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== [https://github.com/Bioconductor-mirror Github Mirrors] ==
= Project =
* https://support.bioconductor.org/p/68824/ Announcement
[https://journal.r-project.org/news/RJ-2022-4-bioconductor/ Bioconductor Notes] published in The R Journal, Nov 2022.


== [http://watson.nci.nih.gov/bioc_mirror/ NIH mirror] ==
== Release News ==
We can safely replace http://www.bioconductor.org/ with http://watson.nci.nih.gov/bioc_mirror/.  
* [http://bioconductor.org/news/bioc_3_9_release/ 3.9] release
* [http://bioconductor.org/news/bioc_3_8_release/ 3.8] release
* [http://bioconductor.org/news/bioc_3_7_release/ 3.7] release
* [https://bioconductor.org/news/bioc_3_6_release/ 3.6] release
* [https://bioconductor.org/news/bioc_3_5_release/ 3.5] release


For example, the 'Biobase' url in the original and nih mirror can be found in
== Annual reports ==
http://bioconductor.org/about/annual-reports/
 
== Download stats ==
* See the overview vignette of [http://bioconductor.org/packages/release/bioc/html/BiocPkgTools.html BiocPkgTools]
* Download stats for Bioconductor
** [http://bioconductor.org/packages/stats/ Download stats for Bioconductor software packages]
* bioconductor.riken.jp mirror in Japan
** [https://bioconductor.riken.jp/packages/stats/index.html Download stats for Bioconductor software packages]
** [http://bioconductor.riken.jp/packages/stats/data-annotation.html Download stats for Bioconductor annotation packages]
* [https://github.com/lgatto/biocpkgs biocpkg] package in github
 
== From the director of the project ==
[https://t.co/rfKF3ABFJp?amp=1 useR 2019] & [https://youtu.be/YEQ5xFewbdA?t=891 youtube]
 
== Community blog ==
https://bioconductor.github.io/biocblog/
 
== Publications ==
https://www.bioconductor.org/help/publications/
 
== Bioconductor User Support ==
https://support.bioconductor.org/
 
== Bioconductor Packages: Development, Maintenance, and Peer Review ==
https://contributions.bioconductor.org/index.html
 
== Submit packages ==
[https://kayla-morrell.github.io/CreateAPackage/ Create A Package] from [https://bioc2020.bioconductor.org/workshops.html Bioc2020]
 
== Update to newer version ==
http://bioconductor.org/install/. Suppose I have version 3.11 and I like to upgrade to version 3.12.
<pre>
<pre>
http://www.bioconductor.org/packages/release/bioc/html/Biobase.html
BiocManager::install(version = "3.12") # Upgrade all my installed packages
->
BiocManager::install(ask = FALSE) # To use the latest version of Bioconductor for your version of R
http://watson.nci.nih.gov/bioc_mirror/packages/release/bioc/html/Biobase.html
 
BiocManager::version()
# [1] ‘3.12’
</pre>
</pre>
and the hgu133plusdb is  
 
=== Check if my current Bioconductor version is outdated ===
Below is an example that shows I am using an outdated Bioconductor.
<syntaxhighlight lang='rsplus'>
require(BiocManager)
# Loading required package: BiocManager
# Bioconductor version 3.15 (BiocManager 1.30.20), R 4.2.2
#  Patched (2022-11-10 r83330)
# Bioconductor version '3.15' is out-of-date; the current
#  release version '3.16' is available with R version
#  '4.2'; see https://bioconductor.org/install
</syntaxhighlight>
 
=== Upgrade to the latest Bioconductor version ===
[https://www.bioconductor.org/install/ Using Bioconductor]
<pre>
<pre>
http://www.bioconductor.org/packages/release/data/annotation/html/hgu133plus2.db.html
if (!require("BiocManager", quietly = TRUE))
->
    install.packages("BiocManager")
http://watson.nci.nih.gov/bioc_mirror/packages/release/data/annotation/html/hgu133plus2.db.html
BiocManager::install(version = "3.12") # the latest version can be obtained from the
                                      # output of require(BiocManager) OR
                                      # checking the Bioconductor website
# Upgrade 53 packages to Bioconductor version '3.12'? [y/n]: y
</pre>
</pre>
and the experiment data package like pasilla
 
=== Upgrading installed Bioconductor packages ===
CAlling '''BiocManager::install()''' without any arguments will attempt to update all installed packages in your R environment. It checks for updates on Bioconductor, CRAN, and GitHub, and if newer versions of the packages are available, it will download and install them.
 
When I run it on Docker, it will also install '''BiocVersion''' package from Bioconductor.
<pre>
BiocManager::install()
</pre>
 
=== BiocVersion ===
[https://bioconductor.org/packages/release/bioc/html/BiocVersion.html BiocVersion].
 
* The BiocManager::install() function in R automatically installs the BiocVersion package during its first use. The BiocVersion package provides repository information for the appropriate version of Bioconductor. It helps BiocManager determine the version of Bioconductor in use. If BiocVersion has not yet been installed, the version is determined by code in base R. This ensures that all Bioconductor packages work best when they are all from the same release. See the document [https://bioconductor.github.io/BiocManager/reference/BiocManager-package.html Install or update Bioconductor, CRAN, or GitHub packages] from '''BiocManager'''.
* This package was suggested (not a default option by install.packages()) by BiocManager and more importantly '''imported''' by AnnotationHub.
* It seems BiocVersion gives the patch version if we like to get that information. For example the current Bioc is 3.14 but I have Bioconductor version 3.13.1.
<pre>
<pre>
http://www.bioconductor.org/packages/release/data/experiment/html/pasilla.html
R> BiocManager::version()
->
[1] ‘3.13’
http://watson.nci.nih.gov/bioc_mirror/packages/release/data/experiment/html/pasilla.html
R> packageVersion("BiocVersion")
[1] ‘3.13.1’
</pre>
</pre>


For R software, the NIH mirror is http://watson.nci.nih.gov/cran_mirror. So for example, the R v3.2.1 url in main CRAN and NIH is
== Devel version of Bioconductor ==
<pre>
<pre>
http://cran.r-project.org/bin/windows/base/R-3.2.1-win.exe
BiocManager::install(version = "devel")
->
http://watson.nci.nih.gov/cran_mirror/bin/windows/base/R-3.2.1-win.exe
</pre>
</pre>
and the 'MASS' package is
 
= Mirrors =
https://www.bioconductor.org/about/mirrors/
 
== [https://github.com/Bioconductor-mirror Github mirror] ==
* https://support.bioconductor.org/p/68824/ Announcement (Update: it is dead)
 
== Japan ==
http://bioconductor.jp
 
= Package source =
* Bioconductor Code & [https://code.bioconductor.org/ Git Browser]
* [[R_repository|R > create Bioconductor repository]]
* https://bioconductor.org/developers/how-to/git/. [https://bioconductor.org/developers/how-to/git/create-local-repository/ Create a local repository for private use]
== Code search ==
http://search.bioconductor.jp/
 
== code.bioconductor.org ==
https://code.bioconductor.org/
 
= Resource =
* [http://rafalab.github.io/pages/teaching.html Teaching resources], [https://rafalab.github.io/pages/harvardx.html HarvardX  Biomedical Data Science Open Online Training] from rafalab
* [https://gallantries.github.io/video-library/modules/bioconductor Module: Bioconductor R analyses] from GTN Video Library
 
= [https://cran.r-project.org/web/packages/BiocManager/index.html BiocManager] from CRAN =
The reason for using BiocManager instead of biocLite() is mostly to stop sourcing an R script from URL which isn’t so safe. So biocLite() should not be recommended anymore.
 
It allows to have multiple versions of Bioconductor installed on the same computer. For example, R 3.5 works with Bioconductor 3.7 and 3.8.
 
On the other hand, setRepositories(ind=1:4) and install.packages() still lets you install Bioconductor packages.
 
[https://www.jumpingrivers.com/blog/security-r-hacking-bioconductor/ Hacking Bioconductor]
 
= BiocPkgTools =
* [http://bioconductor.org/packages/release/bioc/html/BiocPkgTools.html BiocPkgTools]: Collection of simple tools for learning about Bioc Packages
* https://www.biorxiv.org/content/10.1101/642132v1
* [https://kevinrue.github.io/post/biocpkgtools/  GitHub Action executed as a CRON job to update the website daily]. Note that the 'bioc' version needs to be updated once a new version of Bioconductor has been released.
 
= [https://github.com/Shians/BioCExplorer BioCExplorer] =
Explore Bioconductor packages more nicely
 
<pre>
<pre>
http://cran.r-project.org/web/packages/MASS/index.html
source("https://bioconductor.org/biocLite.R")
->
biocLite("BiocUpgrade")
http://watson.nci.nih.gov/cran_mirror/web/packages/MASS/index.html
biocLite("biocViews")
devtools::install_github("seandavi/BiocPkgTools")
devtools::install_github("shians/BioCExplorer")
library(BioCExplorer)
bioc_explore()
</pre>
</pre>


== Annotation packages ==
[[File:BiocExplorer.png|350px]]
 
= [http://www.bioconductor.org/packages/release/BiocViews.html BiocViews] =
* Software
** AssayDomain
** [https://bioconductor.org/packages/release/BiocViews.html#___BiologicalQuestion BiologicalQuestion]
** [https://bioconductor.org/packages/release/BiocViews.html#___Infrastructure Infrastructure]
** [https://bioconductor.org/packages/release/BiocViews.html#___ResearchField ResearchField]
** [https://bioconductor.org/packages/release/BiocViews.html#___StatisticalMethod StatisticalMethod]
** [https://bioconductor.org/packages/release/BiocViews.html#___Technology Technology]
** [https://bioconductor.org/packages/release/BiocViews.html#___WorkflowStep WorkflowStep]
* AnnotationData
** ChipManufacturer
** ChipName
** CustomArray
** CustomCDF
** CustomDBSchema
** FunctionalAnnotation
** Organism
** PackageType
** SequenceAnnotation
* ExperimentData
** AssayDomainData
** DiseaseModel
** OrganismData
** PackageTypeData
** RepositoryData
** ReproducibleResearch
** SpecimenSource
** TechnologyData
* Workflow
** AnnotationWorkflow
** BasicWorkflow
** DifferentialSplicingWorkflow
** EpigeneticsWorkflow
** GeneExpressionWorkflow
** GenomicVariantsWorkflow
** ImmunoOncologyWorkflow
** ProteomicsWorkflow
** ResourceQueryingWorkflow
** [http://www.bioconductor.org/packages/release/workflows/html/simpleSingleCell.html SingleCellWorkflow]
 
= Annotation packages =
* http://bioconductor.org/help/course-materials/2012/SeattleFeb2012/Annotation.pdf
* http://bioconductor.org/help/course-materials/2012/SeattleFeb2012/Annotation.pdf
* https://bioconductor.org/help/course-materials/2017/CSAMA/lectures/1-monday/lecture-04-a-annotation-intro/lecture-04a-annotation-intro.html
* https://bioconductor.org/help/course-materials/2017/CSAMA/lectures/1-monday/lecture-04-a-annotation-intro/lecture-04a-annotation-intro.html
* [http://www.bioconductor.org/packages/release/bioc/vignettes/GenomicFeatures/inst/doc/GenomicFeatures.pdf Making and Utilizing TxDb Objects]
* [http://www.bioconductor.org/packages/release/bioc/vignettes/GenomicFeatures/inst/doc/GenomicFeatures.pdf Making and Utilizing TxDb Objects]
* [https://bioconductor.org/packages/release/workflows/html/annotation.html Genomic Annotation Resources] (2018) Introduction to using gene, pathway, gene ontology, homology annotations and the AnnotationHub. Access GO, KEGG, NCBI, Biomart, UCSC, vendor, and other sources.
** AnnotationHub allows us to query and download many different annotation objects without having to explicitly install them.
** OrgDb
** TxDb
** OrganismDb packages are meta-packages that contain an OrgDb, a TxDb, and a GO.db packages and allow cross-queries between those packages.
** BSgenome packages contain sequence information for a given species/build.
** biomaRt allows queries to an Ensembl Biomart server.
* http://genomicsclass.github.io/book/pages/bioc1_annoCheat.html
* [https://academic.oup.com/bioinformatics/advance-article/doi/10.1093/bioinformatics/btz031/5301311?rss=1 ensembldb] package
<ul>
<li>[https://github.com/jmacdon/Bioc2020Anno Introduction to Bioconductor annotation resources] 2020 Bioc workshop
<ul>
<li>
{| class="wikitable"
|-
! Package type
! Example
|-
| ChipDb
| [https://www.bioconductor.org/packages/release/data/annotation/html/hgu133plus2.db.html hgu133plus2.db]
|-
| OrgDb
| org.Hs.eg.db
|-
| TxDb/EnsDb
| TxDb.Hsapiens.UCSC.hg19.knownGene; EnsDb.Hsapiens.v75
|-
| OrganismDb
| Homo.sapiens
|-
| BSgenome
| BSgenome.Hsapiens.UCSC.hg19
|-
| Others
| GO.db; KEGG.db
|-
| biomaRt
|
|}
</li>
<li>Database concept was used. So there are some terms like '''keys''', '''select''', ..., borrowed from there. </li>
<li>How do you know what the central '''keys''' are? If it's ChipDb (e.g. hugene20sttranscriptcluster.db), the central key are the manufactorer's probe IDs. If it's in the name - org.Hs.eg.db, where 'eg' means '''Entrez''' gene ID. You can see examples using e.g., head(keys(annopkg)), and infer from that.
</li>
<li>Functions (select, mapIds, transcripts accessors work on ChipDb, TxDb, OrgDb, ...). See the blog [https://davetang.org/muse/2013/12/16/bioconductor-annotation-packages/ Bioconductor annotation packages]
{{Pre}}
AnnotationDbi::keys(hgu133plus2.db, keytype="PROBEID")
AnnotationDbi::keytypes(hgu133plus2.db)  # columns(hgu133plus2.db)
AnnotationDbi::select(annopkg, keys, columns, keytype): keytype is optional
AnnotationDbi::mapIds(annopkg, keys, column, keytype, multiVals):
              keytype is required, multiVals is used to handle duplicates.
</pre>
</li>
<li>Packages
<pre>
TxDb packages - eg TxDb.Hsapiens.UCSC.hg19.knownGene. It contains positional information.
EnsDb packages - eg EnsDb.Hsapiens.v79
</pre>
</li>
<li>Examples: ChipDb
{{Pre}}
library(hgu133plus2.db)  # Loading required package: org.Hs.eg.db
keytypes(hgu133plus2.db)
# [1] "ACCNUM"      "ALIAS"        "ENSEMBL"      "ENSEMBLPROT"  "ENSEMBLTRANS"
# [6] "ENTREZID"    "ENZYME"      "EVIDENCE"    "EVIDENCEALL"  "GENENAME"   
#[11] "GO"          "GOALL"        "IPI"          "MAP"          "OMIM"       
#[16] "ONTOLOGY"    "ONTOLOGYALL"  "PATH"        "PFAM"        "PMID"       
#[21] "PROBEID"      "PROSITE"      "REFSEQ"      "SYMBOL"      "UCSCKG"     
#[26] "UNIGENE"      "UNIPROT" 
ls("package:hgu133plus2.db")
# Get all probe IDs
length(hgu133plus2ACCNUM)
# [1] 54675
x <- hgu133plus2ACCNUM
# hgu133plus2ACCNUM is an R object that contains mappings between
# a manufacturer’s identifiers and manufacturers accessions.
mapped_probes <- mappedkeys(x)
str(mapped_probes)
# chr [1:54675] "1007_s_at" "1053_at" "117_at" "121_at" "1255_g_at" ...
length(unique(mapped_probes))
# [1] 54675
length(hgu133plus2ENTREZID)
# [1] 54675
x <- hgu133plus2ENTREZID
mapped_probes <- mappedkeys(x)
str(mapped_probes)
# chr [1:41905] "1053_at" "117_at" "121_at" "1255_g_at" "1316_at" "1320_at" ...
length(unique(mapped_probes))
# [1] 41905
# Using select() to map from probe ID to others
# Note select() will return 1:many mapping
library(hugene20sttranscriptcluster.db)
ids <- c('16737401','16657436' ,'16678303')
select(hugene20sttranscriptcluster.db, ids, c("SYMBOL","ALIAS", "ENSEMBL", "ENTREZID"))
## 'select()' returned 1:many mapping between keys and columns
#    PROBEID  SYMBOL    ALIAS        ENSEMBL  ENTREZID
# 1  16737401    TRAF6 MGC:3310 ENSG00000175104      7189
# 2  16737401    TRAF6    RNF85 ENSG00000175104      7189
# 3  16737401    TRAF6    TRAF6 ENSG00000175104      7189
# 4  16657436  DDX11L1  DDX11L1 ENSG00000223972 100287102
# 5  16657436 DDX11L17 DDX11L17 ENSG00000223972 102725121
# 6  16657436  DDX11L2  DDX11L2 ENSG00000223972    84771
# 7  16657436  DDX11L9  DDX11L9 ENSG00000248472 100288486
# 8  16657436  DDX11L9  DDX11L9 ENSG00000288170 100288486
# 9  16657436 DDX11L10  DDX11L1 ENSG00000233614 100287029
# 10 16657436 DDX11L10  DDX11P ENSG00000233614 100287029
# 11 16657436 DDX11L10 DDX11L10 ENSG00000233614 100287029
# 12 16657436  DDX11L5  DDX11L5 ENSG00000223972 100287596
# 13 16657436  DDX11L5  DDX11L5 ENSG00000248472 100287596
# 14 16657436  DDX11L5  DDX11L5 ENSG00000288170 100287596
# 15 16657436 DDX11L16 DDX11L16 ENSG00000223972    727856
# 16 16657436 DDX11L16 DDX11L16 ENSG00000248472    727856
# 17 16657436 DDX11L16 DDX11L16 ENSG00000233614    727856
# 18 16657436 DDX11L16 DDX11L16 ENSG00000288170    727856
# 19 16678303    ARF1    PVNH8 ENSG00000143761      375
# 20 16678303    ARF1    ARF1 ENSG00000143761      375
keytypes(hugene20sttranscriptcluster.db)
##  [1] "ACCNUM"      "ALIAS"        "ENSEMBL"      "ENSEMBLPROT"  "ENSEMBLTRANS"
##  [6] "ENTREZID"    "ENZYME"      "EVIDENCE"    "EVIDENCEALL"  "GENENAME"   
## [11] "GO"          "GOALL"        "IPI"          "MAP"          "OMIM"       
## [16] "ONTOLOGY"    "ONTOLOGYALL"  "PATH"        "PFAM"        "PMID"       
## [21] "PROBEID"      "PROSITE"      "REFSEQ"      "SYMBOL"      "UCSCKG"     
## [26] "UNIGENE"      "UNIPROT"
# mapIds
# Note that an additional argument, multiVals can be used to control duplicates
mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID") # only select the 1st one
##  16737401  16657436  16678303
##  "TRAF6" "DDX11L1"    "ARF1"
mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID", multiVals = "list")  # list
mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID", multiVals = "CharacterList") # IRanges
mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID", multiVals = "filter") # character vector
# OrganismDb packages
library(Homo.sapiens)
Homo.sapiens
head(genes(Homo.sapiens, columns = c("ENTREZID", "ALIAS", "UNIPROT")), 4)
</pre>
<li>
</ul>
</ul>
== Gene centric ==
* [http://www.bioconductor.org/packages/release/bioc/vignettes/AnnotationDbi/inst/doc/IntroToAnnotationPackages.pdf#page=5 AnnotationDbi]: Introduction To Bioconductor Annotation Packages
<syntaxhighlight lang='rsplus'>
library(hgu133a.db)
library(AnnotationDbi)
k <- head(keys(hgu133a.db, keytype="PROBEID"))
k
# [1] "1007_s_at" "1053_at"  "117_at"    "121_at"    "1255_g_at" "1294_at"
# then call select
select(hgu133a.db, keys=k, columns=c("SYMBOL","GENENAME"), keytype="PROBEID")
# 'select()' returned 1:many mapping between keys and columns
#    PROBEID  SYMBOL                                    GENENAME
# 1 1007_s_at    DDR1  discoidin domain receptor tyrosine kinase 1
# 2 1007_s_at MIR4640                                microRNA 4640
# 3  1053_at    RFC2              replication factor C subunit 2
# 4    117_at  HSPA6 heat shock protein family A (Hsp70) member 6
# 5    121_at    PAX8                                paired box 8
# 6 1255_g_at  GUCA1A              guanylate cyclase activator 1A
# 7  1294_at    UBA7  ubiquitin like modifier activating enzyme 7
# 8  1294_at MIR5193                                microRNA 5193
</syntaxhighlight>
== ExpressionSets objects ==
For example: load(file.path(system.file(package = "Bioc2020Anno", "extdata"), "eset.Rdata")
* exprs(eset)
* pData(phenoData(eset))
* pData(featureData(eset))
== Genomic centric ==
* GRanges()
* GrangesList()
GRanges() and GRangesLists  act like data.frames and lists, and can be subsetted using the '''[''' function.
== SummarizedExperiment objects ==
SummarizedExperiment objects are like ExpressionSets, but the row-wise annotations are GRanges, so you can subset by genomic locations.
[https://rdrr.io/bioc/SummarizedExperiment/man/SummarizedExperiment-class.html SummarizedExperiment] objects are like '''ExpressionSets''', but the row-wise annotations are GRanges, so you can subset by genomic locations.
SummarizedExperiment objects are popular objects for representing expression data and other rectangular data (feature x sample data).
* array() or assays(): genes x samples
* colData(): samples x sample features
* rowData(): genes x gene features. The gene features could be result from running analyses; see [http://www.bioconductor.org/packages/release/bioc/vignettes/EnrichmentBrowser/inst/doc/EnrichmentBrowser.pdf EnrichmentBrowser] vignette.
Examples: [https://bioconductor.org/packages/release/bioc/vignettes/GSEABenchmarkeR/inst/doc/GSEABenchmarkeR.html GSEABenchmarkeR] package.
== biomaRt ==
<pre>
library(biomaRt)
listMarts(host = "useast.ensembl.org")
# biomaRt data sets
mart <- useEnsembl("ensembl")
head(listDatasets(mart))
# biomaRt queries
mart <- useEnsembl("ensembl","hsapiens_gene_ensembl")
# biomaRt attributes and filters
atrib <- listAttributes(mart)
filts <- listFilters(mart)
head(atrib)
head(filts)
# biomaRt query
afyids <- c("1000_at","1001_at","1002_f_at","1007_s_at")
getBM(c("affy_hg_u95av2", "hgnc_symbol"), c("affy_hg_u95av2"), afyids, mart)
</pre>
== AnnotationHub ==
<pre>
library(AnnotationHub)
hub <- AnnotationHub()
hub
# Querying AnnotationHub
names(mcols(hub))
# AnnotationHub Data providers
unique(hub$dataprovider)
# AnnotationHub Data classes
unique(hub$rdataclass)
# AnnotationHub Species
head(unique(hub$species))
length(unique(hub$species))
# AnnotationHub Data sources
unique(hub$sourcetype)
# AnnotationHub query
qry <- query(hub, c("granges","homo sapiens","ensembl"))
qry
qry$sourceurl
# Selecting AnnotationHub resource
whatIwant <- qry[["AH80077"]]
GRCh38TxDb <- makeTxDbFromGRanges(whatIwant)
GRCh38TxDb
</pre>
== Map Ensembl IDs to Entrez IDs ==
See the vignette from [https://bioconductor.org/packages/release/workflows/html/SingscoreAMLMutations.html SingscoreAMLMutations].
Multimapped Ensembl IDs are replaced by NAs, then discarded to enforce unique mapping. Similarly, Entrez IDs that map to multiple Ensembl IDs are identified from the mapping, and discarded. Only features with unique Ensembl ID to Entrez ID mappings remain.
== Gene name errors from Excel ==
[[Data_science#Gene_name_errors_from_Excel|Gene name errors from Excel]]. Gene names such as MAR1, DEC1, OCT4 and SEPT9 are now reformatted as dates.
== Example ==
[https://phys.org/news/2018-05-notch2nl-human-specific-genes-big-brains.html Meet '''NOTCH2NL''', the human-specific genes that may have given us our big brains]
{{Pre}}
library(hgu133plus2.db)
select(hgu133plus2.db, keys="NOTCH2NL", columns=c("SYMBOL","GENENAME"), keytype="SYMBOL")
# Error in .testForValidKeys(x, keys, keytype, fks) :
#  None of the keys entered are valid keys for 'SYMBOL'. Please use the keys method
#  to see a listing of valid arguments.
k <- keys(hgu133plus2.db, keytype="SYMBOL")
k <- sort(k)
grep("NOTCH", k)
# [1] 41224 41225 41226 41227 41228 41229 41230 41231 41232
k[grep("NOTCH", k) ]
[1] "NOTCH1"    "NOTCH2"    "NOTCH2NLA" "NOTCH2NLB" "NOTCH2NLC" "NOTCH2NLR" "NOTCH2P1"
[8] "NOTCH3"    "NOTCH4"
</pre>
= Workflow =
== [https://www.bioconductor.org/help/workflows/high-throughput-sequencing/ Using Bioconductor for Sequence Data] ==
== CyTOF ==
[https://bioconductor.org/packages/release/workflows/html/cytofWorkflow.html CyTOF workflow]: differential discovery in high-throughput high-dimensional cytometry datasets
= Some packages =
== Biobase, GEOquery and limma ==
How to create an ExpressionSet object from scratch? Here we use the code from GEO2R to help to do this task.
<syntaxhighlight lang='rsplus'>
library(Biobase)
library(GEOquery)
library(limma)
# Load series and platform data from GEO
gset <- getGEO("GSE32474", GSEMatrix =TRUE, AnnotGPL=TRUE)
if (length(gset) > 1) idx <- grep("GPL570", attr(gset, "names")) else idx <- 1
gset <- gset[[idx]]
# save(gset, file = "~/Downloads/gse32474_gset.rda")
# load("~/Downloads/gse32474_gset.rda")
table(pData(gset)[, "cell line:ch1"])
pData(gset)
# Create an ExpressionSet object from scratch
# We take a shortcut to obtain the pheno data and feature data matrices
# from the output of getGEO()
phenoDat <- new("AnnotatedDataFrame",
                data=pData(gset))
featureDat <- new("AnnotatedDataFrame",
                  data=fData(gset))
exampleSet <- ExpressionSet(assayData=exprs(gset),
                            phenoData=phenoDat,
                            featureData=featureDat,
                            annotation="hgu133plus2")
gset <- exampleSet
# Make proper column names to match toptable
fvarLabels(gset) <- make.names(fvarLabels(gset))
# group names for all samples
gsms <- paste0("00000000111111111XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX",
              "XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX",
              "XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX",
              "XXXXXXXXXXXXXXXXXXXXXXXX")
sml <- c()
for (i in 1:nchar(gsms)) { sml[i] <- substr(gsms,i,i) }
# Subset an ExpressionSet by eliminating samples marked as "X"
sel <- which(sml != "X")
sml <- sml[sel]
gset <- gset[ ,sel]
# Decide if it is necessary to do a log2 transformation
ex <- exprs(gset)
qx <- as.numeric(quantile(ex, c(0., 0.25, 0.5, 0.75, 0.99, 1.0), na.rm=T))
LogC <- (qx[5] > 100) ||
  (qx[6]-qx[1] > 50 && qx[2] > 0) ||
  (qx[2] > 0 && qx[2] < 1 && qx[4] > 1 && qx[4] < 2)
if (LogC) { ex[which(ex <= 0)] <- NaN
exprs(gset) <- log2(ex) }
# Set up the data and proceed with analysis
sml <- paste("G", sml, sep="")    # set group names
fl <- as.factor(sml)
gset$description <- fl
design <- model.matrix(~ description + 0, gset)
colnames(design) <- levels(fl)
fit <- lmFit(gset, design)
cont.matrix <- makeContrasts(G1-G0, levels=design)
fit2 <- contrasts.fit(fit, cont.matrix)
fit2 <- eBayes(fit2, 0.01)
tT <- topTable(fit2, adjust="fdr", sort.by="B", number=250)
# Display the result with selected columns
tT <- subset(tT, select=c("ID","adj.P.Val","P.Value","t","B","logFC","Gene.symbol","Gene.title"))
tT[1:2, ]
#                  ID  adj.P.Val      P.Value        t        B    logFC Gene.symbol
# 209108_at 209108_at 0.08400054 4.438757e-06 6.686977 3.786222 3.949088      TSPAN6
# 204975_at 204975_at 0.08400054 6.036355e-06 6.520775 3.550036 2.919995        EMP2
#                            Gene.title
# 209108_at                tetraspanin 6
# 204975_at epithelial membrane protein 2
</syntaxhighlight>
== Biostrings ==
* Find the location of a particular sequence. [https://www.rdocumentation.org/packages/Biostrings/versions/2.40.2/topics/matchPattern ?vmatchPattern]
* https://www.bioconductor.org/help/course-materials/2011/BioC2011/LabStuff/BiostringsBSgenomeOverview.pdf
<syntaxhighlight lang='rsplus'>
library(Biostrings)
library(BSgenome.Hsapiens.UCSC.hg19)
vmatchPattern("GCGATCGC", Hsapiens)
</syntaxhighlight>
== plyranges ==
http://bioconductor.org/packages/devel/bioc/vignettes/plyranges/inst/doc/an-introduction.html
= Misc =
== Package release history ==
https://support.bioconductor.org/p/69657/
Search the DESCRIPTION file (eg. [https://github.com/Bioconductor/VariantAnnotation/commits/master/DESCRIPTION VariantAnnotation] package) in github and the release information can be found there.


=== Gene centric ===
== Papers/Overview ==
* [https://www.sciencedirect.com/science/article/pii/S1525157819303976 Using R and Bioconductor in Clinical Genomics and Transcriptomics] 2019
* [https://youtu.be/nzY7bPQOXUs Lori Ann Shepherd: "What is Bioconductor? : How the Core Team Plays an Essential Role] (video) 2021
* [https://almeidasilvaf.github.io/blog/2022-01-03-bioc_publications/ Where can I publish a paper describing my Bioconductor package?]


=== Genomic centric ===
= Cloud =
[https://f1000research.com/slides/9-1456?s=09 Bioconductor On The Cloud]


=== Web based ===
= Conferences =
* [https://bioc2021.bioconductor.org/ Bioc 2021], https://www.youtube.com/user/bioconductor
* [https://bioc2020.bioconductor.org/ Bioc 2020], [https://biocasia2020.bioconductor.org/ BiocAsia 2020] & [https://www.youtube.com/playlist?list=PLdl4u5ZRDMQQT5Vw0T_CbVru5_YnzauRq all videos], [https://eurobioc2020.bioconductor.org/workshops?s=09 European Bioconductor Meeting 2020]
* [http://bioc2019.bioconductor.org/ Bioc 2019], [https://bioconductor.github.io/BiocAsia/ BiocAsia 2019]
* [https://csama2022.bioconductor.eu/ CSAMA Bioconductor 2022] https://github.com/Bioconductor/CSAMA

Latest revision as of 12:45, 17 April 2024

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Check if my current Bioconductor version is outdated

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require(BiocManager)
# Loading required package: BiocManager
# Bioconductor version 3.15 (BiocManager 1.30.20), R 4.2.2
#   Patched (2022-11-10 r83330)
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Upgrade to the latest Bioconductor version

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if (!require("BiocManager", quietly = TRUE))
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BiocManager::install(version = "3.12") # the latest version can be obtained from the 
                                       # output of require(BiocManager) OR
                                       # checking the Bioconductor website 
# Upgrade 53 packages to Bioconductor version '3.12'? [y/n]: y

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CAlling BiocManager::install() without any arguments will attempt to update all installed packages in your R environment. It checks for updates on Bioconductor, CRAN, and GitHub, and if newer versions of the packages are available, it will download and install them.

When I run it on Docker, it will also install BiocVersion package from Bioconductor.

BiocManager::install()

BiocVersion

BiocVersion.

  • The BiocManager::install() function in R automatically installs the BiocVersion package during its first use. The BiocVersion package provides repository information for the appropriate version of Bioconductor. It helps BiocManager determine the version of Bioconductor in use. If BiocVersion has not yet been installed, the version is determined by code in base R. This ensures that all Bioconductor packages work best when they are all from the same release. See the document Install or update Bioconductor, CRAN, or GitHub packages from BiocManager.
  • This package was suggested (not a default option by install.packages()) by BiocManager and more importantly imported by AnnotationHub.
  • It seems BiocVersion gives the patch version if we like to get that information. For example the current Bioc is 3.14 but I have Bioconductor version 3.13.1.
R> BiocManager::version()
[1] ‘3.13’
R> packageVersion("BiocVersion")
[1] ‘3.13.1’

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It allows to have multiple versions of Bioconductor installed on the same computer. For example, R 3.5 works with Bioconductor 3.7 and 3.8.

On the other hand, setRepositories(ind=1:4) and install.packages() still lets you install Bioconductor packages.

Hacking Bioconductor

BiocPkgTools

BioCExplorer

Explore Bioconductor packages more nicely

source("https://bioconductor.org/biocLite.R")
biocLite("BiocUpgrade")
biocLite("biocViews")
devtools::install_github("seandavi/BiocPkgTools")
devtools::install_github("shians/BioCExplorer")
library(BioCExplorer)
bioc_explore()

BiocExplorer.png

BiocViews

  • Software
  • AnnotationData
    • ChipManufacturer
    • ChipName
    • CustomArray
    • CustomCDF
    • CustomDBSchema
    • FunctionalAnnotation
    • Organism
    • PackageType
    • SequenceAnnotation
  • ExperimentData
    • AssayDomainData
    • DiseaseModel
    • OrganismData
    • PackageTypeData
    • RepositoryData
    • ReproducibleResearch
    • SpecimenSource
    • TechnologyData
  • Workflow
    • AnnotationWorkflow
    • BasicWorkflow
    • DifferentialSplicingWorkflow
    • EpigeneticsWorkflow
    • GeneExpressionWorkflow
    • GenomicVariantsWorkflow
    • ImmunoOncologyWorkflow
    • ProteomicsWorkflow
    • ResourceQueryingWorkflow
    • SingleCellWorkflow

Annotation packages

  • Introduction to Bioconductor annotation resources 2020 Bioc workshop
    • Package type Example
      ChipDb hgu133plus2.db
      OrgDb org.Hs.eg.db
      TxDb/EnsDb TxDb.Hsapiens.UCSC.hg19.knownGene; EnsDb.Hsapiens.v75
      OrganismDb Homo.sapiens
      BSgenome BSgenome.Hsapiens.UCSC.hg19
      Others GO.db; KEGG.db
      biomaRt
    • Database concept was used. So there are some terms like keys, select, ..., borrowed from there.
    • How do you know what the central keys are? If it's ChipDb (e.g. hugene20sttranscriptcluster.db), the central key are the manufactorer's probe IDs. If it's in the name - org.Hs.eg.db, where 'eg' means Entrez gene ID. You can see examples using e.g., head(keys(annopkg)), and infer from that.
    • Functions (select, mapIds, transcripts accessors work on ChipDb, TxDb, OrgDb, ...). See the blog Bioconductor annotation packages
      AnnotationDbi::keys(hgu133plus2.db, keytype="PROBEID")
      AnnotationDbi::keytypes(hgu133plus2.db)  # columns(hgu133plus2.db)
      AnnotationDbi::select(annopkg, keys, columns, keytype): keytype is optional
      AnnotationDbi::mapIds(annopkg, keys, column, keytype, multiVals): 
                     keytype is required, multiVals is used to handle duplicates.
      
    • Packages
      TxDb packages - eg TxDb.Hsapiens.UCSC.hg19.knownGene. It contains positional information.
      EnsDb packages - eg EnsDb.Hsapiens.v79
      
    • Examples: ChipDb
      library(hgu133plus2.db)  # Loading required package: org.Hs.eg.db
      keytypes(hgu133plus2.db)
      # [1] "ACCNUM"       "ALIAS"        "ENSEMBL"      "ENSEMBLPROT"  "ENSEMBLTRANS"
      # [6] "ENTREZID"     "ENZYME"       "EVIDENCE"     "EVIDENCEALL"  "GENENAME"    
      #[11] "GO"           "GOALL"        "IPI"          "MAP"          "OMIM"        
      #[16] "ONTOLOGY"     "ONTOLOGYALL"  "PATH"         "PFAM"         "PMID"        
      #[21] "PROBEID"      "PROSITE"      "REFSEQ"       "SYMBOL"       "UCSCKG"      
      #[26] "UNIGENE"      "UNIPROT"  
      ls("package:hgu133plus2.db")
      
      # Get all probe IDs
      length(hgu133plus2ACCNUM)
      # [1] 54675
      x <- hgu133plus2ACCNUM 
      # hgu133plus2ACCNUM is an R object that contains mappings between 
      # a manufacturer’s identifiers and manufacturers accessions.
      mapped_probes <- mappedkeys(x)
      str(mapped_probes)
      # chr [1:54675] "1007_s_at" "1053_at" "117_at" "121_at" "1255_g_at" ...
      length(unique(mapped_probes))
      # [1] 54675
      
      length(hgu133plus2ENTREZID)
      # [1] 54675
      x <- hgu133plus2ENTREZID
      mapped_probes <- mappedkeys(x)
      str(mapped_probes)
      # chr [1:41905] "1053_at" "117_at" "121_at" "1255_g_at" "1316_at" "1320_at" ...
      length(unique(mapped_probes))
      # [1] 41905
      
      # Using select() to map from probe ID to others
      # Note select() will return 1:many mapping
      library(hugene20sttranscriptcluster.db)
      ids <- c('16737401','16657436' ,'16678303')
      select(hugene20sttranscriptcluster.db, ids, c("SYMBOL","ALIAS", "ENSEMBL", "ENTREZID"))
      ## 'select()' returned 1:many mapping between keys and columns
      #     PROBEID   SYMBOL    ALIAS         ENSEMBL  ENTREZID
      # 1  16737401    TRAF6 MGC:3310 ENSG00000175104      7189
      # 2  16737401    TRAF6    RNF85 ENSG00000175104      7189
      # 3  16737401    TRAF6    TRAF6 ENSG00000175104      7189
      # 4  16657436  DDX11L1  DDX11L1 ENSG00000223972 100287102
      # 5  16657436 DDX11L17 DDX11L17 ENSG00000223972 102725121
      # 6  16657436  DDX11L2  DDX11L2 ENSG00000223972     84771
      # 7  16657436  DDX11L9  DDX11L9 ENSG00000248472 100288486
      # 8  16657436  DDX11L9  DDX11L9 ENSG00000288170 100288486
      # 9  16657436 DDX11L10  DDX11L1 ENSG00000233614 100287029
      # 10 16657436 DDX11L10   DDX11P ENSG00000233614 100287029
      # 11 16657436 DDX11L10 DDX11L10 ENSG00000233614 100287029
      # 12 16657436  DDX11L5  DDX11L5 ENSG00000223972 100287596
      # 13 16657436  DDX11L5  DDX11L5 ENSG00000248472 100287596
      # 14 16657436  DDX11L5  DDX11L5 ENSG00000288170 100287596
      # 15 16657436 DDX11L16 DDX11L16 ENSG00000223972    727856
      # 16 16657436 DDX11L16 DDX11L16 ENSG00000248472    727856
      # 17 16657436 DDX11L16 DDX11L16 ENSG00000233614    727856
      # 18 16657436 DDX11L16 DDX11L16 ENSG00000288170    727856
      # 19 16678303     ARF1    PVNH8 ENSG00000143761       375
      # 20 16678303     ARF1     ARF1 ENSG00000143761       375
      
      keytypes(hugene20sttranscriptcluster.db)
      ##  [1] "ACCNUM"       "ALIAS"        "ENSEMBL"      "ENSEMBLPROT"  "ENSEMBLTRANS"
      ##  [6] "ENTREZID"     "ENZYME"       "EVIDENCE"     "EVIDENCEALL"  "GENENAME"    
      ## [11] "GO"           "GOALL"        "IPI"          "MAP"          "OMIM"        
      ## [16] "ONTOLOGY"     "ONTOLOGYALL"  "PATH"         "PFAM"         "PMID"        
      ## [21] "PROBEID"      "PROSITE"      "REFSEQ"       "SYMBOL"       "UCSCKG"      
      ## [26] "UNIGENE"      "UNIPROT"
      
      # mapIds
      # Note that an additional argument, multiVals can be used to control duplicates
      mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID") # only select the 1st one
      ##  16737401  16657436  16678303 
      ##   "TRAF6" "DDX11L1"    "ARF1"
      mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID", multiVals = "list")  # list
      mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID", multiVals = "CharacterList") # IRanges
      mapIds(hugene20sttranscriptcluster.db, ids, "SYMBOL", "PROBEID", multiVals = "filter") # character vector
      
      # OrganismDb packages
      library(Homo.sapiens)
      Homo.sapiens
      head(genes(Homo.sapiens, columns = c("ENTREZID", "ALIAS", "UNIPROT")), 4)
      

Gene centric

library(hgu133a.db)
library(AnnotationDbi)
k <- head(keys(hgu133a.db, keytype="PROBEID"))
k
# [1] "1007_s_at" "1053_at"   "117_at"    "121_at"    "1255_g_at" "1294_at"
# then call select
select(hgu133a.db, keys=k, columns=c("SYMBOL","GENENAME"), keytype="PROBEID")

# 'select()' returned 1:many mapping between keys and columns
#     PROBEID  SYMBOL                                     GENENAME
# 1 1007_s_at    DDR1  discoidin domain receptor tyrosine kinase 1
# 2 1007_s_at MIR4640                                microRNA 4640
# 3   1053_at    RFC2               replication factor C subunit 2
# 4    117_at   HSPA6 heat shock protein family A (Hsp70) member 6
# 5    121_at    PAX8                                 paired box 8
# 6 1255_g_at  GUCA1A               guanylate cyclase activator 1A
# 7   1294_at    UBA7  ubiquitin like modifier activating enzyme 7
# 8   1294_at MIR5193                                microRNA 5193

ExpressionSets objects

For example: load(file.path(system.file(package = "Bioc2020Anno", "extdata"), "eset.Rdata")

  • exprs(eset)
  • pData(phenoData(eset))
  • pData(featureData(eset))

Genomic centric

  • GRanges()
  • GrangesList()

GRanges() and GRangesLists act like data.frames and lists, and can be subsetted using the [ function.

SummarizedExperiment objects

SummarizedExperiment objects are like ExpressionSets, but the row-wise annotations are GRanges, so you can subset by genomic locations.

SummarizedExperiment objects are like ExpressionSets, but the row-wise annotations are GRanges, so you can subset by genomic locations.

SummarizedExperiment objects are popular objects for representing expression data and other rectangular data (feature x sample data).

  • array() or assays(): genes x samples
  • colData(): samples x sample features
  • rowData(): genes x gene features. The gene features could be result from running analyses; see EnrichmentBrowser vignette.

Examples: GSEABenchmarkeR package.

biomaRt

library(biomaRt)
listMarts(host = "useast.ensembl.org")

# biomaRt data sets
mart <- useEnsembl("ensembl")
head(listDatasets(mart))

# biomaRt queries
mart <- useEnsembl("ensembl","hsapiens_gene_ensembl")

# biomaRt attributes and filters
atrib <- listAttributes(mart)
filts <- listFilters(mart)
head(atrib)
head(filts)

# biomaRt query
afyids <- c("1000_at","1001_at","1002_f_at","1007_s_at")
getBM(c("affy_hg_u95av2", "hgnc_symbol"), c("affy_hg_u95av2"), afyids, mart)

AnnotationHub

library(AnnotationHub)
hub <- AnnotationHub()
hub
# Querying AnnotationHub
names(mcols(hub))

# AnnotationHub Data providers
unique(hub$dataprovider)

# AnnotationHub Data classes
unique(hub$rdataclass)

# AnnotationHub Species
head(unique(hub$species))
length(unique(hub$species))

# AnnotationHub Data sources
unique(hub$sourcetype)

# AnnotationHub query
qry <- query(hub, c("granges","homo sapiens","ensembl"))
qry
qry$sourceurl

# Selecting AnnotationHub resource
whatIwant <- qry[["AH80077"]]
GRCh38TxDb <- makeTxDbFromGRanges(whatIwant)
GRCh38TxDb

Map Ensembl IDs to Entrez IDs

See the vignette from SingscoreAMLMutations.

Multimapped Ensembl IDs are replaced by NAs, then discarded to enforce unique mapping. Similarly, Entrez IDs that map to multiple Ensembl IDs are identified from the mapping, and discarded. Only features with unique Ensembl ID to Entrez ID mappings remain.

Gene name errors from Excel

Gene name errors from Excel. Gene names such as MAR1, DEC1, OCT4 and SEPT9 are now reformatted as dates.

Example

Meet NOTCH2NL, the human-specific genes that may have given us our big brains

library(hgu133plus2.db)
select(hgu133plus2.db, keys="NOTCH2NL", columns=c("SYMBOL","GENENAME"), keytype="SYMBOL")
# Error in .testForValidKeys(x, keys, keytype, fks) : 
#   None of the keys entered are valid keys for 'SYMBOL'. Please use the keys method 
#   to see a listing of valid arguments.
k <- keys(hgu133plus2.db, keytype="SYMBOL")
k <- sort(k)
grep("NOTCH", k)
# [1] 41224 41225 41226 41227 41228 41229 41230 41231 41232
k[grep("NOTCH", k) ]
[1] "NOTCH1"    "NOTCH2"    "NOTCH2NLA" "NOTCH2NLB" "NOTCH2NLC" "NOTCH2NLR" "NOTCH2P1" 
[8] "NOTCH3"    "NOTCH4" 

Workflow

Using Bioconductor for Sequence Data

CyTOF

CyTOF workflow: differential discovery in high-throughput high-dimensional cytometry datasets

Some packages

Biobase, GEOquery and limma

How to create an ExpressionSet object from scratch? Here we use the code from GEO2R to help to do this task.

library(Biobase)
library(GEOquery)
library(limma)

# Load series and platform data from GEO

gset <- getGEO("GSE32474", GSEMatrix =TRUE, AnnotGPL=TRUE)
if (length(gset) > 1) idx <- grep("GPL570", attr(gset, "names")) else idx <- 1
gset <- gset[[idx]]
# save(gset, file = "~/Downloads/gse32474_gset.rda")
# load("~/Downloads/gse32474_gset.rda")
table(pData(gset)[, "cell line:ch1"])
pData(gset)

# Create an ExpressionSet object from scratch
# We take a shortcut to obtain the pheno data and feature data matrices 
# from the output of getGEO()
phenoDat <- new("AnnotatedDataFrame",
                 data=pData(gset))
featureDat <- new("AnnotatedDataFrame",
                  data=fData(gset))
exampleSet <- ExpressionSet(assayData=exprs(gset),
                            phenoData=phenoDat,
                            featureData=featureDat,
                            annotation="hgu133plus2")
gset <- exampleSet

# Make proper column names to match toptable 
fvarLabels(gset) <- make.names(fvarLabels(gset))

# group names for all samples
gsms <- paste0("00000000111111111XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX",
               "XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX",
               "XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX",
               "XXXXXXXXXXXXXXXXXXXXXXXX")
sml <- c()
for (i in 1:nchar(gsms)) { sml[i] <- substr(gsms,i,i) }

# Subset an ExpressionSet by eliminating samples marked as "X"
sel <- which(sml != "X")
sml <- sml[sel]
gset <- gset[ ,sel]

# Decide if it is necessary to do a log2 transformation
ex <- exprs(gset)
qx <- as.numeric(quantile(ex, c(0., 0.25, 0.5, 0.75, 0.99, 1.0), na.rm=T))
LogC <- (qx[5] > 100) ||
  (qx[6]-qx[1] > 50 && qx[2] > 0) ||
  (qx[2] > 0 && qx[2] < 1 && qx[4] > 1 && qx[4] < 2)
if (LogC) { ex[which(ex <= 0)] <- NaN
exprs(gset) <- log2(ex) }

# Set up the data and proceed with analysis
sml <- paste("G", sml, sep="")    # set group names
fl <- as.factor(sml)
gset$description <- fl
design <- model.matrix(~ description + 0, gset)
colnames(design) <- levels(fl)
fit <- lmFit(gset, design)
cont.matrix <- makeContrasts(G1-G0, levels=design)
fit2 <- contrasts.fit(fit, cont.matrix)
fit2 <- eBayes(fit2, 0.01)
tT <- topTable(fit2, adjust="fdr", sort.by="B", number=250)

# Display the result with selected columns
tT <- subset(tT, select=c("ID","adj.P.Val","P.Value","t","B","logFC","Gene.symbol","Gene.title"))
tT[1:2, ]
#                  ID  adj.P.Val      P.Value        t        B    logFC Gene.symbol
# 209108_at 209108_at 0.08400054 4.438757e-06 6.686977 3.786222 3.949088      TSPAN6
# 204975_at 204975_at 0.08400054 6.036355e-06 6.520775 3.550036 2.919995        EMP2
#                             Gene.title
# 209108_at                 tetraspanin 6
# 204975_at epithelial membrane protein 2

Biostrings

library(Biostrings) 
library(BSgenome.Hsapiens.UCSC.hg19) 
vmatchPattern("GCGATCGC", Hsapiens)

plyranges

http://bioconductor.org/packages/devel/bioc/vignettes/plyranges/inst/doc/an-introduction.html

Misc

Package release history

https://support.bioconductor.org/p/69657/

Search the DESCRIPTION file (eg. VariantAnnotation package) in github and the release information can be found there.

Papers/Overview

Cloud

Bioconductor On The Cloud

Conferences