megadepth 1.17.0
The goal of megadepth is to provide an R interface to the command line tool Megadepth for BigWig and BAM related utilities created by Christopher Wilks (Wilks, Ahmed, Baker, Zhang, Collado-Torres, and Langmead, 2020). This R package enables fast processing of BigWig files on downstream packages such as dasper and recount3. The Megadepth software also provides utilities for processing BAM files and extracting coverage information from them.
Here is an illustration on how fast megadepth is compared to other tools for processing local and remote BigWig files.
Throughout the documentation we use a capital M
to refer to the software by Christopher Wilks and a lower case m
to refer to this R/Bioconductor package.
megadepth
R
is an open-source statistical environment which can be easily modified to enhance its functionality via packages. megadepth is a R
package available via the Bioconductor repository for packages. R
can be installed on any operating system from CRAN after which you can install megadepth by using the following commands in your R
session:
if (!requireNamespace("BiocManager", quietly = TRUE)) {
install.packages("BiocManager")
}
BiocManager::install("megadepth")
## Check that you have a valid Bioconductor installation
BiocManager::valid()
megadepth is based on many other packages and in particular in those that have implemented the infrastructure needed for dealing with RNA-seq data and high-throughput sequencing data in general. You might benefit from being familiar with the BigWig file format and the rtracklayer for importing those files into R as well as exporting BED files (Lawrence, Gentleman, and Carey, 2009). If you are working with annoation files, GenomicFeatures and GenomicRanges will also be useful to you.
If you are asking yourself the question “Where do I start using Bioconductor?” you might be interested in this blog post.
As package developers, we try to explain clearly how to use our packages and in which order to use the functions. But R
and Bioconductor
have a steep learning curve so it is critical to learn where to ask for help. The blog post quoted above mentions some but we would like to highlight the Bioconductor support site as the main resource for getting help: remember to use the megadepth
tag and check the older posts. Other alternatives are available such as creating GitHub issues and tweeting. However, please note that if you want to receive help you should adhere to the posting guidelines. It is particularly critical that you provide a small reproducible example and your session information so package developers can track down the source of the error.
megadepth
We hope that megadepth will be useful for your research. Please use the following information to cite the package and the overall approach. Thank you!
## Citation info
citation("megadepth")
#> To cite package 'megadepth' in publications use:
#>
#> Zhang D, Collado-Torres L (2024). _megadepth: BigWig and BAM related
#> utilities_. doi:10.18129/B9.bioc.megadepth
#> <https://doi.org/10.18129/B9.bioc.megadepth>,
#> https://github.com/LieberInstitute/megadepth - R package version
#> 1.17.0, <http://www.bioconductor.org/packages/megadepth>.
#>
#> Wilks C, Ahmed O, Baker DN, Zhang D, Collado-Torres L, Langmead B
#> (2020). "Megadepth: efficient coverage quantification for BigWigs and
#> BAMs." _bioRxiv_. doi:10.1101/2020.12.17.423317
#> <https://doi.org/10.1101/2020.12.17.423317>,
#> <https://www.biorxiv.org/content/10.1101/2020.12.17.423317v1>.
#>
#> To see these entries in BibTeX format, use 'print(<citation>,
#> bibtex=TRUE)', 'toBibtex(.)', or set
#> 'options(citation.bibtex.max=999)'.
To get started, we need to load the megadepth package into our R session. This will load all the required dependencies.
library("megadepth")
Once we have the R package loaded, we need to install the Megadepth software. We can do so with install_megadepth()
, which downloads a binary for your OS (Linux, Windows or macOS) 1 Please check Megadepth for instructions on how to compile the software from source if the binary version doesn’t work for you.. We can then use with an example BigWig file to compute the coverage at a set of regions.
## Install the latest version of Megadepth
install_megadepth(force = TRUE)
#> The latest megadepth version is 1.2.0
#> This is not an interactive session, therefore megadepth has been installed temporarily to
#> /tmp/RtmpEzsngd/megadepth
Next, we might want to use megadepth to quantify the coverage at a set of regions of the genome of interest to us. Here we will use two example files that are include in the package for illustration and testing purposes. One of them is a bigWig file that contains the base-pair coverage information for a sample of interest and the second one is BED file which contains the genomic region coordinates of interest. So we first locate them.
## Next, we locate the example BigWig and annotation files
example_bw <- system.file("tests", "test.bam.all.bw",
package = "megadepth", mustWork = TRUE
)
annotation_file <- system.file("tests", "testbw2.bed",
package = "megadepth", mustWork = TRUE
)
## Where are they?
example_bw
#> [1] "/tmp/RtmptFmWqj/Rinst1220b43db2b963/megadepth/tests/test.bam.all.bw"
annotation_file
#> [1] "/tmp/RtmptFmWqj/Rinst1220b43db2b963/megadepth/tests/testbw2.bed"
Once we have located the example files we can proceed to calculating the base-pair coverage for our genomic regions of interest. There are several ways to do this with megadepth, but here we use the user-friendly function get_coverage()
. This function will perform a given operation op on the bigWig file for a given set of regions of interest (annotation). One of those operations is to compute the mean base-pair coverage for each input region. This is what we’ll do with our example bigWig file.
## We can then use megadepth to compute the coverage
bw_cov <- get_coverage(
example_bw,
op = "mean",
annotation = annotation_file
)
bw_cov
#> GRanges object with 4 ranges and 1 metadata column:
#> seqnames ranges strand | score
#> <Rle> <IRanges> <Rle> | <numeric>
#> [1] chr10 0-10 * | 0.00
#> [2] chr10 8756697-8756762 * | 15.85
#> [3] chr10 4359156-4359188 * | 3.00
#> [4] GL000219.1 168500-168620 * | 1.26
#> -------
#> seqinfo: 2 sequences from an unspecified genome; no seqlengths
get_coverage()
returns an object that is familiar to GenomicRanges users, that is, a GRanges
object that can be used with other Bioconductor software packages (Huber, Carey, Gentleman, Anders, Carlson, Carvalho, Bravo, Davis, Gatto, Girke, Gottardo, Hahne, Hansen, Irizarry, Lawrence, Love, MacDonald, Obenchain, Oleś, Pagès, Reyes, Shannon, Smyth, Tenenbaum, Waldron, and Morgan, 2015).
This example is just the tip of the iceberg, as Megadepth and thus megadepth can do a lot of useful processing operations on BAM and bigWig files.
Megadepth is very powerful and can do a lot of different things. The R/Bioconductor package provides two functions for interfacing with Megadepth, megadepth_cmd()
and megadepth_shell()
. For the first one, megadepth_cmd()
, you need to know the actual command syntax you want to use and format it accordingly. If you are more comfortable with R functions, megadepth_shell()
uses cmdfun to power this interface and capture the standard output stream into R.
To make it easier to use, megadepth
includes functions that simplify the number of arguments, read in the output files, and converts them into R/Bioconductor friendly objects, such as get_coverage()
illustrated previously in the quick start section.
We hope that you’ll find megadepth
and Megadepth useful for your work. If you are interested in checking how fast megadepth
is, check out the speed analysis comparison against other tools. Note that the size of the files used and the number of genomic regions queried will affect the speed comparisons.
## R-like interface
## that captures the standard output into R
head(megadepth_shell(help = TRUE))
#> [1] "megadepth 1.2.0" ""
#> [3] "BAM and BigWig utility." ""
#> [5] "Usage:" " megadepth <bam|bw|-> [options]"
## Command-like interface
megadepth_cmd("--help")
#> megadepth 1.2.0
#>
#> BAM and BigWig utility.
#>
#> Usage:
#> megadepth <bam|bw|-> [options]
#>
#> Options:
#> -h --help Show this screen.
#> --version Show version.
#> --threads # of threads to do: BAM decompression OR compute sums over multiple BigWigs in parallel
#> if the 2nd is intended then a TXT file listing the paths to the BigWigs to process in parallel
#> should be passed in as the main input file instead of a single BigWig file (EXPERIMENTAL).
#> --prefix String to use to prefix all output files.
#> --no-auc-stdout Force all AUC(s) to be written to <prefix>.auc.tsv rather than STDOUT
#> --no-annotation-stdout Force summarized annotation regions to be written to <prefix>.annotation.tsv rather than STDOUT
#> --no-coverage-stdout Force covered regions to be written to <prefix>.coverage.tsv rather than STDOUT
#> --keep-order Output annotation coverage in the order chromosomes appear in the BAM/BigWig file
#> The default is to output annotation coverage in the order chromosomes appear in the annotation BED file.
#> This is only applicable if --annotation is used for either BAM or BigWig input.
#>
#> BigWig Input:
#> Extract regions and their counts from a BigWig outputting BED format if a BigWig file is detected as input (exclusive of the other BAM modes):
#> Extracts all reads from the passed in BigWig and output as BED format.
#> This will also report the AUC over the annotated regions to STDOUT.
#> If only the name of the BigWig file is passed in with no other args, it will *only* report total AUC to STDOUT.
#> --annotation <bed> Only output the regions in this BED applying the argument to --op to them.
#> --op <sum[default], mean, min, max> Statistic to run on the intervals provided by --annotation
#> --sums-only Discard coordinates from output of summarized regions
#> --distance (2200[default]) Number of base pairs between end of last annotation and start of new to consider in the same BigWig query window (a form of binning) for performance. This determines the number of times the BigWig index is queried.
#> --unsorted (off[default]) There's a performance improvement *if* BED file passed to --annotation is 1) sorted by sort -k1,1 -k2,2n (default is to assume sorted and check for unsorted positions, if unsorted positions are found, will fall back to slower version)
#> --bwbuffer <1GB[default]> Size of buffer for reading BigWig files, critical to use a large value (~1GB) for remote BigWigs.
#> Default setting should be fine for most uses, but raise if very slow on a remote BigWig.
#>
#>
#> BAM Input:
#> Extract basic junction information from the BAM, including co-occurrence
#> If only the name of the BAM file is passed in with no other args, it will *only* report total AUC to STDOUT.
#> --fasta Path to the reference FASTA file if a CRAM file is passed as the input file (ignored otherwise)
#> If not passed, references will be downloaded using the CRAM header.
#> --junctions Extract co-occurring jx coordinates, strand, and anchor length, per read
#> writes to a TSV file <prefix>.jxs.tsv
#> --all-junctions Extract all jx coordinates, strand, and anchor length, per read for any jx
#> writes to a TSV file <prefix>.all_jxs.tsv
#> --longreads Modifies certain buffer sizes to accommodate longer reads such as PB/Oxford.
#> --filter-in Integer bitmask, any bits of which alignments need to have to be kept (similar to samtools view -f).
#> --filter-out Integer bitmask, any bits of which alignments need to have to be skipped (similar to samtools view -F).
#> --add-chr-prefix Adds "chr" prefix to relevant chromosomes for BAMs w/o it, pass "human" or "mouse".
#> Only works for human/mouse references (default: off).
#>
#> Non-reference summaries:
#> --alts Print differing from ref per-base coverages
#> Writes to a CSV file <prefix>.alts.tsv
#> --include-softclip Print a record to the alts CSV for soft-clipped bases
#> Writes total counts to a separate TSV file <prefix>.softclip.tsv
#> --only-polya If --include-softclip, only print softclips which are mostly A's or T's
#> --include-n Print mismatch records when mismatched read base is N
#> --print-qual Print quality values for mismatched bases
#> --delta Print POS field as +/- delta from previous
#> --require-mdz Quit with error unless MD:Z field exists everywhere it's
#> expected
#> --head Print sequence names and lengths in SAM/BAM header
#>
#> Coverage and quantification:
#> --coverage Print per-base coverage (slow but totally worth it)
#> --auc Print per-base area-under-coverage, will generate it for the genome
#> and for the annotation if --annotation is also passed in
#> Defaults to STDOUT, unless other params are passed in as well, then
#> if writes to a TSV file <prefix>.auc.tsv
#> --bigwig Output coverage as BigWig file(s). Writes to <prefix>.bw
#> (also <prefix>.unique.bw when --min-unique-qual is specified).
#> Requires libBigWig.
#> --annotation <BED|window_size> Path to BED file containing list of regions to sum coverage over
#> (tab-delimited: chrm,start,end). Or this can specify a contiguous region size in bp.
#> --op <sum[default], mean> Statistic to run on the intervals provided by --annotation
#> --no-index If using --annotation, skip the use of the BAM index (BAI) for pulling out regions.
#> Setting this can be faster if doing windows across the whole genome.
#> This will be turned on automatically if a window size is passed to --annotation.
#> --min-unique-qual <int>
#> Output second bigWig consisting built only from alignments
#> with at least this mapping quality. --bigwig must be specified.
#> Also produces second set of annotation sums based on this coverage
#> if --annotation is enabled
#> --double-count Allow overlapping ends of PE read to count twice toward
#> coverage
#> --num-bases Report total sum of bases in alignments processed (that pass filters)
#> --gzip Turns on gzipping of coverage output (no effect if --bigwig is passsed),
#> this will also enable --no-coverage-stdout.
#>
#> Other outputs:
#> --read-ends Print counts of read starts/ends, if --min-unique-qual is set
#> then only the alignments that pass that filter will be counted here
#> Writes to 2 TSV files: <prefix>.starts.tsv, <prefix>.ends.tsv
#> --frag-dist Print fragment length distribution across the genome
#> Writes to a TSV file <prefix>.frags.tsv
#> --echo-sam Print a SAM record for each aligned read
#> --ends Report end coordinate for each read (useful for debugging)
#> --test-polya Lower Poly-A filter minimums for testing (only useful for debugging/testing)
#>
#>
One use case of Megadepth is to convert BAM files to bigWig coverage files. To simplify this process and verify that you are not accidentally overwriting valuable files, megadepth provides the function bam_to_bigwig()
. To illustrate this functionality, we first locate an example BAM file. We then generate the output bigWig files
## Find the example BAM file
example_bam <- system.file("tests", "test.bam",
package = "megadepth", mustWork = TRUE
)
## Create the BigWig file
## Currently Megadepth does not support this on Windows
example_bw <- bam_to_bigwig(example_bam, overwrite = TRUE)
## Path to the output files generated by bam_to_bigwig()
example_bw
#> all.bw
#> "/tmp/RtmpEzsngd/test.bam.all.bw"
Currently this functionality does not work on Windows. In which case, you can continue the vignette with the following example bigWig file.
## On Windows, use the example bigWig file that is already included in
## the R package
example_bw <- system.file("tests", "test.bam.all.bw",
package = "megadepth", mustWork = TRUE
)
Once you have a biWig file, you might want to quantify the mean or total expression across a set of genomic coordinates. bigWig files are typically used by genome browsers, and as part of the recount and recount3 projects we have released thousands of them. Before we expand more complex uses cases, you might be interested in get_coverage()
. This function will use Megadepth to create a tab-separated value (TSV) file containing the coverage summary information 2 Sum, mean, min or max base-pair coverage for each region. for a given input file that can be read into R using read_coverage()
3 If you prefer a tibble
, use read_coverage_table()
. as shown below with an example set of genomic regions of interest (annotation).
## Next, we locate the example annotation BED file
annotation_file <- system.file("tests", "testbw2.bed",
package = "megadepth", mustWork = TRUE
)
## Now we can compute the coverage
bw_cov <- get_coverage(example_bw, op = "mean", annotation = annotation_file)
bw_cov
#> GRanges object with 4 ranges and 1 metadata column:
#> seqnames ranges strand | score
#> <Rle> <IRanges> <Rle> | <numeric>
#> [1] chr10 0-10 * | 0.00
#> [2] chr10 8756697-8756762 * | 15.85
#> [3] chr10 4359156-4359188 * | 3.00
#> [4] GL000219.1 168500-168620 * | 1.26
#> -------
#> seqinfo: 2 sequences from an unspecified genome; no seqlengths
If you are familiar with rtracklayer, you’ll notice that the coverage summaries are basically the same to the one that can be generated with rtracklayer::import.bw()
, which is what derfinder uses internally.
## Checking with derfinder and rtracklayer
bed <- rtracklayer::import(annotation_file)
## The file needs a name
names(example_bw) <- "example"
## Read in the base-pair coverage data
regionCov <- derfinder::getRegionCoverage(
regions = bed,
files = example_bw,
verbose = FALSE
)
## Summarize the base-pair coverage data.
## Note that we have to round the mean to make them comparable.
testthat::expect_equivalent(
round(sapply(regionCov[c(1, 3:4, 2)], function(x) mean(x$value)), 2),
bw_cov$score,
)
#> Warning: `expect_equivalent()` was deprecated in the 3rd edition.
#> ℹ Use expect_equal(ignore_attr = TRUE)
## If we compute the sum, there's no need to round
testthat::expect_equivalent(
sapply(regionCov[c(1, 3:4, 2)], function(x) sum(x$value)),
get_coverage(example_bw, op = "sum", annotation = annotation_file)$score,
)
#> Warning: `expect_equivalent()` was deprecated in the 3rd edition.
#> ℹ Use expect_equal(ignore_attr = TRUE)
Megadepth provides utilities that might be of use for future work or that were developed for building recount3. One of these features is the possibility to extract locally co-ocurring junctions from a BAM file as described in the Megadepth documentation. This feature works only for junctions for which a read or (read pair) has 2 or more junctions.
To illustrate this functionality, we will use an example BAM file and generate the locally co-occurring junction table with bam_to_junctions()
. We’ll then read in the data using read_junction_table()
4 The strand
columns have been switched from 0s and 1s to +
and -
for the forward and reverse strands, to match frequently used Bioconductor packages.. process_junction_table()
can then be used to convert the junctions into a STAR-compatible format.
## Find the example BAM file
example_bam <- system.file("tests", "test.bam",
package = "megadepth", mustWork = TRUE
)
## Run bam_to_junctions()
example_jxs <- bam_to_junctions(example_bam, overwrite = TRUE)
## Path to the output file generated by bam_to_junctions()
example_jxs
#> all_jxs.tsv
#> "/tmp/RtmpEzsngd/test.bam.all_jxs.tsv"
## Read the data as a tibble using the format specified at
## https://github.com/ChristopherWilks/megadepth#megadepth-pathtobamfile---junctions
example_jxs <- read_junction_table(example_jxs)
example_jxs
#> # A tibble: 35 × 7
#> read_name chr start end mapping_strand cigar unique
#> <chr> <chr> <dbl> <dbl> <chr> <chr> <int>
#> 1 26573693 chr10 4358579 4581019 - 61M222441N11M 0
#> 2 59413733 chr10 8458623 8778558 + 13M319936N59M 0
#> 3 63502504 chr10 8722315 8848720 - 50M126406N22M 1
#> 4 15130473 chr10 8722508 8870679 - 61M148172N11M 1
#> 5 22331161 chr10 8756762 8780518 - 62M23757N10M 1
#> 6 37510913 chr10 8756762 8780518 - 62M23757N10M 1
#> 7 38798461 chr10 8756762 8780518 - 62M23757N10M 1
#> 8 62329988 chr10 8756762 8780518 - 62M23757N10M 1
#> 9 66789502 chr10 8756762 8780518 - 62M23757N10M 1
#> 10 78396176 chr10 8756762 8780518 - 62M23757N10M 1
#> # ℹ 25 more rows
process_junction_table(example_jxs)
#> # A tibble: 5 × 8
#> chr start end strand intron_motif annotated uniquely_mapping_reads
#> <chr> <dbl> <dbl> <dbl> <dbl> <dbl> <int>
#> 1 chr10 4358579 4581019 0 0 0 0
#> 2 chr10 8458623 8778558 0 0 0 0
#> 3 chr10 8722315 8848720 0 0 0 1
#> 4 chr10 8722508 8870679 0 0 0 1
#> 5 chr10 8756762 8780518 0 0 0 20
#> # ℹ 1 more variable: multimapping_reads <int>
megadepth was made possible to David Zhang, the author of dasper, and a member of the Mina Ryten’s lab at UCL.
The ReCount
family involves the following teams:
The megadepth package (Zhang and Collado-Torres, 2024) was made possible thanks to:
This package was developed using biocthis.
Code for creating the vignette
## Create the vignette
library("rmarkdown")
system.time(render("megadepth.Rmd", "BiocStyle::html_document"))
## Extract the R code
library("knitr")
knit("megadepth.Rmd", tangle = TRUE)
Date the vignette was generated.
#> [1] "2024-10-29 18:10:53 EDT"
Wallclock time spent generating the vignette.
#> Time difference of 17.678 secs
R
session information.
#> ─ Session info ───────────────────────────────────────────────────────────────────────────────────────────────────────
#> setting value
#> version R Under development (unstable) (2024-10-21 r87258)
#> os Ubuntu 24.04.1 LTS
#> system x86_64, linux-gnu
#> ui X11
#> language (EN)
#> collate C
#> ctype en_US.UTF-8
#> tz America/New_York
#> date 2024-10-29
#> pandoc 3.1.3 @ /usr/bin/ (via rmarkdown)
#>
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This vignette was generated using BiocStyle (Oleś, 2024) with knitr (Xie, 2024) and rmarkdown (Allaire, Xie, Dervieux et al., 2024) running behind the scenes.
Citations made with RefManageR (McLean, 2017).
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