QuasR 1.32.0
The QuasR package (short for Quantify and annotate short reads
in R) integrates the functionality of several R packages (such as IRanges (Lawrence et al. 2013)
and Rsamtools) and external software (e.g. bowtie
, through the
Rbowtie package, and HISAT2
, through the Rhisat2 package).
The package aims to cover the whole analysis workflow of typical high throughput
sequencing experiments, starting from the raw sequence reads, over pre-processing and
alignment, up to quantification. A single R script can contain all steps of a complete
analysis, making it simple to document, reproduce or share the workflow containing all
relevant details.
The current QuasR release supports the analysis of single read and paired-end ChIP-seq (chromatin immuno-precipitation combined with sequencing), RNA-seq (gene expression profiling by sequencing of RNA) and Bis-seq (measurement of DNA methylation by sequencing of bisulfite-converted genomic DNA) experiments. It has been successfully used with data from Illumina, 454 Life Technologies and SOLiD sequencers, the latter by using bam files created externally of QuasR.
If you use QuasR (Gaidatzis et al. 2015) in your work, you can cite it as follows:
citation("QuasR")
##
## Please use the QuasR reference below to cite the software itself. If
## you were using qAlign with Rbowtie as aligner, it can be cited as
## Langmead et al. (2009) (unspliced alignments) or Au et al. (2010)
## (spliced alignments). If you were using qAlign with Rhisat2 as aligner,
## it can be cited as Kim et al. (2015).
##
## Gaidatzis D, Lerch A, Hahne F, Stadler MB. QuasR: Quantification and
## annotation of short reads in R. Bioinformatics 31(7):1130-1132
## (2015).
##
## Langmead B, Trapnell C, Pop M, Salzberg SL. Ultrafast and
## memory-efficient alignment of short DNA sequences to the human
## genome. Genome Biology 10(3):R25 (2009).
##
## Au KF, Jiang H, Lin L, Xing Y, Wong WH. Detection of splice junctions
## from paired-end RNA-seq data by SpliceMap. Nucleic Acids Research,
## 38(14):4570-8 (2010).
##
## Kim D, Langmead B, Salzberg SL. HISAT: a fast spliced aligner with
## low memory requirements. Nat Methods, 12(4):357-60 (2015).
##
## This free open-source software implements academic research by the
## authors and co-workers. If you use it, please support the project by
## citing the appropriate journal articles.
## To see these entries in BibTeX format, use 'print(<citation>,
## bibtex=TRUE)', 'toBibtex(.)', or set
## 'options(citation.bibtex.max=999)'.
QuasR is a package for the R computing environment and it is assumed that you have already installed R. See the R project at (http://www.r-project.org). To install the latest version of QuasR, you will need to be using the latest version of R. QuasR is part of the Bioconductor project at (http://www.bioconductor.org). To get QuasR together with its dependencies you can use
if (!require("BiocManager"))
install.packages("BiocManager")
BiocManager::install("QuasR")
Bioconductor works on a 6-monthly official release cycle. As with other Bioconductor
packages, there are always two versions of QuasR. Most users will
use the current official release version, which will be installed by BiocManager::install
if you are using the current release version of R. There is also a development version
of QuasR that includes new features due for the next official release.
The development version will be installed if you are using the development version of
Bioconductor (see version = "devel"
in BiocManager). The official
release version always has an even second number (for example 1.20.1), whereas the
developmental version has an odd second number (for example 1.21.4).
In order to run the code examples in this vignette, the QuasR package and a few additional packages need to be loaded:
suppressPackageStartupMessages({
library(QuasR)
library(BSgenome)
library(Rsamtools)
library(rtracklayer)
library(GenomicFeatures)
library(Gviz)
})
Most questions about QuasR will hopefully be answered by the documentation or references. If you’ve run into a question which isn’t addressed by the documentation, or you’ve found a conflict between the documentation and software, then there is an active support community which can offer help.
The authors of the package (maintainer: Michael Stadler [email protected]) always appreciate receiving reports of bugs in the package functions or in the documentation. The same goes for well-considered suggestions for improvements.
Any other questions or problems concerning QuasR should be posted to the Bioconductor support site (https://support.bioconductor.org). Users posting to the support site for the first time should read the helpful posting guide at (https://support.bioconductor.org/info/faq/). Note that each function in QuasR has it’s own help page, as described in the section 3.1. Posting etiquette requires that you read the relevant help page carefully before posting a problem to the site.
If you already use R and know about its interface, just skip this section and continue with section 3.2.
The structure of this vignette and in particular this section is based on the excellent user guide of the limma package, which we would like to hereby acknowledge. R is a program for statistical computing. It is a command-driven language meaning that you have to type commands into it rather than pointing and clicking using a mouse. In this guide it will be assumed that you have successfully downloaded and installed R from (http://www.r-project.org) as well as QuasR (see section 2.2). A good way to get started is to type
help.start()
at the R prompt or, if you’re using R for Windows, to follow the drop-down menu items Help \(\succ\) Html help. Following the links Packages \(\succ\) QuasR from the html help page will lead you to the contents page of help topics for functions in QuasR.
Before you can use any QuasR commands you have to load the package by typing
library(QuasR)
at the R prompt. You can get help on any function in any loaded package by typing
?
and the function name at the R prompt, for example
?preprocessReads
or equivalently
help("preprocessReads")
for detailed help on the preprocessReads
function. The function help
page is especially useful to learn about its arguments and its return value.
Working with R usually means creating and transforming objects. Objects might include data sets, variables, functions, anything at all. For example
x <- 2
will create a variable x
and will assign it the value 2. At any stage of your
R session you can type
ls()
to get a list of all the objects currently existing in your session. You can
display an object by typing its name on the prompt. The following displays the
object x
:
x
We hope that you can use QuasR without having to spend a lot of time learning about the R language itself but a little knowledge in this direction will be very helpful, especially when you want to do something not explicitly provided for in QuasR or in the other Bioconductor packages. For more details about the R language see An Introduction to R which is available from the online help, or one of the many great online resources, like the documentation at r-project.org, the growing list of free books at bioconductor.org, or the books from rstudio.com (many of which are also available for free). For more background on using R for statistical analysis see (Dalgaard 2002).
This is a quick overview of what an analysis could look like for users preferring
to jump right into an analysis. The example uses data that is provided with the
QuasR package, which is first copied to the current working directory,
into a subfolder called "extdata"
:
file.copy(system.file(package="QuasR", "extdata"), ".", recursive=TRUE)
## [1] TRUE
The sequence files to be analyzed are listed in sampleFile
(see section
5.1 for details).
The sequence reads will be aligned using bowtie
(Langmead et al. 2009) (from the Rbowtie
package (Hahne, Lerch, and Stadler 2012)) to a small reference genome (consisting of three short segments
from the hg19 human genome assembly, available in full for example in the
BSgenome.Hsapiens.UCSC.hg19 package). Information on selecting
an appropriate reference genome is summarized in section 5.3.
Make sure that you have sufficient disk space, both in your R temporary
directory (tempdir()
) as well as to store the resulting alignments
(see section 7.2).
sampleFile <- "extdata/samples_chip_single.txt"
genomeFile <- "extdata/hg19sub.fa"
proj <- qAlign(sampleFile, genomeFile)
## Creating .fai file for: /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub.fa
## alignment files missing - need to:
## create alignment index for the genome
## create 2 genomic alignment(s)
## Creating an Rbowtie index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub.fa
## Finished creating index
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nebbiolo1: 1
## Performing genomic alignments for 2 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293bc328f4d.txt
## Genomic alignments have been created successfully
proj
## Project: qProject
## Options : maxHits : 1
## paired : no
## splicedAlignment: FALSE
## bisulfite : no
## snpFile : none
## geneAnnotation : none
## Aligner : Rbowtie v1.32.0 (parameters: -m 1 --best --strata)
## Genome : /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vign.../hg19sub.fa (file)
##
## Reads : 2 files, 2 samples (fastq format):
## 1. chip_1_1.fq.bz2 Sample1 (phred33)
## 2. chip_2_1.fq.bz2 Sample2 (phred33)
##
## Genome alignments: directory: same as reads
## 1. chip_1_1_d293b270b22a.bam
## 2. chip_2_1_d293b42b40683.bam
##
## Aux. alignments: none
The proj
object keeps track of all the information of a sequencing experiment,
for example where sequence and alignment files are stored, and what aligner and
reference genome was used to generate the alignments.
Now that the alignments have been generated, further analyses can be performed.
A quality control report is saved to the "extdata/qc_report.pdf"
file using the
qQCReport
function.
qQCReport(proj, "extdata/qc_report.pdf")
## collecting quality control data
## creating QC plots
The number of alignments per promoter region is quantified using qCount
. Genomic
coordinates for promoter regions are imported from a gtf file (annotFile
) into
the GRanges
-object with the name promReg
:
library(rtracklayer)
library(GenomicFeatures)
annotFile <- "extdata/hg19sub_annotation.gtf"
txStart <- import.gff(annotFile, format="gtf", feature.type="start_codon")
promReg <- promoters(txStart, upstream=500, downstream=500)
names(promReg) <- mcols(promReg)$transcript_name
promCounts <- qCount(proj, query=promReg)
## counting alignments...done
promCounts
## width Sample1 Sample2
## TNFRSF18-003 1000 20 4
## TNFRSF18-002 1000 20 4
## TNFRSF18-001 1000 20 4
## TNFRSF4-001 1000 5 2
## SDF4-007 1000 8 2
## SDF4-001 1000 8 2
## SDF4-002 1000 8 2
## SDF4-201 1000 8 2
## B3GALT6-001 1000 25 274
## RPS7-001 1000 121 731
## RPS7-008 1000 121 731
## RPS7-009 1000 121 731
## RPS7-005 1000 121 731
## C3orf10-201 1000 176 496
## C3orf10-001 1000 176 496
## AC034193.1-201 1000 5 2
## VHL-001 1000 61 336
## VHL-002 1000 61 336
## VHL-201 1000 61 336
The following scheme shows the major components of QuasR and their relationships:
QuasR works with data (sequences and alignments, reference genome, etc.) that are stored as files on your storage (the gray cylinder on the lower left of Figure above, see section 4.1 for details on storage locations). QuasR does not need a database management system, or these files to be named and organized according to a specific scheme.
In order to keep track of directory paths during an analysis, QuasR
makes use of a qProject
object that is returned by the qAlign
function, which
at the minimum requires two inputs: the name of a samples text file (see section
5.1 for details), and the reference genome for the alignments
(see section 5.3).
The qProject
object is the main argument passed to subsequent functions such as
qQCReport
and qCount
. The qProject
object contains all necessary information
on the current project and eliminates the need to repeatedly enter the same information.
All functions that work on qProject
objects can be recognized by their names starting
with the letter q.
Read quantification (apart from quantification of methylation which has its own
function qMeth
) is done using the qCount
function: It counts the alignments in
regions of interest (e.g. promoters, genes, exons, etc.) and produces a count table
(regions in rows, samples in columns) for further visualization and analysis. The
count table can also be used as input to a statistical analysis using packages such
as edgeR (Robinson, McCarthy, and Smyth 2010), DESeq (Anders and Huber 2010), DESeq2 (Love, Huber, and Anders 2014),
TCC (Sun et al. 2013), DEXSeq (Anders, Reyes, and Huber 2012) or baySeq (Hardcastle and Kelly 2010).
In summary, a typical QuasR analysis consists of the following steps (some of them are optional):
preprocessReads
(optional): Remove adapters from start or end of reads, filter
out reads of low quality, short length or low complexity (section 5.4).qAlign
: Create qProject
object and specify project parameters. Also download
BSgenome package, create aligner indices and align reads if not already existing
(section 7.2).qQCReport
(optional): Create quality control report with plots on sequence qualities
and alignment statistics (section 7.4).qExportWig
(optional): Export genomic alignments as wiggle tracks for genome
browser visualization (section 7.6).qCount
: Quantify alignments in regions of interest (section 7.7).Recurrent example tasks that may be part of any typical analysis are described in section 5. Example workflows for specific experiment types (ChIP-seq, RNA-seq and Bis-seq) are described in section 6.
Apart from qExportWig
and qQCReport
, which generate wig files and pdf reports,
qAlign
is the only function in QuasR that stores files on the disk
(see section 7.2 for details). All files generated by qAlign
are listed here
by type, together with their default location and how locations can be changed.
tempdir()
): Temporary files include reference genomes
in fasta
format, decompressed input sequence files, and temporary alignments in
text format, and can require a large amount of disk space. By default, these files
will be written to the temporary directory of the R process (as reported by
tempdir()
). If using clObj
for parallel processing, this may be the tempdir()
from the cluster node(s). An alternative location can be set using the TMPDIR
environment variable (see ?tempdir
).bam
format) (default: same directory as the input sequence files):
Alignments against reference genome and auxiliary targets are stored in bam
format
in the same directory that also contains the input sequence file (listed in sampleFile
).
Please note that if the input sequence file corresponds to a symbolic link, QuasR
will follow the link and use the directory of the original file instead. An alternative
directory can be specified with the alignmentsDir
argument from qAlign
, which
will store all bam
files in that directory even if the input sequence files are located
in different directories.genome
and snpFile
arguments):
Many alignment tools including bowtie
require an index of the reference sequence
to perform alignments. If necessary, qAlign
will build this index automatically
and store it in a default location that depends on the genome
argument:
BSgenome
: If genome
is the name of a BSgenome package
(such as "BSgenome.Hsapiens.UCSC.hg19"
), the index will be stored as a
new R package in the default library path (as reported by .libPaths()[1]
,
see ?install.packages
for details). The name of this index package will be
the name of the original BSgenome package with a suffix for
the index type, for example "BSgenome.Hsapiens.UCSC.hg19.Rbowtie"
.fasta
: If genome
refers to a reference genome file in fasta
format,
the index will be stored in a subdirectory at the same location. Similarly,
the indices for files listed in auxiliaryFile
are store at the location
of these files. For example, the Rbowtie
index for the genome at
"./genome/mm9.fa"
is stored in "./genome/mm9.fa.Rbowtie"
.snpFile
(e.g. "./mySNPs.tab"
)
are injected into the genome
(e.g. "BSgenome.Mmusculus.UCSC.mm9"
)
to create two variant genomes to be indexed. These indices are saved at the
location of the snpFile
in a directory named after snpFile
, genome
and the index type (e.g. "./mySNPs.tab.BSgenome.Mmusculus.UCSC.mm9.A.fa.Rbowtie"
).The sample file is a tab-delimited text file with two or three columns. The first row contains the column names: For a single read experiment, these are ‘FileName’ and ‘SampleName’; for a paired-end experiment, these are ‘FileName1’, ‘FileName2’ and ‘SampleName’. If the first row does not contain the correctly spelled column names, QuasR will not accept the samples file. Subsequent rows contain the input sequence files.
Here are examples of such sample files for a single read experiment:
FileName SampleName chip_1_1.fq.bz2 Sample1 chip_2_1.fq.bz2 Sample2
and for a paired-end experiment:
FileName1 FileName2 SampleName rna_1_1.fq.bz2 rna_1_2.fq.bz2 Sample1 rna_2_1.fq.bz2 rna_2_2.fq.bz2 Sample2
These example files are also contained in the QuasR package and may be used as templates. The path of the files can be determined using:
sampleFile1 <- system.file(package="QuasR", "extdata",
"samples_chip_single.txt")
sampleFile2 <- system.file(package="QuasR", "extdata",
"samples_rna_paired.txt")
The columns FileName for single-read, or FileName1 and FileName2 for paired-end
experiments contain paths and names to files containing the sequence data. The paths
can be absolute or relative to the location of the sample file. This allows combining
files from different directories in a single analysis. For each input sequence file,
qAlign
will create one alignment file and by default store it in the same directory
as the sequence file. Already existing alignment files with identical parameters will
not be re-created, so that it is easy to reuse the same sequence files in multiple
projects without unnecessarily copying sequence files or recreating alignments.
The SampleName column contains sample names for each sequence file. The same name
can be used on several lines to indicate multiple sequence files that belong to the
same sample (qCount
can use this information to automatically combine counts for
one sample from multiple files).
Three file formats are supported for input files (but cannot be mixed within a single sample file):
bam
files. This makes it possible to use alignment tools that are not available
within QuasR, but making use of this option comes with a risk and
should only be used by experienced users. For example, it cannot be guaranteed
any more that certain assumptions made by qCount
are fulfilled by the external
aligner (see below). When using external bam
files, we recommend to use files which contain only one alignment per read. This
may also include multi-hit reads, for which one of the alignments is randomly
selected. This allows QuasR to count the total number of reads by
counting the total number of alignments. Furthermore, if the bam
files also
contain the unmapped reads, QuasR will be able to calculate the
fraction of mapped reads. For bisulfite samples we require ungapped alignments
stored in unpaired or paired ff orientation (even if the input reads are fr).
For allele-specific bam
files, QuasR requires an additional tag
for each alignment called XV
of type A
(printable character) with the possible
values R
(Reference), U
(Unknown) and A
(Alternative).fasta and fastq files can be compressed with gzip, bzip2 or xz (file extensions ‘.gz’, ‘.bz2’ or ‘xz’, respectively) and will be automatically decompressed when necessary.
bam
files after performing alignmentsOnce alignments have been created, most analyses will only require the bam
files
and will not access the original raw sequence files anymore. However, re-creating
a qProject
object by a later identical call to qAlign
will still need access to
the raw sequences to verify consistency between raw data and alignments. It may be
desirable to remove this dependency, for example to archive or move away the raw
sequence files and to reclaim used disk space.
This can be achieved using the following procedure involving two sequential calls
to qAlign
. First, qAlign
is called with the orignial sample file (sampleFile1
)
that lists the raw sequence files, and subsequently with a second sample file
(sampleFile2
) that lists the bam
files generated in the first call. Such a
second sample file can be easily generated given the qProject
object (proj1
)
returned by the first call:
sampleFile1 <- "samples_fastq.txt"
sampleFile2 <- "samples_bam.txt"
proj1 <- qAlign(sampleFile1, genomeFile)
write.table(alignments(proj1)$genome, sampleFile2, sep="\t", row.names=FALSE)
proj2 <- qAlign(sampleFile2, genomeFile)
The analysis can now be exclusively based on the bam
files using sampleFile2
and proj2
.
The sample file implicitly defines the type of samples contained in the project:
single read or paired-end read, sequences with or without qualities.
This type will have a profound impact on the downstream analysis. For example,
it controls whether alignments will be performed in single or paired-end mode,
either with or without base qualities. That will also determine availability of
certain options for quality control and quantification in qQCReport
and qCount
.
For consistency, it is therefore required that all samples within a project have
the same type; it is not possible to mix both single and paired-end read samples,
or fasta and fastq files in a single project (sample file). If necessary,
it may be possible to analyse different types of files in separate QuasR
projects and combine the derived results at the end.
By default QuasR aligns reads only to the reference genome. However,
it may be interesting to align non-matching reads to further targets, for example
to identify contamination from vectors or a different species, or in order to
quantify spike-in material not contained in the reference genome. In QuasR,
such supplementary reference files are called auxiliary references and can be
specified to qAlign
using the auxiliaryFile
argument (see section 7.2
for details). The format of the auxiliary file is similar to the one of the sample
file described in section 5.1: It contains two columns with
column names ‘FileName’ and ‘AuxName’ in the first row. Additional rows contain
names and files of one or several auxiliary references in fasta
format.
An example auxiliary file looks like this:
FileName AuxName NC_001422.1.fa phiX174
and is available from your QuasR installation at
auxFile <- system.file(package="QuasR", "extdata", "auxiliaries.txt")
Sequence reads are primarily aligned against the reference genome (see section 5.3.1 on how to choose a suitable reference assembly). If necessary, QuasR will create an aligner index for the genome. The reference genome can be provided in one of two different formats:
a string, referring to the name of a BSgenome package:
available.genomes()
## [1] "BSgenome.Alyrata.JGI.v1"
## [2] "BSgenome.Amellifera.BeeBase.assembly4"
## [3] "BSgenome.Amellifera.NCBI.AmelHAv3.1"
## [4] "BSgenome.Amellifera.UCSC.apiMel2"
## [5] "BSgenome.Amellifera.UCSC.apiMel2.masked"
## [6] "BSgenome.Aofficinalis.NCBI.V1"
## [7] "BSgenome.Athaliana.TAIR.04232008"
## [8] "BSgenome.Athaliana.TAIR.TAIR9"
## [9] "BSgenome.Btaurus.UCSC.bosTau3"
## [10] "BSgenome.Btaurus.UCSC.bosTau3.masked"
## [11] "BSgenome.Btaurus.UCSC.bosTau4"
## [12] "BSgenome.Btaurus.UCSC.bosTau4.masked"
## [13] "BSgenome.Btaurus.UCSC.bosTau6"
## [14] "BSgenome.Btaurus.UCSC.bosTau6.masked"
## [15] "BSgenome.Btaurus.UCSC.bosTau8"
## [16] "BSgenome.Btaurus.UCSC.bosTau9"
## [17] "BSgenome.Carietinum.NCBI.v1"
## [18] "BSgenome.Celegans.UCSC.ce10"
## [19] "BSgenome.Celegans.UCSC.ce11"
## [20] "BSgenome.Celegans.UCSC.ce2"
## [21] "BSgenome.Celegans.UCSC.ce6"
## [22] "BSgenome.Cfamiliaris.UCSC.canFam2"
## [23] "BSgenome.Cfamiliaris.UCSC.canFam2.masked"
## [24] "BSgenome.Cfamiliaris.UCSC.canFam3"
## [25] "BSgenome.Cfamiliaris.UCSC.canFam3.masked"
## [26] "BSgenome.Cjacchus.UCSC.calJac3"
## [27] "BSgenome.Creinhardtii.JGI.v5.6"
## [28] "BSgenome.Dmelanogaster.UCSC.dm2"
## [29] "BSgenome.Dmelanogaster.UCSC.dm2.masked"
## [30] "BSgenome.Dmelanogaster.UCSC.dm3"
## [31] "BSgenome.Dmelanogaster.UCSC.dm3.masked"
## [32] "BSgenome.Dmelanogaster.UCSC.dm6"
## [33] "BSgenome.Drerio.UCSC.danRer10"
## [34] "BSgenome.Drerio.UCSC.danRer11"
## [35] "BSgenome.Drerio.UCSC.danRer5"
## [36] "BSgenome.Drerio.UCSC.danRer5.masked"
## [37] "BSgenome.Drerio.UCSC.danRer6"
## [38] "BSgenome.Drerio.UCSC.danRer6.masked"
## [39] "BSgenome.Drerio.UCSC.danRer7"
## [40] "BSgenome.Drerio.UCSC.danRer7.masked"
## [41] "BSgenome.Dvirilis.Ensembl.dvircaf1"
## [42] "BSgenome.Ecoli.NCBI.20080805"
## [43] "BSgenome.Gaculeatus.UCSC.gasAcu1"
## [44] "BSgenome.Gaculeatus.UCSC.gasAcu1.masked"
## [45] "BSgenome.Ggallus.UCSC.galGal3"
## [46] "BSgenome.Ggallus.UCSC.galGal3.masked"
## [47] "BSgenome.Ggallus.UCSC.galGal4"
## [48] "BSgenome.Ggallus.UCSC.galGal4.masked"
## [49] "BSgenome.Ggallus.UCSC.galGal5"
## [50] "BSgenome.Ggallus.UCSC.galGal6"
## [51] "BSgenome.Hsapiens.1000genomes.hs37d5"
## [52] "BSgenome.Hsapiens.NCBI.GRCh38"
## [53] "BSgenome.Hsapiens.UCSC.hg17"
## [54] "BSgenome.Hsapiens.UCSC.hg17.masked"
## [55] "BSgenome.Hsapiens.UCSC.hg18"
## [56] "BSgenome.Hsapiens.UCSC.hg18.masked"
## [57] "BSgenome.Hsapiens.UCSC.hg19"
## [58] "BSgenome.Hsapiens.UCSC.hg19.masked"
## [59] "BSgenome.Hsapiens.UCSC.hg38"
## [60] "BSgenome.Hsapiens.UCSC.hg38.masked"
## [61] "BSgenome.Mdomestica.UCSC.monDom5"
## [62] "BSgenome.Mfascicularis.NCBI.5.0"
## [63] "BSgenome.Mfuro.UCSC.musFur1"
## [64] "BSgenome.Mmulatta.UCSC.rheMac10"
## [65] "BSgenome.Mmulatta.UCSC.rheMac2"
## [66] "BSgenome.Mmulatta.UCSC.rheMac2.masked"
## [67] "BSgenome.Mmulatta.UCSC.rheMac3"
## [68] "BSgenome.Mmulatta.UCSC.rheMac3.masked"
## [69] "BSgenome.Mmulatta.UCSC.rheMac8"
## [70] "BSgenome.Mmusculus.UCSC.mm10"
## [71] "BSgenome.Mmusculus.UCSC.mm10.masked"
## [72] "BSgenome.Mmusculus.UCSC.mm8"
## [73] "BSgenome.Mmusculus.UCSC.mm8.masked"
## [74] "BSgenome.Mmusculus.UCSC.mm9"
## [75] "BSgenome.Mmusculus.UCSC.mm9.masked"
## [76] "BSgenome.Osativa.MSU.MSU7"
## [77] "BSgenome.Ppaniscus.UCSC.panPan1"
## [78] "BSgenome.Ppaniscus.UCSC.panPan2"
## [79] "BSgenome.Ptroglodytes.UCSC.panTro2"
## [80] "BSgenome.Ptroglodytes.UCSC.panTro2.masked"
## [81] "BSgenome.Ptroglodytes.UCSC.panTro3"
## [82] "BSgenome.Ptroglodytes.UCSC.panTro3.masked"
## [83] "BSgenome.Ptroglodytes.UCSC.panTro5"
## [84] "BSgenome.Ptroglodytes.UCSC.panTro6"
## [85] "BSgenome.Rnorvegicus.UCSC.rn4"
## [86] "BSgenome.Rnorvegicus.UCSC.rn4.masked"
## [87] "BSgenome.Rnorvegicus.UCSC.rn5"
## [88] "BSgenome.Rnorvegicus.UCSC.rn5.masked"
## [89] "BSgenome.Rnorvegicus.UCSC.rn6"
## [90] "BSgenome.Scerevisiae.UCSC.sacCer1"
## [91] "BSgenome.Scerevisiae.UCSC.sacCer2"
## [92] "BSgenome.Scerevisiae.UCSC.sacCer3"
## [93] "BSgenome.Sscrofa.UCSC.susScr11"
## [94] "BSgenome.Sscrofa.UCSC.susScr3"
## [95] "BSgenome.Sscrofa.UCSC.susScr3.masked"
## [96] "BSgenome.Tgondii.ToxoDB.7.0"
## [97] "BSgenome.Tguttata.UCSC.taeGut1"
## [98] "BSgenome.Tguttata.UCSC.taeGut1.masked"
## [99] "BSgenome.Tguttata.UCSC.taeGut2"
## [100] "BSgenome.Vvinifera.URGI.IGGP12Xv0"
## [101] "BSgenome.Vvinifera.URGI.IGGP12Xv2"
## [102] "BSgenome.Vvinifera.URGI.IGGP8X"
genomeName <- "BSgenome.Hsapiens.UCSC.hg19"
In this example, the BSgenome package "BSgenome.Hsapiens.UCSC.hg19"
refers to
an unmasked genome; alignment index and alignments will be performed on the full
unmasked genome sequence (recommended). If using a masked genome (e.g. "BSgenome.Hsapiens.UCSC.hg19.masked"
),
masked regions will be replaced with "N"
bases, and this hard-masked version of
the genome will be used for creating the alignment index and further alignments.
Please also see section 5.3.1 for potential issues with redundant
sequences contained in the reference genome, e.g. in BSgenome.Hsapiens.UCSC.hg19
or BSgenome.Hsapiens.UCSC.hg38.
a file name, referring to a sequence file containing one or several reference
sequences (e.g. chromosomes) in fasta
format:
genomeFile <- system.file(package="QuasR", "extdata", "hg19sub.fa")
For some organisms, several versions of the genome assembly exist. These differ for example in whether or not they include alternative variants for sequences that are variable within the species. This may lead to redundant sequences in the assembly, and thus reads mapping to such sequences being wrongly classified as “multi-mapping”, and comparing data aligned to different assembly version may give rise to incorrect results. A nice summary of this issue is provided in this blog post from Heng Li.
The BSgenome packages BSgenome.Hsapiens.UCSC.hg19 (versions newer than 1.4.0 from Bioconductor 3.10) and BSgenome.Hsapiens.UCSC.hg38 (all versions) do contain such redundant sequences and are therefore not ideal references for alignment of human data. Specific “analysis set” or “primary assembly” versions of the assembly should be used instead (see the before-mentioned blog post for details).
When using a BSgenome reference, QuasR will check
in the qAlign
function whether the chromosome names and lengths contained
in the header of any pre-existing bam files are identical to the ones provided by
the genome and warn if this is not the case.
The preprocessReads
function can be used to prepare the input sequence files
prior to alignment. The function takes one or several sequence files (or pairs
of files for a paired-end experiment) in fasta
or fastq
format as input and
produces the same number of output files with the processed reads.
In the following example, we truncate the reads by removing the three bases from
the 3’-end (the right side), remove the adapter sequence AAAAAAAAAA
from the
5’-end (the left side) and filter out reads that, after truncation and adapter
removal, are shorter than 14 bases or contain more than 2 N
bases:
td <- tempdir()
infiles <- system.file(package="QuasR", "extdata",
c("rna_1_1.fq.bz2","rna_2_1.fq.bz2"))
outfiles <- file.path(td, basename(infiles))
res <- preprocessReads(filename = infiles,
outputFilename = outfiles,
truncateEndBases = 3,
Lpattern = "AAAAAAAAAA",
minLength = 14,
nBases = 2)
## filtering /tmp/RtmpdrDuWc/Rinstcf76f581e955e/QuasR/extdata/rna_1_1.fq.bz2
## filtering /tmp/RtmpdrDuWc/Rinstcf76f581e955e/QuasR/extdata/rna_2_1.fq.bz2
res
## rna_1_1.fq.bz2 rna_2_1.fq.bz2
## totalSequences 3002 3000
## matchTo5pAdapter 466 463
## matchTo3pAdapter 0 0
## tooShort 107 91
## tooManyN 0 0
## lowComplexity 0 0
## totalPassed 2895 2909
unlink(outfiles)
preprocessReads
returns a matrix with a summary of the pre-processing. The matrix
contains one column per (pair of) input sequence files, and contains the total
number of reads (totalSequences
), the number of reads that matched to the five
prime or three prime adapters (matchTo5pAdapter
and matchTo3pAdapter
), the
number of reads that were too short (tooShort
), contained too many non-base
characters (tooManyN
) or were of low sequence complexity (lowComplexity
,
deactivated by default). Finally, the number of reads that passed the filtering
steps is reported in the last row (totalPassed
).
In the example below we process paired-end reads, removing all pairs with one or
several N
bases. Even if only one sequence in a pair fulfills the filtering
criteria, both reads in the pair are removed, thereby preserving the matching
order of the sequences in the two files:
td <- tempdir()
infiles1 <- system.file(package="QuasR", "extdata", "rna_1_1.fq.bz2")
infiles2 <- system.file(package="QuasR", "extdata", "rna_1_2.fq.bz2")
outfiles1 <- file.path(td, basename(infiles1))
outfiles2 <- file.path(td, basename(infiles2))
res <- preprocessReads(filename=infiles1,
filenameMate=infiles2,
outputFilename=outfiles1,
outputFilenameMate=outfiles2,
nBases=0)
## filtering /tmp/RtmpdrDuWc/Rinstcf76f581e955e/QuasR/extdata/rna_1_1.fq.bz2 and
## /tmp/RtmpdrDuWc/Rinstcf76f581e955e/QuasR/extdata/rna_1_2.fq.bz2
res
## rna_1_1.fq.bz2:rna_1_2.fq.bz2
## totalSequences 3002
## matchTo5pAdapter NA
## matchTo3pAdapter NA
## tooShort 0
## tooManyN 3
## lowComplexity 0
## totalPassed 2999
More details on the preprocessReads
function can be found in the function
documentation (see ?preprocessReads
) or in the section 7.1.
Here we show an exemplary single-end ChIP-seq workflow using a small number of
reads from a histone 3 lysine 4 trimethyl (H3K4me3) ChIP-seq experiment. This
histone modification is known to locate to genomic regions with a high density
of CpG dinucleotides (so called CpG islands); about 60% of mammalian genes have
such a CpG island close to their transcript start site. All necessary files are
included in the QuasR package, and we start the example workflow
by copying those files into the current working directly, into a subfolder called "extdata"
:
file.copy(system.file(package="QuasR", "extdata"), ".", recursive=TRUE)
## [1] TRUE
qAlign
functionWe assume that the sequence reads have already been pre-processed as described
in section 5.4. Also, a sample file (section 5.1)
that lists all sequence files to be analyzed has been prepared. A fasta
file
with the reference genome sequence(s) is also available (section 5.3),
as well as an auxiliary file for alignment of reads that failed to match the reference
genome (section 5.2).
By default, newly generated bam
files will be stored at the location of the input
sequence files, which should be writable and have sufficient capacity (an alternative
location can be specified using the alignmentsDir
argument). Make also sure that
you have sufficient temporary disk space for intermediate files in tempdir()
(see section 7.2). We start by aligning the reads using qAlign
:
sampleFile <- "extdata/samples_chip_single.txt"
auxFile <- "extdata/auxiliaries.txt"
genomeFile <- "extdata/hg19sub.fa"
proj1 <- qAlign(sampleFile, genome=genomeFile, auxiliaryFile=auxFile)
## alignment files missing - need to:
## create 2 auxiliary alignment(s)
## Creating an Rbowtie index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/NC_001422.1.fa
## Finished creating index
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nodeNames
## nebbiolo1
## 1
## Performing auxiliary alignments for 2 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293b4117c55c.txt
## Auxiliary alignments have been created successfully
proj1
## Project: qProject
## Options : maxHits : 1
## paired : no
## splicedAlignment: FALSE
## bisulfite : no
## snpFile : none
## geneAnnotation : none
## Aligner : Rbowtie v1.32.0 (parameters: -m 1 --best --strata)
## Genome : /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vign.../hg19sub.fa (file)
##
## Reads : 2 files, 2 samples (fastq format):
## 1. chip_1_1.fq.bz2 Sample1 (phred33)
## 2. chip_2_1.fq.bz2 Sample2 (phred33)
##
## Genome alignments: directory: same as reads
## 1. chip_1_1_d293b270b22a.bam
## 2. chip_2_1_d293b42b40683.bam
##
## Aux. alignments: 1 file, directory: same as reads
## a. /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vigne.../NC_001422.1.fa phiX174
## 1. chip_1_1_d293b71ddb7c7.bam
## 2. chip_2_1_d293b2fd9724b.bam
qAlign
will build alignment indices if they do not yet exist (by default, if the
genome and auxiliary sequences are given in the form of fasta
files, they will
be stored in the same folder). The qProject
object (proj1
) returned by qAlign
now contains all information about the ChIP-seq experiment: the (optional) project name,
the project options, aligner package, reference genome, and at the bottom the sequence
and alignment files. For each input sequence file, there will be one bam
file with
alignments against the reference genome, and one for each auxiliary target sequence
with alignments of reads without genome hits. Our auxFile
contains a single auxiliary
target sequence, so we expect two bam
files per input sequence file:
list.files("extdata", pattern=".bam$")
## [1] "chip_1_1_d293b270b22a.bam" "chip_1_1_d293b71ddb7c7.bam"
## [3] "chip_2_1_d293b2fd9724b.bam" "chip_2_1_d293b42b40683.bam"
## [5] "phiX_paired_withSecondary.bam"
The bam
file names consist of the base name of the sequence file with an added
random string. The random suffix makes sure that newly generated alignment files
do not overwrite existing ones, for example of the same reads aligned against an
alternative reference genome. Each alignment file is accompanied by two additional
files with suffixes .bai
and .txt
:
list.files("extdata", pattern="^chip_1_1_")[1:3]
## [1] "chip_1_1_d293b270b22a.bam" "chip_1_1_d293b270b22a.bam.bai"
## [3] "chip_1_1_d293b270b22a.bam.txt"
The .bai
file is the bam
index used for fast access by genomic coordinate.
The .txt
file contains all the parameters used to generate the corresponding bam
file. Before new alignments are generated, qAlign
will look for available .txt
files in default locations (the directory containing the input sequence file, or
the value of alignmentsDir
), and read their contents to determine if a compatible
bam
file already exists. A compatible bam
file is one with the same reads and
genome, aligned using the same aligner and identical alignment parameters. If a
compatible bam
file is not found, or the .txt
file is missing, qAlign
will
generate a new bam
file. It is therefore recommended not to delete the .txt
file - without it, the corresponding bam
file will become unusable for QuasR.
QuasR can produce a quality control report in the form of a series
of diagnostic plots with details on sequences and alignments (see QuasR scheme figure above).
The plots are generated by calling the qQCReport
function with the qProject
object as argument. qQCReport
uses ShortRead (Morgan et al. 2009) internally
to obtain some of the quality metrics, and some of the plots are inspired by the
FastQC quality control tool by Simon Andrews (http://www.bioinformatics.bbsrc.ac.uk/projects/fastqc/).
The plots will be stored into a multipage PDF document defined by the pdfFilename
argument, or else shown as individual plot windows on the current graphics device.
In order to keep the running time reasonably short, some quality metrics are obtained
from a random sub-sample of the sequences or alignments.
## collecting quality control data
## creating QC plots
qQCReport(proj1, pdfFilename="extdata/qc_report.pdf")
## collecting quality control data
## creating QC plots
Currently available plots are described in section 7.4 and following.
The alignmentStats
gets the number of (un-)mapped reads for each sequence file
in a qProject
object, by reading the bam
file indices, and returns them as a
data.frame
. The function also works for arguments of type character
with one
or several bam
file names (for details see section 7.5).
alignmentStats(proj1)
## seqlength mapped unmapped
## Sample1:genome 95000 2339 258
## Sample2:genome 95000 3609 505
## Sample1:phiX174 5386 251 7
## Sample2:phiX174 5386 493 12
For visualization in a genome browser, alignment coverage along the genome can be
exported to a (compressed) wig file using the qExportWig
function. The created
fixedStep wig file (see (http://genome.ucsc.edu/goldenPath/help/wiggle.html) for
details on the wig format) will contain one track per sample in the qProject
object. The resolution is defined using the binsize
argument, and if scaling
is set to TRUE
, read counts per bin are scaled by the total number of aligned
reads in each sample to improve comparability:
qExportWig(proj1, binsize=100L, scaling=TRUE, collapseBySample=TRUE)
## collecting mapping statistics for scaling...done
## start creating wig files...
## Sample1.wig.gz (Sample1)
## Sample2.wig.gz (Sample2)
## done
qCount
Alignments are quantified using qCount
, for example using a GRanges
object as
a query. In our H3K4me3 ChIP-seq example, we expect the reads to occur around the
transcript start site of genes. We can therefore construct suitable query regions
using genomic intervals around the start sites of known genes. In the code below,
this is achieved with help from the GenomicFeatures package: We first
create a TxDb
object from a .gtf
file with gene annotation. With the promoters
function, we can then create the GRanges
object with regions to be quantified.
Finally, because most genes consist of multiple overlapping transcripts, we select
the first transcript for each gene:
library(GenomicFeatures)
annotFile <- "extdata/hg19sub_annotation.gtf"
chrLen <- scanFaIndex(genomeFile)
chrominfo <- data.frame(chrom=as.character(seqnames(chrLen)),
length=width(chrLen),
is_circular=rep(FALSE, length(chrLen)))
txdb <- makeTxDbFromGFF(file=annotFile, format="gtf",
chrominfo=chrominfo,
dataSource="Ensembl",
organism="Homo sapiens")
## Import genomic features from the file as a GRanges object ... OK
## Prepare the 'metadata' data frame ... OK
## Make the TxDb object ... OK
promReg <- promoters(txdb, upstream=1000, downstream=500,
columns=c("gene_id","tx_id"))
gnId <- sapply(mcols(promReg)$gene_id, paste, collapse=",")
promRegSel <- promReg[ match(unique(gnId), gnId) ]
names(promRegSel) <- unique(gnId)
head(promRegSel)
## GRanges object with 6 ranges and 2 metadata columns:
## seqnames ranges strand | gene_id tx_id
## <Rle> <IRanges> <Rle> | <CharacterList> <integer>
## ENSG00000176022 chr1 31629-33128 + | ENSG00000176022 1
## ENSG00000186891 chr1 6452-7951 - | ENSG00000186891 2
## ENSG00000186827 chr1 14013-15512 - | ENSG00000186827 6
## ENSG00000078808 chr1 31882-33381 - | ENSG00000078808 9
## ENSG00000171863 chr2 1795-3294 + | ENSG00000171863 17
## ENSG00000252531 chr2 7160-8659 + | ENSG00000252531 26
## -------
## seqinfo: 3 sequences from an unspecified genome
Using promRegSel
object as query, we can now count the alignment per sample in
each of the promoter windows.
cnt <- qCount(proj1, promRegSel)
## counting alignments...done
cnt
## width Sample1 Sample2
## ENSG00000176022 1500 157 701
## ENSG00000186891 1500 22 5
## ENSG00000186827 1500 10 3
## ENSG00000078808 1500 73 558
## ENSG00000171863 1500 94 339
## ENSG00000252531 1500 59 9
## ENSG00000247886 1500 172 971
## ENSG00000254999 1500 137 389
## ENSG00000238642 1500 8 3
## ENSG00000134086 1500 9 18
## ENSG00000238345 1500 13 25
## ENSG00000134075 1500 7 3
The counts returned by qCount
are the raw number of alignments per sample and
region, without any normalization for the query region length, or the total number
of aligned reads in a sample. As expected, we can find H3K4me3 signal at promoters
of a subset of the genes with CpG island promoters, which we can visualize with help
of the Gviz package:
gr1 <- import("Sample1.wig.gz")
## Warning in asMethod(object): NAs introduced by coercion
gr2 <- import("Sample2.wig.gz")
## Warning in asMethod(object): NAs introduced by coercion
library(Gviz)
axisTrack <- GenomeAxisTrack()
dTrack1 <- DataTrack(range=gr1, name="Sample 1", type="h")
dTrack2 <- DataTrack(range=gr2, name="Sample 2", type="h")
txTrack <- GeneRegionTrack(txdb, name="Transcripts", showId=TRUE)
plotTracks(list(axisTrack, dTrack1, dTrack2, txTrack),
chromosome="chr3", extend.left=1000)
qProfile
Given a set of anchor positions in the genome, qProfile
calculates the number of
nearby alignments relative to the anchor position, for example to generate a average
profile. The neighborhood around anchor positions can be specified by the upstream
and downstream
argument. Alignments that are upstream of an anchor position will
have a negative relative position, and downstream alignments a positive. The anchor
positions are all aligned at position zero in the return value.
Anchor positions will be provided to qProfile
using the query
argument, which
takes a GRanges
object. The anchor positions correspond to start()
for regions
on +
or *
strands, and to end()
for regions on the -
strand. As mentioned
above, we expect H3K4me3 ChIP-seq alignments to be enriched around the transcript
start site of genes. We can therefore construct a suitable query
object from the
start sites of known genes. In the code below, start sites (start_codon
) are imported
from a .gtf
file with the help of the rtracklayer package. In addition,
strand
and gene_name
are also selected for import. Duplicated start sites, e.g. from
genes with multiple transcripts, are removed. Finally, all regions are given the name
TSS
, because qProfile
combines regions with identical names into a single profile.
library(rtracklayer)
annotationFile <- "extdata/hg19sub_annotation.gtf"
tssRegions <- import.gff(annotationFile, format="gtf",
feature.type="start_codon",
colnames="gene_name")
tssRegions <- tssRegions[!duplicated(tssRegions)]
names(tssRegions) <- rep("TSS", length(tssRegions))
head(tssRegions)
## GRanges object with 6 ranges and 1 metadata column:
## seqnames ranges strand | gene_name
## <Rle> <IRanges> <Rle> | <character>
## TSS chr1 6949-6951 - | TNFRSF18
## TSS chr1 14505-14507 - | TNFRSF4
## TSS chr1 29171-29173 - | SDF4
## TSS chr1 32659-32661 + | B3GALT6
## TSS chr2 3200-3202 + | RPS7
## TSS chr3 2386-2388 + | C3orf10
## -------
## seqinfo: 3 sequences from an unspecified genome; no seqlengths
Alignments around the tssRegions
coordinates are counted in a window defined by
the upstream
and downstream
arguments, which specify the number of bases to
include around each anchor position. For query
regions on +
or *
strands,
upstream refers to the left side of the anchor position (lower coordinates),
while for regions on the -
strand, upstream refers to the right side (higher coordinates).
The following example creates separate profiles for alignments on the same and
on the opposite strand of the regions in query
.
prS <- qProfile(proj1, tssRegions, upstream=3000, downstream=3000,
orientation="same")
## profiling alignments...done
prO <- qProfile(proj1, tssRegions, upstream=3000, downstream=3000,
orientation="opposite")
## profiling alignments...done
lapply(prS, "[", , 1:10)
## $coverage
## -3000 -2999 -2998 -2997 -2996 -2995 -2994 -2993 -2992 -2991
## 8 8 8 8 8 8 8 8 8 8
##
## $Sample1
## -3000 -2999 -2998 -2997 -2996 -2995 -2994 -2993 -2992 -2991
## 1 0 0 0 0 0 0 0 0 0
##
## $Sample2
## -3000 -2999 -2998 -2997 -2996 -2995 -2994 -2993 -2992 -2991
## 0 0 0 2 0 0 1 1 1 0
The counts returned by qProfile
are the raw number of alignments per sample and
position, without any normalization for the number of query regions or the total
number of alignments in a sample per position. To obtain the average number of alignments,
we divide the alignment counts by the number of query
regions that covered a given
relative position around the anchor sites. This coverage is available as the first
element in the return value. The shift between same and opposite strand alignments
is indicative for the average length of the sequenced ChIP fragments.
prCombS <- do.call("+", prS[-1]) /prS[[1]]
prCombO <- do.call("+", prO[-1]) /prO[[1]]
plot(as.numeric(colnames(prCombS)), filter(prCombS[1,], rep(1/100,100)),
type='l', xlab="Position relative to TSS", ylab="Mean no. of alignments")
lines(as.numeric(colnames(prCombO)), filter(prCombO[1,], rep(1/100,100)),
type='l', col="red")
legend(title="strand", legend=c("same as query","opposite of query"),
x="topleft", col=c("black","red"), lwd=1.5, bty="n", title.adj=0.1)
QuasR also allows using of BSgenome packages instead
of a fasta
file as reference genome (see section 5.3).
To use a BSgenome, the genome
argument of qAlign
is set to a
string matching the name of a BSgenome package, for example
"BSgenome.Hsapiens.UCSC.hg19"
. If that package is not already installed, qAlign
will check if it is available from http://bioconductor.org/ and download it automatically.
The corresponding alignment index will be saved as a new package, named after the
original BSgenome package and the aligner used to build the index,
for example BSgenome.Hsapiens.UCSC.hg19.Rbowtie
.
The code example below illustrates the use of a BSgenome reference genome for the same example data as above. Running it for the first time will take several hours in order to build the aligner index:
file.copy(system.file(package="QuasR", "extdata"), ".", recursive=TRUE)
sampleFile <- "extdata/samples_chip_single.txt"
auxFile <- "extdata/auxiliaries.txt"
available.genomes() # list available genomes
genomeName <- "BSgenome.Hsapiens.UCSC.hg19"
proj1 <- qAlign(sampleFile, genome=genomeName, auxiliaryFile=auxFile)
proj1
In QuasR, an analysis workflow for an RNA-seq dataset is very similar
to the one described above for a ChIP-seq experiment. The major difference is that
here reads are aligned using qAlign(..., splicedAlignment=TRUE, aligner="Rhisat2")
,
which will cause qAlign
to align reads with the HISAT2
aligner (Kim, Langmead, and Salzberg 2015) (via the
Rhisat2 package), rather than with bowtie
(Langmead et al. 2009). Before the
Rhisat2 package was available (introduced in Bioconductor 3.9),
qAlign(... splicedAlignment=TRUE)
aligned reads using SpliceMap
(Au et al. 2010), which
is not recommended now but still possible in order to reproduce old results.
Spliced paired-end alignments are also supported; the splicedAlignment
argument can be freely combined with the paired
argument. In addition, HISAT2
also allows the specification of known splice sites, which can help in the read
alignment. This is done by specifying the argument geneAnnotation
in qAlign()
,
to either a .gtf
file or a sqlite
database generated by exporting a TxDb
object.
We start the example workflow by copying the example data files into the current
working directly, into a subfolder called "extdata"
, and then create spliced
alignments using qAlign
:
file.copy(system.file(package="QuasR", "extdata"), ".", recursive=TRUE)
## [1] TRUE
sampleFile <- "extdata/samples_rna_paired.txt"
genomeFile <- "extdata/hg19sub.fa"
proj2 <- qAlign(sampleFile, genome=genomeFile, splicedAlignment=TRUE, aligner="Rhisat2")
## alignment files missing - need to:
## create alignment index for the genome
## create 2 genomic alignment(s)
## Creating an Rhisat2 index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub.fa
## Finished creating index
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nebbiolo1: 1
## Performing genomic alignments for 2 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293b473e526c.txt
## Genomic alignments have been created successfully
proj2
## Project: qProject
## Options : maxHits : 1
## paired : fr
## splicedAlignment: TRUE
## bisulfite : no
## snpFile : none
## geneAnnotation : none
## Aligner : Rhisat2 v1.8.0 (parameters: -k 2)
## Genome : /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vign.../hg19sub.fa (file)
##
## Reads : 2 pairs of files, 2 samples (fastq format):
## 1. rna_1_1.fq.bz2 rna_1_2.fq.bz2 Sample1 (phred33)
## 2. rna_2_1.fq.bz2 rna_2_2.fq.bz2 Sample2 (phred33)
##
## Genome alignments: directory: same as reads
## 1. rna_1_1_d293b12cdea32.bam
## 2. rna_2_1_d293b1c40a356.bam
##
## Aux. alignments: none
Aligning the reads with splicedAlignment=TRUE
will allow to also align reads
that cross exon junctions, and thus have a large deletion (the intron)
relative to the reference genome.
proj2unspl <- qAlign(sampleFile, genome=genomeFile,
splicedAlignment=FALSE)
## alignment files missing - need to:
## create 2 genomic alignment(s)
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nebbiolo1: 1
## Performing genomic alignments for 2 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293b1b0e6272.txt
## Genomic alignments have been created successfully
alignmentStats(proj2)
## seqlength mapped unmapped
## Sample1:genome 95000 5961 6
## Sample2:genome 95000 5914 2
alignmentStats(proj2unspl)
## seqlength mapped unmapped
## Sample1:genome 95000 2258 3746
## Sample2:genome 95000 2652 3348
As with ChIP-seq experiments, qCount
is used to quantify alignments. For
quantification of gene or exon expression levels, qCount
can be called with a
query of type TxDb
, such as the one we constructed in the ChIP-seq workflow above
from a .gtf
file. The argument reportLevel
can be used to control if annotated
exonic regions should be quantified independently (reportLevel="exon"
) or
non-redundantly combined per gene (reportLevel="gene"
):
geneLevels <- qCount(proj2, txdb, reportLevel="gene")
## extracting gene regions from TxDb...done
## counting alignments...done
## collapsing counts by query name...done
exonLevels <- qCount(proj2, txdb, reportLevel="exon")
## extracting exon regions from TxDb...done
## counting alignments...done
head(geneLevels)
## width Sample1 Sample2
## ENSG00000078808 4697 710 1083
## ENSG00000134075 589 1173 1303
## ENSG00000134086 4213 279 295
## ENSG00000171863 5583 2924 2224
## ENSG00000176022 2793 62 344
## ENSG00000186827 1721 37 8
head(exonLevels)
## width Sample1 Sample2
## 1 2793 62 344
## 10 187 3 0
## 11 307 3 0
## 12 300 11 2
## 13 493 19 2
## 14 129 7 0
The values returned by qCount
are the number of alignments. Sometimes it is
required to normalize for the length of query regions, or the size of the libraries.
For example, gene expression levels in the form of RPKM values (reads per kilobase
of transcript and million mapped reads) can be obtained as follows:
geneRPKM <- t(t(geneLevels[,-1] /geneLevels[,1] *1000)
/colSums(geneLevels[,-1]) *1e6)
geneRPKM
## Sample1 Sample2
## ENSG00000078808 21350 31786
## ENSG00000134075 281287 304966
## ENSG00000134086 9354 9653
## ENSG00000171863 73974 54915
## ENSG00000176022 3135 16979
## ENSG00000186827 3037 641
## ENSG00000186891 2681 201
## ENSG00000238345 0 0
## ENSG00000238642 0 0
## ENSG00000247886 0 0
## ENSG00000252531 6066 1691
## ENSG00000254999 213296 222826
Please note the RPKM values in our example are higher than what you would usually get for a real RNA-seq dataset. The values here are artificially scaled up because our example data contains reads only for a small number of genes.
Exon-exon junctions can be quantified by setting reportLevel="junction"
. In this
case, qCount
will ignore the query
argument and scan all alignments for any
detected splices, which are returned as a GRanges
object: The region start and
end coordinates correspond to the first and last bases of the intron, and the
counts are returned in the mcols()
of the GRanges
object. Alignments that
are identically spliced but reside on opposite strands will be quantified separately.
In an unstranded RNA-seq experiment, this may give rise to two separate counts
for the same intron, one each for the supporting alignments on plus and minus
strands.
exonJunctions <- qCount(proj2, NULL, reportLevel="junction")
## counting junctions...done
exonJunctions
## GRanges object with 46 ranges and 2 metadata columns:
## seqnames ranges strand | Sample1 Sample2
## <Rle> <IRanges> <Rle> | <numeric> <numeric>
## [1] chr1 12213-12321 + | 3 0
## [2] chr1 13085-13371 - | 1 0
## [3] chr1 18069-18837 + | 9 16
## [4] chr1 18069-18837 - | 7 4
## [5] chr1 18185-18837 - | 2 0
## ... ... ... ... . ... ...
## [42] chr1 14166-14362 + | 0 1
## [43] chr1 19308-23623 - | 0 2
## [44] chr1 29327-32271 + | 0 2
## [45] chr1 29327-32271 - | 0 1
## [46] chr3 2504-5589 - | 0 3
## -------
## seqinfo: 3 sequences from an unspecified genome; no seqlengths
About half of the exon-exon junctions detected in this sample dataset correspond to known introns; they tend to be the ones with higher coverage:
knownIntrons <- unlist(intronsByTranscript(txdb))
isKnown <- overlapsAny(exonJunctions, knownIntrons, type="equal")
table(isKnown)
## isKnown
## FALSE TRUE
## 25 21
tapply(rowSums(as.matrix(mcols(exonJunctions))),
isKnown, summary)
## $`FALSE`
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## 1 3 7 47 31 340
##
## $`TRUE`
## Min. 1st Qu. Median Mean 3rd Qu. Max.
## 1.0 2.0 16.0 50.6 91.0 210.0
When quantifying exon junctions, only spliced alignments will be included in the
quantification. It is also possible to only include unspliced alignments in the
quantification, for example when counting exon body alignments that complement the
exon junction alignments. This can be done using the includeSpliced
argument
from qCount
:
exonBodyLevels <- qCount(proj2, txdb, reportLevel="exon", includeSpliced=FALSE)
## extracting exon regions from TxDb...done
## counting alignments...done
summary(exonLevels - exonBodyLevels)
## width Sample1 Sample2
## Min. :0 Min. : 0 Min. : 0
## 1st Qu.:0 1st Qu.: 0 1st Qu.: 0
## Median :0 Median : 3 Median : 1
## Mean :0 Mean : 42 Mean : 35
## 3rd Qu.:0 3rd Qu.: 48 3rd Qu.: 50
## Max. :0 Max. :818 Max. :647
## collecting quality control data
## creating QC plots
Expression profiling of miRNAs differs only slightly from the profiling of mRNAs. There are a few details that need special care, which are outlined in this section.
Again, we start the example workflow by copying the example data files into the
current working directly, into a subfolder called "extdata"
.
file.copy(system.file(package="QuasR", "extdata"), ".", recursive=TRUE)
## [1] TRUE
As a next step, we need to remove library adapter sequences from short RNA reads. Most sequencing experiments generate reads that are longer than the average length of a miRNA (22nt). Therefore, the read sequence will run through the miRNA into the library adapter sequence and would not match when aligned in full to the reference genome.
We can remove those adapter sequences using preprocessReads
(see section
7.1 for more details), which for each input sequence file will
generate an output sequence file containing appropriately truncated sequences.
In the example below, we get the input sequence filenames from sampleFile
, and
also prepare an updated sampleFile2
that refers to newly generated processed
sequence files:
# prepare sample file with processed reads filenames
sampleFile <- file.path("extdata", "samples_mirna.txt")
sampleFile
## [1] "extdata/samples_mirna.txt"
sampleFile2 <- sub(".txt", "_processed.txt", sampleFile)
sampleFile2
## [1] "extdata/samples_mirna_processed.txt"
tab <- read.delim(sampleFile, header=TRUE, as.is=TRUE)
tab
## FileName SampleName
## 1 mirna_1.fa miRNAs
tab2 <- tab
tab2$FileName <- sub(".fa", "_processed.fa", tab$FileName)
write.table(tab2, sampleFile2, sep="\t", quote=FALSE, row.names=FALSE)
tab2
## FileName SampleName
## 1 mirna_1_processed.fa miRNAs
# remove adapters
oldwd <- setwd(dirname(sampleFile))
res <- preprocessReads(tab$FileName,
tab2$FileName,
Rpattern="TGGAATTCTCGGGTGCCAAGG")
## filtering mirna_1.fa
res
## mirna_1.fa
## totalSequences 1000
## matchTo5pAdapter 0
## matchTo3pAdapter 1000
## tooShort 0
## tooManyN 0
## lowComplexity 0
## totalPassed 1000
setwd(oldwd)
The miRNA reads in mirna_1.fa
are by the way synthetic sequences and do not
correspond to any existing miRNAs. As you can see above from the return value of
preprocessReads
, all reads matched to the 3’-adapter and were therefore truncated,
reducing their length to roughly the expected 22nt:
# get read lengths
library(Biostrings)
oldwd <- setwd(dirname(sampleFile))
lens <- fasta.seqlengths(tab$FileName, nrec=1e5)
lens2 <- fasta.seqlengths(tab2$FileName, nrec=1e5)
setwd(oldwd)
# plot length distribution
lensTab <- rbind(raw=tabulate(lens,50),
processed=tabulate(lens2,50))
colnames(lensTab) <- 1:50
barplot(lensTab/rowSums(lensTab)*100,
xlab="Read length (nt)", ylab="Percent of reads")
legend(x="topleft", bty="n", fill=gray.colors(2), legend=rownames(lensTab))
Next, we create alignments using qAlign
. In contrast to the general RNA-seq workflow
(section 6.2), alignment time can be reduced by
using the default unspliced alignment (splicedAlignment=FALSE
). Importantly, we
need to set maxHits=50
or similar to also align reads that perfectly match the
genome multiple times. This is required because of the miRNAs that are encoded by
multiple genes. Reads from such miRNAs would not be aligned and thus their expression
would be underestimated if using the default maxHits=1
. An example of such a
multiply-encoded miRNA is mmu-miR-669a-5p, which has twelve exact copies in the
mm10 genome assembly according to mirBase19.
proj3 <- qAlign(sampleFile2, genomeFile, maxHits=50)
## alignment files missing - need to:
## create 1 genomic alignment(s)
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nebbiolo1: 1
## Performing genomic alignments for 1 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293b3418f288.txt
## Genomic alignments have been created successfully
alignmentStats(proj3)
## seqlength mapped unmapped
## miRNAs:genome 95000 1000 0
A more detailed picture of the experiments’ quality can be obtained using
qQCReport(proj3, "qcreport.pdf")
or similar (see also section 7.4).
As with other experiment types, miRNAs are quantified using qCount
. For this
purpose, we first construct a query GRanges
object with the genomic locations
of mature miRNAs. The locations can be obtained from the mirbase.db
package, or directly from the species-specific gff files provided by the mirBase
database (e.g. (ftp://mirbase.org/pub/mirbase/19/genomes/mmu.gff3)). For the purpose
of this example, the QuasR package provides a small gff file
("mirbaseXX_qsr.gff3"
) that is formatted as the ones available from mirBase.
The gff file contains both the locations of pre-miRNAs (hairpin precursors), as
well as mature miRNAs. The two can be discriminated by their "type"
:
mirs <- import("extdata/mirbaseXX_qsr.gff3")
names(mirs) <- mirs$Name
preMirs <- mirs[ mirs$type=="miRNA_primary_transcript" ]
matureMirs <- mirs[ mirs$type=="miRNA" ]
Please note that the name attribute of the GRanges
object must be set appropriately,
so that qCount
can identify a single mature miRNA sequence that is encoded by
multiple loci (see below) by their identical names. In this example, there are no
multiply-encoded mature miRNAs, but in a real sample, you can detect them for
example with table(names(mirs))
.
The preMirs
and matureMirs
could now be used as query
in qCount
. In
practise however, miRNA seem to not always be processed with high accuracy.
Many miRNA reads that start one or two bases earlier or later can be observed
in real data, and also their length may vary for a few bases. This is the case
for the synthetic miRNAs used in this example, whose lengthes and start positions
have been sampled from a read data set:
library(Rsamtools)
alns <- scanBam(alignments(proj3)$genome$FileName,
param=ScanBamParam(what=scanBamWhat(), which=preMirs[1]))[[1]]
alnsIR <- IRanges(start=alns$pos - start(preMirs), width=alns$qwidth)
mp <- barplot(as.vector(coverage(alnsIR)), names.arg=1:max(end(alnsIR)),
xlab="Relative position in pre-miRNA",
ylab="Alignment coverage")
rect(xleft=mp[start(matureMirs)-start(preMirs)+1,1], ybottom=-par('cxy')[2],
xright=mp[end(matureMirs)-start(preMirs)+1,1], ytop=0,
col="#CCAA0088", border=NA, xpd=NA)
By default, qCount
will count alignments that have their 5’-end within the query
region (see selectReadPosition
argument). The 5’-end correspond to the lower
(left) coordinate for alignments on the plus strand, and to the higher (right)
coordinate for alignments on the minus strand. In order not to miss miRNAs that
have a couple of extra or missing bases, we therefore construct a query window
around the 5’-end of each mature miRNA, by adding three bases up- and downstream:
matureMirsExtended <- resize(matureMirs, width=1L, fix="start") + 3L
The resulting extended query is then used to quantify mature miRNAs. Multiple-encoded
miRNAs will be represented by multiple ranges in matureMirs
and matureMirsExtended
,
which have identical names. qCount
will automatically sum all alignments from
any of those regions and return a single number per sample and unique miRNA name.
# quantify mature miRNAs
cnt <- qCount(proj3, matureMirsExtended, orientation="same")
## counting alignments...done
cnt
## width miRNAs
## qsr-miR-9876-5p 7 13
## qsr-miR-9876-3p 7 984
# quantify pre-miRNAs
cnt <- qCount(proj3, preMirs, orientation="same")
## counting alignments...done
cnt
## width miRNAs
## qsr-mir-9876 75 1000
Sequencing of bisulfite-converted genomic DNA allows detection of methylated
cytosines, which in mammalian genomes typically occur in the context of CpG
dinucleotides. The treatment of DNA with bisulfite induces deamination of
non-methylated cytosines, converting them to uracils. Sequencing and aligning
of such bisulfite-converted DNA results in C-to-T mismatches. Both alignment of
converted reads, as well as the interpretation of the alignments for calculation
of methylation levels require specific approaches and are supported in
QuasR by qAlign
(bisulfite
argument, section 7.2) and
qMeth
(section 7.9), respectively.
We start the analysis by copying the example data files into the current working
directly, into a subfolder called "extdata"
. Then, bisulfite-specific alignment
is selected in qAlign
by setting bisulfite
to "dir"
for a directional
experiment, or to "undir"
for an undirectional Bis-seq experiment:
file.copy(system.file(package="QuasR", "extdata"), ".", recursive=TRUE)
## [1] TRUE
sampleFile <- "extdata/samples_bis_single.txt"
genomeFile <- "extdata/hg19sub.fa"
proj4 <- qAlign(sampleFile, genomeFile, bisulfite="dir")
## alignment files missing - need to:
## create alignment index for the genome
## create 1 genomic alignment(s)
## Creating an RbowtieCtoT index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub.fa
## Finished creating index
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nebbiolo1: 1
## Performing genomic alignments for 1 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293b4344e06a.txt
## Genomic alignments have been created successfully
proj4
## Project: qProject
## Options : maxHits : 1
## paired : no
## splicedAlignment: FALSE
## bisulfite : dir
## snpFile : none
## geneAnnotation : none
## Aligner : Rbowtie v1.32.0 (parameters: -k 2 --best --strata -v 2)
## Genome : /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vign.../hg19sub.fa (file)
##
## Reads : 1 file, 1 sample (fasta format):
## 1. bis_1_1.fa.bz2 Sample1
##
## Genome alignments: directory: same as reads
## 1. bis_1_1_d293b5604e1e3.bam
##
## Aux. alignments: none
The resulting alignments are not different from those of non-Bis-seq experiments,
apart from the fact that they may contain many C-to-T (or A-to-G) mismatches that
are not counted as mismatches when aligning the reads. The number of alignments
in specific genomic regions could be quantified using qCount
as with ChIP-seq
or RNA-seq experiments. For quantification of methylation the qMeth
function
is used:
meth <- qMeth(proj4, mode="CpGcomb", collapseBySample=TRUE)
meth
## GRanges object with 3110 ranges and 2 metadata columns:
## seqnames ranges strand | Sample1_T Sample1_M
## <Rle> <IRanges> <Rle> | <integer> <integer>
## [1] chr1 19-20 * | 1 1
## [2] chr1 21-22 * | 1 1
## [3] chr1 54-55 * | 3 1
## [4] chr1 57-58 * | 3 0
## [5] chr1 80-81 * | 6 5
## ... ... ... ... . ... ...
## [3106] chr3 44957-44958 * | 8 7
## [3107] chr3 44977-44978 * | 5 3
## [3108] chr3 44981-44982 * | 4 3
## [3109] chr3 44989-44990 * | 1 1
## [3110] chr3 44993-44994 * | 1 1
## -------
## seqinfo: 3 sequences from an unspecified genome
By default, qMeth
quantifies methylation for all cytosines in CpG contexts,
combining the data from plus and minus strands (mode="CpGcomb"
). The results
are returned as a GRanges
object with coordinates of each CpG, and two metadata
columns for each input sequence file in the qProject
object. These two columns
contain the total number of aligned reads that overlap a given CpG (C-to-C matches
or C-to-T mismatches, suffix _T
in the column name), and the number of read
alignments that had a C-to-C match at that position (methylated events, suffix _M
).
Independent of the number of alignments, the returned object will list all CpGs
in the target genome including the ones that have zero coverage, unless you set
keepZero=FALSE
:
chrs <- readDNAStringSet(genomeFile)
sum(vcountPattern("CG",chrs))
## [1] 3110
length(qMeth(proj4))
## [1] 3110
length(qMeth(proj4, keepZero=FALSE))
## [1] 2929
The fraction methylation can easily be obtained as the ratio between _M
and
_T
columns:
percMeth <- mcols(meth)[,2] *100 /mcols(meth)[,1]
summary(percMeth)
## Min. 1st Qu. Median Mean 3rd Qu. Max. NA's
## 0.0 75.0 90.9 75.4 100.0 100.0 181
axisTrack <- GenomeAxisTrack()
dTrack1 <- DataTrack(range=gr1, name="H3K4me3", type="h")
dTrack2 <- DataTrack(range=meth, data=percMeth,
name="Methylation", type="p")
txTrack <- GeneRegionTrack(txdb, name="Transcripts", showId=TRUE)
plotTracks(list(axisTrack, dTrack1, dTrack2, txTrack),
chromosome="chr3", extend.left=1000)
If qMeth
is called without a query
argument, it will by default return
methylation states for each C or CpG in the genome. Using a query
argument it
is possible to restrict the analysis to specific genomic regions, and if using
in addition collapseByQueryRegion=TRUE
, the single base methylation states will
further be combined for all C’s that are contained in the same query region:
qMeth(proj4, query=GRanges("chr1",IRanges(start=31633,width=2)),
collapseBySample=TRUE)
## GRanges object with 1 range and 2 metadata columns:
## seqnames ranges strand | Sample1_T Sample1_M
## <Rle> <IRanges> <Rle> | <integer> <integer>
## [1] chr1 31633-31634 * | 10 2
## -------
## seqinfo: 3 sequences from an unspecified genome
qMeth(proj4, query=promRegSel, collapseByQueryRegion=TRUE,
collapseBySample=TRUE)
## GRanges object with 12 ranges and 2 metadata columns:
## seqnames ranges strand | Sample1_T Sample1_M
## <Rle> <IRanges> <Rle> | <numeric> <numeric>
## [1] chr1 31629-33128 + | 426 74
## [2] chr1 6452-7951 - | 388 244
## [3] chr1 14013-15512 - | 627 560
## [4] chr1 31882-33381 - | 522 232
## [5] chr2 1795-3294 + | 997 539
## ... ... ... ... . ... ...
## [8] chr3 1276-2775 + | 715 253
## [9] chr3 19069-20568 + | 253 204
## [10] chr3 26692-28191 + | 934 818
## [11] chr3 26834-28333 + | 934 777
## [12] chr3 13102-14601 - | 307 287
## -------
## seqinfo: 3 sequences from an unspecified genome
Finally, qMeth
allows the retrieval of methylation states for individual molecules
(per alignment). This is done by using a query
containing a single genomic region
(typically small, such as a PCR amplicon) and setting reportLevel="alignment"
.
In that case, the return value of qMeth
will be a list (over samples) of lists
(with four elements giving the identities of alignment, C nucleotide, strand and
the methylation state). See the documentation of qMeth
for more details.
All experiment types supported by QuasR (ChIP-seq, RNA-seq and
Bis-seq; only alignments to the genome, but not to auxiliaries) can also be analyzed
in an allele-specific manner. For this, a file containing genomic location and
the two alleles of known sequence polymorphisms has to be provided to the snpFile
argument of qAlign
. The file is in tab-delimited text format without a header
and contains four columns with chromosome name, position, reference allele and
alternative allele.
Below is an example of a SNP file, also available from system.file(package="QuasR", "extdata", "hg19sub_snp.txt")
:
chr1 3199 C T chr1 3277 C T chr1 4162 C T chr1 4195 C T ...
For a given locus, either reference or alternative allele may but does not have
to be identical to the sequence of the reference genome (genomeFile
in this case).
To avoid an alignment bias, all reads are aligned separately to each of the two
new genomes, which QuasR generates by injecting the SNPs listed
in snpFile
into the reference genome. Finally, the two alignment files are combined,
only retaining the best alignment for each read. While this procedure takes more
than twice as long as aligning against a single genome, it has the advantage to
correctly align reads even in regions of high SNP density and has been shown to
produce more accurate results.
While combining alignments, each read is classified into one of three groups (stored
in the bam
files under the XV
tag):
Using these alignment classifications, the qCount
and qMeth
functions will
produce three counts instead of a single count; one for each class. The column
names will be suffixed by _R
, _U
and _A
.
The examples below use data provided with the QuasR package, which
is first copied to the current working directory, into a subfolder called "extdata"
:
file.copy(system.file(package="QuasR", "extdata"), ".", recursive=TRUE)
## [1] TRUE
The example below aligns the same reads that were also used in the ChIP-seq workflow
(section 6.1), but this time using a snpFile
:
sampleFile <- "extdata/samples_chip_single.txt"
genomeFile <- "extdata/hg19sub.fa"
snpFile <- "extdata/hg19sub_snp.txt"
proj1SNP <- qAlign(sampleFile, genome=genomeFile, snpFile=snpFile)
## alignment files missing - need to:
## create alignment index for the genome
## create 2 genomic alignment(s)
## Reading and processing the SNP file: /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt
## Creating the genome fasta file containing the SNPs: /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.R.fa
## Creating the genome fasta file containing the SNPs: /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.A.fa
## Creating a .fai file for the snp genome: /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.R.fa
## Creating a .fai file for the snp genome: /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.A.fa
## Creating an Rbowtie index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.R.fa
## Finished creating index
## Creating an Rbowtie index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.A.fa
## Finished creating index
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nebbiolo1: 1
## Performing genomic alignments for 2 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293b3d40a548.txt
## Genomic alignments have been created successfully
proj1SNP
## Project: qProject
## Options : maxHits : 1
## paired : no
## splicedAlignment: FALSE
## bisulfite : no
## snpFile : /tmp/RtmpdrDuWc/Rbuildcf76f65.../hg19sub_snp.txt
## geneAnnotation : none
## Aligner : Rbowtie v1.32.0 (parameters: -k 2 --best --strata -v 2)
## Genome : /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vign.../hg19sub.fa (file)
##
## Reads : 2 files, 2 samples (fastq format):
## 1. chip_1_1.fq.bz2 Sample1 (phred33)
## 2. chip_2_1.fq.bz2 Sample2 (phred33)
##
## Genome alignments: directory: same as reads
## 1. chip_1_1_d293b6824f7bf.bam
## 2. chip_2_1_d293b305e4bf1.bam
##
## Aux. alignments: none
Instead of one count per promoter region and sample, qCount
now returns three
(promRegSel
was generated in the ChIP-seq example workflow):
head(qCount(proj1, promRegSel))
## counting alignments...done
## width Sample1 Sample2
## ENSG00000176022 1500 157 701
## ENSG00000186891 1500 22 5
## ENSG00000186827 1500 10 3
## ENSG00000078808 1500 73 558
## ENSG00000171863 1500 94 339
## ENSG00000252531 1500 59 9
head(qCount(proj1SNP, promRegSel))
## counting alignments...done
## width Sample1_R Sample1_U Sample1_A Sample2_R Sample2_U
## ENSG00000176022 1500 0 133 0 0 559
## ENSG00000186891 1500 4 16 0 0 5
## ENSG00000186827 1500 2 8 0 0 2
## ENSG00000078808 1500 0 59 0 0 432
## ENSG00000171863 1500 4 78 0 8 263
## ENSG00000252531 1500 3 50 2 0 6
## Sample2_A
## ENSG00000176022 0
## ENSG00000186891 0
## ENSG00000186827 0
## ENSG00000078808 0
## ENSG00000171863 0
## ENSG00000252531 0
The example below illustrates use of a snpFile
for Bis-seq experiments. Similarly
as for qCount
, the count types are labeled by R
, U
and A
. These labels are
added to the total and methylated column suffixes _T
and _M
, resulting in
a total of six instead of two counts per feature and sample:
sampleFile <- "extdata/samples_bis_single.txt"
genomeFile <- "extdata/hg19sub.fa"
proj4SNP <- qAlign(sampleFile, genomeFile,
snpFile=snpFile, bisulfite="dir")
## alignment files missing - need to:
## create alignment index for the genome
## create 1 genomic alignment(s)
## Creating an RbowtieCtoT index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.R.fa
## Finished creating index
## Creating an RbowtieCtoT index for /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/extdata/hg19sub_snp.txt.hg19sub.fa.A.fa
## Finished creating index
## Testing the compute nodes...OK
## Loading QuasR on the compute nodes...OK
## Available cores:
## nebbiolo1: 1
## Performing genomic alignments for 1 samples. See progress in the log file:
## /tmp/RtmpdrDuWc/Rbuildcf76f65a351c2/QuasR/vignettes/QuasR_log_d293b43cc5a4.txt
## Genomic alignments have been created successfully
head(qMeth(proj4SNP, mode="CpGcomb", collapseBySample=TRUE))
## GRanges object with 6 ranges and 6 metadata columns:
## seqnames ranges strand | Sample1_TR Sample1_MR Sample1_TU Sample1_MU
## <Rle> <IRanges> <Rle> | <integer> <integer> <integer> <integer>
## [1] chr1 19-20 * | 0 0 1 1
## [2] chr1 21-22 * | 0 0 1 1
## [3] chr1 54-55 * | 0 0 3 1
## [4] chr1 57-58 * | 0 0 3 0
## [5] chr1 80-81 * | 0 0 6 5
## [6] chr1 103-104 * | 0 0 6 5
## Sample1_TA Sample1_MA
## <integer> <integer>
## [1] 0 0
## [2] 0 0
## [3] 0 0
## [4] 0 0
## [5] 0 0
## [6] 0 0
## -------
## seqinfo: 3 sequences from an unspecified genome
Please refer to the QuasR reference manual or the function
documentation (e.g. using ?qAlign
) for a complete description of QuasR
functions. The descriptions provided below are meant to give an overview over all
functions and summarize the purpose of each one.
preprocessReads
The preprocessReads
function can be used to prepare the input sequences before
alignment to the reference genome, for example to filter out low quality reads
unlikely to produce informative alignments. When working with paired-end experiments,
the paired reads are expected to be contained in identical order in two separate
files. For this reason, both reads of a pair are filtered out if any of the two
reads fulfills the filtering criteria. The following types of filtering tasks
can be performed (in the order as listed):
trimLRPatterns
from the Biostrings package (Pages et al., n.d.).nBases
N
bases, are shorter than minLength
or
have a dinucleotide complexity of less than complexity
-times the average
complexity of the human genome sequence).The dinucleotide complexity is calculated in bits as Shannon entropy using the following formula \(-\sum_i f_i \cdot \log_2 f_i\), where \(f_i\) is the frequency of dinucleotide \(i\) (\(i=1, 2, ..., 16\)).
qAlign
qAlign
is the function that generates alignment files in bam
format, for all
input sequence files listed in sampleFile
(see section 5.1),
against the reference genome (genome
argument), and for reads that do not match
to the reference genome, against one or several auxiliary target sequences
(auxiliaryFile
, see section 5.2).
The reference genome can be provided either as a fasta
sequence file or as a
BSgenome
package name (see section 5.3). If a BSgenome
package is not found in the installed packages but available from Bioconductor,
it will be automatically downloaded.
The alignment program is set by aligner
, and parameters by maxHits
, paired
,
splicedAlignment
and alignmentParameter
. Currently, aligner
can only be set
to "Rbowtie"
, which is a wrapper for bowtie (Langmead et al. 2009) and SpliceMap (Au et al. 2010),
or "Rhisat2"
, which is a wrapper for HISAT2 (Kim, Langmead, and Salzberg 2015).
When aligner="Rbowtie"
, SpliceMap will be used if splicedAlignment=TRUE
(not recommended anymore except for reproducing older analyses). However, it is
recommended to create spliced alignment using splicedAlignment=TRUE, aligner="Rhisat2"
,
which will use the HISAT2 aligner and typically leads to more sensistive
alignments and shorter alignment times compared to SpliceMap. The alignment strategy
is furthermore affected by the parameters snpFile
(alignments to variant genomes containing
sequence polymorphisms) and bisulfite
(alignment of bisulfite-converted reads).
Finally, clObj
can be used to enable parallelized alignment, sorting and
conversion to bam
format.
For each input sequence file listed in sampleFile
, one bam
file with alignments
to the reference genome will be generated, and an additional one for each auxiliary
sequence file listed in auxiliaryFile
. By default, these bam
files are stored
at the same location as the sequence files, unless a different location is specified
under alignmentsDir
. If compatible alignment files are found at this location,
they will not be regenerated, which allows re-use of the same sequencing samples
in multiple analysis projects by listing them in several project-specific sampleFile
s.
The alignment process produces temporary files, such as decompressed input sequence
files or raw alignment files before conversion to bam
format, which can be several
times the size of the input sequence files. These temporary files are stored in the
directory specified by cacheDir
, which defaults to the R process temporary
directory returned by tempdir()
. The location of tempdir()
can be set using
environment variables (see ?tempdir
).
qAlign
returns a qProject
object that contains all file names and paths, as
well as all alignment parameters necessary for further analysis (see section
7.3 for methods to access the information contained in a qProject
object).
qProject
classThe qProject
objects are returned by qAlign
and contain all information about
a sequencing experiment needed for further analysis. It is the main argument passed
to the functions that start with a q letter, such as qCount
, qQCReport
and
qExportWig
. Some information inside of a qProject
object can be accessed by
specific methods (in the examples below, x
is a qProject
object):
length(x)
gets the number of input files.genome(x)
gets the reference genome as a character(1)
. The type of genome
is stored as an attribute in attr(genome(x),"genomeFormat")
: "BSgenome"
indicates that genome(x)
refers to the name of a BSgenome package,
"file"
indicates that it contains the path and file name of a genome in
fasta
format.auxiliaries(x)
gets a data.frame
with auxiliary target sequences. The
data.frame
has one row per auxiliary target file, and two columns “FileName”
and “AuxName”.alignments(x)
gets a list with two elements "genome"
and "aux"
.
"genome"
contains a data.frame
with length(x)
rows and two columns
"FileName"
(containing the path to bam files with genomic alignments) and
"SampleName"
. "aux"
contains a data.frame
with one row per auxiliary
target file (with auxiliary names as row names), and length(x)
columns
(one per input sequence file).x[i]
returns a qProject
object instance with i
input files, where i
can be an NA
-free logical, numeric, or character vector.qQCReport
The qQCReport
function samples a random subset of sequences and alignments from
each sample or input file and generates a series of diagnostic plots for estimating
data quality. The available plots vary depending on the types of available input
(fasta, fastq, bam files or qProject
object; paired-end or single-end). The plots
below show the currently available plots as produced by the ChIP-seq example in
section 6.1 (except for the fragment size distributions which are based
on an unspliced alignment of paired-end RNA seq reads):
Quality score boxplot shows the distribution of base quality values as a box plot for each position in the input sequence. The background color (green, orange or red) indicates ranges of high, intermediate and low qualities.
Nucleotide frequency plot shows the frequency of A, C, G, T and N bases by position in the read.
Duplication level plot shows for each sample the fraction of reads observed at different duplication levels (e.g. once, two-times, three-times, etc.). In addition, the most frequent sequences are listed.
Mapping statistics shows fractions of reads that were (un)mappable to the reference genome.
Library complexity shows fractions of unique read(-pair) alignment positions. Please note that this measure is not independent from the total number of reads in a library, and is best compared between libraries of similar sizes.
Mismatch frequency shows the frequency and position (relative to the read sequence) of mismatches in the alignments against the reference genome.
Mismatch types shows the frequency of read bases that caused mismatches in the alignments to the reference genome, separately for each genome base.
Fragment size shows the distribution of fragment sizes inferred from aligned
read pairs.
alignmentStats
alignmentStats
is comparable to the idxstats
function from Samtools; it returns
the size of the target sequence, as well as the number of mapped and unmapped reads
that are contained in an indexed bam
file. The function works for arguments of type
qProject
, as well as on a string with one or several bam
file names. There is
however a small difference in the two that is illustrated in the following example,
which uses the qProject
object from the ChIP-seq workflow:
# using bam files
alignmentStats(alignments(proj1)$genome$FileName)
## seqlength mapped unmapped
## chip_1_1_d293b270b22a.bam 95000 2339 258
## chip_2_1_d293b42b40683.bam 95000 3609 505
alignmentStats(unlist(alignments(proj1)$aux))
## seqlength mapped unmapped
## chip_1_1_d293b71ddb7c7.bam 5386 251 0
## chip_2_1_d293b2fd9724b.bam 5386 493 0
# using a qProject object
alignmentStats(proj1)
## seqlength mapped unmapped
## Sample1:genome 95000 2339 258
## Sample2:genome 95000 3609 505
## Sample1:phiX174 5386 251 7
## Sample2:phiX174 5386 493 12
If calling alignmentStats
on the bam files directly as in the first two expressions
of the above example, the returned numbers correspond exactly to what you would obtain
by the idxstats
function from Samtools, only that the latter would report them
separately for each target sequence, while alignmentStats
sums them for each
bam
file. These numbers correctly state that there are zero unmapped reads in
the auxiliary bam
files. However, if calling alignmentStats
on a qProject
object, it will report 7 and 12 unmapped reads in the auxiliary bam
files. This
is because alignmentStats
is aware that unmapped reads are removed from auxiliary
bam
files by QuasR, but can be calculated from the total number
of reads to be aligned to the auxiliary target, which equals the number of unmapped
reads in the corresponding genomic bam
file.
qExportWig
qExportWig
creates fixed-step wig files (see (http://genome.ucsc.edu/goldenPath/help/wiggle.html)
for format definition) from the genomic alignments contained in a qProject
object.
The combine
argument controls if several input files are combined into a single
multi-track wig file, or if they are exported as individual wig files. Alignments
of single read experiments can be shifted towards there 3’-end using shift
;
paired-end alignments are automatically shifted by half the insert size. The
resolution of the created wig file is defines by the binsize
argument, and
if scaling=TRUE
, multiple alignment files in the qProject
object are scaled by their total number of reads.
qCount
qCount
is the workhorse for counting alignments that overlap query regions.
Usage and details on parameters can be obtained from the qCount
function
documentation. Two aspects that are of special importance are also discussed here:
How an alignment overlap with a query region is defined can be controlled by the
following arguments of qCount
:
selectReadPosition
specifies the read base that serves as a reference for
overlaps with query regions. The alignment position of that base, eventually
after shifting (see below), needs to be contained in the query region for an
overlap. selectReadPosition
can be set to "start"
(the default) or "end"
, which refer to the biological start (5’-end) and end (3’-end) of the read.
For example, the "start"
of a read aligned to the plus strand is the leftmost
base in the alignment (the one with the lowest coordinate), and the "end"
of a read aligned to the minus strand is also its leftmost base in the alignment.shift
allows shifting of alignments towards their 3’-end prior to overlap
determination and counting. This can be helpful to increase resolution of ChIP-seq
experiments by moving alignments by half the immuno-precipitated fragment size
towards the middle of fragments. shift
can either contain "integer"
values
that specify the shift size, or for paired-end experiments, it can be set to
the keyword "halfInsert"
, which will estimate the true fragment size from
the distance between aligned read pairs and shift the alignments accordingly.orientation
controls the interpretation of alignment strand relative to the
strand of the query region. The default value "any"
will count all overlapping
alignments, irrespective of the strand. This setting is for example used in an
unstranded RNA-seq experiment where both sense and antisense reads are generated
from an mRNA. A value of "same"
will only count the alignments on the same
strand as the query region (e.g. in a stranded RNA-seq experiment), and
"opposite"
will only count the alignments on the opposite strand from the
query region (e.g. to quantify anti-sense transcription in a stranded RNA-seq
experiment).useRead
only applies to paired-end experiments and allows to quantify either
all alignments (useRead="any"
), or only the first (useRead="first"
) or last
(useRead="last"
) read from each read pair or read group. Note that for
useRead="any"
(the default), an alignment pair that is fully contained within
a query region will contribute two counts to the value of that region.includeSpliced
: When set to FALSE
, spliced alignments will be excluded from
the quantification. This could be useful for example to avoid redundant counting
of reads when the spliced alignments are quantified separately using
reportLevel="junction"
.qCount
The features to be quantified are specified by the query
argument. At the same
time, the type of query
selects the mode of quantification. qCount
supports
three different types of query
arguments and implements three corresponding
quantification types, which primarily differ in the way they deal with redundancy,
such as query bases that are contained in more than one query region. A fourth
quantification mode allows counting of alignments supporting exon-exon juctions:
GRanges
query: Overlapping alignments are counted separately for each coordinate
region in the query object. If multiple regions have identical names, their counts
will be summed, counting each alignment only once even if it overlaps more than
one of these regions. Alignments may however be counted more than once if they
overlap multiple regions with different names. This mode is for example used to
quantify ChIP-seq alignments in promoter regions (see section 6.1), or
gene expression levels in an RNA-seq experiment (using a ‘query’ with exon regions
named by gene).GRangesList
query: Alignments are counted and summed for each list element in
the query object if they overlap with any of the regions contained in the list
element. The order of the list elements defines a hierarchy for quantification:
Alignment will only be counted for the first element (the one with the lowest
index in the query) that they overlap, but not for any potential further list
elements containing overlapping regions. This mode can be used to hierarchically
and uniquely count (assign) each alignment to a one of several groups of regions
(the elements in the query), for example to estimate the fractions of different
classes of RNA in an RNA-seq experiment (rRNA, tRNA, snRNA, snoRNA, mRNA, etc.)TxDb
query: Used to extract regions from annotation and report alignment counts
depending on the value of the reportLevel
argument. If reportLevel="exon"
,
alignments overlapping each exon in the query are counted. If reportLevel="gene"
,
alignment counts for all exons of a gene will be summed, counting each alignment
only once even if it overlaps multiple annotated exons of a gene. These are
useful to calculate exon or gene expression levels in RNA-seq experiments
based on the annotation in a TxDb
object. If reportLevel="promoter"
, the
promoters
function from package GenomicFeatures is used
with default arguments to extract promoter regions around transcript start
sites, e.g. to quantify alignments inf a ChIP-seq experiment.NULL
for reportLevel="junction"
: The query
argument
is ignored if reportLevel
is set to "junction"
, and qCount
will count
the number of alignments supporting each exon-exon junction detected in any
of the samples in proj
. The arguments selectReadPosition
, shift
, orientation
,
useRead
and mask
will have no effect in this quantification mode.qProfile
The qProfile
function differs from qCount
in that it returns alignments counts
relative to their position in the query region. Except for upstream
and downstream
,
the arguments of qProfile
and qCount
are the same. This section will describe
these two additional arguments; more details on the other arguments are available
in section 7.7 and from the qProfile
function documentation.
The regions to be profiled are anchored by the biological start position, which
are aligned at position zero in the return value. The biological start position
is defined as start(query)
for regions on the plus strand and end(query)
for
regions on the minus strand. The anchor positions are extended to the left and
right sides by the number of bases indicated in the upstream
and downstream
arguments.
upstream
indicates the number of bases upstream of the anchor position,
which is on the left side of the anchor point for regions on the plus strand
and on the right side for regions on the minus strand.downstream
indicates the number of bases downstream of the anchor position,
which is on the left side of the anchor point for regions on the plus strand
and on the left side for regions on the minus strand.Be aware that query regions with a *
strand are handled the same way as regions
on the plus strand.
qMeth
qMeth
is used exclusively for Bis-seq experiments. In contrast to qCount
,
which counts the number of read alignments per query region, qMeth
quantifies
the number of C and T bases per cytosine in query regions, in order to determine
methylation status.
qMeth
can be run in one of four modes, controlled by the mode
argument:
CpGcomb
: Only C’s in CpG context are considered. It is assumed that methylation
status of the CpG base-pair on both strands is identical. Therefore, the total
and methylated counts obtained for the C at position \(i\) and the C on the opposite
strand at position \(i+1\) are summed.CpG
: As with CpGcomb
, only C’s in CpG context are quantified. However, counts
from opposite strand are not summed, resulting in separate output values for C’s
on both strands.allC
: All C’s contained in query regions are quantified, keeping C’s from
either strand separate. While this mode allows quantification of non-CpG
methylation, it should be used with care, as the large result could use up
available memory. In that case, a possible work-around is to divide the
region of interest (e.g. the genome) into several regions (e.g. chromosomes)
and call qMeth
separately for each region.var
: In this mode, only alignments on the opposite strand from C’s are analysed
in order to collect evidence for sequence polymorphisms. Methylated C’s are
hot-spots for C-to-T transitions, which in a Bis-seq experiment cannot be
discriminated from completely unmethylated C’s. The information is however
contained in alignments to the G from the opposite strand: Reads containing
a G are consistent with a non-mutated C, and reads with an A support the
presence of a sequence polymorphism. qMeth(..., mode="var")
returns counts
for total and matching bases for all C’s on both strands. A low fraction of
matching bases is an indication of a mutation and can be used as a basis to
identify mutated positions in the studied genome relative to the reference
genome. Such positions should not be included in the quantification of methylation.When using qMeth
in a allele-specific quantification (see also section
6.5, cytosines (or CpGs) that overlap a sequence
polymorphism will not be quantified.
The output in this vignette was produced under:
## R version 4.1.0 (2021-05-18)
## Platform: x86_64-pc-linux-gnu (64-bit)
## Running under: Ubuntu 20.04.2 LTS
##
## Matrix products: default
## BLAS: /home/biocbuild/bbs-3.13-bioc/R/lib/libRblas.so
## LAPACK: /home/biocbuild/bbs-3.13-bioc/R/lib/libRlapack.so
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##
## attached base packages:
## [1] grid stats4 parallel stats graphics grDevices utils
## [8] datasets methods base
##
## other attached packages:
## [1] Gviz_1.36.0 GenomicFeatures_1.44.0 AnnotationDbi_1.54.0
## [4] Biobase_2.52.0 Rsamtools_2.8.0 BSgenome_1.60.0
## [7] rtracklayer_1.52.0 Biostrings_2.60.0 XVector_0.32.0
## [10] QuasR_1.32.0 Rbowtie_1.32.0 GenomicRanges_1.44.0
## [13] GenomeInfoDb_1.28.0 IRanges_2.26.0 S4Vectors_0.30.0
## [16] BiocGenerics_0.38.0 BiocStyle_2.20.0
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Anders, Simon, Alejandro Reyes, and Wolfgang Huber. 2012. “Detecting Differential Usage of Exons from RNA-Seq Data.” Genome Research 22: 2008–17. https://doi.org/10.1101/gr.133744.111.
Au, K.F., H. Jiang, L. Lin, Y. Xing, and W.H. Wong. 2010. “Detection of Splice Junctions from Paired-End RNA-Seq Data by SpliceMap.” Nucleic Acids Research 38 (14): 4570–8.
Dalgaard, P. 2002. Introductory Statistics with R. Springer.
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