Your search keyword '"Masaki Unno"' showing total 6 results

1. Neutron crystallography and quantum chemical analysis of bilin reductase PcyA mutants reveal substrate and catalytic residue protonation states

Author

Tatsuya Joutsuka, Ryota Nanasawa, Keisuke Igarashi, Kazuki Horie, Masakazu Sugishima, Yoshinori Hagiwara, Kei Wada, Keiichi Fukuyama, Naomine Yano, Seiji Mori, Andreas Ostermann, Katsuhiro Kusaka, and Masaki Unno

Subjects

Cell Biology, Molecular Biology, Biochemistry

Abstract

PcyA, a ferredoxin-dependent bilin pigment reductase, catalyzes the site-specific reduction of the two vinyl groups of biliverdin (BV), producing phycocyanobilin. Previous neutron crystallography detected both the neutral BV and its protonated form (BVH

Published

2023

2. Structures of the Substrate-free and Product-bound Forms of HmuO, a Heme Oxygenase from Corynebacterium diphtheriae

Author

Albert Ardèvol, Carme Rovira, Masaki Unno, and Masao Ikeda-Saito

Subjects

Biliverdin, biology, Heme binding, Chemistry, Stereochemistry, Active site, Cell Biology, Biochemistry, Enzyme structure, Heme oxygenase, chemistry.chemical_compound, polycyclic compounds, biology.protein, Molecular Biology, Heme, Carbon monoxide, Pyrrole

Abstract

Heme oxygenase catalyzes the degradation of heme to biliverdin, iron, and carbon monoxide. Here, we present crystal structures of the substrate-free, Fe3+-biliverdin-bound, and biliverdin-bound forms of HmuO, a heme oxygenase from Corynebacterium diphtheriae, refined to 1.80, 1.90, and 1.85 Å resolution, respectively. In the substrate-free structure, the proximal and distal helices, which tightly bracket the substrate heme in the substrate-bound heme complex, move apart, and the proximal helix is partially unwound. These features are supported by the molecular dynamic simulations. The structure implies that the heme binding fixes the enzyme active site structure, including the water hydrogen bond network critical for heme degradation. The biliverdin groups assume the helical conformation and are located in the heme pocket in the crystal structures of the Fe3+-biliverdin-bound and the biliverdin-bound HmuO, prepared by in situ heme oxygenase reaction from the heme complex crystals. The proximal His serves as the Fe3+-biliverdin axial ligand in the former complex and forms a hydrogen bond through a bridging water molecule with the biliverdin pyrrole nitrogen atoms in the latter complex. In both structures, salt bridges between one of the biliverdin propionate groups and the Arg and Lys residues further stabilize biliverdin at the HmuO heme pocket. Additionally, the crystal structure of a mixture of two intermediates between the Fe3+-biliverdin and biliverdin complexes has been determined at 1.70 Å resolution, implying a possible route for iron exit.

Published

2013

3. Roles of Distal Asp in Heme Oxygenase from Corynebacterium diphtheriae, HmuO

Author

Momoko Furukawa, Masao Ikeda-Saito, Toshitaka Matsui, Masaki Unno, and Takeshi Tomita

Subjects

chemistry.chemical_classification, Oxygenase, Chemistry, Stereochemistry, Mutant, Resonance Raman spectroscopy, Wild type, Cell Biology, Biochemistry, Heme oxygenase, chemistry.chemical_compound, Oxidoreductase, Enzyme kinetics, Molecular Biology, Heme

Abstract

Heme oxygenases found in mammals, plants, and bacteria catalyze degradation of heme using the same mechanism. Roles of distal Asp (Asp-136) residue in HmuO, a heme oxygenase of Corynebacterium diphtheriae, have been investigated by site-directed mutagenesis, enzyme kinetics, resonance Raman spectroscopy, and x-ray crystallography. Replacements of the Asp-136 by Ala and Phe resulted in reduced heme degradation activity due to the formation of ferryl heme, showing that the distal Asp is critical in HmuO heme oxygenase activity. D136N HmuO catalyzed heme degradation at a similar efficiency to wild type and D136E HmuO, implying that the carboxylate moiety is not required for the heme catabolism by HmuO. Resonance Raman results suggest that the inactive ferryl heme formation in the HmuO mutants is induced by disruption of the interaction between a reactive Fe-OOH species and an adjacent distal pocket water molecule. Crystal structural analysis of the HmuO mutants confirms partial disappearance of this nearby water in D136A HmuO. Our results provide the first experimental evidence for the catalytic importance of the nearby water molecule that can be universally critical in heme oxygenase catalysis and propose that the distal Asp helps in positioning the key water molecule at a position suitable for efficient activation of the Fe-OOH species.

Published

2005

4. Crystal Structure of the Dioxygen-bound Heme Oxygenase from Corynebacterium diphtheriae

Author

Manon Couture, Denis L. Rousseau, Tadashi Yoshida, Masaki Unno, Masao Ikeda-Saito, John S. Olson, Toshitaka Matsui, and Grace C. Chu

Subjects

Steric effects, Chemistry, Hydrogen bond, Stereochemistry, Resonance Raman spectroscopy, Cell Biology, Photochemistry, Biochemistry, Porphyrin, Heme oxygenase, chemistry.chemical_compound, Molecule, Molecular Biology, Heme, Bond cleavage

Abstract

HmuO, a heme oxygenase of Corynebacterium diphtheriae, catalyzes degradation of heme using the same mechanism as the mammalian enzyme. The oxy form of HmuO, the precursor of the catalytically active ferric hydroperoxo species, has been characterized by ligand binding kinetics, resonance Raman spectroscopy, and x-ray crystallography. The oxygen association and dissociation rate constants are 5 μm-1 s-1 and 0.22 s-1, respectively, yielding an O2 affinity of 21 μm-1, which is ∼20 times greater than that of mammalian myoglobins. However, the affinity of HmuO for CO is only 3–4-fold greater than that for mammalian myoglobins, implying the presence of strong hydrogen bonding interactions in the distal pocket of HmuO that preferentially favor O2 binding. Resonance Raman spectra show that the Fe–O2 vibrations are tightly coupled to porphyrin vibrations, indicating the highly bent Fe–O–O geometry that is characteristic of the oxy forms of heme oxygenases. In the crystal structure of the oxy form the Fe–O–O angle is 110°, the O–O bond is pointed toward the heme α-meso-carbon by direct steric interactions with Gly-135 and Gly-139, and hydrogen bonds occur between the bound O2 and the amide nitrogen of Gly-139 and a distal pocket water molecule, which is a part of an extended hydrogen bonding network that provides the solvent protons required for oxygen activation. In addition, the O–O bond is orthogonal to the plane of the proximal imidazole side chain, which facilitates hydroxylation of the porphyrin α-meso-carbon by preventing premature O–O bond cleavage.

Published

2004

5. Crystal Structure at 1.5-Å Resolution of Pyrus pyrifolia Pistil Ribonuclease Responsible for Gametophytic Self-incompatibility

Author

Mamoru Sato, Masaki Unno, Koh Ida, Hiroaki Sakai, Fumio Sakiyama, Shigemi Norioka, and Takanori Matsuura

Subjects

Models, Molecular, Nonsynonymous substitution, Protein Conformation, RNase P, Stereochemistry, Molecular Sequence Data, Glutamic Acid, Crystallography, X-Ray, Biochemistry, Protein Structure, Secondary, Ribonucleases, Protein structure, Catalytic Domain, Hydrolase, Histidine, Amino Acid Sequence, Ribonuclease, Binding site, Molecular Biology, Peptide sequence, Binding Sites, Sequence Homology, Amino Acid, biology, Lysine, Active site, Cell Biology, Plants, Protein Structure, Tertiary, biology.protein

Abstract

The crystal structure of the Pyrus pyrifolia pistil ribonuclease (S(3)-RNase) responsible for gametophytic self-incompatibility was determined at 1.5-A resolution. It consists of eight helices and seven beta-strands, and its folding topology is typical of RNase T(2) family enzymes. Based on a structural comparison of S(3)-RNase with RNase Rh, a fungal RNase T(2) family enzyme, the active site residues of S(3)-RNase assigned were His(33) and His(88) as catalysts and Glu(84) and Lys(87) as stabilizers of an intermediate in the transition state. Moreover, amino acid residues that constitute substrate binding sites of the two RNases could be superimposed geometrically. A hypervariable (HV) region that has an S-allele-specific sequence comprises a long loop and short alpha-helix. This region is far from the active site cleft, exposed on the molecule's surface, and positively charged. Four positively selected (PS) regions, in which the number of nonsynonymous substitutions exceeds that of synonymous ones, are located on either side of the active site cleft, and accessible to solvent. These structural features suggest that the HV or PS regions may interact with a pollen S-gene product(s) to recognize self and non-self pollen.

Published

2001

6. Structures of the Substrate-free and Product-bound Forms of HmuO, aHeme Oxygenase from Corynebacterium diphtheriae.

Author

Masaki Unno, Ardèvol, Albert, Rovira, Carme, and Masao Ikeda-Saito

Subjects

*HEME, *HEMOGLOBINS, *OXYGENASES, *OXIDOREDUCTASES, *CORYNEBACTERIUM diphtheriae

Abstract

Heme oxygenase catalyzes the degradation of heme to bili-verdin, iron, and carbon monoxide. Here, we present crystal structures of the substrate-free, Fe3+-biliverdin-bound, and biliverdin-bound forms of HmuO, a heme oxygenase from Corynebacterium diphtheriae, refined to 1.80,1.90, and 1.85 Å resolution, respectively. In the substrate-free structure, the proximal and distal helices, which tightly bracket the substrate heme in the substrate-bound heme complex, move apart, and the proximal helix is partially unwound. These features are supported by the molecular dynamic simulations. The structure implies that the heme binding fixes the enzyme active site structure, including the water hydrogen bond network critical for heme degradation. The biliverdin groups assume the helical conformation and are located in the heme pocket in the crystal structures of the Fe3+-biliverdin-bound and the biliverdin-bound HmuO, prepared by in situ heme oxygenase reaction from the heme complex crystals. The proximal His serves as the Fe3+-biliverdin axial ligand in the former complex and forms a hydrogen bond through a bridging water molecule with the biliverdin pyrrole nitrogen atoms in the latter complex. In both structures, salt bridges between one of the biliverdin propionate groups and the Arg and Lys residues further stabilize biliverdin at the HmuO heme pocket. Additionally, the crystal structure of a mixture of two intermediates between the Fe3+-biliverdin and biliverdin complexes has been determined at 1.70 A resolution, implying a possible route for iron exit. [ABSTRACT FROM AUTHOR]

Published

2013