recount 1.10.13
R
is an open-source statistical environment which can be easily modified to enhance its functionality via packages. recount is a R
package available via the Bioconductor repository for packages. R
can be installed on any operating system from CRAN after which you can install recount by using the following commands in your R
session:
install.packages("BiocManager")
BiocManager::install("recount")
## Check that you have a valid Bioconductor installation
BiocManager::valid()
recount is based on many other packages and in particular in those that have implemented the infrastructure needed for dealing with RNA-seq data. That is, packages like GenomicFeatures and rtracklayer that allow you to import the data. A recount user is not expected to deal with those packages directly but will need to be familiar with SummarizedExperiment to understand the results recount generates. It might also prove to be highly beneficial to check the
If you are asking yourself the question “Where do I start using Bioconductor?” you might be interested in this blog post.
As package developers, we try to explain clearly how to use our packages and in which order to use the functions. But R
and Bioconductor
have a steep learning curve so it is critical to learn where to ask for help. The blog post quoted above mentions some but we would like to highlight the Bioconductor support site as the main resource for getting help: remember to use the recount
tag and check the older posts. Other alternatives are available such as creating GitHub issues and tweeting. However, please note that if you want to receive help you should adhere to the posting guidelines. It is particularly critical that you provide a small reproducible example and your session information so package developers can track down the source of the error.
We have written a workflow on how to use recount that explains more details on how to use this package with other Bioconductor packages as well as the details on the actual counts provided by recount. Check it at f1000research.com/articles/6-1558/v1 or bioconductor.org/help/workflows/recountWorkflow/ (Collado-Torres, Nellore, and Jaffe, 2017).
We hope that recount will be useful for your research. Please use the following information to cite the package and the overall approach. Thank you!
## Citation info
citation('recount')
##
## Collado-Torres L, Nellore A, Kammers K, Ellis SE, Taub MA, Hansen
## KD, Jaffe AE, Langmead B, Leek JT (2017). "Reproducible RNA-seq
## analysis using recount2." _Nature Biotechnology_. doi:
## 10.1038/nbt.3838 (URL: https://doi.org/10.1038/nbt.3838), <URL:
## http://www.nature.com/nbt/journal/v35/n4/full/nbt.3838.html>.
##
## Collado-Torres L, Nellore A, Jaffe AE (2017). "recount workflow:
## Accessing over 70,000 human RNA-seq samples with Bioconductor
## [version 1; referees: 1 approved, 2 approved with reservations]."
## _F1000Research_. doi: 10.12688/f1000research.12223.1 (URL:
## https://doi.org/10.12688/f1000research.12223.1), <URL:
## https://f1000research.com/articles/6-1558/v1>.
##
## Ellis SE, Collado-Torres L, Jaffe AE, Leek JT (2018). "Improving the
## value of public RNA-seq expression data by phenotype prediction."
## _Nucl. Acids Res._. doi: 10.1093/nar/gky102 (URL:
## https://doi.org/10.1093/nar/gky102), <URL:
## https://doi.org/10.1093/nar/gky102>.
##
## Collado-Torres L, Nellore A, Kammers K, Ellis SE, Taub MA, Hansen
## KD, Jaffe AE, Langmead B, Leek JT (2019). _Explore and download data
## from the recount project_. doi: 10.18129/B9.bioc.recount (URL:
## https://doi.org/10.18129/B9.bioc.recount),
## https://github.com/leekgroup/recount - R package version 1.10.13,
## <URL: http://www.bioconductor.org/packages/recount>.
##
## Frazee AC, Langmead B, Leek JT (2011). "ReCount: A multi-experiment
## resource of analysis-ready RNA-seq gene count datasets." _BMC
## Bioinformatics_. doi: 10.1186/1471-2105-12-449 (URL:
## https://doi.org/10.1186/1471-2105-12-449), <URL:
## https://doi.org/10.1186/1471-2105-12-449>.
##
## Razmara A, Ellis SE, Sokolowski DJ, Davis S, Wilson MD, Leek JT,
## Jaffe AE, Collado-Torres L (2019). "recount-brain: a curated
## repository of human brain RNA-seq datasets metadata." _bioRxiv_.
## doi: 10.1101/618025 (URL: https://doi.org/10.1101/618025), <URL:
## https://doi.org/10.1101/618025>.
##
## Imada E, Sanchez DF, Collado-Torres L, Wilks C, Matam T, Dinalankara
## W, Stupnikov A, Lobo-Pereira F, Yip C, Yasuzawa K, Kondo N, Itoh M,
## Suzuki H, Kasukawa T, Hon CC, de Hoon M, Shin JW, Carninci P,
## FANTOM-consortium, Jaffe AE, Leek JT, Favorov A, Franco GR, Langmead
## B, Marchionni L (2019). "Recounting the FANTOM Cage Associated
## Transcriptome." _bioRxiv_. doi: 10.1101/659490 (URL:
## https://doi.org/10.1101/659490), <URL:
## https://doi.org/10.1101/659490>.
##
## To see these entries in BibTeX format, use 'print(<citation>,
## bibtex=TRUE)', 'toBibtex(.)', or set
## 'options(citation.bibtex.max=999)'.
Main updates:
Here is a very quick example of how to download a RangedSummarizedExperiment
object with the gene counts for a 2 groups project (12 samples) with SRA study id SRP009615 using the recount package (Collado-Torres, Nellore, Kammers, Ellis, et al., 2017). The RangedSummarizedExperiment
object is defined in the SummarizedExperiment (Morgan, Obenchain, Hester, and Pagès, 2017) package and can be used for differential expression analysis with different packages. Here we show how to use DESeq2 (Love, Huber, and Anders, 2014) to perform the differential expresion analysis.
This quick analysis is explained in more detail later on in this document. Further information about the recount project can be found in the main publication. Check the recount website for related publications.
## Load library
library('recount')
## Find a project of interest
project_info <- abstract_search('GSE32465')
## Download the gene-level RangedSummarizedExperiment data
download_study(project_info$project)
## Load the data
load(file.path(project_info$project, 'rse_gene.Rdata'))
## Browse the project at SRA
browse_study(project_info$project)
## View GEO ids
colData(rse_gene)$geo_accession
## Extract the sample characteristics
geochar <- lapply(split(colData(rse_gene), seq_len(nrow(colData(rse_gene)))), geo_characteristics)
## Note that the information for this study is a little inconsistent, so we
## have to fix it.
geochar <- do.call(rbind, lapply(geochar, function(x) {
if('cells' %in% colnames(x)) {
colnames(x)[colnames(x) == 'cells'] <- 'cell.line'
return(x)
} else {
return(x)
}
}))
## We can now define some sample information to use
sample_info <- data.frame(
run = colData(rse_gene)$run,
group = ifelse(grepl('uninduced', colData(rse_gene)$title), 'uninduced', 'induced'),
gene_target = sapply(colData(rse_gene)$title, function(x) { strsplit(strsplit(x,
'targeting ')[[1]][2], ' gene')[[1]][1] }),
cell.line = geochar$cell.line
)
## Scale counts by taking into account the total coverage per sample
rse <- scale_counts(rse_gene)
## Add sample information for DE analysis
colData(rse)$group <- sample_info$group
colData(rse)$gene_target <- sample_info$gene_target
## Perform differential expression analysis with DESeq2
library('DESeq2')
## Specify design and switch to DESeq2 format
dds <- DESeqDataSet(rse, ~ gene_target + group)
## Perform DE analysis
dds <- DESeq(dds, test = 'LRT', reduced = ~ gene_target, fitType = 'local')
res <- results(dds)
## Explore results
plotMA(res, main="DESeq2 results for SRP009615")
## Make a report with the results
library('regionReport')
DESeq2Report(dds, res = res, project = 'SRP009615',
intgroup = c('group', 'gene_target'), outdir = '.',
output = 'SRP009615-results')
The recount project also hosts the necessary data to perform annotation-agnostic differential expression analyses with derfinder (Collado-Torres, Nellore, Frazee, Wilks, et al., 2017). An example analysis would like this:
## Define expressed regions for study SRP009615, only for chromosome Y
regions <- expressed_regions('SRP009615', 'chrY', cutoff = 5L,
maxClusterGap = 3000L)
## Compute coverage matrix for study SRP009615, only for chromosome Y
system.time( rse_ER <- coverage_matrix('SRP009615', 'chrY', regions) )
## Round the coverage matrix to integers
covMat <- round(assays(rse_ER)$counts, 0)
## Get phenotype data for study SRP009615
pheno <- colData(rse_ER)
## Complete the phenotype table with the data we got from GEO
m <- match(pheno$run, sample_info$run)
pheno <- cbind(pheno, sample_info[m, 2:3])
## Build a DESeqDataSet
dds_ers <- DESeqDataSetFromMatrix(countData = covMat, colData = pheno,
design = ~ gene_target + group)
## Perform differential expression analysis with DESeq2 at the ER-level
dds_ers <- DESeq(dds_ers, test = 'LRT', reduced = ~ gene_target,
fitType = 'local')
res_ers <- results(dds_ers)
## Explore results
plotMA(res_ers, main="DESeq2 results for SRP009615 (ER-level, chrY)")
## Create a more extensive exploratory report
DESeq2Report(dds_ers, res = res_ers,
project = 'SRP009615 (ER-level, chrY)',
intgroup = c('group', 'gene_target'), outdir = '.',
output = 'SRP009615-results-ER-level-chrY')
recount is an R package that provides an interface to the recount project website. This package allows you to download the files from the recount project and has helper functions for getting you started with differential expression analyses. This vignette will walk you through an example.
This is a brief overview of what you can do with recount. In this particular example we will download data from the SRP009615 study which sequenced 12 samples as described in the previous link.
If you don’t have recount installed, please do so with:
install.packages("BiocManager")
BiocManager::install("recount")
Next we load the required packages. Loading recount will load the required dependencies.
## Load recount R package
library('recount')
Lets say that we don’t know the actual SRA accession number for this study but we do know a particular term which will help us identify it. If that’s the case, we can use the abstract_search()
function to identify the study of interest as shown below.
## Find a project of interest
project_info <- abstract_search('GSE32465')
## Explore info
project_info
## number_samples species
## 340 12 human
## abstract
## 340 Summary: K562-shX cells are made in an effort to validate TFBS data and ChIP-seq antibodies in Myers lab (GSE32465). K562 cells are transduced with lentiviral vector having Tet-inducible shRNA targeting a transcription factor gene. Cells with stable integration of shRNA constructs are selected using puromycin in growth media. Doxycycline is added to the growth media to induce the expression of shRNA and a red fluorescent protein marker. A successful shRNA cell line shows at least a 70% reduction in expression of the target transcription factor as measured by qPCR. For identification, we designated these cell lines as K562-shX, where X is the transcription factor targeted by shRNA and K562 denotes the parent cell line. For example, K562-shATF3 cells are K562 derived cells selected for stable integration of shRNA targeting the transcription factor ATF3 gene and showed at least a 70% reduction in the expression of ATF3 gene when measured by qPCR. Cells growing without doxycycline (uninduced) are used as a control to measure the change in expression of target transcription factor gene after induction of shRNA using doxycycline. For detailed growth and culturing protocols for these cells please refer to http://hudsonalpha.org/myers-lab/protocols . To identify the potential downstream targets of the candidate transcription factor, analyze the mRNA expression profile of the uninduced and induced K562-shX using RNA-seq. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf Overall Design: Make K562-shX cells as described in the http://hudsonalpha.org/myers-lab/protocols . Measure the mRNA expression levels in uninduced K562-shX and induced K562-shX cells in two biological replicates using RNA-seq. Identify the potential downstream targets of the candidate transcription factor.
## project
## 340 SRP009615
Now that we have a study that we are interested in, we can download the RangedSummarizedExperiment object (see SummarizedExperiment) with the data summarized at the gene level. The function download_study()
helps us do this. If you are interested on how the annotation was defined, check reproduce_ranges()
described in the Annotation section further down.
## Download the gene-level RangedSummarizedExperiment data
download_study(project_info$project)
## 2019-09-03 22:05:39 downloading file rse_gene.Rdata to SRP009615
## Load the data
load(file.path(project_info$project, 'rse_gene.Rdata'))
## Delete it if you don't need it anymore
unlink(project_info$project, recursive = TRUE)
We can explore a bit this RangedSummarizedExperiment as shown below.
rse_gene
## class: RangedSummarizedExperiment
## dim: 58037 12
## metadata(0):
## assays(1): counts
## rownames(58037): ENSG00000000003.14 ENSG00000000005.5 ...
## ENSG00000283698.1 ENSG00000283699.1
## rowData names(3): gene_id bp_length symbol
## colnames(12): SRR387777 SRR387778 ... SRR389083 SRR389084
## colData names(21): project sample ... title characteristics
## This is the sample phenotype data provided by the recount project
colData(rse_gene)
## DataFrame with 12 rows and 21 columns
## project sample experiment run
## <character> <character> <character> <character>
## SRR387777 SRP009615 SRS281685 SRX110461 SRR387777
## SRR387778 SRP009615 SRS281686 SRX110462 SRR387778
## SRR387779 SRP009615 SRS281687 SRX110463 SRR387779
## SRR387780 SRP009615 SRS281688 SRX110464 SRR387780
## SRR389077 SRP009615 SRS282369 SRX111299 SRR389077
## ... ... ... ... ...
## SRR389080 SRP009615 SRS282372 SRX111302 SRR389080
## SRR389081 SRP009615 SRS282373 SRX111303 SRR389081
## SRR389082 SRP009615 SRS282374 SRX111304 SRR389082
## SRR389083 SRP009615 SRS282375 SRX111305 SRR389083
## SRR389084 SRP009615 SRS282376 SRX111306 SRR389084
## read_count_as_reported_by_sra reads_downloaded
## <integer> <integer>
## SRR387777 30631853 30631853
## SRR387778 37001306 37001306
## SRR387779 40552001 40552001
## SRR387780 32466352 32466352
## SRR389077 27819603 27819603
## ... ... ...
## SRR389080 34856203 34856203
## SRR389081 23351679 23351679
## SRR389082 18144828 18144828
## SRR389083 24417368 24417368
## SRR389084 23060084 23060084
## proportion_of_reads_reported_by_sra_downloaded paired_end
## <numeric> <logical>
## SRR387777 1 FALSE
## SRR387778 1 FALSE
## SRR387779 1 FALSE
## SRR387780 1 FALSE
## SRR389077 1 FALSE
## ... ... ...
## SRR389080 1 FALSE
## SRR389081 1 FALSE
## SRR389082 1 FALSE
## SRR389083 1 FALSE
## SRR389084 1 FALSE
## sra_misreported_paired_end mapped_read_count auc
## <logical> <integer> <numeric>
## SRR387777 FALSE 28798572 1029494445
## SRR387778 FALSE 33170281 1184877985
## SRR387779 FALSE 37322762 1336528969
## SRR387780 FALSE 29970735 1073178116
## SRR389077 FALSE 24966859 893978355
## ... ... ... ...
## SRR389080 FALSE 32469994 1163527939
## SRR389081 FALSE 21904197 781685955
## SRR389082 FALSE 17199795 616048853
## SRR389083 FALSE 22499386 806323346
## SRR389084 FALSE 21957003 787795710
## sharq_beta_tissue sharq_beta_cell_type biosample_submission_date
## <character> <character> <character>
## SRR387777 blood k562 2011-12-05T15:40:03.870
## SRR387778 blood k562 2011-12-05T15:40:03.897
## SRR387779 blood k562 2011-12-05T15:40:03.910
## SRR387780 blood k562 2011-12-05T15:40:03.923
## SRR389077 blood k562 2011-12-13T11:26:05.720
## ... ... ... ...
## SRR389080 blood k562 2011-12-13T11:26:05.787
## SRR389081 blood k562 2011-12-13T11:26:05.800
## SRR389082 blood k562 2011-12-13T11:26:05.817
## SRR389083 blood k562 2011-12-13T11:26:05.830
## SRR389084 blood k562 2011-12-13T11:26:05.847
## biosample_publication_date biosample_update_date avg_read_length
## <character> <character> <integer>
## SRR387777 2011-12-07T09:29:59.890 2014-08-27T04:18:20.530 36
## SRR387778 2011-12-07T09:29:59.890 2014-08-27T04:18:21.053 36
## SRR387779 2011-12-07T09:29:59.890 2014-08-27T04:18:21.800 36
## SRR387780 2011-12-07T09:29:59.890 2014-08-27T04:18:22.320 36
## SRR389077 2011-12-13T11:26:06.663 2014-08-27T04:22:14.857 36
## ... ... ... ...
## SRR389080 2011-12-13T11:26:06.663 2014-08-27T04:22:15.933 36
## SRR389081 2011-12-13T11:26:06.663 2014-08-27T04:22:16.290 36
## SRR389082 2011-12-13T11:26:06.663 2014-08-27T04:22:16.647 36
## SRR389083 2011-12-13T11:26:06.663 2014-08-27T04:22:17.037 36
## SRR389084 2011-12-13T11:26:06.663 2014-08-27T04:22:17.473 36
## geo_accession bigwig_file
## <character> <character>
## SRR387777 GSM836270 SRR387777.bw
## SRR387778 GSM836271 SRR387778.bw
## SRR387779 GSM836272 SRR387779.bw
## SRR387780 GSM836273 SRR387780.bw
## SRR389077 GSM847561 SRR389077.bw
## ... ... ...
## SRR389080 GSM847564 SRR389080.bw
## SRR389081 GSM847565 SRR389081.bw
## SRR389082 GSM847566 SRR389082.bw
## SRR389083 GSM847567 SRR389083.bw
## SRR389084 GSM847568 SRR389084.bw
## title
## <character>
## SRR387777 K562 cells with shRNA targeting SRF gene cultured with no doxycycline (uninduced - UI), rep1.
## SRR387778 K562 cells with shRNA targeting SRF gene cultured with doxycycline for 48 hours (48 hr), rep1.
## SRR387779 K562 cells with shRNA targeting SRF gene cultured with no doxycycline (uninduced - UI), rep2.
## SRR387780 K562 cells with shRNA targeting SRF gene cultured with doxycycline for 48 hours (48 hr), rep2.
## SRR389077 K562 cells with shRNA targeting EGR1 gene cultured with no doxycycline (uninduced - UI), rep1.
## ... ...
## SRR389080 K562 cells with shRNA targeting EGR1 gene cultured with doxycycline for 72 hours (72 hr), rep2.
## SRR389081 K562 cells with shRNA targeting ATF3 gene cultured with no doxycycline (uninduced - UI), rep1.
## SRR389082 K562 cells with shRNA targeting ATF3 gene cultured with doxycycline for 24 hours (24 hr), rep1.
## SRR389083 K562 cells with shRNA targeting ATF3 gene cultured with no doxycycline (uninduced - UI), rep2.
## SRR389084 K562 cells with shRNA targeting ATF3 gene cultured with doxycycline for 24 hours (24 hr), rep2.
## characteristics
## <CharacterList>
## SRR387777 cells: K562,shRNA expression: no,treatment: Puromycin
## SRR387778 cells: K562,shRNA expression: yes, targeting SRF,treatment: Puromycin, doxycycline
## SRR387779 cells: K562,shRNA expression: no,treatment: Puromycin
## SRR387780 cells: K562,shRNA expression: yes targeting SRF,treatment: Puromycin, doxycycline
## SRR389077 cell line: K562,shRNA expression: no shRNA expression,treatment: Puromycin
## ... ...
## SRR389080 cell line: K562,shRNA expression: expressing shRNA targeting EGR1,treatment: Puromycin, doxycycline
## SRR389081 cell line: K562,shRNA expression: no shRNA expression,treatment: Puromycin
## SRR389082 cell line: K562,shRNA expression: expressing shRNA targeting ATF3,treatment: Puromycin, doxycycline
## SRR389083 cell line: K562,shRNA expression: no shRNA expression,treatment: Puromycin
## SRR389084 cell line: K562,shRNA expression: expressing shRNA targeting ATF3,treatment: Puromycin, doxycycline
## At the gene level, the row data includes the gene Gencode ids, the gene
## symbols and the sum of the disjoint exons widths, which can be used for
## taking into account the gene length.
rowData(rse_gene)
## DataFrame with 58037 rows and 3 columns
## gene_id bp_length symbol
## <character> <integer> <CharacterList>
## ENSG00000000003.14 ENSG00000000003.14 4535 TSPAN6
## ENSG00000000005.5 ENSG00000000005.5 1610 TNMD
## ENSG00000000419.12 ENSG00000000419.12 1207 DPM1
## ENSG00000000457.13 ENSG00000000457.13 6883 SCYL3
## ENSG00000000460.16 ENSG00000000460.16 5967 C1orf112
## ... ... ... ...
## ENSG00000283695.1 ENSG00000283695.1 61 NA
## ENSG00000283696.1 ENSG00000283696.1 997 NA
## ENSG00000283697.1 ENSG00000283697.1 1184 HSFX3
## ENSG00000283698.1 ENSG00000283698.1 940 NA
## ENSG00000283699.1 ENSG00000283699.1 60 MIR4481
## At the exon level, you can get the gene Gencode ids from the names of:
# rowRanges(rse_exon)
Once we have identified the study of interest, we can use the browse_study()
function to browse the study at the SRA website.
## Browse the project at SRA
browse_study(project_info$project)
The SRA website includes an Experiments link which further describes each of the samples. From the information available for SRP009615 at NCBI we have some further sample information that we can save for use in our differential expression analysis. We can get some of this information from GEO. The function find_geo()
finds the GEO accession id for a given SRA run accession id, which we can then use with geo_info()
and geo_characteristics()
to parse this information. The rse_gene
object already has some of this information.
## View GEO ids
colData(rse_gene)$geo_accession
## [1] "GSM836270" "GSM836271" "GSM836272" "GSM836273" "GSM847561" "GSM847562"
## [7] "GSM847563" "GSM847564" "GSM847565" "GSM847566" "GSM847567" "GSM847568"
## Extract the sample characteristics
geochar <- lapply(split(colData(rse_gene), seq_len(nrow(colData(rse_gene)))), geo_characteristics)
## Note that the information for this study is a little inconsistent, so we
## have to fix it.
geochar <- do.call(rbind, lapply(geochar, function(x) {
if('cells' %in% colnames(x)) {
colnames(x)[colnames(x) == 'cells'] <- 'cell.line'
return(x)
} else {
return(x)
}
}))
## We can now define some sample information to use
sample_info <- data.frame(
run = colData(rse_gene)$run,
group = ifelse(grepl('uninduced', colData(rse_gene)$title), 'uninduced', 'induced'),
gene_target = sapply(colData(rse_gene)$title, function(x) { strsplit(strsplit(x,
'targeting ')[[1]][2], ' gene')[[1]][1] }),
cell.line = geochar$cell.line
)
Shannon Ellis et at have predicted phenotypic information that can be used with any data from the recount project thanks to add_predictions()
. Check that function for more details (Ellis, Collado-Torres, Jaffe, and Leek, 2018).
The recount project records the sum of the base level coverage for each gene (or exon). These raw counts have to be scaled and there are several ways in which you can choose to do so. The function scale_counts()
helps you scale them in a way that is tailored to Rail-RNA output. If you prefer read counts without scaling, check the function read_counts()
. Below we show some of the differences.
## Scale counts by taking into account the total coverage per sample
rse <- scale_counts(rse_gene)
##### Details about counts #####
## Scale counts to 40 million mapped reads. Not all mapped reads are in exonic
## sequence, so the total is not necessarily 40 million.
colSums(assays(rse)$counts) / 1e6
## SRR387777 SRR387778 SRR387779 SRR387780 SRR389077 SRR389078 SRR389079
## 30.26702 29.07199 35.38355 34.65798 23.36050 22.62014 34.74629
## SRR389080 SRR389081 SRR389082 SRR389083 SRR389084
## 35.20971 33.41459 36.78133 34.05013 33.95469
## Compute read counts
rse_read_counts <- read_counts(rse_gene)
## Difference between read counts and number of reads downloaded by Rail-RNA
colSums(assays(rse_read_counts)$counts) / 1e6 -
colData(rse_read_counts)$reads_downloaded / 1e6
## SRR387777 SRR387778 SRR387779 SRR387780 SRR389077 SRR389078 SRR389079
## -8.839994 -12.892541 -7.536284 -6.497571 -13.239233 -15.816168 -14.775568
## SRR389080 SRR389081 SRR389082 SRR389083 SRR389084
## -6.274001 -5.054220 -2.328694 -5.265160 -4.421728
## Check the help page for read_counts() for more details
We are almost ready to perform our differential expression analysis. Lets just add the information we recovered GEO about these samples.
## Add sample information for DE analysis
colData(rse)$group <- sample_info$group
colData(rse)$gene_target <- sample_info$gene_target
Now that the RangedSummarizedExperiment is complete, we can use DESeq2 or another package to perform the differential expression test. Note that you can use DEFormats for switching between formats if you want to use another package, like edgeR.
In this particular analysis, we’ll test whether there is a group difference adjusting for the gene target.
## Perform differential expression analysis with DESeq2
library('DESeq2')
## Specify design and switch to DESeq2 format
dds <- DESeqDataSet(rse, ~ gene_target + group)
## converting counts to integer mode
## Perform DE analysis
dds <- DESeq(dds, test = 'LRT', reduced = ~ gene_target, fitType = 'local')
## estimating size factors
## estimating dispersions
## gene-wise dispersion estimates
## mean-dispersion relationship
## final dispersion estimates
## fitting model and testing
res <- results(dds)
We can now use functions from DESeq2 to explore the results. For more details check the DESeq2 vignette. For example, we can make a MA plot as shown in Figure 1.
## Explore results
plotMA(res, main="DESeq2 results for SRP009615")
We can also use the regionReport package to generate interactive HTML reports exploring the DESeq2 results (or edgeR results if you used that package).
## Make a report with the results
library('regionReport')
report <- DESeq2Report(dds, res = res, project = 'SRP009615',
intgroup = c('group', 'gene_target'), outdir = '.',
output = 'SRP009615-results', nBest = 10, nBestFeatures = 2)
## Warning in c.bibentry(knitcitations = citation("knitcitations"), regionReport
## = citation("regionReport")[1], : method is only applicable to 'bibentry'
## objects
## Writing 10 Bibtex entries ... OK
## Results written to file './SRP009615-results.bib'
## processing file: SRP009615-results.Rmd
## Warning in `[[.bibentry`(bib, "rmarkdown"): subscript out of bounds
## output file: SRP009615-results.knit.md
##
## Output created: SRP009615-results.html
You can view the final report here.
The gene Gencode ids are included in several objects in recount
. With these ids you can find the gene symbols, gene names and other information. The org.Hs.eg.db is useful for finding this information and the following code shows how to get the gene names and symbols.
## Load required library
library('org.Hs.eg.db')
## Loading required package: AnnotationDbi
##
## Extract Gencode gene ids
gencode <- gsub('\\..*', '', names(recount_genes))
## Find the gene information we are interested in
gene_info <- select(org.Hs.eg.db, gencode, c('ENTREZID', 'GENENAME', 'SYMBOL',
'ENSEMBL'), 'ENSEMBL')
## 'select()' returned many:many mapping between keys and columns
## Explore part of the results
dim(gene_info)
## [1] 58236 4
head(gene_info)
## ENSEMBL ENTREZID
## 1 ENSG00000000003 7105
## 2 ENSG00000000005 64102
## 3 ENSG00000000419 8813
## 4 ENSG00000000457 57147
## 5 ENSG00000000460 55732
## 6 ENSG00000000938 2268
## GENENAME SYMBOL
## 1 tetraspanin 6 TSPAN6
## 2 tenomodulin TNMD
## 3 dolichyl-phosphate mannosyltransferase subunit 1, catalytic DPM1
## 4 SCY1 like pseudokinase 3 SCYL3
## 5 chromosome 1 open reading frame 112 C1orf112
## 6 FGR proto-oncogene, Src family tyrosine kinase FGR
The recount project also hosts for each project sample coverage bigWig files created by Rail-RNA and a mean coverage bigWig file. For the mean coverage bigWig file, all samples were normalized to libraries of 40 million reads, each a 100 base-pairs long. recount can be used along with derfinder (Collado-Torres, Nellore, Frazee, Wilks, et al., 2017) to identify expressed regions from the data. This type of analysis is annotation-agnostic which can be advantageous. The following subsections illustrate this type of analysis.
For an annotation-agnostic differential expression analysis, we first need to define the regions of interest. With recount we can do so using the expressed_regions()
function as shown below for the same study we studied earlier.
## Define expressed regions for study SRP009615, only for chromosome Y
regions <- expressed_regions('SRP009615', 'chrY', cutoff = 5L,
maxClusterGap = 3000L)
## 2019-09-03 22:07:28 loadCoverage: loading BigWig file http://duffel.rail.bio/recount/SRP009615/bw/mean_SRP009615.bw
## 2019-09-03 22:07:30 loadCoverage: applying the cutoff to the merged data
## 2019-09-03 22:07:31 filterData: originally there were 57227415 rows, now there are 57227415 rows. Meaning that 0 percent was filtered.
## 2019-09-03 22:07:31 findRegions: identifying potential segments
## 2019-09-03 22:07:31 findRegions: segmenting information
## 2019-09-03 22:07:31 .getSegmentsRle: segmenting with cutoff(s) 5
## 2019-09-03 22:07:31 findRegions: identifying candidate regions
## 2019-09-03 22:07:33 findRegions: identifying region clusters
## Briefly explore the resulting regions
regions
## GRanges object with 808 ranges and 6 metadata columns:
## seqnames ranges strand | value area
## <Rle> <IRanges> <Rle> | <numeric> <numeric>
## 1 chrY 2929794-2929829 * | 14.7265009482702 530.154034137726
## 2 chrY 2956678-2956701 * | 12.8106340567271 307.45521736145
## 3 chrY 2977203-2977227 * | 5.34908433914185 133.727108478546
## 4 chrY 2977957-2977994 * | 6.46976616508082 245.851114273071
## 5 chrY 2978850-2978871 * | 5.7976552139629 127.548414707184
## ... ... ... ... . ... ...
## 804 chrY 26614511-26614546 * | 7.28189378314548 262.148176193237
## 805 chrY 26614548-26614553 * | 5.48768202463786 32.9260921478271
## 806 chrY 26614779-26614808 * | 6.64339276949565 199.301783084869
## 807 chrY 26626808-26626848 * | 12.6038152648181 516.756425857544
## 808 chrY 26626971-26627028 * | 14.1673366941255 821.705528259277
## indexStart indexEnd cluster clusterL
## <integer> <integer> <Rle> <Rle>
## 1 2929794 2929829 1 36
## 2 2956678 2956701 2 24
## 3 2977203 2977227 3 2750
## 4 2977957 2977994 3 2750
## 5 2978850 2978871 3 2750
## ... ... ... ... ...
## 804 26614511 26614546 224 298
## 805 26614548 26614553 224 298
## 806 26614779 26614808 224 298
## 807 26626808 26626848 225 221
## 808 26626971 26627028 225 221
## -------
## seqinfo: 1 sequence from an unspecified genome
Once the regions have been defined, you can export them into a BED file using rtracklayer or other file formats.
Having defined the expressed regions, we can now compute a coverage matrix for these regions. We can do so using the function coverage_matrix()
from recount as shown below. It returns a RangedSummarizedExperiment object.
## Compute coverage matrix for study SRP009615, only for chromosome Y
system.time( rse_ER <- coverage_matrix('SRP009615', 'chrY', regions) )
## 2019-09-03 22:07:35 railMatrix: processing regions 1 to 808
## 2019-09-03 22:07:35 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387777.bw
## 2019-09-03 22:07:36 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387778.bw
## 2019-09-03 22:07:38 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387779.bw
## 2019-09-03 22:07:39 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387780.bw
## 2019-09-03 22:07:41 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389077.bw
## 2019-09-03 22:07:42 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389078.bw
## 2019-09-03 22:07:43 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389079.bw
## 2019-09-03 22:07:45 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389080.bw
## 2019-09-03 22:07:46 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389081.bw
## 2019-09-03 22:07:48 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389082.bw
## 2019-09-03 22:07:49 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389083.bw
## 2019-09-03 22:07:51 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389084.bw
## user system elapsed
## 2.965 0.185 18.377
## Explore the RSE a bit
dim(rse_ER)
## [1] 808 12
rse_ER
## class: RangedSummarizedExperiment
## dim: 808 12
## metadata(0):
## assays(1): counts
## rownames(808): 1 2 ... 807 808
## rowData names(6): value area ... cluster clusterL
## colnames(12): SRR387777 SRR387778 ... SRR389083 SRR389084
## colData names(21): project sample ... title characteristics
The resulting count matrix has one row per region and one column per sample. The counts correspond to the number (or fraction) of reads overlapping the regions and are scaled by default to a library size of 40 million reads. For some differential expression methods, you might have to round this matrix into integers. We’ll use DESeq2 to identify which expressed regions are differentially expressed.
## Round the coverage matrix to integers
covMat <- round(assays(rse_ER)$counts, 0)
You can use scale = FALSE
if you want the raw base-pair coverage counts and then scale them with scale_counts()
. If you want integer counts, use round = TRUE
.
DESeqDataSet
objectWe first need to get some phenotype information for these samples similar to the first analysis we did. We can get this data using download_study()
.
## Get phenotype data for study SRP009615
pheno <- colData(rse_ER)
## Complete the phenotype table with the data we got from GEO
m <- match(pheno$run, sample_info$run)
pheno <- cbind(pheno, sample_info[m, 2:3])
## Explore the phenotype data a little bit
head(pheno)
## DataFrame with 6 rows and 23 columns
## project sample experiment run
## <character> <character> <character> <character>
## SRR387777 SRP009615 SRS281685 SRX110461 SRR387777
## SRR387778 SRP009615 SRS281686 SRX110462 SRR387778
## SRR387779 SRP009615 SRS281687 SRX110463 SRR387779
## SRR387780 SRP009615 SRS281688 SRX110464 SRR387780
## SRR389077 SRP009615 SRS282369 SRX111299 SRR389077
## SRR389078 SRP009615 SRS282370 SRX111300 SRR389078
## read_count_as_reported_by_sra reads_downloaded
## <integer> <integer>
## SRR387777 30631853 30631853
## SRR387778 37001306 37001306
## SRR387779 40552001 40552001
## SRR387780 32466352 32466352
## SRR389077 27819603 27819603
## SRR389078 31758658 31758658
## proportion_of_reads_reported_by_sra_downloaded paired_end
## <integer> <logical>
## SRR387777 1 FALSE
## SRR387778 1 FALSE
## SRR387779 1 FALSE
## SRR387780 1 FALSE
## SRR389077 1 FALSE
## SRR389078 1 FALSE
## sra_misreported_paired_end mapped_read_count auc
## <logical> <integer> <integer>
## SRR387777 FALSE 28798572 1029494445
## SRR387778 FALSE 33170281 1184877985
## SRR387779 FALSE 37322762 1336528969
## SRR387780 FALSE 29970735 1073178116
## SRR389077 FALSE 24966859 893978355
## SRR389078 FALSE 28190059 1009216922
## sharq_beta_tissue sharq_beta_cell_type biosample_submission_date
## <character> <character> <character>
## SRR387777 blood k562 2011-12-05T15:40:03.870
## SRR387778 blood k562 2011-12-05T15:40:03.897
## SRR387779 blood k562 2011-12-05T15:40:03.910
## SRR387780 blood k562 2011-12-05T15:40:03.923
## SRR389077 blood k562 2011-12-13T11:26:05.720
## SRR389078 blood k562 2011-12-13T11:26:05.760
## biosample_publication_date biosample_update_date avg_read_length
## <character> <character> <integer>
## SRR387777 2011-12-07T09:29:59.890 2014-08-27T04:18:20.530 36
## SRR387778 2011-12-07T09:29:59.890 2014-08-27T04:18:21.053 36
## SRR387779 2011-12-07T09:29:59.890 2014-08-27T04:18:21.800 36
## SRR387780 2011-12-07T09:29:59.890 2014-08-27T04:18:22.320 36
## SRR389077 2011-12-13T11:26:06.663 2014-08-27T04:22:14.857 36
## SRR389078 2011-12-13T11:26:06.663 2014-08-27T04:22:15.227 36
## geo_accession bigwig_file
## <character> <character>
## SRR387777 GSM836270 SRR387777.bw
## SRR387778 GSM836271 SRR387778.bw
## SRR387779 GSM836272 SRR387779.bw
## SRR387780 GSM836273 SRR387780.bw
## SRR389077 GSM847561 SRR389077.bw
## SRR389078 GSM847562 SRR389078.bw
## title
## <character>
## SRR387777 K562 cells with shRNA targeting SRF gene cultured with no doxycycline (uninduced - UI), rep1.
## SRR387778 K562 cells with shRNA targeting SRF gene cultured with doxycycline for 48 hours (48 hr), rep1.
## SRR387779 K562 cells with shRNA targeting SRF gene cultured with no doxycycline (uninduced - UI), rep2.
## SRR387780 K562 cells with shRNA targeting SRF gene cultured with doxycycline for 48 hours (48 hr), rep2.
## SRR389077 K562 cells with shRNA targeting EGR1 gene cultured with no doxycycline (uninduced - UI), rep1.
## SRR389078 K562 cells with shRNA targeting EGR1 gene cultured with doxycycline for 72 hours (72 hr), rep1.
## characteristics
## <character>
## SRR387777 c("cells: K562", "shRNA expression: no", "treatment: Puromycin")
## SRR387778 c("cells: K562", "shRNA expression: yes, targeting SRF", "treatment: Puromycin, doxycycline")
## SRR387779 c("cells: K562", "shRNA expression: no", "treatment: Puromycin")
## SRR387780 c("cells: K562", "shRNA expression: yes targeting SRF", "treatment: Puromycin, doxycycline")
## SRR389077 c("cell line: K562", "shRNA expression: no shRNA expression", "treatment: Puromycin")
## SRR389078 c("cell line: K562", "shRNA expression: expressing shRNA targeting EGR1", "treatment: Puromycin, doxycycline")
## group gene_target
## <factor> <factor>
## SRR387777 uninduced SRF
## SRR387778 induced SRF
## SRR387779 uninduced SRF
## SRR387780 induced SRF
## SRR389077 uninduced EGR1
## SRR389078 induced EGR1
Now that we have the necessary data, we can construct a DESeqDataSet
object using the function DESeqDataSetFromMatrix()
from DESeq2.
## Build a DESeqDataSet
dds_ers <- DESeqDataSetFromMatrix(countData = covMat, colData = pheno,
design = ~ gene_target + group)
## converting counts to integer mode
With the DESeqDataSet
object in place, we can then use the function DESeq()
from DESeq2 to perform the differential expression analysis (between groups) as shown below.
## Perform differential expression analysis with DESeq2 at the ER-level
dds_ers <- DESeq(dds_ers, test = 'LRT', reduced = ~ gene_target,
fitType = 'local')
## estimating size factors
## estimating dispersions
## gene-wise dispersion estimates
## mean-dispersion relationship
## final dispersion estimates
## fitting model and testing
res_ers <- results(dds_ers)
We can then visually explore the results as shown in Figure 2, like we did before in Figure 1.
## Explore results
plotMA(res_ers, main="DESeq2 results for SRP009615 (ER-level, chrY)")
We can also use regionReport to create a more extensive exploratory report.
## Create the report
report2 <- DESeq2Report(dds_ers, res = res_ers,
project = 'SRP009615 (ER-level, chrY)',
intgroup = c('group', 'gene_target'), outdir = '.',
output = 'SRP009615-results-ER-level-chrY')
This section describes the annotation used in recount
.
We used the comprehensive gene annotation for (CHR
regions) from Gencode v25 (GRCh38.p7) to get the list of genes. Specifically this GFF3 file. We then used the org.Hs.eg.db package to get the gene symbols. For each gene, we also counted the total length of exonic base pairs for that given gene and stored this information in the bp_length
column. You can see below this information for the rse_gene
object included in recount. The rownames()
are the Gencode gene_id
.
## Gene annotation information
rowRanges(rse_gene_SRP009615)
## GRanges object with 58037 ranges and 3 metadata columns:
## seqnames ranges strand |
## <Rle> <IRanges> <Rle> |
## ENSG00000000003.14 chrX 100627109-100639991 - |
## ENSG00000000005.5 chrX 100584802-100599885 + |
## ENSG00000000419.12 chr20 50934867-50958555 - |
## ENSG00000000457.13 chr1 169849631-169894267 - |
## ENSG00000000460.16 chr1 169662007-169854080 + |
## ... ... ... ... .
## ENSG00000283695.1 chr19 52865369-52865429 - |
## ENSG00000283696.1 chr1 161399409-161422424 + |
## ENSG00000283697.1 chrX 149548210-149549852 - |
## ENSG00000283698.1 chr2 112439312-112469687 - |
## ENSG00000283699.1 chr10 12653138-12653197 - |
## gene_id bp_length symbol
## <character> <integer> <CharacterList>
## ENSG00000000003.14 ENSG00000000003.14 4535 TSPAN6
## ENSG00000000005.5 ENSG00000000005.5 1610 TNMD
## ENSG00000000419.12 ENSG00000000419.12 1207 DPM1
## ENSG00000000457.13 ENSG00000000457.13 6883 SCYL3
## ENSG00000000460.16 ENSG00000000460.16 5967 C1orf112
## ... ... ... ...
## ENSG00000283695.1 ENSG00000283695.1 61 <NA>
## ENSG00000283696.1 ENSG00000283696.1 997 <NA>
## ENSG00000283697.1 ENSG00000283697.1 1184 HSFX3
## ENSG00000283698.1 ENSG00000283698.1 940 <NA>
## ENSG00000283699.1 ENSG00000283699.1 60 MIR4481
## -------
## seqinfo: 25 sequences (1 circular) from an unspecified genome; no seqlengths
## Also accessible via
rowData(rse_gene_SRP009615)
## DataFrame with 58037 rows and 3 columns
## gene_id bp_length symbol
## <character> <integer> <CharacterList>
## ENSG00000000003.14 ENSG00000000003.14 4535 TSPAN6
## ENSG00000000005.5 ENSG00000000005.5 1610 TNMD
## ENSG00000000419.12 ENSG00000000419.12 1207 DPM1
## ENSG00000000457.13 ENSG00000000457.13 6883 SCYL3
## ENSG00000000460.16 ENSG00000000460.16 5967 C1orf112
## ... ... ... ...
## ENSG00000283695.1 ENSG00000283695.1 61 NA
## ENSG00000283696.1 ENSG00000283696.1 997 NA
## ENSG00000283697.1 ENSG00000283697.1 1184 HSFX3
## ENSG00000283698.1 ENSG00000283698.1 940 NA
## ENSG00000283699.1 ENSG00000283699.1 60 MIR4481
For an rse_exon
object, the rownames()
correspond to the Gencode gene_id
. You can add a gene_id
column if you are interested in subsetting the whole rse_exon
object.
## Get the rse_exon object for study SRP009615
download_study('SRP009615', type = 'rse-exon')
## 2019-09-03 22:07:55 downloading file rse_exon.Rdata to SRP009615
load(file.path('SRP009615', 'rse_exon.Rdata'))
## Delete it if you don't need it anymore
unlink('SRP009615', recursive = TRUE)
## Annotation information
rowRanges(rse_exon)
## GRanges object with 603139 ranges and 0 metadata columns:
## seqnames ranges strand
## <Rle> <IRanges> <Rle>
## ENSG00000000003.14 chrX 100627109-100628669 -
## ENSG00000000003.14 chrX 100628670-100629986 -
## ENSG00000000003.14 chrX 100630759-100630866 -
## ENSG00000000003.14 chrX 100632063-100632068 -
## ENSG00000000003.14 chrX 100632485-100632540 -
## ... ... ... ...
## ENSG00000283698.1 chr2 112440396-112440601 -
## ENSG00000283698.1 chr2 112440602-112440611 -
## ENSG00000283698.1 chr2 112463991-112464036 -
## ENSG00000283698.1 chr2 112469548-112469687 -
## ENSG00000283699.1 chr10 12653138-12653197 -
## -------
## seqinfo: 25 sequences (1 circular) from an unspecified genome; no seqlengths
## Add a gene_id column
rowRanges(rse_exon)$gene_id <- rownames(rse_exon)
## Example subset
rse_exon_subset <- subset(rse_exon, subset = gene_id == 'ENSG00000000003.14')
rowRanges(rse_exon_subset)
## GRanges object with 17 ranges and 1 metadata column:
## seqnames ranges strand |
## <Rle> <IRanges> <Rle> |
## ENSG00000000003.14 chrX 100627109-100628669 - |
## ENSG00000000003.14 chrX 100628670-100629986 - |
## ENSG00000000003.14 chrX 100630759-100630866 - |
## ENSG00000000003.14 chrX 100632063-100632068 - |
## ENSG00000000003.14 chrX 100632485-100632540 - |
## ... ... ... ... .
## ENSG00000000003.14 chrX 100636608-100636689 - |
## ENSG00000000003.14 chrX 100636690-100636792 - |
## ENSG00000000003.14 chrX 100636793-100636806 - |
## ENSG00000000003.14 chrX 100636807-100637104 - |
## ENSG00000000003.14 chrX 100639945-100639991 - |
## gene_id
## <character>
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## ... ...
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## ENSG00000000003.14 ENSG00000000003.14
## -------
## seqinfo: 25 sequences (1 circular) from an unspecified genome; no seqlengths
The exons in a rse_exon
object are those that have a Gencode gene_id
and that were disjointed as described in the GenomicRanges package:
?`inter-range-methods`
You can reproduce the gene and exon information using the function reproduce_ranges()
.
If you are interested in using another annotation based on hg38 coordinates you can do so using the function coverage_matrix()
or by running bwtool thanks to the BigWig files in recount
, in which case recount.bwtool will be helpful.
If you are re-processing a small set of samples, it simply might be easier to use coverage_matrix()
as shown below using the annotation information provided by the EnsDb.Hsapiens.v79 package.
## Get the disjoint exons based on EnsDb.Hsapiens.v79 which matches hg38
exons <- reproduce_ranges('exon', db = 'EnsDb.Hsapiens.v79')
## Change the chromosome names to match those used in the BigWig files
library('GenomeInfoDb')
seqlevelsStyle(exons) <- 'UCSC'
## Get the count matrix at the exon level for chrY
exons_chrY <- keepSeqlevels(exons, 'chrY', pruning.mode = 'coarse')
exonRSE <- coverage_matrix('SRP009615', 'chrY', unlist(exons_chrY),
chunksize = 3000)
## 2019-09-03 22:08:29 railMatrix: processing regions 1 to 2562
## 2019-09-03 22:08:29 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387777.bw
## 2019-09-03 22:08:31 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387778.bw
## 2019-09-03 22:08:32 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387779.bw
## 2019-09-03 22:08:34 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR387780.bw
## 2019-09-03 22:08:35 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389077.bw
## 2019-09-03 22:08:37 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389078.bw
## 2019-09-03 22:08:38 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389079.bw
## 2019-09-03 22:08:40 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389080.bw
## 2019-09-03 22:08:41 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389081.bw
## 2019-09-03 22:08:43 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389082.bw
## 2019-09-03 22:08:44 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389083.bw
## 2019-09-03 22:08:46 railMatrix: processing file http://duffel.rail.bio/recount/SRP009615/bw/SRR389084.bw
exonMatrix <- assays(exonRSE)$counts
dim(exonMatrix)
## [1] 2562 12
head(exonMatrix)
## SRR387777 SRR387778 SRR387779 SRR387780 SRR389077 SRR389078 SRR389079
## 1 0 0 0 0 0 0 0.0000000
## 2 0 0 0 0 0 0 0.0000000
## 3 0 0 0 0 0 0 0.0000000
## 4 0 0 0 0 0 0 0.0000000
## 5 0 0 0 0 0 0 0.0000000
## 6 0 0 0 0 0 0 0.3256991
## SRR389080 SRR389081 SRR389082 SRR389083 SRR389084
## 1 0.0000000 0 0 0 0
## 2 0.0000000 0 0 0 0
## 3 0.0000000 0 0 0 0
## 4 0.0000000 0 0 0 0
## 5 0.6875641 0 0 0 0
## 6 0.0000000 0 0 0 0
## Summary the information at the gene level for chrY
exon_gene <- rep(names(exons_chrY), elementNROWS(exons_chrY))
geneMatrix <- do.call(rbind, lapply(split(as.data.frame(exonMatrix),
exon_gene), colSums))
dim(geneMatrix)
## [1] 544 12
head(geneMatrix)
## SRR387777 SRR387778 SRR387779 SRR387780 SRR389077
## ENSG00000012817 9.791214 17.655826 17.8671773 6.7090447 4.832332
## ENSG00000067048 77.902314 69.981889 41.6900803 83.0430650 52.797699
## ENSG00000067646 44.371293 52.123510 22.6257722 57.2505152 44.251631
## ENSG00000092377 10.568294 9.722520 13.8867173 16.0271624 11.364928
## ENSG00000099715 3.613424 1.789214 0.6284937 2.6836179 2.997835
## ENSG00000099721 0.000000 0.000000 0.0000000 0.7827219 1.342314
## SRR389078 SRR389079 SRR389080 SRR389081 SRR389082
## ENSG00000012817 2.893332 12.7255290 8.1132560 16.988920 28.049724
## ENSG00000067048 52.000713 52.3677621 53.9737791 80.441512 106.485062
## ENSG00000067646 44.232314 31.5928125 56.0708495 38.480927 45.905450
## ENSG00000092377 1.426849 17.0061457 24.2022551 33.773154 9.349908
## ENSG00000099715 0.000000 0.8375120 0.0000000 1.023429 2.337477
## ENSG00000099721 0.000000 0.4652844 0.7563205 0.000000 0.000000
## SRR389083 SRR389084
## ENSG00000012817 8.830204 9.139425
## ENSG00000067048 65.978494 34.679041
## ENSG00000067646 35.469641 28.992288
## ENSG00000092377 3.571768 16.450965
## ENSG00000099715 0.000000 0.000000
## ENSG00000099721 0.000000 0.000000
The above solution works well for a small set of samples. However, bwtool
is faster for processing large sets. You can see how we used bwtool
at leekgroup/recount-website. It’s much faster than R and the small package recount.bwtool will be helpful for such scenarios. Note that you will need to run scale_counts()
after using coverage_matrix_bwtool()
and that will have to download the BigWig files first unless you are working at JHPCE or SciServer. coverage_matrix_bwtool()
will download the files for you, but that till take time.
Finally, the BigWig files hosted by recount have the following chromosome names and sizes as specified in hg38.sizes. You’ll have to make sure that you match these names when using alternative annotations.
If you are interested in finding possible gene fusion events in a particular study, you can download the RangedSummarizedExperiment object at the exon-exon junctions level for that study. The objects we provide classify exon-exon junction events as shown below.
library('recount')
## Download and load RSE object for SRP009615 study
download_study('SRP009615', type = 'rse-jx')
## 2019-09-03 22:08:48 downloading file rse_jx.Rdata to SRP009615
load(file.path('SRP009615', 'rse_jx.Rdata'))
## Delete it if you don't need it anymore
unlink('SRP009615', recursive = TRUE)
## Exon-exon junctions by class
table(rowRanges(rse_jx)$class)
##
## alternative_end annotated exon_skip fusion
## 35601 140251 9513 489
## novel
## 26475
## Potential gene fusions by chromosome
fusions <- rowRanges(rse_jx)[rowRanges(rse_jx)$class == 'fusion']
fusions_by_chr <- sort(table(seqnames(fusions)), decreasing = TRUE)
fusions_by_chr[fusions_by_chr > 0]
##
## chr1 chr19 chr6 chr12 chr22 chr17 chr5 chr16 chr11 chr3 chr10 chr2
## 61 54 37 31 27 26 26 24 22 22 21 20
## chr7 chrX chr14 chr4 chr9 chr8 chr15 chr20 chr13 chr21 chr18
## 20 16 13 13 12 10 9 9 6 6 4
## Genes with the most fusions
head(sort(table(unlist(fusions$symbol_proposed)), decreasing = TRUE))
##
## TMEM14B SYCP2L LOC100129924 MATR3 ACSM3
## 6 5 4 4 3
## BMI1
## 3
If you are interested in checking the frequency of a particular exon-exon junction then check the snaptron_query()
function described in the following section.
Our collaborators built SnaptronUI to query the Intropolis database of the exon-exon junctions found in SRA. SnaptronUI allows you to do several types of queries manually and perform analyses. recount has the function snaptron_query()
which uses Snaptron to check if particular exon-exon junctions are present in Intropolis. For example, here we use snaptron_query()
to get in R
-friendly format the information for 3 exon-exon junctions using Intropolis version 1 which uses hg19 coordinates. Version 2 uses hg38 coordinates and the exon-exon junctions were derived from a larger data set: about 50,000 samples vs 21,000 in version 1. snaptron_query()
can also be used to access the 30 million and 36 million exon-exon junctions derived from the GTEx and TCGA consortiums respectively (about 10 and 11 thousand samples respectively).
library('GenomicRanges')
junctions <- GRanges(seqnames = 'chr2', IRanges(
start = c(28971711, 29555082, 29754983),
end = c(29462418, 29923339, 29917715)))
snaptron_query(junctions)
## 2019-09-03 22:08:50 querying Snaptron
## 2019-09-03 22:08:51 processing results
## 2019-09-03 22:08:51 extracting information
## GRanges object with 3 ranges and 14 metadata columns:
## seqnames ranges strand | type snaptron_id
## <Rle> <IRanges> <Rle> | <factor> <integer>
## [1] chr2 28971711-29462418 - | SRAv1:I 22314441
## [2] chr2 29555082-29923339 + | SRAv1:I 22328842
## [3] chr2 29754983-29917715 - | SRAv1:I 22329293
## annotated left_motif right_motif left_annotated
## <CharacterList> <character> <character> <CharacterList>
## [1] <NA> AT AC NA
## [2] <NA> GC AG NA
## [3] 1 GT AG aC19,cG19,cG38,...
## right_annotated samples read_coverage_by_sample
## <CharacterList> <IntegerList> <IntegerList>
## [1] NA 3481 1
## [2] NA 2643,4867,4945,... 1,1,1,...
## [3] aC19,cG19,cG38,... 3,5,13,... 1,1,1,...
## samples_count coverage_sum coverage_avg coverage_median
## <integer> <integer> <numeric> <numeric>
## [1] 1 1 1 1
## [2] 13 13 1 1
## [3] 1625 5380 3.311 1
## source_dataset_id
## <integer>
## [1] 0
## [2] 0
## [3] 0
## -------
## seqinfo: 1 sequence from an unspecified genome; no seqlengths
If you use snaptron_query()
please cite snaptron.cs.jhu.edu. Snaptron is separate from recount. Thank you!
Thanks to Imada, Sanchez, et al., bioRxiv, 2019 you can now use the recount
package to access the FANTOM-CAT annotation that was merged with recount2
. You can use the main recount2
website or the recount::download_study()
function by specifying type = 'rse-fc'
. See their manuscript for further details on how this annotation was derived.
## Example use of download_study()
## for downloading the FANTOM-CAT `rse_fc`
## file for a given study
download_study('DRP000366', type = 'rse-fc', download = FALSE)
recount-brain
The recount-brain
project by Ramzara et al., bioRxiv, 2019 contains curated metadata for brain studies present in recount2
that you can access via recount::add_metadata(source = 'recount_brain_v2')
. The manuscript by Razmara et al describes a curation process that can be used for curating other tissues or projects. If you are interested in doing such a project and/or contributing curated metadata to the recount
package via the add_metadata()
function please let us know.
## recount-brain citation details
citation('recount')[5]
##
## Frazee AC, Langmead B, Leek JT (2011). "ReCount: A multi-experiment
## resource of analysis-ready RNA-seq gene count datasets." _BMC
## Bioinformatics_. doi: 10.1186/1471-2105-12-449 (URL:
## https://doi.org/10.1186/1471-2105-12-449), <URL:
## https://doi.org/10.1186/1471-2105-12-449>.
##
## A BibTeX entry for LaTeX users is
##
## @Article{,
## title = {ReCount: A multi-experiment resource of analysis-ready RNA-seq gene count datasets},
## author = {Alyssa C. Frazee and Ben Langmead and Jeffrey T. Leek},
## year = {2011},
## journal = {BMC Bioinformatics},
## doi = {10.1186/1471-2105-12-449},
## url = {https://doi.org/10.1186/1471-2105-12-449},
## }
If you are interested in downloading all the data you can do so using the recount_url
data.frame included in the package. That is:
## Get data.frame with all the URLs
library('recount')
dim(recount_url)
## [1] 97229 6
## Explore URLs
head(recount_url$url)
## [1] "http://duffel.rail.bio/recount/v2/DRP000366/counts_exon.tsv.gz"
## [2] "http://duffel.rail.bio/recount/v2/DRP000366/counts_gene.tsv.gz"
## [3] "http://duffel.rail.bio/recount/v2/DRP000366/rse_exon.Rdata"
## [4] "http://duffel.rail.bio/recount/v2/DRP000366/rse_gene.Rdata"
## [5] "http://duffel.rail.bio/recount/DRP000366/counts_jx.tsv.gz"
## [6] "http://duffel.rail.bio/recount/DRP000366/rse_jx.Rdata"
You can then download all the data using the download_study()
function or however you prefer to do so with recount_url
.
## Download all files (will take a while! It's over 8 TB of data)
sapply(unique(recount_url$project), download_study, type = 'all')
You can find the code for the website at leekgroup/recount-website if you want to deploy your own local mirror. Please let us know if you choose to do deploy a mirror.
Not everyone has over 8 terabytes of disk space available to download all the data from the recount
project. However, thanks to SciServer you can access it locally via a Jupyter Notebook. If you do so and want to share your work, please let the SciServer maintainers know via Twitter at IDIESJHU.
To use SciServer, you first have to go to http://www.sciserver.org/ then click on “Login to SciServer”. If you are a first time user, click on “Register New Account” and enter the information they request as shown on Figure 3.
Once you’ve registered, open the SciServer compute tool (see Figure 4).
Then click on “Create container”, choose a name of your preference and make sure that you choose to load R 3.3.x and the recount
public volume (see Figure 5). This will enable you to access all of the recount
data as if it was on your computer. Click “Create” once you are ready.
Once you have a container, create a new R Notebook as shown in Figure 6.
In this R Notebook you can insert new code cells where you can type R code. For example, you can install recount and DESeq2 to run the code example from this vignette. You first have to install the packages as shown in Figure 7.
Then, the main part when using SciServer is to use to remember that all the recount
data is available locally. So instead of using download_study()
, you can simply use load()
with the correct path as shown in Figure 8.
Several functions in the recount package have the outdir
argument, which you can specify to use the data locally. Try using expressed_regions()
in SciServer to get started with the following code:
## Expressed-regions SciServer example
regions <- expressed_regions('SRP009615', 'chrY', cutoff = 5L,
maxClusterGap = 3000L, outdir = file.path(scipath, 'SRP009615'))
regions
You can find the R code for a full SciServer demo here. You can copy and paste it into a cell and run it all to see how SciServer compute works.
If you encounter problems when using SciServer please check their support page and the SciServer compute help section.
If you use SciServer for your published work, please cite it accordingly. SciServer is administered by the Institute for Data Intensive Engineering and Science at Johns Hopkins University and is funded by National Science Foundation award ACI-1261715.
The recount package (Collado-Torres, Nellore, Kammers, Ellis, et al., 2017) was made possible thanks to:
Code for creating the vignette
## Create the vignette
library('rmarkdown')
system.time(render('recount-quickstart.Rmd', 'BiocStyle::html_document'))
## Extract the R code
library('knitr')
knit('recount-quickstart.Rmd', tangle = TRUE)
## Clean up
file.remove('quickstartRef.bib')
## [1] TRUE
Date the vignette was generated.
## [1] "2019-09-03 22:08:53 EDT"
Wallclock time spent generating the vignette.
## Time difference of 3.498 mins
R
session information.
## ─ Session info ───────────────────────────────────────────────────────────────────────────────────────────────────────
## setting value
## version R version 3.6.1 (2019-07-05)
## os Ubuntu 18.04.3 LTS
## system x86_64, linux-gnu
## ui X11
## language (EN)
## collate C
## ctype en_US.UTF-8
## tz America/New_York
## date 2019-09-03
##
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This vignette was generated using BiocStyle (Oleś, Morgan, and Huber, 2019) with knitr (Xie, 2014) and rmarkdown running behind the scenes.
Citations made with knitcitations (Boettiger, 2017).
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