1H and 13C NMR investigation of the influence of nonligated residue contacts on the heme electronic structure in cyanometmyoglobin complexes reconstituted with centro- and pseudocentrosymmetric hemins.

The 1H and 13C chemical shifts for the heme methyls of low-spin, ferric sperm whale cyanometmyoglobin reconstituted with a variety of centrosymmetric and pseudocentrosymmetric hemins have been recorded and analyzed to shed light on the nature of heme-protein contacts, other than that of the axial His, that modulate the rhombic perturbation to the heme's in-plane electronic asymmetry. The very similar 1H dipolar shifts for heme pocket residues in all complexes yield essentially the same magnetic axes as in wild type, and the resultant dipolar shifts allow the direct determination of the heme methyl proton and 13C contact shifts in all complexes. It is demonstrated that, even when the magnetic axes and anisotropies are known, the intrinsic uncertainties in the orientational parameters lead to a sufficiently large uncertainty in dipolar shift that the methyl proton contact shifts are inherently significantly less reliable indicators of the unpaired electron spin distribution than the methyl 13C contact shifts. The pattern of the noninversion symmetry in 13C contact shifts in the centro- or pseudocentrosymmetric hemes is shown to correlate with the positions of aromatic rings of Phe43(CD1) and His97(FG3) parallel to, and in contact with, the heme. These results indicate that such pi-pi interactions significantly perturb the in-plane asymmetry of the heme pi spin distribution and cannot be ignored in a quantitative interpretation of the heme methyl 13C contact shifts in terms of the axial His orientation in b-type hemoproteins.

Solution NMR characterization of the thermodynamics of the disulfide bond orientational isomerism and its effect of cluster electronic properties for the hyperthermostable three-iron cluster ferredoxin from the archaeon Pyrococcus furiosus.

The thermodynamics and dynamics of the Cys21-Cys48 disulfide "S" if "R" conformational isomerism in the three-iron, single cubane cluster ferredoxin (Fd) from the hyperthermophilic archaeon Pyrococcus furiosus (Pf) have been characterized by (1)H NMR spectroscopy in both water and water/methanol mixed solvents. The mean interconversion rate at 25 degrees C is 3 x 10(3) s(-1) and DeltaG(298) = -0.2 kcal/mol [DeltaH = 4.0 kcal/mol; DeltaS = 14 cal/(mol.K)], with the S orientation as the more stable form at low temperature (< 0 degrees C) but the R orientation predominating at >100 degrees C, where the organism thrives. The distinct pattern of ligated Cys beta-proton contact shifts for the resolved signals and their characteristic temperature behavior for the forms of the 3Fe Fd with alternate disulfide orientations have been analyzed to determine the influences of disulfide orientation and methanol cosolvent on the topology of the inter-iron spin coupling in the 3Fe cluster. The Cys21-Cys48 disulfide orientation influences primarily the spin couplings involving the iron ligated to Cys17, whose carbonyl oxygen is a hydrogen bond acceptor to the Cys21 peptide proton. Comparison of the Cys beta-proton contact shift pattern for the alternate disulfide orientations with the pattern exhibited upon cleaving the disulfide bridge confirms an earlier [Wang, P.-L., Calzolai, L., Bren, K. L., Teng, Q., Jenney, F. E., Jr., Brereton, P. S., Howard, J. B., Adams, M. W. W., and La Mar, G. N. (1999) Biochemistry 38, 8167-8178] proposal that the structure of the same Fd with the R disulfide orientation resembles that of the Fd upon cleaving the disulfide bond.

Solution NMR determination of the seating(s) of meso-nitro-etioheme-1 in myoglobin: implications for steric constraints to meso position access in heme degradation by coupled oxidation.

The highly stereoselective cleavage of hemin in myoglobin by coupled oxidation has been attributed to steric barriers that leave more space near the alpha- than the other meso-positions. The steric barriers near meso positions in myoglobin have been investigated by establishing the thermodynamics and dynamics of possible seatings in the pocket of horse myoglobin of a four-fold symmetric etioheme I modified with a bulky nitro group at a single meso position. The cyanomet complex of this reconstituted myoglobin exhibits three sets of (1)H NMR resonances that are linked dynamically and occur in approximate populations ratios of 0.82:0.10:0.08. Two dimensional (1)H NMR has been used to assign the hemin and heme pocket resonances in the major isomer in solution and to determine that the hemin is oriented with the nitro group at the canonical gamma-meso position of native hemin. The dominance of this isomer is attributed to the solvent exposure of this portion of the hemin which stabilizes the highly polar nitro group. Using a combination of magnetization transfer among methyl groups of the three isomers due to "hopping" of the hemin about its normal, the assigned resonances of an isoelectronic, bis-cyano complex of meso-nitro-etioheme I, and the known essentially constant rhombic perturbation of heme pocket sites on the hyperfine shifts of heme methyl (Kolczak, U.; Hauksson, J. B.; Davis, N. L.; Pande, U.; de Ropp, J. S.; Langry, K. C.; Smith, K. M.; LaMar, G. N. J. Am. Chem. Soc. 1999, 121, 835-843); the two minor isomers are shown to place their bulky nitro group at the canonical delta-meso (8%) and alpha-meso positions (10%). The comparable population of the isomers with nitro groups at the hydrophobic alpha- and delta-meso positions dictates that, while the static crystal structure finds more room near the alpha-meso position, the deformation at minimal energetic expense near the alpha- and delta-meso positions is comparable. These results argue that factors other than simple steric influences control the selectivity of the ring cleavage in myoglobin.

Solution 1H NMR of the molecular and electronic structure of the heme cavity and substrate binding pocket of high-spin ferric horseradish peroxidase: effect of His42Ala mutation.

Solution 1H NMR has been used to assign a major portion of the heme environment and the substrate-binding pocket of resting state horseradish peroxidase, HRP, despite the high-spin iron(III) paramagnetism, and a quantitative interpretive basis of the hyperfine shifts is established. The effective assignment protocol included 2D NMR over a wide range of temperatures to locate residues shifted by paramagnetism, relaxation analysis, and use of dipolar shifts predicted from the crystal structure by an axial paramagnetic susceptibility tensor normal to the heme. The most effective use of the dipolar shifts, however, is in the form of their temperature gradients, rather than by their direct estimation as the difference of observed and diamagnetic shifts. The extensive assignments allowed the quantitative determination of the axial magnetic anisotropy, Deltachi(ax) = -2.50 x 10(-8) m(3)/mol, oriented essentially normal to the heme. The value of Deltachi(ax) together with the confirmed T(-2) dependence allow an estimate of the zero-field splitting constant D = 15.3 cm(-1), which is consistent with pentacoordination of HRP. The solution structure was generally indistinguishable from that in the crystal (Gajhede, M.; Schuller, D. J.; Henriksen, A.; Smith, A. T.; Poulos, T. L. Nature Structural Biology 1997, 4, 1032-1038) except for Phe68 of the substrate-binding pocket, which was found turned into the pocket as found in the crystal only upon substrate binding (Henriksen, A.; Schuller, D. J.; Meno, K.; Welinder, K. G.; Smith, A. T.; Gajhede, M. Biochemistry 1998, 37, 8054-8060). The reorientation of several rings in the aromatic cluster adjacent to the proximal His170 is found to be slow on the NMR time scale, confirming a dense, closely packed, and dynamically stable proximal side up to 55 degrees C. Similar assignments on the H42A-HRP mutant reveal conserved orientations for the majority of residues, and only a very small decrease in Deltachi(ax) or D, which dictates that five-coordination is retained in the mutant. The two residues adjacent to residue 42, Ile53 and Leu138, reorient slightly in the mutant H42A protein. It is concluded that effective and very informative 1H NMR studies of the effect of either substrate binding or mutation can be carried out on resting state heme peroxidases.

Solution 1H NMR characterization of axial interactions of the proximal and distal His in the cyanomet complexes of the isolated chains and the 65 kDa intact tetramer of human hemoglobin A.

Solution 1H NMR has been used to investigate the axial bonding of the proximal His and the hydrogen-bonding of the distal His to the bound ligand in the isolated chains as well as the subunits of intact, tetrameric, cyanomet human hemoglobin A. The complete proximal His, including all ring protons necessary to monitor bonding in each subunit, could be definitively assigned by 1D/2D methods despite the large size (approximately 65 kDa) and severe relaxation (to T(1) approximately 3 ms, line width approximately 1.5 kHz) of two of the protons. The complete distal His E7 ring was assigned in the alpha-chain and alpha-subunit of HbA, and the dipolar shifts and relaxation were analyzed to reveal a disposition intermediate between the positions adopted in HbCO and HbO2 that is optimal for forming a hydrogen bond with bound cyanide. The lability of the alpha-subunit His E7 NepsilonH is found to be similar to that in sperm whale cyanomet myoglobin. The orientation of the distal His E7 in the beta-subunit is found to be consistent with that seen in either HbCO or HbO2. While the His E7 labile NepsilonH proton signal could not be detected in either the beta-chain or subunit, it is concluded that this more likely reflects increased lability over that of the alpha-subunit, and not the absence of a hydrogen bond to the bound ligand. Analysis of the heme mean methyl hyperfine shift, which has been shown to be very sensitive to the presence of distal hydrogen bonds to bound cyanide (Nguyen, B. D.; Xia, Z.; Cutruzzolá, F.; Travaglini Allocatelli, C.; Brancaccio, A.; Brunori, M.; La Mar, G. N. J. Biol. Chem. 2000, 275, 742-751), directly supports the presence of a distal His E7 hydrogen bond to cyanide in the beta-chain and beta-subunit which is weaker than the same hydrogen bond in the alpha-subunit. The potential for the proximal His hyperfine shifts in serving as indicators of axial strain in the allosteric transition of HbA is discussed.

Solution 1H NMR of the active site of substrate-bound, cyanide-inhibited human heme oxygenase. comparison to the crystal structure of the water-ligated form.

The majority of the active site residues of cyanide-inhibited, substrate-bound human heme oxygenase have been assigned on the basis of two-dimensional NMR using the crystal structure of the water-ligated substrate complex as a guide (Schuller, D. J., Wilks, A., Ortiz de Montellano, P. R., and Poulos, T. L. (1999) Nat. Struct. Biol. 6, 860-867). The proximal helix and the N-terminal portion of the distal helix are found to be identical to those in the crystal except that the heme for the major isomer ( approximately 75-80%) in solution is rotated 180 degrees about the alpha-gamma-meso axis relative to the unique orientation in the crystal. The central portion of the distal helix in solution is translated slightly over the heme toward the distal ligand, and a distal four-ring aromatic cluster has moved 1-2 A closer to the heme, which allows for strong hydrogen bonds between the hydroxyls of Tyr-58 and Tyr-137. These latter interactions are proposed to stabilize the closed pocket conducive to the high stereospecificity of the alpha-meso ring opening. The determination of the magnetic axes, for which the major axis is controlled by the Fe-CN orientation, reveals a approximately 20 degrees tilt of the distal ligand from the heme normal in the direction of the alpha-meso bridge, demonstrating that the close placement of the distal helix over the heme exerts control of stereospecificity by both blocking access to the beta, gamma, and delta-meso positions and tilting the axial ligand, a proposed peroxide, toward the alpha-meso position.

Solution 1H NMR investigation of the seating and rotational "hopping" of centrosymmetric etioheme-I in myoglobin: effect of globin origin and its oxidation/spin state on heme dynamics.

Solution 1H NMR spectroscopy was used to investigate the heme active-site structure and dynamics of rotation about the Fe-His bond of centrosymmetric etioheme-I reconstituted into sperm whale and horse myoglobin (Mb). Comparison of the NOESY cross-peak pattern and paramagnetic relaxation properties of the cyanomet complexes confirm a heme pocket that is essentially the same as Mb with either native protoheme or etioheme-I. Dipolar contacts between etioheme and the conserved heme pocket residues establish a unique seating of etioheme that conserves the orientation of the N-Fe-N vector relative to the axial His plane, with ethyl groups occupying the vinyl positions of protoheme. Saturation transfer between methyls on adjacent pyrroles in etioheme-reconstituted horse Mb in all accessible oxidation/spin states reveals rotational hopping rates that decrease dramatically with either loss of ligands or reduction of the heme, and correlate qualitatively with expectations based on the Fe-His bond strength and the rate of heme dissociation from Mb. The rate of hopping for etioheme in metMbCN, in contrast to hemes with propionates, is the same in the sperm whale and horse proteins.

The use of chemical shift temperature gradients to establish the paramagnetic susceptibility tensor orientation: implication for structure determination/refinement in paramagnetic metalloproteins.

The use of dipolar shifts as important constraints in refining molecular structure of paramagnetic metalloproteins by solution NMR is now well established. A crucial initial step in this procedure is the determination of the orientation. of the anisotropic paramagnetic susceptibility tensor in the molecular frame which is generated interactively with the structure refinement. The use of dipolar shifts as constraints demands knowledge of the diamagnetic shift. which, however, is very often not directly and easily accessible. We demonstrate that temperature gradients of dipolar shifts can serve as alternative constraints for determining the orientation of the magnetic axes, thereby eliminating the need to estimate the diamagnetic shifts. This approach is tested on low-spin, ferric sperm whale cyanometmyoglobin by determining the orientation, anisotropies and anisotropy temperature gradients by the alternate routes of using dipolar shifts and dipolar shift gradients as constraints. The alternate routes ultimately lead to very similar orientation of the magnetic axes, magnetic anisotropies and magnetic anisotropy temperature gradients which, by inference, would lead to an equally valid description of the molecular structure. It is expected that the use of the dipolar shift temperature gradients, rather than the dipolar shifts directly, as constraints will provide an accurate shortcut in a solution structure determination of a paramagnetic metalloprotein.

Solution 1H NMR study of the heme cavity and folding topology of the abbreviated chain 118-residue globin from the cyanobacterium Nostoc commune.

The globin from the cyanobacterium Nostoc commune, abbreviated GlbN, which appears to serve as a part of a terminal oxidase rather than as a respiratory pigment, displays relatively normal O2 binding properties, despite the highly abbreviated polypeptide chain, (118 residues) relative to more conventional globins [Thorsteinsson, M. V. , Bevan, D. R., Potts, M., Dou, Y., Eich, R. F., Hargrove, M. S., Gibson, Q. H., and Olson, J. S. (1999) Biochemistry 38, 2117-2126]. The nature of the heme cavity and the general folding topology of this cyanoglobin were investigated by solution 1H NMR to establish the extent to which, and the manner in which, this compact globin adheres to the standard globin fold. This represents by far the smallest globin subjected to structural analysis. The paramagnetic cyanomet derivative was selected because its characteristically large magnetic anisotropy imparts significant dipolar shifts which both improve resolution to greatly facilitate assignments and serve as indicators of the folding topology of the globin. Identification of the axial His 70 and highly conserved Phe 35 (CD1) determined the absolute orientation of the heme and proximal His. Sequential assignments of four helical and one loop segments, which exhibit dipolar contacts to the heme and among each other, confirm the presence of well-conserved F, G, and H helices and the FG corner. The majority of the abbreviation of the chain relative to the more conventional length globins is accommodated in the A-D helices, of which the last is completely missing. The distal residue which provides a H-bond to bound ligand is identified as Gln 43, but the expected helical position E7 could not be confirmed. His 46, placed at position E10, is found to adopt alternate orientations into, and out of, the heme cavity depending on protonation state, suggesting the presence of a Bohr effect at low pH. It is shown that the dipolar shifts exhibited by backbone protons for the assigned residues conform well to those observed for other cyanomet globins and further support a conserved Mb fold. Perturbed medium-range dipolar contacts and the pH-independent backbone proton lability of the F helix are interpreted in terms of a holoprotein which is less stable than a conventional length globin.

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.

Secondary structure extensions in Pyrococcus furiosus ferredoxin destabilize the disulfide bond relative to that in other hyperthermostable ferredoxins. Global consequences for the disulfide orientational heterogeneity.

The single cubane cluster ferredoxin (Fd) from the hyperthermophilic archaeon Pyrococcus furiosus (Pf) possesses several unique properties when compared even to Fds from other hyperthermophilic archaea or bacteria. These include an equilibrium molecular heterogeneity, a six- to seven-residue increase in size, an Asp rather than the Cys as one cluster ligand, and a readily reducible disulfide bond. NMR assignments and determination of both secondary structure and tertiary contacts remote from the paramagnetic oxidized cluster of Pf 3Fe Fd with an intact disulfide bond reported previously (Teng Q., Zhou, Z. H., Smith, E. T., Busse, S. C., Howard, J. B. Adams, M. W. W., and La Mar, G. (1994) Biochemistry 33, 6316-6328) are extended here to the 4Fe oxidized cluster WT (1H and 15N) and D14C (1H only) Fds with an intact disulfide bond and to the 4Fe oxidized WT Fd (1H and 15N) with a cleaved disulfide bond. All forms are shown to possess a long (13-member) alpha-helix, two beta-sheets (one double-, one triple-stranded), and three turns outside the cluster vicinity, each with tertiary contacts among themselves as found in other Fds. While the same secondary structural elements, with similar tertiary contacts, are found in other hyperthermostable Fds, Pf Fd has two elements, the long helix and the triple-stranded beta-sheet, that exhibit extensions and form multiple tertiary contacts. All Pf Fd forms with an intact disulfide bond exhibit a dynamic equilibrium heterogeneity which is shown to modulate a hydrogen-bonding network in the hydrophobic core that radiates from the Cys21-Cys48 disulfide bond and encompasses residues Lys36, Val24, Cys21, and Cys17 and the majority of the long helix. The heterogeneity is attributed to population of the alternate S and R chiralities of the disulfide bond, each destabilized by steric interactions with the extended alpha-helix. Comparison of the chemical shifts and their temperature gradients reveals that the molecular structure of the protein with the less stable R disulfide resembles that of the Fd with a cleaved disulfide bond. Both cluster architecture (3Fe vs 4Fe) and ligand mutation (Cys for Asp14) leave the disulfide orientational heterogeneity largely unperturbed. It is concluded that the six- to seven-residue extension that results in a longer helix and larger beta-sheet in Pf Fd, relative to other hyperthermostable Fds, more likely serves to destabilize the disulfide bond, and hence make it more readily reducible, than to significantly increase protein thermostability.

Solution 1H NMR investigation of the heme cavity and substrate binding site in cyanide-inhibited horseradish peroxidase.

Solution two-dimensional 1H NMR studies have been carried out on cyanide-inhibited horseradish peroxidase isozyme C (HRPC-CN) to explore the scope and limitations of identifying residues in the heme pocket and substrate binding site, including those of the "second sphere" of the heme, i.e. residues which do not necessarily have dipolar contact with the heme. The experimental methods use a range of experimental conditions to obtain data on residue protons with a wide range of paramagnetic relaxivity. The signal assignment strategy is guided by the recently reported crystal structure of recombinant HRPC and the use of calculated magnetic axes. The goal of the assignment strategy is to identify signals from all residues in the heme, as well as proximal and distal, environment and the benzhydroxamic acid (BHA) substrate binding pocket. The detection and sequence specific assignment of aromatic and aliphatic residues in the vicinity of the heme pocket confirm the validity of the NMR methodologies described herein. Nearly all residues in the heme periphery are now assigned, and the first assignments of several "second sphere" residues in the heme periphery are reported. The results show that nearly all catalytically relevant amino acids in the active site can be identified by the NMR strategy. The residue assignment strategy is then extended to the BHA:HRPC-CN complex. Two Phe rings (Phe 68 and Phe 179) and an Ala (Ala 140) are shown to be in primary dipolar contact to BHA. The shift changes induced by substrate binding are shown to reflect primarily changes in the FeCN tilt from the heme normal. The present results demonstrate the practicality of detailed solution 1H NMR investigation of the manner in which substrate binding is perturbed by either variable substrates or point mutations of HRP.

Influence of proximal side mutations on the molecular and electronic structure of cyanomet myoglobin: an 1H NMR study.

A series of proximal side mutants of sperm whale metmyoglobin (metMb) that involves residues which provide hydrogen bonds to the axial His and heme have been prepared, and the CO binding and solution molecular and electronic structure has been investigated by 1H NMR. These include Ser92(F7), whose O gamma serves as a hydrogen-bond acceptor to the axial His ring NdeltaH and whose O gamma H serves as hydrogen-bond donor to the 7-propionate carboxylate, and His97(FG3) whose ring provides the other hydrogen-bond donor to the 7-propionate carboxylate. 2D NMR data on the S92A-metMbCN, S92P-metMbCN and H97F-metMbCN show that the distal structure is completely conserved and that proximal side structural changes are highly localized. For the S92A-metMbCN, altered dipolar contacts to the F-helix backbone show that the axial His imidazole has rotated clockwise by approximately 10 degrees relative to a stationary heme, while in H97F-metMbCN, the altered heme-E helix backbone contacts reveal that the heme has rotated counterclockwise by approximately 3 degrees relative to a conserved axial His. The pattern of axial His rotation was qualitatively predicted by energy minimization calculations. The assignments and conserved structural elements allow the determination of a set of magnetic axes whose major magnetic axis is unchanged with respect to WT and confirms that local distal, and not proximal, interactions control the orientation of the major magnetic axis and, by inference, the degree and direction of tilt of the Fe-CN from the heme normal. The rhombic magnetic axes in S92A-metMbCN are rotated approximately 10 degrees in the opposite direction from the established approximately 10 degrees rotation for the axial His ring as expected. It is shown, moreover, that the pairwise alpha-, gamma-meso vs beta-, delta-meso-H hyperfine shift differences are well predicted by the change in the location of the rhombic magnetic axes. Carbon monoxide ligation rates experience minor but systematic perturbation for the S92A substitutions which confirms an influence (albeit very small) for axial His orientation on ligand affinity.

Solution and crystal structures of a sperm whale myoglobin triple mutant that mimics the sulfide-binding hemoglobin from Lucina pectinata.

The bivalve mollusc Lucina pectinata harbors sulfide-oxidizing chemoautotrophic bacteria and expresses a monomeric hemoglobin I, HbI, with normal O2, but extraordinarily high sulfide affinity. The crystal structure of aquomet Lucina HbI has revealed an active site with three residues not commonly found in vertebrate globins: Phe(B10), Gln(E7), and Phe(E11) (Rizzi, M., Wittenberg, J. B., Coda, A., Fasano, M., Ascenzi, P., and Bolognesi, M. (1994) J. Mol. Biol. 244, 86-89). Engineering these three residues into sperm whale myoglobin results in a triple mutant with approximately 700-fold higher sulfide affinity than for wild-type. The single crystal x-ray structure of the aquomet derivative of the myoglobin triple mutant and the solution 1H NMR active site structures of the cyanomet derivatives of both the myoglobin mutant and Lucina HbI have been determined to examine further the structural origin of their unusually high sulfide affinities. The major differences in the distal pocket is that in the aquomet form the carbonyl of Gln64(E7) serves as a H-bond acceptor, whereas in the cyanomet form the amido group acts as H-bond donor to the bound ligand. Phe68(E11) is rotated approximately 90 degrees about chi2 and located approximately 1-2 A closer to the iron atom in the myoglobin triple mutant relative to its conformation in Lucina HbI. The change in orientation potentially eliminates the stabilizing interaction with sulfide and, together with the decrease in size of the distal pocket, accounts for the 7-fold lower sulfide affinity of the myoglobin mutant compared with that of Lucina HbI.

A myoglobin mutant designed to mimic the oxygen-avid Ascaris suum hemoglobin: elucidation of the distal hydrogen bonding network by solution NMR.

The solution 1H NMR structure of the active site and ligand dissociation rate for the cyanomet complex have been determined for a sperm whale myoglobin triple mutant Leu29(B10)-->Tyr, His64(E7)-->Gln, Thr67(E10)-->Arg that mimics the distal residue configuration of the oxygen-avid hemoglobin from Ascaris suum. A double mutant that retains Leu29(B10) was similarly investigated. Two-dimensional NMR analysis of the iron-induced dipolar shifts, together with the conserved proximal side structure for the two mutants, allowed the determination of the orientations of the paramagnetic susceptibility tensor for each complex. The resulting magnetic axes, together with paramagnetic relaxation and steady-state NOEs, led to a quantitative description of the distal residue orientations. The distal Tyr29(B10) in the triple mutant provides a strong hydrogen bond to the bound cyanide comparable to that provided by His64(E7) in wild-type myoglobin. The distal Gln64(E7) in the triple mutant is sufficiently close to the bound cyanide to severe as a hydrogen bond donor, but the angle is not consistent with a strong hydrogen bond. Dipolar contacts between the Arg67(E10) guanidinium group and the Gln64(E7) side chain in both mutants support a hydrogen-bond to the Gln64(E7) carbonyl group. The much lower oxygen affinity of this triple mutant relative to that of Ascaris hemoglobin is concluded to arise from side-chain orientations that do not allow hydrogen bonds between the Gln64(E7) side-chain NHs and both the ligand and Tyr29(B10) hydroxyl oxygen. Cyanide dissociation rates for the reduced cyanide complexes are virtually unaffected by the mutations and are consistent with a model of the rate-determining step as the intrinsically slow Fe-C bond breaking that is largely independent of any hydrogen bonds to the cyanide nitrogen.

Solution NMR study of the structural basis of the Bohr effect in the monomeric hemoglobins from Chironomus thummi thummi.

The larva of the midge Chironomus thummi thummi possesses two monomeric hemoglobins. HbIII and HbIV, with extensive sequence homology, which exhibit marked but differential Bohr effects (pH influence on ligand affinity). These Hbs serve as ideal models for allosteric control of ligand affinity via tertiary-only structural changes. The cyanomet derivatives of these two Hbs have been shown to possess essentially indistinguishable heme cavity structures in solution at low pH (Zhang et al., 1996) that are also very similar to that of the low pH form of HbIII in the crystal (Steigemann & Weber, 1979). 2D 1H NMR has been utilized to elucidate the solution heme cavity structure of the alkaline form of the cyanomet derivatives of HbIII and HbIV to identify the Bohr proton binding site and characterize the nature of the structural changes that accompany the allosteric transition. Significant structural changes with pH have been identified in two regions of the heme cavity, near the axial His and at the junction of pyrroles B and C. The Bohr proton site is identified as His94, which at low pH makes a salt bridge to the terminal Met136. The rupture of this salt bridge at high pH leads to the expulsion of the Met136 side chain next to the His F8 ring where it serves as a spacer between the heme and F-helix, and leads to a cascade of side chain reorientations in the densely packed hydrophobic interior involving five Phe (65, 66, 128, 129, 133), Val132, and Ile69, all on the E- and H-helices. The terminal member of the cascade, Phe65, which acts as a spacer between the E- and F-helices at low pH, is rotated toward the heme plane. The conversion of the low pH, low-affinity "tense" to the high pH, high-affinity "relaxed" state is primarily due to the removal of the Met136 and Phe65 spacers. A central residue in transmitting the Bohr effect from His94 to Phe65 is residue 132. In HbIV, Val132 provides a cavity in the hydrophobic core to readily accommodate the initial step in rotating the Phe129 side chain. In HbIII, the Ile132 provides tight packing to all neighboring side chains and hence would inhibit the rotation of the Phe129 side chain. It is proposed that the lone internal residue difference between HbIII (Ile132) and HbIV (Val132) is the primary basis for the different amplitudes of their Bohr effect.

Proton-NMR investigation of the heme cavity in the cyanomet derivative of the cooperative homodimeric hemoglobin from Scapharca inaequivalvis.

The active-site structure of the paramagnetic cyanomet complex of the cooperative homodimeric hemoglobin from Scapharca inaequivalvis has been investigated by solution homonuclear NMR. In spite of the large size (32 kDa), the residues on the key proximal F- and distal E-helices could be sequence-specifically assigned and placed in the heme pocket in a manner common to diamagnetic systems. These backbone assignments were greatly facilitated by the significant dispersion of backbone chemical shifts by the highly anisotropic paramagnetic susceptibility tensor of the low-spin ferric state. The remainder of the residues in contact with the heme are assigned based on unique contacts to the heme predicted by the crystal structure and the observations of scalar connectivities diagnostic for the residues. The magnitude of the dipolar shifts for non-ligated residues was used to determine the anisotropy and orientation of the paramagnetic susceptibility tensor, and the major axis found tilted from the normal in a manner similar to that found for the Fe-CO unit in the crystal structure. The combination of NOESY inter-residue and heme-residue contacts, paramagnetic-induced relaxation and correlation between observed and dipolar shifts provide a description of the heme cavity in cyanomet Hb that is essentially the same as found in the carbonmonoxy Hb crystal structure. The pattern of both the heme methyl dominant contact shifts and the heme meso-proton dominant dipolar shifts are shown to be consistent with the orientation of the axial His. It is concluded that the present homonuclear NMR methods allow effective solution structure determination in the cyanomet form for dimeric Hb and suggest profitable extension to the tetrameric vertebrate hemoglobins.

Molecular model of the solution structure for the paramagnetic four-iron ferredoxin from the hyperthermophilic archaeon Thermococcus litoralis.

A molecular model for the three-dimensional solution structure of the paramagnetic, four-iron ferredoxin (Fd) from the hyperthermophilic archaeon Thermococcus litoralis (Tl) has been constructed on the basis of the reported 1H NMR spectral parameters [Donaire, A. (1996) J. Biomol. NMR 7, 35-47]. The conventional use of long mixing time NOESY cross-peak intensity, backbone angles, and hydrogenbonding constraints for building the structure was augmented by short mixing time NOESY, steady-state NOE, paramagnetic relaxation constraints, and the angular dependence of the ligated Cys H beta contact shifts. Distance geometry was used to generate various initial structures, and these structures were refined with the simulated annealing protocol. The family of structures with inconsequential violations exhibited low RMS deviations for the backbone except for a few residues in the immediate cluster vicinity and traces out a secondary structure very similar to those of the structurally characterized single cubane cluster Fds. The ability to describe the cluster environment depended on the use of numerous paramagnetic relaxation constraints which resulted in even the cluster loop residues exhibiting well-defined orientations, with the exception of one residue (Ilel1) whose 1H signals have not been located. Comparison of the structure of Tl Fd to those of mesophilic ferredoxins reveals that Tl Fd possesses the same secondary structural elements, two beta-sheets, two helices, and four turns, with the exception that the beta-sheet involving the termini incorporates a third strand in Tl Fd. Several minor structural adjustments in Tl Fd relative to other Fds, in addition to the third strand for beta-sheet, include the incorporation of the termini into the beta-sheet, a likely salt bridge from the side chain of the third beta-strand to the N-terminus, and a more hydrophobic and compact interaction between the large beta-sheet and the long helix. It is likely that each of these modifications, among others not yet well-defined (i.e., surface salt bridges), contributes to the extraordinary thermostability of Tl Fd.