Structural characterization of the proximal and distal histidine environment of cytoglobin and neuroglobin

Cytoglobin (Cgb) and neuroglobin (Ngb) are the first examples of hexacoordinated globins from humans and other vertebrates in which a histidine (His) residue at the sixth position of the heme iron is an endogenous ligand in both the ferric and ferrous forms. Static and time-resolved resonance Raman and FT-IR spectroscopic techniques were applied in examining the structures in the heme environment of these globins. Picosecond time-resolved resonance Raman (ps-TR3) spectroscopy of transient five-coordinate heme species produced by the photolysis of carbon monoxide (CO) adducts of Cgb and Ngb showed Fe-His stretching (nu(Fe-His)) bands at 229 and 221 cm(-1), respectively. No time-dependent shift in the nu(Fe-His) band of Cgb and Ngb was detected in the 20-1000 ps time domain, in contrast to the case of myoglobin (Mb). These spectroscopic data, combined with previously reported crystallographic data, suggest that the structure of the heme pocket in Cgb and Ngb is altered upon CO binding in a manner different from that of Mb and that the scales of the structural alteration are different for Cgb and Ngb. The structural property of the heme distal side of the ligand-bound forms was investigated by observing the sets of (nu(Fe-CO), nu(C-O), delta(Fe-C-O)) and (nu(Fe-NO), nu(N-O), delta(Fe-N-O)) for the CO and nitric oxide (NO) complexes of Cgb and Ngb. A comparison of the spectra of some distal mutants of Cgb (H81A, H81V, R84A, R84K, and R84T) and Ngb (H64A, H64V, K67A, K67R, and K67T) showed that the CO adducts of Cgb and Ngb contained three conformers and that the distal His (His81 in Cgb and His64 in Ngb) mainly contributes to the interconversion of the conformers. These structural characteristics of Cgb and Ngb are discussed in relation to their ligand binding and physiological properties.     

Structural basis of human cytoglobin for ligand binding

Cytoglobin (Cgb), a newly discovered member of the vertebrate globin family, binds O(2) reversibly via its heme, as is the case for other mammalian globins (hemoglobin (Hb), myoglobin (Mb) and neuroglobin (Ngb)). While Cgb is expressed in various tissues, its physiological role is not clearly understood. Here, the X-ray crystal structure of wild type human Cgb in the ferric state at 2.4A resolution is reported. In the crystal structure, ferric Cgb is dimerized through two intermolecular disulfide bonds between Cys38(B2) and Cys83(E9), and the dimerization interface is similar to that of lamprey Hb and Ngb. The overall backbone structure of the Cgb monomer exhibits a traditional globin fold with a three-over-three alpha-helical sandwich, in which the arrangement of helices is basically the same among all globins studied to date. A detailed comparison reveals that the backbone structure of the CD corner to D helix region, the N terminus of the E-helix and the F-helix of Cgb resembles more closely those of pentacoordinated globins (Mb, lamprey Hb), rather than hexacoordinated globins (Ngb, rice Hb). However, the His81(E7) imidazole group coordinates directly to the heme iron as a sixth axial ligand to form a hexcoordinated heme, like Ngb and rice Hb. The position and orientation of the highly conserved residues in the heme pocket (Phe(CD1), Val(E11), distal His(E7) and proximal His(F8)) are similar to those of other globin proteins. Two alternative conformations of the Arg84(E10) guanidium group were observed, suggesting that it participates in ligand binding to Cgb, as is the case for Arg(E10) of Aplysia Mb and Lys(E10) of Ngb. The structural diversities and similarities among globin proteins are discussed with relevance to molecular evolutionary relationships.     

Characterization of the heme environmental structure of cytoglobin,a fourth globin in humans

Cytoglobin (Cgb) represents a fourth member of the globin superfamily in mammals, but its function is unknown. Site-directed mutagenesis, in which six histidine residues were replaced with alanine, was carried out, and the results indicate that the imidazoles of His81 (E7) and His113 (F8) bind to the heme iron as axial ligands in the hexacoordinate and the low-spin state. The optical absorption, resonance Raman, and IR spectral results are consistent with this conclusion. The redox potential measurements revealed an E' of 20 mV (vs NHE) in the ferric/ferrous couple, indicating that the imidazole ligands of His81 and His113 are electronically neutral. On the basis of the nu(Fe-CO) and nu(C-O) values in the resonance Raman and infrared spectra of the ferrous-CO complexes of Cgb and its mutants, it was found that CO binds to the ferrous iron after the His81 imidazole is dissociated, and three conformers are present in the resultant CO coordination structure. Two are in closed conformations of the heme pocket, in which the bound CO ligand interacts with the dissociated His81 imidazole, while the third is in an open conformation. The nu(Fe-O2) in the resonance Raman spectra of oxy Cgb can be observed at 572 cm(-1), suggesting a polar heme environment. These structural properties of the heme pocket of Cgb are discussed with respect to its proposed in vivo oxygen storage function.     

Molecular dynamics simulation of carboxy and deoxy human cytoglobin in solution

Cytoglobin (Cgb), the fourth member of the vertebrate heme globin family, is widely expressed in mammalian tissues, and reversibly binds to CO, O₂ and other small ligands. The diverse functions of Cgb may include ligand transport, redox reactions and enzymatic catalysis. Recent studies indicate that Cgb is a potential gene medicine for fibrosis and cancer therapy. In the present work, molecular dynamics (MD) simulations were performed to investigate the functionally related structural properties and dynamic characteristics in carboxy and deoxy human Cgb. The simulation results showed that the loop regions and internal cavities were significantly affected through the binding of an exogenous ligand. The AB, GH and EF loops were found to undergo significant rearrangement and this led to distinct cavity adjustments in Xe2, Xe4 and the distal pocket. In addition, solvent accessibility and torsion angle analyses revealed an interactive distal network comprised of His⁸¹(E7), Leu⁴⁶(B10) and Arg⁸⁴(E10). The MD study of carboxy and deoxy human Cgb revealed that CO-ligated Cgb modulates the protein conformation primarily by loop and cavity rearrangements rather than the heme sliding mechanism found in neuroglobin (Ngb). The significant differences between Cgb and Ngb in the loop and cavity properties are presumably linked to their various biological functions.     

Distal mutation modulates the heme sliding in mouse neuroglobin investigated by molecular dynamics simulation

Neuroglobin (Ngb), a hexa‐coordinated hemoprotein primarily expressed in the brain and retina, is thought to be involved in neuroprotection and signal transduction. Ngb can reversibly bind small ligands such as O₂ and CO to the heme iron by replacing the distal histidine which is bound to the iron as the endogenous ligand. In this work, molecular dynamics (MD) simulations were performed to investigate the functionally related structural properties and dynamical characteristics in carboxy mouse neuroglobin and three distal mutants including single mutants H64V, K67T and double mutant H64V/K67T. MD simulations suggest that the heme sliding motion induced by the binding of exogenous ligand is affected by the distal mutation obviously. Accompanying changes in loop flexibility and internal cavities imply the structural rearrangement of Ngb. Moreover, the solvent accessibility of heme and some crucial residues are influenced revealing an interactive network on the distal side. The work elucidates that the key residues K67 at E10 and H64 at E7 are significant in modulating the heme sliding and hence the structural and physiological function of Ngb. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Cytochromes: Reactivity of the "dark side" of the heme

Ligand binding to the heme distal side is a paradigm of heme-protein biochemistry, the proximal axial ligand being in most cases a His residue. NO binds to the ferrous heme-Fe-atom giving rise to hexa-coordinated adducts (as in myoglobin and hemoglobin) with His and NO as proximal and distal axial ligands, respectively, or to penta-coordinated adducts (as in soluble guanylate cyclase) with NO as the axial distal ligand. Recently, the ferrous derivative of Alcaligenes xylosoxidans cytochrome c' (Axcyt c') and of cardiolipin-bound horse heart cytochrome c (CL-hhcyt c) have been reported to bind NO to the "dark side" of the heme (i.e., as the proximal axial ligand) replacing the endogenous ligand His. Conversely, CL-free hhcyt c behaves as ferrous myoglobin by binding NO to the heme distal side, keeping His as the proximal axial ligand. Moreover, the ferrous derivative of CL-hhcyt c binds CO at the heme distal side, the proximal axial ligand being His. Furthermore, CL-hhcyt c shows peroxidase activity. In contrast, CL-free hhcyt c does not bind CO and does not show peroxidase activity. This suggests that heme-proteins may utilize both sides of the heme for ligand discrimination, which appears to be modulated allosterically. Here, structural and functional aspects of NO binding to ferrous Axcyt c' and (CL-)hhcyt c are reviewed.     

Inversion of axial coordination in myoglobin to create a "proximal" ligand binding pocket

A ligand binding pocket has been created on the proximal side of the heme in porcine myoglobin by site-directed mutagenesis. Our starting point was the H64V/V68H double mutant which has been shown to have bis-histidine (His68 and His93) heme coordination [Dou, Y., Admiraal, S. J., Ikeda-Saito, M., Krzywda, S., Wilkinson, A. J., Li, T., Olson, J. S., Prince, R. C., Pickering, I. J., George, G. N. (1995) J. Biol. Chem. 270, 15993-16001]. The replacement of the proximal His93 ligand by noncoordinating Ala (H64V/V68H/H93A) or Gly (H64V/V68H/H93G) residues resulted unexpectedly in a six-coordinate low-spin species in both ferric and ferrous states. To test the hypothesis that the sixth coordinating ligand in the triple mutants was the imidazole of His97, this residue was mutated to Phe, in the quadruple mutants, H64V/V68H/H93A/H97F and H64V/V68H/H93G/H97F. The ferric quadruple mutants show a clear water/hydroxide alkaline transition and high cyanide and CO affinities, characteristics similar to those of wild-type myoglobin. The nu(Fe-CO) and nu(C-O) stretching frequencies in the ferrous-CO state of the quadruple mutants indicate that the "proximal" ligand binding heme pocket is less polar than the distal pocket in the wild-type protein. Thus, we conclude that the proximal heme pocket in the quadruple mutants has a similar affinity for exogenous ligands to the distal pocket of wild-type myoglobin but that the two pockets have different polarities. The quadruple mutants open up new approaches for developing heme chemistry on the myoglobin scaffold.     

Coordination structure of the ferric heme iron in engineered distal histidine myoglobin mutants.

Recombinant human myoglobin mutants with the distal His residue (E7, His64) replaced by Leu, Val, or Gln residues were prepared by site-directed mutagenesis and expression in Escherichia coli. Electronic and coordination structures of the ferric heme iron in the recombinant myoglobin proteins were examined by optical absorption, EPR, 1H NMR, magnetic circular dichroism, and x-ray spectroscopy. Mutations, His-->Val and His-->Leu, remove the heme-bound water molecule resulting in a five-coordinate heme iron at neutral pH, while the heme-bound water molecule appears to be retained in the engineered myoglobin with His-->Gln substitution as in the wild-type protein. The distal Val and distal Leu ferric myoglobin mutants at neutral pH exhibited EPR spectra with g perpendicular values smaller than 6, which could be interpreted as an admixture of intermediate (S = 3/2) and high (S = 5/2) spin states. At alkaline pH, the distal Gln mutant is in the same so-called "hydroxy low spin" form as the wild-type protein, while the distal Leu and distal Val mutants are in high spin states. The ligand binding properties of these recombinant myoglobin proteins were studied by measurements of azide equilibrium and cyanide binding. The distal Leu and distal Val mutants exhibited diminished azide affinity and extremely slow cyanide binding, while the distal Gln mutant showed azide affinity and cyanide association rate constants similar to those of the wild-type protein.     

An engineered heme–copper center in myoglobin: CO migration and binding

We have investigated CO migration and binding in Cu_BMb, a copper-binding myoglobin double mutant (L29H–F43H), by using Fourier transform infrared spectroscopy and flash photolysis over a wide temperature range. This mutant was originally engineered with the aim to mimic the catalytic site of heme–copper oxidases. Comparison of the wild-type protein Mb and Cu_BMb shows that the copper ion in the distal pocket gives rise to significant effects on ligand binding to the heme iron. In Mb and copper-free Cu_BMb, primary and secondary ligand docking sites are accessible upon photodissociation. In copper-bound Cu_BMb, ligands do not migrate to secondary docking sites but rather coordinate to the copper ion. Ligands entering the heme pocket from the outside normally would not be captured efficiently by the tight distal pocket housing the two additional large imidazole rings. Binding at the Cu ion, however, ensures efficient trapping in Cu_BMb. The Cu ion also restricts the motions of the His64 side chain, which is the entry/exit door for ligand movement into the active site, and this restriction results in enhanced geminate and slow bimolecular CO rebinding. These results support current mechanistic views of ligand binding in hemoglobins and the role of the Cu_B in the active of heme–copper oxidases. This article is part of a Special Issue entitled: Oxygen Binding and Sensing Proteins.     

X-ray crystal structure of the fluoride derivative of Aplysia limacina ferric myoglobin at 2.0 A resolution. Stabilization of the fluoride ion by hydrogen bonding to Arg66 (E10)

The X-ray crystal structure of the fluoride derivative of Aplysia limacina ferric myoglobin has been solved and refined at 2.0 A resolution; the crystallographic R-factor is 13.6%. The fluoride ion binds to the sixth co-ordination position of the heme iron, 2.2 A from the metal. Binding of the negatively charged ligand on the distal side of the heme pocket of this myoglobin, which lacks the distal His, is associated with a network of hydrogen bonds that includes the fluoride ion, the residue Arg66 (E10), the heme propionate III, three ordered water molecules and backbone or side-chain atoms from the CD region. A comparison of fluoride and oxygen dissociation rate constants of A. limacina myoglobin, sperm whale (Physeter catodon) myoglobin and Glycera dibranchiata monomeric hemoglobin, suggests that the conformational readjustment of Arg66 (E10) in A. limacina myoglobin may represent the molecular basis for ligand stabilization, in the absence of a hydrogen-bond donor residue at the distal E7 position.     

The role of the heme distal ligand in the post-translational modification of Synechocystis hemoglobin

Synechocystis sp. PCC 6803 hemoglobin is a cyanobacterial Group I truncated hemoglobin. In the absence of an exogenous ligand, its single heme group is coordinated by His46 (E10, distal) and His70 (F8, proximal). The protein can undergo a post-translational modification by which His117 (H16, in the C-terminal helix) reacts with the heme 2-vinyl group to form a Markownikoff adduct. The new C-N bond prevents heme loss, alters the dynamics of the protein, and influences ligand binding to the heme group. To explore the factors conditioning the formation of the cross-link, variants of the protein that contained an alanine or a leucine at position 46 (E10) were prepared. A double replacement (His46Leu and Tyr22 (B10) to Phe) was also performed to perturb the network of interactions stabilizing bound exogenous ligand. The single and double replacements affected the optical and NMR properties of the globin, each in a different fashion. Heme-protein cross-linking, as promoted by sodium dithionite, was retarded by the replacement of His46, but reactivity was recovered when imidazole or cyanide was used as exogenous ligand. In addition, a significant amount of a second product was systematically obtained when dithionite treatment was performed on the cyanide-bound proteins. This species was identified by NMR spectroscopy to be an adduct to the 4-vinyl group. It was concluded that the specificity and rate of the cross-linking reaction depended critically on the nature of the sixth ligand to the heme iron.     

On the Pathways for CO Egress from Carboxy Human Cytoglobin. A Molecular‐Dynamics Investigation

This work discloses two bona fide gates through which the CO ligand can leave the distal cavity of carboxy human cytoglobin, reaching the solvent. The investigation was based on molecular dynamics, aided by a minimal randomly‐oriented force applied to the ligand. The shortest pathway progresses toward the main gate, H81‐R84, in the open state, with the H81 imidazole moiety turned toward the solvent. A longer pathway develops toward the diametrically opposed W31‐W151 gate. In between, CO may be entrapped into binding cavities, either along the path toward the gates, or in a cul‐de‐sac, from which CO may even be incapable to escape. This behavior contrasts with carboxy myoglobin, where the corresponding H64 gate, when opened, is the sole used by CO to get to the solvent. These observations, which could hold also for other small ligands of biological interest, such as O₂, NO, and NO$\rm{{_{3}^{-}}}$ , provide an answer to a neglected aspect of the mysterious six‐coordinated globins.     

The effects of amino acid substitution at position E7 (residue 64) on the kinetics of ligand binding to sperm whale myoglobin

Association and dissociation rate constants were measured for O2, CO, and alkyl isocyanide binding to a set of genetically engineered sperm whale myoglobins with site-specific mutations at residue 64 (the E7 helical position). Native His was replaced by Gly, Val, Leu, Met, Phe, Gln, Arg, and Asp using the synthetic gene and expression system developed by Springer and Sligar (Springer, B. A., and Sligar, S. G. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 8961-8965). The His64----Gly substitution produced a sterically unhindered myoglobin that exhibited ligand binding parameters similar to those of chelated protoheme suspended in soap micelles. The order of the association rate constants for isocyanide binding to the mutant myoglobins was Gly64 (approximately 10(7) M-1 s-1) much greater than Val64 approximately Leu64 (approximately 10(6) M-1 s-1) greater than Met64 greater than Phe64 approximately His64 approximately Gln64 (10(5)-10(3) M-1 s-1) and indicates that the barrier to isocyanide entry into the distal pocket is primarily steric in nature. The bimolecular rates of methyl, ethyl, n-propyl, and n-butyl isocyanide binding to the His64----Arg and His64----Asp mutants were abnormally high (1-5 x 10(6) M-1 s-1), suggesting that Arg64 and Asp64 adopt conformations with the charged side chains pointing out toward the solvent creating a less hindered pathway for ligand binding. In contrast to the isocyanide data, the association rate constants for O2 and CO binding exhibited little dependence on the size of the E7 side chain. The values for all the mutants except His64----Gln approached or were larger than those for chelated model heme (i.e. approximately 1 x 10(8) M-1 s-1 for O2 and approximately 1 x 10(7) M-1 s-1 for CO), whereas the corresponding rate parameters for myoglobin containing either Gln64 or His64 were 5- to 10-fold smaller. This result suggests that a major kinetic barrier for O2 and CO binding to native myoglobin may involve disruption of polar interactions between His64 and water molecules found in the distal pocket of deoxymyoglobin. Finally, the rate and equilibrium parameters for O2 and CO binding to the His64----Gln, His64----Val, and His64----Leu mutants were compared to those reported previously for Asian elephant myoglobin (Gln-E7), Aplysia limacina myoglobin (Val-E7), and monomeric Hb II from Glycera dibranchiata (Leu-E7).     

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.     

X-ray crystal structure of the ferric sperm whale myoglobin: imidazole complex at 2.0 A resolution

The X-ray crystal structure of the ferric sperm whale (Physeter catodon) myoglobin:imidazole complex has been refined at 2.0 A resolution, to a final R-factor of 14.8%. The overall conformation of the protein is little affected by binding of the ligand. Imidazole is co-ordinated to the heme iron at the distal site, and forces distinguishable local changes in the surrounding protein residues. His64(E7) swings out of the distal pocket and becomes substantially exposed to the solvent: nevertheless, it stabilizes the exogenous ligand by hydrogen bonding. The side-chains of residues Arg45(CD3) and Asp60(E3) are also affected by imidazole association.     

Identification of protein radicals formed in the human neuroglobin-H2O2 reaction using immuno-spin trapping and mass spectrometry

Neuroglobin (Ngb) is a recently discovered protein that shows only minor sequence similarity with myoglobin and hemoglobin but conforms to the typical 3-over-3 alpha-helical fold characteristic of vertebrate globins. An intriguing feature of Ngb is its heme hexacoordination in the absence of external ligands, observed both in the ferrous and in the ferric (met) forms. In Ngb, the imidazole of a histidine residue (His-64) in the distal position, above the heme plane, provides the sixth coordination bond. In this work, a valine residue was introduced at position 64 (H64V variant) to clarify the possible role(s) of the distal residue in protecting the heme iron of Ngb from attack by strong oxidants. SDS-PAGE analyses revealed that the oxidation of the H64V variant of metNgb by H 2O 2 resulted in the formation of dimeric and trimeric products in contrast to the native protein. Dityrosine cross-links were shown by their fluorescence to be present in the oligomeric products. When the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO) was included in the reaction mixture, nitrone adducts were detected by immuno-spin trapping. The specific location of the DMPO adducts on the H64V variant protein was determined by a mass spectrometry method that combines off-line immuno-spin trapping and chromatographic procedures. This method revealed Tyr-88 to be the site of modification by DMPO. The presence of His-64 in the wild-type protein results in the nearly complete loss of detectable radical adducts. Together, the data support the argument that wild-type Ngb is protected from attack by H 2O 2 by the coordinated distal His.     

Structural and functional properties of a truncated hemoglobin from a food-borne pathogen Campylobacter jejuni

Campylobacter jejuni contains two hemoglobins, Cgb and Ctb. Cgb has been suggested to perform an NO detoxification reaction to protect the bacterium against NO attack. On the other hand, the physiological function of Ctb, a class III truncated hemoglobin, remains unclear. By using CO as a structural probe, resonance Raman data show that the distal heme pocket of Ctb exhibits a positive electrostatic potential. In addition, two ligand-related vibrational modes, nu(Fe-O(2)) and nu(O-O), were identified in the oxy derivative, with frequencies at 542 and 1132 cm(-1), respectively, suggesting the presence of an intertwined H-bonding network surrounding the heme-bound ligand, which accounts for its unusually high oxygen affinity (222 microm(-1)). Mutagenesis studies of various distal mutants suggest that the heme-bound dioxygen is stabilized by H-bonds donated from the Tyr(B10) and Trp(G8) residues, which are highly conserved in the class III truncated hemoglobins; furthermore, an additional H-bond donated from the His(E7) to the Tyr(B10) further regulates these H-bonding interactions by restricting the conformational freedom of the phenolic side chain of the Tyr(B10). Taken together, the data suggest that it is the intricate balance of the H-bonding interactions that determines the unique ligand binding properties of Ctb. The extremely high oxygen affinity of Ctb makes it unlikely to function as an oxygen transporter; on the other hand, the distal heme environment of Ctb is surprisingly similar to that of cytochrome c peroxidase, suggesting a role of Ctb in performing a peroxidase or P450-type of oxygen chemistry.     

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.     

Analysis of the kinetic barriers for ligand binding to sperm whale myoglobin using site-directed mutagenesis and laser photolysis techniques

Time courses for NO, O2, CO, methyl and ethyl isocyanide rebinding to native and mutant sperm whale myoglobins were measured at 20 degrees C following 17-ns and 35-ps laser excitation pulses. His64 (E7) was replaced with Gly, Val, Leu, Phe, and Gln, and Val68 (E11) was replaced with Ala, Ile, and Phe. For both NO and O2, the effective picosecond quantum yield of unliganded geminate intermediates was roughly 0.2 and independent of the amino acids at positions 64 and 68. Geminate recombination of NO was very rapid; 90% rebinding occurred within 0.5-1.0 ns for all of the myoglobins examined; and except for the Gly64 and Ile68 mutants, the fitted recombination rate parameters were little influenced by the size and polarity of the amino acid at position 64 and the size of the residue at position 68. The rates of NO recombination and ligand movement away from the iron atom in the Gly64 mutant increased 3-4-fold relative to native myoglobin. For Ile68 myoglobin, the first geminate rate constant for NO rebinding decreased approximately 6-fold, from 2.3 x 10(10) s-1 for native myoglobin to 3.8 x 10(9) s-1 for the mutant. No picosecond rebinding processes were observed for O2, CO, and isocyanide rebinding to native and mutant myoglobins; all of the observed geminate rate constants were less than or equal to 3 x 10(8) s-1. The rebinding time courses for these ligands were analyzed in terms of a two-step consecutive reaction scheme, with an outer kinetic barrier representing ligand movement into and out of the protein and an inner barrier representing binding to the heme iron atom by ligand occupying the distal portion of the heme pocket. Substitution of apolar amino acids for His64 decreased the absolute free energies of the outer and inner kinetic barriers and the well for non-covalently bound O2 and CO by 1 to 1.5 kcal/mol, regardless of size. In contrast, the His64 to Gln mutation caused little change in the barrier heights for all ligands, showing that the polar nature of His64 inhibits both the bimolecular rate of ligand entry into myoglobin and the unimolecular rate of binding to the iron atom from within the protein. Increasing the size of the position 68(E11) residue in the series Ala to Val (native) to Ile caused little change in the rate of O2 migration into myoglobin or the equilibrium constant for noncovalent binding but did decrease the unimolecular rate for iron-O2 bond formation.(ABSTRACT TRUNCATED AT 400 WORDS)