Tomomi Kubota

Crystal structures of cyanide- and triiodide-bound forms of Arthromyces ramosus peroxidase at different pH values. Perturbations of active site residues and their implication in enzyme catalysis.

The structures of the cyanide and triiodide complexes of Arthromyces ramosus peroxidase (ARP) at different pH values were investigated by x-ray crystallography in order to examine the behavior of the invariant residues of arginine (Arg-52) and distal histidine (His-56) during the enzyme reaction as well as to provide the structural basis of the active site of peroxidase. The models of the cyanide complexes at pH 7.5, 5.0, and 4.0, respectively, were refined to the R-factors of 17.8, 17.8, and 18.5% using 7.0-1.6-Å resolution data, and those of the triiodide complexes at pH 6.5 and 5.0 refined to 16.9 and 16.8% using 7.0-1.9-Å resolution data. The structures of the cyanide complexes at pH 7.5, 5.0, and 4.0 are identical within experimental error. Cyanide ion bound to the heme in the bent conformation rather than in the tilt conformation. Upon cyanide ion binding, the N atom of His-56 moved toward the ion by rotation of the imidazole ring around the C-C bond, but there was little conformational change in the remaining residues. The distance between the N atom of His-56 and the nitrogen atom of the cyanide suggests the presence of a hydrogen bond between them in the pH range investigated. In the triiodide complexes, one of the two triiodides bound to ARP was located at the distal side of the heme. When triiodide bound to ARP, unlike the rearrangement of the distal arginine of cytochrome c peroxidase that occurs on formation of the fluoride complex or compound I, the side chain of Arg-52 moved little. The conformation of the side chain of His-56, however, changed markedly. Conformational flexibility of His-56 appears to be a requisite for proton translocation from one oxygen atom to the other of HOO by acid-base catalysis to produce compound I. The iron atom in each cyanide complex (low-spin ferric) is located in the heme plane, whereas in each triiodide complex (high-spin ferric) the iron atom is displaced from the plane about 0.2 Å toward the proximal side.

Three-dimensional structure of bovine cytochrome bC1 complex by electron cryomicroscopy and helical image reconstruction

Cytochrome bc 1 complex from bovine heart has been reconstituted into tubular crystals. The three-dimensional structure of the complex in lipid bilayer has been obtained at an effective resolution of 16 Å by electron cryomicroscopy and helical image reconstruction. The complex is in a dimeric form, in which the monomers are associated closely in extramembrane domains on both sides of the membrane. The large inner domain is distinctively hollow and the small outer domain consists of a flat mass and two bulbous extrusions. These domains are connected by two narrow transmembrane columns. Locations of the subunits and the redox centres in the model are proposed.

Orientation of protein crystals grown in a magnetic field

Abstract Three crystal forms of hen egg-white lysozyme, and ribonuclease A and met-myoglobin crystals exhibited orientation in a magnetic field of

Crystallization and preliminary X-ray crystallographic studies of bovine heart mitochondrial cytochrome bc1 complex

Cytochrome bc1 complex (ubiquinol:ferricytochrome c oxidoreductase, EC. 1.10.2.2) from bovine heart mitochondria was crystallized by a batchwise method from protein solution containing sucrose monolaurate using polyethylene glycol-4000 as a precipitant. The red parallelepiped crystals grew to a size of approximately 1 mm x 1 mm x 1 mm. The crystalline protein showed enzymic activity catalyzing electron transfer from ubiquinol-2 to cytochrome c. The subunit composition and absorption spectrum of the crystalline enzyme were identical to those reported previously for the enzyme in solution. The crystal diffracted X-rays to 7.5 A resolution. The diffraction pattern indicated a monoclinic form, space group P2(1), and unit-cell constants of a = 196 A, b = 179 A, c = 253 A and beta = 97 degrees. Most probably four functional units are present in an asymmetric unit.

Effect of glycosylation on cis/trans isomerization of prolines in IgA1-hinge peptide.

The hinge region of human immunoglobulin A1 (IgA1), connecting the Fab and Fc regions, is mostly composed of Ser, Thr, and Pro (VPSTPPTPSPSTPPTPSPS); hinge peptide (HP). O-Glycans are naturally attached on only particular five Ser/Thr residues in this region. NMR was employed for analysis of the structural changes in HP upon the glycosylation, especially focusing on the cis/trans isomerization of Pro residues. A series of HP containing (13)C,(15)N-labeled Pro residues were chemically synthesized and enzymatically glycosylated. The signals from cis and trans forms of the labeled Pro were identified by two-dimensional NMR spectroscopy. Cis/trans ratios of the Pro residues at the C-terminal side of the glycosylated Ser/Thr were reduced from 9-10% to 2-3% by the glycosylation. Thermodynamic analyses indicated that the decrease in the cis/trans ratio was enthalpy-driven. Hydrogen-deuterium exchange experiments and NOE-based structure determination revealed that the intraresidue hydrogen bonds between the amide group of GalNAc and carbonyl oxygen of the peptide backbone of GalNAc-Thr are formed in the major trans conformers, which is consistent with the thermodynamic parameters. These hydrogen bonds largely restrict the psi angle of the peptide backbone and, thereby, should make the trans conformation of the C-terminal Pro residue more stable than the cis conformation. Namely, it is predicted that the restricted psi angle causes interresidue steric hindrance for the cis conformation. The appropriate glycosylation of HP probably contributes to the decrease in the unfavorable variety of relative orientations between Fab and Fc in IgA1, through stabilizing the conformation of HP.

Strategies for crystallization of large membrane protein complexes

Abstract Crystalline cytochrome c oxidase and ubiquinol: cytochrome c oxidoreductase which diffracted X-rays at 7–8A˚resolution were obtained from bovine heart mitochondria. The methods for the purification and crystallization of these enzymes indicate that large membrane protein complexes are easier to purify and crystallize than smaller homologous membrane protein complexes, because the former have more hydrophilic surface than the latter. Bulky and polydispersed detergents such as Brij-35 and Tween 20 attached to the isolated complex are not always obstructive to crystallization if they are effective for stabilizing the complexes.