The crystal structure of a complex of cycloheptaamylose with 2,5-diiobobenzoic acid

The molecular structure of the 1:1 complex of cycloheptaamylose with 2,5-diiodobenzoic acid has been determined by X-ray crystallography. The iodine atoms of the guest molecular are disordered and were not used in the structure determination. The cycloheptaamylose molecules form channels in the crystal by means of head to head and tail to tail association using the two-fold crystallographic axis.     

The crystal and molecular structure of O-α-D-mannopyranosyl-(1→3)-O-β-D-mannopyranosyl-(1→4)-2-acetamido-2-deoxy-α-D-glucopyranose

The crystal structure of α-D-Manp-(1→3)-β-D-Manp-(1→4)-α-D-GlcNAcp has been determined by the direct method using the multi-solution, tangent formula, and “magic integer” procedures. The space group is P2₂, and 2 molecules are in the unit cell with a  9.894 (5), b  10.372 (6), c  11.816 (6) Å, and β  95.03° (6). The structure was refined to R 0.059 for 2099 reflections measured with Mo Kα radiation. Difference synthesis showed all the hydrogen atoms, and indicated a partial (～30%) substitution of the α-anomer molecules by the β-anomer molecules. The D-mannopyranose and the D-glucopyranose have the normal ⁴C₁ conformation; an intramolecular hydrogen-bond O-3″-H.....O-5′ (2.703 Å) stabilises the GlcNAc in relation to β-D-mannopyranose.     

Molybdenum active centre of DMSO reductase from Rhodobacter capsulatus: crystal structure of the oxidised enzyme at 1.82-Å resolution and the dithionite-reduced enzyme at 2.8-Å resolution

The 1.82-Å X-ray crystal structure of the oxidised (Mo^(VI)) form of the enzyme dimethylsulfoxide reductase (DMSOR) isolated from Rhodobacter capsulatus is presented. The structure has been determined by building a partial model into a multiple isomorphous replacement map and fitting the crystal structure of DMSOR from Rhodobacter sphaeroides to the partial model. The enzyme structure has been refined, at 1.82-Å resolution, to an R factor of 14.8% (R _free?=?18.4%). The molybdenum is coordinated by seven ligands: four dithiolene sulfurs, Oγ of Ser147 and two oxo groups. The four sulfur ligands, at a metal-sulfur distance of 2.4?Å or 2.5?Å, are contributed by the two molybdopterin guanine dinucleotide (MGD) cofactors. The coordination sphere of the molybdenum is different from that in previously reported structures of DMSOR from R. sphaeroides and R. capsulatus. The 2.8-Å structure of DMSOR, reduced by addition of sodium dithionite, is also described and differs from the structure of the oxidised enzyme by the removal of a single oxo ligand from the molybdenum coordination sphere. A structure, at 2.5-Å resolution, has also been obtained from crystals soaked in mother liquor buffered at pH?7.0. No differences are observed in the structure at pH?7 when compared with the native crystal structure at pH?5.5.     

The double-helical molecular structure of crystalline b-amylose

The crystal structure of the B-polymorph of amylose appears to be based on double-stranded helices. The individual strands are in a right-handed six-fold helical conformation repeating in 20.8 Å and are wound parallel around each other. The steric disposition of O-6 is gt. The double helices pack in a hexagonal unit-cell (a  b  18.50 Å, c (fiber repeat)  10.40 Å, γ  120°), with two helices (12 d-glucose residues) per cell. The helices are packed antiparallel and leave an open channel within a hexagonal array that is filled with water molecules. The reliability of the structure analysis is indicated by R  0.22. The structure of B-amylose is consistent with the diffraction diagrams of B-starches and accounts for the physical properties of such starches.     

The crystal and molecular structure of tri-o-ethylamylose (tea 3)

The crystal and molecular structure of a tri-O-ethylamylose polymorph, TEA 3, has been solved by stereochemical conformation and packing analysis, combined with X-ray fibre diffraction analysis. The unit cell is orthorhombic, space group P2₁2₁2₁, with a  15.36 (±0.03) Å, b  12.18 (±0.05) Å, and c (fibre repeat)  15.48 (±0.01) Å. The actual chain conformation is a 4₃ helix with the EtO-6 group in the tg position, as was found in the polymorph TEA 1.     

Induced circular dichroism of cycloamylose complexes with meta- and para-disubstituted benzenes

Cycloamylose complexes with substituted benzenes in aqueous solutions were investigated by circular dichroism (CD) spectroscopy. The differences in CD spectra between cyclohexaamylose complexes and cycloheptaamylose complexes suggests that the orientation and disposition of the guest molecule differ in these two cycloamylose complexes. It was shown theoretically that the sign and intensity of CD are quite sensitive to the orientation of the guest chromophor in the cycloamylose cavity, but that the difference between the cyclohexaamylose complex and the cycloheptaamylose complex is only 13% if the guest molecule is included in the same geometry. Molecular ellipticity and thermodynamic parameters, which were determined by the least-squares curve-fitting procedure, indicate that the guest molecule is more closely packed in the cyclohexaamylose cavity, and that there is no stereospecificity in the complex formation between the meta-disubstituted benzenes and the para-disubstituted benzenes.     

The crystal and molecular structure of methyl 2,4,6-tri-O-acetyl-3-O(2,3,4,6-Tetra-O-acetyl-β-d-glucopyranosyl)-β-d-glucopyranoside (methyl 2,3,4,6,2′,4′,6′,-hepta-O-acetyl-β-d-laminarabioside)

The crystal and molecular structure of methyl 2,3,4,6,2′,4′,6′-hepta-O-acetyl β-laminarabioside has been determined by X-ray diffraction. The crystal belongs to the orthorhombic system space group P2₁2₁2₁,a 10.471 (1), b 22.482(1), c 13.647(1) Å, D_m 1.33 g.cm^?3, Z 4. The structure was established by the direct method and refined by the block-diagonal, least-squares procedure to R 0.093 for 2043 observed reflections. Difference synthesis showed all the hydrogen atoms except the methyl hydrogen ones. The molecule shows a fully-extended conformation and has no intra-molecular hydrogen bond. The ring-to-ring conformation can be described.as (φψ)  (42.5, 4.7°), according to the definition of Sathyanarayana and Rao, and it is compared with (φψ)  (27.9, ?37.5°) of laminarabiose. There is no inter-molecular hydrogen bond. The d-glucopyranose rings of the molecule are piled up along the a axis and approximately parallel to the bc-plane. Each of the acetyl groups is approximately perpendicular to the d-glucopyranose ring.     

Topography of cyclodextrin inclusion complexes : Part II. The iodine-cyclohexa-amylose tetrahydrate complex; its molecular geometry and cage-type crystal structure

Iodine-cyclohexa-amylose tetrahydrate [(C₆H₁₀O₅)₆ ·I₂·d4H₂O] crystallizes in the orthorhombic space-group P2₁2₁2₁, a  14.240 Å, b  36.014 Å, c  9.558 Å. The structure was solved by heavy-atom techniques and refined by least-squares methods to a conventional discrepancy index R  0.148 for the 2872 observed data. The six d-glucose residues are in the C1 chair conformation; the conformational angles vary in magnitude from 45 to 66°, the angles O(5)-C(5)-C(6)-O(6) are close to · 70°, and the six O(4) atoms are almost coplanar (r.m. s. displacement 0.13 Å). Only four of the six O(2) ?O(3) intramolecular hydrogen bonds have formed, which renders the molecule less symmetrical and more conical-shaped than in the previously determined α-cyclodextrin-potassium acetate complex. The iodine molecule is coaxial with the cyclohexa-amylose molecule. The I-I distance is a conventional 2.677 Å. Close interactions between the iodine atoms and the host molecule comprise carbon atoms C(5) and C(6) and oxygen atoms O(4), with interatomic distances all equal to or greater than van der Waals contacts. Intermolecular, almost-linear, short contacts O ? I-I?O with I?O distances of 3.22 and 3.07 Å indicate attractive interaction.The molecules are arranged in herring-bone “cage-type” fashion, with the four water molecules as space-filling mediators; the structure is held together by an intricate network of hydrogen bonds.     

Calcium interactions with D-glucans: crystal structure of alpha, alpha-trehalose-calcium bromide monohydrate

Three-dimensional X-ray diffraction data were used to determine the crystal structure of α,α-trehalose-calcium bromide monohydrate, a model system for investigation of factors involved in the binding of calcium ions to d-glucans of dental plaques. Crystals of C₁₂H₂₂O₁₁ ·CaBr₂·H₂O are orthorhombic, space group C222₁, with a  11.058(1) b  11.537(1), c  15.101(1) Å, and Z  4. Intensity data for 925 independent reflections were measured with an automated diffractometer. A trial structure, obtained by the heavy-atom method, was refined by least-squares to R  0.03. An outstanding feature of the crystal packing is the interaction of trehalose molecules with calcium ions. Each calcium is coordinated to hydroxyl groups from four symmetry-related d-glucose moieties, thereby cross-linking the trehalose molecules. Similar interactions between calcium ions and the d-glucose residues of extracellular d-glucans may be of importance in the agglutination processes involved in dental-plaque formation.     

The crystal structure of an extracellular catechol oxidase from the ascomycete fungus Aspergillus oryzae

Catechol oxidases (EC 1.10.3.1) catalyse the oxidation of o-diphenols to their corresponding o-quinones. These oxidases contain two copper ions (CuA and CuB) within the so-called coupled type 3 copper site as found in tyrosinases (EC 1.14.18.1) and haemocyanins. The crystal structures of a limited number of bacterial and fungal tyrosinases and plant catechol oxidases have been solved. In this study, we present the first crystal structure of a fungal catechol oxidase from Aspergillus oryzae (AoCO4) at 2.5-Å resolution. AoCO4 belongs to the newly discovered family of short-tyrosinases, which are distinct from other tyrosinases and catechol oxidases because of their lack of the conserved C-terminal domain and differences in the histidine pattern for CuA. The sequence identity of AoCO4 with other structurally known enzymes is low (less than 30 %), and the crystal structure of AoCO4 diverges from that of enzymes belonging to the conventional tyrosinase family in several ways, particularly around the central α-helical core region. A diatomic oxygen moiety was identified as a bridging molecule between the two copper ions CuA and CuB separated by a distance of 4.2–4.3 Å. The UV/vis absorption spectrum of AoCO4 exhibits a distinct maximum of absorbance at 350 nm, which has been reported to be typical of the oxy form of type 3 copper enzymes.     

Structure of 2-keto-3-deoxy-6-phosphogluconate aldolase at 2.8 Å resolution

The structure of 2-keto-3-deoxy-6-phosphogluconate aldolase has been extended to 2.8 Å resolution from 3.5 Å resolution by multiple isomorphous replacement methods using three heavy-atom derivatives and anomalous Bijvoet differences to 6 Å resolution (〈m〉 = 0.72). The replacement phases were improved and refined by electron density modification procedures coupled with inverse transform phase angle calculations. A Kendrew model of the molecule was built, which contained all 225 residues of a recently determined amino acid sequence, whereas only 173 were accounted for at 3.5 Å resolution. The missing residues were found to be part of the interior of the molecule and not simply an appendage. The molecule folds to form an eight-strand α/β-barrel structure strikingly similar to triosephosphate isomerase, the A-domain of pyruvate kinase and Taka amylase. With a knowledge of the sequence, the nature of the interfaces of the two kinds of crystallographic trimers have been examined, from which it was concluded that the choice of trimers selected in the 3.5 Å resolution work was probably correct for trimers in solution. The active site region has been established from the position of the Schiff base forming Lys144 but it has not been possible to confirm it conclusively in independent derivative experiments. An apparent anomaly exists in the location of Glu56 (about 25 Å from Lys144). The latter has been reported to assist in catalysis.     

Crystal structure of p-hydroxybenzoate hydroxylase.

The structure of the enzyme p-hydroxybenzoate hydroxylase (EC 1.14.13.2) in a complex with its substrate has been determined at a resolution of 2.5 Å. The molecular weight is 43,000 and the dimensions of one molecule are approximately 70 Å × 50 Å × 45 Å. The crystal structure contains dimers of these molecules. Approximately 16% of the residues occur in β-sheets and 26% in α-heliees. The molecule can be divided into three domains. The active site, near the isoalloxazine ring, is formed by side-chains of the three domains. The N-5 edge of the isoalloxazine ring points to p-hydroxybenzoate, which is bound in a deep cleft.     

Crystallization and initial X-ray diffraction analysis of the multi-domain Brucella blue light-activated histidine kinase LOV-HK in its illuminated state

The pathogenic bacterium Brucella abortus codes for a multi-domain dimeric cytoplasmic histidine kinase called LOV-HK, which is a key blue light-activated virulence factor in this microorganism. The structural basis of the light activation mechanism of this protein remains unclear. In this work, full-length LOV-HK was cloned, expressed and purified. The protein was activated by light and crystallized under a controlled illumination environment. The merge of 14 individual native data sets collected on a single crystal resulted in a complete X-ray diffraction data set to a resolution of 3.70 Å with over 2 million reflections. Crystals belong to space group P2₁2₁2₁, with unit-cell parameters a = 95.96, b = 105.30, c = 164.49 Å with a dimer in the asymmetric unit. Molecular replacement with Phaser using the individual domains as search models allowed for the reconstruction of almost the whole protein. Very recently, improved LOV-HK crystals led to a 3.25-Å resolution dataset. Refinement and model building is underway. This crystal model will represent one of the very few examples of a multi-domain histidine kinase with known structure.     

Crystal structure of the koh-amylose complex

The crystal structure of potassium hydroxide complexed amylose, obtained by heterogeneous deacetylation of amylose triacetate, has been determined through a combined stereochemical structure-refinement and X-ray diffraction-analysis. The structure crystallizes in an orthorhombic unit-cell with parameters a  8.84, b  12.31, and c (fiber repeat)  22.41 Å, and with P2₁2₁2₁ symmetry. The conformation of the amylose chain is a distorted, left-handed helix with 6 d-glucose residues per turn. Each three-residue asymmetric unit is complexed with one molecule of potassium hydroxide and three molecules of water. The K⁺ ion coordinates with four oxygen atoms of the amylose chain and with two other oxygen atoms, and this coordination is probably the cause for the more-extended amylose chain-conformation than would be predicted from a φ, ψ map. The distortions in the chain are primarily manifested by different O-6 rotations and by slightly different bridge and φ, ψ angles for the individual residues. The structure is extensively hydrogen bonded, although largely through water molecules, which accounts for its ready water solubility. The left-handed conformation of the chain in this structure is consistent with the conformations of amylose triacetate and V-amylose, both of which are left-handed.     

Low resolution structure of adenylate kinase

A low resolution model of adenylate kinase has been derived from a 6 Å electron density map. The molecular shape can be described approximately as an oblate ellipsoid with dimensions 40 Å × 40 Å × 30 Å. The molecule is composed of two globular units separated by a 10 Å deep cleft. In contrast to the bigger unit, the smaller globule appears to contain a high amount of α-helical structure. The location of the active centre is discussed.The crystals used for X-ray diffraction analysis belong to one of the enantiomorphic trigonal space groups P3₁21 or P3₂21, with one molecule in the asymmetric unit. The phase determination was based on four isomorphous heavy atom derivatives. Frequent transitions between different crystal forms complicate the analysis.     

Crystal structure of cytochrome c' from Rhodocyclus gelatinosus and comparison with other cytochromes c'

Cytochromes c' are heme proteins found in photosynthetic and denitrifying bacteria, where they are presumably involved in electron transport. The cytochrome c' isolated from the bacterium Rhodocyclus gelatinosus (RGCP) forms a homodimer with each polypeptide containing 129 residues. It has been crystallised in ammonium sulfate at pH?6. Crystals belong to space group P3₁21 with cell parameters a?=?70.2?Å and c?=?126.8?Å, which corresponds to a dimer in the asymmetric unit (VM?=?3.5?ų?/?Da). The crystal structure of RGCP was solved by the molecular replacement method and refined using data to 2.5-Å resolution. The final crystallographic R factor was 17.9% for all reflections (above 2?σ) in the resolution range 27.4 to 2.5?Å. The refined model includes 1876 non-hydrogen protein atoms and 56 water molecules. As typical of c–type cytochromes, the heme group is covalently bound to Cys-X-Y-Cys-His through thio-ether bonds, and His123 occupies the fifth axial coordination position. On the vacant "distal" site, Phe16 blocks the direct access to the sixth coordination site, which is in a predominantly hydrophobic environment. In spite of the low sequence homology among cytochromes c' the overall fold is similar. The monomer structure consists of 4 anti-parallel α-helices and has random coils in the loops between the helices, and at the N- and C-termini. The subunits cross each other to form an X shape.     

Isolation and Characterization of 4-tert-Butylphenol-Utilizing Sphingobium fuliginis Strains from Phragmites australis Rhizosphere Sediment

We isolated three Sphingobium fuliginis strains from Phragmites australis rhizosphere sediment that were capable of utilizing 4-tert-butylphenol as a sole carbon and energy source. These strains are the first 4-tert-butylphenol-utilizing bacteria. The strain designated TIK-1 completely degraded 1.0 mM 4-tert-butylphenol in basal salts medium within 12 h, with concomitant cell growth. We identified 4-tert-butylcatechol and 3,3-dimethyl-2-butanone as internal metabolites by gas chromatography-mass spectrometry. When 3-fluorocatechol was used as an inactivator of meta-cleavage enzymes, strain TIK-1 could not degrade 4-tert-butylcatechol and 3,3-dimethyl-2-butanone was not detected. We concluded that metabolism of 4-tert-butylphenol by strain TIK-1 is initiated by hydroxylation to 4-tert-butylcatechol, followed by a meta-cleavage pathway. Growth experiments with 20 other alkylphenols showed that 4-isopropylphenol, 4-sec-butylphenol, and 4-tert-pentylphenol, which have alkyl side chains of three to five carbon atoms with α-quaternary or α-tertiary carbons, supported cell growth but that 4-n-alkylphenols, 4-tert-octylphenol, technical nonylphenol, 2-alkylphenols, and 3-alkylphenols did not. The rate of growth on 4-tert-butylphenol was much higher than that of growth on the other alkylphenols. Degradation experiments with various alkylphenols showed that strain TIK-1 cells grown on 4-tert-butylphenol could degrade 4-alkylphenols with variously sized and branched side chains (ethyl, n-propyl, isopropyl, n-butyl, sec-butyl, tert-butyl, n-pentyl, tert-pentyl, n-hexyl, n-heptyl, n-octyl, tert-octyl, n-nonyl, and branched nonyl) via a meta-cleavage pathway but not 2- or 3-alkylphenols. Along with the degradation of these alkylphenols, we detected methyl alkyl ketones that retained the structure of the original alkyl side chains. Strain TIK-1 may be useful in the bioremediation of environments polluted by 4-tert-butylphenol and various other 4-alkylphenols.4-tert-Butylphenol is an alkylphenol with a tertiary branched side chain of four carbon atoms at the para position of phenol. It is an industrially important chemical and is abundantly and widely used for the production of phenolic, polycarbonate, and epoxy resins. Production of 4-tert-butylphenol in the European Union in 2001 was 25,251 tons (t) (9). In Japan, according to the National Institute of Technology and Evaluation (http://www.safe.nite.go.jp/english/sougou/view/ComprehensiveInfoDisplay_en.faces), production of 4-tert-butylphenol amounted to 27,761 t in 2007. 4-tert-Butylphenol is widely distributed in aquatic environments, including river waters (20), seawaters (17), river sediments (17), marine sediments (23), and effluent samples from sewage treatment plants and wastewater treatment plants (22). Furthermore, 4-tert-butylphenol interacts with estrogen receptors (29, 30, 34, 35, 39) and exhibits other toxic effects on aquatic organisms and humans (4, 15, 16, 25, 26, 42, 43). Therefore, it is necessary to study the biodegradation of 4-tert-butylphenol to understand its fate in the aquatic environment, to establish technologies to treat the waters polluted by it, and to remove it from contaminated environments.Studies of the biodegradation of alkylphenols have focused mainly on branched 4-nonylphenol. Several strains of sphingomonad bacteria, including Sphingomonas sp. strain TTNP3 (38), Sphingobium xenophagum Bayram (11), and Sphingomonas cloacae S-3^T (10), have recently been isolated from activated sludge. These strains can degrade branched 4-nonylphenol and utilize it as a sole carbon source. In addition, several Pseudomonas strains that can degrade medium-chain 4-n-alkylphenols (e.g., 4-n-butylphenol) and utilize them as sole carbon sources have been isolated from activated sludge or contaminated soil; they include Pseudomonas veronii INA06 (1), Pseudomonas sp. strain KL28 (21), and Pseudomonas putida MT4 (36). Biodegradation of branched 4-nonylphenol and 4-n-butylphenol has been well studied, but little is known about the biodegradation of 4-tert-butylphenol, although this compound has a structure similar to those of branched 4-nonylphenol and 4-n-butylphenol. There is only one report on the biotransformation of 4-tert-butylphenol—by resting cells of S. xenophagum strain Bayram grown on technical nonylphenol—but this strain cannot grow on 4-tert-butylphenol (11, 14). To our knowledge, there are no reports of bacteria that utilize 4-tert-butylphenol as the sole carbon source, and the biochemical pathway of 4-tert-butylphenol utilization has not been described.Here we characterize three Sphingobium fuliginis strains—TIK-1, TIK-2, and TIK-3—isolated from rhizosphere sediment of the reed Phragmites australis. These strains could use 4-tert-butylphenol as a sole carbon source. On the basis of additional tests of strain TIK-1, we propose that it degrades 4-tert-butylphenol through 4-tert-butylcatechol along a meta-cleavage pathway. We also show that strain TIK-1 cells grown on 4-tert-butylphenol can degrade a wide range of 4-alkylphenols via a meta-cleavage pathway.     

Three-dimensional structure of actinoxanthin. IV. A 2.5-Å resolution

The protein actinoxanthin (isolated from Actinomyces globisporus—molecular weight, 10,300; 107 amino acid residues) crystallizes in space group P2₁2₁2₁ with cell dimensions: a = 30.9 Å, b = 48.8 Å, c = 64.1 Å, and Z = 4. The three-dimensional structure of actinoxanthin was determined by the x-ray multiple isomorphous replacement method at 2.5-Å resolution. The molecule is kidney-shaped and has a well-defined cavity. Its characteristic features are the absence of α-helices and the presence of enhanced content of antiparallel β-structure (～55%). A cylinder-shaped formation of seven antiparallel β-strands comprises the main part of the protein structure. The established β-supersecondary structure is characterized by a three-dimensional topology similar to that of immunoglobulin domains, superoxide dismutase subunits, and azurin and plastocyanin proteins.     

Structure of guanylyl-3',5'-cytidine monophosphate. II. Description of the molecular and crystal structure of the calcium derivative in space group P2(1).

The structural features of calcium guanosine-3′,5′-cytidine monophosphate (GpC) have been elucidated by X-ray diffraction analysis. The molecule was crystallized in space group P2₁ with cell constants of a = 21.224 Å, b = 34.207 Å, c = 9.327 Å, and β = 90.527°, Z = 8. The hydration of the crystal is 21% by weight with 72 water molecules in the unit cell. The four GpC molecules in the asymmetric unit occur as two Watson-Crick hydrogen-bonded dimers related by a pseudo-C face centering. Each dimer consists of two independent GpC molecules whose bases are hydrogen bonded to each other in the traditional Watson-Crick fashion. Each dimer possesses a pseudo twofold axis broken by a calcium ion and associated solvent. The four molecules are conformationally similar to helical RNA, but are not identical to it or to each other. Instead, values of conformational angles reflect the intrinsic flexibility of the molecule within the range of basic helical conformations. All eight bases are anti, sugars are all C3′-endo, and the C4′-C5′ bond rotations are gauche-gauche. The R factor is 12.6% for 2918 observed reflections at 1.2-Å resolution.     

The crystal struture of monoclinic ribonuclease-S at six angstroms resolution.

An independent structure analysis has been made of ribonuclease-S crystallized in a monoclinic space group C2 at 6 Å resolution. The conformations of the two crystallographically independent molecules (molecule ZA and ZB) were compared with that of a chemically identical molecule (molecule Y) crystallized in a trigonal space group P3₁21, the structure of which has been solved to 2.0 Å resolution by Wyckoff et al. (1970). The N-terminal tail of the S-protein of molecule ZA assumes a unique conformation somewhat resembling that of ribonuclease-A, while the corresponding part of molecule ZB assumes about a similar conformation to that of molecule Y. Apart from the solvated terminal region, the overall arrangements of various features of the three structures are very similar, although possibilities of local conformational differences are not considered at this stage of the analysis. The environments of the three molecules in the crystal lattice are compared in detail. Two of the four molecules in the primitive cell are related to each other by a crystallographic 2-fold axis very similar to a 2-fold relationship found in the Y-form. All other relationships are quite different.