Walkthrough on command line based tilt series alignment

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This is the command line based version of the GUI based alignment walkthrough

Create the workflow

name = 'hivCommandLine';
folder = 'workflows';
u = dtsa(name,'--nogui','-path',folder,'fp',1); 

Here, we instruct Dynamo to skip opening the GUI. We also create the workflow in a different folder.

Entering the data

The u object contains several areas to interact with the workflow. They can be found by autocompletion using the tab key. Here, we will proceed step by step; remember that you can write all the command lines in a single .m script.

autocompletion of user object
autocompletion of further fields of user object

Basic data

The file of the tilt series can be defined somewhere else

file = '/~/data/b001ts001.mrc'; 
and then linked into the workflow:

u.enter.tiltSeries(file); u.enter.tiltAngles(-57:3:60);

If you want to reject some of the hight tilts (or any other view that appears to have been damages,) u.enter.discardedTiltIndices([1,40]);

Acquisition settings

Here you can enter Cs, nominal defocus, etc... We will just provide the pixel size in Angstroms:

u.enter.settingAcquisition.apix(2.7);

Computation settings

We enable the use of parallel cores

u.enter.settingComputing.parallelCPUUse(1); 

This will be using mainly for gold bead detection (cc computation) and reconstruction.

To ask Dynamo to use all available physical cores, use the '*' symbol. u.enter.settingComputing.cpus('*');

Detection settings

These here are the actual design decisions when running an alignment workflow. The gold bead radius should have been measured beforehand:

u.enter.settingDetection.beadRadius(16); u.enter.settingDetection.maskRadius(28);

u.enter.templateSidelength(64);

The bin level is mainly used to accelerate the detection procedure. Needs to be chosen in a way that a binned gold bead still can be recognisable as such, with a radius of at least 4 pixels.

u.enter.settingDetection.detectionBinningFactor(1);

Changing generic parameters

Yo can find handles to the parameters of the individuals steps through autocompletion on the area, then step items.

u.area.indexing.step.tiltGapFiller.parameterSet.residualsThreshold(8);

Running the workflow

u.run.all('noctf',1);

On the fly reconstruction of particles

Grep coordinates in the binned tomogram

Open the binned reconstruction with dtmslice dtmslice 'workflows/hivCommandLine.AWF/reconstruction/binnedReconstructionWBP.mrc';

view of tilt lines
dtmslice of binned reconstruction
dtmslice contrast control
dtmslice after contrast correction
create a new model
show a full projection
full projection of binned reconstruction
right click on a point
x view of clicked point
main click to fix the 3d coordinates
click around ten markers
export a table into the matlab workspace
the command line shows the variable name assigned to the created table

Now we can save the table as a file: write(temp_table,'binnedGoldbeads.tbl');

Cropping the gold bead particles

tomo = 'workflows/workshop.AWF/reconstruction/binnedReconstructionWBP.mrc'; tbl = 'binnedGoldbeads.tbl'; targetBinnedParticles = 'binnedGoldBeads.Data'; sidelength = 32; o = dtcrop(tomo,tbl,target,sidelength);

And then we visualise a projection along z of each cropped particle

dslices(targetBinnedParticles,'proj','c');shg;
dslices on binned gold beads

Reconstruct particles on the fly

The command that reconstructs full sized particles from an aligned stack is dynama_table_trec. This is an independent function, not part of the workflow, implying that we will need to perform some format conversion.

tbl = dread('binnedGoldbeads.tbl');

We scale the table

alignmentBinLevel = 2;

tblFull = dynamo_table_rescale(tbl,'factor',2^alignmentBinLevel);

source  = 'workflows/hivCommandLine AWF/align/alignedFullStack.mrc';

We create a data folder to contain the particles reconstructed on the fly.

targetDirectory = 'tempCrop.Data';


Angles actually used during the reconstruction are contained in the reconstructionTiltAngles' item of the output folder. Note that they might differ from the nominal angles, as some views might have been eliminated, both explicitely by the user, of by the program not being able to align all tilts.

angles =  'workflows/hivCommandLine.AWF/align/reconstructionTiltAngles.tlt';

The (binned) coordinates were measured in a binned tomogram, whose dimensionality is requested by dynamo_table_rec. We need to provide dynamo_table_rec with visualizationTomogram = 'workflows/ hivCommandLine.AWF/reconstruction/binnedReconstructionWBP.mrc'; sizeTomogram = dynamo_read_size(visualizationTomogram); sizeTomogramFull = sizeTomogram*2^alignmentBinLevel;

The tomogram center can be shifted in order to account for a possible shift in the centre in the binned reconstruction that was used to crop the particles.

shiftTomogramCenter = [0,0,0];

We proceed now to the reconstruction. sidelengthFullSize = 128; dynamo_table_rec(tblFull,source,angles,targetDirectory,sidelength,....

   'applyRampFilter',1,....
   'sizeTomogram',sizeTomogramFull,....
   'shiftTomogramCenter',shiftTomogramCenter);

We can now check that the particles have been reconstructed in full size.

figure;dslices(targetDirectory,'proj','c');shg;
dslices on full sized gold beads