Biomimetic approach to the oxygen evolving center: resonance Raman investigation of a manganese mu-oxo dimer in three oxidation states.

A biologically relevant dinuclear manganese mono-mu-oxo complex with a bound phenolate ligand in three oxidation states, (III,III), (III,IV) and (IV,IV), was studied using resonance Raman spectroscopy. Depending upon the excitation frequency, phenolate vibrations or mu-oxo vibrations were enhanced, which allowed us to assign the UV-visible absorption spectra. In the case of the mixed valence species (III,IV), the mu-oxo vibration at 854 cm-1 has been assigned by isotopic substitution (H2(18)O) to nu as(Mn-O-Mn). This preferential enhancement of the asymmetric vibration stresses the asymmetric character of the bridge.

Enzyme-mediated sulfide production for the reconstitution of [2Fe-2S] clusters into apo-biotin synthase of Escherichia coli. Sulfide transfer from cysteine to biotin.

We previously showed that biotin synthase in which the (Fe-S) cluster was labelled with 34S by reconstitution donates 34S to biotin [B. Tse Sum Bui, D. Florentin, F. Fournier, O. Ploux, A. Méjean & A. Marquet (1998) FEBS Lett. 440, 226-230]. We therefore proposed that the source of sulfur was very likely the (Fe-S) centre. This depletion of sulfur from the cluster during enzymatic reaction could explain the absence of turnover of the enzyme which means that to restore a catalytic activity, the clusters have to be regenerated. In this report, we show that the NifS protein from Azotobacter vinelandii and C-DES from Synechocystis as well as rhodanese from bovine liver can mobilize the sulfur, respectively, from cysteine and thiosulfate for the formation of a [2Fe-2S] cluster in the apoprotein of Escherichia coli biotin synthase. The reconstituted enzymes were as active as the native enzyme. When [35S]cysteine was used during the reconstitution experiments in the presence of NifS, labelled (Fe35S) biotin synthase was obtained. This enzyme produced [35S]biotin, confirming the results obtained with the 34S-reconstituted enzyme. NifS was also effective in mobilizing selenium from selenocystine to produce an (Fe-Se) cluster. However, though NifS could efficiently reconstitute holobiotin synthase from the apoform, starting from cysteine, these two effectors had no significant effect on the turnover of the enzyme in the in vitro assay.

Resonance Raman study of multihemic c-type cytochromes from Desulfuromonas acetoxidans.

Two multihemic cytochromes c from the sulfur reducing bacteria Desulfuromonas acetoxidans have been studied by optical and resonance Raman spectroscopy: cytochrome c551.5, a trihemic cytochrome and cytochrome c Mr 50 000, a recently isolated high molecular mass cytochrome. The redox and Raman characteristics of cytochrome c551.5 are compared to those of the tetrahemic cytochromes c3 from Desulfovibrio. While the redox behavior, followed by spectroelectrochemistry, is similar to that of cytochrome c3, showing the same conformational change after reduction of the highest potential heme, the Raman data show a contribution from a His- form of the axial ligands and lead to the assignment of a band at 218 cm-1 to the Fe(III)-(His)2 stretching vibration. The Raman data on cytochrome c Mr 50 000 are in favor of an entirely low spin species with two different sets of axial ligands. A partially reduced state is easily accessible by ascorbate addition.

A Pentacoordinated Di-N-carboxamido-dithiolato-O-sulfinato-iron(III) Complex Related to the Metal Site of Nitrile Hydratase.

Postcoordination oxidation by dioxygen of one of the thiolate groups in a pentadentate N(2)S(3) ligand results in an iron(III) complex with two N-carboxamido, two thiolato, and one O-sulfinato ligands (see the CAMERON representation). This novel mixed coordination is similar to that determined for the inactive form of the nitrile hydratase from Rhodococcus sp. N-771, but differs by the O versus S binding of the sulfinato ligand.

Engineering, expression and biochemical characterization of the hemoglobin domain of a Erwinia chrysanthemi flavohemoprotein.

An artificial hemoglobin-like domain has been constructed by engineering the gene coding for the multi-domain flavohemoprotein from the bacterium Erwinia chrysanthemi. This domain was designed by molecular modelling, cloned and over-expressed in Escherichia coli. The holo-protein was obtained in large quantities after extraction from inclusion bodies and refolding in presence of alkaline hemin. The purified 140-residue domain was studied and characterized to gain new insights into the biochemical function of the recombinant domain and the biological role of this new flavohemoprotein. The structural and functional features of this domain in solution were studied using far-ultraviolet circular dichroism, resonance Raman, proton-NMR spectroscopy, flash laser photolysis and molecular modelling. The recombinant domain is shown to be folded properly and active. This hemoglobin-like domain is able to bind oxygen and carbon monoxide with very high affinity. It exhibits a rapid auto-oxidation which may explain its tight association with a flavin containing reductase domain. A functional model of this hemoglobin is discussed and compared with the X-ray structures of other hemoproteins.

Electron transfer in tetrahemic cytochromes c3: spectroelectrochemical evidence for a conformational change triggered by heme IV reduction.

Electron transfer in tetrahemic cytochromes c3 from Desulfovibrio vulgaris Hildenborough (D.v.H.) and Desulfovibrio desulfuricans Norway (D.d.N.) strains has been investigated by thin layer spectroelectrochemistry with visible absorption, CD, and resonance Raman (RR) monitoring. The observed splitting of the isosbestic point in the Soret absorption band indicates that the electron transfer from the (FeIII)4 state to the (FeII)4 state proceeds via an intermediate species, which corresponds to 25 and 50% reduction for the D.v.H. cyt.c3 and the D.d.N. cyt.c3, respectively. For the latter, a specific CD signal is observed at half-reduction. RR monitoring of the redox process does not reveal multiple splitting of the high-frequency RR bands, at variance with previously published results on the enzymatic reduction of cyt.c3 from Desulfovibrio vulgaris Miyazaki, a cytochrome highly homologous to D.v.H. cyt.c3 [Verma, A.L., Kimura, A., Nakamura, A., Yagi, T., Inoguchi, H., & Kitagawa, T. (1988) J. Am. Chem. Soc. 110, 6617-6623]. The low-frequency RR spectra of the intermediate species differ significantly from the ones calculated from a linear combination of the all-ferric and all-ferrous states, for the same reduction ratio. Frequency shifts of the bending modes of the cysteine and propionate heme substituents are observed, as well as changes specific to each cytochrome; most notable is the activation of two torsional modes in the case of D.d.N. cyt.c3. Comparison of the results obtained for the two cytochromes leads to the conclusion that reduction of heme IV triggers the observed conformational change. This conclusion is supported by the spectroelectrochemical investigation of the mutant D.v.H. cyt.c3 H25M, in which the sixth ligand of heme III, histidine, is replaced by a methionine.

Molecular shape, dissociation, and oxygen binding of the dodecamer subunit of Lumbricus terrestris hemoglobin.

Small angle x-ray scattering of the 213-kDa dodecamer of Lumbricus terrestris Hb yielded radius of gyration = 3.74 +/- 0.01 nm, maximum diameter = 10.59 +/- 0.01 nm, and volume = 255 +/- 10 nm3, with no difference between the oxy and deoxy states. Sedimentation velocity studies indicate the dodecamer to have a spherical shape and concentration- and Ca2+-dependent equilibria with its constituent subunits, the disulfide-bonded trimer of chains a-c and chain d. Equilibrium sedimentation data were fitted best with a trimer-dodecamer model, ln K4 = 7 (association K in liters3/g3) at 1 degrees C and 4 at 25 degrees C, providing DeltaH = -20 kcal/mol and DeltaS = 4.4 eu/mol. Oxydodecamer dissociation at pH 8.0, in urea, GdmCl, heteropolytungstate K8[SiW11O39] and of metdodecamer at pH 7, was followed by gel filtration. Elution profiles were fitted with exponentially modified gaussians to represent the three peaks. Two exponentials were necessary to fit all the dissociations except in [SiW11O39]-8. Equilibrium oxygen binding measurements at pH 6.5-8. 5, provided P50 = 8.5, 11.5-11.9 and 11.9-13.5 torr, and n50 = 5.2-9. 5, 3.2-4.9, and 1.8-2.7 for blood, Hb, and dodecamer, respectively, at pH 7.5, 25 degrees C. P50 was decreased 3- and 2-fold in approximately 100 mM Ca2+ and Mg2+, respectively, with concomitant but smaller increases in cooperativity.

Study of the coordination chemistry of prostaglandin G/H synthase by resonance Raman spectroscopy.

Resonance Raman spectra of prostaglandin G/H synthase (PGHS) in its ferric and ferrous states have been obtained by Soret excitation. In native PGHS, which contained only 0.25 heme/monomeric apoprotein, the ferric heme was in a high-spin hexacoordinated state. The presence of a vibration at 289 cm-1 that was responsive to H(2)16O -> H(2)18O replacement was taken as evidence for the presence of a H-bonded H2O molecule as the sixth ligand of the Fe. A study, by CD and resonance Raman spectroscopy, of heme incorporation into the apoprotein showed that, for heme/protein ratios lower than 0.5, the heme was in the same ferric high-spin hexacoordinated state as in the native enzyme. For heme/protein ratios higher than 0.5, the concomitant formation of two minor species was observed: a low-spin hexacoordinated species which could be due to the axial coordination of a distal histidine to the Fe trans to its proximal histidine ligand; and a high-spin pentacoordinated species that corresponded to non-specific binding of the heme to the apoprotein. In the reduced state, the heme of PGHS contained a high-spin pentacoordinated Fe(II) with a histidine as the proximal ligand. However, this species shifted spontaneously towards a low-spin hexacoordinated Fe(II) species in which the iron was probably coordinated by a distal histidine as the sixth axial ligand. The PGHS Fe(II).CO derivative displayed an Fe-CO stretching mode at 529 cm-1, which is in the range observed for peroxidases. Such a high frequency could be due to H-bonding between the oxygen atom of the CO ligand and the distal histidine, His207. Since this histidine plays an important role, by coordination of Fe(II) or Fe(III) of PGHS and stabilization of the ligands of the Fe, H2O or CO by H-bonding, it is suggested that this histidine could also play a key role in the cleavage of the O-O bond of peroxides by peroxidases.

The role of the dodecamer subunit in the dissociation and reassembly of the hexagonal bilayer structure of Lumbricus terrestris hemoglobin.

The dissociation of the approximately 3500-kDa hexagonal bilayer (HBL) hemoglobin (Hb) of Lumbricus terrestris upon exposure to Gdm salts, urea and the heteropolytungstates [SiW11O39]8- (SiW), [NaSb9W21O86]18- (SbW) and [BaAs4W40O140]27- (AsW) at neutral pH was followed by gel filtration, SDS-polyacrylamide gel electrophoresis, and scanning transmission electron microscopy. Elution curves were fitted to sums of exponentially modified gaussians to represent the peaks due to undissociated oxyHb, D (approximately 200 kDa), T+L (approximately 50 kDa), and M (approximately 25 kDa) (T = disulfide-bonded trimer of chains a c, M = chain d, and L = linker chains). OxyHb dissociation decreased in the order Gdm*SCN > Gdm.Cl > urea > Gdm.OAc and AsW > SbW > SiW. Scanning transmission electron microscopy mass mapping of D showed approximately 10-nm particles with masses of approximately 200 kDa, suggesting them to be dodecamers (a+b+c)3d3. OxyHb dissociations in urea and Gdm.Cl and at alkaline pH could be fitted only as sums of 3 exponentials. The time course of D was bell-shaped, indicating it was an intermediate. Dissociations in SiW and upon conversion to metHb showed only two phases. The kinetic heterogeneity may be due to oxyHb structural heterogeneity. Formation of D was spontaneous during HBL reassembly, which was minimal (

Polytungstate binding to metmyoglobin: an access to various structural forms of the protein.

Complex formation between metMb and three heteropolytungstates, offering various sizes and charges, has been studied in the pH range 6-8. 1:1 complexes are formed with (KAs4W40O140)27- and (NaSb9W21O86)18-, with an association constant of 10(6) and 4 x 10(5) M-1 respectively, at pH 7.3 and 10 mM ionic strength. Resulting structural changes of the metMb moiety have been investigated by absorption, CD and EPR spectroscopies. Besides an acid-denatured-like form, obtained at a pH as high as 6.5 with the largest polyanion, the formation of an hemichrome is generally observed. It can be reduced to the hemochrome, whereas the complexation of deoxyMb by the polytungstates leaves the deoxy structure unaltered.

Biochemical and spectroscopic characterization of the high molecular weight cytochrome c from Desulfovibrio vulgaris Hildenborough expressed in Desulfovibrio desulfuricans G200.

The gene of high molecular weight, multiheme cytochrome c (Hmc) from the sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough has been overexpressed in Desulfovibrio desulfuricans G200. The recombinant protein has been purified. Its molecular weight (65,600), amino acid composition, and NH2-terminal sequence were found to be identical to those of the wild-type protein. The recombinant protein has been spectroscopically characterized (optical spectrum, EPR, circular dichroism) and compared to the wild-type protein. We have found 16 hemes per molecule by iron analysis and the pyridine hemochrome test. Both high- and low-spin features were observed in the EPR spectrum. A detailed spin quantitation analysis indicates 1 or 2 high-spin hemes and 14 or 15 low-spin hemes per molecule. The redox potentials of the hemes determined by voltammetric techniques gave an average of three different values, 0, -100, and -250 mV (versus NHE), for the wild-type and the recombinant cytochrome. The low potential values are similar to the values observed for the bis(histidinyl) coordinated hemes of cytochrome c3. A comparison of the arrangement of heme binding sites and coordinated histidines in the amino acid sequences of cytochrome c3 and Hmc has shown that the latter contains four domains, three of which are complete c3-like domains, while the fourth represents an incomplete c3-like domain which may contain His-Met coordinated hemes. These data are in agreement with the detailed study of the number and types of hemes reported in this paper.

Formation of cyanoferricytochrome c in the presence of potassium ferricyanide, in the course of a Raman resonance experiment.

Modifications of native ferricytochrome c are observed in the course of Raman resonance experiments, run in the presence of residual amounts of potassium ferricyanide. Visible and EPR data shown that the cyanide-substituted cytochrome is formed, due to photodecomposition of ferricyanide. Its Raman resonance spectrum is reported.

Modification of the structural and redox properties of cytochrome c by heteropolytungstate binding.

Complex formation between horse heart ferricytochrome c and large three-dimensional polyanions has been investigated, in order to study the influence of surface electrostatic interactions on the structural and redox properties of cytochrome c. Cytochrome c binds the large heteropolytungstates (NaSb9W21O86)18- and (KAs4W40O140)27- with a 1/1 polyanion/cytochrome c ratio, and the smaller ion (SiW11O39)8- with a 2/1 ratio. Upon complexation, cytochrome c undergoes structural changes that are dependent on the size and charge of the polyanion, and on the pH and ionic strength of the medium. Three different forms of complexed cytochrome c have been characterized by optical and EPR spectroscopies, in the pH range 6.5-8: an N form, close to the native structure, an A form, analogous to cytochrome c in acidic medium, and a novel B form in which the heme pocket is open but the iron remains low-spin. The redox potential of cytochrome c is lowered to 250-220 mV (vs. NHE) in the N form, and to 80 mV in the B form.

A high melting cis-[Pt(NH3)2[d(GpG)]]adduct of a decanucleotide duplex.

The [cis-Pt(NH3)2(d(GCCGGATCGC)-N7(4), N7(5))]-d(GCGATCCGGC) duplex has been prepared with Tm = 49 degrees C (vs 58 degrees C for the unplatinated form). NMR of the ten observable imino protons supports a kinked structure with intact base pairing of the duplex on the 3'-side of the d(GpG).cis-Pt chelate (relative to the platinated strand) The modification of the B-DNA type CD spectrum, due to the platinum chelate, is comparable to that observed for the platination (at a 0.05 Pt:base ratio) of the Micrococcus Lysodeikticus DNA (72% GC).

Interaction of cis-[Pt(NH3)2(H2O)2](NO3)2 with ribose deoxyribose diguanosine phosphates.

The three diguanosine phosphates GpG (4 X 10(-4) M), d(GpG) (10(-5) M), and d(pGpG) (10(-5) M) have been reacted with cis-[Pt(NH3)2(H2O)2](NO3)2 (1 Pt/dinucleotide) in water at pH 5.5 and 37 degrees C. In each case a single product is formed. The three complexes have been characterized by proton nuclear magnetic resonance (1H NMR) and circular dichroism (CD) analyses. They are N(7)-N(7) chelates of the metal with an anti-anti configuration of the bases. They present a conformational change upon deprotonation of guanine N(1)H whose pKa is ca. 8.7 (D2O). Their CD spectra, compared to those of the free dinucleotides, exhibit an increase of ellipticity in the 275-nm region, which can be qualitatively related to the characteristic increase reported for platinated DNA and poly(dG) . poly(dC). These results are in favor of the hypothesis of intrastrand cross-linking of adjacent guanines, by the cis-PtII(NH3)2 moiety, after a local denaturation of DNA.

Complexes of cobalt (II) and manganese (II) with adenosine 5'-diphosphate and adenosine 5'-triphosphate. A circular dichroism study.

For studies of interactions between Co2+ and adenosine 5'-diphosphate or adenosine 5'-triphosphate (ADPH4+ and ATPH5+ in strongly acidic medium) visible circular dichroism (d-d transitions of Co2+) and ultraviolet circular dichroism (adenine transitions) have proven to be very sensitive to structural changes. Drastic variation of spectra as a function of pH and concentration enabled us to show the existence of various species, to state their stoichiometry and eventually, their self-association. With ATPH22-, C.D. results are in agreement with recent N.M.R. results. With ligands bearing three negative charges, complexes (1 metal:2 nucleotides)n are formed in which bases of the two nucleotides of the molecule are self-associated. With ADP3-, the visible C.D. spectrum of this complex is intense and hides the spectra of the complexes formed with other protonated species of ADP; this self-associated complex is detected up to a lower limit of 5 X 10(-4) M concentration. With ATPH3-, a complex exhibiting the same characteristics as the one with ADP3- is formed but in about twenty times less amount which explains why it was not detected by potentiometry. With 0.1 M ATP4-, dimeric (or polymeric) complexes, of 1:2 and 1:1 stoichiometry are observed. With 0.01 M ATP4-, 1:1 monomeric and 2:1 dimeric (or polymeric) complexes are detected. The interactions between Mn2+ ions and ADP or ATP have been studied by C.D. on the UV range. The same species as with Co2+ ions have been found but the 1:2 complex formation with ADP3- was shown to occur to a lesser extent and was not observed below a 10(-2) M ADP concentration.

Nitrosoalkanes as Fe(II) ligands in the hemoglobin and myoglobin complexes formed from nitroalkanes in reducing conditions.

Primary and secondary aliphatic nitro compounds, R2CHNO2, react with myoglobin and hemoglobin, in the presence of sodium dithionite, leading to new complexes with Soret peaks respectively at 425 and 421 nm. These complexes are very stable even after disappearance of the starting nitro compounds and do not exchange their exogenous ligand after 10 h under 1 atm (101 325 Pa) CO. They are low-spin hexacoordinated myoglobin or hemoglobin complexes, as shown by the resonance Raman spectrum of the nitromethane-derived human hemoglobin complex which is similar to those of the known hemoglobin complexes with O2, CO, NO and nitrosobenzene. Evidence has been produced to show that the nitro compounds themselves do not bind to the hemoproteins; we propose that among the reduction derivatives produced in situ by dithionite, the corresponding unstable nitroso monomers, whose nitroso group is isoelectronic with dioxygen, are the actual ligands of the 425-nm or 421-nm-absorbing complexes.