Proton nuclear magnetic resonance study of the solution distal histidine orientation in monomeric Chironomus thummi thummi cyanomet hemoglobins. Dynamic stability of the heme pocket as monitored by labile proton exchange

Orientation of the heme vinyl groups in the hydrogen sulfide-binding hemoglobin I from Lucina pectinata

Hemoglobin I (HbI) from the claim Lucina pectinata is a unique heme protein that binds and transfers hydrogen sulfide (H2S) to a symbiotic bacteria. The metcyano, metaquo, carbon monoxy, oxy, and deoxy complexes of HbI were studies by resonance Raman (RR) spectroscopy, and the metacyano and carbon monoxy complexes were also studied by 1H-NMR. The results indicate a unique orientation of the heme 2-vinyl group relative to other heme proteins. The RR spectra of the HbICO, metHbICN, metHbIH2O, HbIO2 and deoxyHbI heme derivatives show a band at 1621 cm-1 and a shoulder at 1626 cm-1, indicative of an out-of-plane position for one of the vinyls relative to the other one. Spin-lattice relaxation properties of protons in the metHbICN complex also suggest a unique orientation for the heme 2-vinyl group of HbI. The longitudinal relaxation time (T1) for the 2-H alpha, 2-H beta c, and H beta t protons are 120 ms, 115 ms, and 135 ms, respectively. The data from both techniques suggest an out-of-plane and trans-oriented 2-vinyl group, and an in-plane and cis-oriented 4-vinyl group for the low-spin complexes of HbI. These results imply that the electron withdrawing character of the out-of-plane vinyl group contributes to the stability of the heme Fe+3 oxidation state, facilitates the binding of the H2S ligand, and promotes the stability of this ferric H2S complex.

Dynamic properties of monomeric insect erythrocruorin III from Chironomus thummi-thummi: relationships between structural flexibility and functional complexity

We have investigated the kinetics of geminate carbon monoxide binding to the monomeric component III of Chironomus thummi-thummi erythrocruorin, a protein that undergoes pH-induced conformational changes linked to a pronounced Bohr effect. Measurements were performed from cryogenic temperatures to room temperature in 75% glycerol and either 0.1 M potassium phosphate (pH 7) or 0.1 potassium borate (pH 9) after nanosecond laser photolysis. The distributions of the low temperature activation enthalpy g(H) for geminate ligand binding derived from the kinetic traces are quite narrow and are influenced by temperature both below and above approximately 170 K, the glass transition temperature. The thermal evolution of the CO binding kinetics between approximately 50 K and approximately 170 K indicates the presence of some degree of structural relaxation, even in this temperature range. Above approximately 220 K the width of the g(H) progressively decreases, and at 280 K geminate CO binding becomes exponential in time. Based on a comparison with analogous investigations of the homodimeric hemoglobin from Scapharca inaequivalvis, we propose a link between dynamic properties and functional complexity.

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.

Assignment of the hyperfine-shifted 1H-NMR signals of the heme in the oxygen sensor FixL from Rhizobium meliloti

BACKGROUND

[corrected] The Rhizobial oxygen sensor FixL is a hemoprotein with kinase activity. On binding of strong-field ligands, a change of the ferrous or ferric heme iron from high to low spin reversibly inactivates the kinase. This spin-state change and other information on the heme pocket have been inferred from enzymatic assays, absorption spectra and mutagenesis studies. We set out to investigate the spin-state of the FixL heme and to identify the hyperfine-shifted heme-proton signals by NMR spectroscopy.

RESULTS

Using one-dimensional NMR we directly observed the high- and low-spin nature of the met- and cyanomet-FixL heme domain, respectively. We determined the hyperfine-shifted 1H-NMR signals of the heme and the proximal histidine by one- and two-dimensional spectroscopy and note the absence of distal histidine signals.

CONCLUSIONS

These findings support the spin-state mechanism of FixL regulation. They establish that the site of heme coordination is a histidine residue and strongly suggest that a distal histidine is absent. With a majority of the heme resonances identified, one- and two-dimensional NMR techniques can be extended to provide structural and mechanistic information about the residues that line the heme pocket.

Solution 1H-NMR structure of the heme cavity in the low-affinity state for the allosteric monomeric cyano-met hemoglobins from Chironomus thummi thummi. Comparison to the crystal structure

Solution 1H-NMR studies of the heme cavity were performed for the cyanomet complexes of monomeric hemoglobins III and IV from the insect Chironomus thummi thummi, each of which exhibit marked Bohr effects. The low pH 5, paramagnetic (S = 1/2) derivatives were selected for study because the large dipolar shifts provide improved resolution over diamagnetic forms and allow distinction between the two isomeric heme orientations [Peyton, D. H., La Mar, G. N. & Gersonde, K. (1988) Biochim. Biophys. Acta 954, 82-94]. The crystal structure for the low-pH form of the hemoglobin III derivative, moreover, has been reported and showed that the functionally implicated distal His58 side chain adopts alternative orientation, either in or out of the pocket [Steigemann, W. & Weber, E. (1979) J. Mol. Biol. 127, 309-338]. All heme pocket residues for the low-pH forms of the two hemoglobins were located, at least in part, and positioned in the heme cavity on the basis of nuclear Overhauser effects to the heme and each other, dipolar shifts, and paramagnetic-induced relaxation. The resulting structure yielded the orientation of the major axis of the paramagnetic susceptibility tensor. The heme pocket structure of the cyanomet hemoglobins III and IV were found to be indistinguishable, with both exhibiting a distal His58 oriented solely into the heme cavity and in contact with the ligand, and with two residues, Phe100 and Phe38, exhibiting small but significant displacements in solution relative to hemoglobin III in the crystal.

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.

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.