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== Wednesday March 16, 2011 - P.M. Practical EMAN2 SPT tutorial == SPT (single particle tomography) capabilities are relatively new in EMAN2. They were inspired by Michael Schmid's studies on sub-volume averaging (mostly on viruses), and a stubborn student's insistence on doing extensive sub-volume averaging on chaperons. |
== Wednesday March 16, 2011 - P.M. == This session will be about extracting sub-volumes from a tomogram, preparing them for alignment, aligning them, and averaging them. There is no Wiki version of the tutorial as of now. You MUST download it as a PDF or word document, provided below. The links SHOULD work directly (it is safe to do right-click followed by "save as"). If not, once you click on the link it will take you to another page where you'll see a "DOWNLOAD" link. Click on that to get the corresponding file. == TUTORIAL DOCUMENT == ||<style="color: #FF0000; font-weight: bold;"> PDF || [[attachment:eman2_spt_tutorial.pdf| eman2_spt_tutorial.pdf|&do=get]] ||<style="color: #FF0000; font-weight: bold;"> WORD 2008 || [[attachment:eman2_spt_tutorial.docx| eman2_spt_tutorial.docx|&do=get]] == You should have downloaded ALL the data BEFORE the workshop starts == == You should have downloaded ALL the data BEFORE the Workshop starts == (If you didn't, the tutorial document will lead you through downloading files AS NEEDED) . . . . . == SOFTWARE == All necessary software is provided as part of EMAN2. If you don't have EMAN2 installed, you can download the most updated version (for your specific platform, Windows, Linux or Mac), from here: [[http://ncmi.bcm.edu/ncmi/software/counter_222/software_86]] == RAW DATA == 1) [[attachment:e15tomogram_phaseplate_bin4.rec| e15tomogram_phaseplate_bin4.rec|&do=get]] This first tomogram was reconstructed from a tilt series of epsilon15 virus particles in vitro, recorded using Zernike phase-plate technology. [Liu and Murata et al, 2010]. 2) [[attachment:e15tomogram_phaseplate_bin2.rec| e15tomogram_phaseplate_bin2.rec|&do=get]] It’s the same as the previous one, but shrunk by a factor of 2. 3) [[attachment:e15tomogram_normal_bin4.rec| e15tomogram_normal_bin4.rec|&do=get]] This tomogram also comes from a tilt series of epsilon15 viruses in vitro, but was recorded under “conventional” cryoET imaging conditions. [Liu and Murata et al, 2010]. 4) [[attachment:e15tomogram_normal_bin2.rec| e15tomogram_normal_bin2.rec|&do=get]] (Again, the previous tomogram shrunk by 2). == REFERENCES == [[attachment:e15ref_prep_icos_bin4.hdf| e15ref_prep_icos_bin4.hdf|&do=get]] [[attachment:e15ref_prep_icos_bin2.hdf| e15ref_prep_icos_bin2.hdf|&do=get]] [[attachment:e15ref_prep_asym_bin4.hdf| e15ref_prep_asym_bin4.hdf|&do=get]] [[attachment:e15ref_prep_asym_bin2.hdf| e15ref_prep_asym_bin2.hdf|&do=get]] [[attachment:e15ref_raw.hdf| e15ref_raw.hdf|&do=get]] == PREPARED COORDINATES FILES == [[attachment:e15phaseplate_coords.txt| e15phaseplate_coords.txt|&do=get]] [[attachment:e15normal_coords.txt| e15normal_coords.txt|&do=get]] . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . = RESULTS UH = [[attachment:e15normal_average.hdf| e15nromal_average.hdf|&do=get]] [[attachment:e15normal_average_lp50.hdf| e15nromal_average_lp50.hdf|&do=get]] = ANYTHING BELOW THIS MARK IS DEPRECATED = |
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== SOFTWARE == All necessary software is provided as part of EMAN2. If you don't have EMAN2 installed, you can download the most updated version (for your specific platform, Windows, Linux or Mac), from here: [[http://ncmi.bcm.edu/ncmi/software/counter_222/software_86]] == RAW DATA == We have prepared sample data for this tutorial. The tomogram in the link below comes from a tilt series of epsilon15 virus particles ''in vitro'', recorded using Zernike phase-plate technology: [[attachment:e15phaseplate.rec]] The following tomogram also comes from a tilt series of epsilon15 viruses ''in vitro'' but was recorded under conventional cryoEM imaging conditions: [[attachment:e15normal.rec]] |
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To launch one of the tomograms provided (you're free to choose which ever you prefer) type the following at the commandline: |
To launch the GUI that will show you the tomogram (you're free to choose whichever you prefer, "e15normal.rec" or "e15phaseplate.rec") type the following COMMAND #001 at the commandline: ||<style="color: #FF0000; font-weight: bold;">COMMAND #001|| |
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'''To specify --yshort, or not to''' This option will FLIP orientation of your tomogram respect to the Y and Z coordinates. You should ONLY specify it IF the tomogram has its smallest/slimmest dimension running along the Y-axis, so that it becomes parallel to the Z-axis instead. '''Ok... but, still, WHY? What does this mean?''' Some tomograms are built with the slimmest part of the 3D volume (that corresponding to the "ice thickness" in cryoEM) running along the Y-axis. BUT '''__in EMAN2 volumes are displayed such that the Z-axis is perpendicular to the screen__'''. Ideally, you would want the slimmest part of the volume to be aligned along Z (NOT Y) so you can view the entire tomogram "from the TOP", and look at the entire CCD-captured area in the XY plane slice by slice, as you go through the volume. '''--inmemory''' This option loads your tomogram to memory, allowing to box particles (or do whatever you want to do in e2tomoboxer) more "smoothly" (faster), because reading data "from memory" is faster than reading it "from disk". You can get the entire list of options that e2tomoboxer.py takes (not many at this point) and some sort of explanation of what they're for by typing the following at the commandline: {{{ e2tomoboxer.py -h }}} |
''' ''EXPLANATION'' ''' '''To specify --yshort, or not to''' This option will FLIP the orientation of your tomogram respect to the Y and Z coordinates. You should ONLY specify it IF the tomogram has its smallest/slimmest dimension running along the Y-axis, so that it becomes parallel to the Z-axis instead. '''Ok... but WHY? What does this mean?''' Some tomograms are built with the slimmest part of the 3D volume (that corresponding to the "ice thickness" in cryoEM) running along the Y-axis. BUT '''__in EMAN2 volumes are displayed such that the Z-axis is perpendicular to the screen__'''. If you open one of these tomograms "as is", you'll be looking at it "from the side". Most of the time you want the slimmest part of the volume to be aligned along Z (NOT Y), so you can see the tomogram "from the TOP", and look at the entire CCD-captured area in the XY plane slice by slice, as you go through the volume. '''--inmemory''' This option pre-loads your tomogram to memory, allowing to box particles (or do whatever you want to do in e2tomoboxer) more smoothly (faster), because reading data from memory is faster than reading it from disk. You can get the entire list of options that e2tomoboxer.py takes (not many at this point) and some sort of explanation of what they're for by typing the following at the commandline: {{{ e2tomoboxer.py -h }}} If you ran the command and took a leap of faith in skipping the explanation, you will probably have already clicked a few things in the GUI (Graphical User Interface with nice 'clickable' buttons) that popped up. ''~-(I hope you did; extensive explanations really ought to be read only when following the execution boxes doesn't work smoothly, when you're confused, when you have a lot of time to spare and nothing better to do, or when you're a purist [slightly OCD] about reading manuals in their entirety with the noble purpose of getting the most out of them).-~'' |
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The e2tomoboxer.py GUI should look like this: {{attachment:image.png|alt text|width=100 height=150}} This window is called __ You will notice... |
Single Particle Tomography in EMAN2
Wednesday March 16, 2011 - P.M.
This session will be about extracting sub-volumes from a tomogram, preparing them for alignment, aligning them, and averaging them.
There is no Wiki version of the tutorial as of now. You MUST download it as a PDF or word document, provided below.
The links SHOULD work directly (it is safe to do right-click followed by "save as"). If not, once you click on the link it will take you to another page where you'll see a "DOWNLOAD" link. Click on that to get the corresponding file.
TUTORIAL DOCUMENT
WORD 2008 |
You should have downloaded ALL the data BEFORE the workshop starts
== You should have downloaded ALL the data BEFORE the Workshop starts ==
(If you didn't, the tutorial document will lead you through downloading files AS NEEDED)
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SOFTWARE
All necessary software is provided as part of EMAN2. If you don't have EMAN2 installed, you can download the most updated version (for your specific platform, Windows, Linux or Mac), from here:
http://ncmi.bcm.edu/ncmi/software/counter_222/software_86
RAW DATA
1) e15tomogram_phaseplate_bin4.rec
This first tomogram was reconstructed from a tilt series of epsilon15 virus particles in vitro, recorded using Zernike phase-plate technology. [Liu and Murata et al, 2010].
2) e15tomogram_phaseplate_bin2.rec
It’s the same as the previous one, but shrunk by a factor of 2.
3) e15tomogram_normal_bin4.rec
This tomogram also comes from a tilt series of epsilon15 viruses in vitro, but was recorded under “conventional” cryoET imaging conditions. [Liu and Murata et al, 2010].
4) e15tomogram_normal_bin2.rec
(Again, the previous tomogram shrunk by 2).
REFERENCES
PREPARED COORDINATES FILES
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RESULTS UH
ANYTHING BELOW THIS MARK IS DEPRECATED
This session will cover the beta version of a small fraction of the possibilities for SPT processing EMAN2 will eventually offer.
OUTLINE
- 1) SPT processing through EMAN2's workflow (e2workflow.py)
- 2) Sub-volume extraction from tomograms using EMAN2's 3D particle picking tool (e2tomoboxer.py)
3) "Preparation" of extracted particles for alignment. [Details later. For a myriad of reasons, it is NOT recommendable to align and average sub-volumes directly after extraction without "preparing" them first].
- 4) Reference-based alignment and averaging.
PLEASE NOTE that "particle" and "sub-volume" are used interchangeably
BOXING
There are two options for opening the tomogram for purposes of boxing it.
1) Directly, by typing e2tomoboxer.py followed my the path to the tomogram file at the commandline.
2) Or you can launch e2workflow.py from the commandline and access a tomogram through the browser in the tomographic menu.
[In theory, you can open a tomogram for contemplation purposes by typing: "e2display.py <my_tomogram_path_name_goes_here>" at the commandline. This is NOT recommendable, unless you have a grossly large (VERY, VERY large) amount of virtual memory on your computer; otherwise, catastrophe WILL befall upon you].
Let's explore the FIRST APPROACH.
OPENING A TOMOGRAM DIRECTLY WITH e2tomoboxer.py
To launch the GUI that will show you the tomogram (you're free to choose whichever you prefer, "e15normal.rec" or "e15phaseplate.rec") type the following COMMAND #001 at the commandline:
COMMAND #001 |
e2tomoboxer.py e15normal.rec --yshort --inmemory
EXPLANATION
To specify --yshort, or not to
- This option will FLIP the orientation of your tomogram respect to the Y and Z coordinates. You should ONLY specify it IF the tomogram has its smallest/slimmest dimension running along the Y-axis, so that it becomes parallel to the Z-axis instead.
Ok... but WHY? What does this mean?
Some tomograms are built with the slimmest part of the 3D volume (that corresponding to the "ice thickness" in cryoEM) running along the Y-axis. BUT in EMAN2 volumes are displayed such that the Z-axis is perpendicular to the screen. If you open one of these tomograms "as is", you'll be looking at it "from the side". Most of the time you want the slimmest part of the volume to be aligned along Z (NOT Y), so you can see the tomogram "from the TOP", and look at the entire CCD-captured area in the XY plane slice by slice, as you go through the volume.
--inmemory
- This option pre-loads your tomogram to memory, allowing to box particles (or do whatever you want to do in e2tomoboxer) more smoothly (faster), because reading data from memory is faster than reading it from disk. You can get the entire list of options that e2tomoboxer.py takes (not many at this point) and some sort of explanation of what they're for by typing the following at the commandline:
e2tomoboxer.py -h
If you ran the command and took a leap of faith in skipping the explanation, you will probably have already clicked a few things in the GUI (Graphical User Interface with nice 'clickable' buttons) that popped up. (I hope you did; extensive explanations really ought to be read only when following the execution boxes doesn't work smoothly, when you're confused, when you have a lot of time to spare and nothing better to do, or when you're a purist [slightly OCD] about reading manuals in their entirety with the noble purpose of getting the most out of them).
USING THE WORKFLOW FOR SPT
The e2tomoboxer.py GUI should look like this:
This window is called You will notice...