Gerd N. La Mar scite author profile

The presence of variable static hemin orientational disorder about the ␣-␥-meso axis in the substrate complexes of mammalian heme oxygenase, together with the incomplete averaging of a second, dynamic disorder, for each hemin orientation, has led to NMR spectra with severe spectral overlap and loss of key two-dimensional correlations that seriously interfere with structural characterization in solution. We demonstrate that the symmetric substrate, 2,4-dimethyldeuterohemin, yields a single solution species for which the dynamic disorder is sufficiently rapid to allow effective and informative Mammalian heme oxygenase (HO)1 is a ϳ300-residue, membrane-bound, non-heme enzyme that, using heme as cofactor and substrate, catalyzes the regiospecific conversion of heme to ␣-biliverdin, iron, and CO (1). The physiological roles of HO are heme catabolism (HO-1) (2-4) and the generation of CO as a putative neural messenger (HO-2) (5, 6). Detailed mechanistic (7-13) and spectroscopic (13-17) studies of the fully active recombinant, soluble 265-residue portion of HO-1 have shown that, in contrast to heme peroxidase and cytochrome P450, HO does not act through a ferryl intermediate. Recent crystal structures (18,19) of the substrate-bound, water-ligated complexes of a more truncated 233-residue human HO, hHO (20), and the complete rat HO (18), rHO, have revealed a largely helical enzyme that confirms the binding of heme by His-25 and locates a highly bent distal helix that is sufficiently close to the heme to sterically block all but the ␣-meso position (see Fig.

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Structural correlations and vinyl influences in resonance Raman spectra of protoheme complexes and proteins

Choi¹,

Spiro²,

Langry³

et al. 1982

J. Am. Chem. Soc.

323

248

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NMR determination of the orientation of the magnetic susceptibility tensor in cyanometmyoglobin: a new probe of steric tilt of bound ligand

1990

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The experimentally determined paramagnetic dipolar shifts for noncoordinated amino acid side-chain protons in the heme pocket of sperm whale cyanometmyoglobin [Emerson, S. d., & La Mar, G. N. (1990) Biochemistry (preceding paper in this issue]) were used to determine in solution the orientation of the principal axes for the paramagnetic susceptibility tensor relative to the heme iron molecular coordinates. The determination was made by a least-squares search for the unique Euler rotation angles which convert the geometric factors in the molecular (crystal) coordinates to ones that correctly predict each of 41 known dipolar shifts by using the magnetic anisotropies computed previously [Horrocks, W. D., Jr., & Greenberg, E. S. (973) Biochim. Biophys. Acta 322, 38-44]. An excellent fit to experimental shifts was obtained, which also provided predictions that allowed subsequent new assignments to be made. The magnetic axes are oriented so that the z axis is tipped approximately 15 degrees from the heme normal toward the hem delta-meso-H and coincides approximately with the characterized FeCO tilt axis in the isostructural MbCO complex [Kuriyan, J., Wilz, S., Karplus, M., & Petsko, G. A. (1986) J. Mol. Biol. 192, 133-154]. Since the FeCO and FeCN units are isostructural, we propose that the dominant protein constraints that tips the magnetic z axis from the heme normal is the tilt of the FeCN by steric interactions with the distal residues. The rhombic magnetic axes were found to align closely with the projection of the proximal His imidazole plane on the heme, confirming that the His-Fe bonding provides the protein constraints that orients the in-plane anisotrophy. The tipped magnetic z axis is shown to account quantitatively for the previously noted major discrepancy between the hyperfine shift patterns for the bound imidazole side chain in models and protein. Moreover, it is shown that the proximal His ring nolabile proton hyperfine shifts provide direct and exquisitely sensitive indicators of the degree of the z axis tilt that may serve as a valuable probe for characterizing variable steric interactions in the distal pocket of both point mutants and natural genetic variants of myoglobin.

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Some Notes Added in Proof

Mar

1973

184

241

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¹H NMR Characterization of the Solution Active Site Structure of Substrate-Bound, Cyanide-Inhibited Heme Oxygenase from Neisseria meningitidis: Comparison to Crystal Structures

et al. 2004

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Heme oxygenase, HO, from the pathogenic bacterium Neisseria meningitidis catabolizes heme for the iron necessary for infection. The enzyme, labeled HemO, exhibits less sequence homology to mammalian HO than another studied HO from Corynebacterium diphtheriae. Solution 1H NMR has been utilized to define the active site molecular and electronic structure of the cyanide-inhibited, substrate-bound complex for comparison with those provided by several crystal structures. Extensive assignments by solely 1H NMR 2D methods reveal a structure that is very strongly conserved with respect to the crystal structure, although 1H/2H exchange indicates dynamically much more stable distal and proximal helices than those for other HOs. Several residues found with alternate orientations in crystal structures of water- and NO-ligated complexes were shown to occupy positions found solely in the NO complex, confirming that there are structural accommodations in response to ligating the substrate complex with a diatomic, H-bond acceptor ligand. The observed dipolar shifts allow the determination of the magnetic axes that show that the Fe-CN unit is tilted approximately 10 degrees toward the alpha-meso position, thereby facilitating the alpha-stereoselectivity of the enzyme. Numerous labile protons with larger than usual low-field bias are identified and, in common with the other HO complexes, shown to participate in an extended, distal side H-bond network. This H-bond network orders several water molecules, most, but not all, of which have been detected crystallographically. A series of three C-terminal residues, His207-Arg208-His209, are not detected in crystal structures. However, 1H NMR finds two residues, His207 and likely Arg208 in contact with pyrrole D, which in crystal structures is exposed to solvent. The nature of the NOEs leads us to propose a H-bond between the proximally oriented His207 ring and the carboxylate of Asp27 and a salt-bridge between the terminus of Arg208 and the reoriented 7-propionyl carboxylate. While numerous ordered water molecules are found near both propionates in the crystal structure, we find much larger water NOEs to the 6- than 7-propionate, suggesting that water molecules near the 7-propionate have been expelled from the cavity by the insertion of Arg208 into the distal pocket. The conversion of the 7-propionate link from the N-terminal region (Lys16) to the C-terminal region (Arg208) in the ligated substrate complex both closes the heme cavity more tightly and may facilitate product exit, the rate-limiting step in the enzyme activity.

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Gerd N. La Mar

Solution NMR Characterization of an Unusual Distal H-bond Network in the Active Site of the Cyanide-inhibited, Human Heme Oxygenase Complex of the Symmetric Substrate, 2,4-Dimethyldeuterohemin

Structural correlations and vinyl influences in resonance Raman spectra of protoheme complexes and proteins

NMR determination of the orientation of the magnetic susceptibility tensor in cyanometmyoglobin: a new probe of steric tilt of bound ligand

Some Notes Added in Proof

¹H NMR Characterization of the Solution Active Site Structure of Substrate-Bound, Cyanide-Inhibited Heme Oxygenase from Neisseria meningitidis: Comparison to Crystal Structures

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Gerd N. La Mar

Solution NMR Characterization of an Unusual Distal H-bond Network in the Active Site of the Cyanide-inhibited, Human Heme Oxygenase Complex of the Symmetric Substrate, 2,4-Dimethyldeuterohemin

Structural correlations and vinyl influences in resonance Raman spectra of protoheme complexes and proteins

NMR determination of the orientation of the magnetic susceptibility tensor in cyanometmyoglobin: a new probe of steric tilt of bound ligand

Some Notes Added in Proof

1H NMR Characterization of the Solution Active Site Structure of Substrate-Bound, Cyanide-Inhibited Heme Oxygenase from Neisseria meningitidis: Comparison to Crystal Structures

Contact Info

Product

Resources

About

¹H NMR Characterization of the Solution Active Site Structure of Substrate-Bound, Cyanide-Inhibited Heme Oxygenase from Neisseria meningitidis: Comparison to Crystal Structures