Explore Workflows
View already parsed workflows here or click here to add your own
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project-workflow-sv.cwl
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https://github.com/mskcc/argos-cwl.git
Path: project-workflow-sv.cwl Branch/Commit ID: 0b9721d7d512352c7f80b27f42b3192a585ed5f6 |
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project-workflow.cwl
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https://github.com/mskcc/argos-cwl.git
Path: project-workflow.cwl Branch/Commit ID: 0b9721d7d512352c7f80b27f42b3192a585ed5f6 |
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structural-variants-pair.cwl
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https://github.com/mskcc/argos-cwl.git
Path: modules/pair/structural-variants-pair.cwl Branch/Commit ID: 0b9721d7d512352c7f80b27f42b3192a585ed5f6 |
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GATKBaseRecalBQSRWorkflow_4_1_3.cwl
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https://github.com/PMCC-BioinformaticsCore/janis-pipelines.git
Path: janis_pipelines/wgs_somatic/cwl/tools/GATKBaseRecalBQSRWorkflow_4_1_3.cwl Branch/Commit ID: b4550175be9d485d509c61d87fddf88a8bdb70c1 |
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Motif Finding with HOMER with custom background regions
Motif Finding with HOMER with custom background regions --------------------------------------------------- HOMER contains a novel motif discovery algorithm that was designed for regulatory element analysis in genomics applications (DNA only, no protein). It is a differential motif discovery algorithm, which means that it takes two sets of sequences and tries to identify the regulatory elements that are specifically enriched in on set relative to the other. It uses ZOOPS scoring (zero or one occurrence per sequence) coupled with the hypergeometric enrichment calculations (or binomial) to determine motif enrichment. HOMER also tries its best to account for sequenced bias in the dataset. It was designed with ChIP-Seq and promoter analysis in mind, but can be applied to pretty much any nucleic acids motif finding problem. For more information please refer to: ------------------------------------- [Official documentation](http://homer.ucsd.edu/homer/motif/) |
https://github.com/datirium/workflows.git
Path: workflows/homer-motif-analysis-bg.cwl Branch/Commit ID: ebbf23764ede324cabc064bd50647c1f643726fa |
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Kraken2 Database installation pipeline
This workflow downloads the user-selected pre-built kraken2 database from: https://benlangmead.github.io/aws-indexes/k2 ### __Inputs__ Select a pre-built Kraken2 database to download and use for metagenomic classification: - Available options comprised of various combinations of RefSeq reference genome sets: - [Viral (0.5 GB)](https://genome-idx.s3.amazonaws.com/kraken/k2_viral_20221209.tar.gz), all refseq viral genomes - [MinusB (8.7 GB)](https://genome-idx.s3.amazonaws.com/kraken/k2_minusb_20221209.tar.gz), standard minus bacteria (archaea, viral, plasmid, human1, UniVec_Core) - [PlusPFP-16 (15.0 GB)](https://genome-idx.s3.amazonaws.com/kraken/k2_pluspfp_16gb_20221209.tar.gz), standard (archaea, bacteria, viral, plasmid, human1, UniVec_Core) + (protozoa, fungi & plant) capped at 16 GB (shrunk via random kmer downselect) - [EuPathDB46 (34.1 GB)](https://genome-idx.s3.amazonaws.com/kraken/k2_eupathdb48_20201113.tar.gz), eukaryotic pathogen genomes with contaminants removed (https://veupathdb.org/veupathdb/app) - [16S_gg_13_5 (73 MB)](https://genome-idx.s3.amazonaws.com/kraken/16S_Greengenes13.5_20200326.tgz), Greengenes 16S rRNA database ([release 13.5](https://greengenes.secondgenome.com/?prefix=downloads/greengenes_database/gg_13_5/), 20200326)\n - [16S_silva_138 (112 MB)](https://genome-idx.s3.amazonaws.com/kraken/16S_Silva138_20200326.tgz), SILVA 16S rRNA database ([release 138.1](https://www.arb-silva.de/documentation/release-1381/), 20200827) ### __Outputs__ - k2db, an upstream database used by kraken2 classification tool - compressed_k2db_tar, compressed and tarred kraken2 database directory file for download and use outside of scidap ### __Data Analysis Steps__ 1. download selected pre-built kraken2 database. 2. make available as upstream source for kraken2 metagenomic taxonomic classification. ### __References__ - Wood, D.E., Lu, J. & Langmead, B. Improved metagenomic analysis with Kraken 2. Genome Biol 20, 257 (2019). https://doi.org/10.1186/s13059-019-1891-0 |
https://github.com/datirium/workflows.git
Path: workflows/kraken2-databases.cwl Branch/Commit ID: 69643d8c15f5357a320aa7e2f6adb2e71302fd20 |
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chipseq-header.cwl
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https://github.com/datirium/workflows.git
Path: metadata/chipseq-header.cwl Branch/Commit ID: 69643d8c15f5357a320aa7e2f6adb2e71302fd20 |
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DiffBind - Differential Binding Analysis of ChIP-Seq or CUTß&RUN/Tag Peak Data
Differential Binding Analysis of ChIP-Seq or CUT&RUN/Tag Peak Data --------------------------------------------------- DiffBind processes ChIP-Seq or CUT&RUN/Tag data enriched for genomic loci where specific protein/DNA binding occurs, including peak sets identified by peak caller tools and aligned sequence read datasets. It is designed to work with multiple peak sets simultaneously, representing different ChIP or CUT&RUN/Tag experiments (antibodies, transcription factor and/or histone marks, experimental conditions, replicates) as well as managing the results of multiple peak callers. For more information please refer to: ------------------------------------- Ross-Innes CS, Stark R, Teschendorff AE, Holmes KA, Ali HR, Dunning MJ, Brown GD, Gojis O, Ellis IO, Green AR, Ali S, Chin S, Palmieri C, Caldas C, Carroll JS (2012). “Differential oestrogen receptor binding is associated with clinical outcome in breast cancer.” Nature, 481, -4. |
https://github.com/datirium/workflows.git
Path: workflows/diffbind.cwl Branch/Commit ID: 69643d8c15f5357a320aa7e2f6adb2e71302fd20 |
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SetParameterWorkflowMissing
This is a placeholder for a missing setting workflow. |
https://github.com/gammasim/workflows.git
Path: workflows/SetParameterWorkflowMissing.cwl Branch/Commit ID: bf4d4a44a543bcc04f4508ce020751c71550acf5 |
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genome-kallisto-index.cwl
Generates a FASTA file with the DNA sequences for all transcripts in a GFF file and builds kallisto index |
https://github.com/Barski-lab/workflows.git
Path: tools/genome-kallisto-index.cwl Branch/Commit ID: de847468843203ce92b6d19323c5fe77dc488e34 |
