Catalysis of methemoglobin reduction

Effect of nano cadmium sulfide on the electron transfer reactivity and peroxidase activity of hemoglobin

Hemoglobin (Hb) is immobilized with cadmium sulfide (CdS) nanoparticles (NPs) on pyrolytic graphite (PG) electrode to characterize the electrochemical reactivity and peroxidase activity of the protein. The result demonstrates that fine redox waves of Hb can be achieved after this protein is entrapped in CdS NPs. Meanwhile, the protein can exhibit nice catalytic activity towards hydrogen peroxide (H2O2). Linear relationship between the reductive peak current and the H2O2 concentration has been obtained from 5.0 x 10(-6) to 4.0 x 10(-4) mol/L, on the basis of which a new kind of H2O2 biosensor might be developed in the future.

Third-generation biosensors based on the direct electron transfer of proteins

Recent progress in third-generation electrochemical biosensors based on the direct electron transfer of proteins is reviewed. The development of three generations of electrochemical biosensors is also simply addressed. Special attention is paid to protein-film voltammetry, which is a powerful way to obtain the direct electron transfer of proteins. Research activities on various kinds of biosensors are discussed according to the proteins (enzymes) used in the specific work.

Electrochemical investigation of the chloride effect on hemoglobin

Direct electron transfer between hemoglobin and gold electrode is achieved at both a bare and a 4, 4'-bipyridine-modified gold electrode in the presence of chloride ions. The addition of chloride to hemoglobin solution also increases the reversibility of the direct electrochemistry and shifts the formal potential of hemoglobin to the negative direction. While the existence of chloride does not significantly change the tertiary structure of the protein, it might induce a slight variation of the structure, which is beneficial to the electrochemical response. It is suggested that the chloride binding to hemoglobin is a combination of specific and unspecific bindings.

Effect of dimethyl sulfoxide on the electron transfer reactivity of hemoglobin

Hemoglobin, after being treated with dimethyl sulfoxide, exhibits a direct electrochemical response at a pyrolytic graphite electrode. The apparent standard potential (E degrees ') of hemoglobin is -0.119 V (vs. NHE). Meanwhile, since no electrochemical mediator is required for its direct electrochemistry, this work provides a convenient way to perform electrochemical research on this protein.

Assignment of hyperfine-shifted heme carbon resonances in ferricytochrome b5

The reverse detection heteronuclear multiple quantum coherence, HMQC, study of native bovine ferricytochrome b5 has provided the complete assignment of hyperfine shifted resonances of heme carbons attached proton(s). The dominant delocalized pi-spin density to vinyl groups gives rise to contact shifts which have opposite direction for a carbon and its attached proton(s). The most hyperfine shifted 13C heme signals are mainly generated from 3rd heme pyrrole ring substituents which identifies that the molecular orbital for facile electron transfer is oriented to exposed heme edge. Magnetic/electronic asymmetry of heme induced by two axial His makes spread the hyperfine shifted heme carbon resonances over the range of 280 ppm at 25 degrees C, which would be the more sensitive probe than those of proton resonances in characterizing the nature of heme electronic structure of ferricytochrome b5.

Hydrogen isotope effects on the proton nuclear magnetic resonance spectrum of bovine ferricytochrome b5: axial hydrogen bonding involving the axial His-39 imidazole ligand

The potential role of hydrogen bonding interactions in modulating the molecular and electronic structure of the active site of solubilized bovine ferricytochrome b5 has been investigated by monitoring solvent isotope effects on proton-NMR spectral parameters. It is observed that the hyperfine shifts of both the heme prosthetic group and one coordinated His are sensitive, while those for the other axial His and non-coordinated residues are insensitive, to 2H for 1H exchange. Two types of isotope influences are characterized; one whose chemical shift influence is time-resolved on the NMR time scale, and involves a single proton on one axial ligand, and a second effect which involves multiple protons, is not time resolved, and influences primarily the heme. A large isotope effect on the hyperfine shift is identified for the C beta H signals of His-39 but not His-63. The exchangeable ring NH of His-39 is assigned, and the pH influence on the exchange properties of heme pocket labile protons, when compared to the rate of base catalyzed averaging of the His-39 C beta H isotope effect, lead to the conclusion that the axial hydrogen bond which is responsible for this isotope effect is that between His-39 ring NH and Gly-42 carbonyl. The more rapid exchange of labile protons with solvent for His-63 than His-39 confirms a less solvent accessible and stronger hydrogen bonded His-39 than His-63. The stronger His-39-Gly-42 than His-63-Phe-58 hydrogen bond involving the ring NH leads to more extensive His-39 imidazolate character and hence a stronger iron-His-39 than iron-His-63 bond. The much larger hyperfine shifts for His-39 than His-63 imidazole ring non-labile protons support the stronger bonding of the former ligand, and account for the orientation of the rhombic magnetic axes by His-39 rather than His-63. The solvent isotope effect on the heme leads to rotation of the prosthetic group about the His-Fe-His bond by approximately 0.5 degrees so as to shorten the 7-propionate link to Ser-64. This suggests that the hydrogen bonds between the 7-propionate group and Ser-64 are responsible for the effect.

Interpretation of hyperfine shift patterns in ferricytochromes b5 in terms of angular position of the heme: a sensitive probe for peripheral heme protein interactions

The 1H-NMR hyperfine shift pattern of the heme in a variety of low-spin ferricytochromes b5 has been analyzed in terms of the angular position of the prosthetic group within a structurally and magnetically-conserved protein matrix. A simple model is presented in which the changes in the spread of the predominantly contact shifted methyl and predominantly dipolar shifted meso-H signals of the heme, as well as shift trends for individual signals, provide sensitive indicators of the orientation of the heme relative to the orbital hole (singly-occupied d orbital), which in turn is related to the rhombic magnetic axes. The invariance of the axial His and non-coordinated residue hyperfine shifts show that it is the heme within a relatively rigid protein matrix, rather than the magnetic coordinate system, which is displaced angularly about the heme normal in order to accommodate variations in the polypeptide, orientation of the heme about the alpha,gamma-meso axis, and the length of heme carboxylate chains. Native heme shows increased counterclockwise rotation about the heme normal in the order rat-->beef-->chicken ferricytochrome b5, which is attributed largely to increased bulk of a variable sequence hydrophobic cluster consisting of residues 23, 25 and 32. The two alternate heme orientations about the alpha,gamma-meso axis are shown to also differ by rotation about the heme normal. A semiquantitative estimate of the degree of angular accommodation based on the spread of the meso-H rhombic dipolar shifts indicate rotations of 2-10 degrees. Possible functional consequences of such angular accommodation in relation to the role of these proteins in electron transfer are discussed.

Reactivity patterns for redox reactions of monomer forms of myoglobin, hemocyanin and hemerythrin

Electron-transfer reactions of myoglobin, hemocyanin and hemerythrin with the inorganic complexes [Fe(CN)6]3- (oxidant) and [Co(sep)]2+ (reductant) are considered. Rate constants kFe (25 degrees C) have been determined for the [Fe(CN)6]3- (410 mV) oxidation of horse deoxyMb, I = 0.100 M (NaCl). From the decrease in kFe over the range pH 5.5 to 9.0 a pKa of less than 6.2 is obtained, most likely due to the involvement of the heme propionate(s). At the higher pH values the rate constant is 1.2 x 10(6) M-1 s-1. Rate constants kCo (25 degrees C) for the [Co(sep)]2+ (-260 mV) reduction of metMb are also pH-dependent, pKa = 8.82, corresponding to acid dissociation of the H2O axially coordinated to the Fe(III). The rate constant for the aqua-met form is 2.8 x 10(3) M-1 s-1 at pH values less than 7.0. In contrast, no reaction is observed for the deoxy and met forms of P. interruptus hemocyanin monomer subunit a with the same two complexes (k less than 10(2) M-1 s-1). Comparisons are made with rate constants for hemerythrin, also as the monomer, which have been determined previously. Rate constants for the reactions of deoxy forms with the neutral small molecules, here O2 and H2O2, are also considered. Whereas the reactions of [Fe(CN)6]3- and [Co(sep)]2+ are at the protein surface, those of O2 and H2O2 are at the active site. Hemocyanin with the more buried (approximately 20 A) active site compared with myoglobin (3.8 A) and hemerythrin (6.3 A), does not readily undergo electron transfer with reagents at the surface. However, with the small molecules O2 and H2O2 penetration of the surrounding peptide occurs, with reaction at the active site. Rate constants for the three proteins are now of similar magnitude, and in the range (2.3-7.8) x 10(7) M-1 s-1 for O2, and 10.9 to 3600 M-1 s-1 for H2O2.

1H NMR study of the role of heme carboxylate side chains in modulating heme pocket structure and the mechanism of reconstitution of cytochrome b5

1H nuclear magnetic resonance spectroscopy was used to assign the hyperfine-shifted resonances and determine the position of a side chain in the heme cavity of wild-type rat apocytochrome b5 reconstituted with a series of synthetic hemins possessing systematically perturbed carboxylate side chains. The hemins included protohemin derivatives with individually removed or pairwise shortened and lengthened carboxylate side chains, as well as (propionate)n(methyl)8-nporphine-iron(III) isomers with n = 1-3 designed to force occupation of nonnative propionate sites. The resonance assignments were effected on the basis of available empirical heme contact shift correlations and steady-state nuclear Overhauser effect measurements in the low-spin oxidized proteins. The failure to detect holoproteins with certain hemins dictates that the stable holoproteins, unlike the case of myoglobin, demand the axial iron-His bonds and cannot accommodate carboxylate side chains at interior positions in the binding pocket. Hence, the heme pocket interior in cytochrome b5 is judged much less polar and less sterically accommodating than that of myoglobin. The propionate occupational preference was greatest as the native 7-propionate site, but also possible at the nonnative crystallographic 5-methyl or 8-methyl positions. Only for a propionate at the crystallographic 8-methyl position was a significant perturbation of the native molecular/electronic structure observed, and this was attributed to an alternative propionate-protein hydrogen bond at the crystallographic 8-methyl position. The structures of the transient protein complexes detected only shortly after reconstitution reveal that the initial encounter complexes during assembly of holoprotein from apoprotein and hemin involve one of the two alternate propionate-protein links at either the 7-propionate or native 8-methyl position. In a monopropionate hemin, this leads to the characterization of a new type of heme orientational disorder involving rotation about a N-Fe-N axis.

One- and two-dimensional nuclear Overhauser effect studies of the electronic/molecular structure of the heme cavity of ferricytochrome b5

A nuclear Overhauser effect, NOE, study of solubilized native bovine ferricytochrome b5 has provided the complete assignment of the heme resonances as well as those of the majority of the amino acid side-chains making contact with the prosthetic group. The resonances which could not be identified are those from positions very close to the iron (less than 5 A) for which paramagnetic relaxation is sufficiently strong to significantly decrease the NOEs. The observed 1H-1H dipolar contacts generally confirm a solution structure unchanged from that described in single crystals, except for the detailed orientation of the heme side-chains. The 2-vinyl group is found in both the cis and trans in-plane orientation as opposed to exclusively cis in the crystal, and the 7-propionate group is rotated by 30 degrees in solution towards the 6-propionate group. Identification of resonances for the individual axial histidine residues indicates non-equivalent interaction with the heme iron, and the patterns of meso-H, pyrrole substituent and amino acid dipolar shifts allow the location of the principal magnetic axes in the protein coordinate system. This identifies His-39 as the dominant influence in determining the electronic ground state that orients the molecular orbital for facile electron transfer via the exposed heme edge. The complete two-dimensional NOESY map for ferricytochrome b5 is presented that yields all the cross peaks expected on the basis of the one-dimensional NOE studies, and indicates that such two-dimensional methods should have profitable extension to strongly hyperfine-shifted resonances in paramagnetic proteins.

Investigation of the solution structures and mobility of oxidised and reduced cytochrome b5 by 2D NMR spectroscopy

Two-dimensional 1H NMR spectroscopy is used to examine the structure and mobility of cytochrome b5 in solution. The assignment of many residues and the interpretation of nuclear Overhauser effects (NOEs) in both redox states allow definition of secondary structural elements. Comparison with X-ray diffraction data shows that differences between crystal and solution structures are small. The dynamics of the protein are examined and the protein is shown to be more mobile than cytochrome c. The relationship of the structure and dynamics to the electron transfer function of cytochrome b5 is discussed.

Studies on the energy metabolism of opossum Didelphis virginiana erythrocytes--III. Metabolic depletion with 2-deoxyglucose markedly accelerates methemoglobin reduction in opossum but not in human erythrocytes

1. Glucose-depleted, nitrite-treated erythrocytes reduce ferriheme in vitro in an environment 100 mM to 2-deoxy-D-glucose at a rate of 2.4 microM/ml cells/hr (opossum) and 0.37 microM/ml cells/hr (human). 2. During the process of methemoglobin reduction the breakdown of adenine ribonucleotides is more rapid in opossum (0.9 microM/g hg/hr) than in human (0.36 microM/g hg/hr) erythrocytes. 3. Radiolabelled ribose from [U-14C] ATP is catabolized exclusively to [14C] lactate in opossum, and to [14C] pyruvate and [14C] lactate in human red cells.

1H-NMR assignments and the dynamics of interconversion of the isomeric forms of cytochrome b5 in solution

Cytochrome b5 reconstituted with specifically deuterated hemins has led to the assignment of the resolved 6,7 beta-propionate protons and heme meso protons. Freshly reconstituted cytochrome b5 contains a mixture of two isomers in an approx. 1:1 ratio. As time proceeds the minor isomer decreases in intensity until the equilibrium ratio, approx. 8:1, of the two isomers is reached. The rate of the heme disorder kinetics was investigated for cytochrome b5 as a function of pH, oxidation state and 2,4 heme substitutents. Comparison of the kinetic data for cytochrome b5 with that obtained for other b-type heme proteins supports the proposal that the heme disorder arises from a 180 degree rotation of the heme about the alpha, gamma-meso axis. Computer-difference methods allow the spectra of the two individual isomers to be generated. Comparison of the NMR spectral parameters for the two individual isomers indicates small structural differences for amino acid side-chain orientations.