Direct Phasing of Protein Crystals with Non-Crystallographic Symmetry

An iterative projection algorithm proposed previously for direct phasing of high-solvent-content protein crystals is extended to include non-crystallographic symmetry (NCS) averaging. For proper NCS, when the NCS axis is positioned, the molecular envelope can be automatically rebuilt. For improper NCS, when the NCS axis and the translation vector are known, the molecular envelope can also be automatically reconstructed. Some structures with a solvent content of around 50% could be directly solved using this ab initio phasing method. Trial calculations are described to illustrate the methodology. Real diffraction data are used and the calculated phases are good for automatic model building. The refinement of approximate NCS parameters is discussed.

CAB: a cyclic automatic model-building procedure

The program Buccaneer, a well known fast and efficient automatic model-building program, is also a tool for phase refinement: indeed, input phases are used to calculate electron-density maps that are interpreted in terms of a molecular model, from which new phase estimates may be obtained. This specific property is shared by all other automatic model-building programs and allows their cyclic use, as is usually performed in other phase-refinement methods (for example electron-density modification techniques). Buccaneer has been included in a cyclic procedure, called CAB, aimed at increasing the rate of success of Buccaneer and the quality of the molecular models provided. CAB has been tested on 81 protein structures that were solved via molecular-replacement, anomalous dispersion and ab initio methods. The corresponding phases were submitted to a phase-refinement process that synergically combines current phase-refinement techniques and out-of-mainstream refinement methods [Burla et al. (2017), Acta Cryst. D73, 877–888]. The phases thus obtained were used as input for CAB. The experimental results were compared with those obtained by the sole use of Buccaneer: it is shown that CAB improves the Buccaneer results, both in completeness and in accuracy.

Native SAD Structure Solution from Merohedrally Twinned Data

Up until now, comparatively few structures were solved by native SAD. Recent advances in multi crystal averaging [1] have shown that native SAD can be applied to an increasing number of cases. Though theoretically possible [2], successful structure solutions from twinned data have not been reported yet. Here, we report the structure solution of the human Centromere protein M from a merohedrally twinned crystal with a twinning fraction of 0.45 in the space group P3. The data were collected at the bending magnet beamline X06DA at the Swiss Light Source, which is equipped with the in-house developed multi-axis goniometer PRIGo and the PILATUS 2M detector. A highly redundant 2.2 Å dataset was collected in a number of different crystal orientations. A substructure solution could only be obtained after 50000 SHELXD [3] tries. Automatic model building after phasing and density modification resulted in a model with the majority of residues built correctly. We will present this particularly difficult case together with other more routine cases, all solved with the same experimental setup and at the beamline X06DA.

Protein phasing at non-atomic resolution by combining Patterson andVLDtechniques

Phasing proteins at non-atomic resolution is still a challenge for anyab initiomethod. A variety of algorithms [Patterson deconvolution, superposition techniques, a cross-correlation function (Cmap), theVLD(vive la difference) approach, the FF function, a nonlinear iterative peak-clipping algorithm (SNIP) for defining the background of a map and thefree lunchextrapolation method] have been combined to overcome the lack of experimental information at non-atomic resolution. The method has been applied to a large number of protein diffraction data sets with resolutions varying from atomic to 2.1 Å, with the condition that S or heavier atoms are present in the protein structure. The applications include the use ofARP/wARPto check the quality of the final electron-density maps in an objective way. The results show that resolution is still the maximum obstacle to protein phasing, but also suggest that the solution of protein structures at 2.1 Å resolution is a feasible, even if still an exceptional, task for the combined set of algorithms implemented in the phasing program. The approach described here is more efficient than the previously described procedures:e.g.the combined use of the algorithms mentioned above is frequently able to provide phases of sufficiently high quality to allow automatic model building. The method is implemented in the current version ofSIR2014.

Application of constrained real-space refinement of flexible molecular fragments to automatic model building of RNA structures

New methods have been developed for locating phosphate groups and nucleic acid bases in the electron density of RNA structures. These methods utilize a constrained real-space refinement of molecular fragments and a phased rotation–conformation–translation function. Real-space refinement has also contributed to the improvement of the bone/base method of RNA model building and to redesigning the method of building double helices in nucleic acid structures. This improvement is reflected in the increased accuracy of the model building and the ability to better distinguish between correct and false solutions. A program,RSR, was created, and the programsNUT,HELandDHLwere upgraded and organized into a program system, which is CCP4 oriented. Source codes will also be released.

Lysozyme contamination facilitates crystallization of a heterotrimeric cortactin–Arg–lysozyme complex

Crystallization of contaminating proteins is a frequently encountered problem for macromolecular crystallographers. In this study, an attempt was made to obtain a binary cocrystal structure of the SH3 domain of cortactin and a 17-residue peptide from the Arg nonreceptor tyrosine kinase encompassing a PxxPxxPxxP (PxxP1) motif. However, cocrystals could only be obtained in the presence of trace amounts of a contaminating protein. A structure solution obtained by molecular replacement followed byARP/wARPautomatic model building allowed a `sequence-by-crystallography' approach to discover that the contaminating protein was lysozyme. This 1.65 Å resolution crystal structure determination of a 1:1:1 heterotrimeric complex of Arg, cortactin and lysozyme thus provides an unusual `caveat emptor' warning of the dangers that underpurified proteins harbor for macromolecular crystallographers.