Atomic Resolution Structure (atomic + resolution_structure)

Distribution by Scientific Domains


Selected Abstracts


Atomic resolution structure of pseudoazurin from the methylotrophic denitrifying bacterium Hyphomicrobium denitrificans: structural insights into its spectroscopic properties

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 1 2009
Daisuke Hira
The crystal structure of native pseudoazurin (HdPAz) from the methylotrophic denitrifying bacterium Hyphomicrobium denitrificans has been determined at a resolution of 1.18,Å. After refinement with SHELX employing anisotropic displacement parameters and riding H atoms, Rwork and Rfree were 0.135 and 0.169, respectively. Visualization of the anisotropic displacement parameters as thermal ellipsoids provided insight into the atomic motion within the perturbed type 1 Cu site. The asymmetric unit includes three HdPAz molecules which are tightly packed by head-to-head cupredoxin dimer formation. The shape of the Cu-atom ellipsoid implies significant vibrational motion diagonal to the equatorial xy plane defined by the three ligands (two His and one Cys). The geometric parameters of the type 1 Cu site in the HdPAz structure differ unambiguously from those of other pseudoazurins. It is demonstrated that their structural aspects are consistent with the unique visible absorption spectrum. [source]


Atomic resolution structure of Escherichia coli dUTPase determined ab initio

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 6 2001
A. González
Cryocooled crystals of a mercury complex of Escherichia coli dUTPase diffract to atomic resolution. Data to 1.05,Å resolution were collected from a derivative crystal and the structure model was derived from a Fourier map with phases calculated from the coordinates of the Hg atom (one site per subunit of the trimeric enzyme) using the program ARP/wARP. After refinement with anisotropic temperature factors a highly accurate model of the bacterial dUTPase was obtained. Data to 1.45,Å from a native crystal were also collected and the 100,K structures were compared. Inspection of the refined models reveals that a large part of the dUTPase remains rather mobile upon freezing, with 14% of the main chain being totally disordered and with numerous side chains containing disordered atoms in multiple discrete conformations. A large number of those residues surround the active-site cavity. Two glycerol molecules (the cryosolvent) occupy the deoxyribose-binding site. Comparison between the native enzyme and the mercury complex shows that the active site is not adversely affected by the binding of mercury. An unexpected effect seems to be a stabilization of the crystal lattice by means of long-range interactions, making derivatization a potentially useful tool for further studies of inhibitor,substrate-analogue complexes of this protein at very high resolution. [source]


Atomic resolution structure of the double mutant (K53,56M) of bovine pancreatic phospholipase A2

ACTA CRYSTALLOGRAPHICA SECTION F (ELECTRONIC), Issue 1 2006
K. Sekar
The structure of the double mutant K53,56M has previously been refined at 1.9,Å resolution using room-temperature data. The present paper reports the crystal structure of the same mutant K53,56M refined against 1.1,Å data collected using synchrotron radiation. A total of 116 main-chain atoms from 29 residues and 44 side chains are modelled in alternate conformations. Most of the interfacial binding residues are found to be disordered and alternate conformations could be recognized. The second calcium ion-binding site residue Glu92 adopts two alternate conformations. The minor and major conformations of Glu92 correspond to the second calcium ion bound and unbound states. [source]


A hydrogen-bonding network is important for oxidation and isomerization in the reaction catalyzed by cholesterol oxidase

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 11 2009
Artem Y. Lyubimov
Cholesterol oxidase is a flavoenzyme that catalyzes the oxidation and isomerization of 3,-hydroxysteroids. Structural and mutagenesis studies have shown that Asn485 plays a key role in substrate oxidation. The side chain makes an NH..., interaction with the reduced form of the flavin cofactor. A N485D mutant was constructed to further test the role of the amide group in catalysis. The mutation resulted in a 1800-fold drop in the overall kcat. Atomic resolution structures were determined for both the N485L and N485D mutants. The structure of the N485D mutant enzyme (at 1.0,Å resolution) reveals significant perturbations in the active site. As predicted, Asp485 is oriented away from the flavin moiety, such that any stabilizing interaction with the reduced flavin is abolished. Met122 and Glu361 form unusual hydrogen bonds to the functional group of Asp485 and are displaced from the positions they occupy in the wild-type active site. The overall effect is to disrupt the stabilization of the reduced FAD cofactor during catalysis. Furthermore, a narrow transient channel that is shown to form when the wild-type Asn485 forms the NH..., interaction with FAD and that has been proposed to function as an access route of molecular oxygen, is not observed in either of the mutant structures, suggesting that the dynamics of the active site are altered. [source]


Hydrophobin HFBII in detail: ultrahigh-resolution structure at 0.75,Å

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 4 2006
Markus Linder
Hydrophobins are small proteins secreted by filamentous fungi that have a unique ability to spontaneously form amphiphilic layers. Hydrophobins have only recently been structurally characterized through the first crystal structure determination of a protein of this class, Trichoderma reesei hydrophobin HFBII [Hakanpää, Paananen et al. (2004), J.,Biol.,Chem.279, 534,539]. The resolution of the HFBII structure has now been extended to an ultrahigh resolution of 0.75,Å. The structure was refined conventionally and multipole refinement has been initiated. The ultrahigh-resolution structure is analyzed here in detail and comparison is made to the previous atomic resolution structure of the same protein as well as to other ultrahigh-resolution structures found in the Protein Data Bank. [source]


The structure of PhaZ7 at atomic (1.2,Å) resolution reveals details of the active site and suggests a substrate-binding mode

ACTA CRYSTALLOGRAPHICA SECTION F (ELECTRONIC), Issue 6 2010
Sachin Wakadkar
Poly-(R)-hydroxyalkanoates (PHAs) are bacterial polyesters that are degraded by a group of enzymes known as PHA depolymerases. Paucimonas lemoignei PhaZ7 depolymerase is the only extracellular depolymerase that has been described as being active towards amorphous PHAs. A previously determined crystal structure of PhaZ7 revealed an ,/,-hydrolase fold and a Ser-His-Asp catalytic triad. In order to address questions regarding the catalytic mechanism and substrate binding, the atomic resolution structure of PhaZ7 was determined after cocrystallization with the protease inhibitor PMSF. The reported structure has the highest resolution (1.2,Å) of currently known depolymerase structures and shows a sulfur dioxide molecule covalently attached to the active-site residue Ser136. Structural comparison with the free PhaZ7 structure (1.45,Å resolution) revealed no major changes in the active site, suggesting a preformed catalytic triad. The oxyanion hole was found to be formed by the amide groups of Met137 and Asn49. Nine well ordered water molecules were located in the active site. Manual docking of a substrate trimer showed that the positions of these water molecules coincide well with the substrate atoms. It is proposed that these water molecules are displaced upon binding of the substrate. Furthermore, conformational changes were identified after comparison with a previously determined PhaZ7 dimer structure in a different space group. The changes were located in surface loops involved in dimer formation, indicating some flexibility of these loops and their possible involvement in polyester binding. [source]


Structure-Based Calculation of Binding Affinities of ,2A -Adrenoceptor Agonists

CHEMMEDCHEM, Issue 6 2007
Balázs Balogh
An atomic resolution structure of ,2a -adrenoceptor was constructed and 15 known agonists were docked into the optimized model and experimental binding free energies were estimated. The figure shows the binding of the agonist clonidine (sticks) to the core binding pocket of the adrenoceptor (blue cartoon, key residues are marked with sticks). [source]


Concanavalin A in a dimeric crystal form: revisiting structural accuracy and molecular flexibility

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 5 2002
Katherine A. Kantardjieff
A structure of native concanavalin A (ConA), a hardy perennial of structural biology, has been determined in a dimeric crystal form at a resolution of 1.56,Å (space group C2221; unit-cell parameters a = 118.70, b = 101.38, c = 111.97,Å; two molecules in the asymmetric unit). The structure has been refined to an Rfree of 0.206 (R = 0.178) after iterative model building and phase-bias removal using Shake&wARP. Correspondence between calculated water,tyrosine interactions and experimentally observed structures near the saccharide-binding site suggests that the observed interactions between Tyr12 and water in various crystal forms are to be expected and are not unique to the presence of an active site. The present structure differs from previously reported atomic resolution structures of ConA in several regions and extends insight into the conformational flexibility of this molecule. Furthermore, this third, low-temperature, structure of ConA in a different crystal form, independently refined using powerful model-bias removal techniques, affords the opportunity to revisit assessment of accuracy and precision in high- or atomic resolution protein structures. It is illustrated that several precise structures of the same molecule can differ substantially in local detail and users of crystallographic models are reminded to consider the potential impact when interpreting structures. Suggestions on how to effectively represent ensembles of crystallographic models of a given molecule are provided. [source]