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The phenix.refine graphical interface

GUI overview
Configuration
Input files
Refinement settings
Creating restraints
Neutron crystallography
Atom selection
Identifying and editing TLS groups
Running phenix.refine
After refinement
Frequently Asked Questions
Acknowledgements
References

GUI overview

The graphical interface for phenix.refine runs the unmodified command-line version; default settings are unchanged. All parameters should be configurable through the GUI, although some of these (such as NCS restraint groups) are handled in a non-standard way. This document describes the behavior of the GUI only; see the phenix.refine documentation for details on specific parameters and methods.

At present the GUI has the following capabilities:

  • automatic extraction of parameters from PDB and reflection files
  • detection of unknown ligands, and generation of restraint files
  • graphical mirroring and picking of any atom selection
  • project-specific default settings and restraints
  • NCS restraint group detection and editing tool
  • TLS group detection and editing tool
  • real-time visualization of current model and maps during refinement
  • model validation using programs from the Molprobity server
  • graphical comparison of structure quality measures
  • printable plots of final statistics

Configuration

Because phenix.refine currently has nearly 500 distinct parameters, many of which rarely need changing, and the window controls are mostly created automatically, advanced settings are hidden by default. The "user level" may be set within each window, or set globally in the Preferences. The most important parameters (input and output files, strategy, additional procedures such as solvent updating and simulated annealing) are shown in the main window.

Input files

The first tab contains settings for input files, which can be added by clicking the "+" button below the file list, or by dragging files into the list control and releasing the mouse button. Up to five different reflection files may be used (X-ray data, X-ray R-free flags, neutron data, neutron R-free flags, and experimental phases), but in most cases all data will be in a single file. Any number of PDB files for the starting model may be added; these will be combined internally. You may also specify a reference model for additional restraints (see below). Other supported file formats are CIF (restraint) files for non-standard ligands, and phenix.refine parameter files.

images/refine_gui_files.png

The GUI will attempt to guess the purpose of PDB and X-ray files, but you may change this by right-clicking on the "Data type" field associated with the file and selecting an option from a drop-down menu, or select the file and click the button labeled "Modify file data type".

If your reflection and/or PDB files have the appropriate information on crystal symmetry and data labels, these parameters will be extracted automatically. Appropriate column labels for reflection files will also be added to the drop-down menus; by default, anomalous intensities (I+/I-) will be used if present, but you may also use merged data and/or amplitudes. The R-free flags are optional, since phenix.refine will add them automatically if none are present, but once flags have been used in refinement (including the automated building in AutoSol or AutoBuild) the same set should always be used.

Refinement settings

The second tab contains options for the refinement protocol. Many of these controls will open additional dialog windows in response to mouse clicks or file selection. In many cases, you can open these windows on demand by right-clicking on the appropriate control (for instance, right-clicking the "Rigid body" strategy button will show the atom selection controls for defining rigid groups). All other parameters can be found in the Settings menu.

images/refine_gui_options.png

Most of the refinement options presented on this tab essentially fall into three categories:

  • Model parameterization. This determines which properties of the model will be refined, and how they are grouped. Options include coordinate refinement (individually against reciprocal-space data or real-space maps; or as rigid-body groups against reciprocal-space data); B-factor or ADP (atomic displacement parameter) refinement, with several options for grouping and isotropic versus anisotropic; atomic occupancies (i.e. the fraction of the time the atom is present in the refined position in the crystal); and anomalous groups.
  • Optimization target. This defines the function to be minimized; by default this is at least the agreement of the model amplitudes with the experimentally measured amplitudes. For almost all macromolecular structures restraints on covalent geometry and the B-factors of nearby atoms will also be necessary, and a variety of customizations of the geometry restraints are possible.
  • Optimization method. The standard optimization method used in phenix.refine and similar programs is gradient-driven minimization, but other options are available. These often have a significantly wider radius of convergence, but at the cost of increased runtime.

The default options have been chosen to work well for partially refined structures at moderate resolutions, which comprise the majority of structures in the Protein Data Bank. However, at significantly higher or lower resolution, or for structures at the early or final stages of refinement, additional options may be necessary or beneficial.

The first set of controls determines the parameterization of the model and the attributes to be refined. By default, the Individual Sites, Individual ADPs (B-factors), and Occupancies strategies are selected, since these are usually appropriate at a wide range of resolutions and refinement stages. All strategies have associated atom selections which control what parts of the model are refined. A brief summary follows; note that the resolution limits specified are approximate only, and in practice may vary widely depending on model quality, data quality, and observation-to-parameters ratio.

  • XYZ coordinates is standard Cartesian refinement of model geometry and agreement with X-ray data. It is almost always appropriate, but at low-resolution (typically 3.5A or worse), additional restraints (NCS, reference model, etc.) are often necessary to prevent overfitting.
  • Real-space is similar to the Individual Sites strategy, but refines against the map instead of in reciprocal space. This is generally not useful as a global strategy, but real-space refinement is used in other parts of phenix.refine for local optimization.
  • Rigid-body refines the position of large, user-defined regions of the model without changing geometry. It is typically used immediately after molecular replacement, when the R-factors are usually very high, and at very low resolutions (4.5A or worse). If both rigid-body and individual sites refinement are checked (recommended), the rigid-body step will be done first, in the first cycle of refinement.
  • Individual B-factors is atomic B-factor refinement, and is always appropriate except at low resolution (3.5A or worse). Whether atoms are treated as isotropic or anisotropic is defined separately (see below).
  • Group B-factors refines B-factors for multiple atoms at a time, most often single residues either as a whole or divided into mainchain and sidechain. (Larger user-defined groups are also allowed.) This is usually only necessary at low resolution (3.5A or worse).
  • TLS parameters refines anisotropic displacements for large groups of atoms, typically individual domains or chains. Because this introduces only ten parameters for each group, and relatively few groups are used, it is appropriate at almost any resolution unless individual anisotropic B-factors are refined. (See note about B-factors below.) It is important to provide accurate atom selections here; the TLSMD server may be helpful in determining these automatically.
  • Occupancies refines atomic occupancies. This is appropriate at high resolution (usually 1.7A or better) where alternate conformations are often present, and in situations where a ligand, ion, or solvent atom is not bound in every unit cell. By default, it will only be performed for atoms with partial occupancies. Groupings are determined automatically if possible, but you may specify them manually. (This is especially important if you have complex relationships betweeen alternate conformations in different parts of the model.)
  • Anomalous groups refines the anomalous coefficients f' and f'' for anomalously scattering atoms such as Se or heavy metals; it is only appropriate if you have anomalous data (I+/I- or F+/F-).

The refinement protocol can be further modified by manipulating various restraints (structural and otherwise):

  • NCS restraints preserves non-crystallographic symmetry between identical copies of a molecule. These can be automatically detected or defined manually. If NCS is present in the crystal, these restraints are usually appropriate at intermediate resolution (2.2-2.7A or worse) and essential at lower resolutions.
  • Find NCS restraints automatically instructs phenix.refine to run a built-in NCS identification protocol at the start of refinement; it is ignored if NCS restraints are not activated. Note that this should be disabled if you have already defined NCS groups in the GUI! This setting only affects the global NCS restraints; for the torsion restraints, phenix.refine will always use automatic annotation unless the user supplies restraint groups (which will not be overwritten).
  • Reference model restraints use the dihedral angles of an existing structure as restraints on the input model conformation, for instance, refining a low-resolution structure of a molecule whose high-resolution structure is available. This is most useful at low resolutions (usually worse than 3.0A).
  • Secondary structure restraints add distance restraints for hydrogen bonds in alpha helices, beta sheets, and Watson-Crick base pairs. These are helpful for maintaining correct geometry at lower resolutions (2.5A or worse). Suitable atom selections will be detected automatically but you may also specify them manually.
  • Use experimental phases uses the experimental phase distributions (Hendrickson-Lattman coefficients) from phasing programs such as AutoSol as additional restraints during refinement. This is usually helpful if these phases are available, but only if the same data were used for both phasing and refinement.

Several other options are available for the types of optimization used; these typically apply globally, except as noted.

  • Automatically add hydrogens to model runs phenix.ready_set to add hydrogen atoms (or deuteriums, if performing neutron crystallography) where appropriate. This usually only affects the R-factors at high resolution, but can be very helpful for improving geometry at any resolution. We recommend using explicit hydrogens on protein, nucleic acid, and ligand molecules throughout refinement. (We do not reocmmend adding hydrogens to waters unless you have exceptionally high resolution.) Hydrogen atoms will still be defined using the "riding" model unless otherwise requested, so they do not add parameters during refinement. (Note that this option can be left on if you already have hydrogen atoms in place and are refining as "riding"; if you are refining against neutron data and/or allowing hydrogen atoms to refine individually, you should uncheck the box, as it will otherwise replace the existing atoms.)
  • Update waters automatically adds and removes solvent atoms as necessary; this is usually appropriate at any resolution where water molecules are visible in density (usually 2.5A or better).
  • Simulated annealing uses molecular dynamics with an extra X-ray term as an additional optimization method. It is very helpful for removing phase bias and overcoming energy barriers, and often yields a significant improvement over simple minimization early in refinement. The main disadvantage is speed. Two types of parameterization are available, Cartesian and torsion angles; the latter is more suitable for low resolution.
  • Fix bad sidechain rotamers adjusts sidechain torsion angles to agree with the distribution of conformations in the PDB and the electron density, if possible, and performs local real-space refinement to optimize the fit. It is most useful at intermediate-to-high resolution (2.5A or better), where sidechain density is clearly visible.
  • Automatically correct N/Q/H errors uses the program Reduce to flip backwards sidechains, which appear symmetric when explicit hydrogens are not present. This is almost always a good idea and adds very little to overall run time.
  • Model interatomic scattering adds the contribution of electrons in atomic bonds to the model-derived X-ray amplitudes; it is only appropriate at ultra-high resolution (at least 0.9A).
  • Target function describes the calculation of model-based X-ray terms; "ML" means "Maximum likelihood" and is usually appropriate; "MLHL" use used when experimental phase restraints are added; "ML-SAD" is not suitable for general use. The least-squares (LS) target is only useful for twinned refinement or very small datasets (it will be used automatically if necessary).
  • Scattering table determines how atomic scattering is modeled; this is almost always either "n_gaussian" for standard X-ray refinement, or "neutron" (see below).

The output tab allows you to change the destination directory and modify the default map coefficients and/or map files written out. By default, an MTZ file containing 2mFo-DFc and mFo-DFc map coefficients will be generated.

images/refine_gui_output.png

Creating restraints

If the PDB file contains ligands or prosthetic groups that are not part of the limited monomer library distributed with PHENIX, a warning message will be displayed when the file is loaded. The necessary restraints must be generated by phenix.elbow in order for refinement to proceed. To start this process, click the ReadySet button in the toolbar or choose "Prepare structure and restraints" from the Utilities menu. This will launch a dialog for running phenix.ready_set, a simple utility for preparing structures for phenix.refine.

images/ready_set.png

Generating the restraints will take between 30 seconds and several minutes, depending on computer speed and the size of the ligand. When ReadySet is finished, another window will be displayed summarizing the results. If a project directory is defined, these can be saved for future runs and will be automatically loaded into the GUI when launched.

If your input model does not contain hydrogen atoms and you would like to use them in refinement, this can also be done via the ReadySet dialog, or by clicking the box labeled "Automatically add hydrogens to model" in the main window.

Note: ReadySet look in the PDB's Chemical Components Database (distributed with PHENIX) for the three-letter code of any unknown ligands it finds, and use the database information to generate restraints. For non-standard ligands, users are advised to run eLBOW with a SMILES string or equivalent source of information. Generating robust geometry restraints from a PDB file alone is problematic, because the coordinates are not a reliable guide to molecular topology, chirality, etc.

Neutron crystallography

phenix.refine can perform refinement using either X-ray data, neutron diffraction data, or both. You can change the type of data contained in a reflections file by right-clicking on the "Data type" field in the file list.

At present, phenix.refine always requires that you define an X-ray dataset; this constraint will be removed in future versions. If you are performing refinement against neutron data alone, you must treat the reflections as if they were X-ray data. All of the data options remain the same, and will be extracted automatically. You must change the scattering table to "neutron" in the "Refinement settings" tabe. If you are doing joint X-ray/neutron refinement, you should leave the scattering table set to the default, and specify one reflections file as neutron data. Parameters for neutron data are not chosen automatically; once you have specified a neutron reflections file, click the "Neutron data. . ." button to select the column labels for the data and test set.

If you need to add hydrogens and deuteriums to your model before running phenix.refine, you can either run ReadySet prior to refinement, or change the options for automatic hydrogen addition. If your model already includes these atoms, you may wish to turn automatic hydrogen addition off to ensure that existing atom types are left in place.

Atom selection

The atom-selection syntax used by PHENIX is described in the phenix.refine manual. In the GUI, any valid atom selection can be visualized if you have a suitable graphics card and have already loaded a PDB file with valid symmetry information. The graphics window can be opened by clicking the "View/pick" button next to any atom selection field. Depending on the size of your structure, it may take several seconds for PHENIX to determine the atomic connectivity. The current selection, if any, will be highlighted:

images/gui_atom_selection.png

The Select atoms button opens a window that allows you to type in selections and immediately visualize the results, including the number of atoms selected. On mice with at least two buttons, clicking on an atom with the right button will open a menu for selecting residue ranges or chains. However, we recommend that you learn the selection syntax, as it is much more flexible than mouse controls. Selections made in the graphics window will be sent automatically to the appropriate control.

Once this window is open, it does not need to be closed; clicking a different "View/pick" button will transfer control of the display. (On Linux, you will first need to open the Actions menu and click Restore parent window to transfer mouse and keyboard controls back to the configuration dialog.)

Identifying and editing TLS groups

PHENIX includes a tool (phenix.find_tls_groups) for fast identification of appropriate TLS groupings based on isotropic ADPs in a PDB file. This is integrated into the phenix.refine GUI, and can be accessed from the TLS group editor (the "TLS" button on the toolbar, also available on the "Refinement settings" configuration tab). The editor is essentially just an atom selection list control similar to others in PHENIX:

images/tls_editor.png

Clicking the "Find TLS groups" button will launch the identification program, which typically takes a few seconds to a few minutes to run depending on the size of the structure and the number of processors available. All CPU cores will be used by default, but this can be adjusted using the control near the bottom of the window. You may alternately specify TLS groups manually, or upload a file from the TLSMD server. Once you have the desired groups input, close the editor by clicking either of the buttons at the upper or lower left of the window.

Running phenix.refine

Each time phenix.refine is run from the GUI, a new folder is created (in the current output directory) named Refine_X, where X is an integer corresponding to the job ID. This directory will contain all temporary and output files created during the course of the run. Existing folders will not be overwritten. All output files will be displayed in the GUI in the results tab.

Once you are done configuring refinement, switch to the Run tab in the main window and start the process by clicking the "Run" button. The log output will appear at the bottom of the new tab:

images/refine_run.png

Statistics will be continually updated; any that appear to be outliers (e.g. excessively high R-factors) will be highlighted in red. If an error occurs during refinement, a message box will pop up and the process will be halted.

After refinement

Once the refinement is complete, additional tabs will appear. The first of these is a summary page displaying the final statistics, a list of output files, buttons for opening the refined structure in Coot and PyMOL, and links to assorted graphs. Note that the output files may include one ending in "_data.mtz"; if you did not specify R-free flags as part of the input, the new file will contain the automatically generated flags, and should be re-used in future runs.

images/refine_summary.png

Additional tabs contain the full validation summary, which is essentially identical to the standalone validation program.

Frequently Asked Questions

Questions not specific to the graphical interface are answered here.

  • I have a parameter file that I want to use; how do I load this in the GUI? You have two options: add it to the list of input files in the "Input data" tab, or select "Load parameter file" from the File menu. If you do the latter, the parameters will be immediately incorporated into the working parameters and the GUI will be redrawn to reflect any changes. The disadvantage of this method is that there is no easy way to revert to the previous settings. Adding the file to the input list will postpone parsing until the program is run, so you will not be able to edit the parameters graphically, but you may remove the file at any time.

Acknowledgements

phenix.refine was primarily written by Pavel Afonine and Ralf Grosse-Kunstleve, with additional contributions from Peter Zwart, Jeff Headd, Nat Echols, Nigel Moriarty, and Tom Terwilliger. The electron-density isosurface and anisotropic ellipsoid code in the CCTBX (used in the internal graphics viewer) was contributed by Luc Bourhis.

References

  • phenix.refine : Afonine, P.V., Grosse-Kunstleve, R.W. & Adams, P.D. (2005). CCP4 Newsl. 42, contribution 8.
  • Molprobity : Davis IW, Leaver-Fay A, Chen VB, Block JN, Kapral GJ, Wang X, Murray LW, Arendall WB 3rd, Snoeyink J, Richardson JS, Richardson DC. MolProbity: all-atom contacts and structure validation for proteins and nucleic acids. Nucleic Acids Res. 2007 35:W375-83.