cytochrome-c-t and imidazole

Immobilization of enzymes onto metal-organic frameworks (MOFs) through a biomimetic mineralization approach can preserve biological functionality in harsh environments. Despite the success of this approach, the alkaline environment of the reaction system, which is caused by the organic monomers of MOFs, makes it unsuitable for some pH-sensitive enzymes, especially for trypsin. Herein, we reported a facile approach for the one-pot synthesis of trypsin-immobilized magnetic zeolite imidazolate framework-8 (iron oxide@ZIF-8@trypsin), where the growth of ZIF-8 around the citric acid-modified iron oxide and immobilization of trypsin occurred simultaneously when the pH of the reaction system was changed to some extent. With a large specific surface area and a high enzyme loading capacity, the resultant iron oxide@ZIF-8@trypsin exhibited 2.6 times higher enzymatic activity than free trypsin. Moreover, it showed a favourable magnetic response (43 emu g

Topics: Animals; Cattle; Citric Acid; Cytochromes c; Enzymes, Immobilized; Horseradish Peroxidase; Humans; Imidazoles; Magnetic Iron Oxide Nanoparticles; Metal-Organic Frameworks; Particle Size; Proteolysis; Serum Albumin, Bovine; Surface Properties; Trypsin; Zeolites

Quite surprisingly, cisplatin and cis-[PtI

Topics: Amino Acids; Ammonia; Antineoplastic Agents; Cisplatin; Cytochromes c; Imidazoles; Models, Molecular; Muramidase; Organoplatinum Compounds; Protein Binding; Spectrometry, Mass, Electrospray Ionization

The aggregation of α-synuclein (α-Syn) has been implicated strongly in Parkinson's disease (PD). The intrinsically disordered nature of α-Syn makes this protein prone to self-association or heteroassociation with another protein or lipid. While conformational fluctuation and free radical chemistry have been shown to play important roles in its ability toward self- and heteroassociation, any systematic understanding of their contributions is missing. Here, we report an in vitro investigation of the interaction between α-Syn and cytochrome c in the oxidized (cyt c III) and reduced forms (cyt c II), in which cyt c III was found to induce a large compaction of α-Syn and inhibit the aggregation by favoring a hetero-dityrosine bond formation. In contrast, the presence of cyt c II did not result in any compaction and its presence was found to facilitate α-Syn aggregation. The variation in the charge distribution of the surface residues of cyt c III and cyt c II is expected to play a decisive role in their interaction with α-Syn.

Topics: alpha-Synuclein; Cytochromes c; Enzyme Inhibitors; Escherichia coli; Free Radicals; Humans; Imidazoles; Oxidation-Reduction; Protein Aggregation, Pathological; Protein Binding; Recombinant Proteins

Supramolecular receptors such as water-soluble calixarenes are in development as 'molecular glues' for protein assembly. Here, we obtained cocrystals of sulfonato-calix[6]arene (sclx

Topics: Arginine; Binding Sites; Calixarenes; Crystallography, X-Ray; Cytochromes c; Imidazoles; Lysine; Models, Molecular; Protein Unfolding; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins

Met80, one of the heme iron ligands in cytochrome c (cyt c), is readily oxidized to Met sulfoxide (Met-SO) by several biologically relevant oxidants. The modification has been suggested to affect both the electron-transfer (ET) and apoptotic functions of this metalloprotein. The coordination of the heme iron in Met-oxidized cyt c (Met-SO cyt c) is critical for both of these functions but has remained poorly defined. We present electronic absorption, NMR, and EPR spectroscopic investigations as well as kinetic studies and mutational analyses to identify the heme iron ligands in yeast iso-1 Met-SO cyt c. Similar to the alkaline form of native cyt c, Lys73 and Lys79 ligate to the ferric heme iron in the Met80-oxidized protein, but this coordination takes place at much lower pH. The ferrous heme iron is ligated by Met-SO, implying the redox-linked ligand switch in the modified protein. Binding studies with the model peptide microperoxidase-8 provide a rationale for alterations in ligation and for the role of the polypeptide packing in native and Met-SO cyt c. Imidazole binding experiments have revealed that Lys dissociation from the ferric heme in K73A/K79G/M80K (M80K

Topics: Amino Acid Sequence; Binding Sites; Cytochromes c; Electron Spin Resonance Spectroscopy; Heme; Imidazoles; Iron; Ligands; Methionine; Models, Biological; Oxidation-Reduction; Spectrum Analysis, Raman; Sulfoxides; Yeasts

A variety of mitochondria-targeted small molecules have been invented to manipulate mitochondrial redox activities and improve function in certain disease states. 3-Hydroxypropyl-triphenylphosphonium-conjugated imidazole-substituted oleic acid (TPP-IOA) was developed as a specific inhibitor of cytochrome c peroxidase activity that inhibits apoptosis by preventing cardiolipin oxidation and cytochrome c release to the cytosol. Here we evaluate the effects of TPP-IOA on oxidative phosphorylation in isolated mitochondria and on mitochondrial function in live cells. We demonstrate that, at concentrations similar to those required to achieve inhibition of cytochrome c peroxidase activity, TPP-IOA perturbs oxidative phosphorylation in isolated mitochondria. In live SH-SY5Y cells, TPP-IOA partially collapsed mitochondrial membrane potential, caused extensive fragmentation of the mitochondrial network, and decreased apparent mitochondrial abundance within 3h of exposure. Many cultured cell lines rely primarily on aerobic glycolysis, potentially making them less sensitive to small molecules disrupting oxidative phosphorylation. We therefore determined the anti-apoptotic efficacy of TPP-IOA in SH-SY5Y cells growing in glucose or in galactose, the latter of which increases reliance on oxidative phosphorylation for ATP supply. The anti-apoptotic activity of TPP-IOA that was observed in glucose media was not seen in galactose media. It therefore appears that, at concentrations required to inhibit cytochrome c peroxidase activity, TPP-IOA perturbs oxidative phosphorylation. In light of these data it is predicted that potential future therapeutic applications of TPP-IOA will be restricted to highly glycolytic cell types with limited reliance on oxidative phosphorylation.

Topics: Adenosine Triphosphate; Animals; Apoptosis; Cardiolipins; Cell Line, Tumor; Cell Respiration; Cytochromes c; Cytosol; Energy Metabolism; Female; Galactose; Glucose; Humans; Imidazoles; Membrane Potential, Mitochondrial; Mitochondria; Oleic Acid; Oxidation-Reduction; Oxidative Phosphorylation; Rats; Rats, Long-Evans

Immobilized metal affinity chromatography (IMAC) has been widely used for the specific separation of biopolymers. However, leakage of metal ions from IMAC adsorbents is of concern in IMAC. In this study, we designed a novel tridenate bis(5-methyltetrazolium)amine (BMTA) to reduce the leakage of metal ions by improving the affinity to immobilized metal ions. The ligand was bonded onto silica via three-step reaction to prepare a high-performance IMAC stationary phase. The chromatographic behaviors of ribonuclease A, cytochrome c, and lysozyme on the Cu(II)-, Ni(II)-, and Zn(II)-chelated stationary phase were investigated with respect to pH effect and elution with an imidazole gradient. The retention times of these three proteins increased by increasing the pH of the mobile phase but decreased by increasing the concentration of the competitive displacer. The retaining strength of the three proteins on the chelated stationary phase were in the order Cu(II) > Ni(II) > Zn(II). The behavior of these three proteins was consistent with the properties of a typical IMAC. The BMTA ligand exhibited a much stronger affinity for Cu(II) and Ni(II) than iminodiacetic acid (IDA), which is often regarded as a standard tridentate IMAC ligand. Quantum mechanical calculations at the B3LYP/6-31G level were used to image the coordination mode of the protein-metal ions-BMTA complex. In addition, a fused histidine-tagged cecropin b-human epidermal growth factor (CB-EGF) from Escherichia coli crude extract was purified by the Ni(II)-chelated stationary phase, and the purity of the CB-EGF was determined to be at least 90 %. These results suggest that the BMTA ligand may have potential applications in the preparation of therapeutics. Graphical Abstract A novel ligand of tridenate bis(5-methyltetrazolium)amine (BMTA) was designed to reduce the leakage of metal ions from the column in immobolized metal affinity chromatography (IMAC).

Topics: Adsorption; Chromatography, Affinity; Copper; Cytochromes c; Epidermal Growth Factor; Humans; Hydrogen-Ion Concentration; Imidazoles; Imino Acids; Muramidase; Nickel; Quantum Theory; Ribonuclease, Pancreatic; Silicon Dioxide; Tetrazolium Salts; Zinc

The periplasmic heme chaperone holoCcmE is essential for heme trafficking in the cytochrome c biosynthetic pathway in many bacteria, archaea, and plant mitochondria. This pathway, called system I, involves two steps: (i) formation and release of holoCcmE (by the ABC-transporter complex CcmABCD) and (ii) delivery of the heme in holoCcmE to the putative cytochrome c heme lyase complex, CcmFH. CcmFH is believed to facilitate the final covalent attachment of heme (from holoCcmE) to the apocytochrome c. Although most models for system I propose that holoCcmE delivers heme directly to CcmF, no interaction between holoCcmE and CcmF has been demonstrated. Here, a complex between holoCcmE and CcmF is “trapped”, purified, and characterized. HoloCcmE must be released from the ABC-transporter complex CcmABCD to interact with CcmF, and the holo-form of CcmE interacts with CcmF at levels at least 20-fold higher than apoCcmE. Two conserved histidines (here termed P-His1 and P-His2) in separate periplasmic loops in CcmF are required for interaction with holoCcmE, and evidence that P-His1 and P-His2 function as heme-binding ligands is presented. These results show that heme in holoCcmE is essential for complex formation with CcmF and that the heme of holoCcmE is coordinated by P-His1 and P-His2 within the WWD domain of CcmF. These features are strikingly similar to formation of the CcmC:heme:CcmE ternary complex [Richard-Fogal C, Kranz RG. The CcmC:heme:CcmE complex in heme trafficking and cytochrome c biosynthesis. J Mol Biol 2010;401:350–62] and suggest common mechanistic and structural aspects.

Topics: Amino Acid Sequence; Bacterial Outer Membrane Proteins; Cytochromes c; Escherichia coli; Escherichia coli Proteins; Genetic Complementation Test; Heme; Hemeproteins; Holoenzymes; Imidazoles; Molecular Sequence Data; Plasmids; Protein Transport; Spectrophotometry, Ultraviolet

Mitochondria have emerged as the major regulatory platform responsible for the coordination of numerous metabolic reactions as well as cell death processes, whereby the execution of intrinsic apoptosis includes the production of reactive oxygen species fueling oxidation of cardiolipin (CL) catalyzed by cytochrome (Cyt) c. As this oxidation occurs within the peroxidase complex of Cyt c with CL, the latter represents a promising target for the discovery and design of drugs with antiapoptotic mechanisms of action. In this work, we designed and synthesized a new group of mitochondria-targeted imidazole-substituted analogs of stearic acid TPP-n-ISAs with various positions of the attached imidazole group on the fatty acid (n = 6, 8, 10, 13, and 14). By using a combination of absorption spectroscopy and EPR protocols (continuous wave electron paramagnetic resonance and electron spin echo envelope modulation) we demonstrated that TPP-n-ISAs indeed were able to potently suppress CL-induced structural rearrangements in Cyt c, paving the way to its peroxidase competence. TPP-n-ISA analogs preserved the low-spin hexa-coordinated heme-iron state in Cyt c/CL complexes whereby TPP-6-ISA displayed a significantly more effective preservation pattern than TPP-14-ISA. Elucidation of these intermolecular stabilization mechanisms of Cyt c identified TPP-6-ISA as an effective inhibitor of the peroxidase function of Cyt c/CL complexes with a significant antiapoptotic potential realized in mouse embryonic cells exposed to ionizing irradiation. These experimental findings were detailed and supported by all-atom molecular dynamics simulations. Based on the experimental data and computation predictions, we identified TPP-6-ISA as a candidate drug with optimized antiapoptotic potency.

Topics: Animals; Apoptosis; Cardiolipins; Cytochromes c; Drug Design; Embryonic Stem Cells; Enzyme Inhibitors; Gamma Rays; Horses; Imidazoles; Mice; Mitochondria, Heart; Molecular Dynamics Simulation; Organophosphorus Compounds; Peroxidase; Phosphatidylcholines; Ricinoleic Acids; Stearic Acids; Structure-Activity Relationship

Production of nitric oxide (NO) by nitric oxide synthase (NOS) requires electrons to reduce the heme iron for substrate oxidation. Both FAD and FMN flavin groups mediate the transfer of NADPH derived electrons to NOS. Unlike mammalian NOS that contain both FAD and FMN binding domains within a single polypeptide chain, bacterial NOS is only composed of an oxygenase domain and must rely on separate redox partners for electron transfer and subsequent activity. Here, we report on the native redox partners for Bacillus subtilis NOS (bsNOS) and a novel chimera that promotes bsNOS activity. By identifying and characterizing native redox partners, we were also able to establish a robust enzyme assay for measuring bsNOS activity and inhibition. This assay was used to evaluate a series of established NOS inhibitors. Using the new assay for screening small molecules led to the identification of several potent inhibitors for which bsNOS-inhibitor crystal structures were determined. In addition to characterizing potent bsNOS inhibitors, substrate binding was also analyzed using isothermal titration calorimetry giving the first detailed thermodynamic analysis of substrate binding to NOS.

Topics: Amino Acid Sequence; Animals; Anti-Bacterial Agents; Bacillus subtilis; Bacterial Proteins; Calorimetry; Cloning, Molecular; Cytochromes c; Electrons; Escherichia coli; Ferredoxin-NADP Reductase; Flavodoxin; Humans; Imidazoles; Inhibitory Concentration 50; Microbial Sensitivity Tests; Molecular Sequence Data; NADH, NADPH Oxidoreductases; NADP; Nitric Oxide; Nitric Oxide Synthase; Nitrites; Oxidation-Reduction; Rats

Cytochrome c oxidase (CcO) catalyzes the four-electron reduction of oxygen to water, the one-electron reductant Cytochrome c (Cytc) being the source of electrons. Recently we reported a functional model of CcO that electrochemically catalyzes the four-electron reduction of O(2) to H(2)O (Collman et al. Science 2007, 315, 1565). The current paper shows that the same functional CcO model catalyzes the four-electron reduction of O(2) using the actual biological reductant Cytc in a homogeneous solution. Both single and steady-state turnover kinetics studies indicate that O(2) binding is rate-determining and that O-O bond cleavage and electron transfer from reduced Cytc to the oxidized model complex are relatively fast.

Topics: Animals; Biomimetics; Catalysis; Catalytic Domain; Copper; Cytochromes c; Electron Transport; Electron Transport Complex IV; Ferric Compounds; Heme; Horses; Imidazoles; Kinetics; Oxidation-Reduction; Oxygen; Water

N-Acetylmicroperoxidase-8 (1) contains heme and residues 14-21 of horse mitochondrial cytochrome c (cyt c). The two thioether bonds linking protein to heme in cyt c are present in 1, and the native axial ligand His-18 remains coordinated to iron. As an approach to probing structural or functional roles played by the double covalent heme-protein linkage in cyt c, we have initiated a study in which the properties of 1 are compared with those of a synthetic mono-His coordinated heme peptide containing a single covalent linkage (2). One consequence of the greater conformational restriction imposed on peptide conformation in 1 is that His-Fe(III) coordination is approximately 1.4 kcal/mol more favorable in 1 than in 2. This highlights a clear advantage conferred to cyt c by having two covalent heme-protein linkages rather than one: greater thermodynamic stability of the protein fold. EPR (11 K) and resonance Raman (298 K) studies reveal that 1 and 2 exhibit a thermal high-spin/low-spin ferric equilibrium but that low-spin character is considerably more pronounced in 1. In addition, the thioether 2-(methylthio)ethanol (MTE) coordinates 0.5 kcal/mol more strongly to 1 than to 2 in 60:40 H(2)O/CH(3)OH and only triggers the expected conversion of iron to the low-spin state characteristic of ferric cyt c in the case of 1. This demonstrates that the axial ligand field provided by an imidazole and a thioether is too weak to induce a high-spin to low-spin conversion in a ferric porphyrin. Our results suggest that a conformationally constrained double covalent heme-protein linkage, as exists in 1 and its parent protein cyt c, is an effective solution that nature has evolved to circumvent this limitation. We propose that the stronger His-Fe(III) coordination enabled by such a linkage serves to markedly enhance the effective ligand field strength of His-18. Our studies with 1 and 2 suggest that a double covalent linkage in cyt c may also enable energetically more favorable trans ligation of Met-80 than would be possible if only a single linkage were present. This would serve to further increase the stability of the protein fold and perhaps to increase the effective ligand field strength of Met-80 as well.

Topics: Animals; Binding Sites; Cytochromes c; Electron Spin Resonance Spectroscopy; Enzyme Stability; Ferric Compounds; Glycine; Heme; Hemeproteins; Histidine; Horses; Imidazoles; Iron; Ligands; Mercaptoethanol; Methionine; Peptide Fragments; Peptides; Protein Structure, Secondary; Spectrum Analysis, Raman; Structure-Activity Relationship

The N-terminus acetylated ferric hemeoctapeptide from cytochrome c, N-acetylmicroperoxidase-8 (Fe(III)-NAcMP8) can be reduced by dithionite in aqueous solution to produce Fe(II)-NAcMP8. The UV-Vis spectrum has a broad Soret band and relatively poorly defined Q bands which is consistent with a mixture of a five-coordinate high spin species with His as the axial ligand and a six-coordinate, predominantly high spin species with His/H(2)O as axial ligands. There are two spectroscopically observable pK(a)s at 8.7+/-0.1 and 10.9+/-0.2 which are attributed to ionization of a heme propionic acid group and coordinated H(2)O, respectively; a pK(a) > or = 14 is due to ionization of the proximal His ligand. Equilibrium constants were determined by UV-Vis spectrophotometry at 25.0+/-0.2 degrees C and 0.5 M ionic strength (NaClO(4)) for the coordination of imidazole and a number of substituted pyridines, and complement available data for the ferric hemepeptide, allowing a comparison to be made of the affinity of an iron porphyrin with Fe in the +2 and +3 oxidation states towards these ligands. Imidazole is coordinated more strongly by the ferric porphyrin (log K=4.08) than by the ferrous porphyrin (log K=3.40). The equilibrium constants for coordination of pyridines by the ferric and ferrous porphyrins increase and decrease, respectively, with increasing ligand basicity. Values determined by cyclic voltammetry show the same dependence on the identity of the ligand. In the ferric porphyrin, the stability of the complex increases with the basicity of the ligand and hence its ability to donate electron density onto the metal. In the case of the more electron rich ferrous porphyrin, greater stability occurs with pyridine ligands that have an electron withdrawing group and hence can accept electron density from the metal. This is consistent with the midpoint reduction potentials E(1/2) of the pyridine complexes determined by cyclic voltammetry; E(1/2) is linearly dependent on, and becomes more negative with an increase in, ligand basicity. Log K for coordination of pyridines by the ferrous hemepeptide correlates well with the energy of the ligand frontier orbital with pi symmetry, suggesting that pi-bonding effects are significant in determining the strength of binding of pyridines by a ferrous porphyrin.

Topics: Cytochromes c; Dithionite; Hemeproteins; Hydrogen-Ion Concentration; Imidazoles; Ligands; Molecular Structure; Oxidation-Reduction; Peptide Fragments; Pyridines; Spectrum Analysis

In an effort to investigate factors required to stabilize heme-thiolate ligation, key structural components necessary to convert cytochrome c peroxidase (CcP) into a thiolate-ligated cytochrome P450-like enzyme have been evaluated and the H175C/D235L CcP double mutant has been engineered. The UV-visible absorption, magnetic circular dichroism (MCD) and electron paramagnetic resonance (EPR) spectra for the double mutant at pH 8.0 are reported herein. The close similarity between the spectra of ferric substrate-bound cytochrome P450cam and those of the exogenous ligand-free ferric state of the double mutant with all three techniques support the conclusion that the latter has a pentacoordinate, high-spin heme with thiolate ligation. Previous efforts to prepare a thiolate-ligated mutant of CcP with the H175C single mutant led to Cys oxidation to cysteic acid [Choudhury et al. (1994) J. Biol. Chem. 267, 25656-25659]. Therefore it is concluded that changing the proximal Asp235 residue to Leu is critical in forming a stable heme-thiolate ligation in the resting state of the enzyme. To further probe the versatility of the CcP double mutant as a ferric P450 model, hexacoordinate low-spin complexes have also been prepared. Addition of the neutral ligand imidazole or of the anionic ligand cyanide results in formation of hexacoordinate adducts that retain thiolate ligation as determined by spectral comparison to the analogous derivatives of ferric P450cam. The stability of these complexes and their similarity to the analogous forms of P450cam illustrates the potential of the H175C/D235L CcP double mutant as a model for ferric P450 enzymes. This study marks the first time a stable cyanoferric complex of a model P450 has been made and demonstrates the importance of the environment around the primary coordination ligands in stabilizing metal-ligand ligation.

Topics: Aspartic Acid; Circular Dichroism; Cysteine; Cytochrome c Group; Cytochrome P-450 Enzyme System; Cytochrome-c Peroxidase; Cytochromes c; Electron Spin Resonance Spectroscopy; Escherichia coli; Ferric Compounds; Heme; Histidine; Imidazoles; Leucine; Ligands; Mutagenesis, Site-Directed; Protein Engineering; Spectrophotometry, Ultraviolet

Direct square-wave and cyclic voltammetric electrochemical examination of the yeast iso-1-cytochrome c Phe82His/Cys102Ser variant revealed the intricacies of redox driven changes in axial coordination, concomitant with intramolecular rearrangement. Electrochemical methods are ideally suited for such a redox study, since they provide a direct and quantitative visualization of specific dynamic events. For the iso-1-cytochrome c Phe82His/Cys102Ser variant, square-wave voltammetry showed that the primary species in the reduced state is the Met80-Fe2+-His18 coordination form, while in the oxidized state the His82-Fe3+-His18 form predominates. The addition or removal of an electron to the appropriate form of this variant serves as a switch to a new molecular form of the cytochrome. Using the 2 x 2 electrochemical mechanism, simulations were done for the cyclic voltammetry experiments at different scan rates. These, in turn, provided relative rate constants for the intramolecular rearrangement/ligand exchange and the equilibrium redox potentials of the participating coordination forms: kb,AC = 17 s-1 for Met80-Fe3+-His18 --> His82-Fe3+-His18 and kf,BD > 10 s-1 for His82-Fe2+-His18 --> Met80-Fe2+-His18; E0' = 247 mV for Met80-Fe3+/2+-His18 couple, E0' = 47 mV for His82-Fe3+/2+-His18 couple, and E0' = 176 mV for the cross-reaction couple, His82-Fe3+-His18 + e- --> Met80-Fe2+-His18. Thermodynamic parameters, including the entropy of reaction, DeltaS0'Rxn, were determined for the net reduction/rearrangement reaction, His82-Fe3+-His18 + e- --> Met80-Fe2+-His18, and compared to those for wild-type cytochrome, Met80-Fe3+-His18 + e- --> Met80-Fe2+-His18. For the Phe82His variant mixed redox couple, DeltaS0'Rxn = -80 J/mol.K compared to DeltaS0'Rxn = -52 J/mol.K for the wild-type cyt c couple without rearrangement. Comparison of these entropies indicates that the oxidized His82-Fe3+-His18 form is highly disordered. It is proposed that this high level of disorder facilitates rapid rearrangement to Met80-Fe2+-His18 upon reduction.

Topics: Amino Acid Substitution; Animals; Cysteine; Cytochrome c Group; Cytochromes c; Electrochemistry; Histidine; Horses; Imidazoles; Mutagenesis, Site-Directed; Oxidation-Reduction; Phenylalanine; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins; Serine

A comparison of the binding properties of myoglobin and cytochrome c shows that the latter, in the reduced state, has an unusually large affinity for ligands, including thioethers. This explains the outstanding stability of the methionine-iron bond of ferrous cytochrome c, and results from the intrinsic ability of the cytochrome c iron to delocalize its electrons into orbitals of the sixth axial ligand.

Topics: Animals; Cyanides; Cytochrome c Group; Cytochromes c; Dimethyl Sulfoxide; Imidazoles; Iron; Ligands; Macromolecular Substances; Myoglobin; Protein Binding; Spectrophotometry, Infrared