Provided by: theseus_3.3.0-10build1_amd64 
NAME
theseus - Maximum likelihood, multiple simultaneous superpositions with statistical analysis
SYNOPSIS
theseus [options] pdbfile1 [pdbfile2 ...]
and
theseus_align [options] -f pdbfile1 [pdbfile2 ...]
DESCRIPTION
Theseus superposes a set of macromolecular structures simultaneously using the method of maximum
likelihood (ML), rather than the conventional least-squares criterion. Theseus assumes that the
structures are distributed according to a matrix Gaussian distribution and that the eigenvalues of the
atomic covariance matrix are hierarchically distributed according to an inverse gamma distribution. This
ML superpositioning model produces much more accurate results by essentially downweighting variable
regions of the structures and by correcting for correlations among atoms.
Theseus operates in two main modes: (1) a mode for superimposing structures with identical sequences and
(2) a mode for structures with different sequences but similar structures:
(1) A mode for superpositioning macromolecules with identical sequences and numbers of residues,
for instance, multiple models in an NMR family or multiple structures from different crystal forms
of the same protein.
In this mode, Theseus will read every model in every file on the command line and superpose them.
Example:
theseus 1s40.pdb
In the above example, 1s40.pdb is a pdb file of 10 NMR models.
(2) An ``alignment'' mode for superpositioning structures with different sequences, for example,
multiple structures of the cytochrome c protein from different species or multiple mutated
structures of hen egg white lysozyme.
This mode requires the user to supply a sequence alignment file of the structures being
superpositioned (see option -A and ``FILE FORMATS'' below). Additionally, it may be necessary to
supply a mapfile that tells theseus which PDB structure files correspond to which sequences in the
alignment (see option -M and ``FILE FORMATS'' below). The mapfile is unnecessary if the sequence
names and corresponding pdb filenames are identical. In this mode, if there are multiple
structural models in a PDB file, theseus only reads the first model in each file on the command
line. In other words, theseus treats the files on the command line as if there were only one
structure per file.
Example 1:
theseus -A cytc.aln -M cytc.filemap d1cih__.pdb d1csu__.pdb d1kyow_.pdb
In the above example, d1cih__.pdb, d1csu__.pdb, and d1kyow_.pdb are pdb files of cytochrome c
domains from the SCOP database.
Example 2:
theseus_align -f d1cih__.pdb d1csu__.pdb d1kyow_.pdb
In this example, the theseus_align script is called to do the hard work for you. It will
calculate a sequence alignment and then superpose based on that alignment. The script
theseus_align takes the same options as the theseus program. Note, the first few lines of this
script must be modified for your system, since it calls an external multiple sequence alignment
program to do the alignment. See the examples/ directory for more details, including example
files.
OPTIONS
Algorithmic options, defaults in {brackets}:
--amber
Do special processing for AMBER8 formatted PDB files
Most people will never need to use this long option, unless you are processing MD traces from
AMBER. AMBER puts the atom names in the wrong column in the PDB file.
-a [selection]
Atoms to include in the superposition. This option takes two types of arguments, either (1) a
number specifying a preselected set of atom types, or (2) an explict PDB-style, colon-delimited
list of the atoms to include.
For the preselected atom type subsets, the following integer options are available:
• 0, alpha carbons for proteins, C1´ atoms for nucleic acids
• 1, backbone
• 2, all
• 3, alpha and beta carbons
• 4, all heavy atoms (no hydrogens)
Note, only the -a0 option is available when superpositioning structures with different sequences.
To custom select an explicit set of atom types, the atom types must be specified exactly as given
in the PDB file field, including spaces, and the atom-types must encapsulated in quotation marks.
Multiple atom types must be delimited by a colon. For example,
-a ` N : CA : C : O '
would specify the atom types in the peptide backbone.
-f Only read the first model of a multi-model PDB file
-h Help/usage
-i [nnn]
Maximum iterations, {200}
-p [precision]
Requested relative precision for convergence, {1e-7}
-r [root name]
Root name to be used in naming the output files, {theseus}
-s [n-n:...]
Residue selection (e.g. -s15-45:50-55), {all}
-S [n-n:...]
Residues to exclude (e.g. -S15-45:50-55) {none}
The previous two options have the same format. Residue (or alignment column) ranges are indicated
by beginning and end separated by a dash. Multiple ranges, in any arbitrary order, are separated
by a colon. Chains may also be selected by giving the chain ID immediately preceding the residue
range. For example, -sA1-20:A40-71 will only include residues 1 through 20 and 40 through 70 in
chain A. Chains cannot be specified when superposing structures with different sequences.
-v use ML variance weighting (no correlations) {default}
Input/output options:
-A [sequence alignment file]
Sequence alignment file to use as a guide (CLUSTAL or A2M format)
For use when superposing structures with different sequences. See ``FILE FORMATS'' below.
-E Print expert options
-F Print FASTA files of the sequences in PDB files and quit
A useful option when superposing structures with different sequences. The files output with this
option can be aligned with a multiple sequence alignment program such as CLUSTAL or MUSCLE, and
the resulting output alignment file used as theseus input with the -A option.
-h Help/usage
-I Just calculate statistics for input file; don't superpose
-M [mapfile]
File that maps PDB files to sequences in the alignment.
A simple two-column formatted file; see ``FILE FORMATS'' below. Used with mode 2.
-n Don't write transformed pdb file
-o [reference structure]
Reference file to superpose on, all rotations are relative to the first model in this file
For example, 'theseus -o cytc1.pdb cytc1.pdb cytc2.pdb cytc3.pdb' will superpose the structures
and rotate the entire final superposition so that the structure from cytc1.pdb is in the same
orientation as the structure in the original cytc1.pdb PDB file.
-V Version
Principal components analysis:
-C Use covariance matrix for PCA (correlation matrix is default)
-P [nnn]
Number of principal components to calculate {0}
In both of the above, the corresponding principal component is written in the B-factor field of
the output PDB file. Usually only the first few PCs are of any interest (maybe up to six).
EXAMPLES theseus 2sdf.pdb
theseus -l -r new2sdf 2sdf.pdb
theseus -s15-45 -P3 2sdf.pdb
theseus -A cytc.aln -M cytc.mapfile -o cytc1.pdb -s1-40 cytc1.pdb cytc2.pdb cytc3.pdb cytc4.pdb
ENVIRONMENT
You can set the environment variable 'PDBDIR' to your PDB file directory and theseus will look there
after the present working directory. For example, in the C shell (tcsh or csh), you can put something
akin to this in your .cshrc file:
setenv PDBDIR '/usr/share/pdbs/'
FILE FORMATS
Theseus will read standard PDB formatted files (see <http://www.rcsb.org/pdb/>). Every effort has been
made for the program to accept nonstandard CNS and X-PLOR file formats also.
Two other files deserve mention, a sequence alignment file and a mapfile.
Sequence alignment file
When superposing structures with different residue identities (where the lengths of each the
macromolecules in terms of residues are not necessarily equal), a sequence alignment file must be
included for theseus to use as a guide (specified by the -A option). Theseus accepts both CLUSTAL and
A2M (FASTA) formatted multiple sequence alignment files.
NOTE 1: The residue sequence in the alignment must match exactly the residue sequence given in the
coordinates of the PDB file. That is, there can be no missing or extra residues that do not correspond to
the sequence in the PDB file. An easy way to ensure that your sequences exactly match the PDB files is to
generate the sequences using theseus' -F option, which writes out a FASTA formatted sequence file of the
chain(s) in the PDB files. The files output with this option can then be aligned with a multiple sequence
alignment program such as CLUSTAL or MUSCLE, and the resulting output alignment file used as theseus
input with the -A option.
NOTE 2: Every PDB file must have a corresponding sequence in the alignment. However, not every sequence
in the alignment needs to have a corresponding PDB file. That is, there can be extra sequences in the
alignment that are not used for guiding the superposition.
PDB -> Sequence mapfile
If the names of the PDB files and the names of the corresponding sequences in the alignemnt are
identical, the mapfile may be omitted. Otherwise, Theseus needs to know which sequences in the alignment
file correspond to which PDB structure files. This information is included in a mapfile with a very
simple format (specified with the -M option). There are only two columns separated by whitespace: the
first column lists the names of the PDB structure files, while the second column lists the corresponding
sequence names exactly as given in the multiple sequence alignment file.
An example of the mapfile:
cytc1.pdb seq1
cytc2.pdb seq2
cytc3.pdb seq3
SCREEN OUTPUT
Theseus provides output describing both the progress of the superposing and several statistics for the
final result:
Classical LS pairwise <RMSD>:
The conventional RMSD for the superposition, the average RMSD for all pairwise combinations of
structures in the ensemble.
Least-squares <sigma>:
The standard deviation for the superposition, based on the conventional assumption of no
correlation and equal variances. Basically equal to the RMSD from the average structure.
Maximum Likelihood <sigma>:
The ML analog of the standard deviation for the superposition. When assuming that the correlations
are zero (a diagonal covariance matrix), this is equal to the square root of the harmonic average
of the variances for each atom. In contrast, the ``Least-squares <sigma>'' given above reports the
square root of the arithmetic average of the variances. The harmonic average is always less than
the arithmetic average, and the harmonic average downweights large values proportional to their
magnitude. This makes sense statistically, because when combining values one should weight them by
the reciprocal of their variance (which is in fact what the ML superposing method does).
Marginal Log Likelihood:
The final marginal log likelihood of the superposition, assuming the matrix Gaussian distribution
of the structures and the hierarchical inverse gamma distribution of the eigenvalues of the
covariance matrix. The marginal log likelihood is the likelihood with the covariance matrix
integrated out.
AIC: The Akaike Information Criterion for the final superposition. This is an important statistic in
likelihood analysis and model selection theory. It allows an objective comparison of multiple
theoretical models with different numbers of parameters. In this case, the higher the number the
better. There is a tradeoff between fit to the data and the number of parameters being fit.
Increasing the number of parameters in a model will always give a better fit to the data, but it
also increases the uncertainty of the estimated values. The AIC criterion finds the best
combination by (1) maximizing the fit to the data while (2) minimizing the uncertainty due to the
number of parameters. In the superposition case, one can compare the least squares superposition
to the maximum likelihood superposition. The method (or model) with the higher AIC is preferred. A
difference in the AIC of 2 or more is considered strong statistical evidence for the better model.
BIC: The Bayesian Information Criterion. Similar to the AIC, but with a Bayesian emphasis.
Omnibus chi2:
The overall reduced chi2 statistic for the entire fit, including the rotations, translations,
covariances, and the inverse gamma parameters. This is probably the most important statistic for
the superposition. In some cases, the inverse gamma fit may be poor, yet the overall fit is still
very good. Again, it should ideally be close to 1.0, which would indicate a perfect fit. However,
if you think it is too large, make sure to compare it to the chi2 for the least-squares fit; it's
probably not that bad after all. A large chi2 often indicates a violation of the assumptions of
the model. The most common violation is when superposing two or more independent domains that can
rotate relative to each other. If this is the case, then there will likely be not just one
Gaussian distribution, but several mixed Gaussians, one for each domain. Then, it would be better
to superpose each domain independently.
Hierarchical var (alpha, gamma) chi2:
The reduced chi2 for the inverse gamma fit of the covariance matrix eigenvalues. As before, it
should ideally be close to 1.0. The two values in the parentheses are the ML estimates of the
scale and shape parameters, respectively, for the inverse gamma distribtuion.
Rotational, translational, covar chi2:
The reduced chi2 statistic for the fit of the structures to the model. With a good fit it should
be close to 1.0, which indicates a perfect fit of the data to the statistical model. In the case
of least-squares, the assumed model is a matrix Gaussian distribution of the structures with equal
variances and no correlations. For the ML fits, the assumed model is unequal variances and no
correlations, as calculated with the -v option [default]. This statistic is for the superposition
only, and does not include the fit of the covariance matrix eigenvalues to an inverse gamma
distribution. See ``Omnibus chi2'' below.
Hierarchical minimum var:
The hierarchical fit of the inverse gamma distribution constrains the variances of the atoms by
making large ones smaller and small ones larger. This statistic reports the minimum possible
variance given the inferred inverse gamma parameters.
skewness, skewness Z-value, kurtosis & kurtosis Z-value:
The skewness and kurtosis of the residuals. Both should be 0.0 if the residuals fit a Gaussian
distribution perfectly. They are followed by the P-value for the statistics. This is a very
stringent test; residuals can be very non-Gaussian and yet the estimated rotations, translations,
and covariance matrix may still be rather accurate.
Data pts, Free params, D/P:
The total number of data points given all observed structures, the number of parameters being fit
in the model, and the data-to-parameter ratio.
Median structure:
The structure that is overall most similar to the average structure. This can be considered to be
the most ``typical'' structure in the ensemble.
Total rounds:
The number of iterations that the algorithm took to converge.
Fractional precision:
The actual precision that the algorithm converged to.
OUTPUT FILES
Theseus writes out the following files:
theseus_sup.pdb
The final superposition, rotated to the principle axes of the mean structure.
theseus_ave.pdb
The estimate of the mean structure.
theseus_residuals.txt
The normalized residuals of the superposition. These can be analyzed for deviations from normality
(whether they fit a standard Gaussian distribution). E.g., the chi2, skewness, and kurtosis
statistics are based on these values.
theseus_transf.txt
The final transformation rotation matrices and translation vectors.
theseus_variances.txt
The vector of estimated variances for each atom.
When Principal Components are calculated (with the -P option), the following files are also produced:
theseus_pcvecs.txt
The principal component vectors.
theseus_pcstats.txt
Simple statistics for each principle component (loadings, variance explained, etc.).
theseus_pcN_ave.pdb
The average structure with the Nth principal component written in the temperature factor field.
theseus_pcN.pdb
The final superposition with the Nth principal component written in the temperature factor field.
This file is omitted when superposing molecules with different residue sequences (mode 2).
theseus_cor.mat, theseus_cov.mat
The atomic correlation matrix and covariance matrices, based on the final superposition. The
format is suitable for input to GNU's octave. These are the matrices used in the Principal
Components Analysis.
BUGS
Please send me (DLT) reports of all problems.
RESTRICTIONS
Theseus is not a structural alignment program. The structure-based alignment problem is completely
different from the structural superposition problem. In order to do a structural superposition, there
must be a 1-to-1 mapping that associates the atoms in one structure with the atoms in the other
structures. In the simplest case, this means that structures must have equivalent numbers of atoms, such
as the models in an NMR PDB file. For structures with different numbers of residues/atoms, superposing
is only possible when the sequences have been aligned previously. Finding the best sequence alignment
based on only structural information is a difficult problem, and one for which there is currently no
maximum likelihood approach. Extending theseus to address the structural alignment problem is an ongoing
research project.
AUTHOR
Douglas L. Theobald
dtheobald@brandeis.edu
CITATION
When using theseus in publications please cite:
Douglas L. Theobaldand Phillip A. Steindel (2012)
``Optimal simultaneous superpositioning of multiple structures with missing data.''
Bioinformatics 28(15):1972-1979
The following papers also report theseus developments:
Douglas L. Theobald and Deborah S. Wuttke (2008)
``Accurate structural correlations from maximum likelihood superpositions.''
PLoS Computational Biology 4(2):e43
Douglas L. Theobald and Deborah S. Wuttke (2006)
``THESEUS: Maximum likelihood superpositioning and analysis of macromolecular structures."
Bioinformatics 22(17):2171-2172
Douglas L. Theobald and Deborah S. Wuttke (2006)
``Empirical Bayes models for regularizing maximum likelihood estimation in the matrix Gaussian Procrustes
problem.''
PNAS 103(49):18521-18527
HISTORY
Long, tedious, and sordid.
Brandeis University 25 March 2015 THESEUS(1)