Walkthrough on creation of 3d scenes

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This walkthrough shows how to create graphic depictions of tomogram contents. Those include:

  • Slices of tomograms.
  • Proteins located in the tomogram, with the orientations provided during the alignment.
  • Geometrical objects (as membranes represented by triangulations).
Goal of the tutorial. An antialiasing filter has been used.

The data set

This walkthrough works with the data set from the advanced starters guide. The goal is to depict:

  • One slice of the tomogram in 3D.
    This requires a tomogram file.
  • The viruses placed an oriented along the directions found during a previous computed average.
    This requires a template represe.
  • A sketch of the membrane
    This requires a model object.

From the Dynamo web

The tomogram can get fetched through:

wget  https://wiki.dynamo.biozentrum.unibas.ch/w/doc/data/fhv/crop.rec 

in a linux shell, or through:

curl -O  https://wiki.dynamo.biozentrum.unibas.ch/w/doc/data/fhv/crop.rec 

under MacOS.

The table, template and membrane model can be fetched similarly with names


From your previous work

Assuming you have done the tutorial on the FHV data set, you can use the elements that you have already computed. Just extract them from the best project that you completed. Do not use a subboxing project: we want to get a template for the full crown. Examples below are given assuming that your best project was named localized, substitute if not.


Recover the last computed refined table in the data base of your project

ddb localized:rt -r t

and write it to a file



Fetch the last computed average

ddb localizedFullAngle:a -r a

assuming localizedFullAngle:a is the name of your last project.

and write it into disk


Membrane model

If you created manually a membrane model, it should be inside your catalogue with the name mySurface (or any other you put). You can check inside the catalogue fhv:

dcmodels fhv -nc mySurf

Here -nc mySurf will look for models with the string "mySurf" in the name. You should get a reply as:

Volume 1. Matching models: 1 (total: 1)

So you can read the model into a new variable (arbitrarily called m)

m = dread('Users/casdanie/dynamo/examples/fhvParis/fhv/tomograms/volume_1/models/mySurface.omd');

and write it to disk:


Depicting a slice of a tomogram

The easiest way is to just use the dynamo_slice3d command, which has a simple syntax. For instance,

o = dslice3d(volume,'r',[40,50,67],'normal','y');

will create a slice orthogonal to the 'y' direction that cuts the point [40,50,67], and that by definition will have the full extent of the tomogram. This command is a wrapper around the class dpktomo.volume.slices.Slice. The rest of this section explains how to use objects of this class to get a detailed level of control of the depictede slice.

The slice object

s = dpktomo.volume.slices.Slice(); 

Here s is just an object that will read data from a tomogram file to be defined, along with geometrical parameters as center, eulers (orientation), l, (sidelength)...

s.source = 'crop.rec';
s.center = 'center';

Here, we set the center of the slice. We can pass a [x,y,z] triplet (like [256,200,100], or just use the code 'center' to put the center of the slice in the center of the tomogram. Now, we indicate the horizontal and vertical lengths of the slice (in pixels):

s.l = [1000,1000];

The actual extent of the slice will get cut if the l that we use is bigger than the size of the tomogram.

The orientation of the slice can be computed through a combination of euler angles [tdrort, tilt, narot], or simply with strings 'x', 'y' and 'z' for orthogonal directions.

s.eulers =  'z';

You can also input euler triplets as value for property eulers. Other properties you can fix are bandpass or thickness.

Now, we actually compute the slice;


This will not create any output in the screen. fetchData will just operate the action of visiting the file crop.rec and extracting a numeric matrix that represents the gray intensities of the slice with the indicated parameters. The matrix will be stored inside the s object (as the 'data' property) and will be accessed by the depicting operations to be executed later. General help on this class can be found in

 help dpktomo.volume.slices.Slice 

The slice depictor object

We first create a figure with and empty axis:

 f = figure; haxis = gca();hold on;

Here, f and haxis are handles that will be used later to direct the graphical output to our figure.

Empty matlab figure with an empty axis.

Now, we initialize a depiction object associated with the slice s

sz = dpktomo.volume.slices.SliceGraphic(s);

Note that no graphical output has been created yet. We first inform the object sz in which axis it is to be created.

sz.axis.h = haxis;

and then create the slice in the available axis.


If the figure is below other windows in your system you can rise it through




We can change the angle of view with the rotation icon or programmatically:

View of the slice with the viewing perspective ([-38,60]).

Placement of templates

Here we will place copies of an FHV crown in the positions and orientations given by a table. Here, the density map representing the template needs first to be converted into an isosurface, which will be represented by a triangulation.

Creating a mask

We first want to crop the available average inside a mask, to get rid of the membrane surrounding the crown. For this we first show the template inside mapview

dmapview averagedLocalRefinement.em
mapview on template.

We can apply a 'c12' symmetrization on the template to get better graphical depiction.

Rotational symmetrization of a template.

Now, we can select the area of interest by moving to the central section

Central section in the xz plane.

If you click on shift + S you will get a popup window where you can draw an area of interest. Dynamo will create a revolution solid by rotating the mask that your depict in 2d (on the xz plane) about the z axis. Use the main click to start drawing and the auxiliary click where you are done.

handdrawing GUI created by shift + C in mapview

We read the created mask from the file where Dynamo creates it by default

 maskRevolution = dynamo_read('temp_drawn_revolution_mask.em');

and apply it onto our template. We apply the 12-fold symmetrization on the same operation.

 template = dread('averagedLocalRefinement.em');
 final = dsym(template,'c12').*maskRevolution;

Here the A .* B notation indicates the pixelwise multiplication of two volumes. We can now write the result into a file


and visualize the result:

dview placedTemplate.em 
Final template, after symmetrization and masking

Checking the isolevel in Chimera

You can check the appropriate isolevel using Chimera UCSF, assuming it is activated in your session.

Adjust the isolevel with the Volume Viewer option in Chimera

Creating a Dynamo triangulation for the template

Ideally, we would like to export the triangulation created in Chimera into Dynamo directly (using the Export as STL file in the Export scene menu of Chimera). However, you have probably moved and rotated the object in Chimera in order to visualize it more clearly. Thus, we will just use the isolevel computed by Chimera and recreate the isosurface inside Dynamo:

dt = dynamo_isosurface(final,'isolevel',0.79,'real_isolevel',true,'-show',false);

Here, the output dt is a Dynamo object that manages isosurfaces. In order to see the isosurface that we just created, we open a new figure:

f2 = figure();

and use the trisurf command of matlab to open the matlab triangulation contained in the property tr.

trisurf(dt.tr);axis equal ;
Command <tt>trisurf

Creating a global triangulation

we recover our table with locations 'and alignment parameters

 t = dread('alignmentLocalRefinement.tbl'); 

and create a triangulation object that merges the result of copying, relocating and rotating the isosurface of one template on all positions of the table:

tAll = dpktbl.triangulation.place(t,dt.tr,'rc',64.5);

Here, 64.6 indicates the position of the rotation center. Note that this does not create a graphical output. tAll is just a triangulation object, which we can depict in our figure t (where we had depicted the slide of the tomogram).

hTriangulation  = trisurf(tAll);
The raw hTriangulation object.

The created figure looks rather disappointing: we have to adjust the default matlab settings for representation of triangulations. First we ask for depicting only the faces, not the edges:

hTriangulation.FaceColor= 'c';
hTriangulation.LineStyle = 'none';
hTriangulation object after eliminating the depiction of the edges

The object is indeed cyan, but we don't see any details, as we haven't defined any shading:

axis equal;
f.Name = 'Simple trisurf scene';
% just m the exploration
l = lightangle(-45,30);
addition of a light source

Now we see details, but they are overall defined in a grey scale. We need to simulate in Matlab the coexistence of two colormaps in a figure (a feature missing in the native software).

ocm = dynamo_colormap();
After using dynamo_colormap

Now we repaint the triangulation to cyan.

hTriangulation.FaceColor= 'c'; 
Using a single color for the whole triangulation

Moving the slice

If you want to change an existing slice on an already created scene, you need to change some settings.


After them, any change in thickness, band,center,l,eulers will automatically refresh the appearance of the slice, For instance you can shift it upwards through:


which is equivalent to

s.center = s.center+[0,0,100];
Shifted slice

Adding a membrane triangulation

We make sure that we send the graphical output to the correct figure, using the handle we defined previously:


We recover our membrane model:

m = dread('membraneModel.omd');

and extract the triangulation hidden inside it (mesh.tr property)

hMem =trisurf(m.mesh.tr);

We may want to adjust the appearance a little, for instance the transparence:

hMem.FaceAlpha = 0.3;
Shifted slice