systemPipeR 2.2.0
Ribo-Seq and polyRibo-Seq are a specific form of RNA-Seq gene expression experiments utilizing mRNA subpopulations directly bound to ribosomes. Compared to standard RNA-Seq, their readout of gene expression provides a better approximation of downstream protein abundance profiles due to their close association with translational processes. The most important difference among the two is that polyRibo-Seq utilizes polyribosomal RNA for sequencing, whereas Ribo-Seq is a footprinting approach restricted to sequencing RNA fragments protected by ribosomes (Ingolia et al. 2009; Aspden et al. 2014; Juntawong et al. 2015).
The workflow presented in this vignette contains most of the data analysis steps described by (Juntawong et al. 2014) including functionalities useful for processing both polyRibo-Seq and Ribo-Seq experiments. To improve re-usability and adapt to recent changes of software versions (e.g. R, Bioconductor and short read aligners), the code has been optimized accordingly. Thus, the results obtained with the updated workflow are expected to be similar but not necessarily identical with the published results described in the original paper.
Relevant analysis steps of this workflow include read preprocessing, read
alignments against a reference genome, counting of reads overlapping with a
wide range of genomic features (e.g. CDSs, UTRs, uORFs, rRNAs, etc.),
differential gene expression and differential ribosome binding analyses, as
well as a variety of genome-wide summary plots for visualizing RNA expression
trends. Functions are provided for evaluating the quality of Ribo-seq data,
for identifying novel expressed regions in the genomes, and for gaining
insights into gene regulation at the post-transcriptional and translational
levels. For example, the functions genFeatures
and
featuretypeCounts
can be used to quantify the expression output for
all feature types included in a genome annotation (e.g.
genes,
introns, exons, miRNAs, intergenic regions, etc.). To determine the approximate
read length of ribosome footprints in Ribo-Seq experiments, these feature type
counts can be obtained and plotted for specific read lengths separately.
Typically, the most abundant read length obtained for translated features
corresponds to the approximate footprint length occupied by the ribosomes of a
given organism group. Based on the results from several Ribo-Seq studies, these
ribosome footprints are typically ~30 nucleotides long
(Ingolia, Lareau, and Weissman 2011; Ingolia et al. 2009; Juntawong et al. 2014). However, their
length can vary by several nucleotides depending upon the optimization of the
RNA digestion step and various factors associated with translational
regulation. For quality control purposes of Ribo-Seq experiments it is also
useful to monitor the abundance of reads mapping to rRNA genes due to the high
rRNA content of ribosomes. This information can be generated with the
featuretypeCounts
function described above.
Coverage trends along transcripts summarized for any number of transcripts can
be obtained and plotted with the functions featureCoverage
and
plotfeatureCoverage
, respectively. Their results allow monitoring
of the phasing of ribosome movements along triplets of coding sequences.
Commonly, high quality data will display here for the first nucleotide of each
codon the highest depth of coverage computed for the 5’ ends of the aligned
reads.
Ribo-seq data can also be used to evaluate various aspects of translational
control due to ribosome occupancy in upstream open reading frames (uORFs). The
latter are frequently present in (or near) 5’ UTRs of transcripts. For this,
the function predORFs
can be used to identify ORFs in the
nucleotide sequences of transcripts or their subcomponents such as UTR regions.
After scaling the resulting ORF coordinates back to the corresponding genome
locations using scaleRanges
, one can use these novel features
(e.g. uORFs) for expression analysis routines similar to those
employed for pre-existing annotations, such as the exonic regions of genes. For
instance, in Ribo-Seq experiments one can use this approach to systematically identify all transcripts occupied by ribosomes in their uORF regions. The binding of
ribosomes to uORF regions may indicate a regulatory role in the translation of
the downstream main ORFs and/or translation of the uORFs into functionally
relevant peptides.
Typically, users want to specify here all information relevant for the analysis of their NGS study. This includes detailed descriptions of FASTQ files, experimental design, reference genome, gene annotations, etc.
The systemPipeR
package needs to be loaded to perform the analysis
steps shown in this report (H Backman and Girke 2016). The package allows users
to run the entire analysis workflow interactively or with a single command
while also generating the corresponding analysis report. For details
see systemPipeR's
main vignette.
library(systemPipeR)
systemPipeRdata package is a helper package to generate a fully populated systemPipeR workflow environment in the current working directory with a single command. All the instruction for generating the workflow template are provide in the systemPipeRdata vignette here.
systemPipeRdata::genWorkenvir(workflow = "riboseq", mydirname = "riboseq")
setwd("riboseq")
After building and loading the workflow environment generated by genWorkenvir
from systemPipeRdata all data inputs are stored in
a data/
directory and all analysis results will be written to a separate
results/
directory, while the systemPipeRIBOseq.Rmd
script and the targets
file are expected to be located in the parent directory. The R session is expected to run from this parent
directory. Additional parameter files are stored under param/
.
To work with real data, users want to organize their own data similarly
and substitute all test data for their own data. To rerun an established
workflow on new data, the initial targets
file along with the corresponding
FASTQ files are usually the only inputs the user needs to provide. Please check
the initial targets
file details below.
For more details, please consult the documentation
here. More information about the targets
files from systemPipeR can be found here.
targets
fileThe targets
file defines all FASTQ files and sample comparisons of the analysis workflow.
targetspath <- system.file("extdata", "targetsPE.txt", package = "systemPipeR")
targets <- read.delim(targetspath, comment.char = "#")[, 1:4]
targets
## FileName1 FileName2
## 1 ./data/SRR446027_1.fastq.gz ./data/SRR446027_2.fastq.gz
## 2 ./data/SRR446028_1.fastq.gz ./data/SRR446028_2.fastq.gz
## 3 ./data/SRR446029_1.fastq.gz ./data/SRR446029_2.fastq.gz
## 4 ./data/SRR446030_1.fastq.gz ./data/SRR446030_2.fastq.gz
## 5 ./data/SRR446031_1.fastq.gz ./data/SRR446031_2.fastq.gz
## 6 ./data/SRR446032_1.fastq.gz ./data/SRR446032_2.fastq.gz
## 7 ./data/SRR446033_1.fastq.gz ./data/SRR446033_2.fastq.gz
## 8 ./data/SRR446034_1.fastq.gz ./data/SRR446034_2.fastq.gz
## 9 ./data/SRR446035_1.fastq.gz ./data/SRR446035_2.fastq.gz
## 10 ./data/SRR446036_1.fastq.gz ./data/SRR446036_2.fastq.gz
## 11 ./data/SRR446037_1.fastq.gz ./data/SRR446037_2.fastq.gz
## 12 ./data/SRR446038_1.fastq.gz ./data/SRR446038_2.fastq.gz
## 13 ./data/SRR446039_1.fastq.gz ./data/SRR446039_2.fastq.gz
## 14 ./data/SRR446040_1.fastq.gz ./data/SRR446040_2.fastq.gz
## 15 ./data/SRR446041_1.fastq.gz ./data/SRR446041_2.fastq.gz
## 16 ./data/SRR446042_1.fastq.gz ./data/SRR446042_2.fastq.gz
## 17 ./data/SRR446043_1.fastq.gz ./data/SRR446043_2.fastq.gz
## 18 ./data/SRR446044_1.fastq.gz ./data/SRR446044_2.fastq.gz
## SampleName Factor
## 1 M1A M1
## 2 M1B M1
## 3 A1A A1
## 4 A1B A1
## 5 V1A V1
## 6 V1B V1
## 7 M6A M6
## 8 M6B M6
## 9 A6A A6
## 10 A6B A6
## 11 V6A V6
## 12 V6B V6
## 13 M12A M12
## 14 M12B M12
## 15 A12A A12
## 16 A12B A12
## 17 V12A V12
## 18 V12B V12
systemPipeR
workflows can be designed and built from start to finish with a
single command, importing from an R Markdown file or stepwise in interactive
mode from the R console.
This tutorial will demonstrate how to build the workflow in an interactive mode,
appending each step. The workflow is constructed by connecting each step via
appendStep
method. Each SYSargsList
instance contains instructions needed
for processing a set of input files with a specific command-line or R software
and the paths to the corresponding outfiles generated by a particular tool/step.
To create a Workflow within systemPipeR
, we can start by defining an empty
container and checking the directory structure:
library(systemPipeR)
sal <- SPRproject()
sal
The systemPipeR
package needs to be loaded (H Backman and Girke 2016).
appendStep(sal) <- LineWise(code = {
library(systemPipeR)
library(rtracklayer)
library(GenomicFeatures)
library(ggplot2)
library(grid)
library(BiocParallel)
library(DESeq2, quietly = TRUE)
library(ape, warn.conflicts = FALSE)
library(edgeR)
library(biomaRt)
library(BBmisc) # Defines suppressAll()
library(pheatmap)
library(BiocParallel)
}, step_name = "load_SPR")
preprocessReads
functionThe function preprocessReads
allows to apply predefined or custom
read preprocessing functions to all FASTQ files referenced in a
SYSargsList
container, such as quality filtering or adapter trimming
routines. Internally, preprocessReads
uses the FastqStreamer
function from
the ShortRead
package to stream through large FASTQ files in a
memory-efficient manner.
Here, we are appending a new step to the SYSargsList
object created previously.
All the parameters are defined on the preprocessReads/preprocessReads-pe_riboseq.yml
file.
appendStep(sal) <- SYSargsList(step_name = "preprocessing", targets = "targetsPE.txt",
dir = TRUE, wf_file = "preprocessReads/preprocessReads-pe.cwl",
input_file = "preprocessReads/preprocessReads-pe_riboseq.yml",
dir_path = system.file("extdata/cwl", package = "systemPipeR"),
inputvars = c(FileName1 = "_FASTQ_PATH1_", FileName2 = "_FASTQ_PATH2_",
SampleName = "_SampleName_"), dependency = c("load_SPR"))
The function trimbatch
used trims adapters hierarchically from the longest to
the shortest match of the right end of the reads. If internalmatch=TRUE
then
internal matches will trigger the same behavior. The argument minpatternlength
defines the shortest adapter match to consider in this iterative process. In
addition, the function removes reads containing Ns or homopolymer regions.
More detailed information on read preprocessing is provided in systemPipeR's
main vignette.
yamlinput(sal, step = "preprocessing")$Fct
# [1] ''trimbatch(fq, pattern=\'ACACGTCT\',
# internalmatch=FALSE, minpatternlength=6, Nnumber=1,
# polyhomo=50, minreadlength=16, maxreadlength=101)''
cmdlist(sal, step = "preprocessing", targets = 1)
The following seeFastq
and seeFastqPlot
functions generate and plot a series of useful
quality statistics for a set of FASTQ files, including per cycle quality box
plots, base proportions, base-level quality trends, relative k-mer
diversity, length, and occurrence distribution of reads, number of reads
above quality cutoffs and mean quality distribution. The results are
written to a PDF file named fastqReport.pdf
.
This is the pre-trimming fastq report. Another post-trimming fastq report step is not included in the default. It is recommended to run this step first to decide whether the trimming is needed.
Please note that initial targets files are being used here. In this case,
we used the getColumn
function to extract a named vector.
appendStep(sal) <- LineWise(code = {
fq_files <- getColumn(sal, "preprocessing", "targetsWF",
column = 1)
fqlist <- seeFastq(fastq = fq_files, batchsize = 10000, klength = 8)
pdf("./results/fastqReport.pdf", height = 18, width = 4 *
length(fqlist))
seeFastqPlot(fqlist)
dev.off()
}, step_name = "fastq_report", dependency = "preprocessing")
HISAT2
The following steps will demonstrate how to use the short read aligner Hisat2
(Kim, Langmead, and Salzberg 2015). First, the Hisat2
index needs to be created.
appendStep(sal) <- SYSargsList(step_name = "hisat2_index", dir = FALSE,
targets = NULL, wf_file = "hisat2/hisat2-index.cwl", input_file = "hisat2/hisat2-index.yml",
dir_path = "param/cwl", dependency = "load_SPR")
HISAT2
mappingThe parameter settings of the aligner are defined in the workflow_hisat2-pe.cwl
and workflow_hisat2-pe.yml
files. The following shows how to construct the
corresponding SYSargsList object.
appendStep(sal) <- SYSargsList(step_name = "hisat2_mapping",
dir = TRUE, targets = "targetsPE.txt", wf_file = "workflow-hisat2/workflow_hisat2-pe.cwl",
input_file = "workflow-hisat2/workflow_hisat2-pe.yml", dir_path = "param/cwl",
inputvars = c(FileName1 = "_FASTQ_PATH1_", FileName2 = "_FASTQ_PATH2_",
SampleName = "_SampleName_"), dependency = c("hisat2_index"))
To double-check the command line for each sample, please use the following:
cmdlist(sal, step = "hisat2_mapping", targets = 1)
The following provides an overview of the number of reads in each sample and how many of them aligned to the reference.
appendStep(sal) <- LineWise(code = {
fqpaths <- getColumn(sal, step = "hisat2_mapping", "targetsWF",
column = "FileName1")
bampaths <- getColumn(sal, step = "hisat2_mapping", "outfiles",
column = "samtools_sort_bam")
read_statsDF <- alignStats(args = bampaths, fqpaths = fqpaths,
pairEnd = TRUE)
write.table(read_statsDF, "results/alignStats.xls", row.names = FALSE,
quote = FALSE, sep = "\t")
}, step_name = "align_stats", dependency = "hisat2_mapping")
The symLink2bam
function creates symbolic links to view the BAM alignment files in a
genome browser such as IGV without moving these large files to a local
system. The corresponding URLs are written to a file with a path
specified under urlfile
, here IGVurl.txt
.
Please replace the directory and the user name.
appendStep(sal) <- LineWise(code = {
bampaths <- getColumn(sal, step = "hisat2_mapping", "outfiles",
column = "samtools_sort_bam")
symLink2bam(sysargs = bampaths, htmldir = c("~/.html/", "somedir/"),
urlbase = "http://cluster.hpcc.ucr.edu/~tgirke/", urlfile = "./results/IGVurl.txt")
}, step_name = "bam_IGV", dependency = "hisat2_mapping", run_step = "optional")
The genFeatures
function generates a variety of feature types from
TxDb
objects using utilities provided by the GenomicFeatures
package.
The first step is the generation of the feature type ranges based on
annotations provided by a GFF file that can be transformed into a
TxDb
object. This includes ranges for mRNAs, exons, introns, UTRs,
CDSs, miRNAs, rRNAs, tRNAs, promoter and intergenic regions. In addition, any
number of custom annotations can be included in this routine.
appendStep(sal) <- LineWise(code = {
txdb <- suppressWarnings(makeTxDbFromGFF(file = "data/tair10.gff",
format = "gff3", dataSource = "TAIR", organism = "Arabidopsis thaliana"))
feat <- genFeatures(txdb, featuretype = "all", reduce_ranges = TRUE,
upstream = 1000, downstream = 0, verbose = TRUE)
}, step_name = "genFeatures", dependency = "hisat2_mapping",
run_step = "mandatory")
The featuretypeCounts
function counts how many reads in short read
alignment files (BAM format) overlap with entire annotation categories. This
utility is useful for analyzing the distribution of the read mappings across
feature types, e.g. coding versus non-coding genes. By default the
read counts are reported for the sense and antisense strand of each feature
type separately. To minimize memory consumption, the BAM files are processed in
a stream using utilities from the Rsamtools
and GenomicAlignment
packages.
The counts can be reported for each read length separately or as a single value
for reads of any length. Subsequently, the counting results can be plotted with
the associated plotfeaturetypeCounts
function.
The following generates and plots feature counts for any read length.
appendStep(sal) <- LineWise(code = {
outpaths <- getColumn(sal, step = "hisat2_mapping", "outfiles",
column = "samtools_sort_bam")
fc <- featuretypeCounts(bfl = BamFileList(outpaths, yieldSize = 50000),
grl = feat, singleEnd = FALSE, readlength = NULL, type = "data.frame")
p <- plotfeaturetypeCounts(x = fc, graphicsfile = "results/featureCounts.png",
graphicsformat = "png", scales = "fixed", anyreadlength = TRUE,
scale_length_val = NULL)
}, step_name = "featuretypeCounts", dependency = "genFeatures",
run_step = "mandatory")
To determine the approximate read length of ribosome footprints in Ribo-Seq experiments, one can generate and plot the feature counts for specific read lengths separately. Typically, the most abundant read length obtained for translated features corresponds to the approximate footprint length occupied by the ribosomes.
appendStep(sal) <- LineWise(code = {
fc2 <- featuretypeCounts(bfl = BamFileList(outpaths, yieldSize = 50000),
grl = feat, singleEnd = TRUE, readlength = c(74:76, 99:102),
type = "data.frame")
p2 <- plotfeaturetypeCounts(x = fc2, graphicsfile = "results/featureCounts2.png",
graphicsformat = "png", scales = "fixed", anyreadlength = FALSE,
scale_length_val = NULL)
}, step_name = "featuretypeCounts_length", dependency = "featuretypeCounts",
run_step = "mandatory")
The function predORF
can be used to identify open reading frames (ORFs) and
coding sequences (CDSs) in DNA sequences provided as DNAString
or DNAStringSet
objects. The setting mode='ORF'
returns continuous reading frames that begin
with a start codon and end with a stop codon, while mode='CDS'
returns continuous
reading frames that do not need to begin or end with start or stop codons,
respectively. Non-canonical start and stop condons are supported by allowing
the user to provide any custom set of triplets under the startcodon
and
stopcodon
arguments (i.e.
non-ATG start codons). The argument n
defines
the maximum number of ORFs to return for each input sequence (e.g. n=1
returns only the longest ORF). It also supports the identification of overlapping
and nested ORFs. Alternatively, one can return all non-overlapping ORFs including
the longest ORF for each input sequence with n="all"
and longest_disjoint=TRUE
.
appendStep(sal) <- LineWise(code = {
txdb <- suppressWarnings(makeTxDbFromGFF(file = "data/tair10.gff",
format = "gff3", organism = "Arabidopsis"))
futr <- fiveUTRsByTranscript(txdb, use.names = TRUE)
dna <- extractTranscriptSeqs(FaFile("data/tair10.fasta"),
futr)
uorf <- predORF(dna, n = "all", mode = "orf", longest_disjoint = TRUE,
strand = "sense")
}, step_name = "pred_ORF", dependency = "featuretypeCounts_length")
To use the predicted ORF ranges for expression analysis given genome alignments
as input, it is necessary to scale them to the corresponding genome
coordinates. The function scaleRanges
does this by transforming the
mappings of spliced features (query ranges) to their corresponding genome
coordinates (subject ranges). The method accounts for introns in the subject
ranges that are absent in the query ranges. The above uORFs predicted in the
provided 5’ UTRs sequences using predORF
are a typical use case
for this application. These query ranges are given relative to the 5’ UTR
sequences and scaleRanges
will convert them to the corresponding
genome coordinates. The resulting GRangesList
object (here grl_scaled
)
can be directly used for read counting.
appendStep(sal) <- LineWise(code = {
grl_scaled <- scaleRanges(subject = futr, query = uorf, type = "uORF",
verbose = TRUE)
export.gff3(unlist(grl_scaled), "results/uorf.gff")
}, step_name = "scale_ranges", dependency = "pred_ORF")
To confirm the correctness of the obtained uORF ranges, one can parse their
corresponding DNA sequences from the reference genome with the getSeq
function and then translate them with the translate
function into
proteins. Typically, the returned protein sequences should start with a
M
(corresponding to start codon) and end with *
(corresponding to stop codon).
The following example does this for a single uORF containing three exons.
appendStep(sal) <- LineWise(code = {
translate(unlist(getSeq(FaFile("data/tair10.fasta"), grl_scaled[[7]])))
}, step_name = "translate", dependency = "scale_ranges")
If required custom feature ranges can be added to the standard features generated
with the genFeatures
function above. The following does this for the uORF ranges
predicted with predORF
.
appendStep(sal) <- LineWise(code = {
feat <- genFeatures(txdb, featuretype = "all", reduce_ranges = FALSE)
feat <- c(feat, GRangesList(uORF = unlist(grl_scaled)))
}, step_name = "add_features", dependency = c("genFeatures",
"scale_ranges"))
The following identifies continuous ORFs in intergenic regions. Note,
predORF
can only identify continuous ORFs in query sequences. The
function does not identify and remove introns prior to the ORF prediction.
appendStep(sal) <- LineWise(code = {
feat <- genFeatures(txdb, featuretype = "intergenic", reduce_ranges = TRUE)
intergenic <- feat$intergenic
strand(intergenic) <- "+"
dna <- getSeq(FaFile("data/tair10.fasta"), intergenic)
names(dna) <- mcols(intergenic)$feature_by
sorf <- suppressWarnings(predORF(dna, n = "all", mode = "orf",
longest_disjoint = TRUE, strand = "both"))
sorf <- sorf[width(sorf) > 60] # Remove sORFs below length cutoff, here 60bp
intergenic <- split(intergenic, mcols(intergenic)$feature_by)
grl_scaled_intergenic <- scaleRanges(subject = intergenic,
query = sorf, type = "sORF", verbose = TRUE)
export.gff3(unlist(grl_scaled_intergenic), "sorf.gff")
translate(getSeq(FaFile("data/tair10.fasta"), unlist(grl_scaled_intergenic)))
}, step_name = "pred_sORFs", dependency = c("add_features"))
The featureCoverage
function computes the read coverage along
single and multi component features based on genomic alignments. The coverage
segments of component features are spliced to continuous ranges, such as exons
to transcripts or CDSs to ORFs. The results can be obtained with single
nucleotide resolution (e.g. around start and stop codons) or as mean coverage
of relative bin sizes, such as 100 bins for each feature. The latter allows
comparisons of coverage trends among transcripts of variable length. Additionally,
the results can be obtained for single or many features (e.g. any number of
transcripts) at once. Visualization of the coverage results is facilitated by
the downstream plotfeatureCoverage
function.
appendStep(sal) <- LineWise(code = {
grl <- cdsBy(txdb, "tx", use.names = TRUE)
fcov <- featureCoverage(bfl = BamFileList(outpaths[1:2]),
grl = grl[1:4], resizereads = NULL, readlengthrange = NULL,
Nbins = 20, method = mean, fixedmatrix = FALSE, resizefeatures = TRUE,
upstream = 20, downstream = 20, outfile = "results/featureCoverage.xls",
overwrite = TRUE)
}, step_name = "binned_CDS_coverage", dependency = c("add_features"))
appendStep(sal) <- LineWise(code = {
fcov <- featureCoverage(bfl = BamFileList(outpaths[1:4]),
grl = grl[1:12], resizereads = NULL, readlengthrange = NULL,
Nbins = NULL, method = mean, fixedmatrix = TRUE, resizefeatures = TRUE,
upstream = 20, downstream = 20, outfile = "results/featureCoverage.xls",
overwrite = TRUE)
png("./results/coverage_upstream_downstream.png", height = 12,
width = 24, units = "in", res = 72)
plotfeatureCoverage(covMA = fcov, method = mean, scales = "fixed",
extendylim = 2, scale_count_val = 10^6)
dev.off()
}, step_name = "coverage_upstream_downstream", dependency = c("binned_CDS_coverage"))
appendStep(sal) <- LineWise(code = {
fcov <- featureCoverage(bfl = BamFileList(outpaths[1:4]),
grl = grl[1:4], resizereads = NULL, readlengthrange = NULL,
Nbins = 20, method = mean, fixedmatrix = TRUE, resizefeatures = TRUE,
upstream = 20, downstream = 20, outfile = "results/featureCoverage.xls",
overwrite = TRUE)
png("./results/featurePlot.png", height = 12, width = 24,
units = "in", res = 72)
plotfeatureCoverage(covMA = fcov, method = mean, scales = "fixed",
extendylim = 2, scale_count_val = 10^6)
dev.off()
}, step_name = "coverage_combined", dependency = c("binned_CDS_coverage",
"coverage_upstream_downstream"))
appendStep(sal) <- LineWise(code = {
fcov <- featureCoverage(bfl = BamFileList(outpaths[1:2]),
grl = grl[1], resizereads = NULL, readlengthrange = NULL,
Nbins = NULL, method = mean, fixedmatrix = FALSE, resizefeatures = TRUE,
upstream = 20, downstream = 20, outfile = NULL)
}, step_name = "coverage_nuc_level", dependency = c("coverage_combined"))
summarizeOverlaps
in parallel mode using multiple coresReads overlapping with annotation ranges of interest are counted for each
sample using the summarizeOverlaps
function (Lawrence et al. 2013). The
read counting is preformed for exonic gene regions in a non-strand-specific
manner while ignoring overlaps among different genes. Subsequently, the
expression count values are normalized by (RPKM). The raw read count table (countDFeByg.xls
) and the corresponding
RPKM table (rpkmDFeByg.xls
) are written to separate files in the results
directory of this project.
Parallelization is achieved with the BiocParallel
package, here using 8 CPU cores.
appendStep(sal) <- LineWise(code = {
txdb <- loadDb("./data/tair10.sqlite")
eByg <- exonsBy(txdb, by = c("gene"))
bfl <- BamFileList(outpaths, yieldSize = 50000, index = character())
multicoreParam <- MulticoreParam(workers = 8)
register(multicoreParam)
registered()
counteByg <- bplapply(bfl, function(x) summarizeOverlaps(eByg,
x, mode = "Union", ignore.strand = TRUE, inter.feature = FALSE,
singleEnd = FALSE, BPPARAM = multicoreParam))
countDFeByg <- sapply(seq(along = counteByg), function(x) assays(counteByg[[x]])$counts)
rownames(countDFeByg) <- names(rowRanges(counteByg[[1]]))
colnames(countDFeByg) <- names(bfl)
rpkmDFeByg <- apply(countDFeByg, 2, function(x) returnRPKM(counts = x,
ranges = eByg))
write.table(countDFeByg, "results/countDFeByg.xls", col.names = NA,
quote = FALSE, sep = "\t")
write.table(rpkmDFeByg, "results/rpkmDFeByg.xls", col.names = NA,
quote = FALSE, sep = "\t")
## Creating a SummarizedExperiment object
colData <- data.frame(row.names = SampleName(sal, "hisat2_mapping"),
condition = getColumn(sal, "hisat2_mapping", position = "targetsWF",
column = "Factor"))
colData$condition <- factor(colData$condition)
countDF_se <- SummarizedExperiment::SummarizedExperiment(assays = countDFeByg,
colData = colData)
## Add results as SummarizedExperiment to the workflow
## object
SE(sal, "read_counting") <- countDF_se
}, step_name = "read_counting", dependency = c("featuretypeCounts"))
When providing a BamFileList
as in the example above, summarizeOverlaps
methods
use by default bplapply
and use the register interface from BiocParallel package.
If the number of workers is not set, MulticoreParam
will use the number of cores
returned by parallel::detectCores()
. For more information,
please check help("summarizeOverlaps")
documentation.
Sample of data slice of count table:
read.delim(system.file("extdata/countDFeByg.xls", package = "systemPipeR"),
row.names = 1, check.names = FALSE)[1:4, 1:5]
## M1A M1B A1A A1B V1A
## AT1G01010 57 244 201 169 365
## AT1G01020 23 93 69 126 107
## AT1G01030 41 98 73 58 94
## AT1G01040 180 684 522 664 585
Sample of data slice of RPKM table
read.delim(system.file("extdata/rpkmDFeByg.xls", package = "systemPipeR"),
row.names = 1, check.names = FALSE)[1:4, 1:5]
Note, for most statistical differential expression or abundance analysis
methods, such as edgeR
or DESeq2
, the raw count values
should be used as input. The usage of RPKM values should be restricted to
specialty applications required by some users, e.g. manually comparing
the expression levels among different genes or features.
The following computes the sample-wise Spearman correlation coefficients from
the rlog
transformed expression values generated with the
DESeq2
package. After transformation to a distance matrix,
hierarchical clustering is performed with the hclust
function and
the result is plotted as a dendrogram and written to a file named sample_tree.png
in the results
directory.
appendStep(sal) <- LineWise(code = {
## Extracting SummarizedExperiment object
se <- SE(sal, "read_counting")
dds <- DESeqDataSet(se, design = ~condition)
d <- cor(assay(rlog(dds)), method = "spearman")
hc <- hclust(dist(1 - d))
pdf("results/sample_tree.pdf")
plot.phylo(as.phylo(hc), type = "p", edge.col = "blue", edge.width = 2,
show.node.label = TRUE, no.margin = TRUE)
dev.off()
}, step_name = "sample_tree", dependency = "read_counting")
edgeR
The analysis of differentially expressed genes (DEGs) is performed with the glm
method from the edgeR
package (Robinson, McCarthy, and Smyth 2010). The sample
comparisons used by this analysis are defined in the header lines of the
targetsPE.txt
file starting with <CMP>
.
appendStep(sal) <- LineWise(code = {
countDF <- read.delim("results/countDFeByg.xls", row.names = 1,
check.names = FALSE)
cmp <- readComp(stepsWF(sal)[["hisat2_mapping"]], format = "matrix",
delim = "-")
edgeDF <- run_edgeR(countDF = countDF, targets = targetsWF(sal)[["hisat2_mapping"]],
cmp = cmp[[1]], independent = FALSE, mdsplot = "")
}, step_name = "run_edgeR", dependency = "read_counting")
Add functional gene descriptions, here from biomaRt
.
appendStep(sal) <- LineWise(code = {
m <- useMart("plants_mart", dataset = "athaliana_eg_gene",
host = "https://plants.ensembl.org")
desc <- getBM(attributes = c("tair_locus", "description"),
mart = m)
desc <- desc[!duplicated(desc[, 1]), ]
descv <- as.character(desc[, 2])
names(descv) <- as.character(desc[, 1])
edgeDF <- data.frame(edgeDF, Desc = descv[rownames(edgeDF)],
check.names = FALSE)
write.table(edgeDF, "./results/edgeRglm_allcomp.xls", quote = FALSE,
sep = "\t", col.names = NA)
}, step_name = "custom_annot", dependency = "run_edgeR")
Filter and plot DEG results for up and down regulated genes. The
definition of up and down is given in the corresponding help
file. To open it, type ?filterDEGs
in the R console.
appendStep(sal) <- LineWise(code = {
edgeDF <- read.delim("results/edgeRglm_allcomp.xls", row.names = 1,
check.names = FALSE)
pdf("results/DEGcounts.pdf")
DEG_list <- filterDEGs(degDF = edgeDF, filter = c(Fold = 2,
FDR = 20))
dev.off()
write.table(DEG_list$Summary, "./results/DEGcounts.xls",
quote = FALSE, sep = "\t", row.names = FALSE)
}, step_name = "filter_degs", dependency = "custom_annot")
The overLapper
function can compute Venn intersects for large numbers of sample
sets (up to 20 or more) and plots 2-5 way Venn diagrams. A useful
feature is the possibility to combine the counts from several Venn
comparisons with the same number of sample sets in a single Venn diagram
(here for 4 up and down DEG sets).
appendStep(sal) <- LineWise(code = {
vennsetup <- overLapper(DEG_list$Up[6:9], type = "vennsets")
vennsetdown <- overLapper(DEG_list$Down[6:9], type = "vennsets")
pdf("results/vennplot.pdf")
vennPlot(list(vennsetup, vennsetdown), mymain = "", mysub = "",
colmode = 2, ccol = c("blue", "red"))
dev.off()
}, step_name = "venn_diagram", dependency = "filter_degs")
The following shows how to obtain gene-to-GO mappings from biomaRt
(here for A. thaliana) and how to organize them for the downstream GO
term enrichment analysis. Alternatively, the gene-to-GO mappings can be
obtained for many organisms from Bioconductor’s *.db
genome
annotation packages or GO annotation files provided by various genome
databases. For each annotation this relatively slow preprocessing step needs to
be performed only once. Subsequently, the preprocessed data can be loaded with
the load
function as shown in the next subsection.
appendStep(sal) <- LineWise(code = {
# listMarts() # To choose BioMart database
# listMarts(host='plants.ensembl.org') m <-
# useMart('plants_mart',
# host='https://plants.ensembl.org') listDatasets(m)
m <- useMart("plants_mart", dataset = "athaliana_eg_gene",
host = "https://plants.ensembl.org")
# listAttributes(m) # Choose data types you want to
# download
go <- getBM(attributes = c("go_id", "tair_locus", "namespace_1003"),
mart = m)
go <- go[go[, 3] != "", ]
go[, 3] <- as.character(go[, 3])
go[go[, 3] == "molecular_function", 3] <- "F"
go[go[, 3] == "biological_process", 3] <- "P"
go[go[, 3] == "cellular_component", 3] <- "C"
go[1:4, ]
if (!dir.exists("./data/GO"))
dir.create("./data/GO")
write.table(go, "data/GO/GOannotationsBiomart_mod.txt", quote = FALSE,
row.names = FALSE, col.names = FALSE, sep = "\t")
catdb <- makeCATdb(myfile = "data/GO/GOannotationsBiomart_mod.txt",
lib = NULL, org = "", colno = c(1, 2, 3), idconv = NULL)
save(catdb, file = "data/GO/catdb.RData")
}, step_name = "get_go_annot", dependency = "filter_degs")
Apply the enrichment analysis to the DEG sets obtained the above differential
expression analysis. Note, in the following example the FDR
filter is set
here to an unreasonably high value, simply because of the small size of the toy
data set used in this vignette. Batch enrichment analysis of many gene sets is
performed with the function. When method=all
, it returns all GO terms passing
the p-value cutoff specified under the cutoff
arguments. When method=slim
,
it returns only the GO terms specified under the myslimv
argument. The given
example shows how a GO slim vector for a specific organism can be obtained from
BioMart
.
appendStep(sal) <- LineWise(code = {
load("data/GO/catdb.RData")
DEG_list <- filterDEGs(degDF = edgeDF, filter = c(Fold = 2,
FDR = 50), plot = FALSE)
up_down <- DEG_list$UporDown
names(up_down) <- paste(names(up_down), "_up_down", sep = "")
up <- DEG_list$Up
names(up) <- paste(names(up), "_up", sep = "")
down <- DEG_list$Down
names(down) <- paste(names(down), "_down", sep = "")
DEGlist <- c(up_down, up, down)
DEGlist <- DEGlist[sapply(DEGlist, length) > 0]
BatchResult <- GOCluster_Report(catdb = catdb, setlist = DEGlist,
method = "all", id_type = "gene", CLSZ = 2, cutoff = 0.9,
gocats = c("MF", "BP", "CC"), recordSpecGO = NULL)
m <- useMart("plants_mart", dataset = "athaliana_eg_gene",
host = "https://plants.ensembl.org")
goslimvec <- as.character(getBM(attributes = c("goslim_goa_accession"),
mart = m)[, 1])
BatchResultslim <- GOCluster_Report(catdb = catdb, setlist = DEGlist,
method = "slim", id_type = "gene", myslimv = goslimvec,
CLSZ = 10, cutoff = 0.01, gocats = c("MF", "BP", "CC"),
recordSpecGO = NULL)
}, step_name = "go_enrich", dependency = "get_go_annot")
The data.frame
generated by GOCluster
can be plotted with the goBarplot
function.
Because of the variable size of the sample sets, it may not always be desirable to show
the results from different DEG sets in the same bar plot. Plotting single sample
sets is achieved by subsetting the input data frame as shown in the first line
of the following example.
appendStep(sal) <- LineWise(code = {
gos <- BatchResultslim[grep("M6-V6_up_down", BatchResultslim$CLID),
]
gos <- BatchResultslim
pdf("results/GOslimbarplotMF.pdf", height = 8, width = 10)
goBarplot(gos, gocat = "MF")
goBarplot(gos, gocat = "BP")
goBarplot(gos, gocat = "CC")
dev.off()
}, step_name = "go_plot", dependency = "go_enrich")
Combined with mRNA-Seq data, Ribo-Seq or polyRibo-Seq experiments can be used
to study changes in translational efficiencies of genes and/or transcripts for
different treatments. For test purposes the following generates a small test
data set from the sample data used in this vignette, where two types of RNA
samples (assays
) are considered: polyribosomal mRNA (Ribo
)
and total mRNA (mRNA
). In addition, there are two treatments
(conditions
): M1
and A1
.
appendStep(sal) <- LineWise(code = {
countDFeByg <- read.delim("results/countDFeByg.xls", row.names = 1,
check.names = FALSE)
coldata <- S4Vectors::DataFrame(assay = factor(rep(c("Ribo",
"mRNA"), each = 4)), condition = factor(rep(as.character(targetsWF(sal)[["hisat2_mapping"]]$Factor[1:4]),
2)), row.names = as.character(targetsWF(sal)[["hisat2_mapping"]]$SampleName)[1:8])
coldata
}, step_name = "diff_loading", dependency = "go_plot")
Differences in translational efficiencies can be calculated by ratios of ratios for the two conditions:
\[(Ribo\_A1 / mRNA\_A1) / (Ribo\_M1 / mRNA\_M1)\]
The latter can be modeled with the DESeq2
package using the design
\(\sim assay + condition + assay:condition\), where the interaction term
\(assay:condition\) represents the ratio of ratios. Using the likelihood ratio
test of DESeq2
, which removes the interaction term in the reduced model,
one can test whether the translational efficiency (ribosome loading) is different
in condition A1
than in M1
.
appendStep(sal) <- LineWise(code = {
dds <- DESeq2::DESeqDataSetFromMatrix(countData = as.matrix(countDFeByg[,
rownames(coldata)]), colData = coldata, design = ~assay +
condition + assay:condition)
# model.matrix(~ assay + condition + assay:condition,
# coldata) # Corresponding design matrix
dds <- DESeq2::DESeq(dds, test = "LRT", reduced = ~assay +
condition)
res <- DESeq2::results(dds)
head(res[order(res$padj), ], 4)
write.table(res, file = "transleff.xls", quote = FALSE, col.names = NA,
sep = "\t")
}, step_name = "diff_translational_eff", dependency = "diff_loading")
The following example performs hierarchical clustering on the rlog
transformed
expression matrix subsetted by the DEGs identified in the above differential
expression analysis. It uses a Pearson correlation-based distance measure and
complete linkage for cluster joining.
appendStep(sal) <- LineWise(code = {
geneids <- unique(as.character(unlist(DEG_list[[1]])))
y <- assay(rlog(dds))[geneids, ]
y <- y[rowSums(y[]) > 0, ]
pdf("results/heatmap1.pdf")
pheatmap(y, scale = "row", clustering_distance_rows = "correlation",
clustering_distance_cols = "correlation")
dev.off()
}, step_name = "heatmap", dependency = "diff_translational_eff")
appendStep(sal) <- LineWise(code = {
sessionInfo()
}, step_name = "sessionInfo", dependency = "heatmap")
For running the workflow, runWF
function will execute all the steps store in
the workflow container. The execution will be on a single machine without
submitting to a queuing system of a computer cluster.
sal <- runWF(sal, run_step = "mandatory")
Alternatively, the computation can be greatly accelerated by processing many files in parallel using several compute nodes of a cluster, where a scheduling/queuing system is used for load balancing.
The resources
list object provides the number of independent parallel cluster
processes defined under the Njobs
element in the list. The following example
will run 18 processes in parallel using each 4 CPU cores.
If the resources available on a cluster allow running all 18 processes at the
same time, then the shown sample submission will utilize in a total of 72 CPU cores.
Note, runWF
can be used with most queueing systems as it is based on utilities
from the batchtools
package, which supports the use of template files (*.tmpl
)
for defining the run parameters of different schedulers. To run the following
code, one needs to have both a conffile
(see .batchtools.conf.R
samples here)
and a template
file (see *.tmpl
samples here)
for the queueing available on a system. The following example uses the sample
conffile
and template
files for the Slurm scheduler provided by this package.
The resources can be appended when the step is generated, or it is possible to
add these resources later, as the following example using the addResources
function:
resources <- list(conffile=".batchtools.conf.R",
template="batchtools.slurm.tmpl",
Njobs=18,
walltime=120, ## minutes
ntasks=1,
ncpus=4,
memory=1024, ## Mb
partition = "short"
)
sal <- addResources(sal, c("hisat2_mapping"), resources = resources)
sal <- runWF(sal, run_step = "mandatory")
systemPipeR
workflows instances can be visualized with the plotWF
function.
plotWF(sal, rstudio = TRUE)
To check the summary of the workflow, we can use:
sal
statusWF(sal)
systemPipeR
compiles all the workflow execution logs in one central location,
making it easier to check any standard output (stdout
) or standard error
(stderr
) for any command-line tools used on the workflow or the R code stdout.
sal <- renderLogs(sal)
sessionInfo()
## R version 4.2.0 RC (2022-04-19 r82224)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 20.04.4 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.15-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.15-bioc/R/lib/libRlapack.so
##
## locale:
## [1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
## [3] LC_TIME=en_GB LC_COLLATE=C
## [5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
## [7] LC_PAPER=en_US.UTF-8 LC_NAME=C
## [9] LC_ADDRESS=C LC_TELEPHONE=C
## [11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
##
## attached base packages:
## [1] stats4 stats graphics grDevices utils
## [6] datasets methods base
##
## other attached packages:
## [1] systemPipeR_2.2.0 ShortRead_1.54.0
## [3] GenomicAlignments_1.32.0 SummarizedExperiment_1.26.0
## [5] Biobase_2.56.0 MatrixGenerics_1.8.0
## [7] matrixStats_0.62.0 BiocParallel_1.30.0
## [9] Rsamtools_2.12.0 Biostrings_2.64.0
## [11] XVector_0.36.0 GenomicRanges_1.48.0
## [13] GenomeInfoDb_1.32.0 IRanges_2.30.0
## [15] S4Vectors_0.34.0 BiocGenerics_0.42.0
## [17] BiocStyle_2.24.0
##
## loaded via a namespace (and not attached):
## [1] lattice_0.20-45 png_0.1-7
## [3] assertthat_0.2.1 digest_0.6.29
## [5] utf8_1.2.2 R6_2.5.1
## [7] evaluate_0.15 ggplot2_3.3.5
## [9] pillar_1.7.0 zlibbioc_1.42.0
## [11] rlang_1.0.2 jquerylib_0.1.4
## [13] Matrix_1.4-1 rmarkdown_2.14
## [15] stringr_1.4.0 htmlwidgets_1.5.4
## [17] RCurl_1.98-1.6 munsell_0.5.0
## [19] DelayedArray_0.22.0 compiler_4.2.0
## [21] xfun_0.30 pkgconfig_2.0.3
## [23] htmltools_0.5.2 tidyselect_1.1.2
## [25] tibble_3.1.6 GenomeInfoDbData_1.2.8
## [27] bookdown_0.26 codetools_0.2-18
## [29] fansi_1.0.3 dplyr_1.0.8
## [31] crayon_1.5.1 bitops_1.0-7
## [33] grid_4.2.0 DBI_1.1.2
## [35] jsonlite_1.8.0 gtable_0.3.0
## [37] lifecycle_1.0.1 formatR_1.12
## [39] magrittr_2.0.3 scales_1.2.0
## [41] cli_3.3.0 stringi_1.7.6
## [43] hwriter_1.3.2.1 latticeExtra_0.6-29
## [45] bslib_0.3.1 generics_0.1.2
## [47] ellipsis_0.3.2 vctrs_0.4.1
## [49] RColorBrewer_1.1-3 tools_4.2.0
## [51] glue_1.6.2 purrr_0.3.4
## [53] jpeg_0.1-9 parallel_4.2.0
## [55] fastmap_1.1.0 yaml_2.3.5
## [57] colorspace_2.0-3 BiocManager_1.30.17
## [59] knitr_1.39 sass_0.4.1
This research was funded by National Science Foundation Grants IOS-0750811 and MCB-1021969, and a Marie Curie European Economic Community Fellowship PIOF-GA-2012-327954.
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