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SAD Method (sad + method)

Distribution by Scientific Domains

Chemistry	100%

Selected Abstracts

Purification, crystallization and initial X-ray diffraction study of the zinc-finger domain of zebrafish Nanos

ACTA CRYSTALLOGRAPHICA SECTION F (ELECTRONIC), Issue 9 2009
Hiroshi Hashimoto
Nanos is a highly conserved RNA-binding protein in higher eukaryotes and acts as a key regulator protein involved in translational control utilizing the 3, untranslated region of mRNA. The C-terminal domain of Nanos has two conserved and novel CCHC-type zinc-finger motifs that are responsible for the function of Nanos. To clarify the structural basis of the function of Nanos, the C-terminal domain (residues 59,159) of zebrafish Nanos was overexpressed, purified and crystallized. The crystal belonged to space group P63, with unit-cell parameters a = b = 100.9, c = 71.5,Å, , = 120°. Structure determination by the MAD/SAD method is now in progress. [source]

Characterization of gadolinium complexes for SAD phasing in macromolecular crystallography: application to CbpF

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 8 2009
Rafael Molina
Seven Gd complexes were used in the preparation of heavy-atom derivatives for solving the structure of choline-binding protein F (CbpF), a 36,kDa surface protein from Streptococcus pneumoniae, by the SAD method. CbpF was used as a model system to analyse the phasing capability of each of the derivatives. Three different aspects have been systematically characterized: the efficacy of cocrystallization versus soaking in the binding of the different Gd complexes, their mode of interaction and a comparative study of SAD phasing using synchrotron radiation and using a rotating-anode generator. This study reveals the striking potential of these complexes for SAD phasing using a laboratory source and further reinforces their relevance for high-throughput macromolecular crystallography. [source]

Anomalous signal indicators in protein crystallography

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 11 2005
P. H. Zwart
A Monte Carlo procedure is described that generates random structure factors with simulated errors corresponding to an X-ray data set of a protein of a specific size and given heavy-atom content. The simulated data set can be used to estimate Bijvoet ratios and figures of merit as obtained from SAD phasing routines and can be used to gauge the feasibility of solving a structure via the SAD method. In addition to being able to estimate results from phasing, the simulation allows the estimation of the correlation coefficient between |,F|, the absolute Bijvoet amplitude difference, and FA, the structure-factor amplitude of the heavy-atom model. As this quantity is used in various substructure-solution routines, the estimate provides a rough estimate of the ease of substructure solution. Furthermore, the Monte Carlo procedure provides an easy way of estimating the number of significant Bijvoet intensity differences, denoted as the measurability, and is proposed as an intuitive measure of the quality of anomalous data. [source]

Structure determination of a novel protein by sulfur SAD using chromium radiation in combination with a new crystal-mounting method

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 8 2005
Yu Kitago
A novel and easy crystal-mounting technique was developed for the sulfur SAD method using Cr,K, radiation (2.29,Å). Using this technique, the cryo-buffer and cryoloop around the protein crystal can be removed before data collection in order to eliminate their X-ray absorption. The superiority and reproducibility of the data sets with this mounting technique were demonstrated using tetragonal hen egg-white lysozyme crystals. The structure of a novel protein, PH1109, from Pyrococcus horikoshii OT3 was solved using this technique. At the wavelength of Cr,K, radiation, the anomalous signal ,|,F|,/,|F|, of PH1109 is expected to be 1.72% as this protein of 144 residues includes four methionines and two cysteines. Sulfur SAD phasing was performed using SHELXD and SHELXE. In the case of the data set obtained using this novel crystal-mounting technique, 54.9% of all residues were built with side chains automatically by RESOLVE. On the other hand, only 16.0% were built with side chains for the data set collected using the standard cryoloop. These results indicated that this crystal-mounting technique was superior to the standard loop-mounting method for the measurement of small anomalous differences at longer wavelength and yielded better results in sulfur-substructure solution and initial phasing. The present study demonstrates that the sulfur SAD method with a chromium source becomes enhanced and more practical for macromolecular structure determination using the new crystal-mounting technique. [source]

Gd-HPDO3A, a complex to obtain high-phasing-power heavy-atom derivatives for SAD and MAD experiments: results with tetragonal hen egg-white lysozyme

ACTA CRYSTALLOGRAPHICA SECTION D, Issue 1 2002
Éric Girard
A neutral gadolinium complex, Gd-HPDO3A, is shown to be a good candidate to use to obtain heavy-atom derivatives and solve macromolecular structures using anomalous dispersion. Tetragonal crystals of a gadolinium derivative of hen egg-white lysozyme were obtained by co-crystallization using different concentrations of the complex. Diffraction data from three derivative crystals (100, 50 and 10,mM) were collected to a resolution of 1.7,Å using Cu,K, radiation from a rotating anode. Two strong binding sites of the gadolinium complex to the protein were located from the gadolinium anomalous signal in both the 100 and 50,mM derivatives. A single site is occupied in the 10,mM derivative. Phasing using the anomalous signal at a single wavelength (SAD method) leads to an electron-density map of high quality. The structure of the 100,mM derivative has been refined. Two molecules of the gadolinium complex are close together. Both molecules are located close to tryptophan residues. Four chloride ions were found. The exceptional quality of the SAD electron-density map, only enhanced by solvent flattening, suggests that single-wavelength anomalous scattering with the Gd-HPDO3A complex may be sufficient to solve protein structures of high molecular weight by synchrotron-radiation experiments, if not by laboratory experiments. [source]