New Chimera Fitting Capabilities
3D EM Gordon Conference
June 27, 2011
- Will demonstrate of 3 new methods in UCSF Chimera software
for fitting atomic models in electron microscopy maps, added
in the last month.
- Also will show how to look at protein-protein interfaces
in crystal unit cells.
- The fitting methods don't use novel algorithms. Their value
is that the many map and atomic model analysis capabilities work together well.
Example system: Alpha Crystallin
Alpha crystallin is a molecular chaperone that prevents protein
aggregation. There are two forms A and B with 60% sequence identity
with the A form found only in the vertebrate eye lens. It is about 40
percent of the protein in the human eye lens and prevents
crystallization of the other proteins in the lens. The EM map we will
look at is of the B form found it brain, heart and muscle tissue and
has a role in diseases such as Alzheimer's, Parkinson's and
multiple sclerosis where protein aggregation occurs.
Alpha crystallin forms oligomers of variable size, the map we will look
at consisting of 24 copies, negative stain, 20 Angstrom resolution (FSC 0.5)
from Sevil Weinkauf and Johannes Buchner groups, EM Databank
- Blast PDB.
- Multiple sequence and structure alignments.
- Molecular interfaces in crystal unit cell.
- Global search fitting.
- Determining map symmetry.
- Sequential molecule fitting to avoid clashes.
- Fitting with symmetry.
Finding alpha crystallin PDB models
Use white background, silhouette edges and glossy lighting.
- Fetch 3L1G (a human alphaB crystallin). Two beta sheets.
- Show sequence (Tools / Sequence). Sequence colors: green beta sheet,
yellow alpha helix, red outline, missing residues.
- BLAST sequence against PDB (Sequence dialog / Tools / Blast Protein).
Note 6 human, one zebrafish, two bovine, one rat.
- Show multiple sequence alignment (Blast dialog, Show in MAV button).
- Load all 10 structures (Blast dialog, Load Structure button).
Binding Interfaces - Crystal Unit Cell
- Show binding interfaces from crystal packing.
- Close session. Open human alphaB crystallin 3L1G.
- Show unit cell (Tools / Higher-Order Structure / Unit Cell).
- Show outline box.
- Note 3 equivalent dimers. C-terminal lies in a groove at the edge of
the two beta sheets. Dimer is bound by each C-terminal tail sitting in
the groove of the other monomer.
- Another dimerization mode crosses 2 unit cells. Show it.
(Unit Cell / Options / Number of Cells "2 1 1")
- Each monomer has 3 binding sites: C-terminal tail, beta sheet groove,
and beta-sheet edge-to-edge extension (opposite edge from groove).
- Having 3 binding sites allows oligomers to form cages.
Fitting in EM map, global search
- Fit dimer instead of monomer because the map has 12-fold symmetry
but contains 24 copies of the monomer.
- Joined beta-sheet dimer would be better than C-terminal groove dimer
because it likely has less flexibility.
- We'll use the C-terminal dimer to better illustrate fitting with clashes
- Close all 3L1G monomers except white/yellow dimer using Model Panel.
- Easier to fit dimer as a single molecule. Command "combine #0,3".
Close original models.
- Rename combination to "3L1G dimer" using Model Panel / Rename button.
- Fetch alpha crystallin map, EMDB 1776. Negative stain, 20 Angstrom
resolution, tetrahedral symmetry.
- Fit search 10 placements, command "fit #1 #0 search 10".
- Show map as transparent. Also use one transparent layer.
Color model yellow with color button in model panel.
- Fit tried 10 random placements and orientations and did local
rigid body optimization.
- Many equivalent fits are listed due to symmetry.
Assigning and Using Map Symmetry
- Map symmetry is unfortunately not kept in map header. Use command
"measure symmetry #0" to deduce symmetry.
- Note status line says tetrahedral with center grid point 75 75 74.
- Recompute fits. Add "res 20" to get correlation options.
"fit #1 #0 search 10 res 20".
- Note only 4 unique positions found, identical fits removed. Hits column
of table says how often a fit was found. All fits found are moved to a single asymmetric unit.
- Close original fits.
- Note we have fits and 180 degree flip about dimer symmetry axis.
- Show clash volume between symmetric copies (Fit List / Options).
- 0.6 clash means 60% of volume of fit monomer is overlapped by symmetrically
placed monomers. Is using large envelope of simulated map. Show sim map.
- Show clashing monomers, "sym #1 group #0 update true".
Avoiding fitting clashes: sequential fitting
- Show only 3 dimers of one 3-fold donut.
Command "sym #1 group #0 range 50".
- Hide map to better see clashes.
- Fit sequentially. Command "fit #1,2.1,2.2 #0 seq 3 res 20" fits each
in turn subtracting the other two from the density first.
- Repeat last command to get better convergence.
- Repeat again with "seq 15" for 5 rounds of fitting each monomer.
- This protocol was taken from an Alasdair Steven's lab paper on Rous sarcoma
Avoiding fitting clashes: symmetric fitting
- Above method is a poor approach for symmetry related monomers since
it does not guarantee symmetry. It is better applied to proteins that are
not related by symmetry.
- Better approach to this problem is to fit one monomer taking account
of clashes of symmetrically placed monomers.
- Fit full symmetric assembly. Restore best fit from fit list.
Remove symmetry copies, command "~sym". Fit command "fit #1 #0 res 20 sym true".
- Symmetric fitting optimizes the correlation of the full symmetric assembly by moving one monomer and keeping all other virtual monomers related by symmetry.
- This type of fitting has been done by the URO program for many years
although it does it in Fourier space while we do it in real space.
- Note reported correlation 0.95.
- This avoids clashes because if two monomers overlap they create double
density that gives poor correlation with experimental map. Clashes are
implicitly avoided -- there is no special repulsion introduced.
- Darren Weber - Animation.
- Eric Pettersen - Sequence and structure analysis.
- Elaine Meng - Email help, documentation and tutorials.
- Conrad Huang - Web services and project leader.
- Tom Goddard - Electron microscopy.
- Tom Ferrin - Head of lab.
- Greg Couch - OpenGL graphics.
- YZ Yang Zheng - Homology modeling, SAXS.
The new fitting methods are in the Chimera
daily builds and
demonstrations are on the
Chimera web site.