Electrocatalytic synthesis of ammonia by surface proton hopping.

Highly efficient ammonia synthesis at a low temperature is desirable for future energy and material sources. We accomplished efficient electrocatalytic low-temperature ammonia synthesis with the highest yield ever reported. The maximum ammonia synthesis rate was 30 099 µmol gcat-1 h-1 over a 9.9 wt% Cs/5.0 wt% Ru/SrZrO3 catalyst, which is a very high rate. Proton hopping on the surface of the heterogeneous catalyst played an important role in the reaction, revealed by in situ IR measurements. Hopping protons activate N2 even at low temperatures, and they moderate the harsh reaction condition requirements. Application of an electric field to the catalyst resulted in a drastic decrease in the apparent activation energy from 121 kJ mol-1 to 37 kJ mol-1. N2 dissociative adsorption is markedly promoted by the application of the electric field, as evidenced by DFT calculations. The process described herein opens the door for small-scale, on-demand ammonia synthesis.

Structural basis of the redox switches in the NAD+-reducing soluble [NiFe]-hydrogenase.

NAD+ (oxidized form of NAD:nicotinamide adenine dinucleotide)-reducing soluble [NiFe]-hydrogenase (SH) is phylogenetically related to NADH (reduced form of NAD+):quinone oxidoreductase (complex I), but the geometrical arrangements of the subunits and Fe-S clusters are unclear. Here, we describe the crystal structures of SH in the oxidized and reduced states. The cluster arrangement is similar to that of complex I, but the subunits orientation is not, which supports the hypothesis that subunits evolved as prebuilt modules. The oxidized active site includes a six-coordinate Ni, which is unprecedented for hydrogenases, whose coordination geometry would prevent O2 from approaching. In the reduced state showing the normal active site structure without a physiological electron acceptor, the flavin mononucleotide cofactor is dissociated, which may be caused by the oxidation state change of nearby Fe-S clusters and may suppress production of reactive oxygen species.

Surface Protonics Promotes Catalysis.

Catalytic steam reforming of methane for hydrogen production proceeds even at 473 K over 1 wt% Pd/CeO2 catalyst in an electric field, thanks to the surface protonics. Kinetic analyses demonstrated the synergetic effect between catalytic reaction and electric field, revealing strengthened water pressure dependence of the reaction rate when applying an electric field, with one-third the apparent activation energy at the lower reaction temperature range. Operando-IR measurements revealed that proton conduction via adsorbed water on the catalyst surface occurred during electric field application. Methane was activated by proton collision at the Pd-CeO2 interface, based on the inverse kinetic isotope effect. Proton conduction on the catalyst surface plays an important role in methane activation at low temperature. This report is the first describing promotion of the catalytic reaction by surface protonics.

t-BOOH-induced oxidative damage in sickle red blood cells and the role of flavonoids.

Sickle cell anemia is a genetic disease characterized byan increase in generation of reactive oxygen species, abnormal iron release and low antioxidant activity which can lead to cell injury. Several therapies have been used to decrease the oxidative damage in these patients. In this study, we investigated the effect of flavonoids (quercetin and rutin) on the oxidation of red blood cells (RBC) from sickle cell anemia patients following exposure of the cells to tert-butyl hydroperoxide (t-BOOH). Quercetin provided greater protection against Hb oxidation, the binding of Hb to membrane and lipid peroxidation than did rutin. Quercetin (150 microM) reduced Hb oxidation by 30% and increased the level of oxyHb from 17.5 to 29 microM. Rutin prevented Hb oxidation only at concentrations higher than 200 microM and did not prevent the binding of Hb to RBC membrane. These distinct effects of the flavonoids probably reflect their structural characteristics. Thus, quercetin, which possesses a suitable structure for free-radical scavenging and ion quelation, was a more effective antioxidant than rutin. The presence of rutinose at position C(3) in rutin may impair its antioxidant effect. The presence of ascorbic acid enhanced the protective effect of quercetin and rutin against oxidative stress in sickle Hb and lipid peroxidation. This synergistic action helped to maintain a constant supply of flavonoids and thus, rescue the cells from the injury caused by free radicals and iron ions.

Functional behavior of tortoise hemoglobin Geochelone denticulata

The hemolysate from Geochelone denticulata contains two main hemoglobin components, as shown by ion exchange chromatography and polyacrylamide gel electrophoresis (PAGE). Electrophoresis under dissociating conditions showed three types of globin chains. The apparent molecular mass, as determined by gel filtration on Sephadex G-200, was compatible with tetrameric Hb, which was unable to polymerize. The G. denticulata Hb has a P50 value of 9.56 mm Hg at pH 7.4. The Hb oxygenation appears to be under the control of organic phosphates and hydrogen ion since it is strongly affected by those species. In the presence ATP or IHP the P50 values increased to 29.51 mm Hg and 54.95 mm Hg, respectively, at pH 7.4. The n50 was generally lower than 1.5 in stripped Hb, suggesting a dissociation of tetramers. In the presence of organic phosphates n50 values increased to approximately 2.5. The Bohr effect was evident in oxygen equilibrium experiments. The hematocrit (32 percent) and Hb concentration (5.7 mM as heme) of G. denticulata blood were substantially larger than those of G. carbonaria, but the methemoglobin levels were similar in both species, approximately 1 percent. Thus, the oxygen capacity of blood appears to be higher in G. denticulata than in G. carbonaria, particularly considering the functional properties of their Hbs, which would guarantee the survival of animals

Functional behavior of tortoise hemoglobin Geochelone denticulata.

The hemolysate from Geochelone denticulata contains two main hemoglobin components, as shown by ion exchange chromatography and polyacrylamide gel electrophoresis (PAGE). Electrophoresis under dissociating conditions showed three types of globin chains. The apparent molecular mass, as determined by gel filtration on Sephadex G-200, was compatible with tetrameric Hb, which was unable to polymerize. The G. denticulata Hb has a P50 value of 9.56 mm Hg at pH 7.4. The Hb oxygenation appears to be under the control of organic phosphates and hydrogen ion since it is strongly affected by those species. In the presence ATP or IHP the P50 values increased to 29.51 mm Hg and 54.95 mm Hg, respectively, at pH 7.4. The n50 was generally lower than 1.5 in stripped Hb, suggesting a dissociation of tetramers. In the presence of organic phosphates n50 values increased to approximately 2.5. The Bohr effect was evident in oxygen equilibrium experiments. The hematocrit (32%) and Hb concentration (5.7 mM as heme) of G. denticulata blood were substantially larger than those of G. carbonaria, but the methemoglobin levels were similar in both species, approximately 1%. Thus, the oxygen capacity of blood appears to be higher in G. denticulata than in G. carbonaria, particularly considering the functional properties of their Hbs, which would guarantee the survival of animals.

Functional behavior of tortoise hemoglobin Geochelone denticulata

The hemolysate from Geochelone denticulata contains two main hemoglobin components, as shown by ion exchange chromatography and polyacrylamide gel electrophoresis (PAGE). Electrophoresis under dissociating conditions showed three types of globin chains. The apparent molecular mass, as determined by gel filtration on Sephadex G-200, was compatible with tetrameric Hb, which was unable to polymerize. The G. denticulata Hb has a P50 value of 9.56 mm Hg at pH 7.4. The Hb oxygenation appears to be under the control of organic phosphates and hydrogen ion since it is strongly affected by those species. In the presence ATP or IHP the P50 values increased to 29.51 mm Hg and 54.95 mm Hg, respectively, at pH 7.4. The n50 was generally lower than 1.5 in stripped Hb, suggesting a dissociation of tetramers. In the presence of organic phosphates n50 values increased to approximately 2.5. The Bohr effect was evident in oxygen equilibrium experiments. The hematocrit (32%) and Hb concentration (5.7 mM as heme) of G. denticulata blood were substantially larger than those of G. carbonaria, but the methemoglobin levels were similar in both species, approximately 1%. Thus, the oxygen capacity of blood appears to be higher in G. denticulata than in G. carbonaria, particularly considering the functional properties of their Hbs, which would guarantee the survival of animals.

O hemolisado de Geochelone denticulata contém dois componentes principais, de acordo com a cromatografia de troca iônica e PAGE. Eletroforese sob condições dissociantes mostrou 3 tipos de cadeias de globina. A massa molecular aparente, determinada pela filtração em gel sobre Sephadex G-200, foi compatível com Hb tetramérica que foi incapaz de polimerizar. A Hb de G. denticulata tem valor de P50 de 9,56 mm Hg em pH 7,4. A oxigenação da Hb parece estar sob controle de fosfatos orgânicos e íons hidrogênio, uma vez que ela é fortemente afetada por essas espécies. Na presença de ATP ou IHP, os valores de P50 aumentaram para 29,51 mm Hg e 54,95 mm Hg, respectivamente, a pH 7,4. O n50 foi geralmente menor que 1,5 na Hb stripped, sugerindo dissociação de tetrâmeros. Na presença de fosfatos orgânicos, os valores de n50 aumentaram para aproximadamente 2,5. O efeito Bohr foi evidente nos experimentos de equilíbrio com oxigênio. O hematócrito de 32% e a concentração de Hb de 5,7 mM em heme no sangue de G. denticulata foram substancialmente maiores do que da G. carbonaria, mas os níveis de metahemoglobina foram similares em ambas as espécies, aproximadamente 1%. Portanto, a capacidade de oxigenação do sangue parece ser maior na G. denticulata, particularmente considerando as propriedades funcionais da Hb, que garantiria a sobrevivência dos animais.

Elucidation of the differences between the 430- and 455-nm absorbing forms of P450-isocyanide adducts by resonance Raman spectroscopy.

Alkylisocyanide adducts of microsomal P450 exist in two interconvertible forms, each giving the Soret maximum around 430 or 455 nm. This is demonstrated with a rabbit liver P450 2B4. Resonance Raman spectra of the 430- and 455-nm forms were examined for typical P450s of the two types as well as for P450 2B4 because the 430-nm form of P450 2B4 is liable to change into P420. P450cam and P450nor were selected as a model of the 430- and 455-nm forms, respectively. For the n-butyl isocyanide (CNBu) adduct, the Fe(II)-CNBu stretching band was observed for the first time at 480/467 cm(-1) for P450cam and at 471/459 cm(-1) for P450nor with their (12)CNBu/(13)CNBu derivatives. For P450cam, but not P450nor, other (13)C isotope-sensitive bands were observed at 412/402, 844/835, and 940/926 cm(-1). The C-N stretching mode was identified by Fourier transform IR spectroscopy at 2116/2080 cm(-1) for P450cam and at 2148/2108 cm(-1) for P450nor for the (12)C/(13)C derivatives. These findings suggest that the binding geometry of isocyanide differs between the two forms-bent and linear structures for P450cam-CNBu and P450nor-CNBu, respectively. In contrast, in the ferric state, the Raman (13)C isotopic frequency shifts, and the IR C-N stretching frequencies (2213/2170 and 2215/2172 cm(-1)) were similar between P450cam and P450nor, suggesting similar bent structures for both.

Characterization of imidazolate-bridged dinuclear and mononuclear hydroperoxo complexes.

Dinucleating ligands having two metal-binding sites bridged by an imidazolate moiety, Hbdpi, HMe(2)bdpi, and HMe(4)bdpi (Hbdpi = 4,5-bis(di(2-pyridylmethyl)aminomethyl)imidazole, HMe(2)bdpi = 4,5-bis((6-methyl-2-pyridylmethyl)(2-pyridylmethyl)aminomethyl)imidazole, HMe(4)bdpi = 4,5-bis(di(6-methyl-2-pyridylmethyl)aminomethyl)imidazole), have been designed and synthesized as model ligands for copper-zinc superoxide dismutase (Cu,Zn-SOD). The corresponding mononucleating ligands, MeIm(Py)(2), MeIm(Me)(1), and MeIm(Me)(2) (MeIm(Py)(2) = (1-methyl-4-imidazolylmethyl)bis(2-pyridylmethyl)amine, MeIm(Me)(1) = (1-methyl-4-imidazolylmethyl)(6-methyl-2-pyridylmethyl)(2-pyridylmethyl)amine, MeIm(Me)(2) = (1-methyl-4-imidazolyl-methyl)bis(6-methyl-2-pyridylmethyl)amine), have also been synthesized for comparison. The imidazolate-bridged Cu(II)-Cu(II) homodinuclear complexes represented as [Cu(2)(bdpi)(CH(3)CN)(2)](ClO(4))(3).CH(3)CN.3H(2)O (1), [Cu(2)(Me(2)bdpi)(CH(3)CN)(2)](ClO(4))(3) (2), [Cu(2)(Me(4)bdpi)(H(2)O)(2)](ClO(4))(3).4H(2)O (3), a Cu(II)-Zn(II) heterodinuclear complex of the type of [CuZn(bdpi)(CH(3)CN)(2)](ClO(4))(3).2CH(3)CN (4), Cu(II) mononuclear complexes of [Cu(MeIm(Py)(2))(CH(3)CN)](ClO(4))(2).CH(3)CN (5), [Cu(MeIm(Me)(1))(CH(3)CN)](ClO(4))(2)( )()(6), and [Cu(MeIm(Me)(2))(CH(3)CN)](ClO(4))(2)( )()(7) have been synthesized and the structures of complexes 5-7 determined by X-ray crystallography. The complexes 1-7 have a pentacoordinate structure at each metal ion with the imidazolate or 1-methylimidazole nitrogen, two pyridine nitrogens, the tertiary amine nitrogen, and a solvent (CH(3)CN or H(2)O) which can be readily replaced by a substrate. The reactions between complexes 1-7 and hydrogen peroxide (H(2)O(2)) in the presence of a base at -80 degrees C yield green solutions which exhibit intense bands at 360-380 nm, consistent with the generation of hydroperoxo Cu(II) species in all cases. The resonance Raman spectra of all hydroperoxo intermediates at -80 degrees C exhibit a strong resonance-enhanced Raman band at 834-851 cm(-1), which shifts to 788-803 cm(-1) (Deltanu = 46 cm(-1)) when (18)O-labeled H(2)O(2) was used, which are assigned to the O-O stretching frequency of a hydroperoxo ion. The resonance Raman spectra of hydroperoxo adducts of complexes 2 and 6 show two Raman bands at 848 (802) and 834 (788), 851 (805), and 835 (789) cm(-1) (in the case of H(2)(18)O(2), Deltanu = 46 cm(-1)), respectively. The ESR spectra of all hydroperoxo complexes are quite close to those of the parent Cu(II) complexes except 6. The spectrum of 6 exhibits a mixture signal of trigonal-bipyramid and square-pyramid which is consistent with the results of resonance Raman spectrum.

Hemoglobin-sulfhydryls from tortoise (Geochelone carbonaria) can reduce oxidative damage induced by organic hydroperoxide in erythrocyte membrane.

Sulfhydryl groups are important to avoid oxidative damage to the cell. In RBC, tert-butyl hydroperoxide (tert-BOOH) and hydrogen peroxide (H2O2) are capable of oxidizing heme and promoting lipid peroxidation. H2O2 caused greater oxidation of heme than tert-BOOH, although the oxidation of sulfhydryl groups was similar. Geochelone carbonaria Hb, a rich sulfhydryl protein, inhibited the TBA-reactive substances formation of human erythrocytes exposed to tert-BOOH by about 30%; this decrease was smaller with Geochelone denticulata Hb. Sulfhydryl reagents diminished the number of reactive sulfhydryl groups in the G. carbonaria Hb resulting in a decrease of its antioxidant power, suggesting the involvement of sulfhydryls of Hb in the protection against lipid peroxidation.

Direct Observation by Electrospray Ionization Mass Spectrometry of

The use of methanol as solvent is essential for the formation of the double-bookshelf-type oxide cluster [(Cp*Rh)(2)Mo(6)O(20)(OMe)(2)](2-) from [{Cp*Rh(µ-Cl)Cl}(2)] and four equivalents of [Mo(2)O(7)](2-). The reaction proceeds via [Cp*RhMo(3)O(8)(OMe)(5)](-). The proposed structure for this key intermediate (shown schematically) is supported by electrospray ionization mass spectrometry and labeling experiments with CD(3)OD as solvent. Cp*=eta(5)-C(5)Me(5).

Sulphydryl groups and their relation to the antioxidant enzymes of chelonian red blood cells.

Thiol groups of hemoglobin and blood glutathione are higher in Geochelone carbonaria than in Geochelone denticulata. Exposure of stripped hemolysate of both tortoises to terc-butyl hydroperoxide, resulted in a higher ferroheme oxidation of G. denticulata hemoglobin. In this example glutathione reductase and glutathione peroxidase, were not active due to the absence of GSH and NADPH, suggesting that the thiol groups of G. carbonaria hemoglobin act as antioxidant, similar to GSH. In the total hemolysate, however, where the antioxidant enzymes are active, both species showed similar levels of hemoglobin oxidation, suggesting that the protective effect of thiol groups of hemoglobin are less effective for heme protection. The activity of glutathione reductase and glutathione peroxidase was higher in erythrocytes of G. denticulata and the activity of catalase and superoxide dismutase was higher in erythrocytes of G. carbonaria.

Involvement of available SH groups in the heterogeneity of hemoglobin from the tortoise Geochelone carbonaria.

Geochelone carbonaria hemoglobin (Hb) was analyzed by polyacrylamide gel electrophoresis (PAGE) and purified by ion exchange chromatography on CM-cellulose. Seven fractions were obtained using fresh Hb preparations. CM-cellulose chromatography of Hb reacted with iodoacetamide, showed one minor (HbI) and one major band (HbII). Analysis of the molecular masses of recently collected Hb and of aged solutions determined by gel filtration showed that polymerization increased with the duration of storage. The reaction with oxidized glutathione changed the electrophoretic pattern of Hb, and highlighted the bands corresponding to glutathionyl-Hb. The presence of these bands in fresh Hb solutions and in alkylated preparations suggests that they may occur in vivo. PAGE under dissociating conditions showed that the hemolysate contained 3 different polypeptide chains (G1, G2 and G3). Both Hb components shared the G1 globin chain with HbI containing G1 and G2 and HbII, G1 and G3 chains.

cDNA-derived amino-acid sequence of a land turtle (Geochelone carbonaria) beta-chain hemoglobin.

The cDNA sequence encoding the turtle Geochelone carbonaria beta-chain was determinated. The isolation of hemoglobin mRNA was based on degenerate primers' PCR in combination with 5'- and 3'-RACE protocol. The full length cDNA is 615 bp with the ATG start codon at position 53 and TGA stop codon at position 495; The AATAAA polyadenylation signal is found at position 599. The deduced polypeptyde contains 146 amino-acid residues. The predicted amino acid sequence shares 83% identity with the beta-globin of a related specie, the aquatic turtle C. p. belli. Otherwise, identity is higher when compared with chicken beta-Hb (80%) than with other reptilian orders (Squamata, 69%, and Crocodilia, 61%). Compared with human HbA, there is 67% identity, and at least three amino acid substitutions could be of some functional significance (Glu43 beta-->Ser, His116 beta-->Thr and His143 beta-->Leu). To our knowledge this represents the first cDNA sequence of a reptile globin gene described.

Effect of thiol reagents on functional properties and heme oxidation in the hemoglobin of Geochelone carbonaria.

The reaction of thiol reagents with G. carbonaria hemoglobin was studied, and the oxygen equilibrium and kinetic of oxidation of derivatives determined. The oxygen affinity and kinetic of oxidation of hemoglobin derivatives were modified to various extents depending on the nature of thiol reagents used. Diamide yielded approximately 80% polymeric hemoglobin, although the oxidation kinetic, and the functional properties, were practically invariant (T1/2 = 10.0 min.; P50 = 5.0 mm Hg at pH 7.4; alkaline Bohr effect = -0.64). Iodoacetamide did not modify the electrophoretic pattern significantly, although all the free SH groups of hemoglobin were alkylated. A P50 of 2.5 mmHg at pH 7.4 and the Bohr effect of -0.15 were obtained; the T1/2 of about 6.4 min. was shorter than that for un-modified Hb. Similar T1/2 were obtained for Hb treated with oxidized glutathione, which produced polymeric Hb and glutathionyl-Hb. The oxygen binding characteristics showed that both of Hb derivatives, glutathionyl-Hb and polymeric Hb, maintain the capacity to transport the gas.

Oxygenation properties of hemoglobin from the turtle Geochelone carbonaria

The oxygen-binding properties of hemoglobin (Hb) from the adult terrestrial turtle Geochelone carbonaria are described. Turtle hemoglobins have a low intrinsic oxygen affinity and a low sensitivity to an endogenous cofactor (ATP) usually present at high concentrations in the reptile erythrocytes. The amplitude of the Bohr effect for O2 binding was virtually the same in the absence and presence of saturating ATP concentrations (deltalogP50/deltapH, about -0.60) and increased in the total hemolysate (-0.83). The large Bohr effect found in G. carbonaria Hb may be important for 02 delivery to the tissue. The degree of cooperativity displayed by Hb for 02 binding ranged between 1.5 and 2.0 in stripped solution and total hemolysate. These observations suggest the stability of the low affinity conformation, which needs to be confirmed by additional experiments.

Oxygenation properties of hemoglobin from the turtle Geochelone carbonaria.

The oxygen-binding properties of hemoglobin (Hb) from the adult terrestrial turtle Geochelone carbonaria are described. Turtle hemoglobins have a low intrinsic oxygen affinity and a low sensitivity to an endogenous cofactor (ATP) usually present at high concentrations in the reptile erythrocytes. The amplitude of the Bohr effect for O2 binding was virtually the same in the absence and presence of saturating ATP concentrations (delta logP50/delta pH, about -0.60) and increased in the total hemolysate (-0.83). The large Bohr effect found in G. carbonaria Hb may be important for O2 delivery to the tissue. The degree of cooperativity displayed by Hb for O2 binding ranged between 1.5 and 2.0 in stripped solution and total hemolysate. These observations suggest that stability of the low affinity conformation, which needs to be confirmed by additional experiments.

Bantu beta s cluster haplotype predominates among Brazilian blacks.

We describe the combination of polymorphic restriction-enzyme sites in the beta globin gene cluster (haplotypes) for 74 chromosomes from Brazilian Blacks bearing the sickle hemoglobin gene (beta s). The three most common African beta s haplotypes account for 67 chromosomes: 49/74 (66.2%) were identified as Central African Republic (CAR or Bantu) type, 17 (23.0%) as Benin, and one as Senegal; seven chromosomes (9.5%) had minor atypical haplotypes. This distribution is different from that observed in the United States or Jamaica, where the Benin haplotype predominates, and results from different patterns of slave trades to North and South Americas. Since the beta s gene cluster polymorphisms modulate the severity of sickle cell anemia, this heterogeneity may explain differences of the clinical behavior of the disease in the United States and South America, and should also be considered in relation to other features and diseases.

Polyphosphate binding sites in Liophis miliaris hemoglobin. Evidence with reduced nicotinamide adenine dinucleotide phosphate.

The water-snake Liophis miliaris presents hemoglobin which binds organic polyphosphate through a simple single-site per tetramer (Mol. Wt. 64500) as judged by titration curves of reduced nicotinamide adenine dinucleotide phosphate either in the presence or absence of inositol hexaphosphate. The site seems to have the same structural nature of that found on other hemoglobins and is able to strongly bind most of the known protein effectors such as inositol hexaphosphate, adenosine triphosphate or 2,3-diphosphoglicerate. The high association constant at pH 7 of reduced nicotinamide for the deoxy hemoglobin of about K(D) = 7 x 10(6) M-1 compared to human hemoglobin (K(D) = 7 x 10(5) M-1), and to that of adenosine triphosphate (its natural erythrocytic polyphosphate) still higher of about K(D) = 10(11) M-1, shows clearly the very high affinity of this snake hemoglobin for such allosteric effector. The results besides corroborating the dimer-tetramer transition mechanism proposed to describe the oxygen transport by the hemoglobin of Liophis miliaris--may explain the difficulties to obtain the oxy dimeric conformation of the protein by usual hemolysis and stripped off procedures.