Analysis of an industrial production suspension of<i>Bacillus lentus</i>subtilisin crystals by powder diffraction: a powerful quality-control tool

Frankær, Christian Grundahl; Moroz, Olga V.; Turkenburg, J.P.; Aspmo, Stein Ivar; Thymark, Majbritt; Friis, Esben P.; Ståhl, Kenny; Wilson, K.S.; Harris, Pernille

doi:10.1107/s1399004714001497

Cited by 4 publications

(5 citation statements)

References 27 publications

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“…On the contrary, powder diffraction has long been employed for characterizing crystalline, nanocrystalline, and amorphous powders of pharmaceutical importance, and due to the development of extensive databases, materials can be analyzed efficiently and in a high-throughput manner by their diffraction pattern. , Preliminary structural information, such as phase identification and characterization of unit-cell parameters, is also readily available from macromolecular powder samples. ,,,− ,,,,,,− Microcrystalline formulations provide enhanced bioavailability as well as increased stability and unique dissolution characteristics compared to amorphous or “in solution” counterparts. Although there are numerous attempts − in the literature toward the development of macromolecular microcrystalline formulations, the only successful large-scale example remains that of human insulin.…”

Section: Case Studiesmentioning

confidence: 99%

Rietveld Refinement for Macromolecular Powder Diffraction

Spiliopoulou

Triandafillidis

Valmas

et al. 2020

Crystal Growth & Design

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Powder X-ray diffraction (PXRD) has been employed extensively for the structural characterization of materials, quantitative analysis of multicomponent mixtures, phase identification, texture, and microstructural analysis. At the heart of all those lies the Rietveld method, which has revolutionized the use of powder diffraction for materials studies. Initially applied to minerals and inorganics, the Rietveld method has progressively been used for more complex materials, for instance, zeolites and pharmaceuticals. A major advance of the method came some 20 years ago, when the first protein structure was successfully refined. Because of the sheer complexity of macromolecules, several new approaches and algorithms had to be pioneered or adapted from macromolecular single-crystal diffraction experiments, thus constituting macromolecular PXRD a quite unique field of study. This review aims to provide necessary elements of theory and application of structure solution and refinement via the Rietveld method for macromolecular PXRD data. Practical explanations and highlighted case studies are also presented.

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Section: Case Studiesmentioning

confidence: 99%

Rietveld Refinement for Macromolecular Powder Diffraction

Spiliopoulou

Triandafillidis

Valmas

et al. 2020

Crystal Growth & Design

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“…Molecular replacement was performed using the published 1.4 Å resolution crystal structure of wild-type Savinase (PDB accession code: 4CFY) as the search model (Frankaer et al, 2014). Refinement was performed by PHENIX (Liebschner et al, 2019), to establish preliminary single-conformer structures for the RT and cryogenic crystals.…”

Section: Initial Structure Calculation and Refinementmentioning

confidence: 99%

“…The substrate specificity is low but hydrophobic residues are favoured at positions P1 and P4 of the substrate (Schechter & Berger, 1967). In the structure of Savinase, two structural metal binding sites are found to be occupied by Na + and Ca 2+ (Frankaer et al, 2014).…”

Section: Introductionmentioning

confidence: 98%

Conformational heterogeneity of Savinase from NMR, HDX-MS and X-ray diffraction analysis

Nguyen

Moroz

et al. 2020

PeerJ

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Background Several examples have emerged of enzymes where slow conformational changes are of key importance for function and where low populated conformations in the resting enzyme resemble the conformations of intermediate states in the catalytic process. Previous work on the subtilisin protease, Savinase, from Bacillus lentus by NMR spectroscopy suggested that this enzyme undergoes slow conformational dynamics around the substrate binding site. However, the functional importance of such dynamics is unknown. Methods Here we have probed the conformational heterogeneity in Savinase by following the temperature dependent chemical shift changes. In addition, we have measured changes in the local stability of the enzyme when the inhibitor phenylmethylsulfonyl fluoride is bound using hydrogen-deuterium exchange mass spectrometry (HDX-MS). Finally, we have used X-ray crystallography to compare electron densities collected at cryogenic and ambient temperatures and searched for possible low populated alternative conformations in the crystals. Results The NMR temperature titration shows that Savinase is most flexible around the active site, but no distinct alternative states could be identified. The HDX shows that modification of Savinase with inhibitor has very little impact on the stability of hydrogen bonds and solvent accessibility of the backbone. The most pronounced structural heterogeneities detected in the diffraction data are limited to alternative side-chain rotamers and a short peptide segment that has an alternative main-chain conformation in the crystal at cryo conditions. Collectively, our data show that there is very little structural heterogeneity in the resting state of Savinase and hence that Savinase does not rely on conformational selection to drive the catalytic process.

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“…X-ray powder diffraction (XRPD) permits the analysis of microcrystals as an ensemble. XRPD has already been successfully employed for the structural characterization of proteins (Von Dreele et al, 2000;Basso et al, 2005;Margiolaki et al, 2007Margiolaki et al, , 2013Margiolaki & Wright, 2008;Karavassili et al, 2017) and peptides (Inouye & Kirschner, 2006;Fujii et al, 2011;Fili et al, 2019), resulting in medium-resolution models ($2.5-5 Å ), as well as for crystal and polymorph screening (Margiolaki et al, 2005;Norrman et al, 2006;Hartmann et al, 2010;Hunter et al, 2011;Karavassili et al, 2012;Frankaer et al, 2014;Das et al, 2015;Valmas et al, 2015Valmas et al, , 2018Fili et al, 2015Fili et al, , 2016Trampari et al, 2018;Spiliopoulou et al, 2020). The method is ideal for the identification (Collings et al, 2010), refinement and quantification of multiple protein polymorphs coexisting in the same sample (Basso et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

Insulin polymorphism induced by two polyphenols: new crystal forms and advances in macromolecular powder diffraction

Triandafillidis

Parthenios

Spiliopoulou

et al. 2020

Acta Crystallogr D Struct Biol

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This study focuses on the polymorphism of human insulin (HI) upon the binding of the phenolic derivatives p-coumaric acid or trans-resveratrol over a wide pH range. The determination of the structural behaviour of HI via X-ray powder diffraction (XRPD) and single-crystal X-ray diffraction (SCXRD) is reported. Four distinct polymorphs were identified, two of which have not been reported previously. The intermediate phase transitions are discussed. One of the novel monoclinic polymorphs displays the highest molecular packing among insulin polymorphs of the same space group to date; its structure was elucidated by SCXRD. XRPD data collection was performed using a variety of instrumental setups and a systematic comparison of the acquired data is presented. A laboratory diffractometer was used for screening prior to high-resolution XRPD data collection on the ID22 beamline at the European Synchrotron Radiation Facility. Additional measurements for the most representative samples were performed on the X04SA beamline at the Swiss Light Source (SLS) using the MYTHEN II detector, which allowed the detection of minor previously untraceable impurities and dramatically improved the d-spacing resolution even for poorly diffracting samples.

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Analysis of an industrial production suspension ofBacillus lentussubtilisin crystals by powder diffraction: a powerful quality-control tool

Cited by 4 publications

References 27 publications

Rietveld Refinement for Macromolecular Powder Diffraction

Rietveld Refinement for Macromolecular Powder Diffraction

Conformational heterogeneity of Savinase from NMR, HDX-MS and X-ray diffraction analysis

Insulin polymorphism induced by two polyphenols: new crystal forms and advances in macromolecular powder diffraction

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