Polymorphism of microcrystalline urate oxidase from<i>Aspergillus flavus</i>

Collings, Ines E.; Watier, Yves; Giffard, Marion; Dagogo, Sotonye; Kahn, Richard; Bonneté, Françoise; Wright, Jonathan P.; Fitch, Andrew N.; Margiolaki, I.

doi:10.1107/s0907444910005354

Cited by 24 publications

(29 citation statements)

References 20 publications

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“…Protein powder diffraction continues to excite strong international interest; there are a variety of applications, including industrial protein characterization, such as polymorphs of insulin, as well as extending structure determination to yet smaller crystal samples, which would otherwise be outside the range of synchrotron X-ray data collection from a protein microcrystal [1][2][3][4][5]. Furthermore there are the upcoming X-ray Laser Facilities, with possibilities for protein nanocluster-crystallites' diffraction and de novo structure determination.…”

Section: Introductionmentioning

confidence: 99%

Time-dependent analysis of K₂PtBr₆binding to lysozyme studied by protein powder and single crystal X-ray analysis

Helliwell¹,

Bell

Bryant

et al. 2010

Zeitschrift für Kristallographie

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Abstract. Multi heavy atom cluster compounds like K 2 PtBr 6 offer a way forward to solve, de novo, unknown protein structures by powder diffraction involving dispersive (measured at two X-ray wavelengths) and isomorphous intensity differences as a complement to micro-crystallography or by using both approaches in combination. Towards this end, using the ESRF high resolution synchrotron X-ray powder diffraction beamline ID31, we have recorded high quality protein powder diffractograms at the platinum LIII and bromine K absorption edges, as well as reference wavelengths, for K 2 PtBr 6 bound to lysozyme. These experiments were conducted at 80K to protect the sample against X-radiation damage as much as possible and also to fix the K 2 PtBr 6 bound state, which seemed to show instability at room temperature. With multiple powder pattern analysis we extracted intensities and showed the PtBr 6 bound in lysozyme using 'omit electron density maps'. In addition the wavelength dispersive Fourier around the Br K edge shows up the bromine signal at PtBr 6 binding site 1 in one of the six samples tested. To better understand the chemical properties of this heavy atom compound we have elucidated the detailed binding behaviour using single crystal analyses with time-resolved freeze quenching after soak times of 10, 90 and 170 minutes. Whilst the quick soaking of 10 to 30 minutes, used at ESRF ID31 shows clear binding, there is increasing binding strength with increasing soak time. Thus, these time-resolved analytical chemistry results show that further heavy atom signal optimizations are possible. Prospects for extending our approach to the yet larger isomorphous and wavelength dispersive signal case of Ta 6 Br 12 bound to lysozyme are also described.

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Section: Introductionmentioning

confidence: 99%

Time-dependent analysis of K₂PtBr₆binding to lysozyme studied by protein powder and single crystal X-ray analysis

Helliwell¹,

Bell

Bryant

et al. 2010

Zeitschrift für Kristallographie

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“…in the database in order to narrow the searches in analogy with the search procedures in the PDB. When including experimental protein powder data sets a quality marker based on instrumental resolution would be useful: Well resolved synchrotron data is clearly preferred as they in some cases can be indexed and polymorph mixtures can be detected (Collings et al, 2010;Karavassili et al, 2012).…”

Section: Identification Based On Calculated Powder Patternsmentioning

confidence: 99%

Monitoring protein precipitates by in-house X-ray powder diffraction

et al. 2013

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Powder diffraction from protein powders using in-house diffractometers is an effective tool for identification and monitoring of protein crystal forms and artifacts. As an alternative to conventional powder diffractometers a single crystal diffractometer equipped with an X-ray micro-source can be used to collect powder patterns from 1 μl samples. Using a small-angle Xray scattering (SAXS) camera it is possible to collect data within minutes. A streamlined program has been developed for the calculation of powder patterns from pdb-coordinates, and includes correction for bulk-solvent. A number of such calculated powder patterns from insulin and lysozyme have been included in the powder diffraction database and successfully used for search-match identification. However, the fit could be much improved if peak asymmetry and multiple bulk-solvent corrections were included. When including a large number of protein data sets in the database some problems can be foreseen due to the large number of overlapping peaks in the low-angle region, and small differences in unit cell parameters between pdb-data and powder data. It is suggested that protein entries are supplied with more searchable keywords as protein name, protein type, molecular weight, source organism etc. in order to limit possible hits. a)

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“…According to more recent studies, the synchrotron X‐ray powder diffraction technique has been successfully adapted to various proteins, using state of the art instrumentation and algorithms. Recent progress in powder diffraction data collection11 and interpretation9 has facilitated the study of several biologically interesting proteins 12–18. The successful solution of different protein structures has been achieved via traditional methods in single‐crystal crystallography, such as molecular replacement (MR),11, 13, 17 single isomorphous replacement revealing the molecular envelope,14 and multiple isomorphous replacement showing secondary structure elements of a model protein 15…”

Section: Introductionmentioning

confidence: 99%

A new approach for structure analysis of two‐dimensional membrane protein crystals using X‐ray powder diffraction data

et al. 2011

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The application of powder diffraction methods to problems in structural biology is generally regarded as intractable because of the large number of unresolved, overlapping X-ray reflections. Here, we use information about unit cell lattice parameters, space group transformations, and chemical composition as a priori information in a bootstrap process that resolves the ambiguities associated with overlapping reflections. The measured ratios of reflections that can be resolved experimentally are used to refine the position, the shape, and the orientation of low-resolution molecular structures within the unit cell, in leading to the resolution of the overlapping reflections. The molecular model is then made progressively more sophisticated as additional diffraction information is included in the analysis. We apply our method to the recovery of the structure of the bacteriorhodopsin molecule (bR) to a resolution of 7 Å using experimental data obtained from two-dimensional purple membrane crystals. The approach can be used to determine the structure factors directly or to provide reliable low-resolution phase information that can be refined further by the conventional methods of protein crystallography.

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Polymorphism of microcrystalline urate oxidase fromAspergillus flavus

Cited by 24 publications

References 20 publications

Time-dependent analysis of K₂PtBr₆binding to lysozyme studied by protein powder and single crystal X-ray analysis

Time-dependent analysis of K₂PtBr₆binding to lysozyme studied by protein powder and single crystal X-ray analysis

Monitoring protein precipitates by in-house X-ray powder diffraction

A new approach for structure analysis of two‐dimensional membrane protein crystals using X‐ray powder diffraction data

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Polymorphism of microcrystalline urate oxidase fromAspergillus flavus

Cited by 24 publications

References 20 publications

Time-dependent analysis of K2PtBr6binding to lysozyme studied by protein powder and single crystal X-ray analysis

Time-dependent analysis of K2PtBr6binding to lysozyme studied by protein powder and single crystal X-ray analysis

Monitoring protein precipitates by in-house X-ray powder diffraction

A new approach for structure analysis of two‐dimensional membrane protein crystals using X‐ray powder diffraction data

Contact Info

Product

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Time-dependent analysis of K₂PtBr₆binding to lysozyme studied by protein powder and single crystal X-ray analysis

Time-dependent analysis of K₂PtBr₆binding to lysozyme studied by protein powder and single crystal X-ray analysis