The CcmE protein of the c-type cytochrome biogenesis system: unusual in vitro heme incorporation into apo-CcmE and transfer from holo-CcmE to apocytochrome

Three key steps of cytochrome c biogenesis in many Gram-negative bacteria, the uptake of heme by the heme chaperone CcmE, the covalent attachment of heme to CcmE, and its subsequent release from CcmE to an apocytochrome c, have been achieved in vitro. apo-CcmE from Escherichia coli preferentially bound to ferric, with high affinity (K(d), 200 nM), rather than ferrous heme. The preference for ferric heme was confirmed by competition with 8-anilino-1-naphthalenesulfonate, which bound to a hydrophobic pocket in apo-CcmE. Reduction under certain conditions of the ferric heme-CcmE complex, which has characteristics of a b-type cytochrome, resulted in covalent attachment of heme to the protein. The resulting in vitro-produced holo-CcmE was identical to the in vivo-produced holo-CcmE, proving that unmodified Fe-protoporphyrin IX is incorporated into CcmE. Only noncovalent binding of mesoheme to CcmE was observed, thus implicating at least one vinyl group in covalent binding of heme to CcmE. Heme transferred in vitro from holo-CcmE to apocytochrome c, provided the heme was reduced. The necessity for reduced holo-CcmE might explain the role of the heme chaperone, i.e., prevention of reaction of ferric heme with apocytochrome and thus avoidance of incorrect side products. In addition, an AXXAH mutant of the CXXCH binding motif in the apocytochrome c was unable to accept heme from holo-CcmE. These in vitro results mimic, and thus have implications for, the molecular pathway of heme transfer during c-type cytochrome maturation in many species of bacteria in vivo.     

From the Cover: CcsBA is a cytochrome c synthetase that also functions in heme transport

Little is known about trafficking of heme from its sites of synthesis to sites of heme-protein assembly. We describe an integral membrane protein that allows trapping of endogenous heme to elucidate trafficking mechanisms. We show that CcsBA, a representative of a superfamily of integral membrane proteins involved in cytochrome c biosynthesis, exports and protects heme from oxidation. CcsBA has 10 transmembrane domains (TMDs) and reconstitutes cytochrome c synthesis in the Escherichia coli periplasm; thus, CcsBA is a cytochrome c synthetase. Purified CcsBA contains heme in an “external heme binding domain” for which two external histidines are shown to serve as axial ligands that protect the heme iron from oxidation. This is likely the active site of the synthetase. Furthermore, two conserved histidines in TMDs are required for heme to travel to the external heme binding domain. Remarkably, the function of CcsBA with mutations in these TMD histidines is corrected by exogenous imidazole, a result analogous to correction of heme binding by myoglobin when its proximal histidine is mutated. These data suggest that CcsBA has a heme binding site within the bilayer and that CcsBA is a heme channel.     

Evidence that two forms of bovine erythrocyte cytochrome b5 are identical to segments of microsomal cytochrome b5.

Homogeneous preparations of two forms of soluble cytochrome b5 have been obtained from bovine erythrocytes by successive chromatography on DEAE-cellulose, Bio-Gel P-60, and DEAE-Sephadex. Although the two forms could be separated on disc gel electrophoresis, they appeared to have similar molecular weights of approximately 12,000 and identical visible absorbance spectra. The tryptic hemepeptides derived from the two forms of bovine erythrocyte cytochrome b5 are electrophoretically indistinguishable from each other and from the tryptic core hemepeptide derived from liver microsomal cytochrome b5. The bovine erythrocyte tryptic hemepeptide was purified to homogeneity; its amino acid composition was shown to be identical to that of tryptic hemepeptide from liver microsomal cytochrome b5. The amino acid compositions of the two isolatable forms of erythrocyte cytochrome b5 correspond well to the compositions of the 97- and 95-residue segments of native liver microsomal cytochrome b5 that begin at the NH2 terminus. These results agree with the hypothesis that soluble erythrocyte cytochrome b5 is derived from microsomal protein by proteolysis during erythroid maturation.     

Respiration triggers heme transfer from cytochrome c peroxidase to catalase in yeast mitochondria

In exponentially growing yeast, the heme enzyme, cytochrome c peroxidase (Ccp1) is targeted to the mitochondrial intermembrane space. When the fermentable source (glucose) is depleted, cells switch to respiration and mitochondrial H₂O₂ levels rise. It has long been assumed that CCP activity detoxifies mitochondrial H₂O₂ because of the efficiency of this activity in vitro. However, we find that a large pool of Ccp1 exits the mitochondria of respiring cells. We detect no extramitochondrial CCP activity because Ccp1 crosses the outer mitochondrial membrane as the heme-free protein. In parallel with apoCcp1 export, cells exhibit increased activity of catalase A (Cta1), the mitochondrial and peroxisomal catalase isoform in yeast. This identifies Cta1 as a likely recipient of Ccp1 heme, which is supported by low Cta1 activity in ccp1Δ cells and the accumulation of holoCcp1 in cta1Δ mitochondria. We hypothesized that Ccp1’s heme is labilized by hyperoxidation of the protein during the burst in H₂O₂ production as cells begin to respire. To test this hypothesis, recombinant Ccp1 was hyperoxidized with excess H₂O₂ in vitro, which accelerated heme transfer to apomyoglobin added as a surrogate heme acceptor. Furthermore, the proximal heme Fe ligand, His175, was found to be ∼85% oxidized to oxo-histidine in extramitochondrial Ccp1 isolated from 7-d cells, indicating that heme labilization results from oxidation of this ligand. We conclude that Ccp1 responds to respiration-derived H₂O₂ via a previously unidentified mechanism involving H₂O₂-activated heme transfer to apoCta1. Subsequently, the catalase activity of Cta1, not CCP activity, contributes to mitochondrial H₂O₂ detoxification.Cytochrome c peroxidase (Ccp1) is a monomeric nuclear encoded protein with a 68-residue N-terminal mitochondrial targeting sequence (1). This presequence crosses the inner mitochondrial membrane and is cleaved by matrix proteases (2, 3). Mature heme-loaded Ccp1 is found in the mitochondrial intermembrane space (IMS) in exponentially growing yeast (2, 3) but the point of insertion of its single b-type heme is unknown. Under strict anaerobic conditions, Ccp1 is present in mitochondria as the heme-free form or apoform (4). Once cells are exposed to O₂ and heme biosynthesis is turned on, apoCcp1 converts rapidly to the mature holoenzyme by noncovalently binding heme (5).It is well established that mature Ccp1 functions as an efficient H₂O₂ scavenger in vitro (6). Its catalytic cycle involves the reaction of ferric Ccp1 with H₂O₂ (Eq. 1) to form compound I (CpdI) with a ferryl (Fe^IV) heme and a cationic indole radical localized on Trp191 (W191^+•). CpdI is one-electron reduced by the ferrous heme of cytochrome c (Cyc1) to compound II (CpdII) with ferryl heme (Eq. 2), and electron donation by a second ferrous Cyc1 returns CpdII to the resting Ccp1^III form (Eq. 3):Ccp1^III + H₂O₂ → CpdI(Fe^IV, W191^+?) + H₂O[1]CpdI(Fe^IV, W191^+?) + Cyc1^II → CpdII(Fe^IV) + Cyc1^III[2]CpdII(Fe^IV) + Cyc1^II → Ccp1^III + Cyc1^III + H₂O.[3]Because Ccp1 production is not under O₂/heme control (4, 5), CCP activity is assumed to be the frontline defense in the mitochondria, a major source of reactive oxygen species (ROS) in respiring cells (7). Contrary to the time-honored assumption that Ccp1 catalytically consumes the H₂O₂ produced during aerobic respiration (8), recent studies in our group reveal that the peroxidase behaves more like a mitochondrial H₂O₂ sensor than a catalytic H₂O₂ detoxifier (9–11). Notably, Ccp1 competes with complex IV for reducing equivalents from Cyc1, which shuttles electrons from complex III (ubiquinol cytochrome c reductase) to complex IV (cytochrome c oxidase) in the electron transport chain (12).Because CCP activity in the IMS siphons electrons from energy production, an H₂O₂ sensor role for Ccp1 should be energetically more favorable for the cell. Key evidence for a noncatalytic role for Ccp1 in H₂O₂ removal is that the isogenic strain producing the catalytically inactive Ccp1^W191F protein accumulates less H₂O₂ than wild-type cells (10). In fact, this mutant strain exhibits approximately threefold higher catalase A (Cta1) activity than wild-type cells (10) whereas CCP1 deletion results in a strain (ccp1Δ) with negligible Cta1 activity and high H₂O₂ levels (5). Unlike Cta1, which is the peroxisomal and mitochondrial catalase isoform in yeast (13), the cytosolic catalase Ctt1 (14) exhibits comparable activity in the wild-type, Ccp1^W191F, and ccp1Δ strains (10). Given that both Ccp1 and Cta1 are targeted to mitochondria, we hypothesized that Ccp1 may transfer its heme to apoCta1 in respiring cells.Cta1 is nuclear encoded with embedded mitochondrial and peroxisomal targeting sequences (15). Like Ccp1, each monomer noncovalently binds a b-type heme and mature Cta1 is active as a homotetramer. Synthesis of the Cta1 monomer is under O₂/heme control such that the apoenzyme begins to accumulate only during the logarithmic phase of aerobic growth (16). Hence, its O₂/heme independent production (4, 5) allows apoCcp1 to acquire heme while cells are synthesizing apoCta1. This, combined with our observation that Cta1 activity increases in respiring cells producing Ccp1 or Ccp1^W191F but not in ccp1Δ cells (10), led us to speculate that respiration-derived H₂O₂ triggers heme donation from Ccp1 to apoCta1 within mitochondria.What experimental evidence would support heme donation by Ccp1? It has been demonstrated that mutation of the proximal heme Fe ligand, His175, to a residue with weak or no Fe-coordinating ability produces Ccp1 variants (H175P, H175L, H175R, and H175M) that undergo mitochondrial processing but do not accumulate in isolated yeast mitochondria (17). Presumably, reduced heme affinity allows the Ccp1 variants to unfold and cross the outer mitochondrial membrane (17). Hence, we argued that if wild-type Ccp1 donated its heme, the apoprotein would likewise exit mitochondria. Consequently, we examine here age-dependent Ccp1–green fluorescent protein (Ccp1-GFP) localization in live cells chromosomally expressing Ccp1 C-terminally fused to GFP as well as the distribution of wild-type Ccp1 between subcellular fractions. Because weakening or removal of the proximal Fe ligand on His175 mutation reduces heme affinity (17), His175 oxidation in wild-type Ccp1 should have a similar effect, which we investigate here. We further speculated that in the absence of apoCta1 as an acceptor for its heme, more Ccp1 would remain trapped in the IMS so we compare mitochondrial Ccp1 levels in wild-type and cta1∆ cells. Our combined results support triggering of heme donation from Ccp1 to apoCta1 by respiration-derived H₂O₂. Such H₂O₂-activated heme transfer between proteins has not been reported to date and its implications in H₂O₂ signaling are discussed.     

Diffusion-limited contact formation in unfolded cytochrome c: estimating the maximum rate of protein folding.

How fast can a protein fold? The rate of polypeptide collapse to a compact state sets an upper limit to the rate of folding. Collapse may in turn be limited by the rate of intrachain diffusion. To address this question, we have determined the rate at which two regions of an unfolded protein are brought into contact by diffusion. Our nanosecond-resolved spectroscopy shows that under strongly denaturing conditions, regions of unfolded cytochrome separated by approximately 50 residues diffuse together in 35-40 microseconds. This result leads to an estimate of approximately (1 microsecond)-1 as the upper limit for the rate of protein folding.     

Protein influence on the heme in cytochrome c: evidence from Raman difference spectroscopy.

Raman difference spectra have been obtained for the cytochromes c of a number of species by simultaneous data acquisition from two samples. Frequency differences as small as 0.1 cm-1 can be measured reproducibly by the technique we have developed. In comparisons between cytochromes c isolated from two different species, the frequency differences in the heme vibrational modes range from 0 to 6 cm-1. The vibrational frequencies of the heme are sensitive to the electronic charge density on the porphyrin macrocycle. The frequency differences are interpreted in terms of the influence of the heme-packed aromatic and highly electronegative amino acid side chains on the pi* charge density and distribution on the heme. Such a control of the electronic properties of the heme by the protein may be important for the function of cytochrome c.     

Kinetic evidence for an on-pathway intermediate in the folding of cytochrome c

An early folding event of cytochrome c populates a helix-containing intermediate (I_NC) because of a pH-dependent misligation between the heme iron and nonnative ligands in the unfolded state (U). For folding to proceed, the nonnative ligation error must first be corrected. It is not known whether I is on-pathway, with folding to the native state (N) as in U ↔ I_NC ↔ N, or whether the I must first move back through the U and then fold to the N through some alternative path (I_NC ↔ U ↔ N). By means of a kinetic test, it is shown here that the cytochrome c I does not first unfold to U. The method used provides an experimental criterion for rejecting the off-pathway I ↔ U ↔ N option.     

Neutral thiol as a proximal ligand to ferrous heme iron: implications for heme proteins that lose cysteine thiolate ligation on reduction

Cysteine plays a key role as a metal ligand in metalloproteins. In all well-recognized cases, however, it is the anionic cysteinate that coordinates. Several cysteinate-ligated heme proteins are known, but some fail to retain thiolate ligation in the ferrous state, possibly following protonation to form neutral cysteine. Ligation by cysteine thiol in ferrous heme proteins has not been documented. To establish spectroscopic signatures for such systems, we have prepared five-coordinate adducts of the ferrous myoglobin H94G cavity mutant with neutral thiol and thioether sulfur donors as well as six-coordinate derivatives such as with CO and, when possible, with NO and O(2). A thiol-ligated oxyferrous complex is reported, to our knowledge for the first time. Further, a bis-thioether ferrous H93G model for bis-methionine ligation, as found in Pseudomonas aeruginosa bacterioferritin heme protein, is described. Magnetic CD spectroscopy has been used due to its established ability in axial ligand identification. The magnetic CD spectra of the H93G complexes have been compared with those of ferrous H175CD235L cytochrome c peroxidase to show that its proximal ligand is neutral cysteine. We had previously reported this cytochrome c peroxidase mutant to be cysteinate-ligated in the ferric state, but the ferrous ligand was undetermined. The spectral properties of ferrous liver microsomal cytochrome P420 (inactive P450) are also consistent with thiol ligation. This study establishes that neutral cysteine can serve as a ligand in ferrous heme iron proteins, and that ferric cysteinate-ligated heme proteins that fail to retain such ligation on reduction may simply be ligated by neutral cysteine.     

Definition of the catalytic site of cytochrome c oxidase: specific ligands of heme a and the heme a3-CuB center.

The three-subunit aa3-type cytochrome c oxidase (EC 1.9.3.1) of Rhodobacter sphaeroides is structurally and functionally homologous to the more complex mitochondrial oxidase. The largest subunit, subunit I, is highly conserved and predicted to contain 12 transmembrane segments that provide all the ligands for three of the four metal centers: heme a, heme a3, and CuB. A variety of spectroscopic techniques identify these ligands as histidines. We have used site-directed mutagenesis to change all the conserved histidines within subunit I of cytochrome c oxidase from Rb. sphaeroides. Analysis of the membrane-bound and purified mutant proteins by optical absorption and resonance Raman spectroscopy indicates that His-102 and His-421 are the ligands of heme a, while His-284, His-333, His-334, and His-419 ligate the heme a3-CuB center. To satisfy this ligation assignment, helices II, VI, VII, and X, which contain these histidine residues, must be in close proximity. These data provide empirical evidence regarding the three-dimensional protein structure at the catalytic core of cytochrome c oxidase.     

Mitochondrial membrane biogenesis: identification of a precursor to yeast cytochrome c oxidase subunit II, an integral polypeptide.

Many of the polypeptides made on endogenous ribosomes inside of yeast mitochondria are hydrophobic "integral polypeptides" which are subunits of at least three oligomeric enzyme complexes (cytochrome c oxidase, rutamycin-sensitive ATPase, and coenzyme QH2-cytochrome c reductase) of the inner mitochondrial membrane. In order to elucidate the pathway(s) followed by these polypeptides into the inner membrane we have used an in vitro mitochondrial translation system from yeast. By inhibiting this system with aurintricarboxylic acid, we have been able to demonstrate and accumulate a transient precursor to subunit II of cytochrome c oxidase. This precursor, designated II', is approximately 1,500 daltons larger than mature subunit II and most likely is a form of subunit II with an NH2-terminal extension. Although this precursor appears to be processed cotranslationally under normal conditions, it does associate in unprocessed form with mitochondrial membranes when allowed to accumulate in the presence of aurintricarboxylic acid, and it can be processed postranslationally upon removal of the drug. None of the other mitochondrial translation products made in this system exhibits larger precursors. These results indicate that at least one mitochondrial translation product has a transient "leader sequence" a,d is inserted into the inner mitochondrial membrane and processed cotranslationally, but they suggest that other pathways may be followed by the other translation products.     

Heme-protein vibrational couplings in cytochrome c provide a dynamic link that connects the heme-iron and the protein surface

The active site of cytochrome c (Cyt c) consists of a heme covalently linked to a pentapeptide segment (Cys-X-X-Cys-His), which provides a link between the heme and the protein surface, where the redox partners of Cyt c bind. To elucidate the vibrational properties of heme c, nuclear resonance vibrational spectroscopy (NRVS) measurements were performed on (57)Fe-labeled ferric Hydrogenobacter thermophilus cytochrome c(552), including (13)C(8)-heme-, (13)C(5)(15)N-Met-, and (13)C(15)N-polypeptide (pp)-labeled samples, revealing heme-based vibrational modes in the 200- to 450-cm(-1) spectral region. Simulations of the NRVS spectra of H. thermophilus cytochrome c(552) allowed for a complete assignment of the Fe vibrational spectrum of the protein-bound heme, as well as the quantitative determination of the amount of mixing between local heme vibrations and pp modes from the Cys-X-X-Cys-His motif. These results provide the basis to propose that heme-pp vibrational dynamic couplings play a role in electron transfer (ET) by coupling vibrations of the heme directly to vibrations of the pp at the protein-protein interface. This could allow for the direct transduction of the thermal (vibrational) energy from the protein surface to the heme that is released on protein/protein complex formation, or it could modulate the heme vibrations in the protein/protein complex to minimize reorganization energy. Both mechanisms lower energy barriers for ET. Notably, the conformation of the distal Met side chain is fine-tuned in the protein to localize heme-pp mixed vibrations within the 250- to 400-cm(-1) spectral region. These findings point to a particular orientation of the distal Met that maximizes ET.     

A strategy for finding classes of minima on a hypersurface: implications for approaches to the protein folding problem.

Locating the native structure of a given protein is a task made difficult by the complexity of the potential energy hypersurface and by the huge number of local minima it contains. We have explored a strategy (the "antlion" method) for hypersurface modification that suppresses all minima but that of the native structure. Transferrable penalty functions with general applicability for modifying a hypersurface to retain the desired minimum are identified, and two blocked oligopeptides (alanine dipeptide and tetrapeptide) are used for specific numerical illustration of the dramatic simplification that ensues. In addition, an intermediary role for neural networks to manage some aspects of the antlion strategy applied to large polypeptides and proteins is introduced.     

From one gene to two proteins: the biogenesis of cytochromes b and c1 in Bradyrhizobium japonicum.

Genes coding for polyproteins that are cleaved posttranslationally into two or more functional proteins are rarely found in prokaryotes. One example concerns the biogenesis of the Bradyrhizobium japonicum cytochromes b and c1, two of the three constituent subunits of ubiquinol-cytochrome-c reductase (ubiquinol:ferricytochrome-c oxidoreductase, EC 1.10.2.2); the respective apoproteins for these subunits are encoded by the 5' and 3' halves of a single gene, fbcH. These two halves are linked by an extra piece of DNA encoding a characteristic signal peptide for protein translocation across the cytoplasmic membrane. Processing of the fbcH gene product is shown to occur at a typical signal peptidase recognition site. This reaction is reminiscent of that catalyzed by the regular bacterial signal peptidase that normally cleaves off presequences from the N termini of translocated proteins. Mutational alteration of the signal peptidase recognition site within FbcH results in the appearance of an uncleaved bc1 fusion protein in the membrane. Additionally, a functional heme-binding site in the apocytochrome c1 section of FbcH is shown to be a necessary prerequisite for the formation of the bc1 complex.     

nemy encodes a cytochrome b561 that is required for Drosophila learning and memory

Although many genes have been shown to play essential roles in learning and memory, the precise molecular and cellular mechanisms underlying these processes remain to be fully elucidated. Here, we present the molecular and behavioral characterization of the Drosophila memory mutant nemy. We provide multiple lines of evidence to show that nemy arises from a mutation in a Drosophila homologue of cytochrome B561. nemy is predominantly expressed in neuroendocrine neurons in the larval brain, and in mushroom bodies and antennal lobes in the adult brain, where it is partially coexpressed with peptidyl α-hydroxylating monooxygenase (PHM), an enzyme required for peptide amidation. Cytochrome b561 was found to be a requisite cofactor for PHM activity and we found that the levels of amidated peptides were reduced in nemy mutants. Moreover, we found that knockdown of PHM gave rise to defects in memory retention. Altogether, the data are consistent with a model whereby cytochrome B561-mediated electron transport plays a role in memory formation by regulating intravesicular PHM activity and the formation of amidated neuropeptides.     

Identification of a groES-like chaperonin in mitochondria that facilitates protein folding.

Mitochondria contain a polypeptide that is functionally equivalent to Escherichia coli chaperonin 10 (cpn10; also known as groES). This mitochondrial cpn10 has been identified in beef and rat liver and is able to replace bacterial cpn10 in the chaperonin-dependent reconstitution of chemically denatured ribulose-1,5-bisphosphate carboxylase. Thus, like the bacterial homologue, mitochondrial cpn10 facilitates a K(+)- and Mg.ATP-dependent discharge of unfolded (or partially folded) ribulose bisphosphate carboxylase from bacterial chaperonin 60 (cpn60; also known as groEL). Instrumental to its identification, mitochondrial cpn10 and bacterial cpn60 form a stable complex in the presence of Mg.ATP. Bacterial and mitochondrial cpn10 compete for a common saturable site on bacterial cpn60. As a result of complex formation, with either mitochondrial or bacterial cpn10, the "uncoupled ATPase" activity of bacterial cpn60 is virtually abolished. The most likely candidate for mitochondrial cpn10 is an approximately 45-kDa oligomer composed of approximately 9-kDa subunits. We propose that, like the protein-folding machinery of prokaryotes, mitochondrial cpn60 requires a cochaperonin for full biological function.     

Spectroscopic analysis of the cytochrome c oxidase-cytochrome c complex: circular dichroism and magnetic circular dichroism measurements reveal change of cytochrome c heme geometry imposed by complex formation.

Binding of cytochrome c to cytochrome c oxidase induces a conformational change in both proteins as well as a change of the electronic structure of the heme of cytochrome c, indicating an altered heme c-protein interaction. This follows from the observation that the induced circular dichroism (CD) and magnetic circular dichroism (MCD) spectra of the oxidase-cytochrome c complex in the Soret region differ from the summed spectra of oxidase plus cytochrome c. Spectral changes occur in the complex composed of either the two ferric or the two ferrous hemoproteins. The difference CD and MCD signals saturate at a ratio of 1 heme c per heme aa3. The difference spectra are specific to the cognate complex. The results are interpreted to reflect a direct relationship between the recognition/binding step and the electron-transfer reaction. The conformational rearrangement induced in cytochrome c by cytochrome c oxidase consists of a structural rearrangement of the heme environment and possibly a change of the geometry of the heme iron-methionine-80 sulfur axial bond. This rearrangement may decrease the reorganizational free energy of electron transfer by adjusting the heme c geometry to a state between that of ferri- and ferrocytochrome c.     

Investigations of heme distortion,low-frequency vibrational excitations,and electron transfer in cytochrome c

Cytochrome (cyt) c is an important electron transfer protein. The ruffling deformation of its heme cofactor has been suggested to relate to its electron transfer rate. However, there is no direct experimental evidence demonstrating this correlation. In this work, we studied Pseudomonas aeruginosa cytochrome c₅₅₁ and its F7A mutant. These two proteins, although similar in their X-ray crystal structure, display a significant difference in their heme out-of-plane deformations, mainly along the ruffling coordinate. Resonance Raman and vibrational coherence measurements also indicate significant differences in ruffling-sensitive modes, particularly the low-frequency γ_a mode found between ∼50–60 cm⁻¹. This supports previous assignments of γ_a as having a large ruffling content. Measurement of the photoreduction kinetics finds an order of magnitude decrease of the photoreduction cross-section in the F7A mutant, which has nearly twice the ruffling deformation as the WT. Additional measurements on cytochrome c demonstrate that heme ruffling is correlated exponentially with the electron transfer rates and suggest that ruffling could play an important role in redox control. A major relaxation of heme ruffling in cytochrome c, upon binding to the mitochondrial membrane, is discussed in this context.Cytochrome (cyt) c is an important electron transfer protein that is involved in a variety of biological functions such as photosynthesis, respiration, and apoptosis (1). The heme group (Fe-protoporphyrin IX) is the functional center of cyt c. The heme iron is axially coordinated to His18 (proximal ligand) and Met80 (distal ligand) in its native solution state. The porphyrin ring is also covalently anchored to the protein by two thioether linkages with Cys-14 and Cys-17, which form a Cys-X-X-Cys-His (CXXCH) pentapeptide unit that is a unique feature shared by nearly all c-type hemes (1) [“XX” refers to other amino acids, e.g., Val and Ala, as in Pseudomonas aeruginosa (Pa) cyt c₅₅₁].The heme in cyt c has a geometry that is dominated by a large ruffling distortion, induced by both the protein fold and by the CXXCH motif (2, 3). Systematic analysis of X-ray crystal structures of heme proteins has shown that the proteins belonging to the same functional class share similar out-of-plane (OOP) heme distortions (4–6). These protein-induced OOP distortions are energetically unfavorable for the heme, and their evolutionary conservation implies that they have biological significance. Among them, doming and ruffling have been reasonably well characterized and correlated with protein functions. Doming is typically observed in oxygen storage or transport proteins such as hemoglobin (7, 8) and myoglobin (9). Moreover, the coupling of heme doming to the protein conformational substates has been shown to be functionally significant in a variety of heme protein systems (10–12). However, heme ruffling, which is the primary topic of this paper, is the dominant OOP deformation found in c-type cytochromes (4–6, 13) and nitrophorins (14–16), which are involved in electron and NO transport, respectively.As seen in Fig. 1, ruffling involves a pyrrole-ring twisting about the Fe–N bond. The ruffling distortion tilts the p_z orbitals of the porphyrin nitrogens away from the heme normal and increases overlap of the porphyrin a_2u and iron d_xy orbitals. It has been shown (17) via NMR experiments and density functional theory computation that, in the absence of a strong π-acceptor axial ligand (18), a ruffling deformation increases the Fe 3d_π-based electron density on the iron center, which makes the heme meso-carbon electron donation to the iron 3d_xy orbital less energetically favorable (17). Ruffling destabilizes all three occupied Fe 3d-based molecular orbitals and decreases the positive and negative spin density on the β-pyrrole and meso-carbon, respectively (17). Consequently, the electron transfer rate to the ferric heme is expected to decrease as a function of the ruffling deformation (17). In addition, when ruffling is considered in isolation, it decreases the reduction potential of ferric cyt c (19–22).Open in a separate windowFig. 1.Crystal structure and NSD analysis of hemes in ferric Pa cyt c₅₅₁ and its F7A mutant are compared with hh cyt c. The minus sign of displacement is defined only for doming and inverse doming to indicate the direction of Fe displacement (+, proximal; −, distal). The ruffling mode is shown at the lower left part of the figure and the arrows indicate the rotation of pyrrole rings with respect to Fe–N axis (dotted black lines).The CXXCH pentapeptide in cyt c may be critical to the ruffled structure and the function of cyt c (2, 3, 23). The CXXCH unit is thought to affect the heme reduction potential (1), and it can influence heme deformation through the covalent bonding of the thioether groups and by hydrogen bonding within the pentapeptide (2, 3). Furthermore, the CXXCH pentapeptide may have a biologically important role related to its proximity to the electron transfer partner binding site, as in the yeast cyt c peroxidase/cyt c complex (24). The local vibrational modes of heme in the 250–400 cm⁻¹ region have been shown to strongly mix with the vibrational modes of the CXXCH motif (23). This suggests that the heme–CXXCH vibrational dynamic couplings can play a role in electron transfer by coupling the vibrations of the heme directly to vibrations of the CXXCH unit at the protein–protein interface. This coupling could help to transduce thermal energy or alter the reorganization energy and the barrier for electron tunneling (23).Despite the great deal of work that has been done to investigate electron transfer and heme deformation in cyt c, no experiment has directly demonstrated a quantitative correlation between heme deformation and the electron transfer rate. Generally, the functionally important heme modes, such as doming and ruffling, are delocalized and involve many nuclei and lie in the low-frequency region below 200 cm⁻¹. Infrared and resonance Raman spectroscopy cannot reliably detect heme modes below ∼150 cm⁻¹ in the aqueous phase, owing to the strong absorbance, Rayleigh scattering, and quasi-elastic scattering of water (25). In contrast, impulsive stimulated Raman driven vibrational coherence, or vibrational coherence spectroscopy (VCS), makes it possible to extract vibrational modulations of the third-order polarization of the heme at very low frequency, which provides access to this relatively unexplored region.We have used this technique previously to investigate the low-frequency modes of a variety of heme proteins, using Soret band excitation (26–29). Unlike the higher frequency modes (>200 cm⁻¹), the low-frequency modes (which have weaker force constants) are more easily distorted from equilibrium by the protein surroundings. These modes are activated in VCS when the protein induces symmetry-breaking nonplanar heme distortions (29). In addition, these modes take on a special functional significance because of their thermal accessibility. The low-frequency coherence spectra offer a unique window into how the surrounding protein environment can alter these important thermally active heme modes.In this work, we studied Pa cyt c₅₅₁ and its F7A mutant using absorption spectroscopy, resonance Raman spectroscopy, and VCS. Pa cyt c₅₅₁ and its F7A mutant have very similar crystal structures, but the mutant has a more ruffled heme geometry than the WT. The investigations of this very similar pair of proteins revealed a clear difference between their resonance Raman and VCS spectra, reflecting the different degree of heme ruffling deformation. These observations support the previous assignment that γ_a (45∼60 cm⁻¹) is a mode with major ruffling content in the c-type heme of cyt c. We also investigated the photoreduction kinetics of the two cyt c₅₅₁ proteins as well as horse heart cyt c (hh cyt c hereafter). The photoreduction cross-section determined for WT cyt c₅₅₁ is an order of magnitude larger than for the more ruffled F7A mutant and approximately two orders of magnitude larger than hh cyt c. Although the details of photoreduction in heme proteins are not fully understood (30–32), these measurements provide direct quantitative evidence that correlate dramatic increases in the photoinduced electron transfer rate with only approximately a factor of two decrease in the ruffling distortion.