Package: annotation Version: 1.10.0 Depends: R (>= 3.3.0), VariantAnnotation, AnnotationHub, Organism.dplyr, TxDb.Hsapiens.UCSC.hg19.knownGene, TxDb.Hsapiens.UCSC.hg38.knownGene, TxDb.Mmusculus.UCSC.mm10.ensGene, org.Hs.eg.db, org.Mm.eg.db, Homo.sapiens, BSgenome.Hsapiens.UCSC.hg19, biomaRt, BSgenome, TxDb.Athaliana.BioMart.plantsmart22 Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: e6222459bfadd2eee545556b05a3a48e NeedsCompilation: no Title: Genomic Annotation Resources Description: Annotation resources make up a significant proportion of the Bioconductor project. And there are also a diverse set of online resources available which are accessed using specific packages. This walkthrough will describe the most popular of these resources and give some high level examples on how to use them. biocViews: AnnotationWorkflow, Workflow Author: Marc RJ Carlson [aut], Herve Pages [aut], Sonali Arora [aut], Valerie Obenchain [aut], Martin Morgan [aut], Bioconductor Package Maintainer [cre] Maintainer: Bioconductor Package Maintainer URL: http://bioconductor.org/help/workflows/annotation/Annotation_Resources/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/annotation git_branch: RELEASE_3_10 git_last_commit: f387015 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/annotation_1.10.0.tar.gz vignettes: vignettes/annotation/inst/doc/Annotating_Genomic_Ranges.html, vignettes/annotation/inst/doc/Annotation_Resources.html vignetteTitles: Annotating Genomic Ranges, Genomic Annotation Resources hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/annotation/inst/doc/Annotating_Genomic_Ranges.R, vignettes/annotation/inst/doc/Annotation_Resources.R dependencyCount: 113 Package: arrays Version: 1.12.0 Depends: R (>= 3.0.0) Suggests: affy, limma, hgfocuscdf, knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: 292ecc51374cbcf27c24a841b4bf74fe NeedsCompilation: no Title: Using Bioconductor for Microarray Analysis Description: Using Bioconductor for Microarray Analysis workflow biocViews: Workflow, BasicWorkflow Author: Bioconductor Package Maintainer [aut, cre] Maintainer: Bioconductor Package Maintainer VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/arrays git_branch: RELEASE_3_10 git_last_commit: a5ad999 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/arrays_1.12.0.tar.gz vignettes: vignettes/arrays/inst/doc/arrays.html vignetteTitles: Using Bioconductor for Microarray Analysis hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/arrays/inst/doc/arrays.R dependencyCount: 0 Package: BgeeCall Version: 1.2.1 Depends: R (>= 3.6.0) Imports: GenomicFeatures, rhdf5, tximport, Biostrings, rtracklayer, biomaRt, jsonlite, methods, grDevices, graphics, stats, utils Suggests: knitr, testthat, rmarkdown, AnnotationHub, httr License: GPL-3 MD5sum: fadf9c411c5f487f80b227b26edf8bcd NeedsCompilation: no Title: automatic RNA-Seq present/absent gene expression calls generation Description: Reference intergenic regions are generated by the Bgee RNA-Seq pipeline. These intergenic regions are used to generate all Bgee RNA-Seq present/absent expression calls. BgeeCall now allows to generate present/absent calls for any RNA-Seq library as long as reference intergenic sequences have been generated for the corresponding species. The threshold of present/absent expression is no longer arbitrary defined but is calculated based on expression of all RNA-Seq libraries integrated in Bgee. biocViews: Software, GeneExpression, RNASeq Author: Julien Wollbrett [aut, cre], Julien Roux [aut], Sara Fonseca Costa [ctb], Marc Robinson Rechavi [ctb], Frederic Bastian [aut] Maintainer: Julien Wollbrett URL: https://github.com/BgeeDB/BgeeCall SystemRequirements: kallisto VignetteBuilder: knitr BugReports: https://github.com/BgeeDB/BgeeCall/issues git_url: https://git.bioconductor.org/packages/BgeeCall git_branch: RELEASE_3_10 git_last_commit: 288b8bb git_last_commit_date: 2020-03-09 Date/Publication: 2020-03-11 source.ver: src/contrib/BgeeCall_1.2.1.tar.gz vignettes: vignettes/BgeeCall/inst/doc/bgeecall-manual.html vignetteTitles: automatic RNA-Seq present/absent gene expression calls generation hasREADME: FALSE hasNEWS: TRUE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/BgeeCall/inst/doc/bgeecall-manual.R dependencyCount: 86 Package: BiocMetaWorkflow Version: 1.8.1 Suggests: BiocStyle, knitr, rmarkdown, BiocWorkflowTools License: Artistic-2.0 MD5sum: c5f8c1b0951965a82bc782a0bdb14c21 NeedsCompilation: no Title: BioC Workflow about publishing a Bioc Workflow Description: Bioconductor Workflow describing how to use BiocWorkflowTools to work with a single R Markdown document to submit to both Bioconductor and F1000Research. biocViews: BasicWorkflow Author: Mike Smith [aut, cre], Andrzej OleÅ› [aut], Wolfgang Huber [ctb] Maintainer: Mike Smith VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/BiocMetaWorkflow git_branch: RELEASE_3_10 git_last_commit: c4ab094 git_last_commit_date: 2020-03-27 Date/Publication: 2020-03-30 source.ver: src/contrib/BiocMetaWorkflow_1.8.1.tar.gz vignettes: vignettes/BiocMetaWorkflow/inst/doc/Authoring_BioC_Workflows.html vignetteTitles: Bioc Meta Workflow hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/BiocMetaWorkflow/inst/doc/Authoring_BioC_Workflows.R dependencyCount: 0 Package: CAGEWorkflow Version: 1.2.0 Depends: R (>= 3.6.0), CAGEfightR, nanotubes Suggests: knitr, kableExtra, rmarkdown, BiocStyle, BiocWorkflowTools, pheatmap, ggseqlogo, viridis, magrittr, ggforce, ggthemes, tidyverse, dplyr, GenomicRanges, SummarizedExperiment, GenomicFeatures, BiocParallel, InteractionSet, Gviz, DESeq2, limma, edgeR, statmod, BiasedUrn, sva, TFBSTools, motifmatchr, pathview, BSgenome.Mmusculus.UCSC.mm9, TxDb.Mmusculus.UCSC.mm9.knownGene, org.Mm.eg.db, JASPAR2016, png License: GPL-3 MD5sum: a376483a9766f90346585aed5067327a NeedsCompilation: no Title: A step-by-step guide to analyzing CAGE data using R/Bioconductor Description: Workflow for analyzing Cap Analysis of Gene Expression (CAGE) data using R/Bioconductor. biocViews: GeneExpressionWorkflow, AnnotationWorkflow Author: Malte Thodberg [aut, cre] Maintainer: Malte Thodberg VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/CAGEWorkflow git_branch: RELEASE_3_10 git_last_commit: 1757d03 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/CAGEWorkflow_1.2.0.tar.gz vignettes: vignettes/CAGEWorkflow/inst/doc/CAGEWorkflow.html vignetteTitles: CAGEWorkflow hasREADME: FALSE hasNEWS: TRUE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/CAGEWorkflow/inst/doc/CAGEWorkflow.R dependencyCount: 153 Package: chipseqDB Version: 1.10.0 Suggests: chipseqDBData, BiocStyle, BiocFileCache, ChIPpeakAnno, Gviz, Rsamtools, TxDb.Mmusculus.UCSC.mm10.knownGene, csaw, edgeR, knitr, org.Mm.eg.db, rtracklayer, rmarkdown License: Artistic-2.0 MD5sum: 0ec3e06cb02e7c5801d5ed2c95b7fccd NeedsCompilation: no Title: A Bioconductor Workflow to Detect Differential Binding in ChIP-seq Data Description: Describes a computational workflow for performing a DB analysis with sliding windows. The aim is to facilitate the practical implementation of window-based DB analyses by providing detailed code and expected output. The workflow described here applies to any ChIP-seq experiment with multiple experimental conditions and multiple biological samples in one or more of the conditions. It detects and summarizes DB regions between conditions in a de novo manner, i.e., without making any prior assumptions about the location or width of bound regions. Detected regions are then annotated according to their proximity to genes. biocViews: ImmunoOncologyWorkflow, Workflow, EpigeneticsWorkflow Author: Aaron Lun [aut, cre], Gordon Smyth [aut] Maintainer: Aaron Lun URL: https://www.bioconductor.org/help/workflows/chipseqDB/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/chipseqDB git_branch: RELEASE_3_10 git_last_commit: edc89f5 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/chipseqDB_1.10.0.tar.gz vignettes: vignettes/chipseqDB/inst/doc/cbp.html, vignettes/chipseqDB/inst/doc/h3k27me3.html, vignettes/chipseqDB/inst/doc/h3k9ac.html, vignettes/chipseqDB/inst/doc/intro.html vignetteTitles: 3. Differential binding of CBP in fibroblasts, 4. Differential enrichment of H3K27me3 in lung epithelium, 2. Differential enrichment of H3K9ac in B cells, 1. Introduction hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/chipseqDB/inst/doc/cbp.R, vignettes/chipseqDB/inst/doc/h3k27me3.R, vignettes/chipseqDB/inst/doc/h3k9ac.R, vignettes/chipseqDB/inst/doc/intro.R dependencyCount: 0 Package: csawUsersGuide Version: 1.2.0 Suggests: csaw, chipseqDBData, edgeR, TxDb.Mmusculus.UCSC.mm10.knownGene, org.Mm.eg.db, rtracklayer, Rsamtools, Gviz, knitr, BiocStyle License: GPL-3 MD5sum: 457661cb28628d1fa012d29a2f5bcfbe NeedsCompilation: no Title: csaw User's Guide Description: A user's guide for the csaw package for detecting differentially bound regions in ChIP-seq data. Describes how to read in BAM files to obtain a per-window count matrix, filtering to obtain high-abundance windows of interest, normalization of sample-specific biases, testing for differential binding, consolidation of per-window results to obtain per-region statistics, and annotation and visualization of the DB results. biocViews: Workflow, EpigeneticsWorkflow Author: Aaron Lun [aut, cre] Maintainer: Aaron Lun VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/csawUsersGuide git_branch: RELEASE_3_10 git_last_commit: a91ac9a git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/csawUsersGuide_1.2.0.tar.gz vignettes: vignettes/csawUsersGuide/inst/doc/csaw.pdf vignetteTitles: User's guide hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/csawUsersGuide/inst/doc/csaw.R dependencyCount: 0 Package: cytofWorkflow Version: 1.10.2 Depends: R (>= 3.6.0), BiocStyle, knitr, readxl, CATALYST, diffcyt, HDCytoData, uwot, cowplot Suggests: knitcitations License: Artistic-2.0 MD5sum: e40683acc9b763962531341647af79a4 NeedsCompilation: no Title: CyTOF workflow: differential discovery in high-throughput high-dimensional cytometry datasets Description: High-dimensional mass and flow cytometry (HDCyto) experiments have become a method of choice for high-throughput interrogation and characterization of cell populations. Here, we present an updated R-based pipeline for differential analyses of HDCyto data, largely based on Bioconductor packages. We computationally define cell populations using FlowSOM clustering, and facilitate an optional but reproducible strategy for manual merging of algorithm-generated clusters. Our workflow offers different analysis paths, including association of cell type abundance with a phenotype or changes in signaling markers within specific subpopulations, or differential analyses of aggregated signals. Importantly, the differential analyses we show are based on regression frameworks where the HDCyto data is the response; thus, we are able to model arbitrary experimental designs, such as those with batch effects, paired designs and so on. In particular, we apply generalized linear mixed models or linear mixed models to analyses of cell population abundance or cell-population-specific analyses of signaling markers, allowing overdispersion in cell count or aggregated signals across samples to be appropriately modeled. To support the formal statistical analyses, we encourage exploratory data analysis at every step, including quality control (e.g., multi-dimensional scaling plots), reporting of clustering results (dimensionality reduction, heatmaps with dendrograms) and differential analyses (e.g., plots of aggregated signals). biocViews: ImmunoOncologyWorkflow, Workflow, SingleCellWorkflow Author: Malgorzata Nowicka [aut, cre], Helena L. Crowell [aut], Mark D. Robinson [aut] Maintainer: Malgorzata Nowicka URL: https://github.com/markrobinsonuzh/cytofWorkflow VignetteBuilder: knitr BugReports: https://github.com/markrobinsonuzh/cytofWorkflow/issues git_url: https://git.bioconductor.org/packages/cytofWorkflow git_branch: RELEASE_3_10 git_last_commit: 78b59dd git_last_commit_date: 2019-10-31 Date/Publication: 2019-11-01 source.ver: src/contrib/cytofWorkflow_1.10.2.tar.gz vignettes: vignettes/cytofWorkflow/inst/doc/cytofWorkflow.html vignetteTitles: A workflow for differential discovery in high-throughput high-dimensional cytometry datasets hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE dependencyCount: 261 Package: EGSEA123 Version: 1.10.0 Depends: R (>= 3.4.0), EGSEA (>= 1.5.2), limma, edgeR, illuminaio Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: 79148d555bf4b120a8eaea67f54521db NeedsCompilation: no Title: Easy and efficient ensemble gene set testing with EGSEA Description: R package that supports the F1000Research workflow article `Easy and efficient ensemble gene set testing with EGSEA', Alhamdoosh et al. (2017). biocViews: ImmunoOncologyWorkflow, Workflow, GeneExpressionWorkflow Author: Monther Alhamdoosh, Charity Law, Luyi Tian, Julie Sheridan, Milica Ng and Matthew Ritchie Maintainer: Matthew Ritchie URL: https://www.bioconductor.org/help/workflows/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/EGSEA123 git_branch: RELEASE_3_10 git_last_commit: 2c1ea17 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/EGSEA123_1.10.0.tar.gz vignettes: vignettes/EGSEA123/inst/doc/EGSEAWorkflow.html vignetteTitles: Easy and efficient ensemble gene set testing with EGSEA hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/EGSEA123/inst/doc/EGSEAWorkflow.R dependencyCount: 172 Package: eQTL Version: 1.10.0 Depends: R (>= 3.3.0), GGdata, GGtools, GenomeInfoDb, S4Vectors, SNPlocs.Hsapiens.dbSNP144.GRCh37, bibtex, biglm, data.table, doParallel, foreach, knitcitations, lumi, lumiHumanAll.db, parallel, rmeta, scatterplot3d, snpStats, grid, yri1kgv Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: e938a58e269226da7ef02d441d1d1113 NeedsCompilation: no Title: Cloud-enabled cis-eQTL searches with Bioconductor GGtools 5.x Description: This workflow focuses on searches for eQTL in cis, so that DNA variants local to the gene assayed for expression are tested for association. biocViews: Workflow, GenomicVariantsWorkflow Author: Vincent Carey [aut, cre] Maintainer: Vincent Carey URL: https://www.bioconductor.org/help/workflows/eQTL/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/eQTL git_branch: RELEASE_3_10 git_last_commit: 5d9fc95 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/eQTL_1.10.0.tar.gz vignettes: vignettes/eQTL/inst/doc/cloudeqtl.html vignetteTitles: Cloud-enabled cis-eQTL searches with Bioconductor GGtools 5.x hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/eQTL/inst/doc/cloudeqtl.R dependencyCount: 216 Package: ExpressionNormalizationWorkflow Version: 1.12.0 Imports: Biobase (>= 2.24.0), limma (>= 3.20.9), lme4 (>= 1.1.7), matrixStats (>= 0.10.3), pvca (>= 1.4.0), snm (>= 1.12.0), sva (>= 3.10.0), vsn (>= 3.32.0) Suggests: knitr, BiocStyle License: GPL (>=3) MD5sum: 58ff35661085c111ddbfafc186a622d5 NeedsCompilation: no Title: Gene Expression Normalization Workflow Description: An extensive, customized expression normalization workflow incorporating Supervised Normalization of Microarryas(SNM), Surrogate Variable Analysis(SVA) and Principal Variance Component Analysis to identify batch effects and remove them from the expression data to enhance the ability to detect the underlying biological signals. biocViews: ImmunoOncologyWorkflow, Workflow, GeneExpressionWorkflow Author: Karthikeyan Murugesan [aut, cre], Greg Gibson [sad, ths] Maintainer: Karthikeyan Murugesan VignetteBuilder: knitr BugReports: https://github.com/ git_url: https://git.bioconductor.org/packages/ExpressionNormalizationWorkflow git_branch: RELEASE_3_10 git_last_commit: ef5e5c8 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/ExpressionNormalizationWorkflow_1.12.0.tar.gz vignettes: vignettes/ExpressionNormalizationWorkflow/inst/doc/genExpNrm.html vignetteTitles: Gene Expression Normalization Workflow hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/ExpressionNormalizationWorkflow/inst/doc/genExpNrm.R dependencyCount: 100 Package: generegulation Version: 1.10.0 Depends: R (>= 3.3.0), BSgenome.Scerevisiae.UCSC.sacCer3, Biostrings, GenomicFeatures, MotifDb, S4Vectors, TxDb.Scerevisiae.UCSC.sacCer3.sgdGene, motifStack, org.Sc.sgd.db, seqLogo Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: 8963192f75756e8b62926eb071be1a7f NeedsCompilation: no Title: Finding Candidate Binding Sites for Known Transcription Factors via Sequence Matching Description: The binding of transcription factor proteins (TFs) to DNA promoter regions upstream of gene transcription start sites (TSSs) is one of the most important mechanisms by which gene expression, and thus many cellular processes, are controlled. Though in recent years many new kinds of data have become available for identifying transcription factor binding sites (TFBSs) -- ChIP-seq and DNase I hypersensitivity regions among them -- sequence matching continues to play an important role. In this workflow we demonstrate Bioconductor techniques for finding candidate TF binding sites in DNA sequence using the model organism Saccharomyces cerevisiae. The methods demonstrated here apply equally well to other organisms. biocViews: Workflow, EpigeneticsWorkflow Author: Bioconductor Package Maintainer [aut, cre] Maintainer: Bioconductor Package Maintainer URL: https://www.bioconductor.org/help/workflows/generegulation/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/generegulation git_branch: RELEASE_3_10 git_last_commit: 354caaa git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/generegulation_1.10.0.tar.gz vignettes: vignettes/generegulation/inst/doc/generegulation.html vignetteTitles: Finding Candidate Binding Sites for Known Transcription Factors via Sequence Matching hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/generegulation/inst/doc/generegulation.R dependencyCount: 131 Package: highthroughputassays Version: 1.10.0 Depends: R (>= 3.3.0), flowCore, flowStats, flowWorkspace Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: e0477202a7897f4263a8847e736ea522 NeedsCompilation: no Title: Using Bioconductor with High Throughput Assays Description: The workflow illustrates use of the flow cytometry packages to load, transform and visualize the flow data and gate certain populations in the dataset. The workflow loads the `flowCore`, `flowStats` and `flowWorkspace` packages and its dependencies. It loads the ITN data with 15 samples, each of which includes, in addition to FSC and SSC, 5 fluorescence channels: CD3, CD4, CD8, CD69 and HLADR. biocViews: ImmunoOncologyWorkflow, Workflow, ProteomicsWorkflow Author: Bioconductor Package Maintainer [aut, cre] Maintainer: Bioconductor Package Maintainer URL: https://www.bioconductor.org/help/workflows/highthroughputassays/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/highthroughputassays git_branch: RELEASE_3_10 git_last_commit: a557886 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/highthroughputassays_1.10.0.tar.gz vignettes: vignettes/highthroughputassays/inst/doc/high-throughput-assays.html vignetteTitles: Using Bioconductor with High Throughput Assays hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/highthroughputassays/inst/doc/high-throughput-assays.R dependencyCount: 84 Package: liftOver Version: 1.10.0 Depends: R (>= 3.3.0), gwascat, GenomicRanges, rtracklayer, Homo.sapiens, BiocGenerics Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: 6e4bdc5829fd5792d2db62a39eaa1c9b NeedsCompilation: no Title: Changing genomic coordinate systems with rtracklayer::liftOver Description: The liftOver facilities developed in conjunction with the UCSC browser track infrastructure are available for transforming data in GRanges formats. This is illustrated here with an image of the EBI/NHGRI GWAS catalog that is, as of May 10 2017, distributed with coordinates defined by NCBI build hg38. biocViews: Workflow, BasicWorkflow Author: Bioconductor Package Maintainer [aut, cre] Maintainer: Bioconductor Package Maintainer URL: https://www.bioconductor.org/help/workflows/liftOver/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/liftOver git_branch: RELEASE_3_10 git_last_commit: 158928a git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/liftOver_1.10.0.tar.gz vignettes: vignettes/liftOver/inst/doc/liftov.html vignetteTitles: Changing genomic coordinate systems with rtracklayer::liftOver hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/liftOver/inst/doc/liftov.R dependencyCount: 92 Package: maEndToEnd Version: 2.6.1 Depends: R (>= 3.5.0), Biobase, oligoClasses, ArrayExpress, pd.hugene.1.0.st.v1, hugene10sttranscriptcluster.db, oligo, arrayQualityMetrics, limma, topGO, ReactomePA, clusterProfiler, gplots, ggplot2, geneplotter, pheatmap, RColorBrewer, dplyr, tidyr, stringr, matrixStats, genefilter, openxlsx, Rgraphviz Suggests: BiocStyle, knitr, devtools, rmarkdown License: MIT MD5sum: 91d473a59e285146e8b8bba35a3ad8da NeedsCompilation: no Title: An end to end workflow for differential gene expression using Affymetrix microarrays Description: In this article, we walk through an end-to-end Affymetrix microarray differential expression workflow using Bioconductor packages. This workflow is directly applicable to current "Gene" type arrays, e.g. the HuGene or MoGene arrays, but can easily be adapted to similar platforms. The data analyzed here is a typical clinical microarray data set that compares inflamed and non-inflamed colon tissue in two disease subtypes. For each disease, the differential gene expression between inflamed- and non-inflamed colon tissue was analyzed. We will start from the raw data CEL files, show how to import them into a Bioconductor ExpressionSet, perform quality control and normalization and finally differential gene expression (DE) analysis, followed by some enrichment analysis. biocViews: GeneExpressionWorkflow Author: Bernd Klaus [aut], Stefanie Reisenauer [cre, aut] Maintainer: Stefanie Reisenauer URL: https://www.bioconductor.org/help/workflows/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/maEndToEnd git_branch: RELEASE_3_10 git_last_commit: 57d736e git_last_commit_date: 2020-04-08 Date/Publication: 2020-04-10 source.ver: src/contrib/maEndToEnd_2.6.1.tar.gz vignettes: vignettes/maEndToEnd/inst/doc/MA-Workflow.html vignetteTitles: An end to end workflow for differential gene expression using Affymetrix microarrays hasREADME: FALSE hasNEWS: TRUE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/maEndToEnd/inst/doc/MA-Workflow.R dependencyCount: 207 Package: methylationArrayAnalysis Version: 1.10.0 Depends: R (>= 3.3.0), knitr, rmarkdown, BiocStyle, limma, minfi, IlluminaHumanMethylation450kanno.ilmn12.hg19, IlluminaHumanMethylation450kmanifest, RColorBrewer, missMethyl, matrixStats, minfiData, Gviz, DMRcate, stringr, FlowSorted.Blood.450k License: Artistic-2.0 MD5sum: 36c3cae61d51f34310056efcb92b4053 NeedsCompilation: no Title: A cross-package Bioconductor workflow for analysing methylation array data. Description: Methylation in the human genome is known to be associated with development and disease. The Illumina Infinium methylation arrays are by far the most common way to interrogate methylation across the human genome. This Bioconductor workflow uses multiple packages for the analysis of methylation array data. Specifically, we demonstrate the steps involved in a typical differential methylation analysis pipeline including: quality control, filtering, normalization, data exploration and statistical testing for probe-wise differential methylation. We further outline other analyses such as differential methylation of regions, differential variability analysis, estimating cell type composition and gene ontology testing. Finally, we provide some examples of how to visualise methylation array data. biocViews: Workflow, EpigeneticsWorkflow Author: Jovana Maksimovic [aut, cre] Maintainer: Jovana Maksimovic VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/methylationArrayAnalysis git_branch: RELEASE_3_10 git_last_commit: f5a1649 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/methylationArrayAnalysis_1.10.0.tar.gz vignettes: vignettes/methylationArrayAnalysis/inst/doc/methylationArrayAnalysis.html vignetteTitles: A cross-package Bioconductor workflow for analysing methylation array data hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/methylationArrayAnalysis/inst/doc/methylationArrayAnalysis.R dependencyCount: 217 Package: proteomics Version: 1.10.0 Depends: R (>= 3.3.0), mzR, mzID, MSnID, MSnbase, rpx, MLInterfaces, pRoloc, pRolocdata, MSGFplus, rols, hpar Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: 29faae137b4e8d63d53f4458b51e2214 NeedsCompilation: no Title: Mass spectrometry and proteomics data analysis Description: This workflow illustrates R / Bioconductor infrastructure for proteomics. Topics covered focus on support for open community-driven formats for raw data and identification results, packages for peptide-spectrum matching, data processing and analysis. biocViews: ImmunoOncologyWorkflow, ProteomicsWorkflow, Workflow Author: Laurent Gatto [aut, cre] Maintainer: Laurent Gatto URL: https://www.bioconductor.org/help/workflows/proteomics/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/proteomics git_branch: RELEASE_3_10 git_last_commit: 1c6e1b9 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/proteomics_1.10.0.tar.gz vignettes: vignettes/proteomics/inst/doc/proteomics.html vignetteTitles: An R/Bioc proteomics workflow hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/proteomics/inst/doc/proteomics.R dependencyCount: 207 Package: recountWorkflow Version: 1.10.0 Depends: R (>= 3.4.0) Imports: recount (>= 1.2.3), GenomicRanges, limma, edgeR, DESeq2, regionReport (>= 1.11.2), clusterProfiler (>= 3.5.5), org.Hs.eg.db (>= 3.4.1), gplots, derfinder, rtracklayer (>= 1.36.4), GenomicFeatures, bumphunter (>= 1.17.2), derfinderPlot Suggests: BiocStyle (>= 2.5.19), BiocWorkflowTools, knitr, sessioninfo, rmarkdown, knitcitations License: Artistic-2.0 MD5sum: dc274e26076c626b970bb0fe76bc99fe NeedsCompilation: no Title: recount workflow: accessing over 70,000 human RNA-seq samples with Bioconductor Description: The recount2 resource is composed of over 70,000 uniformly processed human RNA-seq samples spanning TCGA and SRA, including GTEx. The processed data can be accessed via the recount2 website and the recount Bioconductor package. This workflow explains in detail how to use the recount package and how to integrate it with other Bioconductor packages for several analyses that can be carried out with the recount2 resource. In particular, we describe how the coverage count matrices were computed in recount2 as well as different ways of obtaining public metadata, which can facilitate downstream analyses. Step-by-step directions show how to do a gene level differential expression analysis, visualize base-level genome coverage data, and perform an analyses at multiple feature levels. This workflow thus provides further information to understand the data in recount2 and a compendium of R code to use the data. biocViews: Workflow, ResourceQueryingWorkflow Author: Leonardo Collado-Torres [aut, cre], Abhinav Nellore [ctb], Andrew E. Jaffe [ctb] Maintainer: Leonardo Collado-Torres URL: https://github.com/LieberInstitute/recountWorkflow VignetteBuilder: knitr BugReports: https://support.bioconductor.org/t/recountWorkflow/ git_url: https://git.bioconductor.org/packages/recountWorkflow git_branch: RELEASE_3_10 git_last_commit: 22dfeb7 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/recountWorkflow_1.10.0.tar.gz vignettes: vignettes/recountWorkflow/inst/doc/recount-workflow.html vignetteTitles: recount workflow: accessing over 70,,000 human RNA-seq samples with Bioconductor hasREADME: FALSE hasNEWS: TRUE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/recountWorkflow/inst/doc/recount-workflow.R dependencyCount: 222 Package: RNAseq123 Version: 1.10.0 Depends: R (>= 3.3.0), Glimma (>= 1.1.9), limma, edgeR, gplots, RColorBrewer, Mus.musculus Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: 693a07605cc4286b7d48247a1a11874c NeedsCompilation: no Title: RNA-seq analysis is easy as 1-2-3 with limma, Glimma and edgeR Description: R package that supports the F1000Research workflow article on RNA-seq analysis using limma, Glimma and edgeR by Law et al. (2016). biocViews: Workflow, GeneExpressionWorkflow, ImmunoOncologyWorkflow Author: Charity Law, Monther Alhamdoosh, Shian Su, Xueyi Dong, Luyi Tian, Gordon Smyth and Matthew Ritchie Maintainer: Matthew Ritchie URL: https://f1000research.com/articles/5-1408/v3 VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/RNAseq123 git_branch: RELEASE_3_10 git_last_commit: a730b9f git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/RNAseq123_1.10.0.tar.gz vignettes: vignettes/RNAseq123/inst/doc/limmaWorkflow_CHN.html, vignettes/RNAseq123/inst/doc/limmaWorkflow.html vignetteTitles: RNA-seq analysis is easy as 1-2-3 with limma,, Glimma and edgeR (Chinese version), RNA-seq analysis is easy as 1-2-3 with limma,, Glimma and edgeR (English version) hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/RNAseq123/inst/doc/limmaWorkflow_CHN.R, vignettes/RNAseq123/inst/doc/limmaWorkflow.R dependencyCount: 101 Package: rnaseqDTU Version: 1.6.0 Depends: R (>= 3.5.0), DRIMSeq, DEXSeq, stageR, DESeq2, edgeR, rafalib, devtools Suggests: knitr, rmarkdown License: Artistic-2.0 MD5sum: 6a94c5ca938070695fb9e84a69e27143 NeedsCompilation: no Title: RNA-seq workflow for differential transcript usage following Salmon quantification Description: RNA-seq workflow for differential transcript usage (DTU) following Salmon quantification. This workflow uses Bioconductor packages tximport, DRIMSeq, and DEXSeq to perform a DTU analysis on simulated data. It also shows how to use stageR to perform two-stage testing of DTU, a statistical framework to screen at the gene level and then confirm which transcripts within the significant genes show evidence of DTU. biocViews: Workflow, GeneExpressionWorkflow, ImmunoOncologyWorkflow Author: Michael Love [aut, cre], Charlotte Soneson [aut], Rob Patro [aut] Maintainer: Michael Love URL: https://github.com/mikelove/rnaseqDTU/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/rnaseqDTU git_branch: RELEASE_3_10 git_last_commit: 3bd6d2b git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/rnaseqDTU_1.6.0.tar.gz vignettes: vignettes/rnaseqDTU/inst/doc/rnaseqDTU.html vignetteTitles: RNA-seq workflow for differential transcript usage following Salmon quantification hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/rnaseqDTU/inst/doc/rnaseqDTU.R dependencyCount: 173 Package: rnaseqGene Version: 1.10.0 Depends: R (>= 3.3.0), BiocStyle, airway (>= 1.5.3), tximeta, magrittr, DESeq2, apeglm, vsn, dplyr, ggplot2, hexbin, pheatmap, RColorBrewer, PoiClaClu, glmpca, ggbeeswarm, genefilter, AnnotationDbi, org.Hs.eg.db, ReportingTools, Gviz, sva, RUVSeq, fission Suggests: knitr, rmarkdown License: Artistic-2.0 MD5sum: 1c2ed4e174a356b2c8114631a8d354d6 NeedsCompilation: no Title: RNA-seq workflow: gene-level exploratory analysis and differential expression Description: Here we walk through an end-to-end gene-level RNA-seq differential expression workflow using Bioconductor packages. We will start from the FASTQ files, show how these were aligned to the reference genome, and prepare a count matrix which tallies the number of RNA-seq reads/fragments within each gene for each sample. We will perform exploratory data analysis (EDA) for quality assessment and to explore the relationship between samples, perform differential gene expression analysis, and visually explore the results. biocViews: Workflow, GeneExpressionWorkflow, ImmunoOncologyWorkflow Author: Michael Love [aut, cre] Maintainer: Michael Love URL: https://github.com/mikelove/rnaseqGene/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/rnaseqGene git_branch: RELEASE_3_10 git_last_commit: 9468a4d git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/rnaseqGene_1.10.0.tar.gz vignettes: vignettes/rnaseqGene/inst/doc/rnaseqGene.html vignetteTitles: RNA-seq workflow at the gene level hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/rnaseqGene/inst/doc/rnaseqGene.R dependencyCount: 208 Package: RnaSeqGeneEdgeRQL Version: 1.10.0 Depends: R (>= 3.3.0), edgeR, gplots, org.Mm.eg.db, GO.db Suggests: knitr, knitcitations License: Artistic-2.0 MD5sum: d4e368b6ddc499d1e883fb41a9dbdfab NeedsCompilation: no Title: Gene-level RNA-seq differential expression and pathway analysis using Rsubread and the edgeR quasi-likelihood pipeline Description: This workflow package provides, through its vignette, a complete case study analysis of an RNA-Seq experiment using the Rsubread and edgeR packages. The workflow starts from read alignment and continues on to data exploration, to differential expression and, finally, to pathway analysis. The analysis includes publication quality plots, GO and KEGG analyses, and the analysis of a expression signature as generated by a prior experiment. biocViews: Workflow, GeneExpressionWorkflow, ImmunoOncologyWorkflow Author: Yunshun Chen, Aaron Lun, Gordon Smyth Maintainer: Yunshun Chen URL: http://f1000research.com/articles/5-1438 VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/RnaSeqGeneEdgeRQL git_branch: RELEASE_3_10 git_last_commit: d94dac2 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/RnaSeqGeneEdgeRQL_1.10.0.tar.gz vignettes: vignettes/RnaSeqGeneEdgeRQL/inst/doc/edgeRQL.html vignetteTitles: From reads to genes to pathways: differential expression analysis of RNA-Seq experiments using Rsubread and the edgeR quasi-likelihood pipeline hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/RnaSeqGeneEdgeRQL/inst/doc/edgeRQL.R dependencyCount: 40 Package: sequencing Version: 1.10.0 Depends: R (>= 3.3.0), GenomicRanges, GenomicAlignments, Biostrings, Rsamtools, ShortRead, BiocParallel, rtracklayer, VariantAnnotation, AnnotationHub, BSgenome.Hsapiens.UCSC.hg19, RNAseqData.HNRNPC.bam.chr14 Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: efbf90a27d5dd2481e17b1f2957d0428 NeedsCompilation: no Title: Introduction to Bioconductor for Sequence Data Description: Bioconductor enables the analysis and comprehension of high- throughput genomic data. We have a vast number of packages that allow rigorous statistical analysis of large data while keeping technological artifacts in mind. Bioconductor helps users place their analytic results into biological context, with rich opportunities for visualization. Reproducibility is an important goal in Bioconductor analyses. Different types of analysis can be carried out using Bioconductor, for example; Sequencing : RNASeq, ChIPSeq, variants, copy number etc.; Microarrays: expression, SNP, etc.; Domain specific analysis : Flow cytometry, Proteomics etc. For these analyses, one typically imports and works with diverse sequence-related file types, including fasta, fastq, BAM, gtf, bed, and wig files, among others. Bioconductor packages support import, common and advanced sequence manipulation operations such as trimming, transformation, and alignment including quality assessment. biocViews: ImmunoOncologyWorkflow, Workflow, BasicWorkflow Author: Sonali Arora [aut], Martin Morgan [aut], Bioconductor Package Maintainer [cre] Maintainer: Bioconductor Package Maintainer URL: https://www.bioconductor.org/help/workflows/sequencing/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/sequencing git_branch: RELEASE_3_10 git_last_commit: ecd7182 git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/sequencing_1.10.0.tar.gz vignettes: vignettes/sequencing/inst/doc/sequencing.html vignetteTitles: Introduction to Bioconductor for Sequence Data hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/sequencing/inst/doc/sequencing.R dependencyCount: 106 Package: simpleSingleCell Version: 1.10.1 Suggests: knitr, rmarkdown, BiocStyle, readxl, R.utils, SingleCellExperiment, scater, scran, limma, BiocFileCache, org.Mm.eg.db License: Artistic-2.0 MD5sum: e57206a4ce0533fb03c648d4fadad207 NeedsCompilation: no Title: A step-by-step workflow for low-level analysis of single-cell RNA-seq data with Bioconductor Description: Almost all content that was previously in these workflows have been migrated to the "Orchestrating Single-Cell Analyses with Bioconductor" book at https://osca.bioconductor.org. Most vignettes here are retained largely for back-compatibility with existing external links, and provide links to the relevant OSCA book chapters. biocViews: ImmunoOncologyWorkflow, Workflow, SingleCellWorkflow Author: Aaron Lun [aut, cre], Davis McCarthy [aut], John Marioni [aut] Maintainer: Aaron Lun URL: https://www.bioconductor.org/help/workflows/simpleSingleCell/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/simpleSingleCell git_branch: RELEASE_3_10 git_last_commit: dbab834 git_last_commit_date: 2019-11-18 Date/Publication: 2019-11-20 source.ver: src/contrib/simpleSingleCell_1.10.1.tar.gz vignettes: vignettes/simpleSingleCell/inst/doc/batch.html, vignettes/simpleSingleCell/inst/doc/bigdata.html, vignettes/simpleSingleCell/inst/doc/de.html, vignettes/simpleSingleCell/inst/doc/doublets.html, vignettes/simpleSingleCell/inst/doc/intro.html, vignettes/simpleSingleCell/inst/doc/misc.html, vignettes/simpleSingleCell/inst/doc/multibatch.html, vignettes/simpleSingleCell/inst/doc/qc.html, vignettes/simpleSingleCell/inst/doc/reads.html, vignettes/simpleSingleCell/inst/doc/spike.html, vignettes/simpleSingleCell/inst/doc/tenx.html, vignettes/simpleSingleCell/inst/doc/umis.html, vignettes/simpleSingleCell/inst/doc/var.html vignetteTitles: 05. Correcting batch effects, 12. Scalability for big data, 10. Detecting differential expression, 08. Detecting doublets, 01. Introduction, 13. Further analysis strategies, 11. Advanced batch correction, 06. Quality control details, 02. Read count data, 07. Spike-in normalization, 04. Droplet-based data, 03. UMI count data, 09. Advanced variance modelling hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/simpleSingleCell/inst/doc/intro.R, vignettes/simpleSingleCell/inst/doc/misc.R dependencyCount: 0 Package: SingscoreAMLMutations Version: 1.2.0 Depends: R (>= 3.6.0) Imports: dcanr, edgeR, ggplot2, gridExtra, GSEABase, mclust, org.Hs.eg.db, plyr, reshape2, rtracklayer, singscore, SummarizedExperiment, TCGAbiolinks Suggests: knitr, rmarkdown, BiocStyle, BiocWorkflowTools, spelling License: Artistic-2.0 MD5sum: d88a2e9d687394577390b1857aa6fbcd NeedsCompilation: no Title: Using singscore to predict mutations in AML from transcriptomic signatures Description: This workflow package shows how transcriptomic signatures can be used to infer phenotypes. The workflow begins by showing how the TCGA AML transcriptomic data can be downloaded and processed using the TCGAbiolinks packages. It then shows how samples can be scored using the singscore package and signatures from the MSigDB. Finally, the predictive capacity of scores in the context of predicting a specific mutation in AML is shown.The workflow exhibits the interplay of Bioconductor packages to achieve a gene-set level analysis. biocViews: GeneExpressionWorkflow, GenomicVariantsWorkflow, ImmunoOncologyWorkflow, Workflow Author: Dharmesh D. Bhuva [aut, cre] (), Momeneh Foroutan [aut] (), Yi Xie [aut] (), Ruqian Lyu [aut], Joseph Cursons [aut] (), Melissa J. Davis [aut] () Maintainer: Dharmesh D. Bhuva URL: https://github.com/DavisLaboratory/SingscoreAMLMutations VignetteBuilder: knitr BugReports: https://github.com/DavisLaboratory/SingscoreAMLMutations/issues git_url: https://git.bioconductor.org/packages/SingscoreAMLMutations git_branch: RELEASE_3_10 git_last_commit: 70ec16e git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/SingscoreAMLMutations_1.2.0.tar.gz vignettes: vignettes/SingscoreAMLMutations/inst/doc/workflow_transcriptional_mut_sig_chinese.html, vignettes/SingscoreAMLMutations/inst/doc/workflow_transcriptional_mut_sig.html vignetteTitles: Using singscore to predict mutations in AML from transcriptomic signatures (Chinese version), Using singscore to predict mutations in AML from transcriptomic signatures hasREADME: FALSE hasNEWS: TRUE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/SingscoreAMLMutations/inst/doc/workflow_transcriptional_mut_sig_chinese.R, vignettes/SingscoreAMLMutations/inst/doc/workflow_transcriptional_mut_sig.R dependencyCount: 196 Package: TCGAWorkflow Version: 1.10.1 Depends: R (>= 3.4.0) Imports: AnnotationHub, knitr, ELMER, biomaRt, BSgenome.Hsapiens.UCSC.hg19, circlize, c3net, ChIPseeker, ComplexHeatmap, clusterProfiler, downloader (>= 0.4), gaia, GenomicRanges, GenomeInfoDb, ggplot2, ggthemes, graphics, minet, MotIV, motifStack, pathview, pbapply, parallel, rGADEM, pander, maftools, RTCGAToolbox, SummarizedExperiment, TCGAbiolinks, TCGAWorkflowData (>= 1.9.0), DT License: Artistic-2.0 MD5sum: 38411dd7bb2604c77f24acf3f67910b3 NeedsCompilation: no Title: TCGA Workflow Analyze cancer genomics and epigenomics data using Bioconductor packages Description: Biotechnological advances in sequencing have led to an explosion of publicly available data via large international consortia such as The Cancer Genome Atlas (TCGA), The Encyclopedia of DNA Elements (ENCODE), and The NIH Roadmap Epigenomics Mapping Consortium (Roadmap). These projects have provided unprecedented opportunities to interrogate the epigenome of cultured cancer cell lines as well as normal and tumor tissues with high genomic resolution. The Bioconductor project offers more than 1,000 open-source software and statistical packages to analyze high-throughput genomic data. However, most packages are designed for specific data types (e.g. expression, epigenetics, genomics) and there is no one comprehensive tool that provides a complete integrative analysis of the resources and data provided by all three public projects. A need to create an integration of these different analyses was recently proposed. In this workflow, we provide a series of biologically focused integrative analyses of different molecular data. We describe how to download, process and prepare TCGA data and by harnessing several key Bioconductor packages, we describe how to extract biologically meaningful genomic and epigenomic data. Using Roadmap and ENCODE data, we provide a work plan to identify biologically relevant functional epigenomic elements associated with cancer. To illustrate our workflow, we analyzed two types of brain tumors: low-grade glioma (LGG) versus high-grade glioma (glioblastoma multiform or GBM). biocViews: Workflow, ResourceQueryingWorkflow Author: Tiago Chedraoui Silva , Antonio Colaprico , Catharina Olsen , Fulvio D Angelo , Gianluca Bontempi , Michele Ceccarelli , Houtan Noushmehr Maintainer: Tiago Chedraoui Silva URL: https://f1000research.com/articles/5-1542/v2 VignetteBuilder: knitr BugReports: https://github.com/BioinformaticsFMRP/TCGAWorkflow/issues git_url: https://git.bioconductor.org/packages/TCGAWorkflow git_branch: RELEASE_3_10 git_last_commit: 08c0d7e git_last_commit_date: 2020-04-02 Date/Publication: 2020-04-03 source.ver: src/contrib/TCGAWorkflow_1.10.1.tar.gz vignettes: vignettes/TCGAWorkflow/inst/doc/TCGAWorkflow.html vignetteTitles: 'TCGA Workflow: Analyze cancer genomics and epigenomics data using Bioconductor packages' hasREADME: FALSE hasNEWS: TRUE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/TCGAWorkflow/inst/doc/TCGAWorkflow.R dependencyCount: 286 Package: variants Version: 1.10.0 Depends: R (>= 3.3.0), VariantAnnotation, cgdv17, org.Hs.eg.db, TxDb.Hsapiens.UCSC.hg19.knownGene, BSgenome.Hsapiens.UCSC.hg19, PolyPhen.Hsapiens.dbSNP131 Suggests: knitr, rmarkdown, BiocStyle License: Artistic-2.0 MD5sum: 0ca875a149fed668cec5f9c99a006fec NeedsCompilation: no Title: Annotating Genomic Variants Description: Read and write VCF files. Identify structural location of variants and compute amino acid coding changes for non-synonymous variants. Use SIFT and PolyPhen database packages to predict consequence of amino acid coding changes biocViews: ImmunoOncologyWorkflow, AnnotationWorkflow, Workflow Author: Bioconductor Package Maintainer [cre] Maintainer: Bioconductor Package Maintainer URL: https://www.bioconductor.org/help/workflows/variants/ VignetteBuilder: knitr git_url: https://git.bioconductor.org/packages/variants git_branch: RELEASE_3_10 git_last_commit: 3d91edf git_last_commit_date: 2019-10-29 Date/Publication: 2019-10-30 source.ver: src/contrib/variants_1.10.0.tar.gz vignettes: vignettes/variants/inst/doc/Annotating_Genomic_Variants.html vignetteTitles: Annotating Genomic Variants hasREADME: FALSE hasNEWS: FALSE hasINSTALL: FALSE hasLICENSE: FALSE Rfiles: vignettes/variants/inst/doc/Annotating_Genomic_Variants.R dependencyCount: 90