conformational stability of c-type cytochrome, we constructed M58C and M58H mutants of the red alga Porphyra yezoensis cytochrome c(6) in which the sixth heme iron ligand (Met58) was replaced with Cys and His residues, respectively. The Gibbs free energy change for unfolding of the M58H mutant in water (DeltaG degrees (unf)=1.48 kcal/mol) was lower than that of the wild-type (2.43 kcal/mol), possibly due to the steric effects of the mutation on the apoprotein structure. On the other hand, the M58C mutant exhibited a DeltaG degrees (unf) of 5.45 kcal/mol, a significant increase by 3.02 kcal/mol compared with that of wild-type. This increase was possibly responsible for the sixth heme axial bond of M58C mutant being more stable than that of wild-type according to the heme-bound denaturation curve. Based on these observations, we propose that the sixth heme axial ligand is an important key to determine the conformational stability of c-type cytochromes, and the sixth Cys heme ligand will give stabilizing effects.     

The axial ligands of heme in cytochromes: a near-infrared magnetic circular dichroism study of yeast cytochromes c, c1, and b and spinach cytochrome f

Room temperature near-infrared magnetic circular dichroism and low-temperature electron paramagnetic resonance measurements have been used to characterize the ligands of the heme iron in mitochondrial cytochromes c, c1, and b and in cytochrome f of the photosynthetic electron transport chain. The MCD data show that methionine is the sixth ligand of the heme of oxidized yeast cytochrome c1; the identify of this residue is inferred to be the single conserved methionine identified from a partial alignment of the available cytochrome c1 amino acid sequences. A different residue, which is most likely lysine, is the sixth heme ligand in oxidized spinach cytochrome f. The data for oxidized yeast cytochrome b are consistent with bis-histidine coordination of both hemes although the possibility that one of the hemes is ligated by histidine and lysine cannot be rigorously excluded. The neutral and alkaline forms of oxidized yeast cytochrome c have spectroscopic properties very similar to those of the horse heart proteins, and thus, by analogy, the sixth ligands are methionine and lysine, respectively.     

Novel cyanide inhibition at cytochrome c1 of Rhodobacter capsulatus cytochrome bc1

Oxidized cytochrome c(1) in photosynthetic bacterium Rhodobacter capsulatus cytochrome bc(1) reversibly binds cyanide with surprisingly high, micromolar affinity. The binding dramatically lowers the redox midpoint potential of heme c(1) and inhibits steady-state turnover activity of the enzyme. As cytochrome c(1), an auxiliary redox center of the high-potential chain of cytochrome bc(1), does not interact directly with the catalytic quinone/quinol binding sites Q(o) and Q(i), cyanide introduces a novel, Q-site independent locus of inhibition. This is the first report of a reversible inhibitor that manipulates the energetics and electron transfers of the high-potential redox chain of cytochrome bc(1), while maintaining quinone substrate catalytic sites in an intact form.     

Suppression of axial methionine fluxion in Hydrogenobacter thermophilus Gln64Asn cytochrome c552

Proteins in the cytochrome c (cyt c) family with His-Met heme axial ligation display diverse heme electronic structures as revealed by the NMR spectra of their oxidized (paramagnetic) forms. These variations in electronic structure are thought to result primarily from differences in heme axial Met orientation among cyt c species. The factors determining Met orientation in cyts c, however, remain poorly understood. An additional layer of complexity was revealed with the recent finding that the axial Met in Hydrogenobacter thermophilus cytochrome c(552) (Ht cyt c(552)) is fluxional, sampling two conformations rapidly on the NMR time scale, resulting in an unusual compressed range of heme substituent hyperfine shifts [Zhong, L., Wen, X., Rabinowitz, T. M., Russell, B. S., Karan, E. F., and Bren, K. L. (2004) Proc.Natl. Acad. Sci. U.S.A. 101, 8637-8642]. In this work, the (1)H NMR hyperfine shift pattern of Ht cyt c(552) is drastically altered by making the conservative heme pocket mutation Gln64Asn. The mutant (Ht Q64N) displays a pattern of heme hyperfine shifts with a remarkable resemblance to that of structurally homologous Pseudomonas aeruginosa cyt c(551), which has Asn at position 64 and a single heme axial Met conformation. NMR analysis reveals that Asn64 in Ht Q64N is positioned to interact with the axial Met61, whereas the Gln64 in wild-type Ht cyt c(552) is not. It also is found that the heme axial Met is not fluxional in Ht Q64N and has an orientation similar to that in P. aeruginosa cyt c(551). These results indicate that peripheral interactions with the axial Met play an important role in determining axial Met orientation and heme electronic structure in cyts c.