EpiCompare
⚖QC and Benchmarking of Epigenomic DatasetsEpiCompare
is an R package for comparing multiple epigenomic datasets
for quality control and benchmarking purposes. The function outputs a
report in HTML format consisting of three sections:
Note: Peaks located in blacklisted regions and non-standard chromosomes are removed from the files prior to analysis.
To install EpiCompare
use:
if (!require("BiocManager", quietly = TRUE)) install.packages("BiocManager")
BiocManager::install("EpiCompare")
👈 Details
Installing all Imports and Suggests will allow you to use the full
functionality of EpiCompare
right away, without having to stop and
install extra dependencies later on.
To install these packages as well, use:
BiocManager::install("EpiCompare", dependencies=TRUE)
Note that this will increase installation time, but it means that you won’t have to worry about installing any R packages when using functions with certain suggested dependencies
👈 Details
To install the development version of EpiCompare
, use:
if (!require("remotes")) install.packages("remotes")
remotes::install_github("neurogenomics/EpiCompare")
If you use EpiCompare
, please cite:
EpiCompare: R package for the comparison and quality control of epigenomic peak files (2022) Sera Choi, Brian M. Schilder, Leyla Abbasova, Alan E. Murphy, Nathan G. Skene, bioRxiv, 2022.07.22.501149; doi: https://doi.org/10.1101/2022.07.22.501149
The documentation in this README and the GitHub Pages
website pertains to the
development version of EpiCompare
. Older versions of EpiCompare
may have slightly different documentation (e.g. available functions,
parameters). For documentation in older versions of EpiCompare
, please
see the Documentation section of the relevant version on
Bioconductor
Load package and example datasets.
library(EpiCompare)
data("encode_H3K27ac") # example peakfile
data("CnT_H3K27ac") # example peakfile
data("CnR_H3K27ac") # example peakfile
data("CnT_H3K27ac_picard") # example Picard summary output
data("CnR_H3K27ac_picard") # example Picard summary output
Prepare input files:
# create named list of peakfiles
peakfiles <- list("CnT"=CnT_H3K27ac,
"CnR"=CnR_H3K27ac)
# set ref file and name
reference <- list("ENCODE_H3K27ac" = encode_H3K27ac)
# create named list of Picard summary
picard_files <- list("CnT"=CnT_H3K27ac_picard,
"CnR"=CnR_H3K27ac_picard)
👈 Tips on importing user-supplied files
EpiCompare::gather_files
is helpful for identifying and importing peak
or picard files.
# To import BED files as GRanges object
peakfiles <- EpiCompare::gather_files(dir = "path/to/peaks/",
type = "peaks.stringent")
# EpiCompare alternatively accepts paths (to BED files) as input
peakfiles <- list(sample1="/path/to/peaks/file1_peaks.stringent.bed",
sample2="/path/to/peaks/file2_peaks.stringent.bed")
# To import Picard summary output txt file as data frame
picard_files <- EpiCompare::gather_files(dir = "path/to/peaks",
type = "picard")
Run EpiCompare()
:
EpiCompare::EpiCompare(peakfiles = peakfiles,
genome_build = list(peakfiles="hg19",
reference="hg38"),
genome_build_output = "hg19",
picard_files = picard_files,
reference = reference,
run_all = TRUE
output_dir = tempdir())
These input parameters must be provided:
👈 Details
peakfiles
: Peakfiles you want to analyse. EpiCompare accepts
peakfiles as GRanges object and/or as paths to BED files. Files must
be listed and named using list()
. E.g.
list("name1"=peakfile1, "name2"=peakfile2)
.genome_build
: A named list indicating the human genome build used
to generate each of the following inputs:peakfiles
: Genome build for the peakfiles
input. Assumes genome
build is the same for each element in the peakfiles
list.reference
: Genome build for the reference
input.blacklist
: Genome build for the blacklist
input. E.g.
genome_build = list(peakfiles="hg38", reference="hg19", blacklist="hg19")
genome_build_output
Genome build to standardise all inputs to.
Liftovers will be performed automatically as needed. Default is
“hg19”.blacklist
: Peakfile as GRanges object specifying genomic regions
that have anomalous and/or unstructured signals independent of the
cell-line or experiment. For human hg19 and hg38 genome, use built-in
data data(hg19_blacklist)
and data(hg38_blacklist)
respectively.
For mouse mm10 genome, use built-in data data(mm10_blacklist)
.output_dir
: Please specify the path to directory, where all
EpiCompare
outputs will be saved.The following input files are optional:
👈 Details
picard_files
: A list of summary metrics output from
Picard. Picard
MarkDuplicates can be used to identify the duplicate reads amongst
the alignment. This tool generates a summary output, normally with the
ending .markdup.MarkDuplicates.metrics.txt. If this input is
provided, metrics on fragments (e.g. mapped fragments and duplication
rate) will be included in the report. Files must be in data.frame
format and listed using list()
and named using names()
. To import
Picard duplication metrics (.txt file) into R as data frame, use
picard <- read.table("/path/to/picard/output", header = TRUE, fill = TRUE)
.reference
: Reference peak file(s) is used in stat_plot
and
chromHMM_plot
. File must be in GRanges
object, listed and named
using list("reference_name" = GRanges_obect)
. If more than one
reference is specified, EpiCompare
outputs individual reports for
each reference. However, please note that this can take awhile.By default, these plots will not be included in the report unless set to
TRUE
. To turn on all features at once, simply use the run_all=TRUE
argument:
👈 Details
upset_plot
: Upset plot of overlapping peaks between samples.stat_plot
: included only if a reference
dataset is provided. The
plot shows statistical significance (p/q-values) of sample peaks that
are overlapping/non-overlapping with the reference
dataset.chromHMM_plot
: ChromHMM annotation of peaks. If a reference
dataset is provided, ChromHMM annotation of overlapping and
non-overlapping peaks with the reference
is also included in the
report.chipseeker_plot
: ChIPseeker annotation of peaks.enrichment_plot
: KEGG pathway and GO enrichment analysis of peaks.tss_plot
: Peak frequency around (+/- 3000bp) transcriptional start
site. Note that it may take awhile to generate this plot for large
sample sizes.precision_recall_plot
: Plot showing the precision-recall score
across the peak calling stringency thresholds.corr_plot
: Plot showing the correlation between the quantiles when
the genome is binned at a set size. These quantiles are based on the
intensity of the peak, dependent on the peak caller used (q-value for
MACS2).👈 Details
chromHMM_annotation
: Cell-line annotation for ChromHMM. Default is
K562. Options are:interact
: By default, all heatmaps (percentage overlap and ChromHMM
heatmaps) in the report will be interactive. If set FALSE, all
heatmaps will be static. N.B. If interact=TRUE
, interactive heatmaps
will be saved as html files, which may take time for larger sample
sizes.output_filename
: By default, the report is named EpiCompare.html.
You can specify the file name of the report here.output_timestamp
: By default FALSE. If TRUE, the filename of the
report includes the date.EpiCompare
outputs the following:
output_dir
save_output=TRUE
, all plots generated by
EpiCompare
will be saved in EpiCompare_file directory also in
specified output_dir
An example report comparing ATAC-seq and DNase-seq can be found here
EpiCompare
includes several built-in datasets:
👈 Details
encode_H3K27ac
: Human H3K27ac peak file generated with ChIP-seq
using K562 cell-line. Taken from
ENCODE project.
For more information, run ?encode_H3K27ac
. CnT_H3K27ac
: Human H3K27ac peak file generated with CUT&Tag using
K562 cell-line from Kaya-Okur et al.,
(2019).
For more information, run ?CnT_H3K27ac
.CnR_H3K27ac
: Human H3K27ac peak file generated with CUT&Run using
K562 cell-line from Meers et al.,
(2019).
For more details, run ?CnR_H3K27ac
.UK Dementia Research Institute Department of Brain Sciences Faculty of Medicine Imperial College London GitHub DockerHub
👈 Details
utils::sessionInfo()
## R version 4.4.1 (2024-06-14)
## Platform: aarch64-apple-darwin20
## Running under: macOS 15.0.1
##
## Matrix products: default
## BLAS: /Library/Frameworks/R.framework/Versions/4.4-arm64/Resources/lib/libRblas.0.dylib
## LAPACK: /Library/Frameworks/R.framework/Versions/4.4-arm64/Resources/lib/libRlapack.dylib; LAPACK version 3.12.0
##
## locale:
## [1] en_US.UTF-8/en_US.UTF-8/en_US.UTF-8/C/en_US.UTF-8/en_US.UTF-8
##
## time zone: Europe/London
## tzcode source: internal
##
## attached base packages:
## [1] stats graphics grDevices utils datasets methods base
##
## loaded via a namespace (and not attached):
## [1] gtable_0.3.5 jsonlite_1.8.9 renv_1.0.11
## [4] dplyr_1.1.4 compiler_4.4.1 BiocManager_1.30.25
## [7] tidyselect_1.2.1 rvcheck_0.2.1 scales_1.3.0
## [10] yaml_2.3.10 fastmap_1.2.0 here_1.0.1
## [13] ggplot2_3.5.1 R6_2.5.1 generics_0.1.3
## [16] knitr_1.48 yulab.utils_0.1.7 tibble_3.2.1
## [19] desc_1.4.3 dlstats_0.1.7 rprojroot_2.0.4
## [22] munsell_0.5.1 pillar_1.9.0 RColorBrewer_1.1-3
## [25] rlang_1.1.4 utf8_1.2.4 badger_0.2.4
## [28] xfun_0.48 fs_1.6.4 cli_3.6.3
## [31] magrittr_2.0.3 rworkflows_1.0.2 digest_0.6.37
## [34] grid_4.4.1 rstudioapi_0.16.0 lifecycle_1.0.4
## [37] vctrs_0.6.5 evaluate_1.0.1 glue_1.8.0
## [40] data.table_1.16.2 fansi_1.0.6 colorspace_2.1-1
## [43] rmarkdown_2.28 tools_4.4.1 pkgconfig_2.0.3
## [46] htmltools_0.5.8.1
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