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3. An on-demand, drop-on-drop method for studying enzyme catalysis by serial crystallography.

Author

Butryn, Agata, Simon, Philipp S, Aller, Pierre, Hinchliffe, Philip, Massad, Ramzi N, Leen, Gabriel, Tooke, Catherine L, Bogacz, Isabel, Kim, In-Sik, Bhowmick, Asmit, Brewster, Aaron S, Devenish, Nicholas E, Brem, Jürgen, Kamps, Jos JAG, Lang, Pauline A, Rabe, Patrick, Axford, Danny, Beale, John H, Davy, Bradley, Ebrahim, Ali, Orlans, Julien, Storm, Selina LS, Zhou, Tiankun, Owada, Shigeki, Tanaka, Rie, Tono, Kensuke, Evans, Gwyndaf, Owen, Robin L, Houle, Frances A, Sauter, Nicholas K, Schofield, Christopher J, Spencer, James, Yachandra, Vittal K, Yano, Junko, Kern, Jan F, and Orville, Allen M

Subjects
Animals, Chickens, Enzymes, beta-Lactamases, Muramidase, Avian Proteins, Bacterial Proteins, Recombinant Proteins, Crystallography, X-Ray, Equipment Design, Catalytic Domain, Models, Molecular, Biocatalysis, Generic health relevance
Abstract

Serial femtosecond crystallography has opened up many new opportunities in structural biology. In recent years, several approaches employing light-inducible systems have emerged to enable time-resolved experiments that reveal protein dynamics at high atomic and temporal resolutions. However, very few enzymes are light-dependent, whereas macromolecules requiring ligand diffusion into an active site are ubiquitous. In this work we present a drop-on-drop sample delivery system that enables the study of enzyme-catalyzed reactions in microcrystal slurries. The system delivers ligand solutions in bursts of multiple picoliter-sized drops on top of a larger crystal-containing drop inducing turbulent mixing and transports the mixture to the X-ray interaction region with temporal resolution. We demonstrate mixing using fluorescent dyes, numerical simulations and time-resolved serial femtosecond crystallography, which show rapid ligand diffusion through microdroplets. The drop-on-drop method has the potential to be widely applicable to serial crystallography studies, particularly of enzyme reactions with small molecule substrates.

Published
2021

5. VMXm – A sub‐micron focus macromolecular crystallography beamline at Diamond Light Source.

Author

Warren, Anna J., Trincao, Jose, Crawshaw, Adam D., Beale, Emma V., Duller, Graham, Stallwood, Andrew, Lunnon, Mark, Littlewood, Richard, Prescott, Adam, Foster, Andrew, Smith, Neil, Rehm, Guenther, Gayadeen, Sandira, Bloomer, Christopher, Alianelli, Lucia, Laundy, David, Sutter, John, Cahill, Leo, and Evans, Gwyndaf

Abstract

VMXm joins the suite of operational macromolecular crystallography beamlines at Diamond Light Source. It has been designed to optimize rotation data collections from protein crystals less than 10 µm and down to below 1 µm in size. The beamline has a fully focused beam of 0.3 × 2.3 µm (vertical × horizontal) with a tuneable energy range (6–28 keV) and high flux (1.6 × 1012 photons s−1 at 12.5 keV). The crystals are housed within a vacuum chamber to minimize background scatter from air. Crystals are plunge‐cooled on cryo‐electron microscopy grids, allowing much of the liquid surrounding the crystals to be removed. These factors improve the signal‐to‐noise during data collection and the lifetime of the microcrystals can be prolonged by exploiting photoelectron escape. A novel in vacuo sample environment has been designed which also houses a scanning electron microscope to aid with sample visualization. This combination of features at VMXm allows measurements at the physical limits of X‐ray crystallography on biomacromolecules to be explored and exploited. [ABSTRACT FROM AUTHOR]

Published
2024
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6. How Do Gepotidacin and Zoliflodacin Stabilize DNA Cleavage Complexes with Bacterial Type IIA Topoisomerases? 1. Experimental Definition of Metal Binding Sites.

Author

Morgan, Harry, Nicholls, Robert A., Warren, Anna J., Ward, Simon E., Evans, Gwyndaf, Long, Fei, Murshudov, Garib N., Duman, Ramona, and Bax, Benjamin D.

Abstract

One of the challenges for experimental structural biology in the 21st century is to see chemical reactions happen. Staphylococcus aureus (S. aureus) DNA gyrase is a type IIA topoisomerase that can create temporary double-stranded DNA breaks to regulate DNA topology. Drugs, such as gepotidacin, zoliflodacin and the quinolone moxifloxacin, can stabilize these normally transient DNA strand breaks and kill bacteria. Crystal structures of uncleaved DNA with a gepotidacin precursor (2.1 Å GSK2999423) or with doubly cleaved DNA and zoliflodacin (or with its progenitor QPT-1) have been solved in the same P61 space-group (a = b ≈ 93 Å, c ≈ 412 Å). This suggests that it may be possible to observe the two DNA cleavage steps (and two DNA-religation steps) in this P61 space-group. Here, a 2.58 Å anomalous manganese dataset in this crystal form is solved, and four previous crystal structures (1.98 Å, 2.1 Å, 2.5 Å and 2.65 Å) in this crystal form are re-refined to clarify crystal contacts. The structures clearly suggest a single moving metal mechanism—presented in an accompanying (second) paper. A previously published 2.98 Å structure of a yeast topoisomerase II, which has static disorder around a crystallographic twofold axis, was published as containing two metals at one active site. Re-refined coordinates of this 2.98 Å yeast structure are consistent with other type IIA topoisomerase structures in only having one metal ion at each of the two different active sites. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Improving signal strength in serial crystallography with DIALS geometry refinement.

Author

Brewster, Aaron S, Waterman, David G, Parkhurst, James M, Gildea, Richard J, Young, Iris D, O'Riordan, Lee J, Yano, Junko, Winter, Graeme, Evans, Gwyndaf, and Sauter, Nicholas K

Subjects
Humans, Bacillus, Thermolysin, Radiographic Image Interpretation, Computer-Assisted, X-Ray Diffraction, Crystallography, X-Ray, Algorithms, Software, DIALS, XFEL, metrology, refinement, sparse algebra
Abstract

The DIALS diffraction-modeling software package has been applied to serial crystallography data. Diffraction modeling is an exercise in determining the experimental parameters, such as incident beam wavelength, crystal unit cell and orientation, and detector geometry, that are most consistent with the observed positions of Bragg spots. These parameters can be refined by nonlinear least-squares fitting. In previous work, it has been challenging to refine both the positions of the sensors (metrology) on multipanel imaging detectors such as the CSPAD and the orientations of all of the crystals studied. Since the optimal models for metrology and crystal orientation are interdependent, alternate cycles of panel refinement and crystal refinement have been required. To simplify the process, a sparse linear algebra technique for solving the normal equations was implemented, allowing the detector panels to be refined simultaneously against the diffraction from thousands of crystals with excellent computational performance. Separately, it is shown how to refine the metrology of a second CSPAD detector, positioned at a distance of 2.5 m from the crystal, used for recording low-angle reflections. With the ability to jointly refine the detector position against the ensemble of all crystals used for structure determination, it is shown that ensemble refinement greatly reduces the apparent nonisomorphism that is often observed in the unit-cell distributions from still-shot serial crystallography. In addition, it is shown that batching the images by timestamp and re-refining the detector position can realistically model small, time-dependent variations in detector position relative to the sample, and thereby improve the integrated structure-factor intensity signal and heavy-atom anomalous peak heights.

Published
2018

8. Towards in cellulo virus crystallography.

Author

Duyvesteyn, Helen ME, Ginn, Helen M, Pietilä, Maija K, Wagner, Armin, Hattne, Johan, Grimes, Jonathan M, Hirvonen, Elina, Evans, Gwyndaf, Parsy, Marie-Laure, Sauter, Nicholas K, Brewster, Aaron S, Huiskonen, Juha T, Stuart, David I, Sutton, Geoff, and Bamford, Dennis H

Subjects
Escherichia coli, Bacteriophage phi X 174, Cryoelectron Microscopy, Crystallography, X-Ray, Crystallography, X-Ray, Biotechnology, 2.2 Factors relating to physical environment, Infection, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

Viruses are a significant threat to both human health and the economy, and there is an urgent need for novel anti-viral drugs and vaccines. High-resolution viral structures inform our understanding of the virosphere, and inspire novel therapies. Here we present a method of obtaining such structural information that avoids potentially disruptive handling, by collecting diffraction data from intact infected cells. We identify a suitable combination of cell type and virus to accumulate particles in the cells, establish a suitable time point where most cells contain virus condensates and use electron microscopy to demonstrate that these are ordered crystalline arrays of empty capsids. We then use an X-ray free electron laser to provide extremely bright illumination of sub-micron intracellular condensates of bacteriophage phiX174 inside living Escherichia coli at room temperature. We have been able to collect low resolution diffraction data. Despite the limited resolution and completeness of these initial data, due to a far from optimal experimental setup, we have used novel methodology to determine a putative space group, unit cell dimensions, particle packing and likely maturation state of the particles.

Published
2018

9. DIALS: implementation and evaluation of a new integration package

Author

Winter, Graeme, Waterman, David G, Parkhurst, James M, Brewster, Aaron S, Gildea, Richard J, Gerstel, Markus, Fuentes-Montero, Luis, Vollmar, Melanie, Michels-Clark, Tara, Young, Iris D, Sauter, Nicholas K, and Evans, Gwyndaf

Subjects
Algorithms, Bacterial Proteins, Crystallography, X-Ray, Electronic Data Processing, Radiographic Image Interpretation, Computer-Assisted, Repressor Proteins, Software, Thermolysin, X-ray diffraction, data processing, methods development, DIALS, Physical Sciences, Chemical Sciences, Biological Sciences, Biophysics
Abstract

The DIALS project is a collaboration between Diamond Light Source, Lawrence Berkeley National Laboratory and CCP4 to develop a new software suite for the analysis of crystallographic X-ray diffraction data, initially encompassing spot finding, indexing, refinement and integration. The design, core algorithms and structure of the software are introduced, alongside results from the analysis of data from biological and chemical crystallography experiments.

Published
2018

10. Ray-tracing analytical absorption correction for X-ray crystallography based on tomographic reconstructions

Author

Lu, Yishun, primary, Duman, Ramona, additional, Beilsten-Edmands, James, additional, Winter, Graeme, additional, Basham, Mark, additional, Evans, Gwyndaf, additional, Kamps, Jos J. A. G., additional, Orville, Allen M., additional, Kwong, Hok-Sau, additional, Beis, Konstantinos, additional, Armour, Wesley, additional, and Wagner, Armin, additional

Published
2024
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11. A redox switch allows binding of Fe(II) and Fe(III) ions in the cyanobacterial iron-binding protein FutA from Prochlorococcus

Author

Bolton, Rachel, primary, Machelett, Moritz M., additional, Stubbs, Jack, additional, Axford, Danny, additional, Caramello, Nicolas, additional, Catapano, Lucrezia, additional, Malý, Martin, additional, Rodrigues, Matthew J., additional, Cordery, Charlotte, additional, Tizzard, Graham J., additional, MacMillan, Fraser, additional, Engilberge, Sylvain, additional, von Stetten, David, additional, Tosha, Takehiko, additional, Sugimoto, Hiroshi, additional, Worrall, Jonathan A. R., additional, Webb, Jeremy S., additional, Zubkov, Mike, additional, Coles, Simon, additional, Mathieu, Eric, additional, Steiner, Roberto A., additional, Murshudov, Garib, additional, Schrader, Tobias E., additional, Orville, Allen M., additional, Royant, Antoine, additional, Evans, Gwyndaf, additional, Hough, Michael A., additional, Owen, Robin L., additional, and Tews, Ivo, additional

Published
2024
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12. Structure of photosystem II and substrate binding at room temperature

Author

Young, Iris D, Ibrahim, Mohamed, Chatterjee, Ruchira, Gul, Sheraz, Fuller, Franklin D, Koroidov, Sergey, Brewster, Aaron S, Tran, Rosalie, Alonso-Mori, Roberto, Kroll, Thomas, Michels-Clark, Tara, Laksmono, Hartawan, Sierra, Raymond G, Stan, Claudiu A, Hussein, Rana, Zhang, Miao, Douthit, Lacey, Kubin, Markus, de Lichtenberg, Casper, Vo Pham, Long, Nilsson, Håkan, Cheah, Mun Hon, Shevela, Dmitriy, Saracini, Claudio, Bean, Mackenzie A, Seuffert, Ina, Sokaras, Dimosthenis, Weng, Tsu-Chien, Pastor, Ernest, Weninger, Clemens, Fransson, Thomas, Lassalle, Louise, Bräuer, Philipp, Aller, Pierre, Docker, Peter T, Andi, Babak, Orville, Allen M, Glownia, James M, Nelson, Silke, Sikorski, Marcin, Zhu, Diling, Hunter, Mark S, Lane, Thomas J, Aquila, Andy, Koglin, Jason E, Robinson, Joseph, Liang, Mengning, Boutet, Sébastien, Lyubimov, Artem Y, Uervirojnangkoorn, Monarin, Moriarty, Nigel W, Liebschner, Dorothee, Afonine, Pavel V, Waterman, David G, Evans, Gwyndaf, Wernet, Philippe, Dobbek, Holger, Weis, William I, Brunger, Axel T, Zwart, Petrus H, Adams, Paul D, Zouni, Athina, Messinger, Johannes, Bergmann, Uwe, Sauter, Nicholas K, Kern, Jan, Yachandra, Vittal K, and Yano, Junko

Subjects
Plant Biology, Biological Sciences, Physical Sciences, Ammonia, Bacterial Proteins, Binding Sites, Crystallization, Cyanobacteria, Electrons, Lasers, Manganese, Models, Molecular, Oxygen, Photosystem II Protein Complex, Substrate Specificity, Temperature, Water, General Science & Technology
Abstract

Light-induced oxidation of water by photosystem II (PS II) in plants, algae and cyanobacteria has generated most of the dioxygen in the atmosphere. PS II, a membrane-bound multi-subunit pigment protein complex, couples the one-electron photochemistry at the reaction centre with the four-electron redox chemistry of water oxidation at the Mn4CaO5 cluster in the oxygen-evolving complex (OEC). Under illumination, the OEC cycles through five intermediate S-states (S0 to S4), in which S1 is the dark-stable state and S3 is the last semi-stable state before O-O bond formation and O2 evolution. A detailed understanding of the O-O bond formation mechanism remains a challenge, and will require elucidation of both the structures of the OEC in the different S-states and the binding of the two substrate waters to the catalytic site. Here we report the use of femtosecond pulses from an X-ray free electron laser (XFEL) to obtain damage-free, room temperature structures of dark-adapted (S1), two-flash illuminated (2F; S3-enriched), and ammonia-bound two-flash illuminated (2F-NH3; S3-enriched) PS II. Although the recent 1.95 Å resolution structure of PS II at cryogenic temperature using an XFEL provided a damage-free view of the S1 state, measurements at room temperature are required to study the structural landscape of proteins under functional conditions, and also for in situ advancement of the S-states. To investigate the water-binding site(s), ammonia, a water analogue, has been used as a marker, as it binds to the Mn4CaO5 cluster in the S2 and S3 states. Since the ammonia-bound OEC is active, the ammonia-binding Mn site is not a substrate water site. This approach, together with a comparison of the native dark and 2F states, is used to discriminate between proposed O-O bond formation mechanisms.

Published
2016

13. A redox switch allows binding of Fe(II) and Fe(III) ions in the cyanobacterial iron-binding protein FutA from Prochlorococcus

Author

Bolton, Rachel, Machelett, Moritz M., Stubbs, Jack, Axford, Danny, Caramello, Nicolas, Catapano, Lucrezia, Malý, Martin, Rodrigues, Matthew J., Cordery, Charlotte, Tizzard, Graham J., MacMillan, Fraser, Engilberge, Sylvain, von Stetten, David, Tosha, Takehiko, Sugimoto, Hiroshi, Worrall, Jonathan A. R., Webb, Jeremy S., Zubkov, Mike, Coles, Simon, Mathieu, Eric, Steiner, Roberto A., Murshudov, Garib, Schrader, Tobias E., Orville, Allen M., Royant, Antoine, Evans, Gwyndaf, Hough, Michael A., Owen, Robin L., Tews, Ivo, Bolton, Rachel, Machelett, Moritz M., Stubbs, Jack, Axford, Danny, Caramello, Nicolas, Catapano, Lucrezia, Malý, Martin, Rodrigues, Matthew J., Cordery, Charlotte, Tizzard, Graham J., MacMillan, Fraser, Engilberge, Sylvain, von Stetten, David, Tosha, Takehiko, Sugimoto, Hiroshi, Worrall, Jonathan A. R., Webb, Jeremy S., Zubkov, Mike, Coles, Simon, Mathieu, Eric, Steiner, Roberto A., Murshudov, Garib, Schrader, Tobias E., Orville, Allen M., Royant, Antoine, Evans, Gwyndaf, Hough, Michael A., Owen, Robin L., and Tews, Ivo

Abstract

The marine cyanobacterium Prochlorococcus is a main contributor to global photosynthesis, whilst being limited by iron availability. Cyanobacterial genomes generally encode two different types of FutA iron-binding proteins: periplasmic FutA2 ABC transporter subunits bind Fe(III), while cytosolic FutA1 binds Fe(II). Owing to their small size and their economized genome Prochlorococcus ecotypes typically possess a single futA gene. How the encoded FutA protein might bind different Fe oxidation states was previously unknown. Here, we use structural biology techniques at room temperature to probe the dynamic behavior of FutA. Neutron diffraction confirmed four negatively charged tyrosinates, that together with a neutral water molecule coordinate iron in trigonal bipyramidal geometry. Positioning of the positively charged Arg103 side chain in the second coordination shell yields an overall charge-neutral Fe(III) binding state in structures determined by neutron diffraction and serial femtosecond crystallography. Conventional rotation X-ray crystallography using a home source revealed X-ray-induced photoreduction of the iron center with observation of the Fe(II) binding state; here, an additional positioning of the Arg203 side chain in the second coordination shell maintained an overall charge neutral Fe(II) binding site. Dose series using serial synchrotron crystallography and an XFEL X-ray pump–probe approach capture the transition between Fe(III) and Fe(II) states, revealing how Arg203 operates as a switch to accommodate the different iron oxidation states. This switching ability of the Prochlorococcus FutA protein may reflect ecological adaptation by genome streamlining and loss of specialized FutA proteins.

Published
2024

14. Pillar data‐acquisition strategies for cryo‐electron tomography of beam‐sensitive biological samples.

Author

Parkhurst, James M., Varslot, Trond, Dumoux, Maud, Siebert, C. Alistair, Darrow, Michele, Basham, Mark, Kirkland, Angus, Grange, Michael, Evans, Gwyndaf, and Naismith, James H.

Subjects
TOMOGRAPHY, KNOWLEDGE transfer, BIOLOGICAL specimens, VOLUMETRIC analysis, ELECTRON beams, ACQUISITION of data
Abstract

For cryo‐electron tomography (cryo‐ET) of beam‐sensitive biological specimens, a planar sample geometry is typically used. As the sample is tilted, the effective thickness of the sample along the direction of the electron beam increases and the signal‐to‐noise ratio concomitantly decreases, limiting the transfer of information at high tilt angles. In addition, the tilt range where data can be collected is limited by a combination of various sample‐environment constraints, including the limited space in the objective lens pole piece and the possible use of fixed conductive braids to cool the specimen. Consequently, most tilt series are limited to a maximum of ±70°, leading to the presence of a missing wedge in Fourier space. The acquisition of cryo‐ET data without a missing wedge, for example using a cylindrical sample geometry, is hence attractive for volumetric analysis of low‐symmetry structures such as organelles or vesicles, lysis events, pore formation or filaments for which the missing information cannot be compensated by averaging techniques. Irrespective of the geometry, electron‐beam damage to the specimen is an issue and the first images acquired will transfer more high‐resolution information than those acquired last. There is also an inherent trade‐off between higher sampling in Fourier space and avoiding beam damage to the sample. Finally, the necessity of using a sufficient electron fluence to align the tilt images means that this fluence needs to be fractionated across a small number of images; therefore, the order of data acquisition is also a factor to consider. Here, an n‐helix tilt scheme is described and simulated which uses overlapping and interleaved tilt series to maximize the use of a pillar geometry, allowing the entire pillar volume to be reconstructed as a single unit. Three related tilt schemes are also evaluated that extend the continuous and classic dose‐symmetric tilt schemes for cryo‐ET to pillar samples to enable the collection of isotropic information across all spatial frequencies. A fourfold dose‐symmetric scheme is proposed which provides a practical compromise between uniform information transfer and complexity of data acquisition. [ABSTRACT FROM AUTHOR]

Published
2024
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15. TakeTwo: an indexing algorithm suited to still images with known crystal parameters

Author

Ginn, Helen Mary, Roedig, Philip, Kuo, Anling, Evans, Gwyndaf, Sauter, Nicholas K, Ernst, Oliver, Meents, Alke, Mueller-Werkmeister, Henrike, Miller, RJ Dwayne, and Stuart, David Ian

Subjects
Inorganic Chemistry, Chemical Sciences, Algorithms, Crystallography, Crystallography, X-Ray, Electrons, Lasers, Protein Conformation, Proteins, Synchrotrons, Time Factors, X-Rays, TakeTwo, X-ray free-electron lasers, XFELs, data processing, serial crystallography, Physical Sciences, Biological Sciences, Biophysics, Biological sciences, Chemical sciences, Physical sciences
Abstract

The indexing methods currently used for serial femtosecond crystallography were originally developed for experiments in which crystals are rotated in the X-ray beam, providing significant three-dimensional information. On the other hand, shots from both X-ray free-electron lasers and serial synchrotron crystallography experiments are still images, in which the few three-dimensional data available arise only from the curvature of the Ewald sphere. Traditional synchrotron crystallography methods are thus less well suited to still image data processing. Here, a new indexing method is presented with the aim of maximizing information use from a still image given the known unit-cell dimensions and space group. Efficacy for cubic, hexagonal and orthorhombic space groups is shown, and for those showing some evidence of diffraction the indexing rate ranged from 90% (hexagonal space group) to 151% (cubic space group). Here, the indexing rate refers to the number of lattices indexed per image.

Published
2016

16. On the release of cppxfel for processing X‐ray free‐electron laser images

Author

Ginn, Helen Mary, Evans, Gwyndaf, Sauter, Nicholas K, and Stuart, David Ian

Subjects
Inorganic Chemistry, Chemical Sciences, Generic health relevance, X-ray free-electron lasers, XFELS, computer programs, data analysis, serial femtosecond crystallography, Mathematical Sciences, Physical Sciences, Engineering, Inorganic & Nuclear Chemistry, Inorganic chemistry, Physical chemistry, Condensed matter physics
Abstract

As serial femtosecond crystallography expands towards a variety of delivery methods, including chip-based methods, and smaller collected data sets, the requirement to optimize the data analysis to produce maximum structure quality is becoming increasingly pressing. Here cppxfel, a software package primarily written in C++, which showcases several data analysis techniques, is released. This software package presently indexes images using DIALS (diffraction integration for advanced light sources) and performs an initial orientation matrix refinement, followed by post-refinement of individual images against a reference data set. Cppxfel is released with the hope that the unique and useful elements of this package can be repurposed for existing software packages. However, as released, it produces high-quality crystal structures and is therefore likely to be also useful to experienced users of X-ray free-electron laser (XFEL) software who wish to maximize the information extracted from a limited number of XFEL images.

Published
2016

17. Diffraction‐geometry refinement in the DIALS framework

Author

Waterman, David G, Winter, Graeme, Gildea, Richard J, Parkhurst, James M, Brewster, Aaron S, Sauter, Nicholas K, and Evans, Gwyndaf

Subjects
Biological Sciences, Chemical Sciences, Physical Sciences, Models, Theoretical, DIALS framework, centroid refinement, global refinement, Biophysics, Biological sciences, Chemical sciences, Physical sciences
Abstract

Rapid data collection and modern computing resources provide the opportunity to revisit the task of optimizing the model of diffraction geometry prior to integration. A comprehensive description is given of new software that builds upon established methods by performing a single global refinement procedure, utilizing a smoothly varying model of the crystal lattice where appropriate. This global refinement technique extends to multiple data sets, providing useful constraints to handle the problem of correlated parameters, particularly for small wedges of data. Examples of advanced uses of the software are given and the design is explained in detail, with particular emphasis on the flexibility and extensibility it entails.

Published
2016

18. A revised partiality model and post‐refinement algorithm for X‐ray free‐electron laser data

Author

Ginn, Helen Mary, Brewster, Aaron S, Hattne, Johan, Evans, Gwyndaf, Wagner, Armin, Grimes, Jonathan M, Sauter, Nicholas K, Sutton, Geoff, and Stuart, David Ian

Subjects
Inorganic Chemistry, Chemical Sciences, Physical Sciences, Algorithms, Lasers, Models, Molecular, post-refinement, free-electron laser, partiality, Biological Sciences, Biophysics, Biological sciences, Chemical sciences, Physical sciences
Abstract

Research towards using X-ray free-electron laser (XFEL) data to solve structures using experimental phasing methods such as sulfur single-wavelength anomalous dispersion (SAD) has been hampered by shortcomings in the diffraction models for X-ray diffraction from FELs. Owing to errors in the orientation matrix and overly simple partiality models, researchers have required large numbers of images to converge to reliable estimates for the structure-factor amplitudes, which may not be feasible for all biological systems. Here, data for cytoplasmic polyhedrosis virus type 17 (CPV17) collected at 1.3 Å wavelength at the Linac Coherent Light Source (LCLS) are revisited. A previously published definition of a partiality model for reflections illuminated by self-amplified spontaneous emission (SASE) pulses is built upon, which defines a fraction between 0 and 1 based on the intersection of a reflection with a spread of Ewald spheres modelled by a super-Gaussian wavelength distribution in the X-ray beam. A method of post-refinement to refine the parameters of this model is suggested. This has generated a merged data set with an overall discrepancy (by calculating the R(split) value) of 3.15% to 1.46 Å resolution from a 7225-image data set. The atomic numbers of C, N and O atoms in the structure are distinguishable in the electron-density map. There are 13 S atoms within the 237 residues of CPV17, excluding the initial disordered methionine. These only possess 0.42 anomalous scattering electrons each at 1.3 Å wavelength, but the 12 that have single predominant positions are easily detectable in the anomalous difference Fourier map. It is hoped that these improvements will lead towards XFEL experimental phase determination and structure determination by sulfur SAD and will generally increase the utility of the method for difficult cases.

Published
2015

19. Structure of CPV17 polyhedrin determined by the improved analysis of serial femtosecond crystallographic data.

Author

Ginn, Helen M, Messerschmidt, Marc, Ji, Xiaoyun, Zhang, Hanwen, Axford, Danny, Gildea, Richard J, Winter, Graeme, Brewster, Aaron S, Hattne, Johan, Wagner, Armin, Grimes, Jonathan M, Evans, Gwyndaf, Sauter, Nicholas K, Sutton, Geoff, and Stuart, David I

Subjects
Animals, Culicidae, Reoviridae, Viral Structural Proteins, Crystallography, Protein Conformation, Genetic Vectors, Models, Molecular, Image Processing, Computer-Assisted, Models, Molecular, Image Processing, Computer-Assisted, Generic Health Relevance
Abstract

The X-ray free-electron laser (XFEL) allows the analysis of small weakly diffracting protein crystals, but has required very many crystals to obtain good data. Here we use an XFEL to determine the room temperature atomic structure for the smallest cytoplasmic polyhedrosis virus polyhedra yet characterized, which we failed to solve at a synchrotron. These protein microcrystals, roughly a micron across, accrue within infected cells. We use a new physical model for XFEL diffraction, which better estimates the experimental signal, delivering a high-resolution XFEL structure (1.75 Å), using fewer crystals than previously required for this resolution. The crystal lattice and protein core are conserved compared with a polyhedrin with less than 10% sequence identity. We explain how the conserved biological phenotype, the crystal lattice, is maintained in the face of extreme environmental challenge and massive evolutionary divergence. Our improved methods should open up more challenging biological samples to XFEL analysis.

Published
2015

21. Investigation of the milling characteristics of different focused ion beam sources assessed by three-dimensional electron diffraction from crystal lamellae

Author

Parkhurst, James M., primary, Crawshaw, Adam D., additional, Siebert, C. Alistair, additional, Dumoux, Maud, additional, Owen, C. David, additional, Nunes, Pedro, additional, Waterman, David, additional, Glen, Thomas, additional, Stuart, David I., additional, Naismith, James H., additional, and Evans, Gwyndaf, additional

Published
2023
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23. The CCP4 suite: integrative software for macromolecular crystallography

Author

Agirre, Jon, primary, Atanasova, Mihaela, additional, Bagdonas, Haroldas, additional, Ballard, Charles B., additional, Baslé, Arnaud, additional, Beilsten-Edmands, James, additional, Borges, Rafael J., additional, Brown, David G., additional, Burgos-Mármol, J. Javier, additional, Berrisford, John M., additional, Bond, Paul S., additional, Caballero, Iracema, additional, Catapano, Lucrezia, additional, Chojnowski, Grzegorz, additional, Cook, Atlanta G., additional, Cowtan, Kevin D., additional, Croll, Tristan I., additional, Debreczeni, Judit É., additional, Devenish, Nicholas E., additional, Dodson, Eleanor J., additional, Drevon, Tarik R., additional, Emsley, Paul, additional, Evans, Gwyndaf, additional, Evans, Phil R., additional, Fando, Maria, additional, Foadi, James, additional, Fuentes-Montero, Luis, additional, Garman, Elspeth F., additional, Gerstel, Markus, additional, Gildea, Richard J., additional, Hatti, Kaushik, additional, Hekkelman, Maarten L., additional, Heuser, Philipp, additional, Hoh, Soon Wen, additional, Hough, Michael A., additional, Jenkins, Huw T., additional, Jiménez, Elisabet, additional, Joosten, Robbie P., additional, Keegan, Ronan M., additional, Keep, Nicholas, additional, Krissinel, Eugene B., additional, Kolenko, Petr, additional, Kovalevskiy, Oleg, additional, Lamzin, Victor S., additional, Lawson, David M., additional, Lebedev, Andrey A., additional, Leslie, Andrew G. W., additional, Lohkamp, Bernhard, additional, Long, Fei, additional, Malý, Martin, additional, McCoy, Airlie J., additional, McNicholas, Stuart J., additional, Medina, Ana, additional, Millán, Claudia, additional, Murray, James W., additional, Murshudov, Garib N., additional, Nicholls, Robert A., additional, Noble, Martin E. M., additional, Oeffner, Robert, additional, Pannu, Navraj S., additional, Parkhurst, James M., additional, Pearce, Nicholas, additional, Pereira, Joana, additional, Perrakis, Anastassis, additional, Powell, Harold R., additional, Read, Randy J., additional, Rigden, Daniel J., additional, Rochira, William, additional, Sammito, Massimo, additional, Sánchez Rodríguez, Filomeno, additional, Sheldrick, George M., additional, Shelley, Kathryn L., additional, Simkovic, Felix, additional, Simpkin, Adam J., additional, Skubak, Pavol, additional, Sobolev, Egor, additional, Steiner, Roberto A., additional, Stevenson, Kyle, additional, Tews, Ivo, additional, Thomas, Jens M. H., additional, Thorn, Andrea, additional, Valls, Josep Triviño, additional, Uski, Ville, additional, Usón, Isabel, additional, Vagin, Alexei, additional, Velankar, Sameer, additional, Vollmar, Melanie, additional, Walden, Helen, additional, Waterman, David, additional, Wilson, Keith S., additional, Winn, Martyn D., additional, Winter, Graeme, additional, Wojdyr, Marcin, additional, and Yamashita, Keitaro, additional

Published
2023
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24. A redox switch allows binding of Fe(II) and Fe(III) ions in the cyanobacterial iron binding protein FutA fromProchlorococcus

Author

Bolton, Rachel, primary, Machelett, Moritz M., additional, Stubbs, Jack, additional, Axford, Danny, additional, Caramello, Nicolas, additional, Catapano, Lucrezia, additional, Malý, Martin, additional, Rodrigues, Matthew J., additional, Cordery, Charlotte, additional, Tizzard, Graham J., additional, MacMillan, Fraser, additional, Engilberge, Sylvain, additional, von Stetten, David, additional, Tosha, Takehiko, additional, Sugimoto, Hiroshi, additional, Worrall, Jonathan A.R., additional, Webb, Jeremy S., additional, Zubkov, Mike, additional, Coles, Simon, additional, Mathieu, Eric, additional, Steiner, Roberto A., additional, Murshudov, Garib, additional, Schrader, Tobias E., additional, Orville, Allen M., additional, Royant, Antoine, additional, Evans, Gwyndaf, additional, Hough, Michael A., additional, Owen, Robin L., additional, and Tews, Ivo, additional

Published
2023
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25. The CCP4 suite: integrative software for macromolecular crystallography

Author

Agirre, Jon, Atanasova, Mihaela, Bagdonas, Haroldas, Ballard, Charles B., Basle, Arnaud, Beilsten-Edmands, James, Borges, Rafael J., Brown, David G., Burgos-Marmol, J. Javier, Berrisford, John M., Bond, Paul S., Caballero, Iracema, Catapano, Lucrezia, Chojnowski, Grzegorz, Cook, Atlanta G., Cowtan, Kevin D., Croll, Tristan I., Debreczeni, Judit E., Devenish, Nicholas E., Dodson, Eleanor J., Drevon, Tarik R., Emsley, Paul, Evans, Gwyndaf, Evans, Phil R., Fando, Maria, Foadi, James, Fuentes-Montero, Luis, Garman, Elspeth F., Gerstel, Markus, Gildea, Richard J., Hatti, Kaushik, Hekkelman, Maarten L., Heuser, Philipp, Hoh, Soon Wen, Hough, Michael A., Jenkins, Huw T., Jimenez, Elisabet, Joosten, Robbie P., Keegan, Ronan M., Keep, Nicholas, Krissinel, Eugene B., Kolenko, Petr, Kovalevskiy, Oleg, Lamzin, Victor S., Lawson, David M., Lebedev, Andrey A., Leslie, Andrew G. W., Lohkamp, Bernhard, Long, Fei, Maly, Martin, McCoy, Airlie J., McNicholas, Stuart J., Medina, Ana, Millan, Claudia, Murray, James W., Murshudov, Garib N., Nicholls, Robert A., Noble, Martin E. M., Oeffner, Robert, Pannu, Navraj S., Parkhurst, James M., Pearce, Nicholas, Pereira, Joana, Perrakis, Anastassis, Powell, Harold R., Read, Randy J., Rigden, Daniel J., Rochira, William, Sammito, Massimo, Rodriguez, Filomeno Sanchez, Sheldrick, George M., Shelley, Kathryn L., Simkovic, Felix, Simpkin, Adam J., Skubak, Pavol, Sobolev, Egor, Steiner, Roberto A., Stevenson, Kyle, Tews, Ivo, Thomas, Jens M. H., Thorn, Andrea, Trivino Valls, Josep, Uski, Ville, Uson, Isabel, Vagin, Alexei, Velankar, Sameer, Vollmar, Melanie, Walden, Helen, Waterman, David, Wilson, Keith S., Winn, Martyn D., Winter, Graeme, Wojdyr, Marcin, Yamashita, Keitaro, Agirre, Jon, Atanasova, Mihaela, Bagdonas, Haroldas, Ballard, Charles B., Basle, Arnaud, Beilsten-Edmands, James, Borges, Rafael J., Brown, David G., Burgos-Marmol, J. Javier, Berrisford, John M., Bond, Paul S., Caballero, Iracema, Catapano, Lucrezia, Chojnowski, Grzegorz, Cook, Atlanta G., Cowtan, Kevin D., Croll, Tristan I., Debreczeni, Judit E., Devenish, Nicholas E., Dodson, Eleanor J., Drevon, Tarik R., Emsley, Paul, Evans, Gwyndaf, Evans, Phil R., Fando, Maria, Foadi, James, Fuentes-Montero, Luis, Garman, Elspeth F., Gerstel, Markus, Gildea, Richard J., Hatti, Kaushik, Hekkelman, Maarten L., Heuser, Philipp, Hoh, Soon Wen, Hough, Michael A., Jenkins, Huw T., Jimenez, Elisabet, Joosten, Robbie P., Keegan, Ronan M., Keep, Nicholas, Krissinel, Eugene B., Kolenko, Petr, Kovalevskiy, Oleg, Lamzin, Victor S., Lawson, David M., Lebedev, Andrey A., Leslie, Andrew G. W., Lohkamp, Bernhard, Long, Fei, Maly, Martin, McCoy, Airlie J., McNicholas, Stuart J., Medina, Ana, Millan, Claudia, Murray, James W., Murshudov, Garib N., Nicholls, Robert A., Noble, Martin E. M., Oeffner, Robert, Pannu, Navraj S., Parkhurst, James M., Pearce, Nicholas, Pereira, Joana, Perrakis, Anastassis, Powell, Harold R., Read, Randy J., Rigden, Daniel J., Rochira, William, Sammito, Massimo, Rodriguez, Filomeno Sanchez, Sheldrick, George M., Shelley, Kathryn L., Simkovic, Felix, Simpkin, Adam J., Skubak, Pavol, Sobolev, Egor, Steiner, Roberto A., Stevenson, Kyle, Tews, Ivo, Thomas, Jens M. H., Thorn, Andrea, Trivino Valls, Josep, Uski, Ville, Uson, Isabel, Vagin, Alexei, Velankar, Sameer, Vollmar, Melanie, Walden, Helen, Waterman, David, Wilson, Keith S., Winn, Martyn D., Winter, Graeme, Wojdyr, Marcin, and Yamashita, Keitaro

Abstract

The Collaborative Computational Project No. 4 (CCP4) is a UK-led international collective with a mission to develop, test, distribute and promote software for macromolecular crystallography. The CCP4 suite is a multiplatform collection of programs brought together by familiar execution routines, a set of common libraries and graphical interfaces. The CCP4 suite has experienced several considerable changes since its last reference article, involving new infrastructure, original programs and graphical interfaces. This article, which is intended as a general literature citation for the use of the CCP4 software suite in structure determination, will guide the reader through such transformations, offering a general overview of the new features and outlining future developments. As such, it aims to highlight the individual programs that comprise the suite and to provide the latest references to them for perusal by crystallographers around the world., Funding Agencies|Royal Society [UF160039, URF\R\221006, RGF/R1/181006]; UK Engineering and Physical Sciences Research Council (EPSRC) [EP/R513386/1]; BBSRC [BB/S007105/1, BB/S007083/1, BB/T012935/1, BB/S005099/1, BB/S007040/1]; European Union [871037]; CCP4; Medical Research Council as part of United Kingdom Research and Innovation; UK Research and Innovation: MRC [MC_UP_A025_1012]; European Molecular Biology Laboratory-European Bioinformatics Institute; German Federal Ministry of Education and Research [05K19WWA, 05K22GU5]; Deutsche Forschungsgemeinschaft [TH2135/2-1]; MEYS CR [CZ.02.1.01/0.0/0.0/16_019/0000778]; Czech Academy of Sciences [86652036]; CCP4/STFC [521862101]; iNEXT [653706]; iNEXT-Discovery [871037]; West-Life [675858]; EOSC-Life - Horizon 2020 program of the European Commission [824087]; Netherlands Organization for Scientific Research (NWO) [722.011.011, 723.013.003]; Dutch Cancer Society; Dutch Ministry of Health, Welfare and Sport; Wellcome Trust [209407/Z/17/Z]; Wellcome Trust SRF [200898]; Wellcome Centre for Cell Biology core grant [203149]; STFC-UK/CCP4: Agreement for the integration of methods into the CCP4 software distribution, ARCIMBOLDO_LOW; Spanish MICINN/AEI/FEDER/UE [PID2021-128751NB-I00]; NWOApplied Sciences and Engineering Domain; CCP4 [13337, 16219]; Rontgen Angstrom Cluster [349-2013-597]; SciLifeLab and Wallenberg Data Driven Life Science Program [KAW 2020.0239]; Dutch Research Council (NWO) [VI.Veni.192.143]; EMBO fellowship [ALTF 609-2017]; EPSRC [EP/G037280/1]; BBSRC Institute Strategic Programme Grants [BB/P012523/1, BB/P012574/1]; STFC/CCP4 [7920 S2 2020 007]

Published
2023
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26. The CCP4 suite: integrative software for macromolecular crystallography

Author

Royal Society (UK), Engineering and Physical Sciences Research Council (UK), European Commission, Medical Research Council (UK), Federal Ministry of Education and Research (Germany), German Research Foundation, Institute of Geology of the Czech Academy of Sciences, Netherlands Organization for Scientific Research, Dutch Cancer Society, Wellcome Trust, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Agirre, Jon, Atanasova, Mihaela, Bagdonas, Haroldas, Ballard, Charles B., Basle, A., Beilsten-Edmands, James, Borges, Rafael J., Brown, D. G., Burgos-Mármol, J. Javier, Berrisford, J., Bond, Paul S., Caballero, Iracema, Catapano, Lucrezia, Chojnowski, G., Cook, Atlanta G., Cowtan, K., Croll, Tristan I., Debreczeny, Judith E., Devenish, Nicholas E., Dodson, Eleanor J., Drevon, Tarik R., Emsley, Paul, Evans, Gwyndaf, Evans, Phil R., Fando, M., Foadi, James, Fuentes-Montero, Luis, Garman, Elspeth F., Gerstel, Markus, Gildea, Richard J., Hatti, Kaushik, Hekkelman, Maarten L., Heuser, Philipp, Wen Hoh, Soon, Hough, Michael A., Jenkins, Huw T., Jiménez, Elisabet, Joosten, Robbie P., Keegan, R. M., Keep, Nicholas, Krissinel, E., Kolenko, Petr, Kovalevskiy, O., Lamzin, V., Lawson, David M., Lebedev, Andrey, Leslie, A. G. W., Lohkamp, B., Long, Fei, Maly, Martin, McCoy, Airlie J., McNicholas, S., Medina, Ana, Millán, Claudia, Murray, James W., Murshudov, Garib, Nicholls, R. A., Noble, Martin E. M., Oeffner, Robert D., Pannu, Navraj S., Parkhurst, James M., Pearce, Nicholas, Pereira, Joana, Perrakis, Anastassis, Powell, Harold R., Read, Randy J., Rigden, D. J., Rochira, William, Sammito, Massimo, Sánchez Rodríguez, Filomeno, Sheldrick, George M., Shelley, Kathryn L., Simkovic, Felix, Simpkin, A. J., Skubák, P., Sobolev, Egor, Steiner, Roberto A., Stevenson, Kyle, Tews, I., Thomas, J. M. H., Thorn, Andrea, Triviño, Josep, Uski, V., Usón, Isabel, Vagin, Alexei, Velankar, Sameer, Vollmar, Melanie, Walden, Helen, Waterman, David, Wilson, Keith S., Winn, Martyn D., Winter, Graeme, Wojdyr, M., Yamashita, Keitaro, Royal Society (UK), Engineering and Physical Sciences Research Council (UK), European Commission, Medical Research Council (UK), Federal Ministry of Education and Research (Germany), German Research Foundation, Institute of Geology of the Czech Academy of Sciences, Netherlands Organization for Scientific Research, Dutch Cancer Society, Wellcome Trust, Ministerio de Ciencia e Innovación (España), Agencia Estatal de Investigación (España), Agirre, Jon, Atanasova, Mihaela, Bagdonas, Haroldas, Ballard, Charles B., Basle, A., Beilsten-Edmands, James, Borges, Rafael J., Brown, D. G., Burgos-Mármol, J. Javier, Berrisford, J., Bond, Paul S., Caballero, Iracema, Catapano, Lucrezia, Chojnowski, G., Cook, Atlanta G., Cowtan, K., Croll, Tristan I., Debreczeny, Judith E., Devenish, Nicholas E., Dodson, Eleanor J., Drevon, Tarik R., Emsley, Paul, Evans, Gwyndaf, Evans, Phil R., Fando, M., Foadi, James, Fuentes-Montero, Luis, Garman, Elspeth F., Gerstel, Markus, Gildea, Richard J., Hatti, Kaushik, Hekkelman, Maarten L., Heuser, Philipp, Wen Hoh, Soon, Hough, Michael A., Jenkins, Huw T., Jiménez, Elisabet, Joosten, Robbie P., Keegan, R. M., Keep, Nicholas, Krissinel, E., Kolenko, Petr, Kovalevskiy, O., Lamzin, V., Lawson, David M., Lebedev, Andrey, Leslie, A. G. W., Lohkamp, B., Long, Fei, Maly, Martin, McCoy, Airlie J., McNicholas, S., Medina, Ana, Millán, Claudia, Murray, James W., Murshudov, Garib, Nicholls, R. A., Noble, Martin E. M., Oeffner, Robert D., Pannu, Navraj S., Parkhurst, James M., Pearce, Nicholas, Pereira, Joana, Perrakis, Anastassis, Powell, Harold R., Read, Randy J., Rigden, D. J., Rochira, William, Sammito, Massimo, Sánchez Rodríguez, Filomeno, Sheldrick, George M., Shelley, Kathryn L., Simkovic, Felix, Simpkin, A. J., Skubák, P., Sobolev, Egor, Steiner, Roberto A., Stevenson, Kyle, Tews, I., Thomas, J. M. H., Thorn, Andrea, Triviño, Josep, Uski, V., Usón, Isabel, Vagin, Alexei, Velankar, Sameer, Vollmar, Melanie, Walden, Helen, Waterman, David, Wilson, Keith S., Winn, Martyn D., Winter, Graeme, Wojdyr, M., and Yamashita, Keitaro

Abstract

The Collaborative Computational Project No. 4 (CCP4) is a UK-led international collective with a mission to develop, test, distribute and promote software for macromolecular crystallography. The CCP4 suite is a multiplatform collection of programs brought together by familiar execution routines, a set of common libraries and graphical interfaces. The CCP4 suite has experienced several considerable changes since its last reference article, involving new infrastructure, original programs and graphical interfaces. This article, which is intended as a general literature citation for the use of the CCP4 software suite in structure determination, will guide the reader through such transformations, offering a general overview of the new features and outlining future developments. As such, it aims to highlight the individual programs that comprise the suite and to provide the latest references to them for perusal by crystallographers around the world.

Published
2023

31. DIALS as a toolkit

Author

Winter, Graeme, primary, Beilsten‐Edmands, James, additional, Devenish, Nicholas, additional, Gerstel, Markus, additional, Gildea, Richard J., additional, McDonagh, David, additional, Pascal, Elena, additional, Waterman, David G., additional, Williams, Benjamin H., additional, and Evans, Gwyndaf, additional

Published
2021
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33. Application of In Situ Diffraction in High-Throughput Structure Determination Platforms

Author

Aller, Pierre, primary, Sanchez-Weatherby, Juan, additional, Foadi, James, additional, Winter, Graeme, additional, Lobley, Carina M. C., additional, Axford, Danny, additional, Ashton, Alun W., additional, Bellini, Domenico, additional, Brandao-Neto, Jose, additional, Culurgioni, Simone, additional, Douangamath, Alice, additional, Duman, Ramona, additional, Evans, Gwyndaf, additional, Fisher, Stuart, additional, Flaig, Ralf, additional, Hall, David R., additional, Lukacik, Petra, additional, Mazzorana, Marco, additional, McAuley, Katherine E., additional, Mykhaylyk, Vitaliy, additional, Owen, Robin L., additional, Paterson, Neil G., additional, Romano, Pierpaolo, additional, Sandy, James, additional, Sorensen, Thomas, additional, von Delft, Frank, additional, Wagner, Armin, additional, Warren, Anna, additional, Williams, Mark, additional, Stuart, David I., additional, and Walsh, Martin A., additional

Published
2014
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46. DIALS as a toolkit.

Author

Winter, Graeme, Beilsten‐Edmands, James, Devenish, Nicholas, Gerstel, Markus, Gildea, Richard J., McDonagh, David, Pascal, Elena, Waterman, David G., Williams, Benjamin H., and Evans, Gwyndaf

Abstract

The DIALS software for the processing of X‐ray diffraction data is presented, with an emphasis on how the suite may be used as a toolkit for data processing. The description starts with an overview of the history and intent of the toolkit, usage as an automated system, command‐line use, and ultimately how new tools can be written using the API to perform bespoke analysis. Consideration is also made to the application of DIALS to techniques outside of macromolecular X‐ray crystallography. [ABSTRACT FROM AUTHOR]

Published
2022
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50. Machine learning for experimental phasing in MX

Author

Vollmar, Melanie, primary, Parkhurst, James, additional, Jaques, Dominic, additional, Elliott, Jenna, additional, Basle, Arnaud, additional, Murshudov, Garib, additional, Waterman, David, additional, Winn, Martyn, additional, and Evans, Gwyndaf, additional

Published
2019
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