TPP:Developer Documentation
From SPCTools
This page will contain a tutorial for the TPP geared towards a code developer.
It should contain the minimum necessary mass spec and proteomics info necessary to get someone new to the field started.
Languages: C, C++, perl
Library requirements: expat-2.0.0 (copied to cvs), boost 1.32, xerces (version?)
cvs repository: sourceforge, project "sashimi"
cvs access:
Contents |
XML Parsing
perl
- xml tree
c++
- A. Keller's "tag" system
- J. Tasman code
Overview(from Readme)
Trans-Proteomic Pipeline (TPP)
Andrew Keller, ISB
08.11.04
System Requirements
Webserver
Webserver with access to data directories. Ideally, all data directories should be cross mounted under the webserver root. Webserver should have SSI (server side includes) turned on. If it is not already, you can activate the Web Server SSI (Server Side Includes)
Activating SSI on Linux
Modify the /etc/httpd.conf file:
In the document root <Directory> section, add +Includes to the end of already existing Options line:
Options +Includes
Uncomment or add in the mod_mime.c section:
AddType text/html .shtml AddHandler server-parsed .shtml
Then restart web server: /etc/rc.d/init.d/httpd restart
Webserver Root
The environment variable WEBSERVER_ROOT must be set for the program user(s) as well as the webserver. The WEBSERVER_ROOT should point to the webserver's document root directory (e.g. /home/httpd/html on linux, or ??? on windows ).
XSLT Processor
The TPP currently relies on an "xsl transform" processor for manipulating XML data.
- One such program, xsltproc, is usually distributed with Linux so
you most likely already have it. It should reside in the /usr/bin/ directory. If it is not already on your computer, you can download it for free at: http://xmlsoft.org/XSLT/downloads.html
- Another freely available XSLT processor, Xalan, will also work fine
with ProteinProphet. If you use it, just make sure it is installed in a directory already on the library path, or else set the LD_LIBRARY_PATH variable to include its location on the webserver: On Linux, Add LD_LIBRARY_PATH files to /etc/ld.so.conf Then type: ldconfig -v
The viewing of large xml files is sometimes slow. We are hoping to optimize the stylesheets in the future, and in some cases, bypass XSLT altogether.
Required libraries
You will need to install the following C libraries. These libraries are very common on linux distributions. Make sure that you do not already have them before trying to install. If you do need to install, first try to use the standard package system (e.g. RPMs for Fedora linux , cygwin installer for cygwin-- see below, etc.) If you cannot install them via the normal package system for your distribution, go to their website and download directly.
libgd www.boutell.com/gd libpng www.libpng.org zlib www.gzip.org/zlib
Windows users should get this by using the Cygwin installer (www.cygwin.com). Make sure to get the devel packages, in order to have the required .h files.
Configuration
Building from source
Linux only Skip ahead to Compilation for a Cygwin build. Note that we distribute precompiled binaries in a complete custom cygwin installation.
Edit src/Makefile.incl file
- Set the TPP_ROOT variable to the directory where you want to install the TPP,
include the trailing '/' when setting the path, e.g. TPP_ROOT=/usr/local/tpp/
- Set the TPP_WEB variable to the webserver root relative alias to the TPP, include the trailing '/' when setting the path, e.g.
TPP_WEB=/tpp/
WARNING: To avoid problems during the installation you MUST include the trailing '/' when setting the above two paths
- Set the XSLT_PROC to the path of the xsltproc executable on your system
XSLT_PROC=/usr/bin/xsltproc
In the src directory: type 'make configure' (once again, DON'T DO THIS for Windows/Cygwin!!!)
Compilation from source
Linux
In the src directory: type 'make all' to compile binaries
Windows/Cygwin
In the src directory: type 'make windows' to compile binaries
Installation
Linux
In the src directory: type 'make install' to install all the binaries
The TPP will be installed in the following directory structure by default:
/usr/local/tpp TPP root directory /usr/local/tpp/cgi-bin CGI-BIN for tpp, contains all web served executables /usr/local/tpp/bin binary directory /usr/local/tpp/html contains all non-executable web served objects /usr/local/tpp/etc contains miscelaneous configuration files /usr/local/tpp/schema contains all XML schema files
Windows/Cygwin
In the src directory: type 'make install-windows' to install all the binaries
Webserver Configuration
Linux
Add the appropriate web paths to the TPP as described below. If you are using the Apache http server, edit the active 'httpd.conf' file. Add the following Alias and ScriptAlias Directives as described below. Be sure to link to the appropriate tpp-version number.
# # ISB-Tools Trans Proteomic Pipeline directive # Alias /tpp/html "/usr/local/tpp/html" <Directory "/usr/local/tpp/html"> AllowOverride None Options Includes Indexes FollowSymLinks MultiViews Order allow,deny Allow from all </Directory>
<Directory "/usr/local/tpp/schema"> AllowOverride None Options Includes Indexes FollowSymLinks MultiViews Order allow,deny Allow from all </Directory>
ScriptAlias /tpp/cgi-bin/ "/usr/local/tpp/cgi-bin/" <Directory "/usr/local/tpp/cgi-bin"> AllowOverride AuthConfig Limit Options ExecCGI Order allow,deny Allow from all SetEnv WEBSERVER_ROOT /home/httpd/html </Directory>
Windows/Cygwin
Configure as described in "Post-Install Configuration" on the following page: [1]
Running the TPP
You need to start with a converter to write out search results as 'summary.xml' in pepXML format For SEQUEST results, you must specify the sequest.params file used for the search: In directory with summary.html and summary.mzXML (as well as the SEQUEST results .tgz or subdirectory), type: Sequest2XML summary.html -Psequest.params
For Mascot results, you must specify the database used for search: In the directory with summary.dat and summary.mzXML, type: Mascot2XML summary.dat -D/full/path/database
You can view the search results by opening the 'summary.xml' file in your browser.
Next, you can run xinteract to apply all or some parts of the pipeline. Type 'xinteract' with no arguments for usage instructions. You can also convert and run the pipeline in one step. See xinterct instructions for details.
To run the pipeline manually, starting with file1.xml and file2.xml:
1. Combine together data from 2 files: InteractParser interact.xml file1.xml file2.xml
Peptide Results can be viewed at any point along the analysis by opening the interact.shtml link.
2. Run PeptideProphet PeptideProphetParser interact.xml
3. Run XPRESS XPressPeptideParser interact.xml
4. Run ASAPRatio ASAPRatioPeptideParser interact.xml
5. Go into database to retrieve all proteins corresponding to identified peptides RefreshParser interact.xml /full/path/database
6. ProteinProphet ProteinProphet.pl interact.xml interact-prot.shtml XML_INPUT
From this point on, all analysis is on the output from ProteinProphet: interact-prot.xml Protein Results can be viewed at any point along the analysis by opening the interact-prot.shtml link.
7. XPRESS Protein XPressProteinParser interact-prot.xml
8. ASAPRatio Protein ASAPRatioProteinRatioParser interact-prot.xml
9. ASAPRatio Pvalue ASAPRatioPvalueParser interact-prot.xml
Questions? Contact Andrew Keller <akeller@systemsbiology.org>
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XML File Validation: The SAX Validator will use the schema location indicated in the XML file to validate: SAX2Count -v=always myfile.xml
Program Usage:
I. Converters to pepXML
Sequest2XML summary.html (-P/full/path/mysequest.params) (-M) (-m) (-a) (-pI) (-Eenzyme) Converts summary.html to summary.xml in pepXML format. Uses sequest.params file in current directory, unless specified as second argument -M: MALDI mode: do not include spectrum spot number in mzXML file name -m: monoisotopic masses (regardless of sequest.params setting) -a: average masses (regardless of sequest.params setting) -pI: compute peptide pI values -Eenzyme: set sample enzyme (default is trypsin, possible values are: nonspecific, chymotrypsin, elastase, gluc, gluc_bicarb, aspn, tca, cnbr, trypsin/cnbr, clostripain, iodosobenzoate, protein_endopeptidase, staph_protease, trypsin_k, trypsin_r)
Mascot2XML summary.dat -D/full/path/mydatabase.fasta (-pI) (-Eenzyme) Converts summary.dat to summary.xml in pepXML format. See Sequest2XML for option definitions Comet2XML summary.cmt.tar.gz (-Eenzyme) Converts summary.cmt.tar.gz to summary.xml in pepXML format. See Sequest2XML for option definitions
All converted pepXML files reference a standard sytlesheed pepXML_std.xsl to enable a view of the xml file directly in a browser.
II. Peptide-level analyses InteractParser interact.xml file1.xml file2.xml file3.xml ..... Merges together pepXML files file1.xml, file2.xml, file3.xml .... into interact.xml. Combines all analysis_summary elements, and reindexes spectrum_query elements. Makes a system call to pepxml2html.pl (pepxml2html.pl -file interact.xml) to create stylesheet for viewing interact.xml amd interact.shtml in a browser.
DatabaseParser interact.xml Prints the database(s) referenced in pepXML document
RefreshParser interact.xml /full/path/database.fasta Goes into database to find all proteins corresponding to identified peptides and overwrites results to interact.xml
EnzymeDigestionParser interact.xml (-Eenzyme) Computes number of tolerable termini and number of missed cleavages in dataset using sample enzyme stored in interact.xml unless specified as argument.
PeptideProphetParser interact.xml (EXCLUDE) (LEAVE) (ICAT) (NOICAT) (ZERO) (GLYC) (MALDI) (MINPROB=xx) Runs PeptideProphet with options and overwrites results to interact.xml : EXCLUDE: exclude delta stars (SEQUEST)
LEAVE: leave delta star values alone (SEQUEST)
ICAT: use peptide icat info in probability calculation NOICAT: do not use peptide icat info in probability calculation ZERO: do not discard any data GLYC: use peptide NXS/T motif info in probability calculation MALDI: specify maldi spectra PI: use pI information ACCMASS: use accurate mass binning MINPROB=xx: filter away results with a probability less than xx EXTRAITRS=xx: specify additional EM iterations
XPressPeptideParser interact.xml (-b) (-n<str>,<num>) (-n<str>,<num>) (-n<str>,<num>) (-L or -H) Runs XPRESS with options and overwrites results to interact.xml Options: -m<num> change XPRESS mass tolerance (default=1.0)
-l<str> change labeled residues (default='C') -r<num> change XPRESS residue mass difference (default=9.0)
-n<str>,<num> when specifying multiple isotopic labels, use this option e.g. -nK,3.0 -nL,3.0 -r<num> change XPRESS residue mass difference (default=9.0) -b heavy labeled peptide elutes before light labeled partner -L for ratio, set/fix light to 1, vary heavy -H for ratio, set/fix heavy to 1, vary light
ASAPRatioPeptideParser interact.xml (-b) (-l<str>) (-S) (-m<str>) (-F) (-C) Runs ASAPRatio with options and overwrites results to interact.xml Options: -l<str> change labeled residues (default='C') -b heavy labeled peptide elutes before light labeled partner -f<num> areaFlag set to num (ratio display option) -S static modification quantification (i.e. each run is either all light or all heavy) -F use fixed scan range for light and heavy -C quantitate only the charge state where the CID was made -m<str> specified label masses (e.g. M74.325Y125.864), only relevant for static modification quantification
LibraPeptideParser interact.xml -clibra_condition.xml Runs LIBRA using channel information specified in libra_condition.xml file and overwrites results to interact.xml
CompactParser file.xml Compacts either pepXML or protXML, combining together start and end tags when no elements are contained between them
III. Protein-level analyses ProteinProphet.pl '<interact pep prob html file1><interact pep prob html file2>....' <outfile> (ICAT) (GLYC) (XPRESS) (ASAP_PROPHET) (ACCURACY) (ASAP) (REFRESH) (DELUDE) (NOOCCAM)
NOOCCAM: non-conservative maximum protein list ICAT: highlight peptide cysteines GLYC: highlight peptide N-glycosylation motif ACCURACY: min pep prob 0 ASAP: compute ASAP ratios for protein entries (ASAP must have been run previously on interact dataset) REFRESH: import manual changes to ASAP ratios (after initially using ASAP option) ASAP_PROPHET: *New and Improved* compute ASAP ratios for protein entries (ASAP must have been run previously on all input interact datasets with mz/XML raw data format) DELUDE: do NOT use peptide degeneracy information when assessing proteins HTML: write output to static html page (rather than dynamic shtml) Other options in conjunction with HTML: EXCELPEPS: write output tab delim xls file including all peptides EXCELxx: write output tab delim xls file including all protein (group)s with minimum probability xx, where xx is a number between 0 and 1
XPressProteinRatioParser interact-prot.xml Runs XPRESS and overwrites results to interact-prot.xml
ASAPRatioProteinRatioParser interact-prot.xml Runs ASAPRatio and overwrites results to interact-prot.xml
LibraProteinRatioParser interact-prot.xml <normalization_channel> Runs LIBRA using normalizing ratios to normalization_channel and overwrites results to interact-prot.xml
IV. Wrappers
xinteract:
usage: xinteract (generaloptions) (-Oprophetoptions) (-Xxpressoptions) (-Aasapoptions) (-L<conditionfile>libraoptions) xmlfile1 xmlfile2 ....
generaloptions: -Nmyfile.xml [write output to file 'myfile.xml'] -nI [do not run Interact (convert to pepXML only)] -nP [do not run PeptideProphet] -nR [do not run get all proteins corresponding to degenerate peptides from database] -p0 [do not discard search results with PeptideProphet probabilities below 0.05] -x<num> [number of extra PeptideProphet interations; default <num>=0] -p<num> [filter results below PeptideProphet probability <num>; default <num>=0.05] -mw [calculate protein molecular weights] -MONO [calculate monoisotopic peptide masses during conversion to pepXML] -AVE [calculate average peptide masses during conversion to pepXML] -eX [specify sample enzyme other than trypsin] -eC [specify sample enzyme = Chymotrypsin] -eA [specify sample enzyme = AspN] -eG [specify sample enzyme = GluC] -eB [specify sample enzyme = GluC Bicarb] -eM [specify sample enzyme = CNBr] -eD [specify sample enzyme = Trypsin/CNBr] -e3 [specify sample enzyme = Chymotrypsin/AspN/Trypsin] -eE [specify sample enzyme = Elastase] -eL [specify sample enzyme = LysN (cuts before K)] -eP [specify sample enzyme = LysN Promisc (cuts before KASR)] -eN [specify sample enzyme = Nonspecific or None]
For developers: -t [run regression test against a previously derived result] -t! [learn results for regression test]
prophetoptions [following the 'O']: i [use icat information in PeptideProphet] f [do not use icat information in PeptideProphet] g [use N-glyc motif information in PeptideProphet] m [maldi data] I [use pI information in PeptideProphet]
A [use accurate mass binning in PeptideProphet]
w [warning instead of exit with error if instrument types between runs is different] x [exclude all entries with asterisked score values in PeptideProphet] l [leave alone all entries with asterisked score values in PeptideProphet]
p [run ProteinProphet afterwards] u [do not assemble protein groups in ProteinProphet analysis] s [do not use Occam's Razor in ProteinProphet analysis to derive the simplest protein list to explain observed peptides]
xpressoptions [will run XPRESS analysis with any specified options that follow the 'X']: -m<num> change XPRESS mass tolerance (default=1.0) -l<str> change labeled residues (default='C') -n<str>,<num> change XPRESS residue mass difference for <str> to <num> (default=9.0) -b heavy labeled peptide elutes before light labeled partner -L for ratio, set/fix light to 1, vary heavy -H for ratio, set/fix heavy to 1, vary light
asapoptions [will run ASAPRatio analysis with any specified options that follow the 'A']: -l<str> change labeled residues (default='C') -b heavy labeled peptide elutes before light labeled partner -f<num> areaFlag set to num (ratio display option) -S static modification quantification (i.e. each run is either all light or all heavy) -F use fixed scan range for light and heavy -C quantitate only the charge state where the CID was made -m<str> specified label masses (e.g. M74.325Y125.864), only relevant for static modification quantification
libraoptions [will run Libra Quantitation analysis with any specified options that follow the 'L']: -<num> normalization channel (for protein level quantitation)
examples: xinteract *.xml [combines together data in all pepXML files into 'interact.xml', then runs PeptideProphet] xinteract -Ndata.xml *.xml [same as above, but results are written to 'data.xml'] xinteract -Ndata.xml -X -Op *.xml [same as above, but run XPRESS analysis in its default mode, then ProteinProphet] xinteract -X -A file1.xml file2.xml [combines together data in file1.xml and file2.xml into 'interact.xml' and then runs XPRESS (in its default mode) and ASAPRatio (in its default mode)] xinteract -X-nC,6.0 -A file1.xml file2.xml [same as above, but specifies that cysteine label has a heavy/light mass difference of 6.0] xinteract -X -A-lDE-S file1.xml file2.xml [sampe as above, but specifies for ASAP to run in static mode with labeled residues D and E] xinteract -Lmyconditionfile.xml-1 -Op file1.xml file2.xml [run libra quantitiation after PeptideProphet using myconditionfile.xml, and after ProteinProphet normalizing ratios to channel 1 values
runpropet:
Runs ProteinProphet on designated 'interact.xml' file(s)
How to use runprophet:
usage 1: specify input file and options
runprophet -Ooptions <interact file (with probs)>
runs analysis on inputfile with specified options, writes analysis to inputfile-prot.htm options: i: icat data (color Cysteines) g: N-glycosylation data (color NXS/T) m: multifiles (more than one interact.xml file, must specify outfile d: delude (do not look up ALL prots corresponding to degenerate peps) l: use html input files (pre-TPP) X: import XPRESS protein ratios A: import ASAPRatio protein ratios and pvalues L<num>: import Libra protein ratios normalized to channel <num> a: import ASAPRatio results present in file (starting from scratch) r: update changes made to ASAPRatio results (previously run using 'a' option) n: don't use occam's razor for degenerate peps (get max prot list, including many false positives) u: do not assemble PROTEIN GROUPS z: do not include zero probability protein entries in output H: writes results to static html file (and tab delimited excel file) P: includes peptides in tab delimited excel file (must accompany 'H') xx: includes results in tab delimited excel file with minimum probability xx, where xx is a number between 0 and 1 (must accompany 'H')
example: runprophet -OiXA interact.xml (for icat data with mzXML XPRESS and ASAPRatio quantitation information) example: runprophet -Oia interact.xml (for icat data with non-mzXML ASAPRAtio information) example: runprophet -Oi interact.xml (for icat data) example: runprophet -Og interact.xml (for N-glycosylated data) example: runprophet -OL interact.htm (for pre-TPP html input file)
usage 2: specify input file and use default options
runprophet <interact file (with probs)>
runs analysis on inputfile using default options, writes analysis to inputfile-prot.htm
example: runprophet interact.xml (writes output to file: interact-prot.shtml)
usage 3: specify output file
runprophet (-Ooptions) <interact file (with probs)> <outputfile>
runs analysis on inputfile (with specified options), writes analysis to specified outputfile
example: runprophet interact.xml protein.shtml (writes output to file: protein.shtml)
usage 4: combine multiple datasets into a single analysis
runprophet -Om(options) <interactfile1 interactfile2 ...> <outputfile>
runs analysis on multiple inputfiles (with specified options), writes analysis to specified outputfile
example: runprophet -Oim interact-1.xml interact-2.xml protein.shtml (analyzes interact-1.xml and interact-2.xml icat data together and writes output to file: protein.shtml)
usage 5: options for static html output
example: runprophet -OHP0.9 interact.xml writes results to static html file, and results with min prob 0.9 (including peptides) to tab delimited excel file
Note: All Parser programs (children of Parser.cxx) parse pepXML and protXML with the constrain that all text be enclosed within a 'tag'
such as the following example:
<mytag name="akeller">
<email address="akeller@systemsbiology.org/>
</mytag>
NOT ACCEPTABLE are files with text outside of a bracket tag enclosure, such as 'akeller' in the following illegal example: <illegaltag>akeller</illegaltag>
CREDITS: The refreshparser program uses the SPARE Parts by Bruce W. Watson / Loek Cleophas.