Role of Tyr residues on the protein surface of cationic cell-wall-peroxidase (CWPO-C) from poplar: potential oxidation sites for oxidative polymerization of lignin

It was previously reported that an unique peroxidase isoenzyme, cationic cell-wall-bound peroxidase (CWPO-C), from poplar callus oxidizes sinapyl alcohol, ferrocytochrome c and synthetic lignin polymers, unlike other plant peroxidases. Here, the catalytic mechanism of CWPO-C was investigated using chemical modification and homology modeling. The simulated CWPO-C structure predicts that the entrance to the heme pocket of CWPO-C is the same size as those of other plant peroxidases, suggesting that ferrocytochrome c and synthetic lignin polymers cannot interact with the heme of CWPO-C. Since Trp and Tyr residues are redox-active, such residues located on the protein surface were predicted to be active sites for CWPO-C. Modification of CWPO-C Trp residues did not suppress its oxidation activities toward guaiacol and syringaldazine. On the other hand, modification of CWPO-C Tyr residues using tetranitromethane strongly suppressed its oxidation activities toward syringaldazine and 2,6-dimethoxyphenol by 90%, respectively, and also suppressed its guaiacol oxidation activity to a lesser extent. Ferrocytochrome c was not oxidized by Tyr-modified CWPO-C. These results indicate that the Tyr residues in CWPO-C mediate its oxidation of syringyl compounds and high-molecular-weight substrates. Homology modeling indicates that Tyr-177 and Tyr-74 are located near the heme and exposed on the protein surface of CWPO-C. These results suggest that Tyr residues on the protein surface are considered to be important for the oxidation activities of CWPO-C with a wide range of substrates, and potentially unique oxidation sites for the plant peroxidase family.     

Identification of Tyr74 and Tyr177 as substrate oxidation sites in cationic cell wall-bound peroxidase from Populus alba L

Cationic cell wall-bound peroxidase (CWPO-C) has the capability to oxidize sinapyl alcohol, ferrocytochrome c, and synthetic lignin polymers, unlike most peroxidases that have been characterized in flowering plants, such as horseradish peroxidase and Arabidopsis thaliana peroxidase A2. It has been suggested that the oxidation site is located on the CWPO-C surface, and homology modeling and chemically modified CWPO-C studies suggest that Tyr74 and/or Tyr177 are possible participants in the catalytic site. The present study clarifies the importance of these Tyr residues for substrate oxidation, using recombinant CWPO-C and recombinant mutant CWPO-C with phenylalanine substitution(s) for tyrosine. Such recombinant proteins, produced in Escherichia coli as inclusion bodies, were successfully refolded to yield the active form, and purified recombinant protein solutions exhibited typical spectra of high-spin ferric protein and displayed H(2) O(2) -dependent oxidation of guaiacol, 2,6-dimethoxyphenol, and syringaldazine. Measurement of peroxidase activity with these guaiacyl and syringyl compounds as reducing substrates indicated that a single mutation, Y74F or Y177F, resulted in substantial loss of oxidation activity (～ 40-60% and 82%, respectively). Also, over 95% of the oxidation activity was lost with a double mutation, Y74F/Y177F. These results indicated that Tyr74 and Tyr177, rather than the heme pocket, play a central role in the oxidation of these substrates. This is the first report of active residues on an enzyme surface being identified in a plant peroxidase. This study also suggests that sinapyl alcohol incorporation into lignin is performed by a peroxidase that generates Tyr radicals on its surface.     

Ascorbate inhibits the carbethoxylation of two histidyl and one tyrosyl residues indispensable for the transmembrane electron transfer reaction of cytochrome b561

Cytochrome b(561) from bovine adrenal chromaffin vesicles contains two heme B prosthetic groups and transports electron equivalents across the vesicle membranes to convert intravesicular monodehydroascorbate radical to ascorbate. We found previously that treatment of oxidized cytochrome b(561) with diethyl pyrocarbonate caused specific N-carbethoxylation of three fully conserved residues (His88, His161, and Lys85) located at the extravesicular side. The modification lead to a selective loss of the electron-accepting ability from ascorbate without affecting the electron donation to monodehydroascorbate radical [Tsubaki, M., Kobayashi, K., Ichise, T., Takeuchi, F., and Tagawa, S. (2000) Biochemistry 39, 3276-3284]. In the present study, we found that these modifications lead to a drastic decrease of the midpoint potential of heme b at the extravesicular side from +60 to -30 mV. We found further that the O-carbethoxylation of one tyrosyl residue (Tyr218) located at the extravesicular side was significantly enhanced under alkaline conditions, leading to a very slow reduction process of the oxidized heme b with ascorbate. On the other hand, the presence of ascorbate during the treatment with diethyl pyrocarbonate was found to suppress the carbethoxylation of His88, His161, and Tyr218, whereas the modification level of Lys85 was not affected. Concomitantly, the final reduction level of heme b with ascorbate was protected, although the fast reduction phase was not fully restored. These results suggest that the two heme-coordinating histidyl residues (His88 and His161) are also a part of the ascorbate binding site. Tyr218 and Lys85 may have a role in the recognition/binding process for ascorbate and are indispensable for the fast electron transfer reaction.     

C21 steroid side chain cleavage enzyme from porcine adrenal microsomes. Purification and characterization of the 17 alpha-hydroxylase/C17,20-lyase cytochrome P-450

The properties and the purity of a cytochrome P-450 (17 alpha-hydroxylase) from porcine adrenal microsomes have been examined following a report that the corresponding enzyme from bovine adrenocortical microsomes is inactive as a 17 alpha-hydroxylase and fails to show a high spin spectrum on addition of substrate, once the enzyme has been purified (Bumpus, J. A., and Dus, K. M. (1982) J. Biol. Chem. 257, 12696-12704). The purity of the porcine enzyme was demonstrated by electrophoresis on polyacrylamide with sodium dodecyl sulfate, immunoelectrophoresis, and NH2-terminal amino acid sequence (16 residues). The pure enzyme shows Mr = 54,000, heme content of greater than 0.8 nmol/nmol of protein, and absorption spectra typical of cytochrome P-450. The enzyme is active with both delta 4 (progesterone) and delta 5 (pregnenolone) substrates as a 17 alpha-hydroxylase and with the corresponding 17 alpha-hydroxysteroids as a C17,20-lyase. All four substrates produce typical type I spectra with the enzyme (so-called high spin form). We conclude that: 1) porcine adrenal microsomes contain a 17 alpha-hydroxylase/C17,20-lyase which is a single protein molecule readily purified to an enzymatically active form; 2) the C17,20-lyase activity is largely suppressed in the microsomes; and 3) the enzyme closely resembles that found in testicular microsomes. We propose that this enzyme be referred to as the adrenal C21 steroid side chain cleavage enzyme.     

Spectroscopic and biochemical characterization of heme binding to yeast Dap1p and mouse PGRMC1p

Yeast damage-associated response protein (Dap1p) and mouse progesterone receptor membrane component-1 protein (mPGRMC1p) belong to a highly conserved class of putative membrane-associated progesterone binding proteins (MAPR), with Dap1p and inner zone antigen (IZA), the rat homologue of mPGRMC1p, recently being reported to bind heme. While primary structure analysis reveals similarities to the cytochrome b(5) motif, neither of the two axial histidines responsible for ligation to the heme is present in any of the MAPR proteins. In this paper, EPR, MCD, CD, UV-vis, and general biochemical methods have been used to characterize the nature of heme binding in both Dap1p and a His-tagged, membrane anchor-truncated mPGRMC1p. As isolated, Dap1p is a tetramer which can be converted to a dimer upon addition of 150 mM salt. The heme is noncovalently attached, with a maximal, in vitro, heme loading of approximately 30%, for both proteins. CD and fluorescence spectroscopies indicate a well-ordered structure, suggesting the low level of heme loading is probably not due to improperly folded protein. EPR confirmed a five-coordinate, high-spin, ferric resting state for both proteins, indicating one axial amino acid ligand, in contrast to the six-coordinate, low-spin, ferric state of cytochrome b(5). The MCD spectrum confirmed this conclusion for Dap1p and indicated the axial ligand is most likely a tyrosine and not a histidine, or a cysteine; however, an aspartic acid residue could not be conclusively ruled out. Potential axial ligands, which are conserved in all MAPRs, were mutated (Y78F, D118A, and Y138F) and purified to homogeneity. The Y78F and D118A mutants were found to bind heme; however, Y138F did not. This result is consistent with the MCD data and indicates that Tyr138 is most likely the axial ligand to the heme in Dap1p.     

Autophosphorylation of heme-regulated eukaryotic initiation factor 2α kinase and the role of the modification in catalysis

Heme-regulated eukaryotic initiation factor 2α (eIF2α) kinase (HRI), functions in response to heme shortage in reticulocytes and aids in the maintenance of a heme:globin ratio of 1:1. Under normal conditions, heme binds to HRI and blocks its function. However, during heme shortage, heme dissociates from the protein and autophosphorylation subsequently occurs. Autophosphorylation comprises a preliminary critical step before the execution of the intrinsic function of HRI; specifically, phosphorylation of Ser-51 of eIF2α to inhibit translation of the globin protein. The present study indicates that dephosphorylated mouse HRI exhibits strong intramolecular interactions (between the N-terminal and C-terminal domains) compared to phosphorylated HRI. It is therefore suggested that autophosphorylation reduces the intramolecular interaction, which induces irreversible catalytic flow to the intrinsic eIF2α kinase activity after heme dissociates from the protein. With the aid of MS, we identified 33 phosphorylated sites in mouse HRI overexpressed in Escherichia coli. Phosphorylated sites at Ser, Thr and Tyr were predominantly localized within the kinase insertion region (16 sites) and kinase domain (12 sites), whereas the N-terminal domain contained five sites. We further generated 30 enzymes with mutations at the phosphorylated residues and examined their catalytic activities. The activities of Y193F, T485A and T490A mutants were significantly lower than that of wild-type protein, whereas the other mutant proteins displayed essentially similar activity. Accordingly, we suggest that Tyr193, Thr485 and Thr490 are essential residues in the catalysis.     

Diethyl pyrocarbonate modification abolishes fast electron accepting ability of cytochrome b561 from ascorbate but does not influence electron donation to monodehydroascorbate radical: identification of the modification sites by mass spectrometric analysis

Cytochrome b(561) from bovine adrenal chromaffin vesicles contains two heme B prosthetic groups and transports electron equivalents across the vesicle membranes to convert intravesicular monodehydroascorbate radical to ascorbate. To elucidate the mechanism of the transmembrane electron transfer, effects of the treatment of purified cytochrome b(561) with diethyl pyrocarbonate, a reagent specific for histidyl residues, were examined. We found that when ascorbate was added to the oxidized form of diethyl pyrocarbonate-treated cytochrome b(561), less than half of the heme iron was reduced but with a very slow rate. In contrast, radiolytically generated monodehydroascorbate radical was oxidized rapidly by the reduced form of diethyl pyrocarbonate-modified cytochrome b(561), as observed for untreated cytochrome b(561). These results indicate that the heme center specific for the electron acceptance from ascorbate was perturbed by the modification of amino acid residues nearby. We identified the major modification sites by mass spectrometry as Lys85, His88, and His161, all of which are fully conserved and located on the extravesicular side of cytochrome b(561) in the membranes. We suggest that specific N-carbethoxylation of the histidyl ligands of the heme b at extravesicular side abolishes the electron-accepting ability from ascorbate.     

Time-resolved resonance Raman study on ultrafast structural relaxation and vibrational cooling of photodissociated carbonmonoxy myoglobin

A localized small structural change is converted to a higher order conformational change of protein and extends to a mesoscopic scale to induce a physiological function. To understand such features of protein, ultrafast dynamics of myoglobin (Mb) following photolysis of carbon monoxide were investigated. Recent results are summarized here with a stress on structural and vibrational energy relaxation. The core expansion of heme takes place within 2 ps but the out of plane displacement of the heme iron and the accompanying protein conformational change occur in 10 and 100 s of the picosecond regimes, respectively. Unexpectedly, it was found from UV resonance Raman spectra that Trp7 in the N-terminal region and Tyr151 in the C-terminal region undergo appreciable structural changes upon ligand binding-dissociation while Tyr104, Tyr146, and Trp14 do not. Because of the communication between the movements of these surface residues and the heme iron, the rate of spectral change of the iron-histidine (Fe- His) stretching band after CO photodissociation is influenced by the viscosity of solvent. Temporal changes of the anti-Stokes Raman intensity demonstrated immediate generation of vibrationally excited heme upon photodissociation and its decay with a time constant of 1-2 ps.     

Structural heterogeneity and ligand gating in ferric Methanosarcina acetivorans protoglobin mutants

Protoglobin from Methanosarcina acetivorans C2A (MaPgb), a strictly anaerobic methanogenic Archaea, displays peculiar structural and functional properties within members of the hemoglobin superfamily. In fact, MaPgb-specific loops and a N-terminal extension (20 amino acid residues) completely bury the heme within the protein matrix. Therefore, the access of diatomic gaseous molecules to the heme is granted by two apolar tunnels reaching the heme distal site from locations at the B/G and B/E helix interfaces. The presence of two tunnels within the protein matrix could be partly responsible for the slightly biphasic ligand binding behavior. Unusually, MaPgb oxygenation is favored with respect to carbonylation. Here, the crucial role of Tyr(B10)61 and Ile(G11)149 residues, located in the heme distal site and lining the protein matrix tunnels 1 and 2, respectively, on ligand binding to the heme-Fe-atom and on distal site structural organization is reported. In particular, tunnel 1 accessibility is modulated by a complex reorganization of the Trp(B9)60 and Phe(E11)93 side-chains, triggered by mutations of the Tyr(B10)61 and Ile(G11)149 residues, and affected by the presence and type of the distal heme-bound ligand.     

Identification of two heme-binding sites in the cytoplasmic heme-trafficking protein PhuS from Pseudomonas aeruginosa and their relevance to function

PhuS is a cytoplasmic, 39 kDa heme-binding protein from Pseudomonas aeruginosa. It has previously been shown to transfer heme to its cognate heme oxygenase. It is expressed from the phu operon, which encodes a group of proteins known to actively internalize and transport heme from host organisms. This study combines the spectral resolution of resonance Raman spectroscopy with site-directed mutagenesis to identify and characterize the heme-bound states of holo-PhuS. This combined approach has identified a site in monomeric PhuS having alternate His ligands at positions 209 and 212. A second distinct binding site is present in dimeric PhuS. This site supports six-coordinate, low-spin heme, even when both His209 and His212 are mutated to Ala. The presence of conserved His and Tyr residues in all of the homologs characterized to date suggest that the dimer could be of the domain-swapped type in which two protein molecules are cross-linked by bound heme. The multiple heme-bound states and their sensitivity to pH suggest the possibility that these cytoplasmic heme-binding proteins have multiple functions that are toggled by variations in intracellular conditions.     

Roles of noncoordinated aromatic residues in redox regulation of cytochrome c3 from Desulfovibrio vulgaris Miyazaki F

The roles of aromatic residues in redox regulation of cytochrome c(3) were investigated by site-directed mutagenesis at every aromatic residue except for axial ligands (Phe20, Tyr43, Tyr65, Tyr66, His67, and Phe76). The mutations at Phe20 induced large chemical shift changes in the NMR signals for hemes 1 and 3, and large changes in the microscopic redox potentials of hemes 1 and 3. The NMR signals of the axial ligands of hemes 1 and 3 were also affected. Analysis of the nature of the mutations revealed that a hydrophobic environment and aromaticity are important for the reduction of the redox potentials of hemes 1 and 3, respectively. There was also a global effect. The replacement of Tyr66 with leucine induced chemical shift changes for heme 4, and changes in the microscopic redox potentials of heme 4. The mutations of Tyr65 induced changes in the chemical shifts and microscopic redox potentials for every heme, suggesting that Tyr65 stabilizes the global conformation, thereby reducing the redox potentials. In contrast, although the mutations of His67 and Phe76 caused chemical shift changes for heme 2, they did not affect its redox potentials, showing these residues are not important. All noncoordinated aromatic residues conserved in the cytochrome c(3) subfamily with heme binding motifs CXXCH, CXXXXCH, CXXCH, and CXXXXCH (Phe20, Tyr43, and Tyr66) are involved in the pi-pi interaction, which causes a decrease in the redox potential of the interacting heme. The global effect can be attributed to either direct or indirect interactions among the four hemes in the cyclic architecture.     

Identification of HPV-16 E7 peptides that are potent antagonists of E7 binding to the retinoblastoma suppressor protein

Complex formation between the human papilloma virus type-16 E7 protein (HPV-16 E7) and the retinoblastoma suppressor protein (pRB) is believed to be important in the process of cellular transformation that leads to cervical carcinoma. Utilizing an in vitro solution assay as well as a plate binding assay that measures the association between HPV-16 E7 and pRB proteins, we have examined a series of synthetic HPV-16 E7 peptides. HPV-16 E7 peptides which lie between amino acid residues 14 and 32 were found to be potent inhibitors of E7/pRB binding. The minimal peptide structure that possessed full antagonist activity was N-acetyl-E7-(21-29)-peptide amide. This peptide inhibited 100% of E7/pRB binding and exhibited an IC50 of 40 nM in the plate binding assay. A purified beta-galactosidase-E7 fusion protein exhibited an IC50 of 2 nM in the same assay. These results suggest that other regions of the E7 molecule in addition to amino acids 21-29 may contributed to E7/pRB interaction. Analysis of E7-(20-29)-peptides containing single amino acid substitutions suggests that Cys24, Tyr23, Tyr25, Asp21, and Glu26 are important residues for maintaining maximal antagonist activity. This series of peptides should prove useful in analyzing the biological consequences of E7/pRB binding in HPV-infected cells.     

Iron-coordinating tyrosine is a key determinant of NEAT domain heme transfer

In humans, heme iron is the most abundant iron source, and bacterial pathogens such as Staphylococcus aureus acquire it for growth. IsdB of S. aureus acquires Fe(III)-protoporphyrin IX (heme) from hemoglobin for transfer to IsdC via IsdA. These three cell-wall-anchored Isd (iron-regulated surface determinant) proteins contain conserved NEAT (near iron transport) domains. The purpose of this work was to delineate the mechanism of heme binding and transfer between the NEAT domains of IsdA, IsdB, and IsdC using a combination of structural and spectroscopic studies. X-ray crystal structures of IsdA NEAT domain (IsdA-N1) variants reveal that removing the native heme-iron ligand Tyr166 is compensated for by iron coordination by His83 on the distal side and that no single mutation of distal loop residues is sufficient to perturb the IsdA-heme complex. Also, alternate heme-iron coordination was observed in structures of IsdA-N1 bound to reduced Fe(II)-protoporphyrin IX and Co(III)-protoporphyrin IX. The IsdA-N1 structural data were correlated with heme transfer kinetics from the NEAT domains of IsdB and IsdC. We demonstrated that the NEAT domains transfer heme at rates comparable to full-length proteins. The second-order rate constant for heme transfer from IsdA-N1 was modestly affected (< 2-fold) by the IsdA variants, excluding those at Tyr166. Substituting Tyr166 with Ala or Phe changed the reaction mechanism to one with two observable steps and decreased observed rates > 15-fold (to 100-fold excess IsdC). We propose a heme transfer model wherein NEAT domain complexes pass heme iron directly from an iron-coordinating Tyr of the donor protein to the homologous Tyr residues of the acceptor protein.     

Purification and properties of 17 alpha-hydroxylase from microsomes of pig adrenal: a second C21 side-chain cleavage system

We have purified a cytochrome P-450 from microsomes of pig adrenal glands to homogeneity (11.1 n moles heme/mg protein) as demonstrated by electrophoresis on polyacrylamide gels with sodium dodecyl SO4 and by line of identity with an antibody using double diffusion. The enzyme shows both 17 alpha-hydroxylase and C17,20-lyase activities and therefore constitutes a C21 side-chain cleavage system like that previously purified in this laboratory from neonatal pig testis. Antibody to the testicular enzyme cross-reacts (line of identity) with both enzymes. It is concluded that the adrenal enzyme is the same or very similar to the testicular enzyme, that each enzyme possesses two enzymatic activities, and that microsomes provide some regulatory device to limit the lyase activity of the enzyme in vivo. No evidence was found for the usually accepted existence of an adrenal steroid 17 alpha-hydroxylase without lyase activity.     

A novel heme and peroxide-dependent tryptophan-tyrosine cross-link in a mutant of cytochrome c peroxidase

The crystal structure of a cytochrome c peroxidase mutant where the distal catalytic His52 is converted to Tyr reveals that the tyrosine side-chain forms a covalent bond with the indole ring nitrogen atom of Trp51. We hypothesize that this novel bond results from peroxide activation by the heme iron followed by oxidation of Trp51 and Tyr52. This hypothesis has been tested by incorporation of a redox-inactive Zn-protoporphyrin into the protein, and the resulting crystal structure shows the absence of a Trp51-Tyr52 cross-link. Instead, the Tyr52 side-chain orients away from the heme active-site pocket, which requires a substantial rearrangement of residues 72-80 and 134-144. Additional experiments where heme-containing crystals of the mutant were treated with peroxide support our hypothesis that this novel Trp-Tyr cross-link is a peroxide-dependent process mediated by the heme iron.     

Characterization of the periplasmic heme-binding protein shut from the heme uptake system of Shigella dysenteriae

The heme uptake systems by which bacterial pathogens acquire and utilize heme have recently been described. Such systems may utilize heme directly from the host's hemeproteins or via a hemophore that sequesters and transports heme to an outer membrane receptor and subsequently to the translocating proteins by which heme is further transported into the cell. However, little is known of the heme binding and release mechanisms that facilitate the uptake of heme into the pathogenic organism. As a first step toward elucidating the molecular level events that drive heme binding and release, we have undertaken a spectroscopic and mutational study of the first purified periplasmic heme-binding protein (PBP), ShuT from Shigella dysenteriae. On the basis of sequence identity, the ShuT protein is most closely related to the class of PBPs typified by the vitamin B(12) (BtuF) and iron-hydroxamate (FhuD) PBPs and is a monomeric protein having a molecular mass of 28.5 kDa following proteolytic processing of the periplasmic signaling peptide. ShuT binds one b-type heme per monomer with high affinity and bears no significant homology with other known heme proteins. The resonance Raman, MCD, and UV-visible spectra of WT heme-ShuT are consistent with a five-coordinate high spin heme having an anionic O-bound proximal ligand. Site-directed ShuT mutants of the absolutely conserved Tyr residues, Tyr-94 (Y94A) and Tyr-228 (Y228F), which are found in all putative periplasmic heme-binding proteins, were subjected to UV-visible, resonance Raman, and MCD spectroscopic investigations of heme coordination environment and rates of heme release. The results of these experiments confirmed Tyr-94 as the only axial heme ligand and Tyr-228 as making a significant contribution to the stability of heme-loaded ShuT, albeit without directly interacting with the heme iron.     

枯草菌HemAT蛋白质结合配基O2的构象变化——紫外共振拉曼光谱研究

枯草菌HemAT蛋白质是新近发现的一种基于血红素的趋氧性同型二聚体蛋白质。作者对此蛋白质进行了表达和提纯。用紫外共振拉曼光谱研究了全分子和传感域HemAT在与配基O2结合时的构象变化。发现O2配基与HemAT蛋白质的结合使传感域中Trp和Tyr的环境发生变化,而对连接域中Tyr的环境影响可忽略不计。信号发送域对O2配基引起的Trp和Tyr的环境变化不产生影响。O2配基与HemAT蛋白质的结合使得G-螺旋发生位移,传感域与信号发送域通过某种互感方式把O2结合信号从传感域传递到信号发送域。     

Characterization of heme ligation properties of Rv0203, a secreted heme binding protein involved in Mycobacterium tuberculosis heme uptake

The secreted Mycobacterium tuberculosis (Mtb) heme binding protein Rv0203 has been shown to play a role in Mtb heme uptake. In this work, we use spectroscopic (absorption, electron paramagnetic resonance, and magnetic circular dichrosim) methods to further characterize the heme coordination environments of His-tagged and native protein forms, Rv0203-His and Rv0203-notag, respectively. Rv0203-His binds the heme molecule through bis-His coordination and is low-spin in both ferric and ferrous oxidation states. Rv0203-notag is high-spin in both oxidation states and shares spectroscopic similarity with pentacoordinate oxygen-ligated heme proteins. Mutagenesis experiments determined that residues Tyr59, His63, and His89 are required for Rv0203-notag to efficiently bind heme, reinforcing the hypothesis based on our previous structural and mutagenesis studies of Rv0203-His. While Tyr59, His63, and His89 are required for the binding of heme to Rv0203-notag, comparison of the absorption spectra of the Rv0203-notag mutants suggests the heme ligand may be the hydroxyl group of Tyr59, although an exogenous hydroxide cannot be ruled out. Additionally, we measured the heme affinities of Rv0203-His and Rv0203-notag using stopped flow techniques. The rates for binding of heme to Rv0203-His and Rv0203-notag are similar, 115 and 133 μM(-1) s(-1), respectively. However, the heme off rates differ quite dramatically, whereby Rv0203-His gives biphasic dissociation kinetics with fast and slow rates of 0.0019 and 0.0002 s(-1), respectively, and Rv0203-notag has a single off rate of 0.082 s(-1). The spectral and heme binding affinity differences between Rv0203-His and Rv0203-notag suggest that the His tag interferes with heme binding. Furthermore, these results imply that the His tag has the ability to stabilize heme binding as well as alter heme ligand coordination of Rv0203 by providing an unnatural histidine ligand. Moreover, the heme affinity of Rv0203-notag is comparable to that of other heme transport proteins, implying that Rv0203 may act as an extracellular heme transporter.     

Semisynthetic analogs of cytochrome c reconstructed from natural and synthetic peptides.

A biologically active semisynthetic hybrid of horse heart cytochrome c has been prepared by combining the heme peptide 1 through 65 (HP 1-65), prepared by CNBr cleavage of natural cytochrome c, with a semisynthetic peptide corresponding to positions 66 through 104. A fully protected synthetic peptide 66--79 was prepared by a modified solid phase peptide synthesis procedure and was converted to its N-hydroxysuccinimide ester. A peptide corresponding to residues 81--104 of cytochrome c was also isolated from the CNBr cleavage mixture and its epsilon-amino groups and tyrosyl hydroxyl group were protected selectively with the t-butyloxycarbonyl group. This partially protected peptide was reacted with t-butyloxycarbonyl methionine N-hydroxysuccinimide ester to give a derivative having methionine at position 80. This product was deprotected, purified and then t-butyloxycarbonyl groups were again introduced specifically on the epsilon-amino groups to give the peptide, Boc(Lys,Tyr)80--104. A semisynthetic peptide corresponding to residues 66 through 104 of cytochrome c was prepared by condensing the synthetic peptide 66--79 N-hydroxysuccinimide ester with t-butyloxycarbonyl (Lys,Tyr)80--104. The semisynthetic product was deprotected, purified and combined under anaerobic conditions with a heme peptide, HP 1-65, that was isolated from the products of CNBr cleavage of native cytochrome c. The reconstituted semisynthetic cytochrome c was purified by ion exchange chromatography and was shown to have the same oxygen uptake as native cytochrome c when assayed in the succinate oxidase system.     

A novel double heme substitution produces a functional bo3 variant of the quinol oxidase aa3 of Bacillus cereus. Purification and paratial characterization

A novel bo3-type quinol oxidase was highly purified from Bacillus cereus PYM1, a spontaneous mutant unable to synthesize heme A and therefore spectroscopically detectable cytochromes aa3 and caa3. The purified enzyme contained 12.4 nmol of heme O and 11.5 nmol of heme B mg-1 protein. The enzyme was composed of two subunits with an Mr of 51,000 and 30,000, respectively. Both subunits were immunoreactive to antibodies raised against the B cereus aa3 oxidase. Moreover, amino-terminal sequence analysis of the 30-kDa subunit revealed that the first 19 residues were identical to those from the 30-kDa subunit of the B. cereus aa3 oxidase. The purified bo3 oxidase failed to oxidize ferrrocytochrome c (neither yeast nor horse) but oxidized tetrachlorohydroquinol with an apparent Km of 498 microM, a Vmax of 21 micromol of O2 min-1mg-1, and a calculated turnover of 55 s-1. The quinol oxidase activity with tetrachlorohydroquinol was inhibited by potassium cyanide and 2-n-heptyl 4-hydroxyquinoline-N-oxide with an I50 of 24 and 300 microM, respectively. Our results demonstrate that the bo3 oxidase of this mutant is not the product of a new operon but instead is a cytochrome aa3 apoprotein encoded by the qox operon of the aa3 oxidase of B. cereus wild type promiscuously assembled with hemes B and O replacing heme A, producing a novel bo3 cytochrome. This is the first reported example of an enzymatically active promiscuous oxidase resulting from the simultaneous substitution of its original hemes in the high and low spin sites.