The leghemoglobin proximal heme pocket directs oxygen dissociation and stabilizes bound heme

Sperm whale myoglobin (Mb) and soybean leghemoglobin (Lba) are two small, monomeric hemoglobins that share a common globin fold but differ widely in many other aspects. Lba has a much higher affinity for most ligands, and the two proteins use different distal and proximal heme pocket regulatory mechanisms to control ligand binding. Removal of the constraint provided by covalent attachment of the proximal histidine to the F-helices of these proteins decreases oxygen affinity in Lba and increases oxygen affinity in Mb, mainly because of changes in oxygen dissociation rate constants. Hence, Mb and Lba use covalent constraints in opposite ways to regulate ligand binding. Swapping the F-helices of the two proteins brings about similar effects, highlighting the importance of this helix in proximal heme pocket regulation of ligand binding. The F7 residue in Mb is capable of weaving a hydrogen-bonding network that holds the proximal histidine in a fixed orientation. On the contrary, the F7 residue in Lba lacks this property and allows the proximal histidine to assume a conformation favorable for higher ligand binding affinity. Geminate recombination studies indicate that heme iron reactivity on picosecond timescales is not the dominant cause for the effects observed in each mutation. Results also indicate that in Lba the proximal and distal pocket mutations probably influence ligand binding independently. These results are discussed in the context of current hypotheses for proximal heme pocket structure and function.     

Tyrosine B10 inhibits stabilization of bound carbon monoxide and oxygen in soybean leghemoglobin

Detailed comparisons of the carbon monoxide FTIR spectra and ligand-binding properties of a library of E7, E11, and B10 mutants indicate significant differences in the role of electrostatic interactions in the distal pockets of wild-type sperm whale myoglobin and soybean leghemoglobin. In myoglobin, strong hydrogen bonds from several closely related conformations of the distal histidine (His(E7)) side chain preferentially stabilize bound oxygen. In leghemoglobin, the imidazole side chain of His(E7) is confined to a single conformation, which only weakly hydrogen bonds to bound ligands. The phenol side chain of Tyr(B10) appears to "fix" the position of His(E7), probably by donating a hydrogen bond to the Ndelta atom of the imidazole side chain. The proximal pocket of leghemoglobin is designed to favor strong coordination bonds between the heme iron and axial ligands. Thus, high oxygen affinity in leghemoglobin is established by a favorable staggered geometry of the proximal histidine. The interaction between His(E7) and Tyr(B10) prevents overstabilization of bound oxygen. If hydrogen bonding from His(E7) were as strong as it is in mammalian myoglobin, the resultant ultrahigh affinity of leghemoglobin would prevent oxygen transport in root nodules.     

NMR studies of the conformations of leghemoglobins from soybean and lupin

Phase-sensitive two-dimensional NMR methods have been used to obtain extensive proton resonance assignments for the carbon monoxide complexes of lupin leghemoglobins I and II and soybean leghemoglobin a. The assigned resonances provide information on the solution conformations of the proteins, particularly in the vicinity of the heme. The structure of the CO complex of lupin leghemoglobin II in solution is compared with the X-ray crystal structure of the cyanide complex by comparison of observed and calculated ring current shifts. The structures are generally very similar but significant differences are observed for the ligand contact residues, Phe30, His63 and Val67, and for the proximal His97 ligand. Certain residues are disordered and adopt two interconverting conformations in lupin leghemoglobin II in solution. The proximal heme pocket structure is closely conserved in the lupin leghemoglobins I and II but small differences in conformation in the distal heme pocket are apparent. Larger conformational differences are observed when comparisons are made with the CO complex of soybean leghemoglobin. Altered protein-heme packing is indicated on the proximal side of the heme and some conformational differences are evident in the distal heme pocket. The small conformational differences between the three leghemoglobins probably contribute to the known differences in their O2 and CO association and dissociation kinetics. The heme pocket conformations of the three leghemoglobins are more closely related to each other than to sperm whale myoglobin. The most notable differences between the leghemoglobins and myoglobin are: (a) reduced steric crowding of the ligand binding site in the leghemoglobins, (b) different orientations of the distal histidine, and (c) small but significant differences in proximal histidine coordination geometry. These changes probably contribute to the large differences in ligand binding kinetics between the leghemoglobins and myoglobin.     

Circular dichroism studies of myoglobin and leghemoglobin.

The circular dichroism spectra of leghemoglobin a from the root nodules of soybean have been compared with those for sperm whale myoglobin in the fat- and near-ultraviolet and the Soret and visible regions of the spectrum. Circular dichroism spectra in the far-ultraviolet show that the leghemoglobins all have a high alpha-helix content (soybean leghemoglobin a, 55%) regardless of the nature of bound ligands and oxidation or spin state of the heme iron. The known sequence homologies with mammalian hemoglobins may therefore be reflected in conformational homologies as suggested by the x-ray studies of Vainshtein et al. ((1975) Nature (London) 254, 163-164) on lupin leghemoglobin. Removal of the heme moiety decreases helicity by only 9% for leghemoglobins, compared with 23% for myoglobin. This, the much smaller heme contribution to the near-ultraviolet circular dichroism than in myoglobin, and the greater accessibility of the heme moiety to aqueous solvent (Nicola et al. (1974), Proc. Aust. Biochem. Soc. 7, 21) suggest that the association between heme and protein is much weaker in leghemoglobins than in myoglobin. The aromatic Soret and visible circular dichroism spectra for all derivatives of leghemoglobin are opposite in sense to those for myoglobin, showing that the patterns of protein side chain contacts with the heme are different in the two classes of heme proteins. There is strong evidence that one of the two tryptophans whose identity and structural role in myoglobin is known, is present also in plant leghemoglobins, hydrogen-bonded and in a similar nonpolar environment whether heme is present or not. The above findings help to explain the remarkably high oxygen affinity and some other ligand-binding properties of leghemoglobins which differ from those of myoglobin.     

Discrimination between oxygen and carbon monoxide and inhibition of autooxidation by myoglobin. Site-directed mutagenesis of the distal histidine

Sperm whale myoglobin mutants were constructed using site-directed mutagenesis to replace the highly conserved distal histidine residue (His(E7)-64). His-64 was substituted with Gly, Val, Phe, Cys, Met, Lys, Arg, Asp, Thr, and Tyr, and all 10 mutant proteins expressed to approximately 10% of the total soluble cell protein in Escherichia coli as heme containing myoglobin. With the exception of His-64----Tyr, which did not form a stable oxygen (O2) complex, all mutant proteins could be reduced and bound O2 and carbon monoxide (CO) reversibly. However, removal of the distal histidine increased the rate of autooxidation 40-350-fold. The His-64----Gly, Val, Phe, Met, and Arg mutants all showed markedly increased O2 dissociation rate constants which were approximately 50-1500-fold higher than those for wild-type myoglobin and increased O2 association rate constants which were approximately 5-15-fold higher than those for the native protein. All mutants studied (except His-64----Tyr) showed approximately 10-fold increased CO association rates and relatively unchanged CO dissociation rates. These altered O2 and CO association and dissociation rate constants resulted in 3-14-fold increased CO affinities, 10-200-fold decreased O2 affinities, and 50-380-fold greater M (KCO/KO2) values for the mutants compared to the wild-type protein. Thus, the distal histidine of myoglobin discriminates between CO and O2 binding by both sterically hindering bound CO and stabilizing bound O2 through hydrogen bonding. The increased autooxidation rates observed for the mutants appear to be due to a decrease in oxygen affinity and an increase in solvent anion accessibility to the distal pocket.     

Dynamics of dioxygen and carbon monoxide binding to soybean leghemoglobin

The association of dioxygen and carbon monoxide to soybean leghemoglobin (Lb) has been studied by laser flash photolysis at temperatures from 10 to 320 K and times from 50 ns to 100 s. Infrared spectra of the bound and the photodissociated state were investigated between 10 and 20 K. The general features of the binding process in leghemoglobin are similar to the ones found in myoglobin. Below about 200 K, the photodissociated ligands stay in the heme pocket and rebinding is not exponential in time, implying a distributed enthalpy barrier between pocket and heme. At around 300 K, ligands migrate from the solvent through the protein to the heme pocket, and a steady state is set up between the ligands in the solvent and in the heme pocket. The association rate, lambda on, is mainly controlled by the final binding step at the heme, the bond formation with the heme iron. Differences between Lb and other heme proteins show up in the details of the various steps. The faster association rate in Lb compared to sperm whale myoglobin (Mb) is due to a faster bond formation. The migration from the solvent to the heme pocket is much faster in Lb than in Mb. The low-temperature binding (B----A) and the infrared spectra of CO in the bound state A and the photodissociated state B are essentially solvent-independent in Mb, but depend strongly on solvent in Lb. These features can be correlated with the x-ray structure.     

EPR characterization of the stereochemistry of the distal heme pocket of the engineered human myoglobin mutants.

Recombinant human myoglobin mutants with the distal histidine residue replaced by Leu, Val, or Gln residues have been prepared by site-directed mutagenesis and expression in Escherichia coli. The recombinant apomyoglobin proteins have been successfully reconstituted with cobaltous protoporphyrin IX to obtain cobalt myoglobin mutant proteins, and the role of the distal histidine residue on the interaction between the bound ligand and the myoglobin molecule has been studied by EPR spectroscopy. We found that the distal histidine residue is significant in the orientation of the bound oxygen molecule. Low temperature photolysis experiments on both oxy cobalt proteins and ferric nitric oxide complexes indicated that the nature of the photolyzed form depends on the steric crowding of the distal heme pocket. To our surprise, the distal Leu mutant has a less restricted, less sterically crowded distal heme pocket than that of the distal Val mutant myoglobin, despite the fact that Leu has a larger side chain volume than Val. Our results demonstrate that the distal heme pocket steric crowding is not necessarily related to the side chain volume of the E7 residue.     

Residue F4 plays a key role in modulating oxygen affinity and cooperativity in Scapharca dimeric hemoglobin

Residue F4 (Phe 97) undergoes the most dramatic ligand-linked transition in Scapharca dimeric hemoglobin, with its packing in the heme pocket in the unliganded (T) state suggested to be a primary determinant of its low affinity. Mutation of Phe 97 to Leu (previously reported), Val, and Tyr increases oxygen affinity from 8- to 100-fold over that of the wild type. The crystal structures of F97L and F97V show side chain packing in the heme pocket for both R and T state structures. In contrast, in the highest-affinity mutation, F97Y, the tyrosine side chain remains in the interface (high-affinity conformation) even in the unliganded state. Comparison of these mutations reveals a correlation between side chain packing in the heme pocket and oxygen affinity, indicating that greater mass in the heme pocket lowers oxygen affinity due to impaired movement of the heme iron into the heme plane. The results indicate that a key hydrogen bond, previously hypothesized to have a central role in regulation of oxygen affinity, plays at most only a small role in dictating ligand affinity. Equivalent mutations in sperm whale myoglobin alter ligand affinity by only 5-fold. The dramatically different responses to mutations at the F4 position result from subtle, but functionally critical, stereochemical differences. In myoglobin, an eclipsed orientation of the proximal His relative to the A and C pyrrole nitrogen atoms provides a significant barrier for high-affinity ligand binding. In contrast, the staggered orientation of the proximal histidine found in liganded HbI renders its ligand affinity much more susceptible to packing contacts between F4 and the heme group. These results highlight very different strategies used by cooperative hemoglobins in molluscs and mammals to control ligand affinity by modulation of the stereochemistry on the proximal side of the heme.     

Molecular dynamics simulations indicate that tyrosineB10 limits motions of distal histidine to regulate CO binding in soybean leghemoglobin

Myoglobin (Mb) uses strong electrostatic interaction in its distal heme pocket to regulate ligand binding. The mechanism of regulation of ligand binding in soybean leghemoglobin a (Lba) has been enigmatic and more so due to the absence of gaseous ligand bound atomic resolution three‐dimensional structure of the plant globin. While the 20‐fold higher oxygen affinity of Lba compared with Mb is required for its dual physiological function, the mechanism by which this high affinity is achieved is only emerging. Extensive mutational analysis combined with kinetic and CO‐FT‐IR spectroscopic investigation led to the hypothesis that Lba depended on weakened electrostatic interaction between distal HisE7 and bound ligand achieved by invoking B10Tyr, which itself hydrogen bonds with HisE7 thus restricting it in a single conformation detrimental to Mb‐like strong electrostatic interaction. Such theory has been re‐assessed here using CO‐Lba in silico model and molecular dynamics simulation. The investigation supports the presence of at least two major conformations of HisE7 in Lba brought about by imidazole ring flip, one of which makes hydrogen bonds effectively with B10Tyr affecting the former's ability to stabilize bound ligand, while the other does not. However, HisE7 in Lba has limited conformational freedom unlike high frequency of imidazole ring flips observed in Mb and in TyrB10Leu mutant of Lba. Thus, it appears that TyrB10 limits the conformational freedom of distal His in Lba, tuning down ligand dissociation rate constant by reducing the strength of hydrogen bonding to bound ligand, which the freedom of distal His of Mb allows. Proteins 2015; 83:1836–1848. © 2015 Wiley Periodicals, Inc.     

A comparison of the geminate recombination kinetics of several monomeric heme proteins

The geminate rate constants for CO, O2, NO, methyl, ethyl, n-propyl, and n-butyl isocyanide rebinding to soybean leghemoglobin and monomeric component II of Glycera dibranchiata hemoglobin were measured at pH 7, 20 degrees C using a dye laser with a 30-ns square-wave pulse. The results were compared to the corresponding parameters for sperm whale myoglobin and the isolated alpha and beta subunits of human hemoglobin (Olson, J.S., Rohlfs, R.J., and Gibson, Q.H. (1987) J. Biol. Chem., 262, 12930-12938). The rate-limiting step for O2, NO, and isonitrile binding to all five proteins is ligand migration up to the initial geminate state, and the rate of this process determines the overall bimolecular association rate constant for these ligands. In contrast, iron-ligand bond formation limits the overall bimolecular rate for CO binding. The distal pockets in leghemoglobin and in Glycera HbII are approximately 10 times more accessible kinetically to diatomic ligands than that in sperm whale myoglobin. This difference accounts for the much larger association rate constants (1-2 x 10(8) M-1 s-1) that are observed for O2 and NO binding to leghemoglobin and Glycera HbII. The rates of isonitrile migration through leghemoglobin are also very large and indicate a very fluid or open distal structure near the sixth coordination position. In contrast, there is a marked decrease in the rate of migration up to and away from the sixth coordination position in Glycera HbII with increasing ligand size. These results were also used to interpret previously published rate constants and quantum yields for the high (R) and low (T) affinity states of human hemoglobin. In contrast to the differences between the monomeric proteins, the differences between the CO-, O2-, and NO-binding parameters for R and T state hemoglobin appear to be due to a decrease in the geminate reactivity of the heme iron atom, with little or no change in the accessibility of the distal pocket.     

Transient spectroscopy of the reaction of cyanide with ferrous myoglobin. Effect of distal side residues

The reaction of cyanide metmyoglobin with dithionite conforms to a two-step sequential mechanism with formation of an unstable intermediate, identified as cyanide bound ferrous myoglobin. This reaction was investigated by stopped-flow time resolved spectroscopy using different myoglobins, i.e. those from horse heart, Aplysia limacina buccal muscle, and three recombinant derivatives of sperm whale skeletal muscle myoglobin (Mb) (the wild type and two mutants). The myoglobins from horse and sperm whale (wild type) have in the distal position (E7) a histidyl residue, which is missing in A. limacina Mb as well as the two sperm whale mutants (E7 His----Gly and E7 His----Val). All these proteins in the reduced form display an extremely low affinity for cyanide at pH less than 10. The differences in spectroscopy and kinetics of the ferrous cyanide complex of these myoglobins indicate a role of the distal pocket on the properties of the complex. The two mutants of sperm whale Mb are characterized by a rate constant for the decay of the unstable intermediate much faster than that of the wild type, at all pH values explored. Therefore, we envisage a specific role of the distal His (E7) in controlling the rate of cyanide dissociation and also find that this effect depends on the protonation of a single ionizable group, with pK = 7.2, attributed to the E7 imidazole ring. The results on A. limacina Mb, which displays the slowest rate of cyanide dissociation, suggests that a considerable stabilizing effect can be exerted by Arg E10 which, according to Bolognesi et al. (Bolognesi, M., Coda, A., Frigerio, F., Gatti, C., Ascenzi, P., and Brunori, M. (1990) J. Mol. Biol. 213, 621-625), interacts inside the pocket with fluoride bound to the ferric heme iron. A mechanism of control for the rate of dissociation of cyanide from ferrous myoglobin, involving protonation of the bound anion, is discussed.     

Hydrogen bonding interaction of the amide group of Asn and Gln at distal E7 of bovine myoglobin with bound-ligand and its functional consequences.

Asn and Gln with an amide group at gamma- and delta-positions, respectively, were substituted for distal His-E7 of bovine myoglobin to establish a system where hydrogen bonding interaction between the distal residue and bound-ligand can be altered by changing donor-acceptor distance. Two mutant myoglobins showed nearly identical (1)H-NMR spectral pattern for resolved heme peripheral side-chain and amino acid proton signals and similar two-dimensional NMR connectivities irrespective of cyanide-bound and -unbound states, indicating that the heme electronic structure and the molecular structure of the active site are not affected by a difference in one methylene group at the E7 position. Chemical exchange rate of Asn-E7 N(delta)H proton in met-cyano myoglobin is larger than that of Gln-E7 N(epsilon)H proton by at least two orders of magnitude, suggesting a considerable difference in the strength of hydrogen bond between the E7 side-chain and bound-ligand, due to the differential donor-acceptor distance between the two mutants. Thus a comparative study between the two proteins provides an ideal system to delineate a relationship between the stabilization of bound-ligand by the hydrogen bond and myoglobin's ligand affinity. The Asn-mutant showed a faster dissociation of cyano ion from met-myoglobin than the Gln-mutant by over 30-fold. Similarly, oxygen dissociation is faster in the Asn-mutant than in the Gln-mutant by approximately 100-fold. Association of cyanide anion to the mutant met-myoglobin was accelerated by changing Gln to Asn by a 4-fold. Likewise, oxygen binding was accelerated by approximately 2-fold by the above substitution. The present findings confirm that hydrogen bonding with the distal residue is a dominant factor for determining the ligand dissociation rate, whereas steric hindrance exerted by the distal residue is a primary determinant for the ligand association.     

Distal pocket polarity in ligand binding to myoglobin: structural and functional characterization of a threonine68(E11) mutant

Site-directed mutagenesis studies have confirmed that the distal histidine in myoglobin stabilizes bound O2 by hydrogen bonding and have suggested that it is the polar character of the imidazole side chain rather than its size that limits the rate of ligand entry into the protein. We constructed an isosteric Val68 to Thr replacement in pig myoglobin (i) to investigate whether the O2 affinity could be increased by the introduction of a second hydrogen-bonding group into the distal heme pocket and (ii) to examine the influence of polarity on the ligand binding rates more rigorously. The 1.9-A crystal structure of Thr68 aquometmyoglobin confirms that the mutant and wild-type proteins are essentially isostructural and reveals that the beta-OH group of Thr68 is in a position to form hydrogen-bonding interactions both with the coordinated water molecule and with the main chain greater than C=O of residue 64. The rate of azide binding to the ferric form of the Thr68 mutant was 60-fold lower than that for the wild-type protein, consistent with the proposed stabilization of the coordinated water molecule. However, bound O2 is destabilized in the ferrous form of the mutant protein. The observed 17-fold lowering of the O2 affinity may be a consequence of the hydrogen-bonding interaction made between the Thr68 beta-OH group and the carbonyl oxygen of residue 64. Overall association rate constants for O2, NO, and alkyl isocyanide binding to ferrous pig myoglobin were 3-10-fold lower for the mutant compared to the wild-type protein, whereas that for CO binding was little affected.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxygen affinity controlled by dynamical distal conformations: the soybean leghemoglobin and the Paramecium caudatum hemoglobin cases

The binding of diatomic ligands, such as O(2), NO, and CO, to heme proteins is a process intimately related with their function. In this work, we analyzed by means of a combination of classical Molecular Dynamics (MD) and Hybrid Quantum-Classical (QM/MM) techniques the existence of multiple conformations in the distal site of heme proteins and their influence on oxygen affinity regulation. We considered two representative examples: soybean leghemoglobin (Lba) and Paramecium caudatum truncated hemoglobin (PcHb). The results presented in this work provide a molecular interpretation for the kinetic, structural, and mutational data that cannot be obtained by assuming a single distal conformation.     

Ligand binding in the ferric and ferrous states of Paramecium hemoglobin

The unicellular protozoan Paramecium caudatum contains a monomeric hemoglobin (Hb) that has only 116 amino acid residues. This Hb shares the simultaneous presence of a distal E7 glutamine and a B10 tyrosine with several invertebrate Hbs. In the study presented here, we have used ligand binding kinetics and resonance Raman spectroscopy to characterize the effect of the distal pocket residues of Paramecium Hb in stabilizing the heme-bound ligands. In the ferric state, the high-spin to low-spin (aquo-hydroxy) transition takes place with a pK(a) of approximately 9.0. The oxygen affinity (P(50) = 0.45 Torr) is similar to that of myoglobin. The oxygen on- and off-rates are also similar to those of sperm whale myoglobin. Resonance Raman data suggest hydrogen bonding stabilization of bound oxygen, evidenced by a relatively low frequency of Fe-OO stretching (563 cm(-1)). We propose that the oxy complex is an equilibrium mixture of a hydrogen-bonded closed structure and an open structure. Oxygen will dissociate preferentially from the open structure, and therefore, the fraction of open structure population controls the rate of oxygen dissociation. In the CO complex, the Fe-CO stretching frequency at 493 cm(-1) suggests an open heme pocket, which is consistent with the higher on- and off-rates for CO relative to those in myoglobin. A high rate of ligand binding is also consistent with the observation of an Fe-histidine stretching frequency at 220 cm(-1), indicating the absence of significant proximal strain. We postulate that the function of Paramecium Hb is to supply oxygen for cellular oxidative processes.     

Gamma-glutamyltransferase activity of liver plasma membrane: induction following chronic alcohol consumption

The proton nuclear magnetic resonance spectra of soybean ferric leghemoglobin $\text{a}$ in the low-spin cyanide and nicotinate complexes have been assigned by specific deuteration of heme methyl groups. The assignments differ from those obtained solely from nuclear Overhauser enhancement measurements and are indicative of a proximal histidyl imidazole-hemin interaction which is very similar to that found in sperm whale myoglobin. The absence of a hyperfine shifted exchangeable NH peak for the distal histidine in leghemoglobin suggests either a very different orientation for this distal ligand or a significantly faster exchange rate with bulk solvent than found in myoglobin.     

Dioxygen affinity in heme proteins investigated by computer simulation

We present an investigation of the molecular basis of the modulation of oxygen affinity in heme proteins using computer simulation. QM-MM calculations are applied to explore distal and proximal effects on O(2) binding to the heme, while classical molecular dynamics simulations are employed to investigate ligand migration across the polypeptide to the active site. Trends in binding energies and in the kinetic constants are illustrated through a number of selected examples highlighting the virtues and the limitations of the applied methodologies. These examples cover a wide range of O(2)-affinities, and include: the truncated-N and truncated-O hemoglobins from Mycobacterium tuberculosis, the mammalian muscular O(2) storage protein: myoglobin, the hemoglobin from the parasitic nematode Ascaris lumbricoides, the oxygen transporter in the root of leguminous plants: leghemoglobin, the Cerebratulus lacteus nerve tissue hemoglobin, and the Alcaligenes xyloxidans cytochrome c'.     

Kinetics and mechanisms of reduction of Cu(II) and Fe(III) complexes by soybean leghemoglobin alpha

The reduction of low-molecular-weight Cu(II) and Fe(III) complexes by soybean leghemoglobin alpha was characterized using both kinetic analysis and 1H-NMR experiments. Whereas Fe(III) (CN)6(3-) was reduced through an outer sphere transfer over the exposed heme edge, all other Cu(II) and Fe(III) complexes investigated were reduced via a site-specific binding of the metal to the protein. Reduction of all metal complexes was enhanced by decreasing pH while only Fe(III)NTA reduction kinetics were altered by changes in ionic strength. Rates of reduction for both Cu(II) and Fe(III) were also affected inversely by the effective binding constant of the metal chelate used. NMR data confirmed that both Cu(II)NTA and Fe(III)NTA were bound to specific sites on the protein. Cu(II) bound preferentially to distal His-61 and Fe(III) exerted its greatest effect on two surface lysine residues with epsilon proton resonances at 3.04 and 3.12 ppm. The Fe(III)NTA complex also had a mild but noticeable line broadening effect on the distal His-61 singlet resonance near 5.3 ppm. Like hemoglobin and myoglobin, leghemoglobin might function not only as an oxygen carrier, but also as a biological reductant for low-molecular-weight Cu(II) and Fe(III) complexes.     

Crystal structure of the dioxygen-bound heme oxygenase from Corynebacterium diphtheriae: implications for heme oxygenase function

HmuO, a heme oxygenase of Corynebacterium diphtheriae, catalyzes degradation of heme using the same mechanism as the mammalian enzyme. The oxy form of HmuO, the precursor of the catalytically active ferric hydroperoxo species, has been characterized by ligand binding kinetics, resonance Raman spectroscopy, and x-ray crystallography. The oxygen association and dissociation rate constants are 5 microm(-1) s(-1) and 0.22 s(-1), respectively, yielding an O(2) affinity of 21 microm(-1), which is approximately 20 times greater than that of mammalian myoglobins. However, the affinity of HmuO for CO is only 3-4-fold greater than that for mammalian myoglobins, implying the presence of strong hydrogen bonding interactions in the distal pocket of HmuO that preferentially favor O(2) binding. Resonance Raman spectra show that the Fe-O(2) vibrations are tightly coupled to porphyrin vibrations, indicating the highly bent Fe-O-O geometry that is characteristic of the oxy forms of heme oxygenases. In the crystal structure of the oxy form the Fe-O-O angle is 110 degrees, the O-O bond is pointed toward the heme alpha-meso-carbon by direct steric interactions with Gly-135 and Gly-139, and hydrogen bonds occur between the bound O(2) and the amide nitrogen of Gly-139 and a distal pocket water molecule, which is a part of an extended hydrogen bonding network that provides the solvent protons required for oxygen activation. In addition, the O-O bond is orthogonal to the plane of the proximal imidazole side chain, which facilitates hydroxylation of the porphyrin alpha-meso-carbon by preventing premature O-O bond cleavage.     

Binding of alkylisocyanides with soybean leghemoglobin. Comparisons with sperm whale myoglobin

The binding of various linear and branched chain alkylisocyanides to soybean leghemoglobin has been studied with respect to association and dissociation kinetics and the results compared with those obtained in parallel on sperm whale and horse heart myoglobins; the linear ligands used (methyl to n-heptyl) cover a greater distribution of chain lengths than hitherto used. The association rate constants are much higher for leghemoglobin than for myoglobin, while the dissociation rates are slower. For a given protein, the dissociation rate constants are not much different when different isocyanides are used (except for methyl), whereas the association rates show complex behavior in relation with the alkyl chain length; singular differences are observed between leghemoglobin and sperm whale myoglobin in this regard. For myoglobin, the binding rate constants decrease from methyl to n-propyl, but remain approximately the same when the ligand carries a still longer alkyl chain. In contrast, for leghemoglobin, although the rate constants decrease from methyl to n-propyl, they show a progressive and important rise with longer alkyl substituents: n-butyl and n-pentyl.