Biochemical requirements for the maturation of mitochondrial c-type cytochromes

Cytochromes c are metalloproteins that function in electron transfer reactions and contain a heme moiety covalently attached via thioether linkages between the co-factor and a CXXCH motif in the protein. Covalent attachment of the heme group occurs on the positive side of all energy-transducing membranes (bacterial periplasm, mitochondrial intermembrane space and thylakoid lumen) and requires minimally: 1) synthesis and translocation of the apocytochromes c and heme across at least one biological membrane, 2) reduction of apocytochromes c and heme and maintenance under a reduced form prior to 3) catalysis of the heme attachment reaction. Surprisingly, the conversion of apoforms of cytochromes c to their respective holoforms occurs through at least three different pathways (systems I, II and III). In this review, we detail the assembly process of soluble cytochrome c and membrane-bound cytochrome c1, the only two mitochondrial c-type cytochromes that function in respiration. Mitochondrial c-type cytochromes are matured in the intermembrane space via the system I or system III pathway, an intriguing finding considering that the biochemical requirements for cytochrome c maturation are believed to be common regardless of the energy-transducing membrane under study.     

A bacterial c-type cytochrome can be translocated to the periplasm as an apo form; the biosynthesis of cytochrome cd1 (nitrite reductase) from Paracoccus denitrificans

An apo form of cytochrome cd1 (nitrite reductase) of Paracoccus denitrificans has been detected immunologically in the periplasm of a mutant that lacks all c-type cytochromes. A method for the preparation of apo-nitrite reductase (lacking both c- and d-type haem) from the holoenzyme of wild-type cells has been developed. The apoprotein synthesized by the mutant is indistinguishable from the chemically prepared apoprotein in respect of: (i) subunit molecular weight; (ii) formation of a homodimer; (iii) properties on anion exchange chromatography. The holoenzyme has similar properties in respect of (i) and (ii) but behaves differently during anion exchange. A suggested mode of assembly of cytochrome cd1 is translocation into the periplasm of a precursor polypeptide, maturation by a signal peptidase to give an apoprotein identical to that prepared chemically from the holoenzyme, followed by insertion of c-type and d-type haem in an as yet unknown order.     

Control of DegP-dependent degradation of c-type cytochromes by heme and the cytochrome c maturation system in Escherichia coli

c-Type cytochromes are located partially or completely in the periplasm of gram-negative bacteria, and the heme prosthetic group is covalently bound to the protein. The cytochrome c maturation (Ccm) multiprotein system is required for transport of heme to the periplasm and its covalent linkage to the peptide. Other cytochromes and hemoglobins contain a noncovalently bound heme and do not require accessory proteins for assembly. Here we show that Bradyrhizobium japonicum cytochrome c550 polypeptide accumulation in Escherichia coli was heme dependent, with very low levels found in heme-deficient cells. However, apoproteins of the periplasmic E. coli cytochrome b562 or the cytosolic Vitreoscilla hemoglobin (Vhb) accumulated independently of the heme status. Mutation of the heme-binding cysteines of cytochrome c550 or the absence of Ccm also resulted in a low apoprotein level. These levels were restored in a degP mutant strain, showing that apocytochrome c550 is degraded by the periplasmic protease DegP. Introduction of the cytochrome c heme-binding motif CXXCH into cytochrome b562 (c-b562) resulted in a c-type cytochrome covalently bound to heme in a Ccm-dependent manner. This variant polypeptide was stable in heme-deficient cells but was degraded by DegP in the absence of Ccm. Furthermore, a Vhb variant containing a periplasmic signal peptide and a CXXCH motif did not form a c-type cytochrome, but accumulation was Ccm dependent nonetheless. The data show that the cytochrome c heme-binding motif is an instability element and that stabilization by Ccm does not require ligation of the heme moiety to the protein.     

The Rhodobacter sphaeroides cytochrome c2 signal peptide is not necessary for export and heme attachment.

Rhodobacter sphaeroides cytochrome c2 (cyt c2) is a member of the heme-containing cytochrome c protein family that is found in the periplasmic space of this gram-negative bacterium. This exported polypeptide is made as a higher-molecular-weight precursor with a typical procaryotic signal peptide. Therefore, cyt c2 maturation is normally expected to involve precursor translocation across the cytoplasmic membrane, cleavage of the signal peptide, and covalent heme attachment. Surprisingly, synthesis as a precursor polypeptide is not a prerequisite for cyt c2 maturation because deleting the entire signal peptide does not prevent export, heme attachment, or function. Although cytochrome levels were reduced about threefold in cells containing this mutant protein, steady-state cyt c2 levels were significantly higher than those of other exported bacterial polypeptides which contain analogous signal peptide deletions. Thus, this mutant protein has the unique ability to be translocated across the cytoplasmic membrane in the absence of a signal peptide. The covalent association of heme with this mutant protein also suggests that the signal peptide is not required for ligand attachment to the polypeptide chain. These results have uncovered some novel aspects of bacterial c-type cytochrome biosynthesis.     

Import of proteins into mitochondria. The precursor of cytochrome c1 is processed in two steps, one of them heme-dependent

The apoprotein of yeast cytochrome c1 is made outside the mitochondria as a larger precursor which is then processed in at least two steps. In the first step, it is transported across both mitochondrial membranes and converted by a matrix-localized protease to an intermediate form whose molecular weight is between that of the precursor and the mature form. The intermediate form is bound to the outer face of the inner membrane. This first step requires an energized mitochondrial inner membrane, but no heme. In the second step, the intermediate form is converted to the mature cytochrome. This second step requires heme; it is blocked in a heme-deficient mutant or in wild type cells treated with an inhibitor of heme synthesis. Import of cytochrome c1 into mitochondria thus proceeds via two distinct heme-free precursors and at least two maturation steps, one of them dependent on heme.     

The biosynthesis of bacterial and plastidic c-type cytochromes

The biosynthesis of bacterial and plastidic c-type cytochromes includes several steps that occur post-translationally. In the case of bacterial cytochromes, the cytosolically synthesized pre-proteins are translocated across the cytoplasmic membrane, the pre-proteins are cleaved to their mature forms and heme is ligated to the processed apoprotein. Although heme attachment has not been studied extensively at the biochemical level, molecular genetic approaches suggest that the reaction generally occurs after translocation of the apoprotein to the periplasm. Recent studies with Bradyrhizobium japonicum and Rhodobacter capsulatus indicate that the process of heme attachment requires the function of a large number of genes. Mutation of these genes generates a pleiotropic deficiency in all c-type cytochromes, suggesting that the gene products participate in processes required for the biosynthesis of all c-type cytochromes. In eukaryotic cells, the biosynthesis of photosynthetic c-type cytochromes is somewhat more complex owing to the additional level of compartmentation. Nevertheless, the basic features of the pathway appear to be conserved. For instance, as is the case in bacteria, translocation and processing of the pre-proteins is not dependent on heme attachment. Genetic analysis suggests that the nuclear as well as the plastid genomes encode functions required for heme attachment, and that these genes function in the biosynthesis of the membrane-associated as well as the soluble c-type cytochrome of chloroplasts. A feature of cytochromes c biogenesis that appears to be conserved between chloroplasts and mitochondria is the sub-cellular location of the heme attachment reaction (p-side of the energy transducing membrane). Continued investigation of all three experimental systems (bacteria, chloroplasts, mitochondria) is likely to lead to a greater understanding of the biochemistry of cytochrome maturation as well as the more general problem of cofactor-protein association during the assembly of an energy transducing membrane.Abbreviations CCHL cytochrome c/heme lyase - CC₁HL cytochrome cl/heme lyase - cyt cytochrome - EMS ethyl methane sulphonate - n-side electrochemically negative side of an energy transducing membrane - p-side electrochemically positive side of an energy transducing membrane - PhoA alkaline phosphatase (encoded by the phoA locus)     

Cytochrome c biogenesis in bacteria: a possible pathway begins to emerge

Cytochrome c biogenesis describes the posttranslational pathway for the conversion of pre-apocytochrome c into the mature holocytochrome c. It involves an unknown number of consecutive biochemical steps, including translocation of the precursor polypeptide and haem into the periplasm and the covalent linkage between these two molecules. Genetic and molecular analysis of several bacterial mutants suggest that at least eight genes contribute to this process. In this review we summarize the present knowledge of the cytochrome c maturation pathway in bacteria and propose a model in which certain genes and their products are attributed to specific functions.     

A cytochrome b562 variant with a c-type cytochrome CXXCH heme-binding motif as a probe of the Escherichia coli cytochrome c maturation system

Cytochrome b562 is a periplasmic Escherichia coli protein; previous work has shown that heme can be attached covalently in vivo as a consequence of introduction of one or two cysteines into the heme-binding pocket. A heterogeneous mixture of products was obtained, and it was not established whether the covalent bond formation was catalyzed or spontaneous. Here, we show that coexpression from plasmids of a variant of cytochrome b562 containing a CXXCH heme-binding motif with the E. coli cytochrome c maturation (Ccm) proteins results in an essentially homogeneous product that is a correctly matured c-type cytochrome. Formation of the holocytochrome was accompanied by substantial production of its apo form, in which, for the protein as isolated, there is a disulfide bond between the two cysteines in the CXXCH motif. Following addition of heme to reduced CXXCH apoprotein, spontaneous covalent addition of heme to polypeptide occurred in vitro. Strikingly, the spectral properties were very similar to those of the material obtained from cells in which presumed uncatalyzed addition of heme (i.e. in the absence of Ccm) had been observed. The major product from uncatalyzed heme attachment was an incorrectly matured cytochrome with the heme rotated by 180 degrees relative to its normal orientation. The contrast between Ccm-dependent and Ccm-independent covalent attachment of heme indicates that the Ccm apparatus presents heme to the protein only in the orientation that results in formation of the correct product and also that heme does not become covalently attached to the apocytochrome b562 CXXCH variant without being handled by the Ccm system in the periplasm. The CXXCH variant of cytochrome b562 was also expressed in E. coli strains deficient in the periplasmic reductant DsbD or oxidant DsbA. In the DsbA- strain under aerobic conditions, c-type cytochromes were made abundantly and correctly when the Ccm proteins were expressed. This contrasts with previous reports indicating that DsbA is essential for cytochrome c biogenesis in E. coli.     

Characterization of recombinant horse cytochrome c synthesized with the assistance of Escherichia coli cytochrome c maturation factors

Cytochromes c are characterized by the presence of a protoporphyrin IX group covalently attached to the polypeptide via one or two thioether bonds to Cys side chains. The heme attachment process, known as cytochrome c maturation, occurs posttranslationally in the periplasm (for bacterial cytochromes c) or in the mitochondrial intermembrane space (for eukaryotic cytochromes c) through a pathway dependent on the organism. It is demonstrated in this work that a mitochondrial cytochrome c expressed in Escherichia coli that undergoes maturation under control of the E. coli cytochrome c maturation factors achieves a native-like structure and stability. The recombinant protein is characterized spectroscopically (by circular dichroism (CD), absorption, and nuclear magnetic resonance (NMR) spectroscopy) and it is verified that the heme and its environment are indistinguishable from authentic horse cytochrome c. Mass spectrometry reveals that the recombinant protein is not acetylated at the N terminus, however, no significant effect on protein structure or stability is detected as a result.     

Structure at 2.3 A resolution of the cytochrome bc(1) complex from the yeast Saccharomyces cerevisiae co-crystallized with an antibody Fv fragment

BACKGROUND: The cytochrome bc(1) complex is part of the energy conversion machinery of the respiratory and photosynthetic electron transfer chains. This integral membrane protein complex catalyzes electron transfer from ubiquinol to cytochrome c. It couples the electron transfer to the electrogenic translocation of protons across the membrane via a so-called Q cycle mechanism. RESULTS: The cytochrome bc(1) complex from the yeast Saccharomyces cerevisiae was crystallized together with a bound antibody Fv fragment. The structure was determined at 2.3 A resolution using multiple isomorphous replacement, and refined to a crystallographic R factor of 22.2% (R(free) = 25.4%). The complex is present as a homodimer. Each 'monomer' of the refined model includes 2178 amino acid residues of subunits COR1, QCR2, COB, CYT1, RIP1, QCR6, QCR7, QCR8 and QCR9 of the cytochrome bc(1) complex and of the polypeptides V(H) and V(L) of the Fv fragment, the cofactors heme b(H), heme b(L), heme c(1), the [2Fe-2S] cluster and 346 water molecules. The Fv fragment binds to the extrinsic domain of the [2Fe-2S] Rieske protein and is essential for formation of the crystal lattice. CONCLUSIONS: The approach to crystallize membrane proteins as complexes with specific antibody fragments appears to be of general importance. The structure of the yeast cytochrome bc(1) complex reveals in detail the binding sites of the natural substrate coenzyme Q6 and the inhibitor stigmatellin. Buried water molecules close to the binding sites suggest possible pathways for proton uptake and release. A comparison with other cytochrome bc(1) complexes shows features that are specific to yeast.     

Biogenesis of cytochrome c1. Role of cytochrome c1 heme lyase and of the two proteolytic processing steps during import into mitochondria

The biogenesis of cytochrome c1 involves a number of steps including: synthesis as a precursor with a bipartite signal sequence, transfer across the outer and inner mitochondrial membranes, removal of the first part of the presequence in the matrix, reexport to the outer surface of the inner membrane, covalent addition of heme, and removal of the remainder of the presequence. In this report we have focused on the steps of heme addition, catalyzed by cytochrome c1 heme lyase, and of proteolytic processing during cytochrome c1 import into mitochondria. Following translocation from the matrix side to the intermembrane-space side of the inner membrane, apocytochrome c1 forms a complex with cytochrome c1 heme lyase, and then holocytochrome c1 formation occurs. Holocytochrome c1 formation can also be observed in detergent-solubilized preparations of mitochondria, but only after apocytochrome c1 has first interacted with cytochrome c1 heme lyase to produce this complex. Heme linkage takes place on the intermembrane-space side of the inner mitochondrial membrane and is dependent on NADH plus a cytosolic cofactor that can be replaced by flavin nucleotides. NADH and FMN appear to be necessary for reduction of heme prior to its linkage to apocytochrome c1. The second proteolytic processing of cytochrome c1 does not take place unless the covalent linkage of heme to apocytochrome c1 precedes it. On the other hand, the cytochrome c1 heme lyase reaction itself does not require that processing of the cytochrome c1 precursor to intermediate size cytochrome c1 takes place first. In conclusion, cytochrome c1 heme lyase catalyzes an essential step in the import pathway of cytochrome c1, but it is not involved in the transmembrane movement of the precursor polypeptide. This is in contrast to the case for cytochrome c in which heme addition is coupled to its transport directly across the outer membrane into the intermembrane space.     

Physical interaction of CcmC with heme and the heme chaperone CcmE during cytochrome c maturation

Biogenesis of c-type cytochromes requires the covalent attachment of heme to the apoprotein. In Escherichia coli, this process involves eight membrane proteins encoded by the ccmABCDEFGH operon. CcmE binds heme covalently and transfers it to apocytochromes c in the presence of other Ccm proteins. CcmC is necessary and sufficient to incorporate heme into CcmE. Here, we report that the CcmC protein directly interacts with heme. We further show that CcmC co-immunoprecipitates with CcmE. CcmC contains two conserved histidines and a signature sequence, the so-called tryptophan-rich motif, which is the only element common to cytochrome c maturation proteins of bacteria, archae, plant mitochondria, and chloroplasts. We report that mutational changes of these motifs affecting the function of CcmC in cytochrome c maturation do not influence heme binding of CcmC. However, the mutants are defective in the CcmC-CcmE interaction, suggesting that these motifs are involved in the formation of a CcmC-CcmE complex. We propose that CcmC, CcmE, and heme interact directly with each other, establishing a periplasmic heme delivery pathway for cytochrome c maturation.     

Characterization of Hydrogenobacter thermophilus cytochromes c 552 expressed in the cytoplasm and periplasm of Escherichia coli

Hydrogenobacter thermophilus cytochrome c(552) ( Ht cyt c(552)) is a small monoheme protein in the cytochrome c(551) family. Ht cyt c(552) is unique because it is hypothesized to undergo spontaneous cytoplasmic maturation (covalent heme attachment) when expressed in Escherichia coli. This is in contrast to the usual maturation route for bacterial cytochromes c that occurs in the cellular periplasm, where maturation factors direct heme attachment. Here, the expression of Ht cyts c(552) in the periplasm as well as the cytoplasm of E. coli is reported. The products are characterized by absorption, circular dichroism, and NMR spectroscopy as well as mass spectrometry, proteolysis, and denaturation studies. The periplasmic product's properties are found to be indistinguishable from those reported for protein isolated from Ht cells, while the major cytoplasmic product exhibits structural anomalies in the region of the N-terminal helix. These anomalies are shown to result from the retention of the N-terminal methionine in the cytoplasmic product, and not from heme attachment errors. The (1)H NMR chemical shifts of the heme methyls of the oxidized ( S=1/2) expression products display a unique pattern not previously reported for a cytochrome c with histidine-methionine axial ligation, although they are consistent with native-like heme ligation. These results support the hypothesis that proper heme attachment can occur spontaneously in the E. coli cytoplasm for Ht cyt c(552).     

Apocytochrome c: an exceptional mitochondrial precursor protein using an exceptional import pathway

The cytochrome c import pathway differs markedly from the general route taken by the majority of other imported proteins, which is characterized by the import involvement of namely, surface receptors, the general insertion protein (GIP), contact sites and by the requirement of a membrane potential (delta psi). Unique features of both the cytochrome c precursor (apocytochrome c) and of the mechanism that transports it into mitochondria, have contributed to the evolution of a distinct import pathway that is not shared by any other mitochondrial protein analysed thus far. The cytochrome c pathway is particularly unique because i) apocytochrome c appears to have spontaneous membrane insertion-activity; ii) cytochrome c heme lyase seems to act as a specific binding site in lieu of a surface receptor and; iii) covalent heme addition and the associated refolding of the polypeptide appears to provide the free energy for the translocation of the cytochrome c polypeptide across the outer mitochondrial membrane.     

Membrane-spanning and periplasmic segments of CcmI have distinct functions during cytochrome c Biogenesis in Rhodobacter capsulatus

In gram-negative bacteria, like Rhodobacter capsulatus, about 10 membrane-bound components (CcmABCDEFGHI and CcdA) are required for periplasmic maturation of c-type cytochromes. These components perform the chaperoning and thio-oxidoreduction of the apoproteins as well as the delivery and ligation of the heme cofactors. In the absence of any of these components, including CcmI, proposed to act as an apocytochrome c chaperone, R. capsulatus does not have the ability to produce holocytochromes c or consequently to exhibit photosynthetic growth and cytochrome cbb3 oxidase activity. Previously, we have demonstrated that null mutants of CcmI partially overcome cytochrome c deficiency phenotypes upon overproduction of the CcmF-R. capsulatus CcmH (CcmF-CcmH(Rc)) couple in a growth medium-dependent manner and fully bypass these defects by additional overproduction of CcmG. Here, we show that overproduction of the CcmF-CcmH(Rc) couple and overproduction of the N-terminal membrane-spanning segment of CcmI (CcmI-1) have similar suppression effects of cytochrome c maturation defects in CcmI-null mutants. Likewise, additional overproduction of CcmG, the C-terminal periplasmic segment of CcmI (CcmI-2), or even of apocytochrome c2 also provides complementation abilities similar to those of these mutants. These results indicate that the two segments of CcmI have different functions and support our earlier findings that two independent steps are required for full recovery of the loss of CcmI function. We therefore propose that CcmI-1 is part of the CcmF-CcmH(Rc)-dependent heme ligation, while CcmI-2 is involved in the CcdA- and CcmG-dependent apoprotein thioreduction steps, which intersect at the level of CcmI during cytochrome c biogenesis.     

The in vivo turnover of rat liver microsomal epoxide hydrolase and both the apoprotein and heme moieties of specific cytochrome P-450 isozymes

The in vivo turnover rates of liver microsomal epoxide hydrolase and both the heme and apoprotein moieties of cytochromes P-450a, P-450b + P-450e, and P-450c have been determined by following the decay in specific radioactivity from 2 to 96 h after simultaneous injections of NaH14CO3 and 3H-labeled delta-aminolevulinic acid to Aroclor 1254-treated rats. Total liver microsomal protein was characterized by an apparent biphasic exponential decay in specific radioactivity, with half-lives of 5-9 and 82 h for the fast- and slow-phase components, respectively. Most (approximately 90%) of the rapidly turning over microsomal protein fraction was immunologically distinct from membrane-associated serum protein, and thus appeared to represent integral membrane proteins. The existence of two distinct populations of cytochrome P-450a was suggested by the apparent biphasic turnover of both the heme and apoprotein moieties of the holoenzyme. The half-lives of the apoprotein were estimated to be 12 and 52 h for the fast- and slow-phase components, respectively, and 7 and 34 h for the heme moiety. The turnover of cytochromes P-450b + P-450e was identical to that of cytochrome P-450c, with half-lives of 37 and 28 h for the apoprotein and heme moieties, respectively. In all cases, the shorter half-lives of the heme component compared to the protein component were statistically significant. In contrast to the cytochrome P-450 isozymes, epoxide hydrolase (t1/2 = 132 h) turned over slower than the "average" microsomal protein (t1/2 = 82 h). The differential rates of degradation of these major integral membrane proteins during both the rapid and slow phases of total microsomal protein turnover argue against the concepts of unit membrane degradation and unidirectional membrane flow of liver endoplasmic reticulum.     

The role of the twin-arginine motif in the signal peptide encoded by the hydA gene of the hydrogenase from Wolinella succinogenes

The hydABC operon of Wolinella succinogenes encodes the three subunits of the membrane-integrated Ni-hydrogenase. The catalytic subunit, HydB, is on the periplasmic side of the membrane. Residues R41 and R42 of the twin-arginine motif within the signal peptide of the precursor of the iron-sulfur subunit, HydA, were replaced by two glutamine residues. The corresponding mutant did not grow with H₂ as the electron donor of anaerobic respiration. Mature HydB and the precursor protein of HydA were located exclusively in the cytoplasmic cell fraction of the mutant, which catalyzed the reduction of benzyl viologen by H₂, suggesting that HydB contained Ni. The HydC protein was located in the membrane fraction of the mutant in wild-type amounts. HydC was purified and was shown to contain heme. The results suggest that HydA and HydB are translocated across the membrane by the Tat (twin-arginine translocation) system. The translocation of HydA and HydB as well as the maturation of the precursor protein of HydA appear to depend on the presence of the twin-arginine motif. In contrast, maturation of HydB, the insertion of HydC into the membrane, and heme attachment to HydC are apparently independent of the twin-arginine motif and do not require translocation of the two other hydrogenase subunits. Received: 17 June 1999 / Accepted: 21 July 1999     

Expression in Escherichia coli of c-type cytochrome genes from Rhodopseudomonas viridis.

The genes coding for the photosynthetic reaction center cytochrome c subunit (pufC) and the soluble cytochrome c2 (cycA) from the purple non-sulfur bacterium Rhodopseudomonas viridis were expressed in Escherichia coli. Biosynthesis of the reaction center cytochrome without a signal peptide resulted in the formation of inclusion bodies in the cytoplasm amounting to 14% of the total cellular protein. A series of plasmids coding for the cytochrome subunit with varying N-terminal signal peptides was constructed in attempts to achieve translocation across the E. coli cytoplasmic membrane and heme attachment. However, the two major recombinant proteins with N-termini corresponding to the signal peptide and the cytochrome were synthesized in E. coli as non-specific aggregates without heme incorporation. An increased ratio of precursor as compared to 'processed' apo-cytochrome was obtained when expression was carried out in a proteinase-deficient strain. Cytochrome c2 from R. viridis was synthesized in E. coli as a precursor associated with the cytoplasmic membrane. An expression plasmid was designed encoding the N-terminal part of the 33 kDa precursor protein of the oxygen-evolving complex of Photosystem II from spinach followed by cytochrome c2. Two recombinant proteins without heme were found to aggregate as inclusion bodies with N-termini corresponding to the signal peptide and the mature 33 kDa protein.     

The Escherichia coli cytochrome c maturation (Ccm) system does not detectably attach heme to single cysteine variants of an apocytochrome c

Cytochromes c are typically characterized by the covalent attachment of heme to polypeptide through two thioether bonds with the cysteine residues of a Cys-Xaa-Xaa-Cys-His peptide motif. In many Gram-negative bacteria, the heme is attached to the polypeptide by the periplasmically functioning cytochrome c maturation (Ccm) proteins. Exceptionally, Hydrogenobacter thermophilus cytochrome c(552), which has a normal CXXCH heme-binding motif, and variants with AXXCH, CXXAH, and AXXAH motifs, can be expressed as stable holocytochromes in the cytoplasm of Escherichia coli. By targeting these proteins to the periplasm using a signal peptide, with or without co-expression of the Ccm proteins, we have assessed the ability of the Ccm system to attach heme to proteins with no, one, or two cysteine residues in the heme-binding motif. Only the wild-type protein, with two cysteines, was effectively processed and thus accumulated in the periplasm as a holocytochrome. This is strong evidence for disulfide bond formation involving the two cysteine residues of apocytochrome c as an intermediate in Ccm-type Gram-negative bacterial cytochrome c biogenesis and/or that only a pair of cysteines can be recognized by the heme attachment apparatus.     

The C-terminal flexible domain of the heme chaperone CcmE is important but not essential for its function

CcmE is a heme chaperone active in the cytochrome c maturation pathway of Escherichia coli. It first binds heme covalently to strictly conserved histidine H130 and subsequently delivers it to apo-cytochrome c. The recently solved structure of soluble CcmE revealed a compact core consisting of a beta-barrel and a flexible C-terminal domain with a short alpha-helical turn. In order to elucidate the function of this poorly conserved domain, CcmE was truncated stepwise from the C terminus. Removal of all 29 amino acids up to crucial histidine 130 did not abolish heme binding completely. For detectable transfer of heme to type c cytochromes, only one additional residue, D131, was required, and for efficient cytochrome c maturation, the seven-residue sequence (131)DENYTPP(137) was required. When soluble forms of CcmE were expressed in the periplasm, the C-terminal domain had to be slightly longer to allow detection of holo-CcmE. Soluble full-length CcmE had low activity in cytochrome c maturation, indicating the importance of the N-terminal membrane anchor for the in vivo function of CcmE.