G. N. La Mar

Proton magnetic resonance characterization of the dynamic stability of the heme pocket in myoglobin by the exchange behavior of the labile proton of the proximal histidyl imidazole.

The assigned exchangeable proton signals in the proton nuclear magnetic resonance spectra of sperm whale deoxy and Met-cyano myoglobin in H2O solution were found to exhibit pH-dependent saturation transfer from the bulk water, which allowed determination of the kinetics and mechanism of the labile proton exchange with solvent. The exchange rates are base catalyzed for both protein forms, with the rate eight times faster in Met-cyano than in deoxy myoglobin. The exchange rate is taken as a measure of the magnitude of the fluctuation in the protein conformation near the heme cavity. On the basis of tritium exchange methods, the greater stability of the unligated relative to the ligated state in myoglobin has also been reported for hemoglobin. The present study, however, localizes the differential kinetic stability on the F helix whose flexibility has been implicated in the mechanism of cooperativity. The observation that filling the hydrophobic vacancy on the proximal side of the heme near the proximal histidine in Met-cyano myoglobin wih cyclopropane increases the proton lability argues against the role for this hole in facilitating the flexibility of the F helix in the native protein.

The homonuclear Overhauser effect in H2O solution of low-spin hemeproteins

Proton-proton Overhauser effects were observed in 1H2O solutions of sperm whale metcyano myoglobin. Dipolar connectivities involving hyperfine-shifted exchangeable protons such as the proximal and distal histidine ring NHs allowed us to categorize signals as arising from residues located on one side of the heme plane or on the other. With these connectivities, as well as spin-lattice relaxation times, spectral assignments were reached that were used to derive structural and dynamic information about the heme environment. Thus, it was shown that the distal histidine residue does not titrate down to pH ∼4.1 and that the βCH2 of the proximal histidine side chain tumbles with the same correlation time as the protein. Some other applications and limitations are presented.

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.

Pulse Fourier transform water suppression and underwater decoupling in aqueous solutions

Abstract A pulse Fourier transform NMR double-resonance technique is described for simultaneous water suppression and underwater decoupling in 90 to 95% H2O solutions. Suppression of the intense water resonance is achieved via saturation with a selective pulse from the observe rf transmitter. This long soft pulse is applied prior to the nonselective acquisition pulse and is phase shifted from its initial phase by 180° on alternate scans. A requirement of the method, then, is that the observe rf transmitter be capable of switching from a low-power (∼1 W) to a high-power (∼100 W) mode of operation under computer control. Decoupling is achieved with a time-shared homonuclear decoupling field whose rf phase is also shifted by 180° on alternate scans. Spectrometer adjustments which, if not taken into consideration, impede the routine application of the technique, are discussed.

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.

13C nuclear magnetic resonance spectra of aflatoxin B1 derived from acetate

Abstract The labeling distribution of the fungal metabolite, aflatoxin B 1 , produced from [1- or 2- 13 C] acetate was determined by 13 C FT NMR. The results support the polyketide hypothesis for aflatoxin biogenesis.

NMR study of the exchange rates of allosterically responsive labile protons in the heme pockets of hemoglobin A.

1H NMR spectroscopy has been used to measure the proximal histidyl labile ring proton (NH) rates of exchange with bulk solvent in the individual subunits of hemoglobin (Hb) A. These protons displayed a substantial decrease in their exchange rates in comparison with related monomeric proteins and exhibited sensitivity to the quarternary state. With the beta subunit NH, the exchange behaviour was similar to an allosterically responsive subset of protons, which have been identified using 1H-3H methods (Englander, J.J., R. Rogero, and S. W. Englander, 1983, J. Mol. Biol. 169:325-344). Assuming similar exchange mechanisms for the two subunits, the NMR data suggested a more flexible alpha than beta subunit in Hb A.

Proton magnetic resonance study of the influence of heme 2,4 substituents on the exchange rates of labile protons in the heme pocket of myoglobin

Four exchangeable protons with large hyperfine shifts are assigned in the heme pocket of sperm whale met-cyano myoglobin reconstituted with heme possessing acetyl groups, ethyl groups, bromines, and hydrogens at the 2,4 position, using both relaxation and chemical-shift data. The four protons arise from the ring NHs of the proximal (F8), distal (E7), and FG2 histidines, and the peptide NH of His F8. The similarity of all chemical shifts to those of the native protein as well as the invariance of the relaxation rates of the distal histidyl ring NH dictate essentially the same structure for the heme cavity of both native and reconstituted proteins. The exchange rates with bulk water of the four labile proteins in each modified protein were determined by saturation-transfer and line width methods. All four labile protons were found to have the same exchange rate as in the native protein for acetyl and ethyl 2,4 substituents; the two resolved labile protons in the derivative with 2,4 bromine were also unchanged. The reconstituted protein with hydrogens at the 2,4 position exhibited slower exchange rates for three of the four protons, indicating an increased dynamic stability of the heme pocket in the absence of bulky 2,4 substituents.

High-field 1H NMR studies of synthetic analogs of somatostatin: Structural features involving aromatic residues in an active eight-membered ring analog

360 MHz 1H-NMR data are presented for somatostatin and an analog whose primary structure is cyclo(-Gaba-Asn5-Phe6-Phe7-DTrp8-Lys9-Thr10-Phe11-). This report focuses on the aromatic portion of the spectrum, and this region for the analog is unambiguously assigned, using two experimental approaches: selective deuteration and photo-induced CIDNP. The most prominent feature of the analog aromatic spectrum is a two-proton resonance which exhibits a pronounced upfield shift. Significantly, this feature is also present for somatostatin and other active analogs (unpublished data). Assignments show that this resonance derives from the ortho hydrogens of the Phe6 and that aromatic resonances of Phe6 shift markedly upfield as temperature is decreased. In contrast, the aromatic resonances of Phe7,11 and DTrp8 reveal generally much smaller temperature coefficients and shift primarily downfield as temperature is decreased. Ring-current analysis shows that simple pair-wise parallel pi-stacking alone cannot give rise to the observed data. However, a simple hypothesis involving only two phenylalanine residues is totally consistent with the data if they maintain a time-averaged co-perpendicular orientation. Indirect evidence is offered which implicates only one phenylalanine stacking partner for Phe6, which we tentatively identify as Phe11.