Coot: Difference between revisions

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[[Image:Coot-with-ATP-vector.png|400px|thumb|right]]
[[Image:Coot-with-ATP-vector.png|25%|thumb|right]]
__TOC__
Coot is a graphics program for building, refining and analysing macromolecular models obtained with crystallographic procedures.
 
There is a [http://www2.mrc-lmb.cam.ac.uk/Personal/pemsley/coot/ homepage] with extensive [http://www2.mrc-lmb.cam.ac.uk/Personal/pemsley/coot/web/docs/ documentation]. The program may be downloaded for Linux and Windows computers from the [http://www2.mrc-lmb.cam.ac.uk/Personal/pemsley/coot/binaries/pre-release/ primary server]. The license of Coot is GNU GPL.


=Installing Coot=
=Installing Coot=
==Installing Coot on OS X==
==Installing Coot on OS X==
OS X install packages for nightly builds that work on 10.8.X and 10.9.X are available here: [http://scottlab.ucsc.edu/~wgscott/xtal/wiki/index.php/Stand-Alone_Coot Coot OS X package installers]
Please refer to the [http://sage.ucsc.edu/xtal/wiki/index.php/Installing_Coot_on_OS_X Installing Coot on OS X] page
Please refer to the [http://sage.ucsc.edu/xtal/wiki/index.php/Installing_Coot_on_OS_X Installing Coot on OS X] page


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This is the recommended way for those who do not want to delve into the mysteries of compiling and linking a great but complex piece of software. Read the (somewhat outdated, it seems) [http://www.ysbl.york.ac.uk/%7Eemsley/coot/coot-faq.html Coot FAQ] to find "Additional Notes" for your operating system.
This is the recommended way for those who do not want to delve into the mysteries of compiling and linking a great but complex piece of software. Read the (somewhat outdated, it seems) [http://www.ysbl.york.ac.uk/%7Eemsley/coot/coot-faq.html Coot FAQ] to find "Additional Notes" for your operating system.


In short, just go to http://www.ysbl.york.ac.uk/~emsley/software/binaries/nightlies/pre-release/ and pick a suitable binary, e.g.
In short, just go to http://www.ysbl.york.ac.uk/~emsley/software/binaries/nightlies/pre-release/ (a mirror is at ftp://turn5.biologie.uni-konstanz.de/coot/software/binaries/nightlies/pre-release/ ) and pick a suitable binary, e.g.
coot-0.5-pre-1-revision-1003-binary-Linux-i386-fedora-5.tar.gz for a Red Hat Enterprise Linux 5 or CentOS-5 system (Fedora 6 corresponds to RHEL5, thus Fedora 5 binaries are OK). If you prefer a "stable" binary, these are at http://www.ysbl.york.ac.uk/~emsley/software/binaries/stable/.
coot-0.5-pre-1-revision-1003-binary-Linux-i386-fedora-5.tar.gz for a Red Hat Enterprise Linux 5 or CentOS-5 system (Fedora 6 corresponds to RHEL5, thus Fedora 5 binaries are OK). If you prefer a "stable" binary, these are at http://www.ysbl.york.ac.uk/~emsley/software/binaries/stable/.


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and install the library, again using yum (assuming yum is available in your distribution, otherwise use apt or whatever is there for this purpose).
and install the library, again using yum (assuming yum is available in your distribution, otherwise use apt or whatever is there for this purpose).


=== Instalation on Debian/Ubuntu from debian archive files ===
==== Example: installing a 64bit nightly CentOS5 binary build on 64bit SL6.1 ====
As an alternative, you might wish to exploit the debain dpkg/apt/synaptic package management system on Ubuntu and other Debian linux distributions using (unofficial)  
First of all, SL (Scientific Linux) is a derivative of RHEL, as is CentOS. So all three OSs behave exactly the same.
[http://diablo.ucsc.edu/~wgscott/debian/coot_hardy/ pre-compiled debian packages for coot and its dependencies]. (These will be discontinued when official packages become available.)
The binaries with "x86_64" binaries are for 64bit systems; the "i386" binaries are for 32bit systems. Since my notebook is 64bits ("uname -a" reports "x86_64" more than once), I download coot-0.7-pre-1-revision-3999-binary-Linux-x86_64-centos-5-python-gtk2.tar.gz. As root, I "cd /usr/local/src" and un-tar. Next, have to find out which libraries are missing. This can be achieved by (''note the use of LD_LIBRARY_PATH in the second command - do not permanently modify LD_LIBRARY_PATH !''):
[root@localhost]# cd coot-Linux-x86_64-centos-5-gtk2-python
[root@localhost]# LD_LIBRARY_PATH=lib ldd bin/coot-real | grep found
libssl.so.6 => not found
libcrypto.so.6 => not found
libssl.so.6 => not found
  libcrypto.so.6 => not found
 
So only two libraries are missing! Either they can be installed using yum, or they are already available, but have a higher version.
* First possibility: find out about installable RPM packages (preferred way):


To do so, simply download the deb files and install with the command
[root@localhost  src]# yum provides libssl.so.6 libcrypto.so.6
Loaded plugins: refresh-packagekit
openssl098e-0.9.8e-17.el6.i686 : A compatibility version of a general
                                : cryptography and TLS library
Repo        : sl
Matched from:
Other      : libssl.so.6
... (the package is repeated, and libcrypto.so.6 is also mentioned)
: Now don't just install the openssl098e-0.9.8e-17.el6.i686 and its dependencies - it is a 32bit library (the name ends with ".i686")! Installing it does not solve the problem - we need a 64bit library. Unfortunately "yum provides" does not tell us about the 64bit library (is that a yum bug?). By specifying just the package name (openssl098e.x86_64 would also work, and would avoid any 32bit package)
yum install openssl098e
: we install both libssl.so.6 and libcrypto.so.6 in their 64bit versions - done!


  sudo dpkg -i *.deb
* Second possibility: find out if the system already has a higher version of the two libraries:
[root@localhost locate libssl.so
/usr/lib64/.libssl.so.1.0.0.hmac
/usr/lib64/.libssl.so.10.hmac
/usr/lib64/libssl.so
/usr/lib64/libssl.so.1.0.0
  /usr/lib64/libssl.so.10


dpkg will complain if a dependency is missing rather than install a broken program.
: So the answer is: there is /usr/lib64/libssl.so which is at version 10, which is compatible with the version we need (6). For libcrypto.so the same is true. So just
cd coot-Linux-x86_64-centos-5-gtk2-python/lib/
ln -s /usr/lib64/libssl.so libssl.so.6
ln -s /usr/lib64/libcrypto.so libcrypto.so.6
: The way these symlinks are made they would even work if RHEL upgrades libssl or libcrypto to higher versions. Works for me.


=== Converting to rpm packages ===
Final step (this does not need to be repeated for a new coot version): create /usr/local/bin/coot with
You can convert any debian package file into an rpm file using the program ''alien''. I have done this and have made the [http://diablo.ucsc.edu/~wgscott/debian/rpm/coot/ resulting packages] available.
#!/bin/csh -f
setenv LANG C
  exec /usr/local/src/coot-Linux-x86_64-centos-5-gtk2-python/bin/coot $*
and make it executable with
chmod a+x /usr/local/bin/coot


=== Installation from source code via autobuild scripts ===
=== Installation from source code via autobuild scripts ===
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===Controls===
===Controls===


[[Image:Coot-controls-small.png|200px]]
[[Image:Coot-controls-small.png]]
 
 
===Stereographic Display ===
 
Coot has several options for stereographic display, ranging from cross-eyed and wall-eyed split-screen stereo, to hardware-stereo modes that work with CRT systems and most recently the new Zalman 3-D LCD monitor.
 
==== Side-by-Side ====
 
Either cross-eyed or wall-eyed split-screen stereo mode can be invoked using the "Stereo" menu item under "Draw", as is shown in the image below:
 
[[Image:stereo_menu_screenshot.png]]
 
==== Hardware Stereo ====
 
Similarly, hardware stereo can be invoked (assuming you have the CRT, correct graphics card, emitter, etc) using the same menu item, by selecting "Hardware Stereo".
 
[[Image:a_zalman_zm_m220w__2d_35_pic.jpg|150px|thumb|right|3d lcd]]
 
==== Zalman Stereo ====
 
The first viable LCD monitor for stereographics display is made by Zalman and costs about $300:  [http://www.zalman.co.kr/eng/product/product_read.asp?idx=219 Zalman ZM-M220W]
 
The attributes for this monitor have been tested and [http://pymol.org/zalman/ described rather extensively by Warren DeLano] on the PyMOL site. Please read it for important details and suggested purchasing sources.
 
The [[coot zalman]] page describes specifically how to get this to work with coot on Mac OS X, but the instructions should be generalizable to linux and Windoze.
 
Note that the stereo effect is very sensitive to the vertical position of your eyes relative to the screen: if you don't see stereo, try tilting the screen.
 
=== Stereo: left/right (and front/back) interchanged? ===
 
Establish an additional toolbutton "swap stereo":
 
Main Toolbar -> right mouse click-> Manage buttons-> select Swap Stereo
 
Or for the script minded:
 
switch_stereo_sides()
 
This will toggle the stereo images left and right.


===External Links===
===External Links===
====[http://www.ysbl.york.ac.uk/~emsley/coot/doc/user-manual.html On-line User Manual]====
====[http://www.ysbl.york.ac.uk/~emsley/coot/doc/user-manual.html On-line User Manual]====
====[http://www.ysbl.york.ac.uk/~emsley/coot/ Coot's home page]====
====[http://www.ysbl.york.ac.uk/~emsley/coot/ Coot's home page]====
====[http://www.mail-archive.com/coot@jiscmail.ac.uk/ Current mailing list archives]====
====[http://www.ysbl.york.ac.uk/~emsley/coot/mbox/ Mailing list archives: (no longer) current]====
====[http://www.ysbl.york.ac.uk/~emsley/coot/mbox/ Mailing list archives: (no longer) current]====


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The Powermate dial can be used with coot.  One could just assign the rotations to +/-y keys and be done with it, but this script gives you a way of having positive and negative rotations in all three cartesian directions.  The F1 key is mapped to positive rotation, the F2 key to negative rotation, and the F3 key permits you to toggle through x, y, and z, on successive key presses.  I then map F1 and F2 into the ordinary rotations on the powermate (using send key equivalents) and then I map F3 into the single click on the dial, making it easy to toggle through x, y and z.  The press-and-rotate options remain available; I map these into scroll up and down, and put them on the slowest response setting, which makes contouring density easier to control than it is from my mouse scroll wheel.
The Powermate dial can be used with coot.  One could just assign the rotations to +/-y keys and be done with it, but this script gives you a way of having positive and negative rotations in all three cartesian directions.  The F1 key is mapped to positive rotation, the F2 key to negative rotation, and the F3 key permits you to toggle through x, y, and z, on successive key presses.  I then map F1 and F2 into the ordinary rotations on the powermate (using send key equivalents) and then I map F3 into the single click on the dial, making it easy to toggle through x, y and z.  The press-and-rotate options remain available; I map these into scroll up and down, and put them on the slowest response setting, which makes contouring density easier to control than it is from my mouse scroll wheel.


  [[powermate-coot.scm]]
  [http://code.google.com/p/zsh-templates-osx/source/browse/trunk/Library/init/zsh/zshrc.d/local-functions/etc/dotfiles/cootrc_powermate_and_keybindings.scm powermate-coot.scm]


===Example Scheme Script 7: Applying arbitrary value to "B" factor column ===
===Example Scheme Script 7: Applying arbitrary value to "B" factor column ===
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[[bernhards_key_bindings_for_coot.py]]
[[bernhards_key_bindings_for_coot.py]]
===Example 2: More key bindings (inspired by the Coot BB)===
For (re-)colouring maps blue:
[[blueify_map_keys.py]]
To (re-)colour coordinate molecules yellow:
[[yellowify_molecule_keys.py]]
===Example 3: NCS Rotamer differences===
To show NCS where NCS-related side-chains have different rotamers:
[[ncs_rotamer_differences.py]]
===Example 4: Morphing GUI===
GUI to easily access jiggle fit and morphing (currently pre-release Coot required, may be moved into trunk):
[[morph_residues_gui.py]]
===Example 5: Ensemble GUI===
GUI to allow navigation through structural ensembles as obtained e.g. from ensemble refinement:
[[ensemble_plugin.py]]


==Python to Scheme and return==
==Python to Scheme and return==
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Here some simple rules how to translate from Scheme to Python. To translate the other way around, i.e. Python to Scheme, just turn the rules around:
Here some simple rules how to translate from Scheme to Python. To translate the other way around, i.e. Python to Scheme, just turn the rules around:


# replace all '-' with '_' (except in equation when you need arithmetic '-' minus signs)
# Replace all '-' with '_' (except in equation when you need arithmetic '-' minus signs)
# move the brackets around the argument(s)
# Move the brackets around the argument(s)
# separate multiple arguments by commas rather than spaces
# Separate multiple arguments by commas rather than spaces
# replace 'define' for functions with 'def' and for assignments with an '='
# Replace 'define' with 'def' for functions and with '=' for assignments
# Make sure to use indentation for the function content [Python is indentation sensitive] and a ':' after the function definition.
# Make sure to use indentation for the function content [Python is indentation sensitive] and a ':' after the function definition.
Some additional/advanced(?) rules:
# #f -> False
# #t -> True
# (set! variable value) -> variable=value


====A simple example====
====A simple example====
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Edit a file called ~/.gtkrc-2.0 and put into it the following line:
Edit a file called ~/.gtkrc-2.0 and put into it the following line:


  include "/usr/share/themes/Glossy_P/gtk-2.0/gtkrc"
  include "/usr/share/themes/Glossy\ P/gtk-2.0/gtkrc"
 
Alternatively, if you use gnome or xfce4, you can open the theme manager and just make it open the downloaded Glossy_P tarball, and it should add this as a theme.


=Assorted questions and answers (from the mailinglist)=
=Assorted questions and answers (from the mailinglist)=


Q:  
It should be noted that the answers ("A") are from Paul Emsley himself (and were maybe slightly edited).
I am sure this exists somewhere through scripting in COOT, but can I apply NCS edits to only a subset of NCS copies? In  other words, can I tell coot which are NCS related chains, and which aren't.  I am working on this nightmarish case of asymmetrical homodimers, where the sequences are very similar, but the structures are not, so I need to tell coot which chains are actually related to each other.
 
==Coot development==
 
Q: How can I get involved with Coot development?
 
A: Join the [[Coot Janitors]] project. This is a project to get new people involved in improving Coot, by acting as a clearing house for simple tasks which need doing, and providing documentation for doing them.
 
 
== Get rid of the "fix nomenclature" check ==
Q: Is it possible to deactivate the nomenclature errors check? Sometimes this check is not very useful and it becomes rather annoying when one has several molecules loaded only wants to look at the structures...
 
A: Add to your ~/.coot or whatever:
(set-nomenclature-errors-on-read "ignore")
 
 
==NCS edits==
Q: I am sure this exists somewhere through scripting in COOT, but can I apply NCS edits to only a subset of NCS copies? In  other words, can I tell coot which are NCS related chains, and which aren't.  I am working on this nightmarish case of asymmetrical homodimers, where the sequences are very similar, but the structures are not, so I need to tell coot which chains are actually related to each other.


A: Nightmare. If you have a recent [1632 or later for the scheme version, 1646 for the python version] Coot, you can do this:
A: Nightmare. If you have a recent [1632 or later for the scheme version, 1646 for the python version] Coot, you can do this:
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There is also a GUI to activate this feature under Extensions -> NCS.
There is also a GUI to activate this feature under Extensions -> NCS.


----
==SHELXL==
Description of problematic situation: I am using [[SHELXL]] to refine my 1.2 Å data and I am refining the hydrogen atoms. Subsequent rebuilding in coot is difficult though since hydrogens often does not "follow" when you do side chain rebuilding. For the moment I have quit transfering hydrogens to coot and add the hydrogens every refinement cycle, though it would be good I think if I could see them in coot without bothering about wrong positions. So these are my specific questions:
Description of problematic situation: I am using [[SHELXL]] to refine my 1.2 Å data and I am refining the hydrogen atoms. Subsequent rebuilding in coot is difficult though since hydrogens often does not "follow" when you do side chain rebuilding. For the moment I have quit transfering hydrogens to coot and add the hydrogens every refinement cycle, though it would be good I think if I could see them in coot without bothering about wrong positions. So these are my specific questions:


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A: Yes this fails.  Hydrogens are named differently to SHELX hydrogens.  In principal this could be made to work if the dictionary was reworked to use SHELX hydrogen names.  This would also fix the chi angles problem too of course.
A: Yes this fails.  Hydrogens are named differently to SHELX hydrogens.  In principal this could be made to work if the dictionary was reworked to use SHELX hydrogen names.  This would also fix the chi angles problem too of course.


----
Specific Q3: I am unable to open the output pdb file from ShelXL in Coot.
 
A: Well, it's hard to know what's the problem without details - the console should say something. But when handling the output of shelxl, I suggest you read the .res file rather than the pdb, then the subsequent .ins file contains lots of "header" information.
 
Another answer to questions 1+2 is to rename the hydrogen atoms in the shelxl res-file to match the mmCIF dictionaries used by Coot. This only needs to be done once as shelxl does not modify these names. Except for a few manual editions, the renaming can be done semi-automatically using regular expressions (replacing A->1, B->2, etc).


Concerning question 3, the Coot -> Extensions -> Module -> SHELXL menu entry works really well now. It reads in all relevant shelxl files and provides a menu highlighting the problematic areas in the model.
==Image quality on NVidia cards==
Q: improvement of image quality on machines with NVidia cards?
Q: improvement of image quality on machines with NVidia cards?


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I don't know if this works on other/newer systems, but it works for me on my oldish GeForce 6600. (Of course the FPS takes a hit.)  
I don't know if this works on other/newer systems, but it works for me on my oldish GeForce 6600. (Of course the FPS takes a hit.)  


----
 
It should be noted that the answers ("A") are from Paul Emsley himself (and were maybe slightly edited).
==Setting default to show symmetry-related molecules==
Q: How to set the default to display symmetry related molecules?
 
A: Add (set-show-symmetry-master 1) to the appropriate file.
 
==Startup files==
Q: I still have a ".coot" file in my home folder for a few coot preferences that I couldn't find in the new ".coot-preferences/coot-preferences.scm". There is a warning that I should not add commands to this file. So is a "~/.coot" still the proper place to add default commands for coot?
 
A: Coot does not create a ~/.coot file for you, but will read it if it exists.  Likewise, ~/.coot.py in which you can write python commands.~/.coot-preferences is a directory in which all .scm files and .py files are executed.  coot-preferences.scm and coot_preferences.py there are generated by using the Edit -> Preferences dialog (and thus it overwrites older versions - hence the warning).
 
If you want to create a script that will be read by everyone then put those files into a directory defined by environment variable $COOT_SCHEME_EXTRAS_DIR (for *.scm) or $COOT_PYTHON_EXTRAS_DIR (*.py). All *.scm in $COOT_SCHEME_EXTRAS_DIR and *.py files in $COOT_PYTHON_EXTRAS_DIR will be executed at start up.
 
So you have a variety of places. Personally I mostly use ~/.coot.
 
==Torsion general==
Q: How do I use "torsion general"?
 
A: Thanks for pointing out the lack of documentation on this. I'll make a note to add some.
 
You need to click on the torsion-general icon, then click 4 atoms that describe the torsion - the first atom will be the base (non moving) part of the atom tree, on clicking the 4th atom a dialog will pop up with a "Reverse" button [1].
 
Move this dialog out of the way and then left mouse click and drag in the main
window will rotate the moving/"top" part of the residue round the clicked atoms
2 and 3.  When you are happy, click "Accept".
 
Window focus may be an issue - depending on your setting, the window manager may
eat one of your clicks as you change focus between the dialog and the main
graphics window (this I find annoying and there are instructions in the FAQ on
how to turn that off for various systems).
 
[1] which may not work in 0.6-pre (grumble/sigh/sorry).  If it doesn't not work,
the "Reverse" button should invert the moving and "base" part of the residue.
 
==Peak heights in maps==
Q: I have some peaks in my map which take water or sodium/magnesium or chlorine atom with out giving out any positive or negative density upon further refinement. Is there any easy way of calculating the peak height / number of electrons at a given position, say a mouse click point in coot? Is there any formula to calculate the number of electrons based on sigma level and peak height, as given in difference map peaks in coot?
 
A: First, go to the Coot wiki and pick up the [[Coot#Scheme_Scripts|scheme key bindings]].
 
If you want density information at a given cursor point: point at the blob, press the 'g' key (which recentres on the biggest density under the cursor).
 
using the Scheme scripting window:
(apply density-at-point (imol-refinement-map) (rotation-centre))
There is no user access to the peak integration code of coot as yet.
 
==Disulfide bond across crystallographic axis==
Q: I have a pair of disulfide bonds which link two monomers in separate  asymmetric units.  There is a single monomer in the asymmetric unit, and two monomers come together to form disulfides between Cys 26-Cys45, and Cys45-Cys26. When I real-space-refine these residues, they do not form a nice disulfide, and Coot does not seem to recognize them as a disulfide.
 
A: For the record, you can't refine symmetry-related disulfides in Coot (as of Nov 3, 2009).
 
==Macros in COOT==
 
Q: How to use macros in COOT? Do they need to be written in Python or another language that I had not heard of before? Where can I find a low level description of how to write macros with some examples (I know nothing about Python, except that it is fashionable)?
 
A: The other language is a form of Lisp, called [http://en.wikipedia.org/wiki/Scheme_(programming_language) Scheme]. You can learn about programming python in many ways of course (not least the [http://docs.python.org/tutorial/ python tutorial], which is what I read first). The coot python extensions are described in the documentation. There is a standard trivial formatting change that has to be made to get the syntax right for python, see "Python Scripting" [[http://www.ysbl.york.ac.uk/~lohkamp/coot/wincoot-faq.html|here]]. There is a growing collection of coot scripts in this Wiki article.
 
== building loops ==
 
Q: Is there any similar function in COOT as lego_auto_mainchain command in O program?
 
A: there are 2 loop fitting tools in Coot
 
# C alpha -> Mainchain [http://www2.mrc-lmb.cam.ac.uk/personal/pemsley/coot/web/docs/coot.html#C_002dalpha-_002d_003e-Mainchain],[http://www2.mrc-lmb.cam.ac.uk/personal/pemsley/coot/web/docs/coot.html#Building-Links-and-Loops]
# DB Loop: (No good documentation) [http://www2.mrc-lmb.cam.ac.uk/personal/pemsley/coot/web/docs/coot.html#protein_002ddb_002dloops] Extensions -> Modelling -> DB Loop...
 
==LSQ superpositions==
 
Q: Do an LSQ superposition using specified residues in multiple chains (superposing one oligomer on another).
 
A: Something like this then?
 
clear_lsq_matches()
# specs for reference then moving
add_lsq_match(20, 90, "A",  20, 90, "A", 1)
add_lsq_match(20, 90, "B",  20, 90, "B", 1)
add_lsq_match(15, 75, "D",  15, 75, "D", 1)
apply_lsq_matches(1, 2)
 
which presumes that the reference molecule is in 1 and the moving molecule 2.
 
Q: How to do a LSQ superposition of a homologous structure onto my working structure using ± N residues about the current position, where N is a variable (not essential, could be fixed) and the current position is the last residue that I clicked on.
 
A: That is more involved - and more useful because it  can be dynamic. Something like the following perhaps (in Scheme, just for amusement (not tested)). You will need to set imol-ref, perhaps by reading in the reference pdb, as demonstrated below.  The function is bound to Shift-Y.
 
(define dynamic-lsq-range-extent 2)  ;; ± 2 residues either side of centre residue
(define imol-ref (read-pdb "reference.pdb"))
;; convert between the input reference chain id and the chain id of
;; the moving molecule that corresponds to that chain
;;
(define (mov-match-chain ref-chain-id)
  ref-chain-id)
(define (dynamic-lsq-match)
  ;; get the current residue and use that to make residue ranges for
  ;; an LSQ fit
  ;;
  (using-active-atom
  (clear-lsq-matches)
  (add-lsq-match (- aa-res-no dynamic-lsq-range-extent)
          (+ aa-res-no dynamic-lsq-range-extent)
          aa-chain-id
          (- aa-res-no dynamic-lsq-range-extent)
          (+ aa-res-no dynamic-lsq-range-extent)
          (mov-match-chain aa-chain-id)
          1)
  (apply-lsq-matches aa-imol imol-ref)))
(add-key-binding "Dynamic LSQ overlay" "Y" dynamic-lsq-match)
 
== reading MTZ file with experimental PHI and FOM using --auto ==
 
Q:  There is the --auto <filename> commandline option for auto-reading mtz files (mtz file has the default labels FWT, PHWT). Can this be made to work with a SHELXE .phs output file after converting with convert2mtz ? - the resulting MTZ file has labels F PHI FOM.
 
A: use: coot --python -c 'make_and_draw_map("sad.mtz", "F", "PHI", "FOM", "/HKL_base/HKL_base/FOM",1, 0)'
 
== NCS Rotamer differences ==
 
Show me where NCS-related side-chains have different rotamers
 
 
(define (compare-ncs-rotamer imol chain-A chain-B)
  (let ((n-residues (chain-n-residues chain-A imol))
        (mismatched-rotamers '()))
    (for-each
    (lambda (serial-number)
     
      (let ((res-name-A (resname-from-serial-number imol chain-A serial-number))
            (res-no-A  (seqnum-from-serial-number  imol chain-A serial-number))
            (ins-code-A (insertion-code-from-serial-number imol chain-A serial-number))
            (res-name-B (resname-from-serial-number imol chain-A serial-number))
            (res-no-B  (seqnum-from-serial-number  imol chain-A serial-number))
            (ins-code-B (insertion-code-from-serial-number imol chain-A serial-number)))
        (if (not (= res-no-A res-no-B))
            (begin
              (format #t "sequence number for ~s do not match~%" res-no-A))
            (if (not (string=? res-name-A res-name-B))
                (begin
                  (format #t "residue names for ~s do not match~%" res-no-A))
                (let ((rot-name-A (get-rotamer-name imol chain-A res-no-A ins-code-A))
                      (rot-name-B (get-rotamer-name imol chain-B res-no-B ins-code-B)))
                  (if (not (string=? rot-name-A rot-name-B))
                      (begin
                        (set! mismatched-rotamers
                              (cons (list imol chain-A res-no-A ins-code-A
                                          res-name-A
                                          (if (string=? rot-name-A "") "-" rot-name-A)
                                          (if (string=? rot-name-B "") "-" rot-name-B))
                                    mismatched-rotamers))))
                  )))))
    (range n-residues))
    (dialog-box-of-buttons "Mismatched Rotamers"
                          (cons 300 300)
                          (map (lambda(rotamer)
                                  (let ((label (string-append " "
                                                              (list-ref rotamer 1)
                                                              " "
                                                              (number->string (list-ref rotamer 2))
                                                              (list-ref rotamer 3)
                                                              " "
                                                              (list-ref rotamer 4) ;; res-name
                                                              ":  "
                                                              (list-ref rotamer 5)
                                                              " vs. "
                                                              (list-ref rotamer 6)))
                                        (thunk (lambda ()
                                                (set-go-to-atom-molecule imol)
                                                (set-go-to-atom-chain-residue-atom-name
                                                  (list-ref rotamer 1)
                                                  (list-ref rotamer 2) " CA "))))
                                    (list label thunk)))
                                mismatched-rotamers)
                          "  Close  ")))
 
 
 
And one would use this something like:
 
;; example usage:
(let ((imol (read-pdb "test.pdb")))
  (compare-ncs-rotamer imol "A" "B"))
 
== make RSR in coot 0.8.1 behave like in earlier versions ==
 
Q: We've noticed a new behavior in real space refinement in coot 0.8.1 whereby dragged atoms are more tightly restrained to their initial positions than in earlier versions. This seems to be described in the release notes by:
 
  o BUG-FIX: The amount that the other atoms ove with moving the picked atom has been reduced (but is configurable)
 
A: Add e.g. this to your ~/.coot.py file:
 
set_refinement_drag_elasticity(0.8)
 
Q: I'm wondering why this was changed. Does the optimum elasticity change with resolution, map quality, or another experimental limitation? Or does it more of a user preference?
 
A: Because of cis-peptides. My worry was that in the previous regime, it was
too easy to introduce cis-peptides when fitting to low resolution maps. 
I believe the current default setting is much less likely to do that.
 
Q: I've tried various settings of refinement_drag_elasticity and I need to lower it to 0.5 or so before any semblance of earlier behavior appears.
 
A: It used to be 0.167, I think.
 
== Molprobity not active in COOT ==
 
Q: I am using COOT 0.8.1 EL that comes with the CCP4 6.5.010 on my Mac OS X 10.10.2. I wanted to run molprobity but the Validate > Probe clashes button in my pull down menu is not active. Is this function available in this COOT version?
 
A: Reduce and probe are separate programs available from the Richardson’s lab at Duke http://kinemage.biochem.duke.edu/. Download and install on your box. Then coot needs to be told in some instances where it can find these executables. I have the following lines in my ~/.coot file in Linux.
 
<pre>
;; .coot
;; This file is required. As of coot 0.8pre no other mechanism for
;; enabling probe in coot works
;;
;; This is full pathname of molprobity's probe program
(define *probe-command* "/apps/xray/bin/probe")
;; This is full pathname of molprobity's reduce program
(define *reduce-command* "/apps/xray/bin/reduce")
</pre>
Untried: if you have Phenix installed: it comes with phenix.probe and phenix.reduce - you could insert the paths to these binaries into the above definitions.
 
== some symmetry mates not shown ==
 
Q: This structure has been solved and refined using phenix in the hexagonal setting of space group R 3. There is one copy per asymmetric unit in R 3. As you can see from the attached image, coot is rendering some but not all of the symmetry mates.
 
A: Turn up the radius a bit and use (set-symmetry-shift-search-size 3) . I would have thought that 2 is big enough, but maybe not in this case.