The X-ray crystal structure of the Escherichia coli (Ec) direct oxygen sensor heme domain (Ec DosH) has been solved to 1.8 A using Fe multiple-wavelength anomalous dispersion (MAD), and the positions of Met95 have been confirmed by selenomethionine ((Se)Met) MAD. Ec DosH is the sensing part of a larger two-domain sensing/signaling protein, in which the signaling domain has phosphodiesterase activity. The asymmetric unit of the crystal lattice contains a dimer comprised of two differently ligated heme domain monomers. Except for the heme ligands, the monomer heme domains are identical. In one monomer, the heme is ligated by molecular oxygen (O(2)), while in the other monomer, an endogenous Met95 with S --> Fe ligation replaces the exogenous O(2) ligand. In both heme domains, the proximal ligand is His77. Analysis of these structures reveals sizable ligand-dependent conformational changes in the protein chain localized in the FG turn, the G(beta)-strand, and the HI turn. These changes provide insight to the mechanism of signal propagation within the heme domain following initiation due to O(2) dissociation.
Solution 1H NMR spectroscopy and mass spectrometry are utilized to characterize the irreversible "aging" of native heme oxygenase from N. meningitidis, NmHO. 2D NMR characterization of the cyanide-inhibited substrate complex shows that the C-terminal interaction between Arg208His209 and the exposed pyrrole of the protohemin substrate in the "native" NmHO complex is lost in the "aging". Mass spectrometry and N-terminal sequencing of wild type and "aged" NmHO reveal that the "aging" process involves cleavage of the Arg208His209 dipeptide. The construction of the double deletion mutant without Arg208His209 and its NMR comparison as both the resting state substrate complex and its cyanide-inhibited complex with the "aged" NmHO reveal that cleavage of the C-terminal dipeptide is the only modification during the aging. Comparison of cyanide ligand binding constants reveal a factor approximately 1.7 greater CN- affinity in the native than "aged" NmHO. The rate of protohemin degradation and its stereoselectivity are unaffected by the C-terminal truncation. However, the free alpha-biliverdin yield in the presence of desferrioxamine is significantly increased in the "aged" NmHO and its deletion mutant relative to WT, arguing for a role of the NmHO C-terminus in modulating product release. The facile cleavage of Arg208His209 in the resting state complex, with a half-life of approximately 24 h at 25 degrees C, suggests that previous characterization of NmHO may have been carried out on a mixture of native and "aged" NmHO, and may account for the "lost" C-terminal residues in the crystal structures.
Proton NMR assignments of the heme pocket and catalytically relevant amino acid protons have been accomplished for cyanide-ligated yeast cytochrome c peroxidase. This form of the protein, while not enzymatically active itself, is the best model available (that displays a resolvable proton NMR spectrum) for the six-coordinate low-spin active intermediates, compounds I and II. The assignments were made with a combination of one- and two-dimensional nuclear Overhauser effect methods and demonstrate the utility of NOESY experiments for paramagnetic proteins of relatively large size (Mr 34,000). Assignments of both isotope exchangeable and nonexchangeable proton resonances were obtained by using enzyme preparations in both 90% H2O/10% D2O and, separately, in 99.9% D2O solvent systems. Complete resonance assignments have been achieved for the proximal histidine, His-175, and His-52, which is a member of the catalytic triad on the distal side of the heme. In addition, partial assignments are reported for Trp-51 and Arg-48, catalytically important residues, both on the distal side. Aside from His-175, partial assignments for amino acids on the proximal side of the heme are proposed for the alanines at primary sequence positions 174 and 176 and for Thr-180 and Leu-232.
Cryoreduction of the [FeO2]6 (n = 6 is the number of electrons in 3d orbitals on Fe and pi* orbitals on O2) dioxygen-bound ferroheme through irradiation at 77 K generates an [FeO2]7 reduced oxy-heme. Numerous investigations have examined [FeO2]7 centers that have been characterized as peroxo-ferric centers, denoted [FeO2]per7, in which a ferriheme binds a dianionic peroxo-ligand. The generation of such an intermediate can be understood heuristically if the [FeO2]6 parent is viewed as a superoxo-ferric center and the injected electron localizes on the O-O moiety. We here report EPR/ENDOR experiments which show quite different properties for the [FeO2]7 centers produced by cryoreduction of monomeric oxy-hemoglobin (oxy-GMH3) from Glycera dibranchiata, which is unlike mammalian "globins" in having a leucine in place of the distal histidine; of frozen aprotic solutions of oxy-ferrous octaethyl porphyrin; and of the oxy-ferrous complex of the heme model, cyclidene. These [FeO2]7 centers are characterized as "superoxo-ferrous" centers ([FeO2]sup7), with nearly unit spin density localized on a superoxo moiety which is end-on coordinated to a low-spin ferrous ion. This assignment is based on their g tensors and 17O hyperfine couplings, which are characteristic of the superoxide ion coordinated to a diamagnetic metal ion, and on the absence of detectable ENDOR signals either from the in-plane 14N ligands or from an exchangeable H-bond proton. Such a center would arise if the electron that adds to the [FeO2]6 superoxo-ferric parent localizes on the Fe ion, to make a superoxo-ferrous moiety. Upon annealing to T > 150 K, the [FeO2]sup7 species converts to peroxo/hydroperoxo-ferric ([FeO2H]7) intermediates. These experiments suggest that the primary reduction product is [FeO2]sup7 and that the internal redox transition to [FeO2]per7/[FeO2H]7 states is driven at least in part by H-bonding/proton donation by the environment.
Proton NMR spectroscopy at 500 and 361 MHz has been used to characterize the noncovalent or electrostatic complexes of yeast cytochrome c peroxidase (CcP) with horse, tuna, yeast isozyme-1, and yeast isozyme-2 ferricytochromes c and the covalently cross-linked complexes of cytochrome c peroxidase with horse and yeast isozyme-1 ferricytochromes c. Under the conditions employed in this work, the stoichiometry of the predominant complex formed in solution (which totaled greater than 90% of complex formed) was found to be 1:1 in all cases. These studies have elucidated significant differences in the proton NMR absorption spectra and the one-dimensional nuclear Overhauser effect difference spectra of the complexes, depending on the specific species of ferricytochrome c incorporated. In particular, the results indicate that the noncovalent complexes formed between CcP and physiological redox partners (yeast isozyme-1 or yeast isozyme-2 ferricytochromes c) are distinctly different from the noncovalent complexes formed between CcP and ferricytochromes c from horse and tuna. Parallel chemical cross-linking studies carried out using mixtures of cytochrome c peroxidase with horse ferricytochrome c, and cytochrome c peroxidase with yeast isozyme-1 ferricytochrome c further emphasize such cytochrome c-dependent differences, with only the covalently cross-linked complex of physiological redox partners (cytochrome c peroxidase/yeast isozyme-1) displaying NMR spectra characteristic of a heterogeneous mixture of different 1:1 complexes. Finally, one-dimensional nuclear Overhauser effect experiments have proven valuable in selectively and efficiently probing the protein-protein interface in these complexes, including the environment around the cytochrome c heme 3-methyl group and Phe-82.
Solution 1H NMR has been used to characterize the active site molecular and electronic structure of the cyanide-inhibited 2,4-dimethyldeuterohemin complex of the heme oxygenase from Neisseria meningitidis (NmHO) with respect to the mode of interaction of the C-terminus with the substrate and the spontaneous "aging" of NmHO that results in the cleavage of the C-terminal Arg208-His209 dipeptide. The structure of the portion involving residues Ala12-Phe192 is found to be essentially identical to that of the protohemin complex in either solution or crystal. However, His207 from the C-terminus is found to interact strongly with the substrate 1CH3, as opposed to the 8CH3 in the protohemin complex. The different mode of interaction of His207 with the alternate substrates is attributed to the 2-vinyl group of protohemin sterically interfering with the optimal orientation of the proximal helix Asp27 carboxylate that serves as acceptor to the strong H-bond by the peptide of His207. The 2,4-dimethyldeuterohemin HO complex "ages" in manner similary to that of protohemin, (Liu, Y., Ma, L.-H., Satterlee, J.D., Zhang, X., Yoshida, T., and La Mar, G. N., (2006) Biochemistry 45, 3875-3886) with mass spectrometry and N-terminal sequencing indicating that the Arg208-His209 dipeptide is cleaved. The 2,4-dimethyldeuterohemin complex of WT HO populates an equilibrium isomer stabilized in low phosphate concentration for which the axial His imidazole ring is rotated by approximately 20 degrees from that in the WT. The His ring reorientation is attributed to Asp24 serving as the H-bond acceptor to the His207 peptide NH, rather than to the His23 ring NdeltaH as in the crystals. The functional implications of the altered C-terminal interaction with substrate modification are discussed.
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