Crystal structure and biochemical features of EfeB/YcdB from Escherichia coli O157: ASP235 plays divergent roles in different enzyme-catalyzed processes

EfeB/YcdB is a member of the dye-decolorizing peroxidase (DyP) protein family. A recent study has shown that this protein can extract iron from heme without breaking the tetrapyrrole ring. We report the crystal structure of EfeB from Escherichia coli O157 bound to heme at 1.95 Å resolution. The EfeB monomer contains two domains. The heme molecule is located in a large hydrophobic pocket in the C-terminal domain. A long loop connecting the two domains extensively interacts with the heme, which is a distinctive structural feature of EfeB homologues. A large tunnel formed by this loop and the β-sheet of C-terminal domain provides a potential cofactor/substrate binding site. Biochemical data show that the production of protoporphyrin IX (PPIX) is closely related to the peroxidation activity. The mutant D235N keeps nearly the same activity of guaiacol peroxidase as the wild-type protein, whereas the corresponding mutation in the classic DyP protein family completely abolished the peroxidation activity. These results suggest that EfeB is a unique member of the DyP protein family. In addition, dramatically enhanced fluorescence excitation and emission of EfeB-PPIX was observed, implying this protein may be used as a red color fluorescence marker.     

The membrane anchors of the heme chaperone CcmE and the periplasmic thioredoxin CcmG are functionally important

The cytochrome c maturation system of Escherichia coli contains two monotopic membrane proteins with periplasmic, functional domains, the heme chaperone CcmE and the thioredoxin CcmG. We show in a domain swap experiment that the membrane anchors of these proteins can be exchanged without drastic loss of function in cytochrome c maturation. By contrast, the soluble periplasmic forms produced with a cleavable OmpA signal sequence have low biological activity. Both the chimerical CcmE (CcmG'-'E) and the soluble periplasmic CcmE produce low levels of holo-CcmE and thus are impaired in their heme receiving capacity. Also, both forms of CcmE can be co-precipitated with CcmC, thus restricting the site of interaction of CcmE with CcmC to the C-terminal periplasmic domain. However, the low level of holo-CcmE formed in the chimera is transferred efficiently to cytochrome c, indicating that heme delivery from CcmE does not involve the membrane anchor.     

A Brownian dynamics study of the interactions of the luminal domains of the cytochrome b6f complex with plastocyanin and cytochrome c6: the effects of the Rieske FeS protein on the interactions

The availability of the structures of the cytochrome b6f complex (cyt b6f), plastocyanin (PC), and cytochrome c6 (cyt c6) from Chlamydomonas reinhardtii allowed us, for the first time, to model electron transfer interactions between the luminal domains of this complex (including cyt f and the Rieske FeS protein) and its redox partners in the same species. We also generated a model structure in which the FeS center of the Rieske protein was positioned closer to the heme of cyt f than observed in the crystal structure and studied its interactions with both PC and cyt c6. Our data showed that the Rieske protein in both the original crystal structure and in our modeled structure of the cyt b6f complex did not physically interfere with binding position or orientation of PC or cyt c6 on cyt f. PC docked on cyt f with the same orientation in the presence or the absence of the Rieske protein, which matched well with the previously reported NMR structures of complexes between cyt f and PC. When the FeS center of the Rieske protein was moved close to the heme of cyt f, it even enhanced the interaction rates. Studies using a cyt f modified in the 184-191 loop showed that the cyt f structure is a more important factor in determining the rate of complex formations than is the presence or the absence of the Rieske protein or its position with respect to cyt f.     

The crystal structure of the hexadeca-heme cytochrome Hmc and a structural model of its complex with cytochrome c(3)

Sulfate-reducing bacteria contain a variety of multi-heme c-type cytochromes. The cytochrome of highest molecular weight (Hmc) contains 16 heme groups and is part of a transmembrane complex involved in the sulfate respiration pathway. We present the 2.42 A resolution crystal structure of the Desulfovibrio vulgaris Hildenborough cytochrome Hmc and a structural model of the complex with its physiological electron transfer partner, cytochrome c(3), obtained by NMR restrained soft-docking calculations. The Hmc is composed of three domains, which exist independently in different sulfate-reducing species, namely cytochrome c(3), cytochrome c(7), and Hcc. The complex involves the last heme at the C-terminal region of the V-shaped Hmc and heme 4 of cytochrome c(3), and represents an example for specific cytochrome-cytochrome interaction.     

Bacillus subtilis 13-kilodalton cytochrome c-550 encoded by cccA consists of a membrane-anchor and a heme domain

Little is known about c-type cytochromes in Gram-positive bacteria in contrast to the wealth of information available on this type of cytochrome in Gram-negative bacteria and in eucaryotes. In the present work, the strictly aerobic bacterium Bacillus subtilis was analyzed for subcellular localization and number of different cytochromes c. In vivo labeling with radioactive 5-aminolevulinic acid, a precursor to heme, showed that the proteins containing covalently bound heme are predominantly found in the membrane fraction. One major membrane-bound cytochrome c of about 15 kDa and with an alpha-band absorption peak in the reduced state at 550 nm was analyzed in more detail. Cytochrome c-550 has the properties of an integral membrane protein. The physiological function of this relatively high redox potential cytochrome is not known. Its structural gene, cccA, was cloned, sequenced, and overexpressed in B. subtilis. The gene maps adjacent to rpoD (sigA) at 223 degrees on the chromosome. The amino acid sequence of cytochrome c-550 as deduced from the DNA sequence consists of 120 residues and contains one heme c binding site (Cys-Ile-Ala-Cys-His) located approximately in the middle of the polypeptide. From the hydropathy distribution and from comparisons to soluble c-type cytochromes of known three-dimensional structure, cytochrome c-550 seemingly consists of two domains; an N-terminal membrane-anchor domain and a C-terminal heme domain. A model for the topography of the cytochrome in the cytoplasmic membrane is suggested in which the N-terminal part spans the membrane in the form of a single segment in an alpha-helical conformation and the C-terminal heme domain is exposed on the extracytoplasmic side of the membrane. Deletion of cccA from the chromosome revealed another membrane-bound cytochrome with absorption maximum at 550 nm in the reduced state. Analysis of cccA deletion mutants demonstrated that the cytochrome c-550 encoded by cccA is not essential for growth of B. subtilis on rich or minimal media.     

CcmD is involved in complex formation between CcmC and the heme chaperone CcmE during cytochrome c maturation

CcmD is a small membrane protein involved in heme delivery to the heme chaperone CcmE during cytochrome c maturation. Here we show that it physically interacts with CcmE and CcmC, another essential component of the heme delivery system. We demonstrate the formation of a ternary complex consisting of CcmCDE. A deletion analysis of individual domains revealed that the central hydrophobic domain is essential for its function. Moreover, the C-terminal, cytoplasmic domain seems to require a net positive charge to be functional. Our topology analysis indicates that CcmD is an integral interfacial membrane protein with its N and C termini extruding into the cytoplasmic side of the membrane. Interactions of CcmD with either ferrochelatase, the last heme biosynthetic enzyme, or directly with heme were not detectable. We postulate a function for CcmD in protein-protein interaction or membrane protein assembly required for the heme delivery process.     

Site-directed mutagenesis of the heme axial ligands in the hemoflavoenzyme cellobiose dehydrogenase

Cellobiose dehydrogenase (CDH) from Phanerochaete chrysosporium is an extracellular 90-kDa hemoflavoenzyme, organized into an N-terminal heme domain and a C-terminal flavin domain. The amino acid residues Met65 and His114 or His163 were suggested to be heme iron ligands. Mutations of these residues were made and mutant proteins were characterized. H114A mutant cultures produce a stable hemoflavoenzyme with spectral and kinetic characteristics similar to those of wild-type CDH. The M65A and H163A transformants secrete a 90-kDa hemoflavoenzyme, which oxidizes cellobiose in the presence of 2,6-dichlorophenol-indophenol (DCPIP), but is unable to reduce cytochrome c. The heme domains of the M65A and H163A CDH variants are, however, unstable and susceptible to degradation, both yielding a 70-kDa cellobiose-oxidizing flavoenzyme. The spectral and kinetic characteristics of these truncated variants suggest that they contain only their respective flavin domains. The yield of the 90-kDa proteins was low and the proteins could not be purified to homogeneity; however, absorption spectra indicate that the 90-kDa proteins do contain the heme domain. Like the truncated flavoenzymes, the 90-kDa variants reduce DCPIP but are unable to transfer electrons to cytochrome c, in contrast to wild-type CDH. These findings suggest that H163 and M65 are the axial heme ligands and that both ligands are required for the reactivity and structural integrity of the heme domain.     

Crystal structures at atomic resolution reveal the novel concept of "electron-harvesting" as a role for the small tetraheme cytochrome c

The genus Shewanella produces a unique small tetraheme cytochrome c that is implicated in the iron oxide respiration pathway. It is similar in heme content and redox potential to the well known cytochromes c(3) but related in structure to the cytochrome c domain of soluble fumarate reductases from Shewanella sp. We report the crystal structure of the small tetraheme cytochrome c from Shewanella oneidensis MR-1 in two crystal forms and two redox states. The overall fold and heme core are surprisingly different from the soluble fumarate reductase structures. The high resolution obtained for an oxidized orthorhombic crystal (0.97 A) revealed several flexible regions. Comparison of the six monomers in the oxidized monoclinic space group (1.55 A) indicates flexibility in the C-terminal region containing heme IV. The reduced orthorhombic crystal structure (1.02 A) revealed subtle differences in the position of several residues, resulting in decreased solvent accessibility of hemes and the withdrawal of a positive charge from the molecular surface. The packing between monomers indicates that intermolecular electron transfer between any heme pair is possible. This suggests there is no unique site of electron transfer on the surface of the protein and that electron transfer partners may interact with any of the hemes, a process termed "electron-harvesting." This optimizes the efficiency of intermolecular electron transfer by maximizing chances of productive collision with redox partners.     

Heterologous expression of an endogenous rat cytochrome b(5)/cytochrome b(5) reductase fusion protein: identification of histidines 62 and 85 as the heme axial ligands

The gene coding for expression of an endogenous soluble fusion protein comprising a b-type cytochrome-containing domain and a FAD-containing domain has been cloned from rat liver mRNA. The 1461-bp hemoflavoprotein gene corresponded to a protein of 493 residues with the heme- and FAD-containing domains comprising the amino and carboxy termini of the protein, respectively. Sequence analysis indicated the heme and flavin domains were directly analogous to the corresponding domains in microsomal cytochrome b(5) (cb5) and cytochrome b(5) reductase (cb5r), respectively. The full-length fusion protein was purified to homogeneity and demonstrated to contain both heme and FAD prosthetic groups by spectroscopic analyses and MALDI-TOF mass spectrometry. The cb5/cb5r fusion protein was able to utilize both NADPH and NADH as reductants and exhibited both NADPH:ferricyanide (k(cat) = 21.7 s(-1), K(NADPH)(m) = 1 microM. K(FeCN6)(m) = 8 microM) and NADPH:cytochrome c (k(cat) = 8.3 s(-1), K(NADPH)(m) = 1 microM. K(cyt c)(m) = 7 microM) reductase activities with a preference for NADPH as the reduced pyridine nucleotide substrate. NADPH-reduction was stereospecific for transfer of the 4R-proton and involved a hydride transfer mechanism with a kinetic isotope effect of 3.1 for NADPH/NADPD. Site-directed mutagenesis was used to examine the role of two conserved histidine residues, H62 and H85, in the heme domain segment. Substitution of either residue by alanine or methionine resulted in the production of simple flavoproteins that were effectively devoid of both heme and NAD(P)H:cytochrome c reductase activity while retaining NAD(P)H:ferricyanide activity, confirming that the former activity required a functional heme domain. These results have demonstrated that the rat cb5/cb5r fusion protein is homologous to the human variant and has identified the heme and FAD as the sites of interaction with cytochrome c and ferricyanide, respectively. Mutagenesis has confirmed the identity of both axial heme ligands which are equivalent to the corresponding residues in microsomal cytochrome b(5).     

Solution structure and dynamics of the reduced and oxidized forms of the N-terminal domain of PilB from Neisseria meningitidis

The secreted form of the PilB protein was proposed to be involved in pathogen survival fighting against the defensive host's oxidative burst. PilB protein is composed of three domains. The central and the C-terminal domains display methionine sulfoxide reductase A and B activities, respectively. The N-terminal domain, which possesses a CXXC motif, was recently shown to regenerate in vitro the reduced forms of the methionine sulfoxide reductase domains of PilB from their oxidized forms, as does the thioredoxin 1 from E. coli, via a disulfide bond exchange. The thioredoxin-like N-terminal domain belongs to the cytochrome maturation protein structural family, but it possesses a unique additional segment (99)FLHE (102) localized in a loop. This segment covers one edge of the active site in the crystal structure of the reduced form of the N-terminal domain of PilB. We have determined the solution structure and the dynamics of the N-terminal domain from Neisseria meningitidis, in its reduced and oxidized forms. The FLHE loop adopts, in both redox states, a well-defined conformation. Subtle conformational and dynamic changes upon oxidation are highlighted around the active site, as well as in the FLHE loop. The functional consequences of the cytochrome maturation protein topology and those of the presence of FLHE loop are discussed in relation to the enzymatic properties of the N-terminal domain.     

Structure of a novel c7-type three-heme cytochrome domain from a multidomain cytochrome c polymer

The structure of a novel c(7)-type cytochrome domain that has two bishistidine coordinated hemes and one heme with histidine, methionine coordination (where the sixth ligand is a methionine residue) was determined at 1.7 A resolution. This domain is a representative of domains that form three polymers encoded by the Geobacter sulfurreducens genome. Two of these polymers consist of four and one protein of nine c(7)-type domains with a total of 12 and 27 hemes, respectively. Four individual domains (termed A, B, C, and D) from one such multiheme cytochrome c (ORF03300) were cloned and expressed in Escherichia coli. The domain C produced diffraction quality crystals from 2.4 M sodium malonate (pH 7). The structure was solved by MAD method and refined to an R-factor of 19.5% and R-free of 21.8%. Unlike the two c(7) molecules with known structures, one from G. sulfurreducens (PpcA) and one from Desulfuromonas acetoxidans where all three hemes are bishistidine coordinated, this domain contains a heme which is coordinated by a methionine and a histidine residue. As a result, the corresponding heme could have a higher potential than the other two hemes. The apparent midpoint reduction potential, E(app), of domain C is -105 mV, 50 mV higher than that of PpcA.     

Transient protein interactions studied by NMR spectroscopy: the case of cytochrome C and adrenodoxin

The interaction between yeast iso-1-cytochrome c (C102T) and two forms of bovine adrenodoxin, the wild type and a truncated form comprising residues 4-108, has been investigated using a combination of one- and two-dimensional heteronuclear NMR spectroscopy. Chemical shift perturbations and line broadening of amide resonances in the [(15)N,(1)H]HSQC spectrum for both (15)N-labeled cytochrome c and adrenodoxin in the presence of the unlabeled partner protein indicate the formation of a transient complex, with a K(a) of (4 +/- 1) x 10(4) M(-)(1) and a lifetime of <3 ms. The perturbed residues map over a large surface area for both proteins. For cytochrome c, the dominating effects are located around the exposed heme edge but with other areas also affected upon formation of the complex. In the case of adrenodoxin, effects are seen in both the recognition and core domains, with the largest perturbations in the recognition domain. These results indicate that the complex has a dynamic nature, with delocalized binding of cytochrome c on adrenodoxin. A comparison with other transient complexes of redox proteins places this complex between well-defined complexes such as the cytochrome c-cytochrome c peroxidase complex and entirely dynamic complexes such as the cytochrome b(5)-myoglobin complex.     

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.     

Structural Evidence for the Functional Importance of the Heme Domain Mobility in Flavocytochrome b2

Yeast flavocytochrome b₂ (Fcb2) is an l-lactate:cytochrome c oxidoreductase in the mitochondrial intermembrane space participating in cellular respiration. Each enzyme subunit consists of a cytochrome b₅-like heme domain and a flavodehydrogenase (FDH) domain. In the Fcb2 crystal structure, the heme domain is mobile relative to the tetrameric FDH core in one out of two subunits. The monoclonal antibody B2B4, elicited against the holoenzyme, recognizes only the native heme domain in the holoenzyme. When bound, it suppresses the intramolecular electron transfer from flavin to heme b₂, hence cytochrome c reduction. We report here the crystal structure of the heme domain in complex with the Fab at 2.7 Å resolution. The Fab epitope on the heme domain includes the two exposed propionate groups of the heme, which are hidden in the interface between the domains in the complete subunit. The structure discloses an unexpected plasticity of Fcb2 in the neighborhood of the heme cavity, in which the heme has rotated. The epitope overlaps with the docking area of the FDH domain onto the heme domain, indicating that the antibody displaces the heme domain in a movement of large amplitude. We suggest that the binding sites on the heme domain of cytochrome c and of the FDH domain also overlap and therefore that cytochrome c binding also requires the heme domain to move away from the FDH domain, so as to allow electron transfer between the two hemes. Based on this hypothesis, we propose a possible model of the Fcb2·cytochrome c complex. Interestingly, this model shares similarity with that of the cytochrome b₅·cytochrome c complex, in which cytochrome c binds to the surface around the exposed heme edge of cytochrome b₅. The present results therefore support the idea that the heme domain mobility is an inherent component of the Fcb2 functioning.     

Heme ligation and conformational plasticity in the isolated c domain of cytochrome cd1 nitrite reductase

The heme ligation in the isolated c domain of Paracoccus pantotrophus cytochrome cd(1) nitrite reductase has been characterized in both oxidation states in solution by NMR spectroscopy. In the reduced form, the heme ligands are His69-Met106, and the tertiary structure around the c heme is similar to that found in reduced crystals of intact cytochrome cd1 nitrite reductase. In the oxidized state, however, the structure of the isolated c domain is different from the structure seen in oxidized crystals of intact cytochrome cd1, where the c heme ligands are His69-His17. An equilibrium mixture of heme ligands is present in isolated oxidized c domain. Two-dimensional exchange NMR spectroscopy shows that the dominant species has His69-Met106 ligation, similar to reduced c domains. This form is in equilibrium with a high-spin form in which Met106 has left the heme iron. Melting studies show that the midpoint of unfolding of the isolated c domain is 320.9 +/- 1.2 K in the oxidized and 357.7 +/- 0.6 K in the reduced form. The thermally denatured forms are high-spin in both oxidation states. The results reveal how redox changes modulate conformational plasticity around the c heme and show the first key steps in the mechanism that lead to ligand switching in the holoenzyme. This process is not solely a function of the properties of the c domain. The role of the d1 heme in guiding His17 to the c heme in the oxidized holoenzyme is discussed.     

X-ray crystal structure of the trimeric N-terminal domain of gephyrin

Gephyrin is a ubiquitously expressed protein that, in the central nervous system, forms a submembraneous scaffold for anchoring inhibitory neurotransmitter receptors in the postsynaptic membrane. The N- and C-terminal domains of gephyrin are homologous to the Escherichia coli enzymes MogA and MoeA, respectively, both of which are involved in molybdenum cofactor biosynthesis. This enzymatic pathway is highly conserved from bacteria to mammals, as underlined by the ability of gephyrin to rescue molybdenum cofactor deficiencies in different organisms. Here we report the x-ray crystal structure of the N-terminal domain (amino acids 2-188) of rat gephyrin at 1.9-A resolution. Gephyrin-(2-188) forms trimers in solution, and a sequence motif thought to be involved in molybdopterin binding is highly conserved between gephyrin and the E. coli protein. The atomic structure of gephyrin-(2-188) resembles MogA, albeit with two major differences. The path of the C-terminal ends of gephyrin-(2-188) indicates that the central and C-terminal domains, absent in this structure, should follow a similar 3-fold arrangement as the N-terminal region. In addition, a central beta-hairpin loop found in MogA is lacking in gephyrin-(2-188). Despite these differences, both structures show a high degree of surface charge conservation, which is consistent with their common catalytic function.     

PQQ glucose dehydrogenase with novel electron transfer ability

PQQ glucose dehydrogenase from Acinetobacter calcoaceticus (GDH-B) is one of the most industrially attractive enzymes, as a sensor constituent for glucose sensing, because of its high catalytic activity and insensitivity to oxygen. We attempted to engineer GDH-B to enable electron transfer to the electrode in the absence of artificial electron mediator by mimicking the domain structure of the quinohemoprotein ethanol dehydrogenase (QH-EDH) from Comamonas testosteroni, which is composed of a PQQ-containing catalytic domain and a cytochrome c domain. We genetically fused the cytochrome c domain of QH-EDH to the C-terminal of GDH-B. The constructed fusion protein showed not only intra-molecular electron transfer, between PQQ and heme of the cytochrome c domain, but also electron transfer from heme to the electrode, thereby allowing the construction of a direct electron transfer-type glucose sensor.     

Structure of a novel dodecaheme cytochrome c from Geobacter sulfurreducens reveals an extended 12 nm protein with interacting hemes

Multiheme cytochromes c are important in electron transfer pathways in reduction of both soluble and insoluble Fe(III) by Geobacter sulfurreducens. We determined the crystal structure at 3.2? resolution of the first dodecaheme cytochrome c (GSU1996) along with its N-terminal and C-terminal hexaheme fragments at 2.6 and 2.15? resolution, respectively. The macroscopic reduction potentials of the full-length protein and its fragments were measured. The sequence of GSU1996 can be divided into four c(7)-type domains (A, B, C and D) with homology to triheme cytochromes c(7). In cytochromes c(7) all three hemes are bis-His coordinated, whereas in c(7)-type domains the last heme is His-Met coordinated. The full-length GSU1996 has a 12nm long crescent shaped structure with the 12 hemes arranged along a polypeptide to form a "nanowire" of hemes; it has a modular structure. Surprisingly, while the C-terminal half of the protein consists of two separate c(7)-type domains (C and D) connected by a small linker, the N-terminal half of the protein has two c(7)-type domains (A and B) that form one structural unit. This is also observed in the AB fragment. There is an unexpected interaction between the hemes at the interface of domains A and B, which form a heme-pair with nearly parallel stacking of their porphyrin rings. The hemes adjacent to each other throughout the protein are within van der Waals distance which enables efficient electron exchange between them. For the first time, the structural details of c(7)-type domains from one multiheme protein were compared.