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A genomics pipeline build on top of the GATK Queue framework. Main repository: https://github.com/NationalGenomicsInfrastructure/piper (make sure you fork from there)

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A pipeline project started at the SNP&SEQ Technology platform built on top of GATK Queue. Since then Piper has been adopted by the Swedish National Genomics Infrastructure (NGI) for use on all human whole genome samples sequenced at NGI.

Piper builds on the concept of standardized workflows for different next-generation sequencing applications. At the moment Piper supports the following workflows:

  • WholeGenome: For human whole genome sequencing data. This goes through alignment, alignment quality control, data processing, variant calling, and variant filtration according to the best practice recommended by the Broad Institute, using primarily the GATK.
  • Exome: TruSeq and SureSelect human exome sequencing: These use basically the same pipeline as the whole genome pipeline, but with the modifications suggested in the best practice document for exome studies.
  • Haloplex: Haloplex targeted sequencing analysis. Including alignment, data processing, and variant calling.
  • RNACounts: Produces FPKMs for transcripts of an existing reference annotation using Tophat for mapping and Cufflinks to produce the FPKMs.

All supported workflows are available in the workflows directory in the project root.

Prerequisites and installation

Piper has been tested on the Java(TM) SE Runtime Environment (build 1.7.0_25) on the UPPMAX cluster Milou. It might run in other environments, but this is untested. Besides the JVM, Piper depends on Maven (version 3+) for building (the GATK), SBT and git to checkout the source. To install piper, make sure that these programs are in you path and then clone this repository and run the setup script:

git clone https://github.com/NationalGenomicsInfrastructure/piper.git
cd piper
sbt universal:packageBin
# This will create two zip files.
# Unzip these where you wish to install piper
./piper/target/universal/piper-v[version].zip
./setup-file-creator/target/universal/setupfilecreator-v[version].zip
# Then add the workflows and piper bin folders to your PATH, e.g.
export PATH=$PATH:/path/to/piper/bin:/path/to/piper/workflows
# You also need to add the setupcreator to the path
export PATH=$PATH:path/to/setupfilecreator/bin

As Piper acts as a wrapper for several standard bioinformatics programs, it requires that these are installed. At this point it requires that the following programs are installed (depending somewhat on the application):

The paths for these programs are setup in the uppmax_global_config.xml file. If you are running on UPPMAX these should already be pointing to the correct locations. If not, you need to change them there.

Resource files

For the standard application of alignment, data processing, and variant calling in human data, Piper relies on data available in the GATK bundle from the Broad Institute. This is available for download from their website. If you are working on UPPMAX these resources are available at /pica/data/uppnex/reference/biodata/GATK/ftp.broadinstitute.org/bundle/2.8/, however you might want to create your own directory for these in which you soft link the files, as you will be required to create, for example, bwa indexes.

The path to the GATK bundle needs to be setup in the globalConfig.sh.

Running the pipeline

There are a number of workflows currently supported by Piper (See below). For most users these should just be called accoring to the run examples below. If you want to make customizations, open the appropriate workflow bash script and make the changes there. If you need to know what parameters are available, run the script with --help, e.g:

piper -S <path to Script> --help

Setup for run

All workflows start with an xml file, for example: pipelineSetup.xml. This contains information about the raw data (run folders) that you want to run in the project. This is created using the setupFileCreator command.

** Directory structures and report files** Piper depends on one of two specifications for folder structure to be parse metadata about the samples. The first structure looks like this (and is the one used by projects at the SNP&SEQ technology platform in Uppsala):

Top level
|---Runfolder1
    |---report.xml/report.tsv
    |---Sample_1
        |--- 1_<index>_<lane>_<read1>_xxx.fastq.gz
        |--- 1_<index>_<lane>_<read2>_xxx.fastq.gz (optional)
    |---Sample_2
        |--- 2_<index>_<lane>_<read1>_xxx.fastq.gz
        |--- 2_<index>_<lane>_<read2>_xxx.fastq.gz (optional)
|---Runfolder1
    |---report.xml/report.tsv
    |---Sample_1
        |--- 1_<index>_<lane>_<read1>_xxx.fastq.gz
        |--- 1_<index>_<lane>_<read2>_xxx.fastq.gz (optional)
    |---Sample_2
        |--- 2_<index>_<lane>_<read1>_xxx.fastq.gz
        |--- 2_<index>_<lane>_<read2>_xxx.fastq.gz (optional)

As evident from this, the structure of each runfolder needs to have a file named either report.xml or report.tsv. In the report.xml file case, this is a file that is generated by the software Sisyphus, which is used by the SNP&SEQ Technology Platform to process data. If your data is not delivered from the SNP&SEQ Technology Platform you are probably better off using the simple report.tsv format. This is a tab-separated file with the following format:

    #SampleName     Lane    ReadLibrary     FlowcellId
    MyFirstSample   1       FirstLib        9767892AVF
    MyFirstSample   2       SecondLib       9767892AVF
    MySecondSample  1       SomeOtherLib    9767892AVF

The other allowed format is the Illumina Genome Network (IGN) file structure as it has been defined by the NGI.

Project top level
|---Sample
    |---Library
        |---Runfolder
           |--- <project>_<sample_name>_<index>_<lane>_xxx.fastq.gz

Running non-interactively Run setupFileCreator without any arguments. This will show you the list of parameters that you need to set. This will produce a setup file on the following format:

<?xml version="1.0" encoding="UTF-8" standalone="yes"?>
<project xmlns="setup.xml.molmed">
    <metadata>
        <name>NA-001</name>
        <sequenceingcenter>NGI</sequenceingcenter>
        <platform>Illumina</platform>
        <uppmaxprojectid>a2009002</uppmaxprojectid>
        <uppmaxqos></uppmaxqos>
        <reference>/home/MOLMED/johda411/workspace/piper/src/test/resources/testdata/exampleFASTA.fasta</reference>
    </metadata>
    <inputs>
        <sample>
            <samplename>F15</samplename>
            <library>
                <libraryname>SX396_MA140710.1</libraryname>
                <platformunit>
                    <unitinfo>000000000-AA3LB.1</unitinfo>
                    <fastqfile>
                        <path>/home/MOLMED/johda411/workspace/piper/140812_M00485_0148_000000000-AA3LB/Projects/MD-0274/140812_M00485_0148_000000000-AA3LB/Sample_F15/F15_CCGAAGTA_L001_R1_001.fastq.gz</path>
                    </fastqfile>
                    <fastqfile>
                        <path>/home/MOLMED/johda411/workspace/piper/140812_M00485_0148_000000000-AA3LB/Projects/MD-0274/140812_M00485_0148_000000000-AA3LB/Sample_F15/F15_CCGAAGTA_L001_R2_001.fastq.gz</path>
                    </fastqfile>
                </platformunit>
            </library>
        </sample>
        <sample>
            <samplename>E14</samplename>
            <library>
                <libraryname>SX396_MA140710.1</libraryname>
                <platformunit>
                    <unitinfo>000000000-AA3LB.1</unitinfo>
                    <fastqfile>
                        <path>/home/MOLMED/johda411/workspace/piper/140812_M00485_0148_000000000-AA3LB/Projects/MD-0274/140812_M00485_0148_000000000-AA3LB/Sample_E14/E14_AGTCACTA_L001_R2_001.fastq.gz</path>
                    </fastqfile>
                    <fastqfile>
                        <path>/home/MOLMED/johda411/workspace/piper/140812_M00485_0148_000000000-AA3LB/Projects/MD-0274/140812_M00485_0148_000000000-AA3LB/Sample_E14/E14_AGTCACTA_L001_R1_001.fastq.gz</path>
                    </fastqfile>
                </platformunit>
            </library>
        </sample>
        <sample>
            <samplename>P1171_104</samplename>
            <library>
                <libraryname>A</libraryname>
                <platformunit>
                    <unitinfo>AC41A2ANXX.2</unitinfo>
                    <fastqfile>
                        <path>/home/MOLMED/johda411/workspace/piper/src/test/resources/testdata/Sthlm2UUTests/sthlm_runfolder_root/P1171_104/A/140702_AC41A2ANXX/P1171_104_ATTCAGAA-GGCTCTGA_L002_R1_001.fastq.gz</path>
                    </fastqfile>
                </platformunit>
                <platformunit>
                    <unitinfo>AC41A2ANXX.1</unitinfo>
                    <fastqfile>
                        <path>/home/MOLMED/johda411/workspace/piper/src/test/resources/testdata/Sthlm2UUTests/sthlm_runfolder_root/P1171_104/A/140702_AC41A2ANXX/P1171_104_ATTCAGAA-GGCTCTGA_L001_R1_001.fastq.gz</path>
                    </fastqfile>
                    <fastqfile>
                        <path>/home/MOLMED/johda411/workspace/piper/src/test/resources/testdata/Sthlm2UUTests/sthlm_runfolder_root/P1171_104/A/140702_AC41A2ANXX/P1171_104_ATTCAGAA-GGCTCTGA_L001_R2_001.fastq.gz</path>
                    </fastqfile>
                </platformunit>
            </library>
        </sample>
    </inputs>
</project>

Running

Pick the workflow (they are located in the Piper directory under workflows) that you want to run, e.g. haloplex. Then initiate it (by simply running it, or if you do not have access to a node where you can continually run a JVM by using sbatch to send it to a node) accoding to the examples below.

Note that all workflows are by default setup to be run with the human_g1k_v37.fasta reference and associated annotations. This means that if you need some other reference, you will have to set it up manually by configuring the workflow script (and depending somewhat on the use case, make changes to the qscripts themself).

It's also worth mentioning that all the scripts have a optional alignments_only flag which can be set if you are only interested in running the aligments. This is useful what you are working on a project where data is added over time, but you want to create the aligments as data comes in, and then join across the sequencing runs and continue with the downstream analysis.

Unless the run flag is added to the workflow commandline the pipeline will only dry run (i.e. it will not actually run any jobs), this is useful to make sure that all commandline have been setup up properly. Once you are happy with the setup add run to the commandline to run the pipeline.

Haloplex

Haloplex.sh --xml_input <setup.xml> --intervals <regions file> --amplicons <amplicon file> [--alignments_only] [--run]

The files associated with the Haloplex design can be downloaded from Agilent's homepage. Please note that the design files will be converted to interval files to work with Picard. In this process the names in the files are converted to work with the "b37" genome reference, rather than "hg19", which is the reference used by agilent. This means that if you want to use "hg19" then you must specify the --do_not_convert flag in the qscript.

RNACounts

RNACounts.sh --xml_input <setup.xml> --library_type <fr-secondstrand/fr-firststrand/fr-unstranded> [--alignments_only] [--run]

Library types depends on the protcol used. For example, for ScriptSeq libraries (EpiCentre) the library type should be set to fr-secondstrand.

Exome

Exome.sh --xml_input <setup.xml> <--sureselect> || <--truseq> [--alignments_only] [--run]

Pick one of either --sureselect or --truseq to set which exome intervals should be used. If you wish to use another interval file - open up the workflow file and set the INTERVALS to the path of your interval file.

WholeGenome

WholeGenome.sh --xml_input <setup.xml> [--alignments_only] [--run]

Monitoring progress

To follow the progress of the run look in the pipeline_output/logs folder. There you will find the logs for the different scripts. By searching the log file for "Run", you can see how many jobs are currently running, how many have finished, and how many have failed. A recommendation is to use e.g. less -S to view the file with unwrapped lines, as it is quite difficult to read otherwise.

Development

The heavy lifting in Piper is primarily done in Scala, with Bash glueing together the different scripts to into workflows. Some additional Java and the occasional Perl component is used, but the main body of the code is written in Scala.

Coding

For an introduction to Queue, on which Piper is built, see: http://gatkforums.broadinstitute.org/discussion/1306/overview-of-queue

To work on the Piper project I recommend using the Scala IDE. To start developing follow the installation procedure outlined above. When you have finised the installation you can set the project up for your IDE by running:

sbt eclipse

This will create the necessary project file for you to be able to import the project into the Scala IDE and start developing.

Although the Scala IDE will compile the code as you type, you will probably also want to get the hang of a few basic SBT commands (which you can either run from the interactive sbt console which you start by typing sbt in the project root folder, or by typing sbt <command> to run it straight from the CLI):

compile

Will compile your project.

clean

If something looks strange it is probably a good idea to run this. It deletes all of your class files so that you can be sure you have a totally clean build.

test

Run the tests (for more on testing, see the testing chapter) - note that by default this only dry runs the qscript integration tests, which basically makes sure that they compile, but giving you no guarantees for runtime functionality.

Making Piper generate graph files

Queue includes functionallity to generate dot files to visualize the jobs graph. This is highly useful when debugging new qscripts as it lets you see how the jobs connect to one another. So, if you have made a mistake in the chaining of the dependencies it is easy to spot. ".dot" files can be opened with e.g. xdot.

Using the XML binding compiler (xjc):

To generate the xml read classes I use xjc, which uses an xml schema in xsd format to generate a number of java classes, which can then be used to interact with the setup and report xml files. These classes are used by the SetupXMLReader and the SetupFileCreator. An example of how to generate the classes is seen below:

 xjc -d piper/src/main/java/ piper/src/main/resources/xml_schemas/PipelineSetupSchema.xsd

Testing

Running pipeline tests

Running the tests is done by sbt test. However, there are some things which need to be noted. As the pipeline tests take a long time and have dependencies on outside programs (such as bwa for alignment, etc.) these can only be run on machines that have all the required programs installed and that have all the correct resources. This means that by default the tests are setup to just compile the qscripts, but not run them. If you want to run the qscripts you need to go into src/test/resources/testng.xml and set the value of the runpipeline parameter to 'true'.

Writing pipeline tests

Pipeline tests are setup to run a certain QScript and check the md5sums of the outputs. If md5sums do not match, it will show you what the differences between the files are so that you can decide if the changes to the output are reasonable considering the changes to the code you have made. At the moment, pipeline tests are just setup to run (with all the necessary resources, etc) on my workstation. In furture versions I hope to be able to make this more portable.

Continuous integration using Travis:

Piper uses Travis for continious integration. For instruction on how to set this up with a github repository see: http://about.travis-ci.org/docs/user/getting-started/

Troubleshooting

Old projects

In projects where data was generated before the spring of 2013, the report.xml files do not fulfill the current specification. To fix this you need to find the following row in the report.xml:

<SequencingReport>

and substitute it for:

<SequencingReport  xmlns="illuminareport.xml.molmed">

Licence

The MIT License (MIT)

Copyright (c) 2013 The SNP&SEQ Technology Platform, Uppsala

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.