1H NMR investigation of the distal hydrogen bonding network and ligand tilt in the cyanomet complex of oxygen-avid Ascaris suum hemoglobin.

The O(2)-avid hemoglobin from the parasitic nematode Ascaris suum exhibits one of the slowest known O(2) off rates. Solution (1)H NMR has been used to investigate the electronic and molecular structural properties of the active site for the cyano-met derivative of the recombinant first domain of this protein. Assignment of the heme, axial His, and majority of the residues in contact with the heme reveals a molecular structure that is the same as reported in the A. suum HbO(2) crystal structure (Yang, J., Kloek, A., Goldberg, D. E., and Mathews, F. S. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 4224-4228) with the exception that the heme in solution is rotated by 180 degrees about the alpha,gamma-meso axis relative to that in the crystal. The observed dipolar shifts, together with the crystal coordinates of HbO(2), provide the orientation of the magnetic axes in the molecular framework. The major magnetic axis, which correlates with the Fe-CN vector, is found oriented approximately 30 degrees away from the heme normal and indicates significant steric tilt because of interaction with Tyr(30)(B10). The three side chain labile protons for the distal residues Tyr(30)(B10) and Gln(64)(E7) were identified, and their relaxation, dipolar shifts, and nuclear Overhauser effects to adjacent residues used to place them in the distal pocket. It is shown that these two distal residues exhibit the same orientations ideal for H bonding to the ligand and to each other, as found in the A. suum HbO(2) crystal. It is concluded that the ligated cyanide participates in the same distal H bonding network as ligated O(2). The combination of the strong steric tilt of the bound cyanide and slow ring reorientation of the Tyr(30)(B10) side chain supports a crowded and constrained distal pocket.     

Solution (1)H NMR study of the influence of distal hydrogen bonding and N terminus acetylation on the active site electronic and molecular structure of Aplysia limacina cyanomet myoglobin

The sea hare Aplysia limacina possesses a myoglobin in which a distal H-bond is provided by Arg E10 rather than the common His E7. Solution (1)H NMR studies of the cyanomet complexes of true wild-type (WT), recombinant wild-type (rWT), and the V(E7)H/R(E10)T and V(E7)H mutants of Aplysia Mb designed to mimic the mammalian Mb heme pocket reveal that the distal His in the mutants is rotated out of the heme pocket and is unable to provide a stabilizing H-bond to bound ligand and that WT and rWT differ both in the thermodynamics of heme orientational disorder and in heme contact shift pattern. The mean of the four heme methyl shifts is shown to serve as a sensitive indicator of variations in distal H-bonding among a set of mutant cyanomet globins. The heme pocket perturbations in rWT relative to WT were traced to the absence of the N-terminal acetyl group in rWT that participates in an H-bond to the EF corner in WT. Analysis of dipolar contacts between heme and axial His and between heme and the protein matrix reveal a small approximately 2 degrees rotation of the axial His in rWT relative to true WT and a approximately 3 degrees rotation of the heme in the double mutant relative to rWT Mb. It is demonstrated that both the direction and magnitude of the rotation of the axial His relative to the heme can be determined from the change in the pattern of the contact-dominated heme methyl shift and from the dipolar-dominated heme meso-H shift. However, only NOE data can determine whether it is the His or heme that actually rotates in the protein matrix.     

Solution 1H nuclear magnetic resonance determination of the distal pocket structure of cyanomet complexes of genetically engineered sperm whale myoglobin His64 (E7)-->Val, Thr67 (E10)-->Arg. The role of distal hydrogen bonding by Arg67 (E10) in modulating ligand tilt.

Sequence-specific 2D methodology has been used to assign the 1H NMR signals for all active site residues in the paramagnetic cyano-met complexes of sperm whale synthetic double mutant His64[E7]-->Val/Thr67[E10]-->Arg (VR-met-MbCN) and triple mutant His64[E7]-->Val/Thr67[E10]-->Arg/Arg45[CD3]-->Asn (VRN-metMbCN). The resulting dipolar shifts for noncoordinated proximal side residues were used to quantitatively determine the orientation of the paramagnetic susceptibility tensor in the molecular framework for the two mutants, which were found indistinguishable but distinct from those of both wild-type and the His64[E7]-->Val single point mutant (V-metMbCN). The observed dipolar shifts for the E helix backbone protons and Phe43[CD1], together with steady-state nuclear Overhauser effect between the E helix and the heme, were analyzed to show that both the E helix and Phe43[CD1] move slightly closer to the iron to minimize the vacancy resulting from the His64[E7]-->Val substitution, as found in V-metMbCN (Rajarathnam, K., J. Qin, G.N. LaMar, M. L. Chiu, and S. G. Sligar. 1993. Biochemistry. 32:5670-5680). The dipolar shifts of the mutated Val64[E7] and Arg67[E10] allow the determination of their orientations relative to the heme, and the latter residue is shown to insert into the pocket and provide a hydrogen bond to the coordinated ligand, as found in the naturally occurring ValE7/ArgE10 genetic variant, Aplysia limacina Mb. The oxy-complex of both A. limacina Mb and VR-Mb, VRN-Mb have been proposed to be stabilized by this hydrogen bonding interaction (Travaglini Allocatelli, C. et al. 1993. Biochemistry. 32:6041-6049). The magnitude of the tilt of the major magnetic axes from the heme normal in VR-metMbCN and VRN-metMbCN, which is related to the tilt of the ligand, is the same as in wild-type or V-metMbCN, but the direction of tilt is altered from that in V-metMbCN. It is concluded that the change in the direction of the ligand tilt in both the double and triple mutants, as compared to WT metMbCN and V-metMbCN single mutant, is due to the attractive hydrogen-bonding between ArgE10 and the bound cyanide.     

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.     

Cyanide binding to hexacoordinate cyanobacterial hemoglobins: hydrogen-bonding network and heme pocket rearrangement in ferric H117A Synechocystis hemoglobin

The truncated hemoglobin (Hb) from the cyanobacterium Synechocystis sp. PCC 6803 is a bis-histidyl hexacoordinate complex in the absence of exogenous ligands. This protein can form a covalent cross-link between His117 in the H-helix and the heme 2-vinyl group. Cross-linking, the physiological importance of which has not been established, is avoided with the His117Ala substitution. In the present work, H117A Hb was used to explore exogenous ligand binding to the heme group. NMR and thermal denaturation data showed that the replacement was of little consequence to the structural and thermodynamic properties of ferric Synechocystis Hb. It did, however, decelerate the association of cyanide ions with the heme iron. Full complexation required hours, instead of minutes, of incubation at optical and NMR concentrations. At neutral pH and in the presence of excess cyanide, binding occurred with a first-order dependence on cyanide concentration, eliminating distal histidine decoordination as the rate-limiting step. The cyanide complex of the H117A variant was characterized for the conformational changes occurring as the histidine on the distal side, His46 (E10), was displaced. Extensive rearrangement allowed Tyr22 (B10) to insert in the heme pocket and Gln43 (E7) and Gln47 (E11) to come in contact with it. H-bond formation to the bound cyanide was identified in solution with the use of (1)H(2)O/(2)H(2)O mixtures. Cyanide binding also resulted in a change in the ratio of heme orientational isomers, in a likely manifestation of heme environment reshaping. Similar observations were made with the related Synechococcus sp. PCC 7002 H117A Hb, except that cyanide binding was rapid in this protein. In both cases, the (15)N chemical shift of bound cyanide was reminiscent of that in peroxidases and the orientation of the proximal histidine was as in other truncated Hbs. The ensemble of the data provided insight into the structural cooperativity of the heme pocket scaffold and pointed to the reactive 117 site of Synechocystis Hb as a potential determinant of biophysical and, perhaps, functional properties.     

The heme pocket geometry of Lucina pectinata hemoglobin II restricts nitric oxide and peroxide entry: model of ligand control for the design of a stable oxygen carrier

Blood pressure elevation has been attributed in large part to the consumption of nitric oxide (NO) by extracellular hemoglobin (Hb) therapeutics following infusion in humans. We studied NO and hydrogen peroxide (H2O2) oxidative reaction kinetics of monomeric Hbs isolated from the clam Lucina pectinata to probe the effects of their distinctive heme pocket chemistries on ligand controls and heme oxidative stability. HbI (Phe43(CD1), Gln64(E7), Phe29(B10), and Phe68(E11)) reacted with high avidity with NO (k'(ox,NO) = 91 microM-1 s-1), whereas HbII (Phe44(CD1), Gln65(E7), Tyr30(B10), and Phe69(E11)) reacted at a much slower rate (k'(ox,NO)= 2.8 microM-1 s-1). However, replacing B10 (Phe) by Tyr in recombinant HbI (HbI PheB10Tyr) produced only a 2-fold reduction in the NO-induced oxidation rate (k'(ox,NO)= 49.9 microM-1 s-1). Among the clam Hbs, HbII exhibited the fastest NO dissociation and the slowest NO association with ferrous iron. Autoxidation, H2O2-mediated ferryl iron (FeIV) formation, and the subsequent heme degradation kinetics were much slower in HbII and HbI PheB10Tyr when compared to those of HbI. The Tyr(B10) residue appears to afford a greater heme oxidative stability advantage toward H2O2, whereas the close proximity of this residue together with Gln(E7) to the heme iron contributes largely to the distal control of NO binding. Engineering of second-generation Hb-based oxygen therapeutics that are resistant to NO/H2O2-driven oxidation may ultimately require further optimization of the heme pocket architecture to limit heme exposure to solvent.     

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)     

1H NMR study of the molecular structure and magnetic properties of the active site for the cyanomet complex of O2-avid hemoglobin from the trematode Paramphistomum epiclitum.

The solution molecular and electronic structures of the active site in the extremely O2-avid hemoglobin from the trematode Paramphistomum epiclitum have been investigated by 1H NMR on the cyanomet form in order to elucidate the distal hydrogen-bonding to a ligated H-bond acceptor ligand. Comparison of the strengths of dipolar interactions in solution with the alternate crystal structures of methemoglobin establish that the solution structure of wild-type Hb more closely resembles the crystal structure of the recombinant wild-type than the true wild-type met-hemoglobin. The distal Tyr66(E7) is found oriented out of the heme pocket in solution as found in both crystal structures. Analysis of dipolar contacts, dipolar shift and paramagnetic relaxation establishes that the Tyr32(B10) hydrogen proton adopts an orientation that allows it to make a strong H-bond to the bound cyanide. The observation of a significant isotope effect on the heme methyl contact shifts confirms a strong contact between the Tyr32(B10) OH and the ligated cyanide. The quantitative determination of the orientation and anisotropies of the paramagnetic susceptibility tensor reveal that the cyanide is tilted approximately 10 degrees from the heme normal so as to avoid van der Waals overlap with the Tyr32(B10) Oeta. The pattern of heme contact shifts with large low-field shifts for 7-CH3 and 18-CH3 is shown to arise not from the 180 degrees rotation about the alpha-gamma-meso axis, but due to the approximately 45 degrees rotation of the axial His imidazole ring, relative to that in mammalian globins.     

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.     

1H NMR structure of the heme pocket of HNO-myoglobin

The unique (1)H NMR signal of nitrosyl hydride at 14.8 ppm is used to obtain a solution structure of the distal pocket of Mb-HNO, a rare nitroxyl adduct with a half-life of several months at room temperature. (1)H NMR, NOESY and TOCSY data were obtained under identical experimental conditions on solutions of the diamagnetic HNO and CO complexes of equine Mb, allowing direct comparison of NMR data to a crystallographically characterized structure. Twenty NOEs between the nitrosyl hydride and protein and heme-based signals were observed. The HNO orientation obtained by modeling the experimental (1)H NMR NOESY data yielded an orientation of ca. -104 degrees referenced to the N-Fe-N vector between alpha and beta mesoprotons. An essentially identical orientation was obtained by simple energy minimization of the HNO adduct using ESFF potentials, suggesting steric control of the orientation. Differences in chemical shifts are seen for protons on residues Phe43(CD1) and Val68(E11), but both exhibit virtually identical NOESY contacts to other residues, and thus are attributed to small movements of ca. 0.1 A within the strong ring current. The most significant differences are seen in the NOESY peak intensities and chemical shifts for the ring non-labile protons of the distal His64(E7). The orientation of the His64(E7) in Mb-HNO was analyzed on the basis of the NOESY cross-peak changes and chemical shift changes, predicting a ca. 20 degrees rotation about the beta-gamma bond. The deduced HNO and His64(E7) orientations result in geometry where the His64(E7) ring can serve as the donor for a significant H-bond to the oxygen atom of the bound HNO.     

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.     

Solution 1H nuclear magnetic resonance determination of hydrogen bonding of the E10 (66) Arg side-chain to the bound ligand in Aplysia cyano-met myoglobin.

A combined one-dimensional nuclear Overhauser effect, paramagnetic-induced relaxation and two-dimensional sequence-specific 1H n.m.r. assignment of the spectrum of portions of the distal pocket of Aplysia cyano metMyoglobin (metMbCN) has been carried out in order to establish the presence and identity of distal residues in the heme pocket. In the absence of the usual distal E7 His in Aplysia Mb (E7 Val), the sequence-specific assignment of the E7 and E10 residues, together with their hyperfine shift patterns, relaxivities and dipolar connectivities to each other and the remainder of the E helix, reveal that the E10 Arg is turned into the pocket and hydrogen bonds to the bound cyanide group. We have previously found a similar rearrangement of the E10 Arg in Aplysia fluoro metMyoglobin, and the stabilizing effect of this residue was proposed to be responsible for the slow rate of cyanide dissociation from rapidly reduced ferrous Aplysia myoglobin. Based on the similar distal E7 His hydrogen-bonding interaction to the bound ligand in the crystal of sperm whale MbO2 and in solution of its cyano met complex, we propose that the E10 Arg similarly hydrogen bonds to the bound O2 in Aplysia MbO2 and accounts for its strong ligand binding and slow dissociation rate.     

Structure and ligand selection of hemoglobin II from Lucina pectinata

Lucina pectinata ctenidia harbor three heme proteins: sulfide-reactive hemoglobin I (HbI(Lp)) and the oxygen transporting hemoglobins II and III (HbII(Lp) and HbIII(Lp)) that remain unaffected by the presence of H(2)S. The mechanisms used by these three proteins for their function, including ligand control, remain unknown. The crystal structure of oxygen-bound HbII(Lp) shows a dimeric oxyHbII(Lp) where oxygen is tightly anchored to the heme through hydrogen bonds with Tyr(30)(B10) and Gln(65)(E7). The heme group is buried farther within HbII(Lp) than in HbI(Lp). The proximal His(97)(F8) is hydrogen bonded to a water molecule, which interacts electrostatically with a propionate group, resulting in a Fe-His vibration at 211 cm(-1). The combined effects of the HbII(Lp) small heme pocket, the hydrogen bonding network, the His(97) trans-effect, and the orientation of the oxygen molecule confer stability to the oxy-HbII(Lp) complex. Oxidation of HbI(Lp) Phe(B10) --> Tyr and HbII(Lp) only occurs when the pH is decreased from pH 7.5 to 5.0. Structural and resonance Raman spectroscopy studies suggest that HbII(Lp) oxygen binding and transport to the host bacteria may be regulated by the dynamic displacements of the Gln(65)(E7) and Tyr(30)(B10) pair toward the heme to protect it from changes in the heme oxidation state from Fe(II) to Fe(III).     

Heme orientation modulates histidine dissociation and ligand binding kinetics in the hexacoordinated human neuroglobin

Neuroglobin (Ngb) is a globin present in the brain and retina of mammals. This hexacoordinated hemoprotein binds small diatomic molecules, albeit with lower affinity compared with other globins. Another distinctive feature of most mammalian Ngb is their ability to form an internal disulfide bridge that increases ligand affinity. As often seen for prosthetic heme b containing proteins, human Ngb exhibits heme heterogeneity with two alternative heme orientations within the heme pocket. To date, no details are available on the impact of heme orientation on the binding properties of human Ngb and its interplay with the cysteine oxidation state. In this work, we used ¹H NMR spectroscopy to probe the cyanide binding properties of different Ngb species in solution, including wild-type Ngb and the single (C120S) and triple (C46G/C55S/C120S) mutants. We demonstrate that in the disulfide-containing wild-type protein cyanide ligation is fivefold faster for one of the two heme orientations (the A isomer) compared with the other isomer, which is attributed to the lower stability of the distal His64–iron bond and reduced steric hindrance at the bottom of the cavity for heme sliding in the A conformer. We also attribute the slower cyanide reactivity in the absence of a disulfide bridge to the tighter histidine–iron bond. More generally, enhanced internal mobility in the CD loop bearing the disulfide bridge hinders access of the ligand to heme iron by stabilizing the histidine–iron bond. The functional impact of heme disorder and cysteine oxidation state on the properties of the Ngb ligand is discussed.     

Residues in the distal heme pocket of neuroglobin. Implications for the multiple ligand binding steps

Amino acid residues in the ligand binding pocket of human neuroglobin have been identified by site-directed mutagenesis and their properties investigated by resonance Raman and flash photolysis methods. Wild-type neuroglobin has been shown to have six-coordinate heme in both ferric and ferrous states. Substitution of His96 by alanine leads to complete loss of heme, indicating that His96 is the proximal ligand. The resonance Raman spectra of M69L and K67T mutants were similar to those of wild-type (WT) neuroglobin in both ferric and ferrous states. By contrast, H64V was six-coordinate high-spin and five-coordinate high-spin in the ferric and ferrous states, respectively, at acidic pH. The spectra were pH-dependent and six-coordinate with the low-spin component dominating at alkaline pH. In a double mutant H64V/K67T, the high-spin component alone was detected in the both ferric and the ferrous states. This implies that His64 is the endogenous ligand and that Lys67 is situated nearby in the distal pocket. In the ferrous H64V and H64V/K67T mutants, the nu(Fe-His) stretching frequency appears at 221 cm(-1), which is similar to that of deoxymyoglobin. In the ferrous CO-bound state, the nu(Fe-CO) stretching frequency was detected at 521 and 494 cm(-1) in WT, M69L, and K67T, while only the 494 cm(-1) component was detected in the H64V and H64V/K67T mutants. Thus, the 521 cm(-1) component is attributed to the presence of polar His64. The CO binding kinetics were biphasic for WT, H64V, and K67T and monophasic for H64V/K67T. Thus, His64 and Lys67 comprise a unique distal heme pocket in neuroglobin.     

High-level production of recombinant sulfide-reactive hemoglobin I from Lucina pectinata in Escherichia coli. High yields of fully functional holoprotein synthesis in the BLi5 E. coli strain

Hemoglobin I (HbI) from Lucina pectinata is a monomeric protein composed of 143 amino acids with high sulfide affinity. Its unique heme pocket contains three residues not commonly found in vertebrate globins: Phe 29 (B10), Gln 64 (E7), and Phe 68 (E11), which are thought to be important for high affinity for hydrogen sulfide. Recombinant HbI (rHbI) and several site-directed mutants were cloned and expressed in Escherichia coli yielding high amounts of protein. The highest rHbI protein yield was obtained when the HbI cDNA was cloned into the pET28 (a+) expression vector, transformed into BLi5 cells, the induction performed with 1 mM IPTG at 30 degrees C and TB medium was supplemented with 30 microg/mL hemin chloride and 1% glucose. The highest yield obtained of HbI was 32 mg/L of culture using Fernbach flasks. UV/Visible spectral analysis showed that rHbI binds heme and ESI-MS shows that its molecular weight corresponds to the expected size. Kinetic studies with H2S confirmed that rHbI and HbI have identical binding properties, where the kON for the clam's Hb is 2.73x10(4)M-1s-1 and for rHbI is 2.43x10(4)M-1s-1.     

Distal residue-CO interaction in carbonmonoxy myoglobins: a molecular dynamics study of three distal mutants.

Six 90-ps molecular dynamics trajectories, two for each of three distal mutants of sperm whale carbonmonoxy myoglobin, are reported; solvent waters within 16 A of the active site have been included. In both His64GIn trajectories, the distal side chain remains part of the heme pocket, forming a "closed" conformation similar to that of the wild type 64N delta H tautomer. Despite a connectivity more closely resembling the N epsilon H histidine tautomer, close interactions with the carbonyl ligand similar to those observed for the wild type 64N epsilon H tautomer are prevented in this mutant by repulsive interactions between the carbonyl O and the 64O epsilon. The aliphatic distal side chain of the His64Leu mutant shows little interaction with the carbonyl ligand in either His64Leu trajectory. Solvent water molecules move into and out of the active site in the His64Gly mutant trajectories; during all the other carbonmonoxy myoglobin trajectories, including the wild type distal tautomers considered in an earlier work, solvent molecules rarely encroach closer than 6 A of the active site. These results are consistent with a recent structural interpretation of the wild type infrared spectrum, and the current reinterpretation that the distal-ligand interaction in carbonmonoxy myoglobin is largely electrostatic, not steric, in nature.     

The comparative study on the solution structures of the oxidized bovine microsomal cytochrome b5 and mutant V45H

A comparative study on the solution structures of bovine microsomal cytochrome b5 (Tb5) and the mutant V45H has been achieved by 1D and 2D 1H-NMR spectroscopy to clarify the differences in the solution conformations between these two proteins. The results reveal that the global folding of the V45H mutant in solution is unchanged, but the subtle changes exist in the orientation of the axial ligand His39, and heme vinyl groups. The side chain of His45 in V45H mutant extends to the outer edge of the heme pocket leaving a cavity at the site originally occupied by the inner methyl group of Val45 residue. In addition, the imidazole ring of axial ligand His39 rotates counterclockwise by approximately 3 degrees around the His-Fe-His axis, and the 4-heme vinyl group turns to the space vacated by the removed side chain due to the mutation. Furthermore, the helix III of the heme pocket undergoes outward displacement, while the linkage between helix II and III is shifted leftward. These observations are not only consistent with the pattern of the pseudocontact shifts of the heme protons, but also well account for the lower stability of V45H mutant against heat and urea.     

Sulfide-binding hemoglobins: Effects of mutations on active-site flexibility

The dynamics of Hemoglobin I (HbI) from the clam Lucina pectinata, from wild-type sperm whale (SW) myoglobin, and from the L29F/H64Q/V68F triple mutant of SW, both unligated and bound to hydrogen sulfide (H2S), have been studied in molecular dynamics simulations. Features that account for differences in H2S affinity among the three have been examined. Our results verify the existence of an unusual heme rocking motion in unligated HbI that can promote the entrance of large ligands such as H2S. The FQF-mutant partially reproduces the amplitude and relative orientation of the motion of HbI's heme group. Therefore, besides introducing favorable electrostatic interactions with H2S, the three mutations in the distal pocket change the dynamic properties of the heme group. The active-site residues Gln-64(E7), Phe-43(CD1), and His-93(F8) are also shown to be more flexible in unligated HbI than in FQF-mutant and SW. Further contributions to H2S affinity come from differences in hydrogen bonding between the heme propionate groups and nearby amino acid residues.