Electrocatalytic interconversion of NADH and NAD(+) by Escherichia coli flavohemoglobin.

E. coli flavohemoglobin, oriented at electrodes via amphiphilic polymyxin B, electrocatalytically interconverts NADH and NAD(+) at its heme potentials operating as an electron transfer relay between the electrode and the protein FAD, where NADH/NAD(+) is transformed. The results are crucial for the development of NAD(+)-dependent bioelectrodes for biosynthesis, biosensors and biofuel cells.

The distal heme pocket of Escherichia coli flavohemoglobin probed by infrared spectroscopy.

The infrared absorption spectra of ferric cyanide and ferrous carbonmonoxy Escherichia coli flavohemoglobin have been measured in order to probe the fine structural properties of the distal heme pocket, characterized by the presence of a tyrosine in position B10 and a glutamine in position E7. The stretching frequency of iron bound cyanide occurs at 2136 cm(-1), an unusually high value if compared to other heme proteins. The infrared spectrum of the CO bound derivative displays two peaks centered at 1960 cm(-1) and at 1909 cm(-1) respectively. H(2)O effects have been studied in both the ferric cyanide and ferrous CO derivatives in order to establish the presence of a distal hydrogen bonding to the iron bound ligand. The observed isotope shifts indicate that in the ferric cyanide derivative a hydrogen bond is donated from a residue in the distal pocket to the biatomic ligand whereas in the ferrous carbon monoxy derivative only the 1909 cm(-1) component is most likely hydrogen bonded to the phenolic group of TyrB10.

Irreversible inhibition of pig kidney copper-containing amine oxidase by sodium and lithium ions.

Copper amine oxidase was found to be inhibited in a complex way by small alkali metal ions. Classic enzyme kinetic studies showed that Li+ and Na+ were weak noncompetitive inhibitors, whereas the larger alkali metals K+, Rb+ and Cs+ were not inhibitors. However, freezing in the presence of Na+ or Li+ surprisingly resulted in complete and irreversible inactivation. In the case of Li+, it was possible to show that one ion per subunit was retained permanently in the inactivated enzyme, suggesting a structural rearrangement. The mechanism of inhibition was studied using a wide range of spectroscopic and analytic techniques. Only minor changes in the protein structure could be detected, except for a significant change in the geometry of the copper site. The unique topaquinone cofactor was apparently functional and able to proceed through the reductive half of the catalytic cycle, but the enzyme no longer reacted with oxygen. The effect of Na+ and Li+ was source-specific for pig kidney and bovine kidney amine oxidases, while the enzymes from bovine serum or plants were not inactivated, consistent with a mechanism dependent on small structural differences. A model for irreversible inactivation is proposed in which the cofactor is co-ordinated directly to copper, in analogy with the inactivation reported for Escherichia coli amine oxidase under crystal growth conditions.

Monomer-dimer equilibrium and oxygen binding properties of ferrous Vitreoscilla hemoglobin.

The monomer-dimer equilibrium and the oxygen binding properties of ferrous recombinant Vitreoscilla hemoglobin (Vitreoscilla Hb) have been investigated. Sedimentation equilibrium data indicate that the ferrous deoxygenated and carbonylated derivatives display low values of equilibrium dimerization constants, 6 x 10(2) and 1 x 10(2) M(-1), respectively, at pH 7.0 and 10 degrees C. The behavior of the oxygenated species, as measured in sedimentation velocity experiments, is superimposable to that of the carbonylated derivative. The kinetics of O(2) combination, measured by laser photolysis at pH 7.0 and 20 degrees C, is characterized by a second-order rate constant of 2 x 10(8) M(-1) s(-1) whereas the kinetics of O(2) release at pH 7.0 is biphasic between 10 and 40 degrees C, becoming essentially monophasic below 10 degrees C. Values of the first-order rate constants (at 20 degrees C) and of the activation energies for the fast and slow phases of the Vitreoscilla Hb deoxygenation process are 4.2 s(-1) and 19.2 kcal mol(-1) and 0.15 s(-1) and 24.8 kcal mol(-1), respectively. Thus the biphasic kinetics of Vitreoscilla Hb deoxygenation is unrelated to the association state of the protein. The observed biphasic oxygen release may be accounted for by the presence of two different conformers in thermal equilibrium within the monomer. The two conformers may be assigned to a structure in which the heme-iron-bound ligand is stabilized by direct hydrogen bonding to TyrB10 and a structure in which such interaction is absent. The slow interconversion between the two conformers may reflect a very large conformational rearrangement in the disordered distal pocket segment connecting helices C and E.

The heme-globin and dimerization equilibria of recombinant human hemoglobins carrying site-specific beta chains mutations.

The heme-globin and dimer-tetramer equilibria of ferric recombinant human hemoglobins with site-specific beta chain mutations at the heme pocket or at either the a1beta1 or the alpha1beta2 interfaces have been determined. The heme pocket mutation V67T leads to a marked stabilization of the beta chain heme and does not affect the dimer-tetramer association constant, K2,4. In the C112 mutants, the intrinsic rate of beta chain heme loss with respect to recombinant HbA (HbA-wt) is significantly increased only in C112G with some heme released also from the alpha chains. Gel filtration experiments indicate that the K2,4 value is essentially unaltered in C112G and C112L, but is increased in C112V and decreased in C112N. Substitution of cysteine 93 with A or M leads to a slight decrease of the rate of beta chain heme release, whereas the obvserved K2,4 value is similar to that obtained for HbA-wt. Modifications in oxygen affinity were observed in all the mutant hemoglobins with the exception of V67T, C93A, and C112G. The data indicate that there is no correlation between tetramer stability, beta chain heme affinity, and hemoglobin functionality and therefore point to a separate regulation of these properties.

Hagfish hemoglobins: structure, function, and oxygen-linked association.

Cyclostomes, hagfishes and lampreys, contain hemoglobins that are monomeric when oxygenated and polymerize to dimers or tetramers when deoxygenated. The three major hemoglobin components (HbI, HbII, and HbIII) from the hagfish Myxine glutinosa have been characterized and compared with lamprey Petromyzon marinus HbV, whose x-ray crystal structure has been solved in the deoxygenated, dimeric state (Heaslet, H. A., and Royer, W. E., Jr. (1999) Structure 7, 517-526). Of these three, HbII bears the highest sequence similarity to P. marinus HbV. In HbI and HbIII the distal histidine is substituted by a glutamine residue and additional substitutions occur in residues located at the deoxy dimer interface of P. marinus HbV. Infrared spectroscopy of the CO derivatives, used to probe the distal pocket fine structure, brings out a correlation between the CO stretching frequencies and the rates of CO combination. Ultracentrifugation studies show that HbI and HbIII are monomeric in both the oxygenated and deoxygenated states under all conditions studied, whereas deoxy HbII forms dimers at acidic pH values, like P. marinus HbV. Accordingly, the oxygen affinities of HbI and HbIII are independent of pH, whereas HbII displays a Bohr effect below pH 7.2. HbII also forms heterodimers with HbIII and heterotetramers with HbI. The functional counterparts of heteropolymer formation are cooperativity in oxygen binding and the oxygen-linked binding of protons and bicarbonate. The observed effects are explained on the basis of the x-ray structure of P. marinus HbV and the association behavior of site-specific mutants (Qiu, Y., Maillett, D. H., Knapp, J., Olson, J. S., and Riggs, A. F. (2000) J. Biol. Chem. 275, 13517-13528).

Plasticity of secondary structure in the N-terminal region of beta-dystroglycan.

The secondary structure content of the N-terminal extracellular domain of beta-dystroglycan (a recombinant fragment extending from positions 654 to 750) has been quantitatively determined by means of CD and FTIR spectroscopies. The elements of secondary structure, namely an 8-10 residue long alpha-helix (10%) and two beta-strands (24%) have been assigned to specific amino acid sequences by means of a GOR constrained prediction method. The remaining 66% of the whole sequence is classified as turns or unordered. The temperature dependence of CD and FTIR spectra has been investigated in detail. A reversible, non-cooperative thermal transition is observed with both CD and FTIR spectroscopies up to 95 degrees C. The profile of the transition is typical of the unfolding of isolated peptides and corresponds to the progressive loss of the secondary structure elements of the protein with no evidence for collapsing phenomena, typical of globular proteins, upon heating.

Secondary structure and post-translational modifications of the leucine-rich repeat protein PGIP (polygalacturonase-inhibiting protein) from Phaseolus vulgaris.

A detailed analysis of the secondary structure has been carried out on the polygalacturonase-inhibiting protein (PGIP) from Phaseolus vulgaris, a leucine-rich repeat (LRR) protein present in the cell wall of many plants. Far-UV CD and infrared spectroscopies coupled to constrained secondary structure prediction methods indicated the presence of 12 alpha- and 12 beta-segments, thus allowing a schematic representation of three domains of the protein, namely, the central LRR region and the two cysteine-rich flanking domains. Peptides from endoproteinase-degraded PGIP were analyzed by mass spectrometry, and four disulfide bonds were identified. Mass spectrometric analysis in combination with glycosidase treatments revealed two N-linked oligosaccharides located on Asn 64 and Asn 141. The main structure resembled the typical complex plant N-glycan consisting of a core pentasaccharide beta1,2-xylosylated, carrying an alpha1,3-fucose linked to the innermost N-acetylglucosamine and one outer arm N-acetylglucosamine residue. The schematic representation of PGIP structural domains is discussed in the framework of the structure and function of LRR proteins.

Determination of H(2)S solubility via the reaction with ferric hemoglobin I from the bivalve mollusc Lucina pectinata.

A new, simple and fast spectrophotometric method for the determination of the H(2)S concentration is reported. This method, based on the 1:1 reaction between H(2)S and the ferric derivative of hemoglobin I (HbI) from the bivalve mollusc Lucina pectinata, allows the quantitative determination of H(2)S dissolved in a given solution even at concentrations as low as 1 x 10(-6) M. Note that L. pectinata HbI is considered the physiological receptor of H(2)S.

Structural and thermodynamic aspects of cooperativity in the homodimeric hemoglobin from Scapharca inaequivalvis.

The homodimeric cooperative hemoglobin from the mollusk Scapharca inaequivalvis displays an unusual subunit assembly with respect to vertebrate hemoglobins. The intersubunit contact region is formed by the two heme-carrying E and F helices, which bring the two hemes in contact with each other. At variance with tetrameric vertebrate hemoglobins, the ligand binding is not accompanied by a significant quaternary transition. The major ligand-linked changes are tertiary and are limited to the heme pocket and subunit interface. These unique structural features of HbI are not easily reconciled with the classical thermodynamic models used to describe cooperative ligand binding in vertebrate hemoglobins. The lack of distinct quaternary states and the absence of allosteric effectors suggested that cooperativity in HbI is entirely homotropic in origin. Thereafter, high resolution X-ray crystallographic data displayed the preferential binding of water molecules at the intersubunit interface in the unliganded protein with respect to the liganded one. These ordered water molecules were thus proposed to act as heterotropic effectors in HbI. The contribution of specific water binding to the observed cooperativity in HbI is discussed in the framework of the enthalpy-entropy compensation effect emerging from previous accurate equilibrium oxygen binding measurements.

Heme symmetry, vibronic structure, and dynamics in heme proteins: ferrous nicotinate horse myoglobin and soybean leghemoglobin.

We report the visible and Soret absorption bands, down to cryogenic temperatures, of the ferrous nicotinate adducts of native and deuteroheme reconstituted horse heart myoglobin in comparison with soybean leghemoglobin-a. The band profile in the visible region is analyzed in terms of vibronic coupling of the heme normal modes to the electronic transition in the framework of the Herzberg-Teller approximation. This theoretical approach makes use of the crude Born-Oppenheimer states and therefore neglects the mixing between electronic and vibrational coordinates; however, it takes into account the vibronic nature of the visible absorption bands and allows an estimate of the vibronic side bands for both Condon and non-Condon vibrational modes. In this framework, an x-y splitting of the Q transition for native and deuteroheme reconstituted horse myoglobin is clearly assessed and attributed to electronic perturbations that, in turn, are caused by a reduction of the typical D(4h) symmetry of the system due to heme distortions of B(1g)-type symmetry and/or to an x-y asymmetric position of the nicotinate ring; in deuteroheme reconstituted horse myoglobin the asymmetric heme peripheral substituents add to the above effect(s). On the contrary, in leghemoglobin-a no spectral splitting upon nicotinate binding is observed, pointing to a planar heme configuration in which only distortions of A(1g)-type symmetry are effective and to which the nicotinate ring is bound in an x - y symmetric position. The local dynamic properties of the heme pocket of the three proteins are investigated through the temperature dependence of spectral line broadening. Leghemoglobin-a behaves as a softer matrix with respect to horse myoglobin, thus validating the hypothesis of a looser heme pocket conformation in the former protein, which allows a nondistorted heme configuration and a symmetric binding of the bulky nicotinate ligand.

Proximal and distal effects on the coordination chemistry of ferric Scapharca homodimeric hemoglobin as revealed by heme pocket mutants.

The ferric form of the homodimeric hemoglobin from Scapharca inaequivalvis (HbI) displays a unique pH-dependent behavior involving the interconversion among a monomeric low-spin hemichrome, a dimeric high-spin aquomet six-coordinate derivative, and a dimeric high-spin five-coordinate species that prevail at acidic, neutral, and alkaline pH values, respectively. In the five-coordinate derivative, the iron atom is bound to a hydroxyl group on the distal side since the proximal Fe-histidine bond is broken, possibly due to the packing strain exerted by the Phe97 residue on the imidazole ring [Das, T. K., Boffi, A., Chiancone, E. and Rousseau, D. L. (1999) J. Biol. Chem. 274, 2916-2919]. To determine the proximal and distal effects on the coordination and spin state of the iron atom and on the association state, two heme pocket mutants have been investigated by means of optical absorption, resonance Raman spectroscopy, and analytical ultracentrifugation. Mutation of the distal histidine to an apolar valine causes dramatic changes in the coordination and spin state of the iron atom that lead to the formation of a five-coordinate derivative, in which the proximal Fe-histidine bond is retained, at acidic pH values and a high-spin, hydroxyl-bound six-coordinate derivative at neutral and alkaline pH values. At variance with native HbI, the His69 --> Val mutant is always high-spin and does not undergo dissociation into monomers at acidic pH values. The Phe97 --> Leu mutant, like the native protein, forms a monomeric hemichrome species at acidic pH values. However, at alkaline pH, it does not give rise to the unusual hydroxyl-bound five-coordinate derivative but forms a six-coordinate derivative with the proximal His and distal hydroxyl as iron ligands.

Ligand-linked changes at the subunit interfaces in Scapharca hemoglobins probed through the sulfhydryl infrared absorption.

FTIR spectra of native Scapharca homodimeric hemoglobin (HbI) and of the Phe97-->Ile mutant have been measured in the region 2400-2700 cm(-1) where the absorption of the sulfhydryl groups can be observed. In native HbI, the two Cys92 residues give rise to a relatively intense band centered at 2559 cm(-1) that is shifted to 2568 cm(-1) and strongly quenched upon ligand binding. In the Phe97-->Leu mutant, such ligand-linked changes are not observed and the strong peak at around 2560 cm(-1) persists in the liganded derivatives. In native HbI, the observed changes have been attributed to the decrease in polarity of the interface due to the ligand-induced extrusion of the Phe97 phenyl ring from the heme pocket to the interface and the subsequent release of several water molecules that are clustered in the vicinity of Cys92. In contrast, in the Phe97-->Leu mutant, the Leu residue does not leave the heme pocket upon ligand binding and the interface is unaltered. The Cys92/S-H infrared band, therefore, represents a sensitive probe of the structural rearrangements that take place in the intersubunit interface upon ligand binding to HbI. The heterotetrameric Scapharca hemoglobin HbII contains, in addition to the Cys92 residues in the interfaces, two extra sulfhydryl groups per tetramer (Cys9 in the B chain) that are exposed to solvent in the A helix. The frequency of the Cys9/S-H stretching vibration occurs at 2582 cm(-1) in the unliganded and at 2586 cm(-1) in the liganded derivative, pointing to the involvement of the A helix in the ligand-linked polymerization characteristic of HbII.

Anticooperative ligand binding properties of recombinant ferric Vitreoscilla homodimeric hemoglobin: a thermodynamic, kinetic and X-ray crystallographic study.

Thermodynamics and kinetics for cyanide, azide, thiocyanate and imidazole binding to recombinant ferric Vitreoscilla sp. homodimeric hemoglobin (Vitreoscilla Hb) have been determined at pH 6.4 and 7.0, and 20.0 degrees C, in solution and in the crystalline state. Moreover, the three-dimensional structures of the diligated thiocyanate and imidazole derivatives of recombinant ferric Vitreoscilla Hb have been determined by X-ray crystallography at 1.8 A (Rfactor=19.9%) and 2.1 A (Rfactor=23.8%) resolution, respectively. Ferric Vitreoscilla Hb displays an anticooperative ligand binding behaviour in solution. This very unusual feature can only be accounted for by assuming ligand-linked conformational changes in the monoligated species, which lead to the observed 300-fold decrease in the affinity of cyanide, azide, thiocyanate and imidazole for the monoligated ferric Vitreoscilla Hb with respect to that of the fully unligated homodimer. In the crystalline state, thermodynamics for azide and imidazole binding to ferric Vitreoscilla Hb may be described as a simple process with an overall ligand affinity for the homodimer corresponding to that for diligation in solution. These data suggest that the ligand-free homodimer, observed in the crystalline state, is constrained in a low affinity conformation whose ligand binding properties closely resemble those of the monoligated species in solution. From the kinetic viewpoint, anticooperativity is reflected by the 300-fold decrease of the second-order rate constant for cyanide and imidazole binding to the monoligated ferric Vitreoscilla Hb with respect to that for ligand association to the ligand-free homodimer in solution. On the other hand, values of the first-order rate constant for cyanide and imidazole dissociation from the diligated and monoligated derivatives of ferric Vitreoscilla Hb in solution are closely similar. As a whole, ligand binding and structural properties of ferric Vitreoscilla Hb appear to be unique among all Hbs investigated to date.

Cyanide binding to Lucina pectinata hemoglobin I and to sperm whale myoglobin: an x-ray crystallographic study.

The x-ray crystal structures of the cyanide derivative of Lucina pectinata monomeric hemoglobin I (L. pectinata HbI) and sperm whale (Physeter catodon) myoglobin (Mb), generally taken as reference models for monomeric hemoproteins carrying hydrogen sulfide and oxygen, respectively, have been determined at 1.9 A (R-factor = 0. 184), and 1.8 A (R-factor = 0.181) resolution, respectively, at room temperature (lambda = 1.542 A). Moreover, the x-ray crystal structure of the L. pectinata HbI:cyanide derivative has been studied at 1.4-A resolution (R-factor = 0.118) and 100 K (on a synchrotron source lambda = 0.998 A). At room temperature, the cyanide ligand is roughly parallel to the heme plane of L. pectinata HbI, being located approximately 2.5 A from the iron atom. On the other hand, the crystal structure of the L. pectinata HbI:cyanide derivative at 100 K shows that the diatomic ligand is coordinated to the iron atom in an orientation almost perpendicular to the heme (the Fe-C distance being 1.95 A), adopting a coordination geometry strictly reminescent of that observed in sperm whale Mb, at room temperature. The unusual cyanide distal site orientation observed in L. pectinata HbI, at room temperature, may reflect reduction of the heme Fe(III) atom induced by free radical species during x-ray data collection using Cu Kalpha radiation.

Pentacoordinate hemin derivatives in sodium dodecyl sulfate micelles: model systems for the assignment of the fifth ligand in ferric heme proteins.

Ferric iron protoporhyrin IX derivatives in SDS micelles have been investigated by means of visible absorption, resonance Raman, and XANES spectroscopies to establish specific correlations between the marker bands of the pentacoordinate derivatives obtained from the three different techniques. Hydroxyl and 1,2-dimethyl imidazole coordinated hemins display the typical spectroscopic marker bands of a pentacoordinate high-spin ferric iron derivative in both Raman and XANES spectra. In turn, the optical absorption spectra of these two derivatives are very different. This difference is in line with the assignment of hydroxyl as the fifth coordination ligand to free hemin in SDS micelles, as demonstrated by the isotopic shift of the frequency of Fe-OH bond with H(2)(18)O. The present assignments are relevant to the identification of the coordination state and the nature of the fifth ligand in ferric heme proteins.

Hydroxide rather than histidine is coordinated to the heme in five-coordinate ferric Scapharca inaequivalvis hemoglobin.

The ferric form of the homodimeric Scapharca hemoglobin undergoes a pH-dependent spin transition of the heme iron. The transition can also be modulated by the presence of salt. From our earlier studies it was shown that three distinct species are populated in the pH range 6-9. At acidic pH, a low-spin six-coordinate structure predominates. At neutral and at alkaline pHs, in addition to a small population of a hexacoordinate high-spin species, a pentacoordinate species is significantly populated. Isotope difference spectra clearly show that the heme group in the latter species has a hydroxide ligand and thereby is not coordinated by the proximal histidine. The stretching frequency of the Fe-OH moiety is 578 cm-1 and shifts to 553 cm-1 in H218O, as would be expected for a Fe-OH unit. On the other hand, the ferrous form of the protein shows substantial stability over a wide pH range. These observations suggest that Scapharca hemoglobin has a unique heme structure that undergoes substantial redox-dependent rearrangements that stabilize the Fe-proximal histidine bond in the functional deoxy form of the protein but not in the ferric form.

Immobilized human hemoglobin, a versatile matrix for analytical and biotechnological applications.

The analytical and biotechnological applications of human hemoglobin immobilized covalently on CNBr-Sepharose 4B are reviewed. Hemoglobin is bound to the matrix as alphabeta dimers via either chain. The immobilized alphabeta dimers maintain the capacity to interact reversibly with soluble ones under conditions where the soluble protein is in self-association equilibrium. Under these conditions, therefore, immobilized dimers bind part of the soluble protein. In turn, the binding process can be used to assess the specific features of the equilibrium on solid-phase and to extract selectively hemoglobin from a variety of biological specimens of practical interest. A different application of immobilized alphabeta dimers concerns their use in the determination of the equilibrium and kinetic stability of the heme-globin linkage, a property that is directly correlated with the stability of the hemoglobin molecule. The advantages and limitations attendant the use of the immobilized protein relative to the soluble one are discussed.

The apolar distal histidine mutant (His69-->Val) of the homodimeric Scapharca hemoglobin is in an R-like conformation.

The effect of the apolar mutation of the distal histidine (His69-->Val) has been studied in the cooperative homodimeric hemoglobin from the mollusc Scapharca inaequivalvis. Absorption, circular dichroism, and resonance Raman spectroscopy point to a more symmetric heme structure of the deoxy derivative, which is indicative of an R-like conformation of the deoxy heme. Resonance Raman spectroscopy also brings out alterations in the geometry and interactions of the bound CO molecule. The iron-carbon stretching frequency is decreased by about 30 cm-1 with respect to the native protein, while the diatomic ligand stretching frequency is increased by about the same degree. Consistent with the structural changes, the ligand binding properties are significantly altered. In the mutant the overall rate and the affinity for CO binding are increased about 100-fold with respect to the native protein, and cooperativity is abolished. In addition, the amplitude and the rate of the geminate rebinding process increase significantly. This finding may be correlated to the longer average residence time of the photolyzed CO molecule within the heme pocket of the H69V mutant, as indicated by molecular dynamics simulations.

Immobilized apo-myoglobin, a new stable reagent for measuring rates of heme dissociation from hemoglobin.

Apo-myoglobin covalently linked on CNBr-activated Sepharose 4B is proposed as a new heme acceptor for investigating the heme transfer reaction from hemoproteins. Immobilized apo-myoglobin has the desirable properties of an ideal heme acceptor in that it is characterized by a high affinity for ferric heme, a high stability towards denaturation even at physiological temperatures and can be lyophilized for long-term storage. The study of heme release from myoglobin at pH 5.0 and 37 degrees C indicates that heme affinity is increased at least 10-fold relative to the soluble protein. Experiments with human hemoglobin allowed the estimation of the heme release rates from both alpha and beta chains and brought out the greater temperature sensitivity of the alpha chain heme-globin linkage.